Background

Sexual-size dimorphism (SSD), the difference in body size between males and females, is perhaps the most familiar and widespread form of sexual dimorphism. This condition is extremely variable among species. For example, a female blanket octopus can weigh 10,000–20,000 times more than a male [1], while a male southern elephant seal can weigh seven times more than a female [2]. Further, the degree of SSD is highly evolutionarily labile, and can vary between closely related species or among populations within species, sometimes dramatically. For example, among populations of the Australian carpet python, females range from being less than 1.5 × to more than 10 × the size of males [3]. While intraspecific variation in SSD is likely due, in part, to genetic differences between populations, it may also be a consequence of sex-specific differences in the phenotypic plasticity of body size. Environmental variation can account for the vast majority of variation in body size within a population [4, 5], and if males and females differ in the extent to which the environment affects body size, this will generate changes in SSD across environments [6]. This is a form of G × E interaction, where G is genetic sex and E is the environment. While there is considerable evidence that males and females differ in the extent of their body size response to a variety of environmental variables [7]—a phenomenon called sex-specific plasticity (SSP)—the role that SSP plays in the developmental generation and evolution of sexual size dimorphism is largely unknown. At the same time, despite an extensive literature on the role that growth rate and developmental time play in generating SSD [8,9,10,11,12,13] and on the genetic mechanisms that determine sex [14,15,16], the developmental mechanisms through which genetic sex affects growth parameters remains largely unknown.

Perhaps the most important, and certainly the best understood, environmental factor that regulates body size is developmental nutrition. In all animals where it has been studied, the nutritional regulation of growth is mediated via the insulin/IGF-signaling (IIS) pathway, a highly conserved receptor tyrosine kinase pathway, the components of which pre-date the Metazoa [17]. Insulin-like peptides are released in response to nutrition and bind to receptors of dividing cells to initiate a signal-transduction cascade that regulates the expression of positive and negative growth regulator. The IIS pathway positively regulates the activity of TOR-signaling, which also responds directly to cellular levels of amino acid. Activation of IIS/TOR-signaling results in an increase in both growth rate and (typically) adult body size at high levels of nutrition, while deactivation of IIS/TOR-signaling does the opposite at low levels of nutrition [18,19,20,21,22,23,24,25].

Although both males and female typically display nutritional plasticity, in many species one sex is more nutritionally plastic than the other, and typically this is the larger sex [26]. Thus, in birds and mammals, where SSD is generally male-biased, male growth tends to be affected more by nutritional stress than female growth [12]. In contrast, in in arthropods, where SSD is typically female-biased [27, 28], female growth is more affected by nutritional stress [7, 29]. This suggests that the mechanisms that generate SSD at least partially overlap with those that generate sex-specific nutritional plasticity.

Several adaptive hypotheses that explain why selection acts differently on males versus females may explain a relationship between SSD and SSP [7]. Under the adaptive canalization hypothesis [30], if body size in the larger sex is under stronger directional selection—for example, sexual selection for increased body size in males or fecundity selection for increased body size in females—then individuals with small bodies will suffer higher fitness costs in the larger sex than the smaller sex. The result is that the larger sex will show reduced sensitivity to environmental factors that affect body size. Under the condition dependence hypothesis [31, 32], if body size in the larger sex is under stronger directional selection, then that sex will have greater fitness benefits if it opportunistically exploits favorable environmental conditions that increase body size. The result is that the larger sex will show increased sensitivity to environmental factors that affect body size. The observation that in both vertebrates and invertebrates the larger sex tend to be the more nutritionally plastic [7, 26, 29] provides support for the condition dependence hypothesis, at least with respect to body size, although individual traits may show patterns of SSD and SSP that follow the adaptive canalization hypothesis [30].

While these adaptive hypotheses provide an ultimate evolutionary mechanism for a correlation between SSD and SSP, several studies have hinted at the proximate developmental mechanism linking the two phenomena. A study by Emlen et al. [33] found that exaggerated male traits—specifically the horns of the beetle Trypoxylus dichotomus—are more insulin sensitive than other traits in the body. This accounted for both the trait’s increase in size in males relative to females, and their elevated nutritional plasticity, as predicted by the condition dependence hypothesis. In Drosophila melanogaster, where females are larger and more nutritionally plastic than males, again consistent with the condition dependence hypothesis, SSD also appears to be regulated by the IIS pathway. This is based on three pieces of evidence: (1) SSD is eliminated in flies with suppressed IIS through hypomorphic mutation of the insulin receptor (InR) [8]; (2) well-fed females have higher IIS activity than males [34], and; (3) SSD requires sex-specific difference in the neurosecretory cells that produce insulin-like peptides (dILPs), the hormone that activates the IIS pathway [35]. Because SSD is eliminated in flies with a loss of InR activity, it follows that female body size is more sensitive to changes in insulin-signaling than male body size. Consequently, as for the beetle horn, SSP of body size in D. melanogaster may result from sex-specific differences in insulin-sensitivity. Further, developmental studies in D. melanogaster indicate that trait-specific increases in expression of InR is sufficient to increase both trait size and trait plasticity, providing further support for a mechanistic link between size and plasticity that supports the condition dependence hypothesis. Nevertheless, it is not yet known whether the differences in body size and nutritional plasticity between males and females are evident at the level of IIS/TOR-signaling activity itself.

To address this question, we looked at the expression of genes that regulate and are transcriptionally regulated by the IIS and TOR-signaling pathways across a nutritional landscape, where nutritional quality and quantity varies. In a previous study [36], we looked at the effect of changes in protein-to-carbohydrate ratio (diet quality) and total food concentration (diet quantity) on the size of the wing, maxillary palp, femur of the first leg and thorax. For all traits, female trait size was more sensitive to changes in either diet quality or quantity than male trait size. Intriguingly, however, these sex-specific differences could be attributed to each trait’s size response to changes in carbohydrate versus protein concentration: males and female trait sizes were equally sensitive to changes in protein concentration, but only female trait size was detectibly sensitive to changes in carbohydrate concentration. Here we test the hypothesis that these observed sex-specific differences in body-size plasticity are reflected by corresponding differences in response to diet at the level of the IIS/TOR-signaling pathways.

Results

Female and male body size responds differently to changes in carbohydrates but not proteins

We used principal component analysis to generate a measure of overall body size for each individual fly based on their wing, leg, thorax and palp size. We found that, consistent with prior results [36], males and females differed in their size response to dietary carbohydrate versus protein (Fig. 1; Additional file 1: Fig. S1). Specifically, both male and female body size responded to changes in dietary protein as a negative quadratic, with body size increasing as protein concentration increased, but at a decreasing rate (Table 1). In contrast, only female body size responded to dietary carbohydrate concentration, this time as a positive quadratic, such that body size declined with increasing carbohydrate, but at a decreasing rate (Table 1). Correspondingly, including an interaction between sex and carbohydrate when modeling the relationship between diet and body size significantly improved model fit, while including an interaction between sex and protein did not further improve fit (Table 2). Thus, male and female body size appears to respond differently to carbohydrate but not to protein. As a result, sexual size dimorphism (SSD: female size – male size) varied across the nutritional geometry landscape (Fig. 1; Additional file 1: Fig. S1).

Fig. 1
figure 1

The effect of protein and carbohydrate concentration on female and male body size and sexual size dimorphism (SSD). a, b Surfaces show the fitted relationship between body size (PC1 from a PCA on the size of four body parts), carbohydrate level and protein level in female and male flies, based on the statistical model specified by the equation above each chart. T = body size, P = protein, C = carbohydrate, ε = error, subscripts refer to levels within each factor. c Surface shows the difference in female and male body size (SSD: female size – male size) across the same nutritional landscape, using fitted values from a and b. Points indicate diets tested and dotted lines connect diets with equal protein-to-carbohydrate ratios (1:14.6, 1:7.2, 1:3.5, 1:1.7, 1.3:1, 1.4:1). Asterisk indicates approximate composition of standard cornmeal–molasses medium. Corresponding thin-plate spline plots are shown in Additional file 1: Fig. S1

Table 1 Effects of protein (P), carbohydrate (C), and their squares and product on body size in females and males
Table 2 Effect of including sex as an interactive versus additive term when modeling the influence of diet on body size

Female and male IIS/TOR gene expression responds differently to changes in diet

We collected expression data for eight genes that either regulate or are regulated by the IIS/TOR-signaling pathway: insulin receptor (InR); eukaryotic translation initiation factor 4E binding protein (4E-BP/Thor); Drosophila insulin-like peptides 2, 3, 5 and 8 (dILP 2, 3, 5,8), Absent, small, or homeotic discs-like protein (Ash2L), and CG3071 (the Drosophila homolog of UTP15/SAW). Expression of both InR and 4E-BP is negatively regulated by the IIS pathway [37], dILPs 2,3,5 encode peptides that ostensibly activate the IIS pathway, while dILP8 retards development by inhibiting the synthesis and release of ecdysone [38]. Finally, expression of both Ash2L and CG3071 has been shown to be negatively and positive regulated by TOR signaling, respectively [39]. We first tested how the expression of each gene correlated with overall body size, using the fitted values for body size at each diet from the linear mixed model of the relationship between body size and protein/carbohydrate level (Fig. 1). Expression of only a few genes correlated directly with body size: 4EBP and dILP5 negatively and positively correlated with body size in females, respectively, while expression of InR negatively correlated with body size in males (Table 3). Nevertheless, a multivariate analysis of gene expression across all diets supported a significant interaction between the effects of sex and carbohydrate, as a linear variable, and sex and protein, as a quadratic variable, on gene expression (Table 4). We therefore explored how sex and diet affected the expression of individual genes. Specifically, we looked to see whether sex-specific responses in the expression of genes that either regulate or are regulated by the IIS/TOR-signaling pathways reflected the sex-specific response of body size to changes in diet.

Table 3 Coefficients and partial eta-squared for multiple regression of body size against gene expression in males and females
Table 4 Effect of including sex as an interactive versus additive term when modeling the influence of diet on the expression of multiple genes

Genes regulated by IIS

Both InR and 4E-BP expression responded to changes only in dietary protein but not carbohydrate (Fig. 2). InR expression in males and females had a positive quadratic response to protein level, decreasing as protein level increased, but at a declining rate (Table 5). The expression of InR was lower across all diets in males than in females, but there was no significant interaction between the effects of sex and protein level on gene expression (Table 6). In contrast, 4E-BP expression was sensitive to protein level only in females, decreasing linearly as protein increased, but was unaffected by diet in males (Table 5). Consequently, there was a significant interaction between the effect of sex and protein level on 4E-BP expression (Table 6).

Fig. 2
figure 2

The effect of protein and carbohydrate concentration on the expression of IIS and TOR transcriptionally regulated genes in females and males. Surfaces show the fitted relationship between gene expression, carbohydrate level and protein level in female and male flies, based on the statistical model specified by the equation above each chart (Table 4). P = protein, C = carbohydrate, ε = error, subscripts refer to levels within each factor. Expression of (a, a′) InR, and (b, b′) 4E-BP, both negatively regulated by the activity of the IIS via the Forkhead transcription factor FOXO. c, c′ Expression of Ash2L, ostensibly negatively regulated by the activity of TOR signaling. d, d′ Expression of CG3071, ostensibly positively regulated by the activity of TOR signaling. Points indicate diets tested and dotted lines connect diets with equal protein-to-carbohydrate ratios (1:16, 1:8, 1:4, 1:2, 1:1, 2:1). Corresponding thin-plate spline plots are shown in Additional file 2: Fig. S2

Table 5 Effects of protein (P), carbohydrate (C), and their squares and product on gene expression in females and males
Table 6 Effect of including sex as an interactive versus additive term when modeling the influence of diet on the expression of individual genes

Genes regulated by TOR signaling

Expression of both Ash2L and CG3071 had a complex and sex-specific response to diet. Carbohydrate significantly affected Ash2L expression as a linear relationship, but in opposite directions in either sex: increased carbohydrate increased Ash2L expression in males but decreased Ash2L expression in females (Fig. 2; Table 5). Ash2L expression was not affected by protein in males but had a positive quadratic response to protein in females, decreasing as protein increased but at a declining rate. There was therefore a significant interaction between sex and diet on the expression of Ash2L, although only between sex and carbohydrate and not sex and protein (Table 6). CG3071 also showed a sex-specific expression response to diet. In females, CG3071 expression had a negative quadratic response to protein level (increasing at a declining rate as protein increased), a positive quadratic response to carbohydrate level (decreasing at a declining rate as carbohydrate increased), with a significant carbohydrate: protein interaction (Table 5). In contrast, CG3071 expression was not affected by diet in males, which lead to a significant diet-by-sex interaction effect on CG3071 expression (Table 6).

Genes that regulate IIS/TOR signaling

The expression of dILP2 showed a significant response to diet in females, declining linearly with increasing protein, and at a decreasing rate with increasing carbohydrate, as a positive quadratic (Fig. 3, Table 5). There was also a significant carbohydrate-by-protein interaction effect on dILP2 expression in females. There was no significant effect of diet on dILP2 expression in males (Table 5), although this appears to be a consequence of low statistical power, due to large amount of within-diet variation in dILP2 expression among male samples compared to female samples. Fitting a one-way ANOVA of dILP2 expression against diet, where diet is each protein-to-carbohydrate ratio at each concentration, the residual variance (a measure of average variance within diets) was significantly higher in males than in females, by a ratio of 8.68 (Additional file 4: Table S1). Correspondingly, we had very low power (0.22) to detect a significant sex-by-diet interaction for dILP2 expression, based on the observed effect size (Cohen’s f2 = 0.023, see R scripts posted on Dryad for details). Further, there was no evidence that expression of dILP2 was different between males and females, independent of diet (Table 6).

Fig. 3
figure 3

The effect of protein and carbohydrate concentration on the expression of dILPs in females and males. Surfaces show the fitted relationship between gene expression, carbohydrate level and protein level in female and male flies, based on the statistical model specified by the equation above each chart (Table 4). P = protein, C = carbohydrate, ε = error, subscripts refer to levels within each factor. a dILP2. b dILP3. c dILP 5. d dILP8. Points indicate diets tested and dotted lines connect diets with equal protein-to-carbohydrate ratios (1:16, 1:8, 1:4, 1:2, 1:1, 2:1). Corresponding thin-plate spline plots are shown in Additional file 3: Fig. S3

The expression of dILP3 decreased linearly with protein in females, but there was no detectable effect of diet on dILP3 expression in males (Fig. 3; Table 5 measured mRNA abundance measured mRNA abundance). There was also no detectable difference in expression between the sexes (Table 6). As for dILP2, variation in expression of dILP3 among samples within diets was significantly higher in males than in females (Additional file 4: Table S1), and a power analysis gave a power of only 0.05 to detect a sex-by-protein interaction on dILP3 expression, based on the observed effect size (Cohen’s f2 < 0.001).

The expression of dILP5 was only marginally affected by diet in females, with a significant negative quadratic effect of protein (Fig. 3, Table 5). We could detect no significant effect of either carbohydrate or protein on dILP5 expression in males (Table 5). As for dILP2 and 3, dILP5 expression was more variable among male samples within diets than among female samples (Additional file 4: Table S1), and a power analysis gave a power of only 0.23 to detect a sex-by-protein interaction on dILP5 expression, based on the observed effect size (Cohen’s f2 = 0.022). Nevertheless, there was sex-specific expression independent of diet, such that dILP5 expression was higher in males than in females (Table 6).

The expression of dILP8 responded as a positive quadratic in response to protein in females, declining as protein increased at a decreasing rate, but did not show any response to any aspect of diet in males (Fig. 3; Table 5). The lack of a corresponding response to protein in males was not due to a lack of statistical power: a power analysis suggested that the power to detect the female effect size of protein on dILP8 expression (Cohen’s f2 = 0.46) in males was 0.99. Further, dILP8 expression was not more variable among male samples within diets than among female samples (Additional file 4: Table S1). Consequently, we detected a significant sex-by-protein interaction on dILP8 expression (Table 6).

dILP protein levels in the brain increase with increasing food concentration

Our finding that dILP expression in females was generally higher in larvae fed on lower food concentrations was surprising, given that dILPs (apart from dILP8) are canonically positive regulators of growth in response to nutrition. We therefore explored the relationship between diet, dILP expression and the levels of dILP peptide in the insulin-producing cells (IPCs) of the brain. Staining for dILP2 and dILP5 peptide was higher in larvae fed a higher food concentration (360 g/l) versus a lower food concentration (45 g/l), with a 1:2 protein:carbohydrate ratio (Fig. 4).

Fig. 4
figure 4

The effect of diet on dILP2/5 expression and peptide levels in the brain in females and males. a, b The relationship between diet and dILP2 and dILP5 expression. Points indicate 45 and 360 g/l food concentration at 1:2 protein: carbohydrate ratio. a′, b′ Representative images of dILP2 and dILP5 levels in the insulin-producing cells (IPCs) of female larvae reared on different diets. (a″, b″) Mean normalized level of dILP2 and dILP5 in the IPCs of larvae reared on different diets. P-values are for a pooled t-test

Discussion

Previous studies indicate that in Drosophila melanogaster, body size is more nutritionally plastic in females than in males, a phenomenon referred to sex-specific plasticity (SSP) [36]. Nutritional plasticity is canonically regulated by the insulin/IGF-signaling and TOR-signaling pathways in D. melanogaster and most other animals. We hypothesized, therefore, that differences in nutritional plasticity between the sexes reflect sex-specific differences in the activation and activity of these pathways. In this study, we applied a nutritional geometry framework to test this hypothesis and explored the sex-specific effects of protein and carbohydrates on body size and the expression of genes that activate and are transcriptionally regulated by IIS/TOR. Our results indicate that, broadly, gene expression is more nutritionally sensitive in females than in males, although the effect of nutrition on the expression of IIS and TOR-signaling genes is both quantitatively and qualitatively different between males and females.

The simplest hypothesis to account for sex-specific differences in the nutritional plasticity of body size in D. melanogaster is that females have the same response to nutrition as males, but at a higher sensitivity. Under this hypothesis, the response surfaces of body size and gene expression across a nutritional landscape of varying protein and carbohydrate concentrations should be the same shape in both sexes, but with lower gradients in males. This would be evident as lower parameter values in males versus females. This is not supported by the data, however. In particular, body size in males shows more or less the same sensitivity to changes in protein concentration as females, but has no detectable sensitivity to changes in carbohydrate concentration. This in turn suggests that an important aspect of sex-specific nutritional plasticity in D. melanogaster is differences in the response to variation in dietary carbohydrates.

The best understood regulators of body size with respect to nutrition are the insulin/IGF-signaling and TOR-signaling pathways [19, 40]. The IIS pathway is activated by circulating dILPs, some of which are released in a nutrition-dependent manner [38]. The TOR-signaling pathway is in part regulated by IIS, but also responds directly to circulating amino acids [24, 41, 42]. Because the SSP of body size in flies appears to primarily drive by a differential response to carbohydrates but not to protein, we might expect that the effect of diet on body size is mediated primarily by IIS rather than TOR-signaling. Our data do not support this hypothesis. We used the expression of InR and 4E-BP as a measure of IIS activity: both are transcriptionally regulated by the forkhead transcription factor FOXO, which is activated when nutrition and IIS activity is low [37, 43]. If sex-specific plasticity is mediated by IIS, then we would expect to see sex-specific differences in Inr and 4EBP expression in response to changes in carbohydrate but not to protein. In both males and females, however, InR expression responded only to protein level—and to the same extant—but did not respond to carbohydrate level. Expression of 4E-BP only responded to protein level in females, but did not respond to carbohydrate level in either sex. Collectively, variation in the expression of 4E-BP correlated most strongly with body size in females while expression of InR correlated most strongly with body size in males (Table 3), consistent with the hypothesis that the IIS is the major regulator of body size with respect to nutrition in D. melanogaster. However, expression of 4E-BP and Inr do not reflect sex-specific differences in the effect of carbohydrate on body size, and so do not explain sex-specific plasticity in our study.

The extent to which protein level has a differential effect on male and female body size may, however, be equivocal. A recent study shown that elevated protein increased female but not male body size in D. melanogaster, and that this is echoed by sex-specific changes in FOXO-target genes (InR, 4E-BP and brummer) [44]. The diet in this study had ~ 140 g/l carbohydrate, with protein increasing from ~ 16 g/l to ~ 27 g/l, a much smaller range of protein concentrations than used in our study. While our study also found sex-specific differences in the effect of protein on 4E-BP expression across a much larger range of protein concentrations, we did not see these sex-specific effects on InR expression, nor on body size. It is important to note, however, that the two studies used different genotypes of flies (indeed our body-size analysis used an outbred fly population). There is considerable genetic variation in SSD in D. melanogaster [45, 46], and it is possible that there is similar genetic variation for SSP, which may account for inconsistencies among studies using different populations and lineages of flies.

In contrast to InR and 4E-BP, the expression of Ash2L and CG3071 both responded to carbohydrates in a sex-specific manner. However, the response is not consistent with a previous study on the regulation of these genes’ expression by TOR-signaling [39]. This study reported that Ash2L is negatively regulated by TOR-signaling while CG3071 is positively regulated. If TOR-signaling increases with protein, then we would expect Ash2L expression to decrease correspondingly, which is true in females. However, Ash2L expression also decreases with increasing carbohydrate, which is difficult to reconcile with the negative effects that carbohydrate has on female growth. Even more challenging to interpret is the observation that Ash2L expression increases with carbohydrate but not protein in males, even though male do not appear to have a growth response to carbohydrate. Thus, the relationship between Ash2L expression and body size is not a simple one. The expression pattern of CG3071 is similarly unclear. While CG3071 also has a carbohydrate and protein response in females, this response is qualitatively similar to the response of Ash2L, which is not expected if TOR-signaling positively regulates CG3071 expression but negatively regulates Ash2L expression. Thus, the role that TOR signaling plays in regulating SSD and SSP is equivocal based on our data. Problematically, the mechanism by which TOR-signaling regulates Ash2L and CG3071 expression has not been fully explored, which makes interpreting changes in Ash2L and CG3071 expression with diet even more challenging.

Our data suggest a complex relationship between sex, diet, dILP expression and dILP retention levels in the IPCs. In females, there were stark differences in the pattern of expression among the dILPs. Of all the dILPs, dILP5 expression was most strongly correlated with body size, increasing with increasing protein level but decreasing with increasing carbohydrate level. We also found that dILP5 levels in the IPCs were lower in larvae fed on lower food concentrations. Thus, chronic reductions in nutrition reduce dILP5 expression and dILP5 IPCs level. This is consistent with dILP5 being a positive regulator of growth in response to nutrition [47]. The negative effect of low nutrition on dILP5 expression has been observed in previous studies [40, 47, 48]. However, at least one of these studies reported an increase in dILP5 retention in the IPCs of larvae that were either starved for 24 h or reared on a low-protein diet since birth [48], which is inconsistent with our data. The low-protein diet in this study was generated by reducing the amount of protein from ~ 16 g/l to ~ 0.8 g/l, while keeping the concentration of carbohydrate at ~ 60 g/l, thereby decreasing the protein-to-carbohydrate ratio. In our study we reduced overall food concentration from 360 g/l to 45 g/l while retaining a 1:2 protein-to-carbohydrate ratio. It is possible, therefore, that the retention of dILP5 in the IPCs in the earlier study is due to a low protein-to-carbohydrate ratio. Indeed, a second earlier study showed that a chronic high-sugar diet with low protein-to-carbohydrate ratio also increased dILP5 levels in the IPCs [49], although this time accompanied by an increase in dILP5 expression. Thus, the relationship between dILP5 expression and dILP5 levels in the IPCs may depend not only on the overall food concentration, but also on food composition, in particular the protein-to-carbohydrate level.

Previous studies suggest that dILP2 expression is unaffected by reduced nutrition [40, 48] (although see supplementary data in [50]), but that dILP2 peptides are retained in the IPCs in larvae that have been starved 24 h or are reared on a low-protein diet [48, 51, 52]. A high-sugar diet is also associated with increased retention of dILP2 peptide in the IPCs, but with an increase in dILP2 expression [49]. In our study, however, we found that dILP2 expression declined with an increase in both protein and carbohydrate, and that dILP2 peptide was lower in the IPCs of larvae fed on lower food concentrations. Our observed expression of dILP3 was also inconsistent with previous studies that found that acute starvation reduced expression [40], while rearing on a high protein diet increased expression [53]. In contrast, we found that, as for dILP2, dILP3 expression declined with increasing protein, although was unaffected by carbohydrate level, which is surprising given that circulating sugars promote the release of dILP3 from the IPCs [52]. Our finding that dILP2 and dILP3 expression is lowest on low-protein diets that restrict growth, and that dILP2 peptides levels are higher when dILP2 expression is lower, suggests that dILP2 and dILP3 may negatively regulate their own expression, which is a common characteristic of hormone regulation.

Finally, the expression of dILP8 showed a similar pattern to dILP3, increasing with a decrease in protein concentration. dILP8 is involved in regulating growth and developmental timing through its inhibitory effects on ecdysone synthesis [54, 55]. It is released from imaginal discs in response to damage or growth perturbation, as well as showing periodic changes in expression throughout development. Ecdysone synthesis is also inhibited by low nutrition early in the third larval instar, leading to a delay in metamorphosis [56]. The observation that females on low-protein diets also show elevated levels of dILP8 expression, suggests that dILP8 may play a role in regulating growth and/or development in response to nutrition, at least in females.

We did not detect an effect of diet on the expression of any of the dILPs in male larvae. This did not, however, translate into a significant interaction between diet and sex on dILP expression, and therefore does not help explain the sex-specific differences in nutritional plasticity of body size. This was because variation in dILP 2,3,5 and 8 expression among samples within diets was significantly higher for male samples than for female samples (Additional file 4: Table S1), reducing the statistical power to detect diet-by-sex interactions. The only exception was for dILP8, such that dILP8 expression was significantly more plastic in females than in males. Nevertheless, dILP8 expression in females did not correlate with carbohydrate level, and so is unlikely to explain the differential effect of carbohydrate on body size in females versus males. The elevated variation in dILP expression among male samples was not seen for expression of 4eBP, InR, Ash2L, or CG3072, and is therefore not likely due to sample degradation. It is also not due to lower levels of expression in males relative to females. It is possible, therefore, that dILP expression levels are more developmentally dynamic in males then females, and that we are capturing aspects of that instability by measuring gene expression at only a single point in development.

Collectively, there appears to be no simple explanatory relationship between the sex-specific nutritional geometry of body size with the sex-specific nutritional geometry of IIS/TOR-signaling gene expression. Further, many of our findings do not replicate what has been reported in previous studies. An earlier study looking at dILP expression in adults across a nutritional landscape saw similarly complex and non-intuitive relationships between diet and gene expression [57]. What is very clear from both studies is that the protein-to-carbohydrate ratio affects the transcriptional response of IIS/TOR-signaling genes to changes in total diet, and our study indicates that it does so in a sex-specific way. This has important implications for interpreting those studies that have looked at changes in the expression of IIS/TOR-signaling genes in response to changes in nutrition. First, many studies simply dilute diet to reduce overall nutrition. Problematically, while most Drosophila labs use ‘standard’ food recipes, the use of different types of yeast, cornmeal, molasses, etc., means that the composition of these diets may be unique to most research groups [58]. Our data indicate that the effect of diet dilution on both body size and IIS/TOR-signaling gene expression—and potentially the activity of the IIS/TOR-signaling pathways—will depend on the P:C ratio of that specific diet. Second, these responses are sex-specific, and studies that do not consider sex may come to different conclusions than studies that do. Third, the relationship between dILP expression, dILP retention and diet is similarly complex, and may also depend on the composition of the diet being manipulated. Finally, while many laboratory studies use ostensibly the same isogenic lineage of flies (e.g., OreR, CantonS, w118), different lineages will likely have different responses to changes in diet over different portions of the nutrition.

One important caveat with our, and almost all other studies of IIS/TOR-signaling gene expression during development, is that we measured expression at a single developmental time point, at the very beginning of larval wandering. Previous studies have shown that the activity of the IIS and TOR-signaling pathways change dynamically during development, and that different dILPs are expressed at different life stages. This may also account for differences between our and other studies of the effects of nutrition on IIS/TOR-signaling gene expression. Ideally, one would like to conduct a multidimensional study of gene expression across both time and a nutritional landscape, and to tie this with a corresponding study of dILP levels both in the IPCs and circulating in the hemolymph. Such a study would not only help elucidate the relationship between IIS/TOR-signaling and the sex-specific effects of nutrition on body size, but also help us understand better how nutrition regulates the transcription, translation, storage and release of dILPs.

Conclusions

Our study provides a foundation for future work that looks at the sex-specific effects of diet quantity and quality on body size and on the developmental mechanisms that regulate body size. Our data show significant differences in the effect of diet on gene expression in males and females, although they do not suggest a simple explanatory relationship between gene expression and body size. Future studies on sex-specific plasticity in Drosophila, and other animals, should therefore consider not only the nutritional geometry of gene expression, but also of protein levels, pathway activity and other developmental parameters such as growth rate and growth duration, ideally at multiple time points throughout development.

Materials and methods

The goal of the study was to test the hypothesis that sex-specific differences in body-size plasticity across a nutritional landscape in D. melanogaster correspond to sex-specific differences in the response to diet at the level of the IIS/TOR-signaling pathways, using the expression of genes that regulate or are regulated by IIS/TOR-signaling to assay pathway activity.

Fly stocks and maintenance

Flies used for the nutritional geometry of body size were as described in [36]. Flies used for the nutritional geometry of gene expression were an isogenic line of white-eyed, but otherwise wild-type flies (VDRC 60,000). Flies were maintained as a stock at 17 °C on standard media of 45 g of molasses, 75 g of sucrose, 70 g of cornmeal, 20 g of yeast extract, 10 g of agar, 1100 ml of water, and 25 ml of a 10% Nipagin solution per liter of fly food, under constant light.

Diet manipulation for nutritional geometry of body size

Flies were reared on 24 diets: six protein-to-carbohydrate ratios (1:14.6, 1:7.2, 1:3.5, 1:1.7, 1.3:1, 1.4:1), at four food concentrations: (45, 90, 180 and 360 g l−1), with six replicate vials per diet, as described in [36]. We measured four non-genital traits in each fly: the length of the first femur, the area of the wing, the area of the maxillary palp and the length of the thorax (see [36] for details). Data were collected from, on average, 17 flies from each sex at each diet, with no more than 30 flies coming from any one vial. To assay the effect of diet on overall body size, we conducted a principal component analysis on the covariance matrix of all log-transformed non-genital morphological data from all flies and used each fly’s value for the first principal component (PC1) as a proxy for overall body size [59, 60].

Diet manipulation for nutritional geometry of gene expression

Flies were reared on 28 different diets: seven protein-to-carbohydrate ratios (1:16, 1:8, 1:4, 1:2, 1:1, 1.5:1 and 2:1) at four food concentrations (45, 90, 180, and 360 g/l). To generate the diets, we made an instant-yeast solution (Lesaffre SAF-Instant Red: 44% protein, 33% carbohydrate) and a sucrose solution (Mallinokrodt, Paris, Kentucky) at each food concentration. We also added 0.5% agar, 10% nipagin (10% p-hydroxy benzoic acid methyl ester in 95% ethanol) and 1% propionic acid (Sigma Life Science, St. Louis, Missouri) to each solution, to control consistency and prevent fungal growth. The solutions were autoclaved and mixed at different ratios to achieve the desired protein-to-carbohydrate ratios for each diet. 10 ml of each of the 28 different diets were aliquoted into separate 25 × 95 mm vials.

Populations of 50 flies were placed in mating cages with 60 mm petri dishes of standard lab food. The flies were allowed to lay eggs for 24 h. The adult flies were removed, and the eggs were left on the petri dish for another 24 h until the larvae had hatched. The first instar larvae were then transferred in groups of 50 into each food vial. There were at least five replicate vials for each diet.

All cultures were maintained at 25 °C at constant light under 60–70% humidity. Larvae were collected from the food vials when they had just initiated wandering, to ensure that all larvae were collected at the same developmental stage regardless of diet. All larvae were sexed and flash-frozen to – 80 °C within five minutes of being removed from the vial. The larvae were stored at – 80 °C until they were used for RNA extractions.

Gene expression quantification

We used qPCR to assay gene expression in male and female larvae collected at the beginning of larval wandering. Larvae were pooled into cohorts of 15 individuals, and we collected 3 cohorts of each sex for each of the 28 diets, with the exception of the 1:16 360 g/l diet, which only generated enough larvae for 2 cohorts of each sex. For each sample, RNA was extracted using Trizol (Invitrogen, Grand Island, NY, USA) and treated with DNase 1 (Invitrogen) before being reverse-transcribed with High-Capacity cDNA Reverse Transcription Kit synthesis according to manufactures instructions (Thermo Fischer Scientific, Carlsbad, CA, USA). We used SYBR Green PCR master mix (Thermo Fischer Scientific, Carlsbad, CA, USA) to conduct qPCR using a CFX Connect Real-time System (Bio-Rad Laboratories, Inc., Hercules, CA, USA). mRNA abundance was calculated using the standard curve method [61]. Relative gene expression was normalized by dividing the measured mRNA abundance of the gene of interest with the measured mRNA abundance of ribosomal protein 49 (RP49). Prior studies have indicated that RP49 is insensitive to changes in nutritional conditions [57]. In two samples (1:16 180 g and 1:4 45 g male), gene expression levels were an order of magnitude above all other samples across all amplicons. Data from these samples were therefore excluded from subsequent analysis. The complete protocol is provided in the supplementary material, along with primer sequences.

dILP2 and dILP5 levels in the brain

The following antibodies were used: dILP2 rat (1:800); dILP5 rabbit (1:800) (both gifts of P. Leopold); AlexaFluor 594 Donkey anti-Rat IgG (1:500); AlexaFluor 594 Goat anti-Rabbit IgG (1:500) (both from Life Technologies).

Larvae were reared on either 45 g/l or 360 g/l at a protein:carbohydrate ratio of 1:2, as described above. Brains were dissected in 1 × PBS on ice from wandering female third instar larvae. The brains were fixed for 30 min in 4% paraformaldehyde and washed in 0.3% Triton-X in PBS (PBT) overnight at 4 °C. They were then washed for 1 h. in 2% NGS in 0.2% I-Block in PBT (BBT/NGS) and incubated with primary antibody diluted in BBT/NGS overnight at 4 °C. Subsequently, brains were washed four time in 0.2% BSA/I-Block in PBT (BBT), 15 min per wash. Brains were then incubated in secondary antibody at room temperature for 2 h. Finally, brains were washed in four times in PBT for 15 min per wash and mounted with vector shield + DAPI.

We acquired images using Olympus Fluoview FV101 confocal microscope. For both 45 g/l and 360 g/l dILP2 images, 35% DAPI and 35% Alexa 594 intensity settings were used. For both 45 g/l and 360 g/l dILP5 images, 30% DAPI and 30% Alexa 594 intensity settings were used. We used a 1.5-micron step size to capture a Z-stack of images for each IPC (one per brain), which was flattened to a single image using a maximum-intensity projection in FIJI software. The intensity of the IPC in both the Alexa 594 and DAPI channel was then used to generate a normalized measure of the level of dILP2 or dILP5 in each brain. We repeated this for five brains for dILP2 and dILP5 at each diet level (nine for dILP5 at 45 g/l). dILP levels were then compared between diets using a standard pooled t-test.

Statistical analysis

Nonlinear response surfaces are routinely modeled using the second-order polynomial regression [36, 57, 62, 63]. To determine the effect of protein and carbohydrate level on body size or gene expression we therefore fit the model:

$$T_{ijk } = C_{i} + P_{j} + C_{i}^{2} + P_{j}^{2} + C_{i} P_{j} + \varepsilon_{ijk} ,$$

where T is trait (body size or expression level), C is carbohydrate concentration, P is protein concentration and ε is error (subscripts are levels within variables). Models for body size included replicate vial as a random factor and were fit using lmer in the lme4 package in R [64]. Models for expression level were fit using lm in the base package of R [65]. For each trait, the significance of each parameter was tested with a type III ANOVA using the ANOVA function in the car package [66] for standard models and the summary function in the lmerTest package [67] for mixed models. Any non-significant parameters were subsequently removed from the model before the data were reanalyzed using the simplified model. Models that did not contain interactions were analyzed with a type II ANOVA. We subsequently plotted the fitted values of the simplest model against carbohydrate and protein levels. We also plotted thin-plate splines of the raw measurements against carbohydrate and protein levels, with the caveat that the thin plate spline may show trends that are indistinguishable from random noise. Finally, we plotted sexual size dimorphism (SSD) as the difference between the female and male fitted values against carbohydrate and protein level, as well a thin-plate splines of the difference between mean female and male values at each diet.

To test whether the response to carbohydrates or protein differed between the sexes, we fit two models:

$${\text{Model}} \;1: T_{ijk} = S_{k} + \left( {C_{i} + P_{j} + C_{i}^{2} + P_{j}^{2} + C_{i} P_{j} } \right) + \varepsilon_{ijk} ,$$
$${\text{Model}} \;2: T_{ijk} = S_{k} \times \left( {C_{i} + P_{j} + C_{i}^{2} + P_{j}^{2} + C_{i} P_{j} } \right) + \varepsilon_{ijk} ,$$

where S is sex. Models were compared using ANOVA (for standard models of expression level) or parametric bootstrapping (for mixed models of body size). If inclusion of sex as an interactive factor rather than an additive factor significantly improved the fit of the model, we concluded that the relationship between trait and diet varied between males and females. If the relationship between trait and diet could be explained by a simpler model, we tested whether inclusion of sex as an interactive rather than an additive factor in the simplified model improved the fit of the model. We also conducted a similar multivariate analysis on the effect of diet and sex on the expression of multiple genes, using MANOVA to compare models. Finally, we used the fitted values from the relationship between diet and body size to test the relationship between body size and the expression of each gene, using the linear model:

$$Tij...p = Ai + Bj + \ldots + Hp + \varepsilon ij...p,$$

where T is body size (fitted values from the linear mixed model of the relationship between body size and diet) and A through H is the expression of the genes measured in our analysis.

All analyses were conducted in R and the data and scripts for the analyses are provided on Dryad. To maintain homogeneity of variance, normalized gene expression levels were log-transformed prior to analysis. For all analyses, we plotted residual against fitted values to confirm homogeneity of variance and generated a QQ plot to confirm that the residuals were approximately normally distributed.