Introduction

Spermatogenesis, the most fundamental biological process in male reproductive system, is strongly yet adversely affected by the increase in scrotal temperature in mammals with descended testicle1,2,3,4,5,6,7,8,9. Such increase in scrotal temperature would result in impaired spermatogenesis, thus ultimately affecting the reproductive potential of a wide range of mammalian species with testicular descent, including our own species Homo sapiens1,2,3,5,8. Therefore, in long-term, the elevated surrounding temperature may pose a major threat to the mammalian diversity. While most mammals, with a few exceptions4, have external testes where spermatogenesis occurs at 2–8 °C lower than the core body temperatures that range from 35 to 39 °C2,3,4,6,7,8,10,11,12,13,14, birds maintain an efficient spermatogenesis at an elevated internal body temperature of 40–41 °C 6,13. In contrast to the efficient spermatogenesis at the elevated internal body temperature (40–41 °C) in birds6,13, mammalian male germ cell was reported to have undergone apoptosis at an internal body temperature of 37 °C 6, thus indicating fundamental differences in spermatogenesis between these two homoeothermic groups6,13. Recent findings suggest that the testis-enriched heat shock protein A2 (HSPA2), which is reported to exhibit temperature-dependent yet contrasting patterns of expression in mammalian3,15,16 and avian species (e.g.17,18), play a crucial role in spermatogenesis and male fertility3,19,20,21,22. Its expression in the testis or in spermatozoa is reported to decrease in men with abnormal spermatogenesis23,24,25,26,27,28. Nevertheless, such striking differences in the mammalian and avian spermatogenesis indicate that HSPA2 may exhibit unique evolutionary trajectory in respective lineages and the avian species are likely to have an adaptive advantage over the scrotal mammals in response to the elevated surrounding temperature (e.g.3,6,15,16,18,29). Under such circumstances, functional modifications due to the adaptive evolutionary changes of certain amino acid residues in the avian HSPA2 are expected.

The molecular chaperone HSPA2, which is a member of the 70 kDa heat shock protein (HSP70) family19,20,22,30,31 and is characterized by the presence of an ATPase domain at the N-terminal followed by a peptide binding domain and a G/P-rich domain at the C-terminal19,30,32, regulates the expression of sperm surface receptors involved in sperm-oocyte recognition in humans19,20,21, thus suggesting its vital role in fertility. While HSPA2 was reported to be down-regulated in mammalian male germ cells in response to heat stress3,15,16,29, this gene was up-regulated in chicken18. Collectively, such contrasting patterns of expression of HSPA2 in birds and mammals in response to acute heat stress further indicate that despite being evolutionarily highly conserved across the metazoan lineages22,31, this chaperone may exhibit distinct selection profiles in the avian and mammalian lineages.

Given such temperature-sensitive contrasting patterns of expression of this testis-enriched HSPA2 in the avian and mammalian germ cells3,15,16,18,29, we hypothesize that avian HSPA2 may have experienced positive selection and is therefore likely to have evolved adaptively, whereas the mammalian HSPA2 may have experienced intense purifying selection. By quantifying the ratio of the rates of non-synonymous (amino acid replacement) (dN) and synonymous (no change in amino acid) (dS) substitutions (ω = dN/dS), which has been widely used to detect the footprints of natural selection in the protein-coding genes33, we seek to evaluate the pervasive role of positive selection in the evolution of avian and mammalian HSPA2.

Results and Discussion

Phylogenetic analyses based on the amino acid sequences representing the members of HSP70 family revealed the orthology and monophyly of the avian and mammalian HSPA2 with strong nodal support (Fig. 1). The phylogenetic affiliations of other members of the family are consistent with the results of a previous study31. The avian and mammalian HSPA2 gene trees (Fig. 2) revealed phylogenetic consistency in the placement of each group/order with the previously reported genome-based avian and mammalian phylogenies34,35,36,37. However, neither of the gene trees showed habitat/temperature-gradient-based phylogenetic clustering, rather the clusterings are consistent with their systematic classifications (i.e., family; order). Given the long evolutionary history of HSPA222,31, the observation of high sequence homologies (and low sequence divergence) of HSPA2 at the amino acid and nucleotide levels between and within the mammalian and avian groups (Table 1; Fig. S1) further indicates that this testis-enriched protein is evolutionarily conserved across the metazoan lineages. Based on this observation, one might speculate that HSPA2 is likely to have been subjected to intense purifying selection throughout the mammalian and avian evolution. However, despite being evolutionarily highly conserved, the observation of striking differences in gene expressions3,15,16,18,29, testicular physiology, spermatogenesis4,6,38, as well as its crucial role in male fertility3,6,19,20,21,22, prompted us to hypothesize that this testis-enriched HSPA2 may have been subjected to differential selection pressures in these two groups.

Table 1 Estimates of net evolutionary divergence (in %) between avian and mammalian groups and within each group.
Figure 1
figure 1

Maximum likelihood (ML) tree inferred from the complete amino acid sequences representing multiple species depicting relationships among the members of HSP70 family.

Bootstrap values >70 are shown at the base of the nodes. Common name, scientific name and accession numbers are shown.

Figure 2
figure 2

ML trees inferred from the complete nucleotide coding sequence data of (A) avian and (B) mammalian HSPA2. Bootstrap values >70 are shown at the base of the nodes. Common name, scientific name, nucleotide accession numbers and systematic order of each species are shown. Spermatogenesis in birds6,13 and mammals2,4,6,14 occurs at the internal body temperature and at 2–8 °C lower than the core body temperature, respectively.

Interestingly, while the null models (M1a and M7) that assume no positive selection could not be rejected for the mammalian HSPA2 (p > 0.05; Table 2), the corresponding alternative selection models (M2a, M8) are the best-fit models for the avian HSPA2 (p < 0.05; Table 2), indicating the pervasive role of positive selection in the evolution of avian HSPA2. Consistently, analyses using other methods provide evidence of positive selection on the avian HSPA2 (Table 3). The differences in the selection profile between mammalian and avian HSPA2 could possibly be associated with the response of HSPA2 to heat stress/temperature. For instance, while exposure of the scrotal mammalian testes to high temperature has been reported to cause impaired spermatogenesis2,5, birds maintain an efficient spermatogenesis at the elevated internal body temperature6,13. This indicates that the avian HSPA2, which has been subjected to positive selection, could possibly adapt to elevated temperature, whereas the mammalian HSPA2, which is constrained by purifying selection, may unlikely function efficiently due to prolonged exposure to high temperature. Nixon et al.19 proposed three possible factors such as (i) genetic mutations in the encoding sequence of Hspa2 gene, (ii) epigenetic regulation and (iii) exposure of developing germ cells to oxidative stress, which may be related to impaired spermatogenesis in mammals19. However, given the high sequence homology of HSPA2 across the metazoans19,22,30,31, increasing incidence of male infertility in human populations due to genetic mutations in the encoding Hspa2 gene is highly unlikely. The other two explanations of epigenetic regulation and oxidative stress19, however, are more plausible explanations for the high incidence of male infertility in the human populations. Prolonged exposure to high temperature, including the prolonged use of laptop computers, was proven to significantly increase scrotal temperature39 and therefore, may adversely affect spermatogenesis1,2,5,8. Such prolonged exposure to high temperature may be linked to the gene expression and oxidative stress. Additionally, factors such as age40,41,42,43,44,45, exposure to pollutants and individual lifestyle could also affect spermatogenesis12. However, how these factors adversely affect the spermatogenesis and the underlying mechanisms need to be explored.

Table 2 Likelihood Ratio Tests (LRTs) statistic for positive selection on the avian and mammalian HSPA2.
Table 3 Positively selected sites detected in the avian and mammalian HSPA2 under different methods.

Taken together with the results of previous studies2,5,6, our study indicates that the observed adaptive evolutionary changes in certain amino acid residues of the avian HSPA2 are likely temperature-driven. Of the four amino acid residues that were detected to be under positive selection in the avian HSPA2 (Table 3), three residues occur close to one another and are located at the end of the gene (i.e., C-terminal), a pattern that is consistent with previous studies46. Further, given the fact that protein secondary structure has a significant effect on the rate of protein adaptation46,47, we sought to find the location of the positively selected sites in the avian HSPA2 protein secondary structure. Interestingly, while three sites (sites 540, 559 and 572) are located at the peptide binding domain, only one site (site 138) is located at the ATPase domain. Of the three sites at the peptide binding domain, site-540 and site-572 are on the α-helix with high confidence and site-559 falls at the β-sheet, however, with low confidence (Fig. 3). While detections of positively selected sites at the coil regions are common46, the detections of positively selected sites at the helix and β-sheets, which are less tolerant to molecular adaptation, are less common46. However, if any of the residues in the helix and β structures were detected to be under positive selection, the protein may have important functional consequences46. Under this circumstance, the avian HSPA2 may have exhibited functional diversification driven by the positive Darwinian selection. Intuitively, although the specific roles of these three positively selected amino acid residues located at the peptide binding domain are unknown, given the regulatory role of HSPA2 in sperm-oocyte recognition in humans19,20,21, these amino acid residues in avian HSPA2 may have important functional significance. Nevertheless, these predictions warrant further investigations on the biological significance of these positively selected residues in relation to temperature/heat adaptation.

Figure 3
figure 3

Predicted secondary structure and functional domains of chicken HSPA2.

ATPase domain (~385 amino acids), peptide binding domain (~225 amino acids) and G/P-rich region (~30 amino acids) are shown. Predicted domains (α-helix, β-sheet and coil) and their respective confidence values (0, low; 9, high) are also shown. Two of the positively selected sites (site-540 and site-572) are predicted to be in the α-helix located at the peptide binding domain, whereas site-559 is in the coil of the peptide binding domain. Site-138 is in the coil at the ATPase domain. Secondary structure was predicted by using the PSIPRED server58. Functional domains were identified based on the previously published reports30,32.

Collectively, the present study indicates that while mammalian HSPA2 has been constrained by purifying selection, the avian HSPA2 has been subjected to positive selection and therefore, has an adaptive advantage over the mammalian HSPA2. Mammals with testicular descent, including our own species Homo sapiens, therefore, is at a greater risk in the event of prolonged exposure of the testicle to high temperature, as it would ultimately affect the spermatogenesis. However, further studies are required to explore the possible involvement of multiple testis-specific temperature-dependent genes that affect spermatogenesis and male fertility, their expression patterns in response to heat stress as well as how natural selection has shaped the evolution of those genes (if any) in the avian and mammalian groups.

Methods

Complete nucleotide coding sequences of the avian and mammalian HSPA2 as well as the complete nucleotide and amino acid sequences of other members of the HSP70 family were retrieved from GenBank48. Amino acid and nucleotide coding sequences were aligned using the MUSCLE algorithm implemented in MEGA ver. 5 49. To determine the phylogenetic relatedness and monophyly of the avian and mammalian HSPA2, we reconstructed maximum likelihood (ML)-based HSP70 phylogeny using the previously reported complete amino acid sequences representing the members of the HSP70 family as reference sequences31. The accession numbers of the amino acid sequences that were used as reference sequences for the respective members are shown in Fig. 1. The best-fit amino acid substitution model was selected by the Bayesian Information Criterion (BIC) implemented in MEGA 549. The amino acid based HSP70 ML phylogeny was reconstructed under the JTT (Jones-Taylor-Thornton) model with gamma distribution shape parameter (G) using MEGA 549. Using the same program nodal supports were estimated with 1000 bootstrap replicates. To assess the strength of natural selection on the avian and mammalian HSPA2, we retrieved respectively 56 avian HSPA2 complete nucleotide coding sequences representing 52 species, 41 families and 31 orders, as well as 29 mammalian HSPA2 complete nucleotide coding sequences representing 29 species, 16 families and 6 orders from GenBank48. The nucleotide accession numbers of the avian and mammalian HSPA2 used in the present study are shown in Fig. 2A,B. The evolutionary divergence between the avian and mammalian groups and within each group was estimated using the MEGA program49. Standard errors of the distance estimates were estimated with 1000 replicates. Using the PhyML ver 3 50 program, ML-based mammalian and avian HSPA2 phylogenies were constructed under the best-fit nucleotide substitution models of the respective data sets. The best-fit nucleotide substitution models for the respective data sets were selected by BIC implemented in jModelTest2 51. Phylogenetic trees were visualized using the FigTree 1.4.2 software (available at http://tree.bio.ed.ac.uk/software/figtree/).

The test for positive selection was performed using the ML based codon substitution models33 implemented in the CODEML program of PAML package52. The likelihood ratio test (LRT) was used to compare the null models (M1a and M7) that assume no positive selection (ω < 1) with their corresponding alternative models (M2a and M8) that assume positive selection (ω > 1), respectively33. Additionally, sites under positive selection were also detected using the SLAC (single-likelihood ancestor counting), FEL (fixed effects likelihood), IFEL (internal fixed effects likelihood), REL (random effects likelihood) and FUBAR (fast unbiased Bayesian approximation) methods53,54,55 implemented in the datamonkey server56.

Secondary structure predictions and the confidence values for the avian HSPA2 protein were made by using the PSIPRED57 and the Protein Structure Prediction Server (http://bioinf.cs.ucl.ac.uk/psipred)58.

Additional Information

How to cite this article: Padhi, A. et al. Testis-enriched heat shock protein A2 (HSPA2): Adaptive advantages of the birds with internal testes over the mammals with testicular descent. Sci. Rep. 6, 18770; doi: 10.1038/srep18770 (2016).