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Review

Environmental Reservoirs of Vibrio cholerae: Challenges and Opportunities for Ocean-Color Remote Sensing

1
Plymouth Marine Laboratory, Prospect Place, The Hoe, Plymouth PL1 3DH, UK
2
National Centre for Earth Observation (NCEO), Plymouth PL1 3DH, UK
3
Council of Scientific and Industrial Research (CSIR)-National Institute of Oceanography (NIO), Regional Centre, Abraham Madamakkal Road, Cochin, Kerala 682 018, India
4
Indian Council of Agricultural Research (ICAR)-Central Marine Fisheries Research Institute (CMFRI), Abraham Madamakkal Road, Kochi 682 018, India
5
Nansen Environmental Research Centre India (NERCI), First floor, Amenity Centre, KUFOS, Kochi, Kerala 682506, India
*
Author to whom correspondence should be addressed.
Remote Sens. 2019, 11(23), 2763; https://doi.org/10.3390/rs11232763
Submission received: 4 October 2019 / Revised: 18 November 2019 / Accepted: 20 November 2019 / Published: 24 November 2019

Abstract

:
The World Health Organization has estimated the burden of the on-going pandemic of cholera at 1.3 to 4 million cases per year worldwide in 2016, and a doubling of case-fatality-rate to 1.8% in 2016 from 0.8% in 2015. The disease cholera is caused by the bacterium Vibrio cholerae that can be found in environmental reservoirs, living either in free planktonic form or in association with host organisms, non-living particulate matter or in the sediment, and participating in various biogeochemical cycles. An increasing number of epidemiological studies are using land- and water-based remote-sensing observations for monitoring, surveillance, or risk mapping of Vibrio pathogens and cholera outbreaks. Although the Vibrio pathogens cannot be sensed directly by satellite sensors, remotely-sensed data can be used to infer their presence. Here, we review the use of ocean-color remote-sensing data, in conjunction with information on the ecology of the pathogen, to map its distribution and forecast risk of disease occurrence. Finally, we assess how satellite-based information on cholera may help support the Sustainable Development Goals and targets on Health (Goal 3), Water Quality (Goal 6), Climate (Goal 13), and Life Below Water (Goal 14).

1. Introduction

Vibrio bacteria are ubiquitous Gram-negative bacteria in the marine environment. These microscopic microorganisms live either in free planktonic form or in association with host organisms, non-living particulate matter or in the sediment, and participate in various biogeochemical cycles [1]. They are particularly abundant and diverse in the coastal environment, represented by more than 100 species, of which at least twelve are pathogenic. The Vibrio cholerae is the principal diarrheal human pathogen, causing acute intestinal infection with watery diarrhea. There are at least 200 serogroups of V. cholerae, with toxigenic serogroups of O1 and O139 involved in human epidemics [2,3]. In 2017, the cholera disease was reported to affect at least 47 countries worldwide, resulting in an estimated 2.9 million cases per year worldwide [4].
Over the past decades, several programs have been initiated across the globe for continuous monitoring of microbial quality of coastal waters, such as the European Centre for Disease Prevention and Control which maps V. cholerae in the environment, the U.S. Holden Laboratory project on coastal microbial water quality, and the Seawater Quality Monitoring Program in India. The use of remote-sensing observations to map cholera outbreaks in relation to environmental conditions was first proposed R. Colwell in 1996 [5]. Since then, associations between satellite-derived environmental variables such as temperature, salinity, sea surface height, chlorophyll concentration, and phytoplankton abundance have been further explored and exploited to improve our understanding of the ecology of bacterial pathogens and assess the risk of various water-associated diseases at different spatial and temporal scales (e.g., [6,7]). In the case of Vibrio bacteria, remote-sensing observations have been used to characterize the environment in which the pathogens and their hosts thrive, and specifically with ocean-color remote sensing observations to infer key biological variables related to the dynamics of phytoplankton (a putative host for Vibrio bacteria).
In the coming years, the development of research programs integrating in-situ and remote-sensing observations will be key in helping to address issues related to the risk of water-borne infectious diseases for human health. In the international coordination context, the intergovernmental organization Group on Earth Observations (GEO) has been working to promote the development of such research programs and to improving the use of Earth observations to support achievement of the United Nations 2030 Agenda for Sustainable Development. The agenda sets out a collection of Sustainable Development Goals (SDGs) with associated targets and indicators around three interdependent pillars of sustainable development: economic, social, and environmental. The potential of satellite observations to help achieve the global goals is recognized across the span of social, economic, and environmental SDG indicators [8,9]. However, the specific assessment of the potential of EO to support progress in SDGs related to the risk of water-borne infectious diseases for human health, and how these may help to design research activities that minimize negative interactions between goals and maximize positive ones [10] are yet to be addressed.
Many reviews have been published in relation to disease incidence, pathogenicity, anti-microbial resistance, and persistence mechanisms of Vibrio bacteria, and the use of satellite-based remote-sensing observations and modeling approaches for monitoring and forecasting risks to human health, e.g., [11,12,13,14,15,16,17,18]. However, none of these reviews have specifically addressed the potential of ocean-color to study the dynamics of environmental reservoirs of Vibrio bacteria via the characterization of ecological and biogeochemical signatures of Vibrio bacteria, and how this information may be relevant to support SDGs and assess related targets and indicators.
Here, we review: (1) The interaction of Vibrio bacteria with the environment and with living/non-living hosts present in the aquatic system; (2) the opportunities provided by remote-sensing observations, especially ocean color, to advance our understanding of the dynamics of environmental reservoirs of Vibrio bacteria and improve predictability of occurrence of disease outbreaks and risks to public health; and (3) articulate how these activities provide support to SDG targets on Health (Goal 3), Water quality (Goal 6), Climate (Goal 13), and Life under the water (Goal 14).

2. Global Distribution of Vibrio cholerae and Cholera Disease Outbreaks

Vibrio bacteria represent a significant portion of the culturable fraction of heterotrophic bacteria in estuarine and marine waters around the world [19]. The species V. cholerae may colonize human populations exposed to contaminated marine waters during recreational and fishing activities, or through drinking and consumption of contaminated water or seafood respectively [20,21,22,23]. The infected persons may then carry the bacteria to different places to which they travel.
Based on genetic reconstruction from clinical data, the onset of the seventh pandemic of cholera in 1961 has been traced back to a population of V. cholerae, El Tor, in the north-eastern Indian Ocean basin [24]. Since then, this pandemic has spread globally. Detailed genomic analysis shows that in the Americas, the pandemic spread in three main transmission waves through pathogens introduced by human travelers: A first introduction in Latin America in 1991 of a lineage from west-Africa; a second introduction in Mexico in 1991 but this time, belonging to a lineage from Asia or Eastern Europe; and a third, more recent introduction in 2010, into Haiti, involving the import of a South Asian strain [25,26].
However, V. cholerae does not require a human host to survive. They form an integral part of the native flora of aquatic environments, living (1) as free-floating bacterioplankton, (2) attached to non-living particles, and (3) in a symbiotic association with a living host ([27], see Section 3). The bacteria may be transported through long-distance oceanic corridors by currents, as well as in ballast-waters from ships. The occurrence of epidemics in endemic and non-endemic countries have been shown to originate primarily in coastal regions, and then spread inland through human transportation.
The presence of V. cholerae serogroups O1/139 that can cause cholera disease and non-O1/139 groups that can cause gastrointestinal infections or extra-intestinal infections, such as wound infections or otitis, have been reported in European coastal waters and recreational beaches of the North Sea [28,29], Baltic sea [30]; coastal waters of America in Argentina [31], Brazil [32], Haiti [3,33], Mexico [34], Peru [35,36], Uruguay [31], Venezuela [37], United States [38], and in ballast water tanks of ships in the Chesapeake Bay [39]; coastal provinces of African countries bordering the Gulf of Guinea, including Angola, Benin, Cameroun, Cote d’Ivoire, Republic of the Congo, Guinea, Guinea-Bissau, Senegal, Sierra Leone [4], and coastal provinces of Eastern African countries including Djibouti, Kenya [40], Mozambique [41], Tanzania [4]; estuarine waters of India and Bangladesh [42,43,44,45,46]; as well as in coastal regions in China [47], Vietnam [48], Comoros islands, and coastal waters of the State of Papua New Guinea [4].

3. Interactions of Vibrio cholerae with the Aquatic Environment

This section presents aquatic reservoirs of V. cholerae along with the environmental processes influencing bacterial growth, mortality, virulence, and biogeochemical activity. A schematic diagram of the bacterial interaction with the environmental reservoirs is presented in Figure 1.

3.1. Vibrio cholerae: Growth, Pathogenicity, Dormancy, and Mortality

3.1.1. Growth and Abundance

The growth and abundance of V. cholerae are primarily controlled by temperature and salinity. This tight relationship is well established across the northern and southern hemispheres, with reports for instance in the North Atlantic and North Sea [50,51], the Chesapeake Bay [38,52], tropical riverine-estuarine environments [45], and along the coast of Peru [36]. Other environmental variables including pH, turbidity (mixing of particles), the concentrations of dissolved oxygen (DO), dissolved organic carbon (DOM), particulate organic carbon (POM), ammonium, nitrate, phosphate, silicate, iron, heavy metals, pigments, the carbon/nitrogen ratio of suspended organic particulates, the abundance of host organisms, and effects of predation by protozoans and viruses have also been reported to affect the abundance of V. cholerae. However, they tend to explain a smaller fraction of the variance in V. cholerae abundance or the relationships between the environmental covariates and bacteria abundance may be less consistent across sites (e.g., [53,54,55]). These findings may also be subject to the availability of observations, availability of concurrent measurements of environmental variables and V. cholerae abundance, and the difficulty in detecting and measuring changes in abundance during short-term, sporadic events. For instance, an intense phytoplankton bloom was shown to stimulate fast-growth rates of V. cholerae population (>4 doublings per day), allowing them to overcome the grazing pressure exerted by heterotrophic nanoflagellates [56,57]. A rapid and explosive increase in V. cholerae abundance has also been reported in relation to the atmospheric deposition of nutrient-rich dust from the Saharan desert in surface waters of the subtropical Atlantic Ocean [58]. However, the role of dust-associated iron is controversial and other growth factors have been suggested as main drivers of Vibrio spp. population dynamics in response to addition of dust leachate [59].

3.1.2. Dormancy

Variations in environmental conditions such as the occurrence of a temperature outside the optimum-growth range, elevated or lowered osmotic concentrations, nutrient limitation, reduced oxygen levels, and high concentration of pollutants such as heavy metals may cause V. cholerae to remain dormant for a long time, i.e., viable but non-culturable status (VBNC) and regain viability once conditions become favorable [60]. The VBNC status may adversely affect cultivability and introduce a bias in forecast models designed from culture-based experiments. V. cholerae in VBNC status has been shown to regain its viability and pathogenicity on ingestion into the human intestine [15].

3.1.3. Pathogenicity

The pathogenicity of V. cholerae is controlled by the synergistic expression of different genes initiated by the transcriptional activator ToxR that leads to the production of a cholera toxin (CT) genetic element called CTX. Pathogenic strains of V. cholerae are evolved from environmental forms that have the ability to colonize intestines. The major virulence genes of V. cholerae are reported to be acquired from a lysogenic bacteriophage (CTXφ). Under favorable environmental conditions, other phages may cooperate with the CTXφ in a horizontal transfer of genes in V. cholerae including acquiring virulence genes from other organisms [61,62]. Coastal waters can be particularly favorable for horizontal gene transfer as divalent cations such as Ca2+ and Mg2+ present in saline waters, and metals such as vanadium, cadmium, and nickel (often found as pollutants in coastal systems), could improve the competency of bacterial cells and exert selective pressure promoting horizontal gene transfer [63].

3.1.4. Mortality

Predation by lytic phages [64], heterotrophic nanoflagellates, protozoans, rotifers, and cladocerans [14], and changes in hydrological and chemical conditions (e.g., availability of nutrients, viable temperature, and salinity conditions), are the main factors controlling the mortality of V. cholerae in the aquatic environment. V. cholerae has developed several mechanisms to survive predation and reduce pressure of hydrological stressors. Biofilm formation and morphological shift may provide physical protection to grazing by protozoans. The environmental amoeba, Acanthamoeba castellanii, has been reported to ingest and promote the growth of V. cholerae in the cytoplasm of their trophozoites and cysts [65]. Such ingestion may protect V. cholerae from other environmental stressors and grazing pressure. Furthermore, culture experiments [66] and epidemiological studies in coastal waters [67] suggest that control of V. cholerae populations may be more influenced by phage predation than by nutrient limitation. Vibriophages have also been shown to significantly influence the seasonal dynamics of cholera epidemics [61]. For instance, positive relationships have been reported between cholera incidence and the prevalence of lytic phages in the environment during the weeks preceding an outbreak in sewage waters in Lima, Peru [68], and in coastal waters of Dhaka, Bangladesh [69].

3.2. Environmental Reservoirs and Dissemination of V. cholerae

Sediment, as well as benthic and pelagic organisms, can form reservoirs of V. cholerae [15,49]. Some examples include the association of V. cholerae with aquatic plants [70], arthropods and chironomid egg masses [71,72], shellfish [23], waterfowl [73], fish [74,75], and planktonic and benthic organisms containing chitin, such as diatoms [76], bivalves, copepods, cladocerans, and other crustaceans [77], and aquatic sediments (e.g., [49,78]). The presence and abundance of V. cholerae in one reservoir may reflect a specific survival strategy of the bacteria in the environment through the attachment to organic matter, sediment particles, debris, or biofilms. However, it remains unclear whether V. cholerae generally predominate in one environmental reservoir over another.

3.2.1. Host–Pathogen Interactions

Attachment of V. cholerae to living or non-living hosts is mediated by their pili via three sets of differentially regulated genes, which also control the degradation of chitin ([79]; please see Section 3.3). Temperature, salinity, and pH have been shown to influence attachment rates of V. cholerae to planktonic crustaceans such as copepods by activating the expression of the Mannose-sensitive haemagglutinin (MSHA) pilus receptor and the outer membrane colonization (protein) factor GbpA [15,80]. In addition, several studies have confirmed the role of chemotaxis in chitin and the production of multiple chitinases in zooplankton–V. cholerae interactions [79,81,82,83].
The metabolic interactions of V. cholerae with host organisms in the marine ecosystems are diverse and may occur anywhere in a continuum between parasitism and mutualism. In many cases, the host organisms provide space and nutrients for the growth of the bacteria [15]. An example is with the dissolved organic matter secreted by phytoplankton, which has been shown to support the growth of V. cholerae [84]. In return, the bacteria may provide CO2, nitrogen, phosphorus, sulfur, and trace elements to the phytoplankton.

3.2.2. Aerial-Dissemination Modes

Free-living V. cholerae can attach to the surface of windblown sand and dust particles from large desert areas, and to the eggs of flies that settled on hard substrates in the surface water and on the emergent adult flies [85]. Flying chironomids carrying large numbers of V. cholerae may be uplifted by winds into the troposphere and transport pathogens over long distances and time [85], possibly causing the occurrence of cholera outbreaks in geographically distant localities in India, Africa, and Yemen [71,72,86].
Aquatic birds, especially migratory ones, play a significant role in the transportation of V. cholerae via two main routes. In the first route, birds may eat contaminated fish or other contaminated organisms in one pond and shed the pathogens in another area, as demonstrated by the presence of pathogenic V. cholerae in intestinal and fecal samples of aquatic birds [73,87,88,89]. In the second route, chironomids and copepods, which are known to be reservoirs of V. cholerae, attach externally to the feather and feet of birds and facilitate the transport of pathogens [73].

3.2.3. Aquatic-Dissemination Modes

Aquatic plants such as water hyacinth can serve as a dissemination vector of V. cholerae. The pathogenic bacteria may concentrate in the plant roots [90,91], which may then be transported by tidal currents across the estuaries from the river mouth to the open sea where the plants may decay due to increased salinity, while the pathogens may survive as they can tolerate moderate salinity and temperature.
Ballast and other non-potable waters from cargo ships are well-established long-distance dispersal mechanisms for human pathogens and waterborne diseases, including cholera. In the early 1990s, an Asian strain of V. cholerae transported through ballast water was found to be responsible for a cholera outbreak in Peru [92]. In around the same time period, a Latin American strain of V. cholerae was reported in the ballast water of several ships arriving in the Gulf of Mexico, leading U.S. coast guards to issue an advisory requesting that ballast waters be exchanged in open seas before entry of ships in the U.S. port [20,93]. More recent studies reported the presence of V. cholerae in the ballast tanks of ships docked in the ports of Brazil [94] and Singapore [95].
Tiny plastic beads, or “nurdles”, found on beaches and in rivers and seas around the world, could form a novel means of dispersal for potentially pathogenic Vibrio spp., including V. cholerae. In coastal and estuarine waters of the North Sea where V. cholerae occurrences have been reported [96], up to 75% of nurdles found on bathing beaches were contaminated with Vibrio spp. [97]. The hard surface of plastic debris provides an ideal environment for the formation of biofilm to which Vibrio bacteria can bind effectively [98]. Furthermore, the slow degradation of synthetic polymers, in comparison to naturally occurring polymers like chitin, may allow transportation and persistence of V. cholerae across coastal and marine environments and act as long-distances transportation vectors.

3.3. Role of Vibrio cholerae in Biogeochemical Cycling

The bacteria V. cholerae are largely discussed as pathogens affecting humans and aquatic organisms. However, being a dominant bacterium in the marine environment, they also play important roles in the pelagic and benthic biogeochemical cycling, especially participation in marine carbon and nutrients cycles [1]. When colonizing particulate matter, Vibrio bacteria secrete an array of hydrolytic enzymes to convert high-molecular-weight polymers such as proteins, lipids, carbohydrates, chitin, and laminarin into small-molecular-weight compounds that can be taken up by other pelagic and benthic microorganisms and incorporated into the microbial loop [27].
One of the most abundant carbon sources in the marine environment is chitin. The annual release of chitin associated with the death of chitin-producing organisms may be more than 2.3 million metric tons per year in the whole marine biocycle [99]. The high-molecular-weight chitin polymers are not available to the food web until they are mineralized into low-molecular-weight GlcNac monomers through the action of chitinase enzymes produced by heterotrophic bacteria including V. cholerae [1,79,81]. Chitin degradation is initiated with the adherence of the bacteria to the surface of the particulate matter or organisms with the aid of MSHA pilus [76]. Subsequently, the chitin is degraded in a step-wise process into N-acetyl glucosamine by the concerted action of chitinase and β-N-acetylglucosaminidase [83].

3.4. Climatological Conditions

In coastal and lacustrine regions, the predominant climate-related drivers affecting the distribution of V. cholerae and disease transmission rates include water temperature, precipitation, freshwater runoff, drought, sea-level rise, flooding, and storm surge, which in turn influence salinity, turbidity, and plankton abundance and composition [100,101]. Changes in climate forcing and environmental conditions may affect the distribution of V. cholerae and disease transmission rates at different timescales (short-term, seasonal, inter-annual, and long-term variations) and over different geographic areas (local, regional, and global). For instance, in Bangladesh, the timing of the monsoon has been shown to influence the seasonal dynamics in V. cholerae pathogens, resulting in disease transmission rates remaining low during the summer rains and dry winter, and peaking in spring and autumn [102].
Large-scale patterns of climate variability such as the El Niño Southern Oscillation (ENSO) can alter local and regional temperature and precipitation conditions, which might favor V. cholerae growth and increase cholera outbreaks (e.g., [103,104,105,106,107]). For instance, in Bangladesh, short-term variation in cholera transmission rates showed a significant 8–10 month lagged correlation with the global climate index Niño3.4 [102]. In regions under the influence of the monsoon such as in Indian and Bangladesh, positive feedback is observed between an anomalous SST warming in the tropical Pacific following winter El Niño events and the changes in summer monsoon atmospheric circulation that result in enhanced precipitation and river discharge, which may lead to a rise in cholera outbreaks [108,109]. Recently, changes in precipitation patterns associated with El Niño perturbations have also been shown to impact disease transmission rates in Africa [106]. In addition, through the long-range effects of coupled-ocean-atmosphere teleconnections, El Niño has been suggested as a possible “long-distance corridor” for the oceanic transmission of pathogenic strains of V. cholerae between Asia and the Americas [110].
Over long timescales and large geographic areas, the potential impact of climate change on the distribution of cholera has been estimated based on the relationship between V. cholerae abundance and the environmental variables of temperature and salinity [54]. Under a moderate climate change scenario, the majority of the coastal areas currently less suitable for V. cholerae may become more suitable, including latitudinal expansion in V. cholerae range from low to medium and high latitudes and an increment of suitable conditions in open waters. The tight relationship between temperature and V. cholerae growth has also been used to forecast the increase and new incidence of pathogenic strains in temperate regions of Northern Europe under the regional warming trend [51,111]. Climate-change-driven sea level rise and changes in precipitation may increase surface extent of water-submerged areas and decrease salinity in coastal regions, which may enhance seasonal and geographical availability of habitat suitable for V. cholerae. Ocean acidification associated with increasing CO2 emissions may reduce attachment rates of V. cholerae to zooplankton hosts [80,112]. However, more research is needed in this area as high CO2 levels have also been shown to enhance the diversity of the particle-attached bacterial community [113], influence the dynamic and diversity of plankton community, and in some instances, has been shown to reduce development of mesozooplankton species including copepods and to alter trophic interactions [114], which in turn could also affect growth and distribution of bacteria such as V. cholerae.

4. Surveillance and Forecast of Aquatic Reservoirs of Vibrio and Cholera Disease Outbreaks: Existing Approaches and Development Opportunities

An increasing number of human health and epidemiological studies are using a combination of in-situ and remote-sensing data for monitoring, surveillance, forecast, and risk mapping of pathogen occurrence and disease outbreaks (e.g., [7,115,116,117]). Although microbial pathogens cannot be sensed directly by satellite sensors, the remotely-sensed data can be used to infer their presence. To date, the majority of modeling approaches are based on empirical relationships between pathogen presence/absence or abundance or disease incidence, and a series of bio-physical covariates, such as salinity, sea surface temperature (SST), sea surface height (SSH), pH, dissolved oxygen concentration, Chlorophyll-a concentration, plankton biomass, land cover type, precipitation, and humidity or vapor pressure (e.g., [5,52,116,118,119,120]).

4.1. Predictive Models Developed Using Ocean-Color Remote-Sensing Data

Ocean-color sensors measure water-leaving reflectance in spectrally contiguous bands in the spectral range of visible wavelengths of the light emerging from the water surface. The remote-sensing reflectance is then used as the basic input to many derived-product algorithms such as inherent optical properties, diffuse attenuation, particulate matter, and chlorophyll-a. The concentration of chlorophyll-a, the primary photosynthetic pigment found in phytoplankton, varies seasonally following the growth and decline of phytoplankton populations. It is the key variable required to estimate primary production (i.e., the rate at which organic carbon is produced by phytoplankton cells), providing unique information on the dynamics of the marine food chain and the biological carbon cycle. Remotely-sensed chlorophyll-a concentration can be retrieved in marine and fresh-waters, allowing us to monitor phytoplankton distribution at high temporal (<1 day) and spatial (<1 km) resolutions from regional to global scales.
To assess the current status of methods and approaches that use ocean-color observations to survey and forecast Vibrio spp. occurrence and/or cholera disease incidence, we conducted a structured literature search using PubMed query tools from January 1950 to August 2019, with the keywords cholera; Vibrio; chlorophyll; ocean-color; satellite; and remote-sensing. Additional articles and reports were searched in reference lists of published articles, and using a Google Scholar query between January 1950 and August 2019. The latter query returned 2460 results. The titles and abstracts of the top 10% of the results sorted by relevance were screened. Combining the results from all searches, a total of 16 studies were found to include satellite ocean-color data in their analysis and/or to use the data as a covariate in the development of predictive models of Vibrio spp. or cholera dynamics (Table 1).
In summary, based on the structured literature search, studies that were found to include ocean-color observations in their analyses have investigated predictive skills of: (a) Chlorophyll-a concentration (either as a single explanatory variable or in combination with other environmental covariates) in relation to cholera cases (12 out of 16 studies, Table 1), (b) V. cholerae habitat suitability (one study, [54]), or (c) V. parahaemolyticus density in oysters (two studies, [121,129]). Covariates investigated in addition to chlorophyll-a, included remotely-sensed observations of SST, SSH, precipitation, and field measurements of salinity, pH, bottom temperature, phyto- and zoo-plankton biomass, river discharge, climate indices, and socioeconomic status. Furthermore, one study developed a satellite water marker (SWM) model that relates coastal water conditions to seasonal cholera incidence [123]. More details about the methodology, geographical coverage, and predictive skill of the different models reported in Table 1 are presented in Section 4.1.1, Section 4.1.2, Section 4.1.3 and Section 4.1.4.

4.1.1. Ocean-Color and Cholera Cases

In coastal regions, such as the Bay of Bengal in Bangladesh and India (Colwell and Calkins, unpub. data; [6,17,44,116,123,124,126]), Mozambique Channel [6,123], Zhejiang province in China [47,122], KwaZulu-Natal province in South Africa [128], and in the inland Lake Kivu region in the Democratic Republic of the Congo [119,125], chlorophyll-a was found to be a significant explanatory variable, with best results often obtained using time-lag correlation between one and six months. Contrasting results were found in the coastal region of Hue, Vietnam, where chlorophyll-a was not significantly associated with the probability of cholera outbreak. However, this latter finding may be related to infrequent cholera epidemics and lull in cholera cases between outbreaks in the region during the study period 1997–2003.
In the coastal regions of the Bay of Bengal and the Mozambique Channel, an SWM model depicting coastal water conditions, suitable for V. cholerae bacteria, was utilized, based on the variability of the difference between remote-sensing reflectance in the blue (412 nm) and green (555 nm) wavelengths, which can be related to seasonal incidence of cholera [123]. The SWM index is bounded between physically separable wavelengths for relatively clear (blue) and turbid (green) water. Using the SWM model, prediction of cholera with reasonable accuracy at least two months in advance can potentially be achieved in endemic coastal regions in spring in Bangladesh and in winter in Mozambique, respectively [123]. Comparative analysis, reported by [123], showed higher predictive ability for SWM (predicted r2 = 78% and 57%) than chlorophyll-a (predicted r2 = 58% and 23%) in Bangladesh and Mozambique regions respectively. These results suggest that SWM captures biological properties in coastal waters that may not be represented in chlorophyll algorithms. The correlation between detrended anomalies of October–November–December Chlorophyll-a and a positive SWM index, indicative of suitable habitat for V. cholerae is shown in Figure 2c for the period 1997–2017. High positive correlations are observed in coastal regions where the water conditions are more turbid and associated with changes in phytoplankton chlorophyll-a.

4.1.2. Ocean-Color and V. cholerae Habitat Distribution

The prediction of most suitable areas for potential V. cholerae distribution has been investigated in oceanic and coastal regions across the world on the basis of a mathematical representation of their known distribution in environmental space, or so-called realized ecological niche. This approach, referred to as ecological niche modeling, has been used to assess the influence of 12 environmental covariates, including SST, salinity, pH, dissolved oxygen, nutrient concentrations, photosynthetically available radiation, and chlorophyll-a concentration [54]. The results indicate that chlorophyll-a, pH, SST, and salinity could explain most of the variability, with chlorophyll-a having the highest predictive power (49% relative contribution). These findings are consistent with the key environmental factors identified to trigger cholera outbreaks in studies based on empirical relationships between environmental covariates and cholera incidence (e.g., [6,17,44,116]). In the northern Indian Ocean, contemporary distribution of suitable areas for V. cholerae predicted by the ecological niche model [54] is in general agreement with the location of maximum risk of cholera incidence predicted by the SWM model [123], although differences can be seen, especially in coastal regions (Figure 2).

4.1.3. Ocean-Color and V. parahaemolyticus in Oysters

Predictive models of V. parahaemolyticus in oysters showed inconstant findings, with a study of British Columbia oysters reporting no association with remote-sensing chlorophyll-a [121], whereas a study of Alabama oysters showed significant relationship with remote-sensing chlorophyll-a after correcting for the effects of temperature and salinity [129].

4.1.4. Local and Regional Specificity

Inconsistent findings regarding the influence of ocean-color and other environmental covariates on Vibrio bacteria abundance or cholera cases may be due to differences in spatial (e.g., study area extent, grid size) and temporal (e.g., weekly, monthly, or annual observations, length of data records) data resolution and coverage, differences in the ecological systems (e.g., freshwater, coastal or open ocean waters), differences in the socio-economic context (e.g., sanitation and access to drinking water, raw sea-food consumption), and differences in the disease epidemiological patterns (uni- or bi-annual peaks, outbreaks of primary and secondary cases). Overall, outbreaks of primary cases, resulting from environment-to-human transmission, will be influenced by regional-scale environmental factors, whereas secondary cases, consisting of human-to-human transmission, will primarily depend on local-scale socio-economic factors. Furthermore, outbreaks in coastal systems may have different dominant drivers than in inland systems because they are not only affected by climatic and geographic conditions, but also by oceanic conditions. For instance, cholera incidence data from the coastal Mathbaria region of Bangladesh show endemic patterns with a single peak in the spring while further inland, in other districts of the Ganges-Brahmaputra-Meghna basin (Dhaka, Matlab, Bakerganj, and Kolkata) bi-annual peaks pattern is observed with outbreaks in the spring and post-monsoon in the fall [6,43,44,131,132]. In most affected areas of coastal Mozambique, infection patterns are characterized by a single annual peak in the spring [6]. On the other hand, in landlocked regions such as the East African lake region, intra-annual patterns of cholera vary according to the location, and peaks are generally observed during post-flood situations or after extreme precipitation events [119,125].

4.2. Surveillance and Forecast of V. cholerae Reservoirs and Cholera Disease Outbreaks: Development Opportunities from Ocean-Color Remote-Sensing

4.2.1. Sensor-Related Developments

Over the past three decades, national and international space agencies such as the US National Aeronautics and Space Administration (NASA), European Space Agency (ESA), the European Organisation for the Exploitation of Meteorological Satellites (EUMETSAT), The China National Space Administration and State of (CNSA), the Indian Space Research Organisation (ISRO), the Japan Aerospace Exploration Agency (JAXA), the Korean Space Agency, and the French National Centre for Space Studies (CNES) have deployed and operated a range of ocean-color sensors dedicated to measure water-leaving radiance in the visible part of the spectrum [133]. A review of the current status and future perspective of ocean-color observations presented in [134] shows that the sensors deployed have different swath width, spectral coverage, number of wavelength bands (8 to 21), spatial resolution (~300 m to 4 km), temporal frequency (from <1 h to ~4 days), orbit (polar or geostationary), and operate over different time spans (from few months to > decade). The range of characteristics of these sensors are bound by technological and scientific advances, and have been developed to meet user requirements for different applications. For instance, sensors with: high-spatial resolution (~300 m) are particularly suited to study sub-mesoscale processes; high-temporal frequency (<1 day) allows us to study diurnal processes; large number of wavebands permits development of retrieval algorithms for various water constituents and their refinement in complex coastal waters. For the purpose of climate studies, the Global Climate Observing System (GCOS) has identified the requirements for the essential climate variables of remote-sensing reflectance and chlorophyll-a, in terms of data frequency (daily and weekly), spatial resolution (4 km), uncertainty (5% and 30% respectively), and stability (0.5% and 3% respectively) [134]. However, the differences in sensor characteristics make the process of sensor calibration inter-comparison and validation particularly challenging. To address these issues, the ESA Ocean-Colour Climate Change Initiative (OC-CCI) program was launched in 2011, to develop and validate algorithms to meet requirements for consistent, stable, error-characterized merged ocean-color data from multi-sensor archives, including SeaWiFS, Aqua-MODIS, MERIS, and VIIRS. The merged products provide the longest continuous record (more than two decades) of ocean-color observations with global coverage at 1 to 4 km and daily resolution [130].
In addition to the OC-CCI data archive, observations at high-spatial resolution (~300 m) are becoming increasingly available, with the launch since 2016 of a series of Sentinel missions with sensors dedicated to measure ocean color, SST, and surface topography variables (please see review about relevance and applications of other remote-sensing data in Section 5). Ocean-color sensors onboard the Sentinel-3 missions are presently used and validated to retrieve data on phytoplankton and other water constituents, and are currently being evaluated for their incorporation into the OC-CCI time series [130]. Sentinel-3 Ocean and Land Colour Instrument (OLCI), which is operated by EUMETSAT, provide significant improvements when compared to previous ocean-color sensors, including an increase in the number of spectral bands (from 15 in MERIS to 21 in OLCI), sun-glint mitigation, improved coverage of the global ocean (<2 days with two satellites in constellation, where MERIS is ~15 days), complete overlap with other sensors such as the Sea and Land Surface Temperature Radiometer (SLSTR), which allows us to analyze ocean-color and SST observations in synergy [135]. As part of the space component of the Copernicus program, Sentinel-3 has moved ocean color into the operational domain for the coming decade, with two platforms currently in orbit (Sentinel-3A and Sentinel-3B) and at least two further planned (3C and 3D). Furthermore, data archives of land-designed sensors such as Landsat-8 and Sentinel-2 have also been explored to develop algorithms to retrieve information on phytoplankton and particulate matter. The land sensors have the advantage to provide data at very-high spatial resolution (~30 m), which is most relevant for investigating the dynamics of water constituent at local scale, such as in coastal areas and lakes.
Other remote-sensing platforms, which can carry small-size and lightweight sensors that can measure water-leaving radiance a few meters above the water, include airplanes and unmanned aerial vehicles (UAV) such as balloons or drones [136]. The advantages of these platforms over satellites are further improvement in spatial resolution and the potential to avoid disturbances of the optical signal due to cloud coverage. Furthermore, hyperspectral technology developments have resulted in UAV-compatible smaller and lighter sensors, which are characterized by narrow contiguous spectral bands over a continuous spectral range. Hyperspectral measurements in the spectral range of visible wavelengths are being investigated to produce novel retrieval algorithms for water constituents such as Chlorophyll-a, turbidity, and total suspended solids, providing new perspective for water quality monitoring in shallow coastal and inland waters [137,138].
To date, a limited number of studies (~16) have reported using ocean-color remote sensing to develop applications related to Vibrio bacteria habitat suitability and/or cholera disease incidence (Table 1). The data sources, types, spatio-temporal resolution, and the predictive models used, as well as their applications varied from region to region, and were shown to depend on the epidemiological data (e.g., weekly to annual report of bacteria abundance or cholera cases at local, district, or state level). To produce comprehensive recommendation of the requirements for ocean-color remote-sensing data in the context of the Vibrio pathogen or cholera applications will require user-engagement review amongst research communities, such as epidemiologists, clinicians, modelers, remote sensing, climate, and social researchers, as well as consultation of stakeholders and end-users, including coastal or lake-shore populations, fishermen, boat-tourism industry workers, port officers, environmental regulators, NGOs, decision-makers, and health service officials. This is would be very useful to do in the future, however is beyond the scope of the present paper.

4.2.2. Applications-Related Development

Since the launch of the Coastal Zone Color Scanner (CZCS) by NASA in 1978, ocean-color products have continuously been developed and validated, and transited to scientific applications such as in research on the carbon and nitrogen cycles, biogenic trace gases, and in operational mode for fisheries management, harvesting, aquaculture, water quality assessment, harmful algal blooms (HABs) detection, tracking, and prediction. Some of the products developed for these applications may also be relevant to study the geographic distribution and temporal dynamics of the aquatic reservoirs of V. cholerae and help us to better characterize the ecological and biogeochemical signatures of the bacteria.
Based on the environmental interactions of V. cholerae described in Section 3, we have reviewed existing ocean-color products that may be used to monitor and forecast aquatic reservoirs of V. cholerae, and possible transmission routes of the disease (Table 2).

5. Applications of Satellite Remote-Sensing to Cholera Epidemics: Supporting Sustainable Development Goals and Targets

Satellite remote-sensing observations, such as ocean-color, SST, SSH, and precipitation, have supplied mechanistic insights that support the construction of predictive models of both V. cholerae habitat distribution and cholera disease outbreaks. In particular, the studies reviewed in Table 1 have highlighted the importance of including covariates of terrestrial nutrient influx and abundance of planktonic hosts, which are key environmental processes in freshwater and coastal regions of cholera endemic countries. Figure 3 shows possible ocean corridors for cholera outbreaks in coastal tropical regions based on 20 years of ESA OC-CCI ocean-color data.
Ocean-color provides information on phytoplankton abundance and is related to the increased presence of zooplankton. The V. cholerae bacteria may attach themselves to the phyto- and zoo-plankton, and particularly to diatoms and copepods containing chitin, which has been reported as an effective chemotactic attractant and may help in the formation of biofilms (see Section 3.2). The plankton hosts may then provide shelter and protection for the Vibrio bacteria and support its survival, growth, and dissemination in the aquatic environment. SST and salinity are indicative of growth conditions, with the bacteria growing preferentially in warm (>15 ℃), low salinity (<25 ppt NaCl) seawaters [51], as well as the conditions favorable for plankton blooms, which also depend on warm ocean temperatures [171]. SSH relates to human–Vibrio contact through tidal intrusion of coastal waters carrying plankton laden with Vibrio in inland river systems. Finally, precipitation is also important driver, indicative of intense rainfall events associated with increased river flows, which can minimize tidal intrusion of contaminated coastal waters into inland waters. Incorporating this cartographic information in epidemiological models generates new knowledge of the dynamic of cholera epidemics, with the potential to improve our capability to forecast outbreaks in affected countries, and in turn, reduces risks of waterborne diseases for human health.
To assess the potential of satellite applications to support the achievement of Sustainable Development Goals, we have reviewed the knowledge gaps and research priorities on water-borne diseases which have been identified in the 10 year synthesis report ‘Global Goals Mapping: the Environment Human Landscape’ [173]. We found that applications of satellite remote-sensing to cholera epidemics may help to address some of the knowledge gaps for SDG targets on 3-Health, 6-Water quality, 13-Climate, and 14-Life under the water. We have mapped, for each relevant SDG target, the research priorities on water-borne diseases that can be advanced using remote-sensing. We indicate how these possible advancements might transit to societal benefits, and list SDG indicators that might be used to evaluate impact (Table 3).
The potential of remote sensing to provide support to the implementation of SDGs may be achieved only if technology transfer is effectively carried out to affected nations. Based on an analysis of situations in the Bengal Delta Region (Bangladesh) and in the Vembanad Lake region in Kerala state in India, [120] have provided recommendations on how to transfer and make best use of remote-sensing technology to build resilience against water-borne disease outbreaks. Primary factors to achieve these include education of all social classes, as well as credibility and timeliness of scientific advice provided as preventive measures and during emergencies. In addition, the engagement of citizens in the collection of scientific observations—related to social (e.g., sanitation, access to drinking water, infrastructure damage during floods) and environmental (e.g., water temperature, color, clarity, [174]) conditions can be particularly useful for the development and validation of predictive models of Vibrio bacteria growth and risks of disease outbreaks. Furthermore, the use of smartphone applications to record and disseminate citizen observations has proven to be critical to providing timely updates on risk of outbreaks and/or spread of the disease [175,176].

6. Conclusions

Ocean-color remote sensing observations are increasingly used to map and forecast cholera disease outbreaks and the distribution of V. cholerae environmental reservoirs in fresh, coastal, and open-ocean systems. The ocean-color data have been found to relate to the increase in phytoplankton that can be associated with increase in zooplankton, which forms key environmental reservoirs of V. cholerae, and reflect the intrusion of coastal waters carrying plankton laden with V. cholerae into inland waters. Human infection may then be caused by drinking water and/or consuming seafood contaminated with pathogenic V. cholerae bacteria.
In predictive model of V. cholerae bacteria distribution and primary disease transmission, ocean-color is often reported as a major explanatory variable, and the models are performing best when ocean-color is used in combination with other remotely-sensed variables such as SST, SSH, precipitation, and in-situ measurements, including salinity, pH, bottom temperature, phyto- and zoo-plankton biomass, river discharge, and climate indices. Secondary disease transmission is strongly dependent on access to drinking water and sanitation, and consumption of seafood, which are best reflected by including data on the socio-economic status of the populations.
From the wide range of models that have been developed for cholera outbreaks (Table 1), and for other infectious diseases [7,18], the level of refinement in time and space mapping and forecast of environmental reservoirs and disease occurrence appears to be related principally to: (a) The understanding of the pathogens’ ecology, including its life cycle, interaction with environmental hosts, and transmission routes; (b) the coverage, spatial-temporal resolution, length of time-series data available for mapping, and predictive model developments; and (c) the extent of the mechanistic understanding and previous mapping efforts of disease outbreak dynamics. Refinements of predictive models are anticipated to take place with advancements in satellite sensors, including the availability of multi-decadal merged products, high-resolution and multi-spectral observations, as well as in development of satellite applications, which have the potential transit to societal benefits. These advancements will help to further actions towards sustainable human–environment interactions, for instance, by providing policy information on coastal areas where microbial and antibiotic pollution should be treated as priorities, and on country-level preparation needs of cholera vaccine stockpile [177]. In turn, these water management actions will also help to regulate the threat of waterborne diseases and to meet the needs to reduce the risks of waterborne diseases for human health.

Author Contributions

Conceptualization, M.-F.R., A.A., S.S.; formal analysis, M.-F.R.; investigation, M.-F.R.; data curation, K.M., B.L.; writing—original draft preparation, M.-F.R., M.P., V.V., A.A., S.S., B.L., J.C, K.M., N.M., G.G., T.P.; writing—review and editing, M.-F.R., S.S., A.A., B.L., T.P.; visualization, M.-F.R.; funding acquisition, M.-F.R., S.S., A.A., T.P., G.G., N.M.

Funding

This research was funded by the India–UK water quality research program under the Department of Science and Technology (DST) and the Natural Environment Research Council (NERC) REVIVAL project grant numbers [NE/R003521/1 and DST/TM/INDO-UK/2k17/64(C)]; the DST—Science and Engineering Research Board under Jawaharlal Nehru Science Fellowship (DST-SERB JNSF) to Trevor Platt, held at the Central Marine Fisheries Research Institute; and the United Kingdom Research and Innovation (UKRI) Towards a Sustainable Earth (TaSE) program under the Japan Science and Technology Agency (JST), the India Department for Biotechnology (DBT) and the NERC project PODCAST grant numbers [NE/S012567/1 and BT/IN/TaSE/71/AA/2018-19].

Acknowledgments

The financial support from DST Government of India and NERC under Indo–UK water call program; and from JST-Japan, DBT-India and UKRI NERC under Towards a Sustainable Earth (TaSE) Japan–India–UK program are acknowledged. The authors are thankful to the directors of CSIR-National Institute of Oceanography and ICAR-Central Marine Fisheries Research Institute for the support and encouragement to complete the work. This work is a contribution to the UKRI-NERC Pathways Of Dispersal for Cholera And Solution Tools (PODCAST) project, the NERC rehabilitation of Vibrio Infested waters of Vembanad Lake: pollution and solution (REVIVAL) project, the NERC National Centre for Earth Observation (NCEO), the European Space Agency Ocean Color Climate Change Initiative (ESA OC-CCI), and to the GEO Blue Planet Water-associated Diseases Working Group supported by a grant from the Partnership for Observation of the Global Ocean (POGO). The authors thank the ESA OC-CCI team for providing chlorophyll data and the World Health Organization (WHO) for providing cholera cases data. The authors further acknowledge Jon White (PML) for technical support with Adobe Reader for Figure 1.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Zhang, X.; Lin, H.; Wang, X.; Austin, B. Significance of Vibrio species in the marine organic carbon cycle—A review. Sci. China Earth Sci. 2018, 61, 1357–1368. [Google Scholar] [CrossRef]
  2. Huq, A.; Haley, B.J.; Taviani, E.; Chen, A.; Hasan, N.A.; Colwell, R.R. Detection, isolation, and identification of Vibrio cholerae from the environment. Curr. Protoc. Microbiol. 2012, 26, 6A-5. [Google Scholar] [CrossRef] [PubMed]
  3. Chapman, C.; Henry, M.; Bishop-Lilly, K.A.; Awosika, J.; Briska, A.; Ptashkin, R.N.; Wagner, T.; Rajanna, C.; Tsang, H.; Johnson, S.L.; et al. Scanning the Landscape of Genome Architecture of Non-O1 and Non-O139 Vibrio cholerae by Whole Genome Mapping Reveals Extensive Population Genetic Diversity. PLoS ONE 2015, 10, e0120311. [Google Scholar] [CrossRef] [PubMed]
  4. World Health Organisation; United Nations Children’s Fund. Wash in the 2030 Agenda: New Global Indicators for Drinking Water, Sanitation and Hygeine; World Health Organisation: Geneva, Switzerland, 2017; p. 8. [Google Scholar]
  5. Colwell, R.R. Global Climate and Infectious Disease: The Cholera Paradigm*. Science 1996, 274, 2025–2031. [Google Scholar] [CrossRef]
  6. Jutla, A.S.; Akanda, A.S.; Islam, S. Tracking Cholera in Coastal Regions Using Satellite Observations. JAWRA J. Am. Water Resour. Assoc. 2010, 46, 651–662. [Google Scholar] [CrossRef]
  7. Hay, S.I.; Battle, K.E.; Pigott, D.M.; Smith, D.L.; Moyes, C.L.; Bhatt, S.; Brownstein, J.S.; Collier, N.; Myers, M.F.; George, D.B.; et al. Global mapping of infectious disease. Philos. Trans. R. Soc. B Biol. Sci. 2013, 368, 20120250. [Google Scholar] [CrossRef]
  8. Andries, A.; Morse, S.; Murphy, R.; Lynch, J.; Woolliams, E.; Fonweban, J. Translation of Earth observation data into sustainable development indicators: An analytical framework. Sustain. Dev. 2019, 27, 366–376. [Google Scholar] [CrossRef]
  9. Andries, A.; Morse, S.; Murphy, R.J.; Lynch, J.; Woolliams, E.R. Seeing Sustainability from Space: Using Earth Observation Data to Populate the UN Sustainable Development Goal Indicators. Sustainability 2019, 11, 5062. [Google Scholar] [CrossRef]
  10. Nilsson, M.; Griggs, D.; Visbeck, M. Policy: Map the interactions between Sustainable Development Goals. Nat. News 2016, 534, 320. [Google Scholar] [CrossRef]
  11. Kitaoka, M.; Miyata, S.T.; Unterweger, D.; Pukatzki, S. Antibiotic resistance mechanisms of Vibrio cholerae. J. Med. Microbiol. 2011, 60, 397–407. [Google Scholar] [CrossRef]
  12. Almagro-Moreno, S.; Pruss, K.; Taylor, R.K. Intestinal Colonization Dynamics of Vibrio cholerae. PLoS Pathog. 2015, 11, e1004787. [Google Scholar] [CrossRef] [PubMed]
  13. Childers, B.M.; Klose, K.E. Regulation of virulence in Vibrio cholerae: The ToxR regulon. Future Med. 2007, 2, 335–344. [Google Scholar]
  14. Cottingham, K.L.; Chiavelli, D.A.; Taylor, R.K. Environmental microbe and human pathogen: The ecology and microbiology of Vibrio cholerae. Front. Ecol. Environ. 2003, 1, 80–86. [Google Scholar] [CrossRef]
  15. Lutz, C.; Erken, M.; Noorian, P.; Sun, S.; McDougald, D. Environmental reservoirs and mechanisms of persistence of Vibrio cholerae. Front. Microbiol. 2013, 4, 375. [Google Scholar] [CrossRef] [PubMed]
  16. Grimes, D.J.; Ford, T.E.; Colwell, R.R.; Baker-Austin, C.; Martinez-Urtaza, J.; Subramaniam, A.; Capone, D.G. Viewing Marine Bacteria, Their Activity and Response to Environmental Drivers from Orbit: Satellite Remote Sensing of Bacteria. Microb. Ecol. 2014, 67, 489–500. [Google Scholar] [CrossRef]
  17. Jutla, A.S.; Akanda, A.S.; Islam, S. A framework for predicting endemic cholera using satellite derived environmental determinants. Environ. Model. Softw. 2013, 47, 148–158. [Google Scholar] [CrossRef]
  18. Semenza, J.C.; Trinanes, J.; Lohr, W.; Sudre, B.; Löfdahl, M.; Martinez-Urtaza, J.; Nichols, G.L.; Rocklöv, J. Environmental Suitability of Vibrio Infections in a Warming Climate: An Early Warning System. Environ. Health Perspect. 2017, 125, 107004. [Google Scholar] [CrossRef]
  19. Colwell, R.; Huq, A. Marine ecosystems and cholera. Hydrobiologia 2001, 460, 141–145. [Google Scholar] [CrossRef]
  20. Lipp, E.K.; Rose, J.B. The role of seafood in foodborne diseases in the United States of America. Rev. Sci. Tech. Off. Int. Epizoot. 1997, 16, 620–640. [Google Scholar] [CrossRef]
  21. Feldhusen, F. The role of seafood in bacterialfoodborne diseases. Microbes Infect. 2000, 2, 1651–1660. [Google Scholar] [CrossRef]
  22. Iwamoto, M.; Ayers, T.; Mahon, B.E.; Swerdlow, D.L. Epidemiology of Seafood-Associated Infections in the United States. Clin. Microbiol. Rev. 2010, 23, 399–411. [Google Scholar] [CrossRef] [PubMed]
  23. Barange, M. Impacts of Climate Change on Fisheries and Aquaculture: Synthesis of Current Knowledge, Adaptation and Mitigation Options; Food and Agriculture Organization: Rome, Italy, 2018. [Google Scholar]
  24. Mutreja, A.; Kim, D.W.; Thomson, N.R.; Connor, T.R.; Lee, J.H.; Kariuki, S.; Croucher, N.J.; Choi, S.Y.; Harris, S.R.; Lebens, M.; et al. Evidence for several waves of global transmission in the seventh cholera pandemic. Nature 2011, 477, 462–465. [Google Scholar] [CrossRef] [PubMed]
  25. Domman, D.; Quilici, M.L.; Dorman, M.J.; Njamkepo, E.; Mutreja, A.; Mather, A.E.; Delgado, G.; Morales-Espinosa, R.; Grimont, P.A.; Lizárraga-Partida, M.L. Integrated view of Vibrio cholerae in the Americas. Science 2017, 358, 789–793. [Google Scholar] [CrossRef] [PubMed]
  26. Ramamurthy, T.; Mutreja, A.; Weill, F.X.; Das, B.; Ghosh, A.; Nair, G.B. Revisiting the Global Epidemiology of Cholera in Conjunction with the Genomics of Vibrio cholerae. Front. Public Health 2019, 7, 203. [Google Scholar] [CrossRef] [PubMed]
  27. Thompson, J.R.; Polz, M.F. Dynamics of Vibrio Populations and Their Role in Environmental Nutrient Cycling. Biol. Vibrios 2006, 190–203. [Google Scholar] [CrossRef]
  28. Böer, S.I.; Heinemeyer, E.A.; Luden, K.; Erler, R.; Gerdts, G.; Janssen, F.; Brennholt, N. Temporal and Spatial Distribution Patterns of Potentially Pathogenic Vibrio spp. at Recreational Beaches of the German North Sea. Microb. Ecol. 2013, 65, 1052–1067. [Google Scholar] [CrossRef]
  29. Bresnan, E.; Baker-Austin, C.; Campos, C.J.A.; Davidson, K.; Edwards, M.; Hall, A.; Lees, D.; McKinney, A.; Milligan, S.; Silke, J. Human health. MCCIP Sci. Rev. 2017, 2017, 100–107. [Google Scholar]
  30. Schwartz, K.; Hammerl, J.A.; Göllner, C.; Strauch, E. Environmental and Clinical Strains of Vibrio cholerae Non-O1, Non-O139 From Germany Possess Similar Virulence Gene Profiles. Front. Microbiol. 2019, 10, 733. [Google Scholar] [CrossRef]
  31. Binsztein, N.; Costagliola, M.C.; Pichel, M.; Jurquiza, V.; Ramírez, F.C.; Akselman, R.; Vacchino, M.; Huq, A.; Colwell, R. Viable but Nonculturable Vibrio cholerae O1 in the Aquatic Environment of Argentina. Appl. Environ. Microbiol. 2004, 70, 7481–7486. [Google Scholar] [CrossRef]
  32. Martinelli Filho, J.E.; Lopes, R.M.; Rivera, I.N.G.; Colwell, R.R. Vibrio cholerae O1 detection in estuarine and coastal zooplankton. J. Plankton Res. 2011, 33, 51–62. [Google Scholar] [CrossRef]
  33. Azarian, T.; Ali, A.; Johnson, J.A.; Jubair, M.; Cella, E.; Ciccozzi, M.; Nolan, D.J.; Farmerie, W.; Rashid, M.H.; Sinha-Ray, S.; et al. Non-toxigenic environmental Vibrio cholerae O1 strain from Haiti provides evidence of pre-pandemic cholera in Hispaniola. Sci. Rep. 2016, 6, 36115. [Google Scholar] [CrossRef] [PubMed]
  34. Chávez, M.D.; Sedas, V.P.; Borunda, E.O.; Reynoso, F.L. Influence of water temperature and salinity on seasonal occurrences of Vibrio cholerae and enteric bacteria in oyster-producing areas of Veracruz, México. Mar. Pollut. Bull. 2005, 50, 1641–1648. [Google Scholar] [CrossRef] [PubMed]
  35. Lipp, E.K.; Rivera, I.N.G.; Gil, A.I.; Espeland, E.M.; Choopun, N.; Louis, V.R.; Russek-Cohen, E.; Huq, A.; Colwell, R.R. Direct Detection of Vibrio cholerae and ctxA in Peruvian Coastal Water and Plankton by PCR. Appl. Environ. Microbiol. 2003, 69, 3676–3680. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  36. Gil, A.I.; Louis, V.R.; Rivera, I.N.G.; Lipp, E.; Huq, A.; Lanata, C.F.; Taylor, D.N.; Russek-Cohen, E.; Choopun, N.; Sack, R.B.; et al. Occurrence and distribution of Vibrio cholerae in the coastal environment of Peru. Environ. Microbiol. 2004, 6, 699–706. [Google Scholar] [CrossRef]
  37. Graü, C.; Barbera, A.L.; Zerpa, A. Isolation of Vibrio spp. And Evaluation of the Sanitary Condition of Bivalve Mollusks Arca zebra and Perna perna Collected on the Northeastern Coast of Sucre State, Venezuela. Rev. Cient. 2004, 14, 513–521. [Google Scholar]
  38. Louis, V.R.; Russek-Cohen, E.; Choopun, N.; Rivera, I.N.G.; Gangle, B.; Jiang, S.C.; Rubin, A.; Patz, J.A.; Huq, A.; Colwell, R.R. Predictability of Vibrio cholerae in Chesapeake Bay. Appl. Environ. Microbiol. 2003, 69, 2773–2785. [Google Scholar] [CrossRef] [Green Version]
  39. Dobbs, F.C.; Goodrich, A.L.; Thomson, F.K.; Hynes, W. Pandemic Serotypes of Vibrio cholerae Isolated from Ships’ Ballast Tanks and Coastal Waters: Assessment of Antibiotic Resistance and Virulence Genes (tcpA and ctxA). Microb. Ecol. 2013, 65, 969–974. [Google Scholar] [CrossRef]
  40. Kiiru, J.; Mutreja, A.; Mohamed, A.A.; Kimani, R.W.; Mwituria, J.; Sanaya, R.O.; Muyodi, J.; Revathi, G.; Parkhill, J.; Thomson, N.; et al. A Study on the Geophylogeny of Clinical and Environmental Vibrio cholerae in Kenya. PLoS ONE 2013, 8, e74829. [Google Scholar] [CrossRef] [Green Version]
  41. Du Preez, M.; Van der Merwe, M.R.; Cumbana, A.; Le Roux, W. A survey of Vibrio cholerae O1 and O139 in estuarine waters and sediments of Beira, Mozambique. Water SA 2010, 36. [Google Scholar] [CrossRef] [Green Version]
  42. Mukhopadhyay, A.K.; Basu, A.; Garg, P.; Bag, P.K.; Ghosh, A.; Bhattacharya, S.K.; Takeda, Y.; Nair, G.B. Molecular Epidemiology of Reemergent Vibrio cholerae O139 Bengal in India. J. Clin. Microbiol. 1998, 36, 2149–2152. [Google Scholar]
  43. Sack, R.B.; Siddique, A.K.; Longini, I.M., Jr.; Nizam, A.; Yunus, M.; Islam, M.S.; Morris, J.G., Jr.; Ali, A.; Huq, A.; Nair, G.B.; et al. A 4-Year Study of the Epidemiology of Vibrio cholerae in Four Rural Areas of Bangladesh. J. Infect. Dis. 2003, 187, 96–101. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  44. de Magny, G.C.; Murtugudde, R.; Sapiano, M.R.P.; Nizam, A.; Brown, C.W.; Busalacchi, A.J.; Yunus, M.; Nair, G.B.; Gil, A.I.; Lanata, C.F.; et al. Environmental signatures associated with cholera epidemics. Proc. Natl. Acad. Sci. USA 2008, 105, 17676–17681. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  45. Batabyal, P.; Mookerjee, S.; Einsporn, M.H.; Lara, R.J.; Palit, A. Environmental drivers on seasonal abundance of riverine-estuarine V. cholerae in the Indian Sundarban mangrove. Ecol. Indic. 2016, 69, 59–65. [Google Scholar] [CrossRef]
  46. Ali, M.; Gupta, S.S.; Arora, N.; Khasnobis, P.; Venkatesh, S.; Sur, D.; Nair, G.B.; Sack, D.A.; Ganguly, N.K. Identification of burden hotspots and risk factors for cholera in India: An observational study. PLoS ONE 2017, 12, e0183100. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  47. Xu, M.; Cao, C.X.; Wang, D.C.; Kan, B.; Xu, Y.F.; Ni, X.L.; Zhu, Z.C. Environmental factor analysis of cholera in China using remote sensing and geographical information systems. Epidemiol. Infect. 2016, 144, 940–951. [Google Scholar] [CrossRef] [Green Version]
  48. Emch, M.; Feldacker, C.; Islam, M.S.; Ali, M. Seasonality of cholera from 1974 to 2005: A review of global patterns. Int. J. Health Geogr. 2008, 7, 31. [Google Scholar] [CrossRef] [Green Version]
  49. Vezzulli, L.; Pruzzo, C.; Huq, A.; Colwell, R.R. Environmental reservoirs of Vibrio cholerae and their role in cholera: Environmental reservoirs of V. cholerae. Environ. Microbiol. Rep. 2010, 2, 27–33. [Google Scholar] [CrossRef]
  50. Vezzulli, L.; Grande, C.; Reid, P.C.; Hélaouët, P.; Edwards, M.; Höfle, M.G.; Brettar, I.; Colwell, R.R.; Pruzzo, C. Climate influence on Vibrio and associated human diseases during the past half-century in the coastal North Atlantic. Proc. Natl. Acad. Sci. USA 2016, 113, E5062–E5071. [Google Scholar] [CrossRef] [Green Version]
  51. Baker-Austin, C.; Trinanes, J.A.; Taylor, N.G.H.; Hartnell, R.; Siitonen, A.; Martinez-Urtaza, J. Emerging Vibrio risk at high latitudes in response to ocean warming. Nat. Clim. Chang. 2013, 3, 73–77. [Google Scholar] [CrossRef]
  52. Huq, A.; Sack, R.B.; Nizam, A.; Longini, I.M.; Nair, G.B.; Ali, A.; Morris, J.G.; Khan, M.N.H.; Siddique, A.K.; Yunus, M.; et al. Critical Factors Influencing the Occurrence of Vibrio cholerae in the Environment of Bangladesh. Appl. Environ. Microbiol. 2005, 71, 4645–4654. [Google Scholar] [CrossRef] [Green Version]
  53. Takemura, A.F.; Chien, D.M.; Polz, M.F. Associations and dynamics of Vibrionaceae in the environment, from the genus to the population level. Front. Microbiol. 2014, 5, 38. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  54. Escobar, L.E.; Ryan, S.J.; Stewart-Ibarra, A.M.; Finkelstein, J.L.; King, C.A.; Qiao, H.; Polhemus, M.E. A global map of suitability for coastal Vibrio cholerae under current and future climate conditions. Acta Trop. 2015, 149, 202–211. [Google Scholar] [CrossRef]
  55. Kopprio, G.A.; Streitenberger, M.E.; Okuno, K.; Baldini, M.; Biancalana, F.; Fricke, A.; Martínez, A.; Neogi, S.B.; Koch, B.P.; Yamasaki, S.; et al. Biogeochemical and hydrological drivers of the dynamics of Vibrio species in two Patagonian estuaries. Sci. Total Environ. 2017, 579, 646–656. [Google Scholar] [CrossRef] [PubMed]
  56. Beardsley, C.; Pernthaler, J.; Wosniok, W.; Amann, R. Are Readily Culturable Bacteria in Coastal North Sea Waters Suppressed by Selective Grazing Mortality? Appl. Environ. Microbiol. 2003, 69, 2624–2630. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  57. Worden, A.Z.; Seidel, M.; Smriga, S.; Wick, A.; Malfatti, F.; Bartlett, D.; Azam, F. Trophic regulation of Vibrio cholerae in coastal marine waters. Environ. Microbiol. 2006, 8, 21–29. [Google Scholar] [CrossRef]
  58. Westrich, J.R.; Ebling, A.M.; Landing, W.M.; Joyner, J.L.; Kemp, K.M.; Griffin, D.W.; Lipp, E.K. Saharan dust nutrients promote Vibrio bloom formation in marine surface waters. Proc. Natl. Acad. Sci. USA 2016, 113, 5964–5969. [Google Scholar] [CrossRef] [Green Version]
  59. Zhang, R.; Kelly, R.L.; Kauffman, K.M.; Reid, A.K.; Lauderdale, J.M.; Follows, M.J.; John, S.G. Growth of marine Vibrio in oligotrophic environments is not stimulated by the addition of inorganic iron. Earth Planet. Sci. Lett. 2019, 516, 148–155. [Google Scholar] [CrossRef]
  60. Fernández-Delgado, M.; García-Amado, M.A.; Contreras, M.; Incani, R.N.; Chirinos, H.; Rojas, H.; Suárez, P. SURVIVAL, INDUCTION AND RESUSCITATION OF Vibrio cholerae FROM THE VIABLE BUT NON-CULTURABLE STATE IN THE SOUTHERN CARIBBEAN SEA. Rev. Inst. Med. Trop. São Paulo 2015, 57, 21–26. [Google Scholar] [CrossRef]
  61. Faruque, S.M.; Mekalanos, J.J. Phage-bacterial interactions in the evolution of toxigenic Vibrio cholerae. Virulence 2012, 3, 556–565. [Google Scholar] [CrossRef] [Green Version]
  62. Ellison, C.K.; Dalia, T.N.; Vidal Ceballos, A.; Wang, J.C.Y.; Biais, N.; Brun, Y.V.; Dalia, A.B. Retraction of DNA-bound type IV competence pili initiates DNA uptake during natural transformation in Vibrio cholerae. Nat. Microbiol. 2018, 3, 773–780. [Google Scholar] [CrossRef]
  63. Suzuki, S.; Hoa, P.T.P. Distribution of Quinolones, Sulfonamides, Tetracyclines in Aquatic Environment and Antibiotic Resistance in Indochina. Front. Microbiol. 2012, 3, 67. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  64. Wilhelm, S.W.; Suttle, C.A. Viruses and Nutrient Cycles in the SeaViruses play critical roles in the structure and function of aquatic food webs. BioScience 1999, 49, 781–788. [Google Scholar] [CrossRef] [Green Version]
  65. Abd, H.; Saeed, A.; Weintraub, A.; Nair, G.B.; Sandstrom, G. Vibrio cholerae O1 strains are facultative intracellular bacteria, able to survive and multiply symbiotically inside the aquatic free-living amoeba Acanthamoeba castellanii: Vibrio cholerae in amoebae. FEMS Microbiol. Ecol. 2007, 60, 33–39. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  66. Wei, Y.; Perez, L.J.; Ng, W.L.; Semmelhack, M.F.; Bassler, B.L. Mechanism of Vibrio cholerae Autoinducer-1 Biosynthesis. ACS Chem. Biol. 2011, 6, 356–365. [Google Scholar] [CrossRef] [PubMed]
  67. Conner, J.G.; Teschler, J.K.; Jones, C.J.; Yildiz, F.H. Staying alive: Vibrio cholerae’s cycle of environmental survival, transmission, and dissemination. Microbiol. Spectr. 2016, 4. [Google Scholar] [CrossRef] [Green Version]
  68. Madico, G.; Checkley, W.; Gilman, R.H.; Bravo, N.; Cabrera, L.; Calderon, M.; Ceballos, A. Active surveillance for Vibrio cholerae O1 and vibriophages in sewage water as a potential tool to predict cholera outbreaks. J. Clin. Microbiol. 1996, 34, 2968–2972. [Google Scholar]
  69. Jensen, M.A.; Faruque, S.M.; Mekalanos, J.J.; Levin, B.R. Modeling the role of bacteriophage in the control of cholera outbreaks. Proc. Natl. Acad. Sci. USA 2006, 103, 4652–4657. [Google Scholar] [CrossRef] [Green Version]
  70. Hood, M.A.; Winter, P.A. Attachment of Vibrio cholerae under various environmental conditions and to selected substrates. FEMS Microbiol. Ecol. 1997, 22, 215–223. [Google Scholar] [CrossRef]
  71. Paz, S.; Broza, M. Wind Direction and Its Linkage with Vibrio cholerae Dissemination. Environ. Health Perspect. 2007, 115, 195–200. [Google Scholar] [CrossRef] [Green Version]
  72. Paz, S. The cholera epidemic in Yemen—How did it start? The role of El Niño conditions followed by regional winds. Environ. Res. 2019, 176, 108571. [Google Scholar] [CrossRef]
  73. Halpern, M.; Senderovich, Y.; Izhaki, I. Waterfowl—The Missing Link in Epidemic and Pandemic Cholera Dissemination? PLoS Pathog. 2008, 4, e1000173. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  74. Senderovich, Y.; Izhaki, I.; Halpern, M. Fish as Reservoirs and Vectors of Vibrio cholerae. PLoS ONE 2010, 5, e8607. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  75. Halpern, M.; Izhaki, I. Fish as Hosts of Vibrio cholerae. Front. Microbiol. 2017, 8, 282. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  76. Frischkorn, K.R.; Stojanovski, A.; Paranjpye, R. Vibrio parahaemolyticus type IV pili mediate interactions with diatom-derived chitin and point to an unexplored mechanism of environmental persistence. Environ. Microbiol. 2013, 15, 1416–1427. [Google Scholar] [CrossRef] [PubMed]
  77. Weiss, I.M.; Schönitzer, V.; Eichner, N.; Sumper, M. The chitin synthase involved in marine bivalve mollusk shell formation contains a myosin domain. FEBS Lett. 2006, 580, 1846–1852. [Google Scholar] [CrossRef] [Green Version]
  78. Dalusi, L.; Lyimo, T.J.; Lugomela, C.; Hosea, K.M.M.; Sjöling, S. Toxigenic Vibrio cholerae identified in estuaries of Tanzania using PCR techniques. FEMS Microbiol. Lett. 2015, 362, fnv009. [Google Scholar] [CrossRef] [Green Version]
  79. Meibom, K.L.; Li, X.B.; Nielsen, A.T.; Wu, C.Y.; Roseman, S.; Schoolnik, G.K. The Vibrio cholerae chitin utilization program. Proc. Natl. Acad. Sci. USA 2004, 101, 2524–2529. [Google Scholar] [CrossRef] [Green Version]
  80. Huq, A.; West, P.A.; Small, E.B.; Huq, M.I.; Colwell, R.R. Influence of water temperature, salinity, and pH on survival and growth of toxigenic Vibrio cholerae serovar 01 associated with live copepods in laboratory microcosms. Appl. Environ. Microbiol. 1984, 48, 420–424. [Google Scholar]
  81. Colwell, R.R. Polyphasic Taxonomy of the Genus Vibrio: Numerical Taxonomy of Vibrio cholerae, Vibrio parahaemolyticus, and Related Vibrio Species. J. Bacteriol. 1970, 104, 410–433. [Google Scholar]
  82. Li, X.; Wang, L.X.; Wang, X.; Roseman, S. The chitin catabolic cascade in the marine bacterium Vibrio cholerae: Characterization of a unique chitin oligosaccharide deacetylase. Glycobiology 2007, 17, 1377–1387. [Google Scholar] [CrossRef]
  83. Pruzzo, C.; Vezzulli, L.; Colwell, R.R. Global impact of Vibrio cholerae interactions with chitin. Environ. Microbiol. 2008, 10, 1400–1410. [Google Scholar] [CrossRef] [PubMed]
  84. Sison-Mangus, M.P.; Jiang, S.; Kudela, R.M.; Mehic, S. Phytoplankton-Associated Bacterial Community Composition and Succession during Toxic Diatom Bloom and Non-Bloom Events. Front. Microbiol. 2016, 7, 1433. [Google Scholar] [CrossRef] [PubMed]
  85. Broza, M.; Gancz, H.; Halpern, M.; Kashi, Y. Adult non-biting midges: Possible windborne carriers of Vibrio cholerae non-O1 non-O139. Environ. Microbiol. 2005, 7, 576–585. [Google Scholar] [CrossRef] [PubMed]
  86. Broza, M.; Halpern, M. Chironomid egg masses and Vibrio cholerae. Nature 2001, 412, 40. [Google Scholar] [CrossRef] [PubMed]
  87. Ogg, J.E.; Ryder, R.A.; Smith, H.L. Isolation of Vibrio cholerae from aquatic birds in Colorado and Utah. Appl. Environ. Microbiol. 1989, 55, 95–99. [Google Scholar] [PubMed]
  88. Laviad-Shitrit, S.; Lev-Ari, T.; Katzir, G.; Sharaby, Y.; Izhaki, I.; Halpern, M. Great cormorants (Phalacrocorax carbo) as potential vectors for the dispersal of Vibrio cholerae. Sci. Rep. 2017, 7, 7973. [Google Scholar] [CrossRef] [PubMed]
  89. Laviad-Shitrit, S.; Izhaki, I.; Arakawa, E.; Halpern, M. Wild waterfowl as potential vectors of Vibrio cholerae and Aeromonas species. Trop. Med. Int. Health 2018, 23, 758–764. [Google Scholar] [CrossRef]
  90. Spira, W.M.; Huq, A.; Ahmed, Q.S.; Saeed, Y.A. Uptake of Vibrio cholerae Biotype eltor from Contaminated Water by Water Hyacinth (Eichornia crassipes). Appl. Environ. Microbiol. 1981, 42, 550–553. [Google Scholar]
  91. Feikin, D.R.; Tabu, C.W.; Gichuki, J. Does Water Hyacinth on East African Lakes Promote Cholera Outbreaks? Am. J. Trop. Med. Hyg. 2010, 83, 370–373. [Google Scholar] [CrossRef] [Green Version]
  92. Wachsmuth, I.K.; Evins, G.M.; Fields, P.I.; Olsvik, Ø.; Popovic, T.; Bopp, C.A.; Wells, J.G.; Carrillo, C.; Blake, P.A. The Molecular Epidemiology of Cholera in Latin America. J. Infect. Dis. 1993, 167, 621–626. [Google Scholar] [CrossRef]
  93. McCarthy, S.A.; Khambaty, F.M. International dissemination of epidemic Vibrio cholerae by cargo ship ballast and other nonpotable waters. Appl. Environ. Microbiol. 1994, 60, 2597–2601. [Google Scholar] [PubMed]
  94. Rivera, I.N.G.; Souza, K.M.C.; Souza, C.P.; Lopes, R.M. Free-Living and Plankton-Associated Vibrios: Assessment in Ballast Water, Harbor Areas, and Coastal Ecosystems in Brazil. Front. Microbiol. 2013, 3, 443. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  95. Ng, C.; Le, T.H.; Goh, S.G.; Liang, L.; Kim, Y.; Rose, J.B.; Yew-Hoong, K.G. A Comparison of Microbial Water Quality and Diversity for Ballast and Tropical Harbor Waters. PLoS ONE 2015, 10, e0143123. [Google Scholar] [CrossRef] [PubMed]
  96. Kirstein, I.V.; Kirmizi, S.; Wichels, A.; Garin-Fernandez, A.; Erler, R.; Löder, M.; Gerdts, G. Dangerous hitchhikers? Evidence for potentially pathogenic Vibrio spp. on microplastic particles. Mar. Environ. Res. 2016, 120, 1–8. [Google Scholar] [CrossRef] [Green Version]
  97. Rodrigues, A.; Oliver, D.M.; McCarron, A.; Quilliam, R.S. Colonisation of plastic pellets (nurdles) by E. coli at public bathing beaches. Mar. Pollut. Bull. 2019, 139, 376–380. [Google Scholar] [CrossRef] [Green Version]
  98. Yokota, K.; Waterfield, H.; Hastings, C.; Davidson, E.; Kwietniewski, E.; Wells, B. Finding the missing piece of the aquatic plastic pollution puzzle: Interaction between primary producers and microplastics. Limnol. Oceanogr. Lett. 2017, 2, 91–104. [Google Scholar] [CrossRef] [Green Version]
  99. Jeuniaux, C.; Voss-Foucart, M.F. Chitin biomass and production in the marine environment. Biochem. Syst. Ecol. 1991, 19, 347–356. [Google Scholar] [CrossRef] [Green Version]
  100. Trtanj, J.; Jantarasami, L.; Brunkard, J.; Collier, T.; Jacobs, J.; Lipp, E.; McLellan, S.; Moore, S.; Paerl, H.; Ravenscroft, J.; et al. Ch. 6: Climate Impacts on Water-Related Illness. The Impacts of Climate Change on Human Health in the United States: A Scientific Assessment; MFR, U.S. Global Change Research Program: Washington, DC, USA, 2016. [Google Scholar]
  101. Parmesan, C.; Attrill, M. Impacts and effects of ocean warming on human health (disease). In Explaining Ocean Warming: Causes, Scale, Effects and Consequences; Laffoley, D., Baxter, J.M., Eds.; IUCN: Gland, Switzerland, 2016; pp. 439–449. [Google Scholar]
  102. Koelle, K. The impact of climate on the disease dynamics of cholera. Clin. Microbiol. Infect. 2009, 15, 29–31. [Google Scholar] [CrossRef] [Green Version]
  103. Colwell, R.; Patz, J. Climate, Infectious Disease and Health: An Interdisciplinary Perspective; MFR: Washington, DC, USA, 1998. [Google Scholar]
  104. Pascual, M.; Bouma, M.J.; Dobson, A.P. Cholera and climate: Revisiting the quantitative evidence. Microbes Infect. 2002, 4, 237–245. [Google Scholar] [CrossRef]
  105. Pascual, M.; Chaves, L.; Cash, B.; Rodó, X.; Yunus, M. Predicting endemic cholera: The role of climate variability and disease dynamics. Clim. Res. 2008, 36, 131–140. [Google Scholar] [CrossRef]
  106. Moore, J.K.; Fu, W.; Primeau, F.; Britten, G.L.; Lindsay, K.; Long, M.; Doney, S.C.; Mahowald, N.; Hoffman, F.; Randerson, J.T. Sustained climate warming drives declining marine biological productivity. Science 2018, 359, 1139–1143. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  107. Martinez, P.P.; Reiner, R.C.; Cash, B.A.; Rodó, X.; Mondal, M.S.; Roy, M.; Yunus, M.; Faruque, A.S.G.; Huq, S.; King, A.A.; et al. Cholera forecast for Dhaka, Bangladesh, with the 2015–2016 El Niño: Lessons learned. PLoS ONE 2017, 12, e0172355. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  108. Cash, B.A.; Rodó, X.; Kinter, J.L. Links between Tropical Pacific SST and Cholera Incidence in Bangladesh: Role of the Eastern and Central Tropical Pacific. J. Clim. 2008, 21, 4647–4663. [Google Scholar] [CrossRef]
  109. Hashizume, M.; Armstrong, B.; Hajat, S.; Wagatsuma, Y.; Faruque, A.S.G.; Hayashi, T.; Sack, D.A. The Effect of Rainfall on the Incidence of Cholera in Bangladesh. Epidemiology 2008, 19, 103–110. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  110. Martinez-Urtaza, J.; Trinanes, J.; Gonzalez-Escalona, N.; Baker-Austin, C. Is El Niño a long-distance corridor for waterborne disease? Nat. Microbiol. 2016, 1, 16018. [Google Scholar] [CrossRef]
  111. Vezzulli, L.; Brettar, I.; Pezzati, E.; Reid, P.C.; Colwell, R.R.; Höfle, M.G.; Pruzzo, C. Long-term effects of ocean warming on the prokaryotic community: Evidence from the vibrios. ISME J. 2012, 6, 21–30. [Google Scholar] [CrossRef] [Green Version]
  112. Jacobs, J.; Moore, S.K.; Kunkel, K.E.; Sun, L. A framework for examining climate-driven changes to the seasonality and geographical range of coastal pathogens and harmful algae. Clim. Risk Manag. 2015, 8, 16–27. [Google Scholar] [CrossRef] [Green Version]
  113. Sperling, M.; Piontek, J.; Gerdts, G.; Wichels, A.; Schunck, H.; Roy, A.S.; Roche, J.L.; Gilbert, J.; Nissimov, J.I.; Bittner, L.; et al. Effect of elevated CO2 on the dynamics of particle-attached and free-living bacterioplankton communities in an Arctic fjord. Biogeosciences 2013, 10, 181–191. [Google Scholar] [CrossRef] [Green Version]
  114. Riebesell, U.; Aberle-Malzahn, N.; Achterberg, E.P.; Algueró-Muñiz, M.; Alvarez-Fernandez, S.; Arístegui, J.; Bach, L.T.; Boersma, M.; Boxhammer, T.; Guan, W.; et al. Toxic algal bloom induced by ocean acidification disrupts the pelagic food web. Nat. Clim. Chang. 2018, 8, 1082–1086. [Google Scholar] [CrossRef]
  115. Beck, L.R.; Lobitz, B.M.; Wood, B.L. Remote sensing and human health: New sensors and new opportunities. Emerg. Infect. Dis. 2000, 6, 217. [Google Scholar] [CrossRef] [Green Version]
  116. Lobitz, B.; Beck, L.; Huq, A.; Wood, B.; Fuchs, G.; Faruque, A.S.G.; Colwell, R. Climate and infectious disease: Use of remote sensing for detection of Vibrio cholerae by indirect measurement. Proc. Natl. Acad. Sci. USA 2000, 97, 1438–1443. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  117. Tatem, A.J.; Goetz, S.J.; Hay, S.I. Terra and Aqua: New data for epidemiology and public health. Int. J. Appl. Earth Obs. Geoinf. 2004, 6, 33–46. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  118. de Magny, G.C.; Paroissin, C.; Cazelles, B.; de Lara, M.; Delmas, J.F.; Guégan, J.F. Modeling environmental impacts of plankton reservoirs on cholera population dynamics. ESAIM Proc. 2005, 14, 156–173. [Google Scholar] [CrossRef] [Green Version]
  119. Finger, F.; Knox, A.; Bertuzzo, E.; Mari, L.; Bompangue, D.; Gatto, M.; Rodriguez-Iturbe, I.; Rinaldo, A. Cholera in the Lake Kivu region (DRC): Integrating remote sensing and spatially explicit epidemiological modeling. Water Resour. Res. 2014, 50, 5624–5637. [Google Scholar] [CrossRef] [Green Version]
  120. Sathyendranath, S.; Abdulaziz, A.; Menon, N.; Grinson, G.; Evers-King, H.; Kulk, G.; Colwell, R.; Jutla, A.S.; Platt, T. Building capacity and resilience against diseases transmitted via water under climate perturbations and extreme weather stress. In Space Capacity Building in the XXI Century; Ferretti, S., Ed.; Springer Nature: Basel, Switzerland, 2019; Volume 24, p. 14. [Google Scholar]
  121. Konrad, S.; Paduraru, P.; Romero-Barrios, P.; Henderson, S.B.; Galanis, E. Remote sensing measurements of sea surface temperature as an indicator of Vibrio parahaemolyticus in oyster meat and human illnesses. Environ. Health 2017, 16, 92. [Google Scholar] [CrossRef]
  122. Xu, M.; Cao, C.; Wang, D.; Kan, B. Identifying Environmental Risk Factors of Cholera in a Coastal Area with Geospatial Technologies. Int. J. Environ. Res. Public Health 2015, 12, 354–370. [Google Scholar] [CrossRef]
  123. Jutla, A.; Akanda, A.S.; Huq, A.; Faruque, A.S.G.; Colwell, R.; Islam, S. A water marker monitored by satellites to predict seasonal endemic cholera. Remote Sens. Lett. 2013, 4, 822–831. [Google Scholar] [CrossRef] [Green Version]
  124. Jutla, A.S.; Akanda, A.S.; Islam, S. Satellite Remote Sensing of Space-Time Plankton Variability in the Bay of Bengal: Connections to Cholera Outbreaks. Remote Sens. Environ. 2012, 123, 196–206. [Google Scholar] [CrossRef] [Green Version]
  125. Nkoko, D.; Giraudoux, P.; Plisnier, P.D.; Tinda, A.; Piarroux, M.; Sudre, B.; Horion, S.; Tamfum, J.J.; Ilunga, B.; Piarroux, R. Dynamics of Cholera Outbreaks in Great Lakes Region of Africa, 1978–2008. Emerg. Infect. Dis. 2011, 17, 2026. [Google Scholar] [CrossRef]
  126. Emch, M.; Yunus, M.; Escamilla, V.; Feldacker, C.; Ali, M. Local population and regional environmental drivers of cholera in Bangladesh. Environ. Health 2010, 9, 2. [Google Scholar] [CrossRef] [Green Version]
  127. Ford, T.E. Using Satellite Images of Environmental Changes to Predict Infectious Disease Outbreaks. Emerg. Infect. Dis. 2009, 15, 1341–1346. [Google Scholar] [CrossRef] [PubMed]
  128. Mendelsohn, J.; Dawson, T. Climate and cholera in KwaZulu-Natal, South Africa: The role of environmental factors and implications for epidemic preparedness. Int. J. Hyg. Environ. Health 2008, 211, 156–162. [Google Scholar] [CrossRef] [PubMed]
  129. Phillips, A.M.B.; DePaola, A.; Bowers, J.; Ladner, S.; Grimes, D.J. An Evaluation of the Use of Remotely Sensed Parameters for Prediction of Incidence and Risk Associated with Vibrio parahaemolyticus in Gulf Coast Oysters (Crassostrea virginica). J. Food Prot. 2007, 70, 879–884. [Google Scholar] [CrossRef] [PubMed]
  130. Sathyendranath, S.; Brewin, R.J.W.; Brockmann, C.; Brotas, V.; Calton, B.; Chuprin, A.; Cipollini, P.; Couto, A.B.; Dingle, J.; Doerffer, R.; et al. An Ocean-Colour Time Series for Use in Climate Studies: The Experience of the Ocean-Colour Climate Change Initiative (OC-CCI). Sensors 2019, 19, 4285. [Google Scholar] [CrossRef] [Green Version]
  131. Akanda, A.S.; Jutla, A.S.; Gute, D.M.; Sack, R.B.; Alam, M.; Huq, A.; Colwell, R.R.; Islam, S. Population Vulnerability to Biannual Cholera Outbreaks and Associated Macro-Scale Drivers in the Bengal Delta. Am. J. Trop. Med. Hyg. 2013, 89, 950–959. [Google Scholar] [CrossRef] [Green Version]
  132. Bouma, M.J.; Pascual, M. Seasonal and interannual cycles of endemic cholera in Bengal 1891–1940 in relation to climate and geography. Hydrobiologia 2001, 460, 147–156. [Google Scholar] [CrossRef]
  133. CEOS EO HANDBOOK. Available online: http://eohandbook.com/sdg/ (accessed on 30 September 2019).
  134. Groom, S.; Sathyendranath, S.; Ban, Y.; Bernard, S.; Brewin, R.; Brotas, V.; Brockmann, C.; Chauhan, P.; Choi, J.; Chuprin, A.; et al. Satellite Ocean Colour: Current Status and Future Perspective. Front. Mar. Sci. 2019, 6, 485. [Google Scholar] [CrossRef] [Green Version]
  135. Donlon, C.; Berruti, B.; Buongiorno, A.; Ferreira, M.H.; Féménias, P.; Frerick, J.; Goryl, P.; Klein, U.; Laur, H.; Mavrocordatos, C.; et al. The Global Monitoring for Environment and Security (GMES) Sentinel-3 mission. Remote Sens. Environ. 2012, 120, 37–57. [Google Scholar] [CrossRef]
  136. Liardon, J.L.; Hostettler, L.; Zulliger, L.; Kangur, K.; Shaik, N.; Barry, D.A. Lake Imaging and Monitoring Aerial Drone. HardwareX 2018, 3, 146–159. [Google Scholar] [CrossRef]
  137. Wu, J.L.; Ho, C.R.; Huang, C.C.; Srivastav, A.L.; Tzeng, J.H.; Lin, Y.T. Hyperspectral Sensing for Turbid Water Quality Monitoring in Freshwater Rivers: Empirical Relationship between Reflectance and Turbidity and Total Solids. Sensors 2014, 14, 22670–22688. [Google Scholar] [CrossRef] [Green Version]
  138. Kisevic, M.; Morovic, M.; Andricevic, R. The use of hyperspectral data for evaluation of water quality parameters in the River Sava. Fresenius Environ. Bull. 2016, 25, 4814–4822. [Google Scholar]
  139. Bidigare, R.R.; Ondrusek, M.E.; Morrow, J.H.; Kiefer, D.A. In-vivo absorption properties of algal pigments. 1990, Volume 1302, pp. 290–302. Available online: https://www.researchgate.net/publication/252465392_In-vivo_absorption_properties_of_algal_pigments (accessed on 30 September 2019).
  140. Trees, C.C.; Clark, D.K.; Bidigare, R.R.; Ondrusek, M.E.; Mueller, J.L. Accessory pigments versus chlorophyll a concentrations within the euphotic zone: A ubiquitous relationship. Limnol. Oceanogr. 2000, 45, 1130–1143. [Google Scholar] [CrossRef]
  141. Sathyendranath, S.; Cota, G.; Stuart, V.; Maass, H.; Platt, T. Remote sensing of phytoplankton pigments: A comparison of empirical and theoretical approaches. Int. J. Remote Sens. 2001, 22, 249–273. [Google Scholar] [CrossRef]
  142. Brewin, R.J.W.; Sathyendranath, S.; Hirata, T.; Lavender, S.J.; Barciela, R.M.; Hardman-Mountford, N.J. A three-component model of phytoplankton size class for the Atlantic Ocean. Ecol. Model. 2010, 221, 1472–1483. [Google Scholar] [CrossRef]
  143. Brewin, R.J.W.; Dall’Olmo, G.; Sathyendranath, S.; Hardman-Mountford, N.J. Particle backscattering as a function of chlorophyll and phytoplankton size structure in the open-ocean. Opt. Express 2012, 20, 17632–17652. [Google Scholar] [CrossRef]
  144. Brewin, R.J.W.; Sathyendranath, S.; Jackson, T.; Barlow, R.; Brotas, V.; Airs, R.; Lamont, T. Influence of light in the mixed-layer on the parameters of a three-component model of phytoplankton size class. Remote Sens. Environ. 2015, 168, 437–450. [Google Scholar] [CrossRef]
  145. Brewin, R.J.W.; Morán, X.A.G.; Raitsos, D.E.; Gittings, J.A.; Calleja, M.L.; Viegas, M.; Ansari, M.I.; Al-Otaibi, N.; Huete-Stauffer, T.M.; Hoteit, I. Factors Regulating the Relationship Between Total and Size-Fractionated Chlorophyll-a in Coastal Waters of the Red Sea. Front. Microbiol. 2019, 10, 1964. [Google Scholar] [CrossRef]
  146. Alvain, S.; Moulin, C.; Dandonneau, Y.; Bréon, F.M. Remote sensing of phytoplankton groups in case 1 waters from global SeaWiFS imagery. Deep Sea Res. Part Oceanogr. Res. 2005, 52, 1989–2004. [Google Scholar] [CrossRef] [Green Version]
  147. Alvain, S.; Moulin, C.; Dandonneau, Y.; Loisel, H. Seasonal distribution and succession of dominant phytoplankton groups in the global ocean: A satellite view. Glob. Biogeochem. Cycles 2008, 22. [Google Scholar] [CrossRef]
  148. Alvain, S.; Loisel, H.; Dessailly, D. Theoretical analysis of ocean color radiances anomalies and implications for phytoplankton groups detection in case 1 waters. Opt. Express 2012, 20, 1070–1083. [Google Scholar] [CrossRef] [PubMed]
  149. Rêve-Lamarche, A.H.; Alvain, S.; Racault, M.F.; Dessailly, D.; Guiselin, N.; Jamet, C.; Vantrepotte, V.; Beaugrand, G. Estimation of the Potential Detection of Diatom Assemblages Based on Ocean Color Radiance Anomalies in the North Sea. Front. Mar. Sci. 2017, 4, 408. [Google Scholar] [CrossRef] [Green Version]
  150. Sathyendranath, S.; Watts, L.; Devred, E.; Platt, T.; Caverhill, C.; Maass, H. Discrimination of diatoms from other phytoplankton using ocean-colour data. Mar. Ecol. Prog. Ser. 2004, 272, 59–68. [Google Scholar] [CrossRef]
  151. Racault, M.F.; Le Quéré, C.; Buitenhuis, E.; Sathyendranath, S.; Platt, T. Phytoplankton phenology in the global ocean. Ecol. Indic. 2012, 14, 152–163. [Google Scholar] [CrossRef]
  152. Racault, M.F.; Raitsos, D.E.; Berumen, M.L.; Brewin, R.J.W.; Platt, T.; Sathyendranath, S.; Hoteit, I. Phytoplankton phenology indices in coral reef ecosystems: Application to ocean-color observations in the Red Sea. Remote Sens. Environ. 2015, 160, 222–234. [Google Scholar] [CrossRef] [Green Version]
  153. Racault, M.F.; Sathyendranath, S.; Menon, N.; Platt, T. Phenological Responses to ENSO in the Global Oceans. Surv. Geophys. 2017, 38, 277–293. [Google Scholar] [CrossRef] [Green Version]
  154. Cole, H.S.; Henson, S.; Martin, A.P.; Yool, A. Basin-wide mechanisms for spring bloom initiation: How typical is the North Atlantic? ICES J. Mar. Sci. 2015, 72, 2029–2040. [Google Scholar] [CrossRef] [Green Version]
  155. Sallée, J.B.; Llort, J.; Tagliabue, A.; Lévy, M. Characterization of distinct bloom phenology regimes in the Southern Ocean. ICES J. Mar. Sci. 2015, 72, 1985–1998. [Google Scholar] [CrossRef] [Green Version]
  156. Platt, T.; Sathyendranath, S. Oceanic Primary Production: Estimation by Remote Sensing at Local and Regional Scales. Science 1988, 241, 1613–1620. [Google Scholar] [CrossRef]
  157. Sathyendranath, S.; Stuart, V.; Nair, A.; Oka, K.; Nakane, T.; Bouman, H.; Forget, M.H.; Maass, H.; Platt, T. Carbon-to-chlorophyll ratio and growth rate of phytoplankton in the sea. Mar. Ecol. Prog. Ser. 2009, 383, 73–84. [Google Scholar] [CrossRef]
  158. Martinez-Vicente, V.; Dall’Olmo, G.; Tarran, G.; Boss, E.; Sathyendranath, S. Optical backscattering is correlated with phytoplankton carbon across the Atlantic Ocean. Geophys. Res. Lett. 2013, 40, 1154–1158. [Google Scholar] [CrossRef]
  159. Kostadinov, T.S.; Milutinović, S.; Marinov, I.; Cabré, A. Carbon-based phytoplankton size classes retrieved via ocean color estimates of the particle size distribution. Ocean Sci. 2016, 12, 561–575. [Google Scholar] [CrossRef] [Green Version]
  160. Roy, S.; Sathyendranath, S.; Platt, T. Size-partitioned phytoplankton carbon and carbon-to-chlorophyll ratio from ocean colour by an absorption-based bio-optical algorithm. Remote Sens. Environ. 2017, 194, 177–189. [Google Scholar] [CrossRef] [Green Version]
  161. Dogliotti, A.I.; Ruddick, K.G.; Nechad, B.; Doxaran, D.; Knaeps, E. A single algorithm to retrieve turbidity from remotely-sensed data in all coastal and estuarine waters. Remote Sens. Environ. 2015, 156, 157–168. [Google Scholar] [CrossRef] [Green Version]
  162. Stramski, D.; Reynolds, R.A.; Babin, M.; Kaczmarek, S.; Lewis, M.R.; Röttgers, R.; Sciandra, A.; Stramska, M.; Twardowski, M.S.; Franz, B.A.; et al. Relationships between the surface concentration of particulate organic carbon and optical properties in the eastern South Pacific and eastern Atlantic Oceans. Biogeosciences 2008, 5, 171–201. [Google Scholar] [CrossRef] [Green Version]
  163. Evers-King, H.; Martinez-Vicente, V.; Brewin, R.J.W.; Dall’Olmo, G.; Hickman, A.E.; Jackson, T.; Kostadinov, T.S.; Krasemann, H.; Loisel, H.; Röttgers, R.; et al. Validation and Intercomparison of Ocean Color Algorithms for Estimating Particulate Organic Carbon in the Oceans. Front. Mar. Sci. 2017, 4, 251. [Google Scholar] [CrossRef]
  164. Gordon, H.R.; Boynton, G.C.; Balch, W.M.; Groom, S.B.; Harbour, D.S.; Smyth, T.J. Retrieval of coccolithophore calcite concentration from SeaWiFS Imagery. Geophys. Res. Lett. 2001, 28, 1587–1590. [Google Scholar] [CrossRef]
  165. Balch, W.M.; Gordon, H.R.; Bowler, B.C.; Drapeau, D.T.; Booth, E.S. Calcium carbonate measurements in the surface global ocean based on Moderate-Resolution Imaging Spectroradiometer data. J. Geophys. Res. Oceans 2005, 110. [Google Scholar] [CrossRef]
  166. Smyth, T.J.; Tyrrell, T.; Tarrant, B. Time series of coccolithophore activity in the Barents Sea, from twenty years of satellite imagery. Geophys. Res. Lett. 2004, 31. [Google Scholar] [CrossRef] [Green Version]
  167. Moore, T.S.; Dowell, M.D.; Franz, B.A. Detection of coccolithophore blooms in ocean color satellite imagery: A generalized approach for use with multiple sensors. Remote Sens. Environ. 2012, 117, 249–263. [Google Scholar] [CrossRef] [Green Version]
  168. Lee, Z.; Carder, K.L.; Arnone, R.A. Deriving inherent optical properties from water color: A multiband quasi-analytical algorithm for optically deep waters. Appl. Opt. 2002, 41, 5755–5772. [Google Scholar] [CrossRef] [PubMed]
  169. Maritorena, S.; Siegel, D.A.; Peterson, A.R. Optimization of a semianalytical ocean color model for global-scale applications. Appl. Opt. 2002, 41, 2705–2714. [Google Scholar] [CrossRef] [PubMed]
  170. Werdell, P.J.; Franz, B.A.; Bailey, S.W.; Feldman, G.C.; Boss, E.; Brando, V.E.; Dowell, M.; Hirata, T.; Lavender, S.J.; Lee, Z.; et al. Generalized ocean color inversion model for retrieving marine inherent optical properties. Appl. Opt. 2013, 52, 2019–2037. [Google Scholar] [CrossRef] [PubMed]
  171. Doney, S.C. Plankton in a warmer world. Nature 2006, 444, 695–696. [Google Scholar] [CrossRef] [Green Version]
  172. Ali, M.; Nelson, A.R.; Lopez, A.L.; Sack, D.A. Updated Global Burden of Cholera in Endemic Countries. PLoS Negl. Trop. Dis. 2015, 9, e0003832. [Google Scholar] [CrossRef] [Green Version]
  173. Scharlemann, J.P.W.; Mant, R.C.; Balfour, N.; Brown, C.; Burgess, N.D.; Guth, M.; Ingram, D.J.; Lane, R.; Martin, J.; Wicander, S.; et al. Global Goals Mapping: The Environment-Human Landscape. Available online: http://www.nerc.ac.uk/research/partnerships/international/overseas/tase/mapping/ (accessed on 30 September 2019).
  174. Brewin, R.J.W.; Brewin, T.G.; Phillips, J.; Rose, S.; Abdulaziz, A.; Wimmer, W.; Sathyendranath, S.; Platt, T. A Printable Device for Measuring Clarity and Colour in Lake and Nearshore Waters. Sensors 2019, 19, 936. [Google Scholar] [CrossRef] [Green Version]
  175. Akanda, A.S.; Aziz, A.; Jutla, A.; Huq, A.; Alam, M.; Asham, G.U.; Colwell, R.R. Satellites and Cell Phones Form a Cholera Early-Warning System. Eos Trans. Am. Geophys. Union 2018, 99. [Google Scholar] [CrossRef]
  176. Finger, F.; Genolet, T.; Mari, L.; de Magny, G.C.; Manga, N.M.; Rinaldo, A.; Bertuzzo, E. Mobile phone data highlights the role of mass gatherings in the spreading of cholera outbreaks. Proc. Natl. Acad. Sci. USA 2016, 113, 6421–6426. [Google Scholar] [CrossRef] [Green Version]
  177. Abubakar, A.; Azman, A.S.; Rumunu, J.; Ciglenecki, I.; Helderman, T.; West, H.; Lessler, J.; Sack, D.A.; Martin, S.; Perea, W.; et al. The First Use of the Global Oral Cholera Vaccine Emergency Stockpile: Lessons from South Sudan. PLoS Med. 2015, 12, e1001901. [Google Scholar] [CrossRef] [Green Version]
Figure 1. A schematic representation of environmental reservoirs of V. cholerae. The bacteria can be found as free-floating organism in the water column or interacting with various ecosystem components, including phytoplankton, zooplankton, fish, water-column and sediment particulate organic matter (POM) and dissolved organic matter (DOM), benthic organisms such as crustaceans, bivalves and macrophytes, aquatic birds, chironomids, and humans. The environmental reservoirs may support: (1) Host–pathogen interactions with a host providing a source of nutrients and protection; (2) transport mechanisms (for instance with birds and insects) allowing dissemination of the bacteria over long distances; (3) vectors of infection allowing transmission of pathogenic bacteria to human, for instance through consumption of fish or seafood or drinking of contaminated water; (4) predatory–prey interactions; and (5) biogeochemical cycling via organic matter decomposition associated with the secretion of hydrolytic enzymes by V. cholerae, such as chitinase that degrades chitin polymers into low-molecular-weight compounds such as N-Acetylglucosamine (GlcNAc) monomers that enter the microbial loop and can be taken up by other organisms in the ecosystem. The presence and interactions with chitin are indicated in boxes with purple color background (i.e., boxes labeled as Chitin, Diatoms, and Copepods). The influence of environmental and climate conditions is indicated, with hydrological drivers such as temperature, salinity, O2, pH, nutrients, and cations influencing the growth, mortality, virulence, and dormancy (also-called Viable But Non-Culturable (VBNC) state). The concepts depicted in this schematic are described in the literature review presented in Section 3.1, Section 3.2, Section 3.3 and Section 3.4 and in [1,15,49].
Figure 1. A schematic representation of environmental reservoirs of V. cholerae. The bacteria can be found as free-floating organism in the water column or interacting with various ecosystem components, including phytoplankton, zooplankton, fish, water-column and sediment particulate organic matter (POM) and dissolved organic matter (DOM), benthic organisms such as crustaceans, bivalves and macrophytes, aquatic birds, chironomids, and humans. The environmental reservoirs may support: (1) Host–pathogen interactions with a host providing a source of nutrients and protection; (2) transport mechanisms (for instance with birds and insects) allowing dissemination of the bacteria over long distances; (3) vectors of infection allowing transmission of pathogenic bacteria to human, for instance through consumption of fish or seafood or drinking of contaminated water; (4) predatory–prey interactions; and (5) biogeochemical cycling via organic matter decomposition associated with the secretion of hydrolytic enzymes by V. cholerae, such as chitinase that degrades chitin polymers into low-molecular-weight compounds such as N-Acetylglucosamine (GlcNAc) monomers that enter the microbial loop and can be taken up by other organisms in the ecosystem. The presence and interactions with chitin are indicated in boxes with purple color background (i.e., boxes labeled as Chitin, Diatoms, and Copepods). The influence of environmental and climate conditions is indicated, with hydrological drivers such as temperature, salinity, O2, pH, nutrients, and cations influencing the growth, mortality, virulence, and dormancy (also-called Viable But Non-Culturable (VBNC) state). The concepts depicted in this schematic are described in the literature review presented in Section 3.1, Section 3.2, Section 3.3 and Section 3.4 and in [1,15,49].
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Figure 2. Habitat suitability for V. cholerae in the northern Indian Ocean inferred from (a) [54] the ecological niche model (Figure 2a is adapted from [54] their Figure 4) and (b) [123] the satellite water marker (SWM) model applied to the European Space Agency Ocean Color Climate Change Initiative (ESA OC-CCI) remote-sensing reflectance data [130]. The maximum values of SWM (in percent) over the period 1997–2017 are shown. The correlation between chlorophyll-a and satellite water marker is shown in (c). Pearson correlation has been performed using detrended anomalies of October–November–December (OND) chlorophyll-a and OND satellite water marker over the period 1997–2017. OND corresponds to the months analyzed in [123] in the Bengal Delta region. Positive values of SWM, indicating suitable habitat for V. cholerae associated with cholera incidence, are used in the correlation analysis. The high positive correlation found in coastal waters suggests a connection between oceanic plankton abundance and cholera incidence in OND. In (c), white color indicates non-significant correlation values. Chlorophyll-a data were obtained from ESA OC-CCI version 4 [130] and satellite water marker data were calculated as indicated in (b).
Figure 2. Habitat suitability for V. cholerae in the northern Indian Ocean inferred from (a) [54] the ecological niche model (Figure 2a is adapted from [54] their Figure 4) and (b) [123] the satellite water marker (SWM) model applied to the European Space Agency Ocean Color Climate Change Initiative (ESA OC-CCI) remote-sensing reflectance data [130]. The maximum values of SWM (in percent) over the period 1997–2017 are shown. The correlation between chlorophyll-a and satellite water marker is shown in (c). Pearson correlation has been performed using detrended anomalies of October–November–December (OND) chlorophyll-a and OND satellite water marker over the period 1997–2017. OND corresponds to the months analyzed in [123] in the Bengal Delta region. Positive values of SWM, indicating suitable habitat for V. cholerae associated with cholera incidence, are used in the correlation analysis. The high positive correlation found in coastal waters suggests a connection between oceanic plankton abundance and cholera incidence in OND. In (c), white color indicates non-significant correlation values. Chlorophyll-a data were obtained from ESA OC-CCI version 4 [130] and satellite water marker data were calculated as indicated in (b).
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Figure 3. Global map of annual mean chlorophyll-a concentration (ocean) and maximum number of World Health Organization (WHO) reported annual cholera cases (land) over the decades (a) 1997–2006 and (b) 2007–2016. Possible ocean corridors for cholera outbreaks are shown in tropical coastal regions between 30ºS to 30ºN using numbered arrows. Ocean corridors are defined as locations where plankton intrusion may be possible to inland waters and annual cholera cases have been reported during one or both time periods. The location of possible ocean corridors has been adapted based on [6]. At locations 1 and 2, cholera outbreaks are sporadic. At locations 3 to 9, cholera is endemic (based on definition by [172]). The Amazon River in region 2 is the largest river worldwide by discharge volume of water and by the area of land that drains into it. However, cholera is not reported as endemic in that region, which may be explained by annually constant and high outflows of freshwater that is carried to the sea, and by low population density in the Amazon river basin. At locations 1 and 7, there are no major river inflows into the land and the possible cause of disease outbreaks may be contaminated food or water by Vibrio pathogens transported through long-distance oceanic corridors [110] or human travelers [25]. Chlorophyll-a concentration data were obtained from the ESA OC-CCI version 4 [130]. Reported cholera cases were obtained from, and are limited to, the WHO Global Health Observatory data archive. Arrows indicating the location of possible ocean corridors, as well as the color scales for Chlorophyll-a concentration and number of reported cholera cases apply to (a,b). White color means that no data were available.
Figure 3. Global map of annual mean chlorophyll-a concentration (ocean) and maximum number of World Health Organization (WHO) reported annual cholera cases (land) over the decades (a) 1997–2006 and (b) 2007–2016. Possible ocean corridors for cholera outbreaks are shown in tropical coastal regions between 30ºS to 30ºN using numbered arrows. Ocean corridors are defined as locations where plankton intrusion may be possible to inland waters and annual cholera cases have been reported during one or both time periods. The location of possible ocean corridors has been adapted based on [6]. At locations 1 and 2, cholera outbreaks are sporadic. At locations 3 to 9, cholera is endemic (based on definition by [172]). The Amazon River in region 2 is the largest river worldwide by discharge volume of water and by the area of land that drains into it. However, cholera is not reported as endemic in that region, which may be explained by annually constant and high outflows of freshwater that is carried to the sea, and by low population density in the Amazon river basin. At locations 1 and 7, there are no major river inflows into the land and the possible cause of disease outbreaks may be contaminated food or water by Vibrio pathogens transported through long-distance oceanic corridors [110] or human travelers [25]. Chlorophyll-a concentration data were obtained from the ESA OC-CCI version 4 [130]. Reported cholera cases were obtained from, and are limited to, the WHO Global Health Observatory data archive. Arrows indicating the location of possible ocean corridors, as well as the color scales for Chlorophyll-a concentration and number of reported cholera cases apply to (a,b). White color means that no data were available.
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Table 1. Studies using ocean-color remote-sensing observations to survey and forecast Vibrio spp. occurrence or cholera disease outbreaks. RS = remote sensing.
Table 1. Studies using ocean-color remote-sensing observations to survey and forecast Vibrio spp. occurrence or cholera disease outbreaks. RS = remote sensing.
Predicted variableCovariateMethodStudy Region and PeriodSatellite Sensor or ProductReference
Vibrio parahaemolyticus densities in oyster meatRS: SST, Chlorophyll-a
Other: salinity
Multilinear regression modelBritish Columbia, Canada; 2003–2015Multi-scale Ultra-high-resolution SST Analysis, MODIS[121]
Cholera incidenceRS: SST, SSH, Chlorophyll-a
Other: precipitation, temperature
Macro environment–SIR model and multilinear regression analysis of environmental driversZhejiang province, China;
2001–2008
AVHRR, TOPEX/Poseidon and Jason-1, SeaWiFS[47]
Cholera incidenceRS: SST, SSH, Chlorophyll-aMultilinear regression modelChina; 1999–2008AVHRR TOPEX/Poseidon and Jason-1, SeaWiFS[122]
Vibrio cholerae habitat suitability indexRS: Chlorophyll-a, SST, Photosynthetically Available Radiation
Other: salinity, pH, O2, nitrate, phosphate
Ecological niche modelGlobal oceans; 2005–2010MODIS aqua, SeaWiFS[54]
Cholera incidenceRS: Chlorophyll-a, precipitation
Other: ENSO and DMI climate indices
Inhomogeneous Markov Chain modelLake Kivu region, DRC; 2002–2012MODIS aqua, TRMM[119]
Cholera incidenceRS: reflectance at 412 and 555 nmSatellite Water Marker (SWM) model based on RS reflectance Bay of Bengal, Mozambique Channel; 1998–2009SeaWiFS[123]
Cholera incidenceRS: Chlorophyll-aCorrelation analysesBay of Bengal coastal and offshore; 1998–2007SeaWiFS[124]
Cholera incidenceRS: Chlorophyll-a
Other: precipitation, fishing activities
Time-series and correlation analysesLake Kivu region, DRC; 2002–2006MODIS aqua[125]
Cholera incidenceRS: SST, SSH, Chlorophyll-a
Other: socio-economic status
Generalized linear modelBangladesh, Bay of Bengal; 2003–2007AVHRR, Jason-1, SeaWiFS[126]
Cholera incidenceRS: Chlorophyll-a
Other: river discharge data
Analysis of annual variationsBay of Bengal, Mozambique Channel; 1997–2010SeaWiFS[6]
Cholera incidenceRS: SST, SSH, (Chlorophyll-a)Correlation analyses Bangladesh, Bay of Bengal; 1992–1995 and 1997–1998AVHRR, TOPEX/Poseidon, (SeaWiFS)[116]
Cholera incidence RS: SST, SSH, Chlorophyll-aAnalysis of interannual variations Bangladesh, Bay of Bengal; 1998–2002AVHRR, TOPEX/Poseidon, SeaWiFSColwell and Calkins, unpub. data reported in [16,127]
Cholera incidenceRS: SST, Chlorophyll-a, precipitationGeneralized linear modelBangladesh, Matlab, India, Kolkata, Bay of Bengal; 1998–2006NOAA Optimally Interpolated product, SeaWiFS, Global Precipitation Climatology Project (GPCP)[44]
Cholera incidenceRS: SST, SSH, Chlorophyll-a, precipitationLinear regression analysesKwaZulu-Natal, South Africa; 2000–2001AVHRR, Topex/Poseidon, SeaWiFS, Merge of infrared and microwave satellite estimates with rain gauge data (GPCP)[128]
Cholera incidenceRS: SST, SSH, Chlorophyll-a
Other: Precipitation, temperature, river discharge or height
Multivariate regression analysesMatlab, Bangladesh, Hue, Vietnam; 1997–2003AVHRR, TOPEX/Poseidon and Jason-1, SeaWiFS[48]
Vibrio parahaemolyticus densities in oyster meatRS: SST, turbidity, Chlorophyll-a
Other: salinity, bottom water temperature
Regression analyses Alabama coastal region, USA; 1999–2000AVHRR, SeaWiFS[129]
Table 2. Existing ocean-color products with realized or potentially-new applications on environmental reservoirs of V. cholerae.
Table 2. Existing ocean-color products with realized or potentially-new applications on environmental reservoirs of V. cholerae.
ApplicationStatusEnvironmental InteractionReservoirOcean-Color ProductOcean-Color Product Reference
Reservoir distribution and cholera outbreaksRealized
(references in Table 1)
Host–pathogenPhytoplankton biomassTotal chlorophyll-a[139,140,141]
Reservoir distribution and cholera outbreaksRealized
Jutla et al., 2013
Host–pathogenPhytoplankton biomass and suspended matterSatellite Water Marker based on Rrs[123]
Reservoir distributionPotentialHost–pathogenPhytoplankton size structureMicro-, nano-, picohytoplankton chlorophyll-a[142,143,144,145]
Reservoir distributionPotentialHost–pathogen Phytoplankton functional groupsDiatoms, Coccolithophores, Phaeocystis, Prochlorococcus, Synechoccus, Nano-Eukaryotes [146,147,148,149]
Reservoir distributionPotentialHost–pathogen Chitin-containing phytoplanktonDiatoms[150]
Reservoir temporal dynamicsPotentialHost–pathogen Phytoplankton phenologyTimings of initiation, peak, termination, and duration[151,152,153,154,155]
Biogeochemical cycles regulationPotentialCarbon cyclePhytoplankton organic carbon productivityPrimary production[156]
Biogeochemical cycles regulationPotentialCarbon cyclePhytoplankton carbonTotal phytoplankton carbon[157,158,159,160]
Biogeochemical cycles regulationPotentialCarbon cyclePhytoplankton carbonMicro-, nano-, picohytoplankton carbon[159,160]
Reservoir distributionPotentialHost–pathogenSuspended matterTurbidity, total suspended matter[161]
Biogeochemical cycles regulationPotentialNutrients, Carbon cycleParticulate organic matterParticulate organic carbon[162,163]
Biogeochemical cycles regulationPotentialCarbon cycleParticulate inorganic matterParticulate inorganic carbon[164,165]
Biogeochemical cycles regulationPotentialCarbon cycleCarbon export, acidificationCoccolithophores[166,167]
Biogeochemical cycles regulationPotentialNutrients, Carbon cycleDissolved organic matterColored dissolved organic matter[168,169,170]
Table 3. Potential of satellite applications to address knowledge gaps on water-borne diseases and support achievement of Sustainable Development Goals (SDGs) targets on 3-Health, 6-Water quality, 13-Climate, and 14-Life under the water. For each target and indicator, the reference number in square brackets is based on the numbering presented in the SDGs 2030 agenda.
Table 3. Potential of satellite applications to address knowledge gaps on water-borne diseases and support achievement of Sustainable Development Goals (SDGs) targets on 3-Health, 6-Water quality, 13-Climate, and 14-Life under the water. For each target and indicator, the reference number in square brackets is based on the numbering presented in the SDGs 2030 agenda.
GoalTargetSupport from Satellite Applications Indicator of Impact
3-Health[3.3] Combat epidemics of water-borne diseases;
[3.d] Strengthen capacity for early warning, risk reduction and management of national and global health risks
- Improve knowledge on the transmission patterns of the Vibrio cholerae pathogens in affected countries → the information will be useful for health services to help provide the most adapted and efficient treatment for the affected local populations, and to increase chances of recovery;
- Improve surveillance systems and strengthen the capacity of affected countries to produce early warning and risk maps for cholera outbreaks → the improved/local/regional forecast systems may be delivered to national agencies for operational use and the risk warning may be placed in the public domain to reduce public health risks.
[3.3.5] a reduction in the number of people requiring treatment against Vibrio disease;
[3.9.2] a reduction in mortality rate associated with exposure to contaminated water;
[3.d.1] an increase in capacity for disaster mitigation in affected areas.
6-Water quality[6.3] Improve water quality by reducing pollution, halving the proportion of untreated wastewater;
[6.5] Implement integrated water resource management
- Provide evidence on Vibrio disease hotspots → this information will help government authorities to identify areas where microbial and antibiotic pollution should be treated as a priority.
- Improve knowledge of the transmission routes and dynamics of cholera pathogens in the lacustrine and coastal ecosystems in relation to climate variability and disease outbreaks → this information will support increased preparedness along the transmission routes, and integration of locally-targeted water sanitation control measures that will help to interrupt the transmission routes.
[6.b.1] an increase in the number of actions taken by local administrations to treat sources of pollution, and to engage the local communities in water and sanitation management.
13-Climate[13.1] Strengthen resilience and adaptive capacity to climate-related hazards and natural disasters- Improve knowledge of the influence of extreme weather events and climate variability on the incidence of cholera outbreaks and the contamination routes of Vibrio pathogens → this will help to prioritize policy measures for health service preparedness and population awareness when high-risk climate events occur, and hence improve cholera-disaster risk mitigation.[13.3.1] an increase in the number of countries that recognize the need to integrate climate-related risk in their early warning systems for cholera outbreaks, and in their adaptation and mitigation plans (to reduce impact and risk of cholera outbreaks).
14-Marine Life[14.1] Prevent and significantly reduce marine pollution of all kinds;
[14.2] Sustainably manage and protect marine and coastal ecosystems to avoid significant adverse impacts and achieve healthy and productive oceans
- Provide evidence on the extent to which lacustrine and coastal communities are suffering from Vibrio diseases → this information can be used to support the development of sustainable management plans.[14.c.1] an increase in the number of countries that incorporate ecosystem-based management in their stewardship of coastal ecosystems and their resources.

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Racault, M.-F.; Abdulaziz, A.; George, G.; Menon, N.; C, J.; Punathil, M.; McConville, K.; Loveday, B.; Platt, T.; Sathyendranath, S.; et al. Environmental Reservoirs of Vibrio cholerae: Challenges and Opportunities for Ocean-Color Remote Sensing. Remote Sens. 2019, 11, 2763. https://doi.org/10.3390/rs11232763

AMA Style

Racault M-F, Abdulaziz A, George G, Menon N, C J, Punathil M, McConville K, Loveday B, Platt T, Sathyendranath S, et al. Environmental Reservoirs of Vibrio cholerae: Challenges and Opportunities for Ocean-Color Remote Sensing. Remote Sensing. 2019; 11(23):2763. https://doi.org/10.3390/rs11232763

Chicago/Turabian Style

Racault, Marie-Fanny, Anas Abdulaziz, Grinson George, Nandini Menon, Jasmin C, Minu Punathil, Kristian McConville, Ben Loveday, Trevor Platt, Shubha Sathyendranath, and et al. 2019. "Environmental Reservoirs of Vibrio cholerae: Challenges and Opportunities for Ocean-Color Remote Sensing" Remote Sensing 11, no. 23: 2763. https://doi.org/10.3390/rs11232763

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