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Apples before the fall: Does shape stability coincide with maturity?

Published online by Cambridge University Press:  30 April 2021

Maria D. Christodoulou*
Affiliation:
Department of Statistics, University of Oxford, Oxford, United Kingdom University of Reading Herbarium, School of Biological Sciences, University of Reading, Reading, United Kingdom
Alastair Culham*
Affiliation:
University of Reading Herbarium, School of Biological Sciences, University of Reading, Reading, United Kingdom
*
*Authors for correspondence: M. D. Christodoulou, E-mail: [email protected]; and Alastair Culham, E-mail: [email protected]
*Authors for correspondence: M. D. Christodoulou, E-mail: [email protected]; and Alastair Culham, E-mail: [email protected]

Abstract

Fruit shape is the result of the interaction between genetic, epigenetic, environmental factors and stochastic processes. As a core biological descriptor both for taxonomy and horticulture, the point at which shape stability is reached becomes paramount in apple cultivar identification, and authentication in commerce. Twelve apple cultivars were sampled at regular intervals from anthesis to harvest over two growing seasons. Linear and geometric morphometrics were analysed to establish if and when shape stabilised and whether fruit asymmetry influenced this. Shape stability was detected in seven cultivars, four asymmetric and three symmetric. The remaining five did not stabilise. Shape stability, as defined here, is cultivar-dependent, and when it occurs, it is late in the growing season. Geometric morphometrics detected stability more readily than linear, especially in symmetric cultivars. Key shape features are important in apple marketing, giving the distinctness and apparent uniformity between cultivars expected at point of sale.

Type
Original Research Article
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - SA
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike licence (http://creativecommons.org/licenses/by-nc-sa/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the same Creative Commons licence is included and the original work is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use.
Copyright
© The Author(s), 2021. Published by Cambridge University Press in association with The John Innes Centre

1. Introduction

Shape development in plant organs is the product of a highly complex series of interacting molecular, biochemical and environmental pathways. At the starting point, shape development and diversity are controlled by genetics. For example, the tomato fruit shape, which has great diversity due to domestication and improvement processes, is controlled by four genes (Azzi et al., Reference Azzi, Deluche, Gevaudant, Frangne, Delmas, Hernould and Chevalier2015). Two of these (OVATE and SUN) control fruit elongation whereas the other two (FASCIATED and LOCULE NUMBER) control locule numbers (Azzi et al., Reference Azzi, Deluche, Gevaudant, Frangne, Delmas, Hernould and Chevalier2015). The combination of mutations in these four genes can result in the domesticated tomato shape ranging from spheroid to flat and obovoid (Monforte et al., Reference Monforte, Diaz, Cano-Delgado and van der Knaap2014).

Aside from genetic effects, shape development is also impacted by phenotypic plasticity. Phenotypic plasticity is defined as the morphological, phenotypical or behavioural changes that are caused as a direct response to environmental stimuli (Price et al., Reference Price, Qvarnström and Irwin2003). There are multiple examples of shape change as an environmental response in both plants and animals. In a study of Datura wrightii hort. ex Regel floral shape, phenotypic plasticity was demonstrated as a response to watering regime (Elle & Hare, Reference Elle and Hare2002). In a common-garden experiment, plants that were watered twice a week had consistently longer corollas compared with plants that received only rainfall (Elle & Hare, Reference Elle and Hare2002). In a range of ecotypes of Arabidopsis thaliana (L.) Heynh., leaf shape is reportedly altered when light levels are reduced, presenting smaller leaves and longer petioles (Tsukaya, Reference Tsukaya2006).

Even though phenotypic plasticity is well recorded, there are processes counteracting the environmental impact on the phenotype, specifically two buffering processes that promote phenotypic stability have been described (Willmore et al., Reference Willmore, Klingenberg and Hallgrimsson2005). Canalisation is described as the ability of an organism to buffer against both environmental and genetic variation in order to maintain phenotypic stability (Breuker et al., Reference Breuker, Patterson and Klingenberg2006). On the other hand, developmental stability is the ability of an organism to buffer against random variation in order to maintain phenotypic stability (Willmore et al., Reference Willmore, Klingenberg and Hallgrimsson2005). The two mechanisms, although clearly defined, are difficult to isolate in developmental work. In a study of Drosophila melanogaster Meigen wing shape and size, Breuker et al. (Reference Breuker, Patterson and Klingenberg2006) demonstrated the possibility that the two buffering pathways were fundamentally parts of a single process. Examples of developmental buffering have been described in both animals and plants. Tsukaya (Reference Tsukaya2003) reported that in A. thaliana, manipulation of cell size and numbers in developing leaves was to a certain degree buffered in order to produce a stable phenotype. Manipulation of cell division rates in Pelargonium leaves demonstrated a mechanism where the faster dividing cells compensated for the slower dividing ones, resulting in a consistent shape (Day & Lawrence, Reference Day and Lawrence2000).

Shape is a major morphological descriptor of an organism; as such shape stability and by extension morphological stability, become fundamental biological concepts. This is even more so for cultivars which are distinguished by multiple but often very minor morphological differences. A key element of cultivar description is variation in size and shape. As opposed to species, cultivars have a very clear definition, a fact primarily due to the man-made nature of cultivars. Cultivars are described based on the selection of particular characters and these characters are required to be distinct, uniform and stable (Brickell et al., Reference Brickell, Alexander, David, Hetterscheid, Leslie, Malecot, Jin and Cubey2009). If a cultivar, therefore, is described based on particular morphological characters (which could include shape) then there is a requirement for stability of these characters. Differences in commercial value of cultivars within a species can be substantial which gives rise to the need for confident identification of individual cultivars (Christodoulou et al., Reference Christodoulou, Battey and Culham2018; Christodoulou et al., Reference Christodoulou, Clark and Culham2020).

Closer to the focus of this work, there have been a number of studies on the effect of environmental conditions on apple fruit growth and development. McKenzie (Reference McKenzie1971), in a general survey of apple fruit shape in New Zealand, recorded differences in shape between apples of the same cultivar grown in the north and south of New Zealand. In a study of light quality effect on ‘Golden Delicious’ apples, Noè and Eccher (Reference Noè and Eccher1996) established that light levels and quality can affect both fruit shape and russeting. On the other hand, when Tromp (Reference Tromp1990) studied the environmental effects on fruit shape of ‘Cox’s Orange Pippin’ using controlled environment rooms he found no significant differences. What makes this finding particularly interesting is that the environment was controlled for all the trees from anthesis onwards. It is therefore possible that the phenotypic plasticity recorded by McKenzie (Reference McKenzie1971) was due to environmental differences prior to anthesis. This is of interest because it has been recorded that the effect of the OVATE gene in tomatoes is established prior to anthesis (Monforte et al., Reference Monforte, Diaz, Cano-Delgado and van der Knaap2014). Although it is not argued that the apple will have the same mechanisms as the tomato, both are climacteric domesticated fruit therefore similarities are possible. Since, the first whole genome iteration for apples was released (Velasco et al., Reference Velasco, Zharkikh, Affourtit, Dhingra, Cestaro, Kalyanaraman, Fontana, Bhatnagar, Troggio, Pruss, Salvi, Pindo, Baldi, Castelletti, Cavaiuolo, Coppola, Costa, Cova, Dal Ri and Viola2010), characters such as ripening, pedigree origins, and leaf morphology have been studied, making the genetic basis of fruit shape an expected future topic of study by horticultural geneticists (Migicovsky et al., Reference Migicovsky, Li, Chitwood and Myles2018; Muranty et al., Reference Muranty, Denancé, Feugey, Crépin, Barbier, Tartarini, Ordidge, Troggio, Lateur, Nybom, Paprstein, Laurens and Durel2020; Peace et al., Reference Peace, Bianco, Troggio, van de Weg, Howard, Cornille, Durel, Myles, Migicovsky, Schaffer, Costes, Fazio, Yamane, van Nocker, Gottschalk, Costa, Chagné, Zhang, Patocchi and Vanderzande2019).

Apple fruit are therefore seen to be subject to variation caused by environmental factors as well as due to genetic differences. Despite this variation, there appears to be sufficient buffering to ensure that apple fruit can be identified to cultivar by appearance with a reasonable degree of accuracy (>77%, Christodoulou et al., Reference Christodoulou, Battey and Culham2018) which is further evidenced by the fact that the widely sold apple cultivars seen in supermarkets look much the same throughout the year whether they are sourced from UK, South Africa, Spain, Chile or New Zealand. Supermarket fruit are subject to quality selection and so are more homogeneous in morphology than random samples from an orchard. If environment has a greater influence than genotype such fruit homogeneity would not be achievable by supermarkets.

Traditionally, apple fruit shape was described by comparison with a standard geometric object (Bultitude, Reference Bultitude1983). Examples of the possible shape categories included: oblong, conical or round (Clark & Cleal, Reference Clark and Cleal2005). This practice, which is still common in both identification keys and collection curation tools, aimed to summarise the extensive variety of shapes by grouping using a collection of predefined geometrical shapes (Sanders, Reference Sanders2010). In order to quantify shape, Westwood (Reference Westwood1962) used the ratio between length and diameter (L/D) of the fruit. Using the L/D ratio as a proxy for shape, Westwood (Reference Westwood1962) suggested that shape for apple cultivars stabilised between Day 60 and Day 100 from anthesis. The use of the L/D ratio has both benefits and limitations. By using measurements in two perpendicular axes, it facilitated the description of the overall shape in two dimensions. It also permitted the comparison between shapes, with ratios below 1 indicating a fruit that is wider than long and vice versa.

The description of ratios is easy to communicate, and intuitive but there are analytical concerns which arise from such use. First, a ratio of two normally distributed variables is not necessarily normally distributed (Atchley et al., Reference Atchley, Gaskins and Anderson1976). This means that a ratio may not be suitable for analysis using parametric techniques, which assume normality. Second, ratio use is inherently paradoxical: if the variables in the ratio are unrelated, the ratio calculation creates a relationship (Curran-Everett, Reference Curran-Everett2013). If, on the other hand, the two variables are related, the ratio calculation will only successfully demonstrate this relationship if it is linear and crosses the origin (Jackson et al., Reference Jackson, Harvey and Somers1990). Third, ratio use can give rise to spurious correlations if the two variables used are both affected by a common confounding factor (Tu et al., Reference Tu, Law, Ellison and Gilthorpe2010). These three issues can be avoided, while still using length and diameter measurements as shape proxies, by performing an analysis of covariance (Tu et al., Reference Tu, Law, Ellison and Gilthorpe2010).

In this work, we aim to investigate if and when fruit shape stabilises for apple cultivars, whether the timings of this are cultivar-dependent, and if shape stability timings as described through linear morphometrics differ from those described through geometric morphometrics. These findings will have immediate commercial application to the marketing of apple cultivars harvested prior to full physiological maturity.

2. Materials and methods

2.1. Sample collection

Twelve apple cultivars were sampled throughout the 2013 growing season at regular intervals, beginning at 2 weeks from flowering (anthesis) and ending when the orchard’s pickers deemed the fruit ripe for eating. Ten fruit per cultivar were collected at every sampling point with the exception of the last harvest were 20 fruit were collected. Anthesis for the orchard in 2013 occurred on June 10, 2013. All fruit were collected from the National Fruit Collection, in Brogdale, Kent, UK. In 2014, 6 of the 12 cultivars were randomly selected to be resampled. Anthesis for 2014 occurred on 1May 15, 2014. A full list of cultivars and their sampling times are available in the Supplementary Materials.

2.2. Morphometric data collection

Measurements of length and diameter (linear morphometrics), and geometric morphometrics for each sample were collected as described in Christodoulou et al. (Reference Christodoulou, Battey and Culham2018). Geometric morphometrics were only collected for the 2013 season. The chosen landmarks and linear morphometrics are summarised in Figure 1.

Fig. 1. Example images for Adam’s Pearmain, digitised landmarks and linear morphometrics used on the sampled fruit. Six landmarks were selected per sample: two on the crown apices, one on the calyx, one on the pedicel attachment point and two on the shoulder apices. Maximum length and diameter were measured using precision callipers.

2.3. Shape development analysis

Analysis of Covariance (ANCOVA) was performed for each cultivar to examine how sampling week interacts with the correlation between length and diameter. To detect stability of shape for two sampling weeks, their slopes and intercepts had to be found not to be significantly different.

For the geometric morphometrics, regression for allometric effect was performed on MorphoJ (Klingenberg, Reference Klingenberg2011) and if found to be significant, analysis proceeded using the regressed dataset (Klingenberg & Marugán-Lobón, Reference Klingenberg and Marugán-Lobón2013; Openshaw & Keogh, Reference Openshaw and Keogh2014). If not, the dataset prior to allometric correction was employed. The allometric analysis step was performed to establish whether the effect of size was significant to the variation between samples. If the results were found to be significant, the dataset was corrected to exclude the variation that was explained by size. After removing the variation that was explained by size, the remaining variation between samples was attributed to shape differences. If the allometric analysis indicated that the effect of size was not significant for the variation between samples, the correction was not necessary and the data prior to regression were used. A canonical variates analysis (CVA) was performed using harvest times as the classifier followed by a permutation test (10,000 permutations). The p-values of the Mahalanobis distances of the permutation test were used to establish shape differences between weeks (Zelditch et al., Reference Zelditch, Swiderski, Sheets and Fink2004).

2.4. Asymmetry analysis

To study whether differences in shape stability between cultivars were linked to fruit asymmetry, Procrustes ANOVAs were performed on the selected landmarks for the final harvest images for each cultivar (Klingenberg et al., Reference Klingenberg, Barluenga and Meyer2002). In each case, the axis of asymmetry was selected to pass through the calyx and pedicel landmarks. The two halves were compared with each other to establish whether there was statistical evidence of systematic asymmetry.

3. Results

3.1. Linear morphometrics

Only 3 of the 12 cultivars stabilised prior to the last harvest. These were ‘Adam’s Pearmain’ (stable from Week 12 until Week 15), ‘Beacon’ (stable from Week 9 until Week 12) and ‘Wheeler’s Russet’ (stable from Week 12 until Week 17 in 2013, and Week 12 until 18 in 2014). All other cultivars demonstrated significant differences in the intercepts for the final sampling weeks. All code and model results are available as an R project, in the Supplementary Materials.

3.2. Geometric morphometrics

When studied for allometry, 11 out of 12 cultivars demonstrated a significant allometric effect. The only cultivar that did not present a significant allometric effect was ‘Beacon’, and in this case, the original data were not corrected for allometry. The remaining 11 cultivars were all corrected for allometry prior to further analysis. The percentage of variation explained by size as well as the associated p-values are summarised in Table S1, in the Supplementary Materials.

Each cultivar was studied using a CVA with harvesting times as the grouping factor. This was followed by a permutations test that compared the differences between all possible harvesting time combinations. The p-values from the 10,000 permutations test on the Mahalanobis distances were recorded for each harvest comparison. As the focus of this analysis was on the stability of shape between at least penultimate and ultimate harvests, only those comparison results are summarised in Table 1 below. Results from all other harvest comparisons can be found in the Supplementary Materials.

Table 1 Summary of canonical variates analyses results between penultimate and ultimate harvests for the 12 studied cultivars

The p-values from the 10,000 permutations tests on the Mahalanobis distances are reported for each comparison (star significance in brackets).

Shape stability for 2013, using both linear and geometric morphometrics, is summarised in Figure 2. Shape stability for the six cultivars repeated in 2014, using linear morphometrics, is summarised in Figure 3.

Fig. 2. Shape stability status per Week/Cultivar for the 2013 growing season. Stability detection through linear morphometrics indicated in purple (pale for fluctuating shape and dark purple for stable shape), and geometric morphometrics in green (pale for fluctuating shape and dark green for stable shape). Asymmetric cultivars indicated with an asterisk after the cultivar name. Weeks are measured from flowering (anthesis). The two early season cultivars (‘Beacon’ and ‘Red Fortune’) are placed on the top of the chart. All other cultivars are main season cultivars.

Fig. 3. Shape stability status per Week/Cultivar for the 2014 growing season. Stability detection for that year was only conducted through linear morphometrics (pale purple for fluctuating shape and dark purple for stable shape). Asymmetric cultivars indicated with an asterisk after the cultivar name. Weeks are measured from flowering (anthesis). All cultivars are main season cultivars.

The impact of the linear versus geometric morphometrics used to describe potential fruit shape stability can be observed in Figure 1. Whether stability happens and when it occurs matches on half of the tested cultivars for the two techniques. Five out of these six cultivars do not demonstrate shape stability as defined here (‘Bovarde’, ‘Kaiser Franz Joseph’, ‘Limoncella’, ‘Present van Engeland’ and ‘Rheinischer Krummstiel’). Shape stability using each method occurs at the same time only on ‘Wheeler’s Russet’. Cultivar ‘Beacon’ demonstrates shape stability for each of these methods but the point in time at which this is reached differs. For four of the remaining cultivars, stability is detected through geometric and not through linear morphometrics (‘Boiken’, ‘Catshead’, ‘Fuji’ and ‘Red Fortune’). Shape stability was detected through linear morphometrics and not geometric only for ‘Adam’s Pearmain’.

Results from the symmetry analysis are in Table 2. Of the 12 cultivars, 5 were asymmetric and seven symmetric.

Table 2 Symmetry analysis results for harvest week samples

Significant p-values (star significance in brackets), suggest substantial differences between the two sides of the fruit, indicating asymmetry.

Summary results for stability detection and presence of symmetry are in Table S2 of the Supplementary Materials. Overall, presence of stability in symmetric cultivars was detected only through geometric morphometrics. For asymmetric fruit, both methods perform similarly.

4. Discussion

Our results highlight two clear outcomes:

  1. 1. The method used to quantify shape impacts on our ability to describe and detect shape stability.

  2. 2. Shape stability, when it happens, occurs late in the season and is cultivar dependent.

The earliest time when stability is first detected in any cultivar is Week 7 (‘Beacon’, 49 days from anthesis), and the latest time of first detection is during Week 12 (e.g. ‘Catshead’, 84 days from anthesis). In total, 7 of the 12 cultivars tested reach shape stability by at least one measure during this period. The remaining five cultivars do not achieve a stable shape by the time they are harvested based on our two approaches to measurement. This could be an accurate description of absence of stability or a consistent failure of either method to detect it. Comparing these findings with Westwood’s (Reference Westwood1962) original observations of shape stability occurring between Day 60 (Week 9) and Day 100 (Week 14) from anthesis, suggests that for the majority of cultivars we are detecting similar trends. Whether these patterns are representative of shape stability is more a question of the reliability of our definition of the phenomenon than the presence of significant differences between weeks.

We define shape stability under linear morphometrics by testing whether the regression between length and diameter for the last harvest is significantly different to the regression of the preceding week. This therefore depends on whether we consider length and diameter in combination to be sufficient shape descriptors. For the geometric morphometrics, the method in combination with a permutation test, uses the position of the six landmarks selected to detect whether there are significant differences between weeks. Again, the success of the method relies on whether we believe the six landmarks selected to be sufficient shape descriptors. Both linear and geometric morphometrics, as described here, were used as underlying data for a machine learning classification method aiming to identify apple cultivars, which achieved 77.8% accuracy on an unclassified test set (Christodoulou et al., Reference Christodoulou, Battey and Culham2018) As such, we believe that the shape descriptions used for both methods are reflective of the cultivar shape, therefore their use for evaluation of shape stability is justified. Shape stability is an important commercial factor in fruit sales because customers expect uniform fruit at the point of purchase.

Linear morphometrics rely on individual measurements, geometric morphometrics combine positions of multiple landmarks. Comparison of findings between the two techniques illustrates this fundamental difference. In the case of shape stability this would be illustrated by geometric morphometrics detecting stability more readily than linear ones. This is the case for five cultivars in this study. Shape stability for symmetric apples was detected only using geometric morphometrics, whilst shape stability for asymmetric apples was detected in three out five cultivars by geometric morphometrics and two out of five by linear morphometrics. This means that linear morphometrics is not an effective approach to detect shape stability in symmetric apples and that geometric morphometrics is effective for both.

Some cultivars (such as ‘Beacon’ and ‘Wheeler’s Russet’) stabilised in shape prior to the final harvest week, while others did not appear to do so (e.g. ‘Bovarde’ and ‘Rheinischer Krummstiel’). This suggests that shape stability is cultivar dependent. These findings are congruent with the 2014 follow-up collection for limited samples. In terms of growing practices, the National Fruit Collection followed identical growing protocols between the 2 years. No differences in pest presence or management were recorded between the 2 years and pollination levels were similar. The observable difference in the 2 years is weather. Specifically, 2013 was cooler and drier than 2014. As this resulted in no differences in which cultivar stabilised prior to harvest, we can hypothesise that stability of shape is not easily perturbed by weather, We find that to be an unexpected finding and therefore this hypothesis would have to be specifically tested, as it contradicted previous work. For example, McKenzie (Reference McKenzie1971) demonstrated that weather conditions can substantially affect shape in ‘Delicious’ apples grown in New Zealand. Studies on ‘Cox’s Orange Pippin’ suggested that cooler spring temperatures – such as the ones observed in 2013 – were associated with higher fruit yield by improving seed-set (Jackson et al., Reference Jackson, Hamer and Wickenden1983; Jackson & Hamer, Reference Jackson and Hamer1980). The fact that seed-set was affected by pre-anthesis temperatures is directly relevant to fruit shape as Drazeta et al. (Reference Drazeta, Lang, Hall, Volz and Jameson2004) demonstrated increased asymmetry on ‘Granny Smith’ apples due to seed-set success and seed weight. These led us to expect differences in fruit shape stability between the 2 years which we did not observe. The levels of ‘June drop’ (self-thinning immature fruit drop) were similar in the 2 years.

The observed shape stability differences between cultivars could be due to differences in developmental buffering. If the developmental stability or canalisation abilities differed between cultivars, then some would be less prone to reaching a stable shape than others. It is therefore possible that the environmental conditions under which all the cultivars were grown, affected the developmental buffering mechanisms to different degrees, resulting in shape stability for some cultivars and none for others. Measuring developmental buffering in morphometric studies often relies on the concept of fluctuating asymmetry (FA) (Klingenberg et al., Reference Klingenberg, Barluenga and Meyer2002). By measuring the differences between two structures in the same organism which are controlled by the same genetic mechanisms the stability of developmental process can be measured (Willmore et al., Reference Willmore, Klingenberg and Hallgrimsson2005). For example, if the asymmetry between the right wing and the left wing of a Drosophila is measured then the success of the developmental buffering for that Drosophila can be quantified. Since both wings were developed under exactly the same genetic, epigenetic and environmental conditions any differences between the two sides should be down to the buffering success of the organisms as a whole. Using FA as a measure of developmental buffering however may not be appropriate for apple fruit development. This is because the assumption of environmental stability between the two sides of the fruit may not hold. As apple fruit grow in clusters, the exposure of the individual fruit to the external environment varies. These different localised environmental conditions confound the developmental buffering. To measure developmental buffering for apples, we believe that a study needs to be conducted under strictly controlled environmental conditions, otherwise the environmental noise is likely to overcome the developmental signal.

We have previously shown that apples do not stop growing until they are harvested (Christodoulou & Culham, Reference Christodoulou and Culham2020). The mix of cultivars that show shape stability before harvest and those that do not, may be indicative of growth and development of individual fruit slowing sufficiently resulting in our metrics not detecting subtle changes as the fruit approach physiological maturity. The evidence that changes become increasingly subtle as maturity is reached is congruent with the fact that apple cultivars can be recognised from their distinct shapes and sizes at harvest. Contrasting our findings with earlier work on authentication of apples using harvest shape (Christodoulou et al., Reference Christodoulou, Battey and Culham2018), we note that there is no correlation in the success in identification and the cultivars that stabilised prior to harvest.

5. Conclusions

In this work, we aimed to establish if and when fruit shape of apple cultivars stabilises prior to harvesting, and whether the findings are impacted by the method used – contrasting linear and geometric morphometrics. We established that the consistency of our findings is method-dependent, with geometric morphometrics detecting stability more readily than linear morphometrics. Some cultivars never reached stability prior to harvest. Whether or not the shape stabilised, apple cultivars are geometrically different from each other such that they can usually be identified by their shape. Remarkably, apple cultivars can be identified with a high degree of success despite continued growth and sometimes continued shape change up until the point of harvest.

Acknowledgements

We thank Prof Nick Battey, Dr Matthew Ordidge, and the National Fruit Collection, Brogdale, Kent, for access to samples and assistance with sampling.

Financial support

This work was supported by BBSRC: 1132848, https://www.bbsrc.ac.uk/. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Conflict of interest

The authors declare no conflicts of interest.

Authorship contributions

M.D.C. was responsible for data curation, formal analysis, methodology, validation, writing of manuscript. A.C. was responsible for conceptualisation, funding acquisition, project administration, supervision and writing of manuscript.

Data availability statement

All data and code have been submitted as supplementary materials.

Supplementary Materials

To view supplementary material for this article, please visit http://dx.doi.org/10.1017/qpb.2021.5.

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Figure 0

Fig. 1. Example images for Adam’s Pearmain, digitised landmarks and linear morphometrics used on the sampled fruit. Six landmarks were selected per sample: two on the crown apices, one on the calyx, one on the pedicel attachment point and two on the shoulder apices. Maximum length and diameter were measured using precision callipers.

Figure 1

Table 1 Summary of canonical variates analyses results between penultimate and ultimate harvests for the 12 studied cultivars

Figure 2

Fig. 2. Shape stability status per Week/Cultivar for the 2013 growing season. Stability detection through linear morphometrics indicated in purple (pale for fluctuating shape and dark purple for stable shape), and geometric morphometrics in green (pale for fluctuating shape and dark green for stable shape). Asymmetric cultivars indicated with an asterisk after the cultivar name. Weeks are measured from flowering (anthesis). The two early season cultivars (‘Beacon’ and ‘Red Fortune’) are placed on the top of the chart. All other cultivars are main season cultivars.

Figure 3

Fig. 3. Shape stability status per Week/Cultivar for the 2014 growing season. Stability detection for that year was only conducted through linear morphometrics (pale purple for fluctuating shape and dark purple for stable shape). Asymmetric cultivars indicated with an asterisk after the cultivar name. Weeks are measured from flowering (anthesis). All cultivars are main season cultivars.

Figure 4

Table 2 Symmetry analysis results for harvest week samples

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Author comment: Apples before the fall: Does shape stability coincide with maturity? — R0/PR1

Comments

Dear Editor,

Please find our submission on development and stability of apple fruit shape during the growing season, as discussed in our recent email exchange.

Kind Regards,

Maria Christodoulou

Review: Apples before the fall: Does shape stability coincide with maturity? — R0/PR2

Conflict of interest statement

Reviewer declares none.

Comments

Comments to Author: The study applied linear and geometric morphometrics to determine fruit shape stability during apple fruit development. Key findings from the study are that geometric morphometrics is more effecive to detect shape stability than linear (mainly fruit length and diameter), especially for symetric fruits. The results concerning fruit descriptors provide some useful information for classification of apple fruits and cultivar authentication.

In general, fruit shape of most plant species is stable after the fruit enters ripening stages. In this study, fruit shape in only seven out of the twelve apple cultivars analyzed stabilized. The question is the extent of shape variations in the later fruit devlopment stages. If the shape changes are subtle though can be detected by these methods used in this study, shape stability offers very little help to cultivar identification and authentication in commerce. Do the authors have additional data (or fruit images) to support that shape stability is relevant to cultivar identification?

In the method section, how geometric morphometrics were collected and processed need more detailed description. The reference cited as Christodoulou et al (2018) is incomplete, no journnal and page information was provided. I even can’t find it in any database using the title listed. Also, page numbers were missing in few additional references.

Review: Apples before the fall: Does shape stability coincide with maturity? — R0/PR3

Conflict of interest statement

Reviewer declares none.

Comments

Comments to Author: The authors investigate fruit shape stability within and among twelve commercial apple cultivars, placing the investigation in the context of confident cultivar identification and the expectations of consumers for apple cultivars to have expected geometric shapes. The conclusions reached in the paper, i.e., methods affects the ability to describe and detect shape stability and that shape stability is cultivar dependent, has implications for the use of geometric morphometrics in plant identification beyond commercial issues. However, one limitation of the study is that it was conducted in only one common orchard (Brogdale, UK). It would be of considerable interest to know whether similar findings would be obtained if the study were repeated in other orchards in other climatic zones.

The paper introduction could be more clearly arranged. Currently, paragraphs are arranged as: genetics and fruit geometry; environment and leaf/ flower geometry; cultivar concepts; environment and fruit geometry; buffering and phenotypic stability; approaches to apple fruit description; and issues over the use of ratios. This arrangement separates ideas associated with apple cultivars, and the importance of the linkages among fruit geometry, genetics and environment are diminished.

In the Materials and Methods, it would be useful to have outlines of typical final fruit shapes for the 12 apple cultivars used (perhaps as part of Fig. 1). This would clarify the discussion of ‘symmetric’ and ‘asymmetric’ cultivars.

Ln 55: Cultivars need not be distinguished by single differences as implied by this line – a suite of differences may be used if they are contained within the cultivar description under the ICNCP. Ln 57 states that cultivars have a ‘very clear definition’, although this may be less so for top fruit, such as apples and pears, that have been cultivated, selected and bred for centuries.

Ln 77: ‘Exact same’ – change phrasing.

Lns 137-138: Replace ‘when the fruit was deemed ripe for eating by the orchard’s pickers’ to ‘when the orchard’s pickers deemed the fruit ripe for eating’.

Ln 313: ‘don’t’ to ‘do not’.

Review: Apples before the fall: Does shape stability coincide with maturity? — R0/PR4

Conflict of interest statement

Reviewer declares none.

Comments

Comments to Author: In the manuscript "Apples before the fall: does shape stability coincide with maturity?", Christodoulou et al. use Shape Development Analysis (Linear e and geometric morphometrics) and Asymmetry Analysis to establish if and when shape stabilized and whether fruit asymmetry influenced this. They then analyze 12 apple cultivars at regular intervals from anthesis to harvest over two growing seasons, and find that shape stability of apples, when it happens, occurs late in the season and is cultivar dependent. This research is very valuable for agricultural production and commercial authentication. I am enthusiastic about this work and support publication in Quantitative Plant Biology but have some requests before publication.

1. It would be better if the photos of apple samples of different cultivars and periods could be given in the text or supplementary materials. This will make reading more intuitive. For example, I don’t have much research on apples, and I’m even more confused about the names of these cultivars.

2. None of the tables has a caption, although I can see what each table might mean from the text. Please add a caption for each table.

3. Intuitively, six landmarks can not describe the 2D shape of apple. Although it is mentioned in this paper, machine learning can identify apple varieties only through six landmarks, with an accuracy of 78%. But so far, human beings do not understand the mechanism behind machine learning and artificial intelligence. I think it is better to quantitatively analyze shape stability by overlapping the 2D contours of multiple apples [1,2]. Asymmetry Analysis can also be realized by overlapping two halves.

[1] Hong L, et al. Variable Cell Growth Yields Reproducible Organ Development through Spatiotemporal Averaging. Developmental Cell, 2016.

[2] Lüwen Z, et al. Epidermal restriction confers robustness to organ shapes. Journal of Integrative Plant Biology, 2020.

4. The linear and geometric morphometrics used in this paper are 2D in nature, which can not fully reflect the 3D shape of a apple. I suggest that the authors should consider more possible methods in his future work. For example, the apple can be projected from different angles, and the 3D shape of the apple can be reconstructed through algorithms like inverse Radon transform. These are very mature mathematical methods of image reconstruction in computed tomography, and there is no technical bottleneck. Then shape stability and asymmetry analysis can be achieved by overlapping volume.

5. The covariance analysis of length and diameter is essentially to estimate the linear correlation between the two variables. The essence is not much better than ratio, because there is no extra input information except for length and diameter. However, the author points out three shortcomings of ratios in the introduction. Therefore, in addition to the cited literature, the author may need to add additional explanations to dispel my doubts. Once again, I strongly suggest that the author should adopt more sophisticated methods in his future research work.

6. Some of the conclusions obtained in this paper are in conflict with previous work. This may be the value of the article. But it may also be caused by the limited data samples. For example, this paper only collects the data from 2013 and 2014, and thus concludes that stability of shape is not easily stabilized by weather. This conclusion may be too hasty and the author needs to identify it carefully.

Recommendation: Apples before the fall: Does shape stability coincide with maturity? — R0/PR5

Comments

Comments to Author: This work has been seen by three reviewers. Whereas all reviewers recognize the importance of this work, they also raised important questions. In particular, the reviewers concern about whether the data is reproducible in other orchids, and in additional cultivar. The reviewers also provided suggestion on data presentation. I would like to ask you to submit a revised version that carefully address the reviewers comments, ideally within one month.

Decision: Apples before the fall: Does shape stability coincide with maturity? — R0/PR6

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Author comment: Apples before the fall: Does shape stability coincide with maturity? — R1/PR7

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Review: Apples before the fall: Does shape stability coincide with maturity? — R1/PR8

Comments

Comments to Author: The revision has addressed my concerns/comments. I endorse the publication of this manuscript.

Review: Apples before the fall: Does shape stability coincide with maturity? — R1/PR9

Comments

Comments to Author: Points raised in the previous reviews have been addressed and the manuscript clarified.

Three very minor editorial points are:

Line 107-109: Sentence structure is awkward and ambiguous.

Line 108: ‘that’ to ‘than’?

Line 109: ‘was’ to ‘has’?

Review: Apples before the fall: Does shape stability coincide with maturity? — R1/PR10

Comments

Comments to Author: The authors have addressed my concerns in their revision and response, and I would like to recommend to accept this manuscript.

Recommendation: Apples before the fall: Does shape stability coincide with maturity? — R1/PR11

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Decision: Apples before the fall: Does shape stability coincide with maturity? — R1/PR12

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Author comment: Apples before the fall: Does shape stability coincide with maturity? — R2/PR13

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Recommendation: Apples before the fall: Does shape stability coincide with maturity? — R2/PR14

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Decision: Apples before the fall: Does shape stability coincide with maturity? — R2/PR15

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