Apple Pollination: Demand Depends on Variety and Supply Depends on Pollinator Identity

M. P. D. Garratt; T. D. Breeze; V. Boreux; M. T. Fountain; M. McKerchar; S. M. Webber; D. J. Coston; N. Jenner; R. Dean; D. B. Westbury; J. C. Biesmeijer; S. G. Potts

doi:10.1371/journal.pone.0153889

Abstract

Insect pollination underpins apple production but the extent to which different pollinator guilds supply this service, particularly across different apple varieties, is unknown. Such information is essential if appropriate orchard management practices are to be targeted and proportional to the potential benefits pollinator species may provide. Here we use a novel combination of pollinator effectiveness assays (floral visit effectiveness), orchard field surveys (flower visitation rate) and pollinator dependence manipulations (pollinator exclusion experiments) to quantify the supply of pollination services provided by four different pollinator guilds to the production of four commercial varieties of apple. We show that not all pollinators are equally effective at pollinating apples, with hoverflies being less effective than solitary bees and bumblebees, and the relative abundance of different pollinator guilds visiting apple flowers of different varieties varies significantly. Based on this, the taxa specific economic benefits to UK apple production have been established. The contribution of insect pollinators to the economic output in all varieties was estimated to be £92.1M across the UK, with contributions varying widely across taxa: solitary bees (£51.4M), honeybees (£21.4M), bumblebees (£18.6M) and hoverflies (£0.7M). This research highlights the differences in the economic benefits of four insect pollinator guilds to four major apple varieties in the UK. This information is essential to underpin appropriate investment in pollination services management and provides a model that can be used in other entomolophilous crops to improve our understanding of crop pollination ecology.

Citation: Garratt MPD, Breeze TD, Boreux V, Fountain MT, McKerchar M, Webber SM, et al. (2016) Apple Pollination: Demand Depends on Variety and Supply Depends on Pollinator Identity. PLoS ONE 11(5): e0153889. https://doi.org/10.1371/journal.pone.0153889

Editor: Hiroshi Ezura, University of Tsukuba, JAPAN

Received: October 1, 2015; Accepted: April 5, 2016; Published: May 6, 2016

Copyright: © 2016 Garratt et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: Data is available through the University of Reading 'Research data archive' at DOI: http://dx.doi.org/10.17864/1947.50.

Funding: This research was carried out as part of the Insect Pollinators Initiative funded jointly by a grant from British Biological Science Research Council, Department for the Environment Farming and Rural Affairs, Natural Environment Research Council, the Scottish Government and the Wellcome Trust, under the Living with Environmental Change Partnership BB/I000275/1. The Worshipful Company of Fruiterers, Sainsbury’s Supermarkets Ltd, Waitrose and Fruition funded some of the surveys involved in the analysis. These funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. Avalon Produce also provided support in the form of salaries for authors, but did not have any additional role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript. The specific roles of these authors are articulated in the ‘author contributions’ section.

Competing interests: One of the authors works for Avalon Produce, but this does not alter the authors' adherence to PLOS ONE policies on sharing data and materials.

Introduction

Insect pollination is a key ecosystem service for agriculture, influencing the productivity of ~75% of crop species [1] and contributing ~$361bn to global crop markets in 2009 [2]. The area of insect pollinated crops has grown substantially in recent decades, resulting in greater demands for pollination services [3]. In the UK, evidence suggests that supplies of pollination services, both from managed honeybees [4] and wild pollinators [5,6], do not match these increasing demands. Of the insect pollinated crops grown in the UK, apples (Malus domestica) are among the most valuable per hectare and as a self-incompatible crop which requires pollen from other compatible varieties (known as pollinisers) to set fruit, insect pollination services are essential to attaining profitable yields in apples [7]. Garratt et al. [8] recently demonstrated that by affecting both the quality and quantity of apples produced, pollination services underpinned ~65% of market output per hectare in two important apple varieties (Cox and Gala).

Managed European honeybees (Apis mellifera) can be used as pollinators in large commercial orchards to improve productivity [9,10]. A number of wild insects are also thought to be significant pollinators [11–14]. Notably, mason bees (e.g. Osmia spp.), mining bees (e.g. Andrena spp.) and bumblebees (Bombus spp.) have all been demonstrated to be effective pollinators of apples and, in some cases, more effective than honeybees [12,15–17]. Surveys of pollinator communities visiting UK Cox apple orchards suggest that wild pollinators form the majority of visitors [18], however, there has not been a systematic assessment of the relative pollination service contribution made by different pollinator guilds to apple orchards, or an estimation of the relative economic benefits of different pollinating taxa.

There are examples where crop pollination services do not meet the demand of the crop, resulting in yield and quality deficits [19–21] and sparking interest in the possible economic benefits of increasing pollinator populations. Previous research has shown that outputs in UK Gala orchards could be limited by sub-optimal pollination by ~£6,500/ha [8]. Therefore, improving pollinator management in this crop could provide significant economic returns. How pollinator dependence and possible yield deficits vary between different crop varieties is a fundamental question when considering the economic benefits and management of crop pollinators. Impacts of variety on pollination has only been investigated in a few crops including oilseed [22], blueberry [23] and strawberries [24].

In order to sustainably intensify crop production and meet growing global food demands, it is essential to understand the influence of ecological functions on yield [25]. For insect pollinated crops such as apples, this includes quantifying the impacts of insect pollination services and identifying which species are the most important service providers so they can be appropriately protected and managed. Few studies have considered how crop variety affects dependence on insect pollination or indeed how crop variety affects visitation by different pollinators. Furthermore, although the economic benefits of insect pollinators to crop production have been estimated many times, few studies have estimate the relative economic benefits of different taxa to a single crop. In order to assess the relative importance of different pollinators to different varieties of a crop, this study utilises a combination of pollinator effectiveness measures, visitor observational data and measures of crop dependency to evaluate the supply of pollination service provided by four major pollinator guilds (honeybees, bumblebees, solitary bees and hoverflies) to four UK apple varieties (Cox, Gala, Bramley and Braeburn). In doing so we have: (1) quantified the relative effectiveness of four pollinators to a major UK crop; (2) provided a unique appraisal of the variation in pollination service supply provided by different pollinator guilds across four varieties of a single crop; (3) quantified the demand for insect pollination services of these varieties; and (4) estimated the economic benefits of each pollinator guild to UK production of each variety.

Materials and Methods

Pollinator effectiveness

To compare the ability of different pollinators to pollinate apple flowers, both pollinators and apple trees were manipulated using insect flight cages. Four potential pollinators were chosen: the honeybee (Apis mellifera), a bumblebee (Bombus terrestris-audax), a solitary mason bee (Osmia bicornis) and a hoverfly (Episyrphus balteatus) and their ability to pollinate Malus domesticas var. Scrumptious was studied. This variety was selected because a smaller, potted variety was necessary for use in cage studies. As apples are self-incompatible, a donor variety, Evereste, was also present in all cages. These pollinators represent four distinct flower visiting insect guilds which may provide important pollination services in apple orchards [18]. To manipulate trees and pollinators, insect-proof flight cages were constructed at the University of Reading and University of Leeds experimental farms, using 2.4 x 2.1m frames covered with a polyethylene mesh with a gauge size of 1.33mm. During experiments, each pollinator species was housed in separate flight cages. Each pollinator was provided with appropriate nesting and forage resources within the flight cage when not directly involved in experiments, thus encouraging natural behaviour for the period of experimentation. The honeybees, through the use of a double entrance hive, were given access both to the flight cage and the outside, which could be controlled as needed.

Study trees (variety: Scrumptious and variety: Evereste) were kept in 25L pots. During experiments (spring 2012 and 2013) trees were 2.5 and 3.5 years old respectively and fully productive. When in flower, but not directly involved in experiments, the trees were stored inside isolation flight cages to avoid any interaction with potential pollinators.

Pollination experiments involved placing two flowering polliniser trees (Evereste) into flight cages with each of the four pollinator species. The experiment began when a single apple tree (Scrumptious) was placed in the flight cage. This experimental apple tree was then observed continuously and any insect visits to flowers were recorded by marking a dot on the petal of flowers which received individual visits. This was continued until at least three flowers on that apple tree had received five visits. Each flower which had received a visit was marked with a coloured cable tie; different colours were used to denote flowers which had received a different number of visits (between one and five). The total number of flowers which received each visit number was recorded for each tree. The tree was then stored in an isolation cage until fruit harvest. Pollination experiments were carried out at the end of April and beginning of May in 2012, and mid-May in 2013. The availability of flowering apple trees, polliniser trees and active pollinators enabled 18 trees to be pollinated by bumblebees, 11 by honeybees, three by hoverflies and 13 by solitary bees with a total of 1,831 flowers involved in the study.

In September of each experimental year when apples were ripe, a fruit set measurement was taken. The number of fruit remaining on each tree for each visit number and the original number of flowers which received that number of visits was used to calculate a percentage fruit set for each visit number per tree. During apple development, to prevent damage to trees, non-experimental apples and a small number of experimental fruit were removed from heavily laden branches. Size (max width cm), weight (g) and seed number per apple was measured.

Pollinator visitation

To compare the flower visitation of different pollinators to different apple varieties, we combined data from a number of UK apple pollinator surveys. Surveys were carried out in Cox, Bramley, Braeburn and Gala orchards in the top fruit growing region of Kent, UK between 2011 and 2014. The owners of the orchards from which data was collected gave permission to conduct the study on these sites. All surveys were carried out in conventionally managed orchards, of varying tree age, surrounded by plantations of other varieties of apple and varying amounts of semi-natural habitat. Orchards of different apple varieties were distributed across data sets and different varieties were often sampled on the same farms, therefore we anticipate no confounding effects of location on pollinators observed visiting flowers of different varieties. Honeybees were not typically utilised for pollination in the orchards although five hives were located close to one of the Gala orchards involved in the surveys. Surveys involved stationary tree observations or mobile transects within the orchards depending on the study (Table A in S1 File). Visitors to apple flowers were recorded to broad taxonomic groups and for transect surveys, where possible, caught and taken back to the laboratory for identification to species.

Pollinator dependence

To measure the dependence of apple production on insect pollination, three Bramley and two Braeburn orchards were used for experimental trials in 2013. Bramley is the most common variety of culinary apple grown in the UK, accounting for >90% of planted culinary apple area [26]. Braeburn is the third most widely grown dessert apple variety after Cox and Gala, with over 500ha planted as of 2012 [27]. The owners of the orchards from which data was collected gave permission to conduct the study on these sites. Within each of the orchards, three centrally located rows were selected, and on those rows, 10 trees at least 25 m from the orchard edge were involved in the study. Shortly before flowering, two branches on each tree were selected and randomly assigned to one of two treatments: an open treatment and a pollinator exclusion treatment. The pollinator excluded branches were covered with a PVC mesh bag with a mesh size of 1.2 mm² which are wind and rain permeable, but exclude visitation by insects. The number of flowers receiving each treatment was then recorded. When flowering had finished at all sites, bags were removed and the branches were marked with coloured cable ties and string so they could be located for harvest.

Prior to commercial thinning carried out in the orchards (early July), a visit was made to each site. For each branch, the number of set apples was recorded. The apples on each branch, which included any experimental inflorescences, were then thinned according to standard industry practice whereby apples from experimental inflorescences were removed so no more than two remained on any one inflorescence. At the end of the season, all apples from experimental inflorescences were collected one day to a week before commercial harvest (early September for Bramley and late October for Braeburn). Apples were bagged individually by treatment, tree, row and orchard and taken back to the laboratory for quality assessment. Industry standard quality measures for classifying apples for market were taken for all apples collected.

Seed number and maximum width of each apple was recorded. Apples were then scored for shape, either classified as ‘normal’ or ‘deformed’ if there was any shape irregularity. To calculate the economic benefits of pollination to each variety, apples were classed using parameters utilised in the industry (Jenner, 2014 pers. comm.). Apples were classified as class 1 or 2 based on size and shape. Class 1 Braeburn apples are those with no shape deformities and a width greater than 60 mm. Class 1 Bramley apples are between 80–100 mm wide and all other sizes were class 2.

Using the same methodology, the dependence of Cox and Gala apples, and the resultant economic contribution of pollination to profit, had been established in a previous study [8]. These data are analysed in conjunction with data on Bramley and Braeburn for the subsequent economic analysis and pollinator contribution estimates. Data for all four varieties are presented together for the remainder of the manuscript.

Economic analysis

The economic benefits of pollination services to producers were calculated for each variety following the methods in Garratt et al. [8] by comparing fruit set and quality after commercial thinning, from open pollinated and pollinator excluded treatments. For each treatment, the estimated monetary output of apples produced (£/ha) was calculated with respect to two commercial quality classes using average weekly prices for 2012 from DEFRA [28]. Differences in labour costs, the only cost factor expected to vary by yield, were estimated as the percentage change in the number of apples produced in each treatment multiplied by industry standard costs (Jenner, 2013 pers. Comm.). The impacts of pollination services on output are therefore the differences in the output of apples, less the differences in labour costs from the two treatments (both £/ha). The estimated net change in output was extrapolated to a national scale using the 2012 area of Braeburn and Gala reported in DEFRA [27] and the 2012/2013 area data from DEFRA [26] for Cox and Bramley. In this manuscript we also update the estimated economic benefits of pollination services to Cox and Gala apples reported in Garratt et al. [8] by using 2012 area data alongside 2012 prices. For completeness, results for Gala, Cox, Braeburn and Bramley are reported together for the remainder of the manuscript.

Pollinator contribution

The contribution of different pollinator guilds to Bramley, Braeburn, Gala and Cox production in the UK was calculated by incorporating pollinator effectiveness, pollinator visitation in the field and the economic benefits of insect pollination to each variety of apple. The effectiveness (E) of each pollinator guild (i) was estimated based on a product of the fruit set (F) and seed set (S) resulting from three visits by the taxa to apple flowers in the cage study. Three visits were chosen given that, in the field, apple blossoms can expect a varying number of floral visits and previous research has shown that assuming an apple blossom is receptive for approximately three days and pollinators may be most active for about 6 hours on those days, between two and three visits per flower is a realistic number of visits that one blossom may receive from these pollinators [18]. Given the significant interactive effect of visit number on the pollination effectiveness of our pollinator guilds we also carried out the same economic assessment assuming pollination effectiveness following a single visit. This may better reflect pollinator contributions in years with low overall visitation rates to flowers (Table B in S1 File). The relative pollination service contribution (R) of each guild to each variety (v) was calculated as the effectiveness of each guild, multiplied by the observed visitation rate of all members of the guild (T) divided by the effectiveness and visitation rate of all observed pollinators. The standard deviation of the relative pollination service contribution across all sites was taken as a measure of variance.

Where E_i = (F_i × S_i)

This percentage was then used to calculate the monetary contribution of each pollinator (GP) to each apple variety based on the economic benefits of insect pollination to each variety (PB).

As Bombus terrestris, Osmia bicornis and Ephyserphis balteatus may not be representative of the effectiveness of their pollinator guilds as a whole, the economic analysis was re-conducted using only the relative visitation rates of the guild (GT) to each variety without weighting visits by the pollination service effectiveness (Table C in S1 File).

Statistical analysis

Pollinator effectiveness was analysed using generalised linear mixed effects models to understand effects of pollinator and visit number (1–5) on fruit set and seed set in Scrumptious apples. Pollinator, visit number and their interaction were included in the model as fixed effects; year (2012, 2013), location (Reading, Leeds) and tree were random effects. Fruit set is a proportional response thus a binomial error structure was specified, and seed set is a count so a Poisson error structure was used. Apple width and weight were normally distributed and analysed using linear mixed effects models with the same fixed and random effects as for fruit set and seed number.

Orchard pollinator visitation data were analysed using a generalised linear mixed effects model with pollinator guild (honeybee, bumblebee, hoverfly, solitary bee and other), apple variety (Cox, Gala, Bramley and Braeburn) and a pollinator:variety interaction as main effects in the model. The number of pollinators observed visiting flowers on any given survey day was summed for the analysis so the response variable was a count and thus a Poisson error distribution was defined. Data set, year, survey round and site were included in the model as random effects. An observer level random effect was also included to account for overdispersion. A significant pollinator:variety effect was found so each variety was analysed separately using the same generalised linear model with appropriate random effects as necessary for each data set. Again an observer level random effect was used to account for overdispersion. A Tukey comparison from the ‘multcomp’ R package was used to investigate significant differences between pollinator guilds within varieties.

The dependence of different varieties on insect pollination was analysed using generalised linear mixed effects models to investigate pollination treatment effects on fruit set and seed number. Pollination treatment (open and pollinators excluded) was a fixed effect with tree, nested within row, nested within orchard as random effects. Seed number and fruit set had a Poisson and binomial error structure defined, respectively. A linear mixed effects model with the same fixed and random effects as for the generalised linear mixed effects model was used to analyse apple width. Braeburn width was transformed before analysis. All statistical analysis was carried out in R version 3.2.2.