Figures
Abstract
The molecular basis of short term cold resistance (indexed as chill-coma recovery time) has been mostly addressed in D. melanogaster, where candidate genes (Dca (also known as smp-30) and Frost (Fst)) have been identified. Nevertheless, in Drosophila, the ability to tolerate short term exposure to low temperatures evolved several times independently. Therefore, it is unclear whether variation in the same candidate genes is also responsible for short term cold resistance in distantly related Drosophila species. It should be noted that Dca is a candidate gene for cold resistance in the Sophophora subgenus only, since there is no orthologous gene copy in the Drosophila subgenus. Here we show that, in D. americana (Drosophila subgenus), there is a north-south gradient for a variant at the 5′ non-coding region of regucalcin (a Dca-like gene; in D. melanogaster the proteins encoded by the two genes share 71.9% amino acid identities) but in our D. americana F2 association experiment there is no association between this polymorphism and chill-coma recovery times. Moreover, we found no convincing evidence that this gene is up-regulated after cold shock in both D. americana and D. melanogaster. Size variation in the Fst PEST domain (putatively involved in rapid protein degradation) is observed when comparing distantly related Drosophila species, and is associated with short term cold resistance differences in D. americana. Nevertheless, this effect is likely through body size variation. Moreover, we show that, even at two hours after cold shock, when up-regulation of this gene is maximal in D. melanogaster (about 48 fold expression change), in D. americana this gene is only moderately up-regulated (about 3 fold expression change). Our work thus shows that there are important differences regarding the molecular basis of cold resistance in distantly related Drosophila species.
Citation: Reis M, Vieira CP, Morales-Hojas R, Aguiar B, Rocha H, Schlötterer C, et al. (2011) A Comparative Study of the Short Term Cold Resistance Response in Distantly Related Drosophila Species: The Role of regucalcin and Frost. PLoS ONE 6(10): e25520. https://doi.org/10.1371/journal.pone.0025520
Editor: Sergios-Orestis Kolokotronis, Barnard College, Columbia University, United States of America
Received: April 4, 2011; Accepted: September 5, 2011; Published: October 3, 2011
Copyright: © 2011 Reis 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.
Funding: This work has been funded by the project PTDC/BIA-BDE/66765/2006 and PTDC/BIA-BEC/099933/2008 comp-01-0124-FEDER-008916, and through PhD grants attributed to Micael Reis and Bruno Aguiar, funded by Programa Operacional para a Ciência e Inovação (POCI) 2010, co-funded by Fundo Europeu para o Desenvolvimento Regional (FEDER) funds and Programa Operacional para a Promoção da competividade (COMPETE; FCOMP-01-0124-FEDER-008923). Ramiro Morales-Hojas is supported by the programme Ciência 2007, financed by the Programa Operacional Potencial Humano - Quadro de Referência Estratégico Nacional(POPH – QREN), cofinanced by the European Social Fund and Portuguese funds from the Ministerio da Ciência Tecnologia e Ensino Superior (MCTES). The fly collection was funded by the American Portuguese Biomedical Research Fund (APBRF). We thank Sara Magalhães for technical assistance. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
How species adapt to daily and seasonal temperature changes is determined by the genetic variation present in local populations [1]. The molecular basis of short term cold resistance has been mostly addressed in D. melanogaster, where candidate genes have been identified (see [2], [3] for reviews of candidate genes for cold-resistance in D. melanogaster). In this species, short term cold resistance is very often indexed as chill-coma recovery time (the time it takes an individual to recover from chill-coma once it has been returned to non-stressful temperature [3], , although it is unlikely that this index captures all the complexities of the cold response. It should be noted that there is no effect of acclimation on chill-coma recovery times [9].
The ability to tolerate short term exposure to low temperatures seems to have evolved several times in Drosophila [4], but it is unclear whether the same genes have been used in the independent evolutions. Moreover, the model species D. melanogaster, where most studies regarding this issue have been performed, is originally a tropical species, and it is conceivable that the genetic basis of cold resistance is different in tropical and temperate species. Comparative studies using divergent species are lacking [2], but are needed in order to establish whether the findings reported for the D. melanogaster cold response can be extrapolated to other species. In this work we address the role of Dca-like genes and Frost (Fst) [3] in the cold response of species of the subgenus Drosophila.
The Dca (in Drosophila this gene is also known as senescence marker protein-30; smp-30) gene has been found to be up-regulated when D. melanogaster flies are exposed one day at 15°C [10]. Moreover, in this species, non-coding polymorphisms have been shown to be significantly associated with cold tolerance [11]. This gene has a predicted Ca(2+)-binding function and thus may be involved in the regulation of cytosolic Ca(2+) concentration [12]. It should be noted that in mammals the names regucalcin and smp-30 are synonyms (see for instance, the Human alternative gene names for regucalcin at ENSEMBL; http://www.ensembl.org). Nevertheless, in D. melanogaster, regucalcin and smp-30 are the names of two distinct genes on Muller's elements A and E, respectively (http://flybase.org) that code for proteins with 71.9% amino acid identities. In this work, we use the nomenclature for D. melanogaster.
Recently, it has been shown that Dca arose by a duplication event from the ancestral regucalcin-like gene after the split of the Sophophora and Drosophila subgenera but before the Sophophora radiation [13]. There is thus, no Dca orthologous gene in species of the Drosophila subgenus [13]. Nevertheless, given the degree of similarity between Dca (smp-30) and regucalcin, we decided to address the possible involvement of the latter gene in the cold response of species of the Drosophila subgenus. It should be noted, however, that after the duplication event, there is an acceleration of the rate of fixation of nonsynonymous substitutions in the branch leading to Dca, which could be indicative of the acquisition of a new function [13]. In D. melanogaster, Dca promoter polymorphisms show latitudinal clines, and are also associated with wing size but not thorax size [14], [15].
In D. melanogaster, the Fst gene has been shown to be greatly overexpressed after cold shock [10], [16] and Colinet et al. [16] have shown that, in this species, this gene is essential for cold tolerance. It should be noted that, unlike heat-shock genes [17], Fst expression was not altered after heat stress [18]. Moreover, this gene is included in a QTL for thermo tolerance [5], [19]. These observations clearly show an important involvement of this gene in the cold response in D. melanogaster. Despite its important role in the D. melanogaster cold response, length variation in the promoter region of this gene seems to explain at most 1% of the variation in cold-resistance [3]. The D. melanogaster Fst protein resembles a mucin-like protein. Like typical mucins it contains multiple tandem repeats rich in serine (S), threonine (T) and proline (P) [16], located in the C terminus of the protein, where Goto [10] identified nine PEEST motives (not identified by this author as PEST (putatively involved in rapid protein degradation) domains). Indeed, Goto [10] identified moderate and weak PEST domains at the N-terminal region of Fst only. Moreover, like secreted mucins, Fst shows an 18 amino acid signal peptide in the N-terminal region [10]. This protein may thus be directed into the endoplasmatic reticulum and secreted into extracellular space [10]. Homology searches revealed similarity with two D. melanogaster mucins: Mur18B and Muc11A [16] that, like Fst, show a mRNA enrichment in adult malpighian tubule [20], [21]. Fst may help keep membrane integrity by protecting it from oxidative stress and by allowing the reestablishment of local molecular environments with respect to hydration, ionic composition and concentration. Such injuries are typical features of chilling-injury [16]. In addition to cold tolerance, Fst has been reported to respond weakly to abiotic stressors [18], [22], [23], [24], [25] and to be involved in the immune response against virus, bacteria and fungi [26], [27], [28], [29].
Building on the previous work in D. melanogaster, we determine the possible involvement of variation in Fst and regucalcin in the short term cold resistance response in D. americana, a temperate species of the virilis group of Drosophila that has been diverging from D. melanogaster for about 40 My [30]. D. americana inhabits the Central and Eastern regions from the South (Texas to the states around the Gulf of Mexico) to the North of the country (from Montana to Maine) [31]. The wide geographic distribution of D. americana means that individuals from this species face very different climatic conditions.
Materials and Methods
Strains
The following 64 D. americana strains were used: NN97.2, NN97.4, NN97.9 (Nebraska, USA); G96.11, G96.21, G96.36, G96.48 (Indiana, USA); LP97.7, ML97.4 .2, ML97.5 (Louisiana, USA) and CD97.5 (Louisiana, USA). These strains were originally collected by Bryant McAllister (Iowa University, USA) in the years 1996 and 1997. Furthermore, isofemale strains established with flies collected at the end of July and beginning of August 2004 from four collection sites in the USA, Howell Island, Missouri (HI1, HI13, HI14, HI15, HI18, HI23, HI25, HI27, HI29), Lake Wappapelo, Missouri (W4, W10, W11, W18, W23,W25, W26, W27, W28, W29, W33, W36, W37, W42, W46), Lake Ashbaugh, Arkansas (LA10, LA14, LA18, LA37); Lake Hurricane, Mississippi (H5) and isofemale strains established with flies collected at the end of July 2008 at Fremont (Nebraska) (O27, O28, O29, O30, O31, O32, O33, O34, O35, O37, O38, O39, O40, 042, O45, O47, O50, O53, O57, O61, O62, O64, O66, O69) were also used. The Drosophila melanogaster strain Oregon-R was also used in the gene expression experiment described below.
PCR amplification, cloning and DNA sequencing
Genomic DNA from single males was extracted using the QIAamp DNA Mini Kit from QIAGEN (Izasa Portugal, Lda.). The coding region of regucalcin was amplified using primers Dcaf and Dcar (Table S1) designed based on the D. virilis regucalcin 5′ flanking and coding regions. Standard amplification conditions were 35 cycles of denaturation at +94°C for 30s, primer annealing at +53°C for 45s, and primer extension at +72°C for 3 min. A Dca paralogous gene (regucalcin) is here studied, since there is no Dca orthologous gene in species of the subgenus Drosophila (see Introduction).
An amplification product was obtained for 18 D. americana individuals (data not shown). The PCR products were cloned using the TOPO-TA Cloning Kit for Sequencing (Invitrogen, Spain). Positive colonies were picked randomly, grown in 5 mL of LB with Ampicillin, and plasmids were extracted using the QIAprep Spin Miniprep Kit from QIAGEN (Izasa, Portugal). Four colonies were sequenced in order to correct for possible nucleotide missincorporations that may have occurred during the PCR reaction. Sequencing was performed using ABI PRISM Big Dye cycle-sequencing kit version 1.1 (Perkin Elmer, CA, USA) and the primers for the M13 forward and reverse priming sites of the pCR2.1 vector. Sequencing runs were performed by STABVIDA (Portugal). A common polymorphism was observed at the regucalcin site −58 which was then used as a molecular marker (see below).
The Fst coding region was amplified using primers FrostF and FrostR designed based on the D. virilis Fst 5′ and 3′ flanking sequence (Table S1). Standard amplification conditions were those described above. In order to have sequence data for the full spectra of D. americana Fst allele sizes found in the 64 D. americana strains analyzed (see results), the complete coding sequence of at least one allele of the autosomal Fst gene was determined in the following strains, using an approach similar to that described for regucalcin (the relative Fst allele size, due to different PEST region sizes, is indicated within brackets): NN97.4 (M1), W4 (M1), W11 (M1), NN97.9 (M2), ML97.3 (M2), W29 (M2), ML97.5 (M2), NN97.2 (M3), NN97.8 (M3), LA18 (M3), HI25 (M3), H5 (M3 and M3.5), LP97.7 (M4), HI1 (M4), W11 (M4), ML97.4.2 (M4), LA37 (M5), HI23 (M5), and W37 (M6). DNA sequences were deposited in GenBank (accession numbers JN674303-JN674322).
regucalcin and Fst genotyping
Because of the possibility of lab adaptation, it is always best to estimate polymorphism frequencies using a sample of wild caught individuals. Therefore, in order to determine the frequency and distribution of the regucalcin polymorphism at site −58 in natural populations, 56 wild-caught males and 26 male progeny of inseminated wild-caught females from the D. americana populations described in [32], plus 18 wild-caught male individuals from Fremont (Nebraska, July, 2008), 9 wild-caught male individuals from Saint Francisville (Louisiana, July, 2010) and the 4 males, progeny of inseminated wild-caught females from the same population, were used. These individuals were screened for the regucalcin −58 polymorphism using the amplification product obtained with Dcaf and Dcar and restriction enzymes AvaII plus BstBI. DNA fragments were run in a 2% agarose gel stained with ethidium bromide, using SGTB (Grisp, Portugal) buffer. It should be noted that the regucalcin −58 polymorphism is distinguished solely with BstBI. Nevertheless it is difficult to distinguish small size differences when DNA fragments are large, as it is here the case (the polymorphism is located at about 40 bp from the 5'end of the amplification product). Therefore, it was necessary to use AvaII, which recognizes a shared variant, in order to have the resolution needed to distinguish the DNA bands in a 2% agarose gel. The individuals used in the association studies (see below) were genotyped, as well, for this polymorphism.
Fst size variability typing was performed in the individuals mentioned above, using the PCR amplification conditions described above and specific primers covering the entire Fst coding region (FrostF and FrostR) and primers flanking only the PEST region (Frost_PEST_F and Frost_PEST_R, see Table S1) with an annealing temperature of +55°C. Amplification products were run in a 2% agarose gel stained with ethidium bromide using either TAE or SGTB (Grisp, Portugal) buffers.
PEST domain prediction
PEST regions were predicted using the reference amino acid sequences and the PEST-SCORE algorithm [33]; http://www.at.embnet.org/embnet/tools/bio/PESTfind/.
Association studies and phenotyping
Two strains (H5 from Lake Hurricane, Mississippi, and W11 from Lake Wappapelo, Missouri) were used to perform an F2 association study. These strains were selected, since, according to the markers used, they show the same polymorphic chromosomal rearrangements, namely, the X/4 fusion, the Xc, and 5a inversions and show differences regarding several traits including chill-coma recovery times. The X/4 fusion and Xc chromosomal rearrangements were typed as described in [34], [35] and [32]. The 4ab inversion was typed as described in [36] and the 5b inversion was typed using primers 5bGJ17741F (CCAGCGATAAAGAGAAGA) plus 5bGJ17741R (GCAGGCGGAGATTAGGAC) and the restriction enzyme BssHII (Reis et al., unpublished results). It should be noted that inversions 5a and 5b are mutually exclusive. A total of 975 F2 males obtained from three crosses between H5 males and W11 females (F0) were phenotyped for developmental time, chill-coma recovery time, abdominal size and lifespan, but for this work only chill-coma recovery time and abdominal size (as an approximation of total body size) are relevant. The first trait to be measured was developmental time. For this purpose, each of the 83 second generation crosses (F1) were transferred to new flasks every day in order to obtain the precise period of time between oviposition and adult emergence. The resulting F2 males were then individually collected. When F2 males were 10 days old (young adult flies), individual chill-coma recovery times were measured at +25°C after four hours of cold exposure at 0°C. Flies must be able to stand up on their legs in order to be considered completely recovered. Individual photographs were taken when individuals were 20 days old, using a stereomicroscope Nikon ZMS 1500 ®. The resulting JPG files were saved with a resolution of 1600×1200 pixels. Relative abdominal size was estimated by counting the number of pixels in the picture that correspond to this structure, using Adobe Photoshop ®. The flies were then transferred to new vials and kept until they died, in order to measure lifespan. Only males were used in order to avoid potential confounding effects caused by differences between sexes for the traits being studied (see for instance [37]). A total of 453 F2 males corresponding to approximately 66% of the individuals showing the most extreme values for the four phenotypic traits measured were selected to conduct the analyses. Genomic DNA was then extracted and the individuals were genotyped for Fst allele sizes (using the primers flanking the PEST region) and the −58 polymorphic site at the 5′ region of the regucalcin gene on Muller's element A, as described above. Not all individuals could be genotyped due to unknown reasons. For Fst and regucalcin, 440 and 422 individuals could be genotyped, respectively.
In the F2 association study there is only one generation of recombination. Therefore associations are expected between the phenotypic traits under study and many polymorphic sites in the region(s) where the causative variant(s) are located. To overcome this issue, 64 individuals (one individual per strain) were phenotyped for chill-coma recovery time and abdominal size, and genotyped for the polymorphic site at the 5′ region of the regucalcin gene, as well as for Fst allele sizes. Abdominal size could not be determined for four individuals. In this sample, associations between the phenotypic traits under study and polymorphic sites should be found only in the close vicinity of the causative polymorphism.
Statistical analyses
Genotype – phenotype associations were tested using non-parametric tests and the software SPSS Statistics 17.0 (SPSS Inc., Chicago, Illinois). Using the same software, non-linear as well as linear regression analyses (including a constant) were performed, in order to estimate the amount of phenotypic variation explained by variation in candidate genes.
Gene expression analyses
Fst and regucalcin expression levels were determined for three sets of three individuals from the H5 strain, three sets of three individuals from the W11 strain, and three sets of three D. melanogaster (Oregon-R) individuals, that were subjected to different conditions, (without chill coma (control), immediately after chill coma recovery (469,8±128,4 seconds for D. americana and 1153,3±119,6 seconds for D. melanogaster), and 2 hours of recovery after chill coma). Chill coma experiments were performed as described above. It should be noted that all flies are of the same age (10 days old; young adult flies). Immediately after the treatment individuals were frozen in liquid nitrogen. Total RNA was isolated from each set of individuals using TRIzol Reagent (Invitrogen, Spain) according to the manufacturer's instructions and treated with DNase I (RNase-Free) (Ambion, Portugal). cDNA was synthesized by reverse transcription with SuperScript III First-Strand Synthesis SuperMix for qRT-PCR (Invitrogen, Spain) using random primers. No-template controls and reactions with RNA that was not reverse transcribed were performed in order to confirm the absence of genomic DNA contamination. Highly efficient specific primers (Table S1) for regucalcin and Fst were used when performing qRT-PCR experiments using the isolated cDNA. Every experiment was performed in duplicate. qRT-PCR was performed with the iQ SYBR Green Supermix (Bio-Rad, Portugal) according to the manufacturer's instructions on a Bio-Rad iCycler with the following program: 3 min at 95°C; 40 cycles of 30 s at 94°C, 30 s at 58°C and 30 s at 72°C followed by a standard melt curve for the D. americana strains and 3 min at 95°C; 40 cycles of 30 s at 94°C, 30 s at 60°C and 30 s at 72°C followed by a standard melt curve for the D. melanogaster strain. Specific primers (Table S1) were also developed for the endogenous ribosomal protein L32 (RpL32) which was used as the reference gene. Fold change in expression was calculated using the 2−ΔΔCT method [38].
Likelihood tests of selection
The random-sites models implemented by the PAML 3.15 codeml software [39] have been used. The likelihoods estimated using neutral and positive selection models were compared using a Likelihood Ratio Test: M0 vs. M3, M1a vs. M2a, and M7 vs. M8. The regucalcin sequences from the 12 Drosophila genomes (http://flybase.org/) and one sequence from D. americana (strain NN97.4) were used. The D. willistoni sequence was excluded since the change in codon bias reported in this species [40], may affect the inferred phylogeny. For Fst, only those species belonging to the Sophophora subgenus were used (D. simulans, D. sechellia, D. melanogaster, D. yakuba, D. erecta, D. ananassae, D. persimilis, D. pseudoobscura), since a reliable alignment could not be obtained when using all species.
For both regucalcin and Fst, the phylogenetic trees used as input in the codeml analysis were estimated with Maximum Likelihood (ML), using PAUP* v4.0b10 [41]. The evolutionary model used in the ML phylogenetic reconstruction is that suggested by Modeltest 3.7 (Akaike Information Criterion [42]). Trees topology (data not shown) were in general agreement with the view of the group systematics [30]. Heuristic searches were run with the starting tree obtained via stepwise addition and random addition of sequences with 100 replicates. Tree-bisection-reconnection was used as the branch-swapping algorithm. All characters were considered unordered and to have equal weight.
Results
The regucalcin gene
In the literature, there is no evidence for the involvement of the regucalcin gene (on Mulleŕs element A) in cold tolerance. Indeed, in D. melanogaster, Morgan and Mackay [19] and Norry et al. [5] did not find any QTL peak for chill-coma recovery on Muller's element A. It is, however, conceivable that the parental lines used in these studies did not segregate X-linked alleles for this trait. Therefore, despite these observations, given the high similarity between the regucalcin and the smp-30 proteins (71.9% amino acid identities) we performed F2 association analyses in D. americana using the regucalcin gene.
In Drosophila, temperature resistance is known to be dependent on body size ([43] and references therein), and, as expected, in the F2 association study here performed, using 453 individuals, chill-coma recovery times are negatively linearly correlated with abdominal size (Pearson correlation = −0.290; P<0.0001; Non-parametric Spearman's correlation = −0.263; P<0.0001). The negative correlation between chill-coma recovery times and abdominal size holds when using all the F2 phenotypic data available (N = 974 individuals), although the amount of chill-coma recovery time variability explained by abdominal size is smaller than when using the extremes of the distribution (Pearson correlation = −0.211; P<0.0001; Non-parametric Spearman's correlation = −0.160; P<0.0001). Therefore we looked for associations between the C and T variants at the −58 regucalcin site polymorphism and both chill-coma recovery times and abdominal size. There are significant associations between this polymorphism and abdominal size (Non-parametric Mann-Whitney Test; P<0.0001) but not with chill-coma recovery time (Non-parametric Mann-Whitney Test; P>0.05). For abdominal size, on average, male flies having the C variant are 5.2% larger than male flies having the T variant (from 0.96 (N = 245) relative units for the T variant to 1.01 (N = 177) relative units for the C variant). Overall, the polymorphism at the regucalcin gene explains 3.5% of the variation in abdominal size.
The regucalcin polymorphism in the 5′ flanking region (at position −58 relative to the start codon), may be ecologically relevant. Indeed, when using wild-caught individuals, a clear linear correlation between latitude and the frequency of the regucalcin T variant at site −58 is observed (Pearson's r = 0.996; P<0.001; Table 1). In D. americana, there is a north-south cline for an X/4 fusion – Xc inversion chromosomal arrangement that is frequent in the north of the geographic distribution and is almost absent in the south of the distribution [32], [34], [35], [36], [44], and thus it was conceivable that the two gradients were not independent. When the same wild-caught flies are typed for the presence of the X/4 fusion, using the fused1 ClaI marker [34], no association is, however, observed between this marker and the presence of the regucalcin T variant at position -58 (Fisher's exact test; P<0.05). It should be noted that 79 X/4 fusion and 33 non-fusion chromosomes are being analyzed. Therefore, the gradients for the X/4 fusion and that for the regucalcin T variant at position −58 are independent.
The H5 strain (used in the F2 association experiment) is fixed for the T variant and the W11 strain (also used in the F2 association experiment) is fixed for the C variant. Nevertheless for both D. americana and D. melanogaster no obvious changes in expression levels are detected after cold shock (Fig. 1).
The housekeeping gene RpL32 was used to normalize the expression values. Expression fold changes were addressed immediately after chill coma recovery and after 2 hours of recovery both for D. americana and D. melanogaster strains.
We also looked for signs of positive selection at the regucalcin gene at the Drosophila genus level. Signs of positive selection are expected at regucalcin if amino acid changes at a few sites in the coding region result in changes in cold resistance. The following species were included: D. melanogaster, D. simulans, D. sechellia, D. yakuba, D. erecta, D. ananassae, D. pseudoobscura, D. mojavensis, D. virilis, D. americana and D. grimshawi. The analyses revealed no evidence for positively selected amino acid sites (twice the difference of the ln likelihood values is zero and 0.115 (non-significant) when comparing models M1a and M2a and models M7 and M8, respectively; [39]). This result is not unexpected since, in D. americana all replacement variants are singletons (based on 18 sequences covering 302 out of the 303 regucalcin amino acids; data not shown).
Chill coma recovery times, relative abdominal sizes, and the regucalcin variant at position −58 were determined for 64 unrelated individuals (one individual per strain). In this sample of unrelated individuals a low level of linkage disequilibrium is expected. Therefore, when using such an approach, associations are only expected when the marker used is very close to the causative polymorphism. No association is observed between the regucalcin variant at position -58 and chill-coma recovery times or abdominal size (for both Non-parametric Mann-Whitney Test; P>0.05). It should be noted that, in this sample, chill-coma recovery time and abdominal size are as strongly correlated (Pearson correlation = −0.267; P<0.05; Non-parametric Spearman's correlation = −0.300; P<0.05), as in the F2 association experiment (Pearson correlation = −0.290; Non-parametric Spearman's correlation = −0.263; see above).
The Fst candidate gene
The Fst gene is located on Muller's element E, and has been shown to be up-regulated in D. melanogaster, after chill-coma recovery [10]. In this species, Goto [10] used the PEST-SCORE algorithm [33] to predict the presence of weak PEST regions (putatively involved in rapid protein degradation) in the N-terminal region of the protein. Therefore, we looked for the presence of PEST domains in the Fst protein from 12 Drosophila species. Only highly supported PEST region predictions were used, since the biological meaning of weakly predicted PEST regions is unclear [33]. Surprisingly, highly supported PEST regions were detected in seven species but at the C-terminal region of the protein (Fig. 2). Nevertheless, the number and percentage of the amino acid residues that contribute to PEST regions varies widely even in closely related species (Fig 2). For instance, the D. sechellia and D. simulans Fst sequences differ at 18 amino acid positions. No PEST regions are found in D. sechellia because PEST domains must be flanked by a lysine, arginine or histidine [33] and the lysine residues flanking the PEST regions in D. simulans are mutated to non-positively charged residues in D. sechellia. PEST regions seem to be present in only four species of the Sophophora subgenus. In three out of these four species, PEST domains represent less than 10% of the Fst protein sequence. This is in contrast with species from the Drosophila subgenus (D. mojavensis, D. virilis and D. grimshawi), where more than 47% of the Fst protein are PEST regions. It is unlikely that such marked differences can be attributed to the use of a single individual per species.
Numbers after species names indicate, respectively, the total size (number of amino acids) of PEST regions, the size of the Fst protein, and the fraction of the protein containing PEST regions.
In D. americana, seven Fst alleles of different sizes were found when using primers FrostF and FrostR and one individual from 64 strains (data not shown). In order to determine the nature of such allele size differences, representatives of each allele size were sequenced (Table 2). Sequencing data indicated that allele size differences are due to a variable number of PEST regions. In this species, PEST regions represent in between 43.3 and 51.3% of the Fst protein depending on the allele size considered.
In the F2 association study here performed, the PEST size genotypes found were homozygous 1 (N = 62), 3 (N = 1), and 4 (N = 18), and heterozygous for allele sizes 1 and 3 (N = 72), 1 and 3.5 (N = 88), 1 and 4 (N = 29), 3 and 3.5. (N = 63), 3 and 4 (N = 63) and 3.5 and 4 (N = 44). This observation reveals that the D. americana strains used in the crosses are polymorphic. A significant association between PEST size genotype and chill-coma recovery times was found (Non-parametric Kruskal-Wallis Test; P<0.05), as well as with abdominal size (Non-parametric Kruskal-Wallis Test; P<0.001).
The genotype homozygous for allele size 1 is associated with the slowest chill-coma recovery times (Table 3). On average, male flies homozygous for allele size 1 take 11.6% longer to recover from chill-coma than males from all other genotypic classes (from 429.2 (N = 378) to 478.9 (N = 62) seconds; the two classes explain 1.9% (P<0.005) of the variability observed in the F2 association experiment regarding chill-coma recovery time). On the other hand, Fst allele size 3 seems to be associated with large abdominal size (the average for the two categories, namely, not having or having allele size 3, are 0.94 and 1.05 relative units, respectively; Non-parametric Mann-Whitney Test; P<0.001; 17.5% of the variation in abdominal size is explained; P<0.001).
In natural populations, Fst allele sizes 3 and 4 are the most common (Table 4). Allele size 4 shows a significant non-linear north-south gradient (Pearson's r = 0.711; P>0.05; non-parametric Spearman's r = 0.886; P<0.05). This could be an indication for a north-south cline for chill-coma recovery or size, since the latter is significantly correlated with chill-coma recovery.
Chill coma recovery times, abdominal sizes and Fst size variation were determined for 64 individuals (one individual per strain). As described earlier, associations between polymorphic sites should have been destroyed by free recombination and therefore associations are only expected to be observed when the marker used is very close to the causative polymorphism. Since many Fst allele sizes are present in the sample but most are rare, we analyzed the data by defining two groups of individuals, those that have Fst allele size 3 (N = 39) and those that do not have (N = 25). A significant association is observed with abdominal size (Non-parametric Mann-Whitney Test; P<0.05), but not with chill-coma recovery time (Non-parametric Mann-Whitney Test; P>0.05). In this sample, as noted previously, the two variables are as strongly correlated (Pearson correlation = −0.267; P<0.05; Non-parametric Spearman's correlation = −0.300; P<0.05), as in the F2 association experiment (Pearson correlation = −0.290; Non-parametric Spearman's correlation = −0.263; see above). This result strongly suggests that the association observed in the F2 association experiment between Fst allele sizes and chill-coma recovery is due to body size differences. Surprisingly, given the results obtained in the F2 association study using strains H5 and W11 where Fst allele size 3 is associated with large abdominal size, on average, in the sample of 60 unrelated individuals, Fst allele size 3 is associated with a 10.1% smaller abdominal size. Therefore, it is not variation in Fst allele sizes that contributes to size differences but rather a closely linked polymorphism. Under the assumption that the marker Fst allele size 3 is dominant over the other allele sizes, 8.0% of the variation in abdominal size is explained (P<0.05).
In order to address whether other amino acid positions along the Fst protein could be associated with cold resistance, we looked for signs of positive selection at the Fst coding region. Signs of positive selection are expected if, amino acid changes at a few Fst amino acid sites result in changes in cold resistance. Analyses for positive selection using random-sites models were run for the Fst gene, using the sequences from the sequenced genomes of D. simulans, D. sechellia, D. melanogaster, D. yakuba, D. erecta, D. ananassae, D. persimilis and D. pseudoobscura. Given the heterogeneity observed for PEST regions from the different species, the alignment used in the present analysis did not include the sequences of the most divergent species D. virilis, D. mojavensis and D. grimshawi, as they were not aligned with confidence. No evidence for sites under positive selection was found in any of the model comparisons (twice the difference of the ln likelihood values is zero when comparing models M1a and M2a, and 0.002118 (non-significant) when comparing models M7 and M8; [39]).
In D. americana there are no obvious differences in Fst expression levels immediately after chill-coma recovery (Fig. 3). However, after 2 hours of recovery an increase of about 3-fold in Fst mRNA levels is observed in both D. americana strains H5 and W11. In D. melanogaster a 10-fold increase in Fst expression was observed immediately after chill coma recovery whereas after 2 hours of recovery a 48-fold increase was observed. Therefore there are important differences in Fst expression levels after cold shock in D. americana and D. melanogaster.
The housekeeping gene RpL32 was used to normalize the expression values. Expression fold changes were addressed immediately after chill coma recovery and after 2 hours of recovery both for D. americana and D. melanogaster strains.
Discussion
In D. melanogaster, the autosomal Dca (smp-30) gene is up-regulated by cold-shock [12]. Although Rako et al. [3] and Telonis-Scott et al. [45] failed to find an association between variability at this gene and chill-coma recovery times, Clowers et al. were able to find non-coding polymorphisms that are significantly associated with cold tolerance [11], and thus, this is still one of the most credible candidate genes for cold resistance. Nevertheless, there is no Dca gene in species of the Drosophila subgenus [13], and thus the Dca gene is not a candidate for cold resistance at the whole Drosophila genus level. It should be noted that the Dca paralogous gene here studied, the regucalcin gene on Muller's element A, encodes for a protein that shares 71.9% amino acid identities with Dca, but has never been implicated in cold resistance in Drosophila.
In the D. americana F2 association study, for the X-linked gene regucalcin, no association is observed between a common polymorphism in the 5′ flanking region (at position −58 relative to the regucalcin start codon) and chill-coma recovery time. Nevertheless, the T variant at position -58 is present at highest frequency in the populations experiencing the lowest average temperatures, and thus those where cold resistance must be most important. Indeed there is a north-south gradient for this polymorphism that is independent of the previously reported north-south X/4 fusion – Xc inversion gradient [32], [34], [35], [36], [44]. It should be noted that, for regucalcin, we find no evidence for positively selected amino acid sites at the Drosophila genus level, and all D. americana amino acid variants are singletons. Therefore, changes in expression levels are likely the only way regucalcin could be associated with phenotypic differences. Despite this observation, for both D. americana and D. melanogaster, we find no obvious expression level differences after cold shock. It is conceivable, however, that cold shock does not capture every aspect of cold resistance and thus this gene could still be involved in such a response. In the same F2 association study, an association was, however, observed between the −58 regucalcin polymorphism and abdominal size. In this experiment, the T variant that is present at highest frequency in the north of the distribution is associated with small abdominal size. This is in contrast with the commonly reported observation that body size is larger in coldest places (see for instance [46]). Nevertheless, an association could not, however, be detected between this variant and abdominal size when using a sample of unrelated individuals, suggesting that it is variation at another gene located in the same region that is responsible for the observed variation.
Little is known about the function of the Drosophila regucalcin protein, and thus we can only speculate about the meaning of the T/C frequency cline. Recently, Kankare et al. [47] reported an about 4 fold up-regulation of the Dca gene when comparing non-diapausing and diapausing D. montana (a member of the virilis group of Drosophila) females. There is, however, as noted above, no Dca gene in species of the subgenus Drosophila and thus in D. montana [13]. Therefore they likely studied changes in regucalcin expression. If so, the D. americana north-south gradient for regucalcin site −58 could be linked to the propensity to enter diapause. It would be interesting to address whether significant differences in expression level changes are observed in D. americana when C/C, T/C and T/T females are compared but this is beyond the scope of this article.
The Fst gene shows remarkable variation regarding the size of PEST regions (putatively involved in rapid protein degradation) located in the C-terminal region of the protein encoded by this gene, both within and between Drosophila species. The biological meaning of such differences is at present unknown, but this observation suggests that there are important differences in the biological role of Fst in different species.
In D. americana, we find evidence for associations between PEST region sizes and chill-coma recovery times. It is unknown how differences in PEST region sizes could translate into chill-coma recovery time differences. Nevertheless, associations are also observed between PEST region sizes and abdominal size. Therefore, the association with chill-coma recovery time could be through abdominal size, since, in D. americana, the two variables are negatively correlated. When unrelated individuals are used, an association is observed between PEST region sizes and abdominal size, but not with chill-coma recovery times. This result strongly suggests that the association between Fst PEST region sizes and chill-coma recovery time is through size. Further studies are needed in order to determine which polymorphism, in the close vicinity of the Fst PEST region, could be responsible for the abdominal size differences. The causative polymorphism could be located outside the Fst gene. It should be noted that, Fst is located inside an intron of the diuretic hormone (Dh) gene that controls body fluid secretions [48]. It should be noted that, in D. melanogaster, Rako et al. [3] report that length variation in the Fst promoter explains at most 1% of the variation in cold-resistance.
In D. melanogaster Fst gene expression is up-regulated during recovery from cold shock [10], [16], [18]. In this species we observe an increase in Fst expression levels both immediately after (10-fold) and 2 hours after cold exposure (48-fold), which correlate well with those obtained by Colinet et al. [16]. Nevertheless, in D. americana we find no obvious expression level differences immediately after cold shock, and we find a 3 fold increase in Fst expression levels 2 hours after cold shock. Taken together with the differences regarding the presence of PEST domains, these results suggest that Fst gene may have remarkable different roles regarding cold resistance in distantly related Drosophila species. In addition to cold tolerance, Fst has been reported to respond weakly to abiotic stressors [18], [22], [23], [24], [25] and to be involved in immune response against virus, bacteria and fungi [26], [27], [28], [29]. Therefore, it is conceivable that the relative importance of the different selection pressures vary in the different species.
In conclusion, our work shows that there are significant differences regarding the molecular basis of cold resistance in distantly related Drosophila species.
Supporting Information
Table S1.
Frost and regucalcin primers used for PCR amplification and sequencing.
https://doi.org/10.1371/journal.pone.0025520.s001
(PDF)
Author Contributions
Conceived and designed the experiments: JV CPV CS. Performed the experiments: MR BA HR. Analyzed the data: MR CPV RMH CS JV. Contributed reagents/materials/analysis tools: JV. Wrote the paper: MR CPV RMH BA HR CS JV.
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