Factors that affect the growth and photosynthesis of the filamentous green algae, Chaetomorpha valida, in static sea cucumber aquaculture ponds with high salinity and high pH

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Aquatic Biology

Introduction

The Green tide is one of the most important issues affecting shallow coastal areas around the world (Edlund et al., 2009; Bianchi et al., 2010; Harmon et al., 2014; Fleming-Lehtinen et al., 2015). Outbreaks of thalloid green macroalgae (e.g., Ulva armoricana and Ulva rotundata) occur near the Yellow sea coast of China. However, outbreaks of filamentous green macroalgae (e.g., Chaetomorpha spp. and Cladophora spp.) are found in ponds and lakes (Le Luherne et al., 2016). The dominant species of filamentous green macroalgae are in the genera Ulva, Chaetomorpha, Cladophora, Enteromorpha, and Codium, which are characterized by rapid absorption of nutrients and high growth rates (Valiela et al., 1997; Anderson, Glibert & Burkholde, 2002; Zhang & Shao, 2013). In recent years, an invasive filamentous green algae, Chaetomorpha valida, has been found in sea cucumber aquaculture ponds (Chi et al., 2009; Deng et al., 2012).

Chaetomorpha is a common and widespread green algae genus in the order Cladophorales which is characterized by unbranched filaments. C. valida was originally described from Tasmania, Australia (Womersley, 1984; South & Skelton, 2003). As an invasive species in China, C. valida was first reported in sea cucumber aquaculture ponds in coastal provinces, including the Liaoning and Shandong Provinces (Chi et al., 2009; Deng et al., 2012). C. valida, a filamentous green tide forming algae, is visible throughout the year and dominates aquaculture ponds (Chi et al., 2009). C. valida grows more luxuriantly from April to September of every year, and sometimes the macroalgal mat exceeds 0.5 m in thickness. C. valida outbreaks present a significant problem in aquaculture ponds, especially when loose algal mats accumulate and decompose (Deng et al., 2012). A large number of C. valida floating on the surface of the water blocks the sunlight and suppresses the growth of benthic diatoms, which are the diet for sea cucumbers (Deng et al., 2012).

The growth and photosynthetic activity of algae are closely tied to the temperature, pH, salinity, and other environmental factors (Yun, Sangheon & Ikkyo, 2010; Fu, 2014). Although the growth of Chaetomorpha sp. is affected by the temperature and salinity of the culture environment, the algae can grow rapidly in stagnant water, despite large fluctuations in salt water and temperature (Tsutsui et al., 2015; Gao, Endo & Agatsuma, 2018a, 2018b). Scrippsiella trochoidea and Alexandrium tamarense are very sensitive to pH, with a suitable pH range of 7.0–9.0, and an optimal pH of 7.5–8.0 (Deng et al., 2004). Chen et al. (2015) found that the photosynthetic activity of Ceratophyllum demersum was higher between pH 7 and 9. With increasing salinity, temperature, and light intensity, the photosynthesis of Chaetoceros aeruginosa first increased and then decreased. When the salinity was more than 40 ‰, the photosynthesis of the Chaetoceros aeruginosa was inhibited (Qi et al., 2008). Thus, different environmental factors may promote the growth and photosynthesis of algae, resulting in its overgrowth and potential outbreak. However, very little research has been done on the Chaetomorpha (De Paula Silva et al., 2008; Xu & Lin, 2008; Deng et al., 2012).

The aim of this study was to clarify the ecological conditions for optimal growth of C. valida and evaluate its tolerance to pH and salinity in sea cucumber aquaculture ponds near the coast in northern China. The ultimate goal of the study was to provide an explanation of why C. valida outbreaks occur. To achieve this goal, we conducted both a field survey and laboratory studies to understand the effects of salinity and pH on C. valida growth.

Materials and Methods

Field surveys

Field surveys were carried out in the aquaculture ponds of sea cucumbers (36°46′N, 121°9′E). The aquaculture pond area was 80 acres. The biomass of sea cucumber was 300–400 kg/acre. Water was exchanged twice a month over a 3 to 4 day period, exchanging approximately 1/3 per day. Three ponds were selected randomly, and samples were collected at six randomly selected fixed sites in each pond. Each sampling site was separated into two m2 quadrats (1 × 1m). The samples were collected on the 15th of each month. Salinity and pH of the seawater in the ponds were recorded from January to December in 2016. Salinity was measured with a salinity meter (MASTER-S10α; Shanghai Renhe Scientific Instrument Co., Ltd., Shanghai, China), and pH was measured with a pH meter (PHS-3C; Shanghai INESA Instruments Co., Ltd., Shanghai, China).

Chaetomorpha valida samples were harvested from the sampling spot, other algae were removed, sediment was cleaned from the algae surface with clean seawater, and the sample was placed on a bamboo pole and air-dried for 10 min. The wet weight of the algae was checked every month. After recording the wet weight of C. valida, the algae were returned to the original cages to monitor the annual growth of algae. The last wet weight was measured on the shore and the C. valida was not returned to the ponds.

Laboratory experiments

Chaetomorpha valida were collected from a sea cucumber aquaculture pond in October 2016 and transported in seawater to the laboratory. Healthy thalli, which were full of plump cells, were selected and cleaned with sterilized seawater to remove epiphytes and their metabolites. Then healthy thalli were cut into 2.5 cm fragments for the experiment, using a scale.

For the salinity experiments, seawater was filtered and sterilized. The salinity of seawater was diluted with deionized water to 22‰. Using sodium chloride, the salinity of seawater was adjusted to 22‰, 24‰, 28‰, 30‰, 32‰, 34‰, 36‰, and 40‰. A total of 30 fragments were placed in a 90 mm petri dish, and 15 mL of seawater was added to each dish. The petri dish was covered during the experiment. Samples were analyzed in triplicate for each salinity group. Samples were incubated for 18 days at 25 °C, with a light intensity of 108 mol photon·m−2·s−1, and a photoperiod of 12 L:12 D. Alga length was measured with a scale every 2 days. After 30 min of dark-adaptation, the Fv/Fm (quantum yield of photosynthesis) of algae was measured with an AquaPen-P AP-P 100 (Photon Systems Instruments, Ltd., Brno, Czech Republic) at 4 and 18 days. Seawater with different salinity was changed every 2 days.

For the pH experiments, the pH of seawater was adjusted to 6.5, 7.0, 7.5, 8.0, and 8.5 with sodium hydroxide and hydrochloric acid. The seawater salinity was 32‰. Culture conditions and treatments were the same as described previously. Samples were analyzed in triplicate for each pH group. Algae length was measured with a scale every 2 days during the 32 days of the experiment. The Fv/Fm of algae was measured with an AquaPen-P AP-P 100 (Photon Systems Instruments, Ltd., Brno, Czech Republic) every 2 days. Seawater with different pH was changed every 2 days.

Data analysis

Data were processed using Origin 8.5. Values are reported as mean ± standard deviation. Regression analysis was used to analyze the relationship between various factors. Statistical analyses were one-way ANOVA with Dunnett’s posttest, and p < 0.05 was considered significant. These analyses were conducted using SPSS 13.0.

Results

Field surveys

The salinity changed significantly over time (p = 1 × 10−6, df = 11, F = 74,642.628) (Fig. 1). Salinity varied from 24.3 ± 0.01‰ to 32.0 ± 0.02‰. As shown in Fig. 1, the salinity of seawater decreased from June to September (summer and early autumn) then increased from October to December (autumn and early winter), and salinity was lowest at the end of summer.

Changes in salinity, pH, and biomass of C. valida in ponds of sea cucumber over time.

Figure 1: Changes in salinity, pH, and biomass of C. valida in ponds of sea cucumber over time.

Values are expressed as mean ± standard deviation (n = 18).

The results of the field survey show that pH changed significantly over time in the sea cucumber ponds (p = 1 × 10−5, df = 11, F = 451.595) (Fig. 1). The pH tended to decrease first and then increase. The pH varied from 7.5 ± 0.02 to 8.6 ± 0.04.

The biomass of C. valida changed significantly over time (p = 1 × 10−6, df = 11, F = 2,448.658) (Fig. 1). The biomass of C. valida increased first and then decreased later in the year. From January to May, the alga biomass was first low and then gradually increased. The biomass of C. valida peaked in September (27.2 ± 0.541 Kg/m2) and decreased gradually.

The results of the field investigation showed that the biomass of C. valida was inversely proportional to the salinity and pH of seawater in the ponds (Fig. 1). In the early stages, salinity and pH were high, at which time the biomass of C. valida was lower. Over time, salinity and pH decreased, while C. valida biomass increased gradually. Salinity and pH reached their lowest values in August and September, whereas the biomass of C. valida peaked in September. After peaking, the C. valida biomass gradually decreased while seawater salinity and pH increased rapidly.

Laboratory experiments

Salinity had significant effects on the growth of C. valida (p = 1 × 10−4, df = 7, F = 12.205) (Fig. 2) on day 16. The growth of C. valida increased significantly when grown in salinity of 24–34‰ compared to the 22‰ salinity. However, no significant differences in C. valida growth were detected at 36‰ and 40‰ salinity compared to 22‰ salinity. At the same salinity, the length of C. valida increased over time. At the same culture time, the length of C. valida increased with increasing salinity, but then decreased at higher salinity. When the salinity was 40‰, the growth of C. valida was relatively low, and the length was only 9.26 ± 2.36 cm after 16 days in culture. In contrast, C. valida grew faster when the salinity was between 24‰ and 34‰. When the salinity was 34‰, the length of C. valida was 26.44 ± 5.89 cm after 16 days in culture, which was 10.6 times the initial value (day 2).

Effects of salinity on the growth of C. valida. Values are expressed as mean ± standard deviation; n = 3 replicates.

Figure 2: Effects of salinity on the growth of C. valida. Values are expressed as mean ± standard deviation; n = 3 replicates.

The different letters on the right side of the curve indicate significant differences (one-way ANOVA with Dunnett’s posttest α = 0.05): a<b.

The pH affected the grown of C. valida significantly (p = 0.001, df = 4, F = 10.238) (Fig. 3). At pH 7.5–8.5, the growth of C. valida increased significantly compared to pH 6.5–7.0 (Fig. 3). At the same pH, the length of C. valida increased over time. At the same culture time, the length of C. valida increased with increasing pH and peaked at pH 8.0. At 32 days of culture, C. valida grew to 67.96 ± 4.45 cm at pH 8.0, which was 27.18 times the initial value. However, C. valida samples only grew to 23.83 ± 2.16 cm at a pH of 6.5.

Effects of pH on the growth of C. valida.

Figure 3: Effects of pH on the growth of C. valida.

Values are expressed as mean ± standard deviation; n = 3 replicates. The different letters on the right side of the curve indicate significant differences (one-way ANOVA with Dunnett’s posttest α = 0.05): a<b<c.

Salinity significantly affected the Fv/Fm of C. valida (p = 1 × 10−5, df = 6, F = 530.941) (Fig. 4). At 18 days in culture, the Fv/Fm of C. valida increased with increasing salinity. When the salinity was 32‰, Fv/Fm was the highest (0.635 ± 0.002). Under the same salinity conditions, Fv/Fm of C. valida decreased significantly with time (4 days vs. 18 days). At 4 days in culture, Fv/Fm was the lowest (0.620 ± 0.004) when the salinity was 34‰.

Effects of salinity on the Fv/Fm of C. valida after 4 and 18 days of culture.

Figure 4: Effects of salinity on the Fv/Fm of C. valida after 4 and 18 days of culture.

Values are expressed as mean ± standard deviation; n = 3 replicates.

The pH had significant effects on the Fv/Fm of C. valida (p = 1 × 10−5, df = 4, F = 520.696) (Fig. 5). At the same pH, Fv/Fm of C. valida was unstable over time. When the pH was 6.5, Fv/Fm was lower compared to other pH conditions (0.50 ± 0.006 vs. 0.63 ± 0.001, pH 6.5 vs. pH 8 on day 32). Fv/Fm ranged from 0.55 ± 0.006 to 0.65 ± 0.007 at pH 7.5.

Effects of pH on the Fv/Fm of C. valida.

Figure 5: Effects of pH on the Fv/Fm of C. valida.

Values are expressed as mean ± standard deviation; n = 3 replicates.

Discussion

Field survey

In the field survey, we found that salinity, pH, and biomass of C. valida in the ponds fluctuated. In summer and autumn, the salinity and pH of the seawater decreased, while the biomass of the C. valida increased rapidly. We speculate that the root cause for the changes in salinity and pH were more rainfall in summer and autumn. In sea cucumber ponds, sediments, seawater, and organisms constitute a complete ecological system, and this system has a self-regulating effect; the environment affects algae growth and the algae growth affects the environment (Tang et al., 2013). During summer and autumn, the biomass of C. valida was highest, and C. valida even bloomed, which may have been due to changes in the salinity and pH of seawater.

The results of the field investigation showed that the biomass of C. valida was inversely proportional to the salinity and pH of seawater in the ponds. In the early stages, salinity and pH were higher, at which time the biomass of C. valida was low. As time progressed, salinity and pH decreased, while the biomass of C. valida increased rapidly. Salinity and pH reached their lowest values in September and August, respectively, whereas the biomass of C. valida peaked in September. In subsequent months, a rapid increase in seawater salinity and pH was accompanied by decreases in C. valida biomass. These observations show that the algae grew even before the ecological environment was most suitable for their rapid growth, and the previous environmental conditions may have provided the impetus for their rapid growth. In the ecosystem of sea cucumber aquaculture ponds, the high salinity and the high pH during the period of low biomass of C. valida may have laid the foundation for rapid growth in the next few months. In addition to the changes in pH and salinity, the increase in temperature during the summer months may have further accelerated the growth of C. valida. Many factors interact in the field environment, and it is difficult to isolate the effects of pH and salinity in the field, so laboratory experiments were conducted to verify the conclusions from the field experiments.

Static simulation in the laboratory

Salinity and pH are environmental factors that affect the growth of C. valida. Seawater salinity varies depending on the location of the sea, which affects the climate (Lin et al., 2005). The main factors affecting salinity are precipitation and evaporation. Marine life living in estuaries is exposed to rapid changes in salinity and temperature, and these organisms generally have a wide range of salinity and temperature tolerance (Matsuyamaserisawa, Serisawa & Tanaka, 2004; Tsutsui et al., 2015). Tsutsui et al. (2015) found that Chaetomorpha sp. survived in salinities of 3.4–90.0‰. However, we found that when the salinity was 40%, the growth of C. valida was very low, and the length of the C. valida was relatively short. According to our data, the growth of C. valida was more rapid at salinities between 24‰ and 34‰ compared to other salinities. This result is in agreement with the field investigation, indicating that C. valida can grow rapidly in relatively high salinity, just like the salinity in sea cucumber ponds from January to May.

One of the most important physical and chemical parameters of aqueous solutions is pH, which is a measure of hydrogen ion concentration and is often referred to as the acidity and alkalinity of a solution. We showed that the growth of C. valida increased with increasing pH. According to our data, C. valida growth increased significantly at pH 7.5–8.5 compared to pH 6.5 and 7.0. This result indicates that C. valida can grow rapidly at the higher pH of the sea cucumber culture environment. However, algae have a strong buffering capacity for pH, possibly through carbon dioxide and nutrient metabolism. Thus, the proliferative activity of some algae species can change the pH of the water (Xu et al., 2009). The results of this experiment show that pH had an effect on the growth of C. valida, and C. valida blooms may change the salinity and pH of the seawater.

Fv/Fm is the maximum photochemical efficiency of Photosynthetic system II (PSII) in the dark or the maximal quantum yield of PSII. Fv/Fm reflects the intrinsic light intensity conversion efficiency (PSII), or the largest PSII light energy conversion efficiency (maximal PSII efficiency). Changes in Fv/Fm during normal growth of algae are very small and are not affected by the species and growth conditions. However, environmental stress conditions result in decreased Fv/Fm. The results of this study demonstrate that the Fv/Fm is maintained between 0.5 and 0.7 while C. valida is exposed to a wide range of salinity. When salinity was between 24% and 40%, C. valida maintained normal photosynthesis (Fv/Fm between 0.56 ± 0.003 and 0.69 ± 0.002). In contrast, when the pH was 6.5, the Fv/Fm value of C. valida eventually fell below 0.50, indicating that the photosynthesis of the C. valida was weak and not conducive to the growth of the algae. Under other pH conditions, the Fv/Fm value of C. valida was maintained at about 0.6, indicating that the photosynthesis of C. valida was stronger and favorable for the growth of algae. Many reports show that salinity and pH affect the photosynthesis of algae (Borlongan et al., 2016). The results of this experiment show that C. valida is adaptable to the pH in the sea cucumber pond environment.

There are many factors affecting the growth of Chaetomorpha including temperature, light, nutrients, salinity, pH, and CO2 (Gao, Endo & Agatsuma, 2018a, 2018b). The reported factors affecting the growth of C. valida are temperature and light (Deng et al., 2012). In the course of our research, we found that in addition to temperature and light, salinity and pH had a significant effect on the growth of C. valida. Other factors will be studied in subsequent research, including nutrients and sediment in sea cucumber ponds.

Conclusion

In a field survey, we demonstrate that the growth of C. valida, a species of filamentous green tide macroalgae, is closely related to the salinity and pH in the seawater from ponds in which sea cucumber are grown. The high salinity and the high pH during the period of low biomass of C. valida may lay the foundation for its rapid growth in the next few months. The results of laboratory experiments verified that salinity and pH were the two main factors that affected the growth of C. valida. At the same time, the results show that C. valida can bloom in sea cucumber ponds despite the relatively high salinity and high pH compared to coastal sea water.

Supplemental Information

Field survey raw data and data analysis.

DOI: 10.7717/peerj.6468/supp-1

Lab experiment raw data and data analysis.

DOI: 10.7717/peerj.6468/supp-2
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