Sequencing and comparative analysis of a conserved syntenic segment in the Solanaceae

Comparative genomics is a powerful tool for gaining insight into genomic function and evolution. However, in plants, sequence data that would enable detailed comparisons of both coding and noncoding regions have been limited in availability. Here we report the generation and analysis of sequences for an unduplicated conserved syntenic segment (CSS) in the genomes of five members of the agriculturally important plant family Solanaceae. This CSS includes a 105-kb region of tomato chromosome 2 and orthologous regions of the potato, eggplant, pepper, and petunia genomes. With a total neutral divergence of 0.73-0.78 substitutions/site, these sequences are similar enough that most noncoding regions can be aligned, yet divergent enough to be informative about evolutionary dynamics and selective pressures. The CSS contains 17 distinct genes with generally conserved order and orientation, but with numerous small-scale differences between species. Our analysis indicates that the last common ancestor of these species lived approximately 27-36 million years ago, that more than one-third of short genomic segments (5-15 bp) are under selection, and that more than two-thirds of selected bases fall in noncoding regions. In addition, we identify genes under positive selection and analyze hundreds of conserved noncoding elements. This analysis provides a window into 30 million years of plant evolution in the absence of polyploidization.     

Genomic footprints of speciation in Atlantic eels (Anguilla anguilla and A. rostrata)

The importance of speciation‐with‐geneflow scenarios is increasingly appreciated. However, the specific processes and the resulting genomic footprints of selection are subject to much discussion. We studied the genomics of speciation between the two panmictic, sympatrically spawning sister species; European (Anguilla anguilla) and American eel (A. rostrata). Divergence is assumed to have initiated more than 3 Ma, and although low gene flow still occurs, strong postzygotic barriers are present. Restriction‐site‐associated DNA (RAD) sequencing identified 328 300 SNPs for subsequent analysis. However, despite the presence of 3757 strongly differentiated SNPs (F_ST > 0.8), sliding window analyses of F_ST showed no larger genomic regions (i.e. hundreds of thousands to millions of bases) of elevated differentiation. Overall F_ST was 0.041, and linkage disequilibrium was virtually absent for SNPs separated by more than 1000 bp. We suggest this to reflect a case of genomic hitchhiking, where multiple regions are under directional selection between the species. However, low but biologically significant gene flow and high effective population sizes leading to very low genetic drift preclude accumulation of strong background differentiation. Genes containing candidate SNPs for positive selection showed significant enrichment for gene ontology (GO) terms relating to developmental processes and phosphorylation, which seems consistent with assumptions that differences in larval phase duration and migratory distances underlie speciation. Most SNPs under putative selection were found outside coding regions, lending support to emerging views that noncoding regions may be more functionally important than previously assumed. In total, the results demonstrate the necessity of interpreting genomic footprints of selection in the context of demographic parameters and life‐history features of the studied species.     

Nucleotide sequence variation of the chloroplast trnK/matK region in two wild Fagopyrum (Polygonaceae) species, F. leptopodum and F. statice

Nucleotide sequence polymorphisms of the intron of the chloroplast trnK (UUU) gene, including a matK gene, were investigated within two wild Fagopyrum species, F. leptopodum and F. statice, to assess the degree and pattern of the inter- and intraspecific differences in coding and noncoding chloroplast DNA regions in higher plants. Ten and five accessions were used for F. leptopodum and F. statice, respectively. The length of the trnK intron region in these species ranged from 2494 to 2506 bp. In the trnK intron, the net nucleotide substitution number per site (Da) between the two species was 0.00109, lower than the nucleotide diversity (pi), 0.00195 for F. leptopodum and 0.00144 for F. statice, suggesting a low level of interspecific divergence. This result seems to be due to the phylogenetic pattern that both species are interspersed with each other, which was revealed by the phylogenetic analyses based on the nucleotide substitutions and indels. In the matK gene region (1524 bp), seven and two nucleotide substitutions were found within F. leptopodum and F. statice, respectively. All of the nine nucleotide substitutions (eight of which were nonsynonymous) within and between F. leptopodum and F. statice were clustered in the 5' part of the matK gene region, and no variation was found in the 3' part. This suggests that most of the 3' part is occupied by the conserved domains that are important for the binding activity of the gene product to the precursor mRNA, and therefore implies that the 3' part is more functionally constrained than the 5' part.     

Human-chimpanzee DNA sequence variation in the four major genes of the renin angiotensin system

The renin angiotensin system (RAS) is involved in blood pressure control and water/sodium metabolism. The genes encoding the proteins of this system are candidate genes for essential hypertension. The RAS involves four main molecules: angiotensinogen, renin, angiotensin I-converting enzyme, and the angiotensin II type 1 receptor (encoded by the genes AGT, REN, DCP1, and AGTR1, respectively). We performed a molecular screening over 17,037 bp of the coding and 5' and 3' untranslated regions of these genes, from three to six common chimpanzees. We identified 44 single-nucleotide polymorphisms (SNPs) in chimpanzee samples, including 18 coding-region SNPs, 5 of which led to an amino acid replacement. We observed common and different features at various sites (synonymous, nonsynonymous, and noncoding) within and between the four chimpanzee genes: (1) the nucleotide diversity at noncoding sites was similar; (2) the nucleotide diversity at nonsynonymous sites was low, probably reflecting purifying selection, except for the AGT gene; (3) the nucleotide diversity at synonymous sites, which was dependent on the G+C content at the third position of the codon, was high, except for the AGTR1 gene. Comparison of the chimpanzee SNPs with those previously reported for humans identified 119 sites with fixed differences (including 62 coding sites, 17 of which resulted in amino acid differences between the species). Analysis of polymorphism within species and divergence between species shed light on the evolutionary constraints on these genes. In particular, comparison of the pattern of mutation at polymorphic and fixed sites between humans and chimpanzees suggested that the high G+C content of the DCP1 gene was maintained by positive selection at its silent sites. Finally, we propose 68 ancestral alleles for the human RAS genes and discuss the implications for their use in future hypertension-susceptibility association studies.     

SRY evolution in Cebidae (Platyrrhini: Primates)

Sex determination in mammals is dependent on the presence of SRY, which codes for a protein with a DNA binding motif (the HMG-box domain). Here we analyze the evolution of SRY among seven genera of New World monkeys belonging to the family Cebidae. Estimates of the number of synonymous and nonsynonymous substitutions indicated the absence of positive selection acting on SRY evolution. The presence of indels at the C-terminus coding region in different genera and species maintained an open reading frame, indicating a selective pressure constraining the evolution of this coding region. Available data on the fertility of natural and captive interspecific hybrids failed to show any relationship between SRY evolution and speciation for the genera herein studied. Our phylogenetic arrangement for Cebidae genera was similar to previous topologies based on mitochondrial and autosomal DNA sequences. This arrangement also corroborated the division of Cebus into two species groups. However, for Callithrix the differences among SRY topology and those derived from autosomal and mitochondrial genes suggested a Y-chromosome ancestral polymorphism.     

Kappa-chain constant-region gene sequences in genus Rattus: coding regions are diverging more rapidly than noncoding regions

We have determined the nucleotide sequence of a 1,200-base pair (bp) genomic fragment that includes the kappa-chain constant-region gene (C kappa) from two species of native Australian rodents, Rattus leucopus cooktownensis and Rattus colletti. Comparison of these sequences with each other and with other rodent C kappa genes shows three surprising features. First, the coding regions are diverging at a rate severalfold higher than that of the nearby noncoding regions. Second, replacement changes within the coding region are accumulating at a rate at least as great as that of silent changes. Third, most of the amino acid replacements are localized in one region of the C kappa domain--namely, the carboxy-terminal "bends" in the alpha-carbon backbone. These three features have previously been described from comparisons of the two allelic forms of C kappa genes in R. norvegicus. These data imply the existence of considerable evolutionary constraints on the noncoding regions (based on as yet undetermined functions) or powerful positive selection to diversify a portion of the constant-region domain (whose physiological significance is not known). These surprising features of C kappa evolution appear to be characteristic only of closely related C kappa genes, since comparison of rodent with human sequences shows the expected greater conservation of coding regions, as well as a predominance of silent nucleotide substitutions within the coding regions.      

Nucleotide Variation and Divergence in the Histone Multigene Family in Drosophila Melanogaster

Nucleotide differences in the histone H3 gene family in Drosophila melanogaster were studied on three levels: (1) within a chromosome, (2) within a population and (3) between species (D. melanogaster and Drosophila simulans). The average difference within the H3 gene within a chromosome was 0.0040 per nucleotide site, about 52% of that within a population (0.0077). The proportion of divergent sites between the two species was 0.0575, which is about 8.5 times the difference within a species. The distribution of divergence between species was similar to that of variation within a species. Divergence and variation were noted to be greatest in the 3' noncoding region and least in the coding region. Values intermediate between these were found for the 5' noncoding region. Divergence and variation in silent sites exceeded those in the total coding region, thus indicating possible purifying selection for amino-acid-altering change. Phylogenetic relations among H3 genes and genetic differences on these three levels are evidence for the concerted evolution of the histone gene family. The molecular mechanism by which variation is produced and maintained is discussed.     

小麂Sry基因的克隆和测序

应用人的性别决定基因SRY(Sex-determining Region Y gene,SRY)中HMG框内的一对引物,对小麂细胞株的基因组DNA进行PCR扩增,得到雄性小麂细胞的220bp扩增产物,而在雌性小麂细胞中未发现扩增产物。将雄性小麂细胞的220bp扩增产物通过T-A互补法克隆到质粒pGEM-T 载体中,筛选阳性克隆进行DNA测序。测序结果表明小麂Sry基因保守序列与人的SRY基因保守区相同碱基的比值为152/184,达到82.6%。提示小麂Sry基因与人的SRY基因存在着较高的同源性,说明SRY基因在进化过程中高度保守。 Abstract:Using the primers from SRY gene——HMG Box for PCR amplification in genomic DNA of Muntiacus reevesi cell strains,a 220bp fragment was obtained in the male but not in the female.The 220bp fragment was cloned into the pGEM-T vector using T/A clone method.The identified positive clone was sequenced.The result shows that 82.6% nucleotides(152bp/184bp) are homologous between Muntiacus Sry and human SRY gene.It suggests that SRY is highly conserved during evolution.     

High levels of nucleotide diversity in the European rabbit (Oryctolagus cuniculus) SRY gene

We have sequenced 2,388 bp of the European rabbit sex determining region Y (SRY) gene. These data provide a 10-fold increase in the coverage of the Y chromosome in this species, including the entire open reading frame of the SRY, the polyadenylation signal, and two repetitive sequences in the 5' -region. A survey of 2021 bp of this gene in eight domestic breeds and four wild individuals revealed a total of nine single nucleotide polymorphisms and one indel, defining two deeply divergent lineages. The resulting estimation of nucleotide diversity (pi=1.34 x10(-3)) is very high when compared with other species, but no variability was detected among the domestic breeds. This study represents a first step in the characterization of the European rabbit Y chromosome and its variability. These sequences can be used in additional phylogeographical analyses of the European rabbit and other Leporid species, as well as in evolutionary studies of sex determination and the Y chromosome in wild species.     

Patterns of natural selection at the Alcohol dehydrogenase gene of Drosophila americana

Similar outcomes are often observed in species exposed to similar selective regimes, but it is unclear how often the same mechanism of adaptive evolution is followed. Here we present an analysis of selection affecting sequence variation in the Alcohol dehydrogenase (Adh) gene of Drosophila americana, a species endemic to a large climate range that has been colonized by D. melanogaster. Unlike D. melanogaster, there is no evidence of selection on allozymes of ADH across the sampled range. This indicates that if there has been a similar adaptive response to climate in D. americana, it is not within the coding region of Adh. Instead, analyses of a combined dataset containing 86 alleles of Adh reveal purifying selection on the Adh gene, especially within its intron sequences. Frequency spectra of derived unpreferred variants at synonymous sites indicate that these sites are affected by weak purifying selection, but the deviation from neutrality is less drastic than observed for derived variants in noncoding introns. This contrast further supports the notion that noncoding sites in Drosophila are often subject to stronger selection pressures than synonymous sites.     

Potential evolutionary influences on overlapping reading frames in the bovine leukemia virus pXBL region

Bovine leukemia virus contains a pXBL region encoding the 3' parts of four regulatory proteins (Tax, Rex, G4, R3) in overlapping reading frames. Here we report the pXBL polymorphisms of 30 isolates from four countries. Rates of overall and synonymous substitutions were consistently lower, and nucleotide/amino acid composition bias and codon bias higher, in more-overlapped than in less-overlapped regions. Ratios of nonsynonymous/synonymous substitutions were lowest in the tax gene and its subregions. The 5' parts of the four genes showed selection patterns corresponding to their genomic context outside of the pXBL region. Longer G4 variants due to a natural stop codon mutation had additional triple overlap with reduced sequence variability. These data support the concept that a higher level of overlapping in coding regions correlates with greater evolutionary constraint. Tax, the most conserved among the four regulatory proteins, showed purifying selection consistent with its importance in the viral life cycle.     

Diverse selective modes among orthologs/paralogs of the chalcone synthase (Chs) gene family of Arabidopsis thaliana and its relative A. halleri ssp. gemmifera

As a model system, Arabidopsis thaliana and its wild relatives have played an important role in the study of genomics and evolution in plants. In this study, we examined the genetic diversity of the chalcone synthase (Chs) gene, which encodes a key enzyme of the flavonoid pathway and is located on chromosome five, as well as two Chs-like genes on the first and fourth chromosomes of Arabidopsis. The objectives of the study are to determine if natural selection operates differentially on the paralogs of the Chs gene family in A. thaliana and Arabidopsis halleri ssp. gemmifera. The mode of selection was inferred from Tajima's D values from noncoding and coding regions, as well as from the ratio of nonsynonymous to synonymous substitutions. Both McDonald-Kreitman and HKA tests revealed the effects of selection on the allelic distribution, except for the chromosome 1 paralog in ssp. gemmifera. The Chs gene on chromosome 5 was under purifying selection in both species. Significant, negative Tajima's D values at synonymous sites and positive Fay and Wu's H values within coding region, plus reduced genetic variability in introns, indicated effects of background selection in shaping the evolution of this gene region in A. thaliana. The Chs paralog on chromosome 1 was under positive selection in A. thaliana, while interspecific introgression and balancing selection determined the fates of the paralog and resulted in high heterogeneity in ssp. gemmifera. Local adaptation differentiated populations of Japan and China at the locus. In contrast, the other Chs-paralog of chromosome 4 was shaped by purifying selection in A. thaliana, while under positive selection in ssp. gemmifera, as indicated by dn/ds>1. Moreover, these contrasting patterns of selection have likely resulted in functional divergence in Arabidopsis, as indicated by radical amino acid substitutions at the chalcone synthase/stilbene synthase motif of the Chs genes. Unlike previous studies of the evolutionary history of A. thaliana, the high levels of genetic diversity in most gene regions of Chs paralogs and nonsignificant Tajima's D in the intron sequences of the Chs gene family in A. thaliana did not reflect the effects of a recent demographic expansion.     

山鹧鸪属鸟类线粒体基因组的比较及系统发育研究

海南山鹧鸪(Arborophila ardens)对生境选择比较严格,种群数量稀少,属于濒危物种。为进一步研究山鹧鸪属的进化和系统发育关系,文章利用Illumina Hiseq2000高通量测序技术获得了海南山鹧鸪线粒体全基因组序列,从比较基因组学角度分析了4种山鹧鸪鸟类的线粒体基因组特征,并探讨了山鹧鸪属鸟类的系统发育地位。研究结果表明：(1) 海南山鹧鸪线粒体基因组长度为16 730 bp,编码13个蛋白质编码基因、2个核糖体RNA基因、22个转运RNA基因以及1个控制区;(2) 山鹧鸪属物种受到了纯化选择的作用,且在进化过程中积累了更多的非同义替换;(3) 山鹧鸪属位于雉科鸟类系统树的基部位置,其中白眉山鹧鸪与红喉山鹧鸪互为姐妹群,海南山鹧鸪位于山鹧鸪属的基部位置,与其他3种山鹧鸪鸟类的亲缘关系较远。     

The genetic mosaic suggests a new role for hitchhiking in ecological speciation

Early in ecological speciation, the genomically localized effects of divergent selection cause heterogeneity among loci in divergence between incipient species. We call this pattern of genomic variability in divergence the 'genetic mosaic of speciation'. Previous studies have used F(ST) outliers as a way to identify divergently selected genomic regions, but the nature of the relationship between outlier loci and quantitative trait loci (QTL) involved in reproductive isolation has not yet been quantified. Here, we show that F(ST) outliers between a pair of incipient species are significantly clustered around QTL for traits that cause ecologically based reproductive isolation. Around these key QTL, extensive 'divergence hitchhiking' occurs because reduced inter-race mating and negative selection decrease the opportunity for recombination between chromosomes bearing different locally adapted QTL alleles. Divergence hitchhiking is likely to greatly increase the opportunity for speciation in populations that are sympatric, regardless of whether initial divergence was sympatric or allopatric. Early in ecological speciation, analyses of population structure, gene flow or phylogeography based on different random or arbitrarily chosen neutral markers should be expected to conflict--only markers in divergently selected genomic regions will reveal the evolutionary history of adaptive divergence and ecologically based reproductive isolation. Species retain mosaic genomes for a very long time, and gene exchange in hybrid zones can vary dramatically among loci. However, in hybridizing species, the genomic regions that affect ecologically based reproductive isolation are difficult to distinguish from regions that have diverged for other reasons.     

PCR扩增泥鳅和大鳞副泥鳅SRY盒基因

以特异扩增人ＳＲＹ基因保守区的一对引物,研究了泥鳅和大鳞副泥鳅基因组中ＳＲＹ盒基因的扩增。结果表明,该引物可以在泥鳅中扩增出四条带,其长度分别为２００,５５０、９４０和１０００ｂｐ。在大鳞副泥鳞中扩增出三条带,大小为２００,５５０和９００ｂｐ。经Ｓｏｕｔｈｅｒｎ杂交显示出二者的阳性带为２００和５５０ｂｐ。阳性带在雌雄个体间和两个物种间无差异。     

Adaptive functional divergence among triplicated alpha-globin genes in rodents

The functional divergence of duplicated genes is thought to play an important role in the evolution of new developmental and physiological pathways, but the role of positive selection in driving this process remains controversial. The objective of this study was to test whether amino acid differences among triplicated alpha-globin paralogs of the Norway rat (Rattus norvegicus) and the deer mouse (Peromyscus maniculatus) are attributable to a relaxation of purifying selection or to a history of positive selection that has adapted the gene products to new or modified physiological tasks. In each rodent species, the two paralogs at the 5'-end of the alpha-globin gene cluster (HBA-T1 and HBA-T2) are evolving in concert and are therefore identical or nearly identical in sequence. However, in each case, the HBA-T1 and HBA-T2 paralogs are distinguished from the third paralog at the 3'-end of the gene cluster (HBA-T3) by multiple amino acid substitutions. An analysis of genomic sequence data from several rodent species revealed that the HBA-T3 genes of Rattus and Peromyscus originated via independent, lineage-specific duplication events. In the independently derived HBA-T3 genes of both species, a likelihood analysis based on a codon-substitution model revealed that accelerated rates of amino acid substitution are attributable to positive directional selection, not to a relaxation of purifying selection. As a result of functional divergence among the triplicated alpha-globin genes in Rattus and Peromyscus, the red blood cells of both rodent species contain a mixture of functionally distinct alpha-chain hemoglobin isoforms that are predicted to have different oxygen-binding affinities. In P. maniculatus, a species that is able to sustain physiological function under conditions of chronic hypoxia at high altitude, the coexpression of distinct hemoglobin isoforms with graded oxygen affinities is expected to broaden the permissible range of arterial oxygen tensions for pulmonary/tissue oxygen transport.     

Patterns of natural selection at the Alcohol dehydrogenase gene of Drosophila americana

Similar outcomes are often observed in species exposed to similar selective regimes, but it is unclear how often the same mechanism of adaptive evolution is followed. Here we present an analysis of selection affecting sequence variation in the Alcohol dehydrogenase (Adh) gene of Drosophila americana, a species endemic to a large climate range that has been colonized by D. melanogaster. Unlike D. melanogaster, there is no evidence of selection on allozymes of ADH across the sampled range. This indicates that if there has been a similar adaptive response to climate in D. americana, it is not within the coding region of Adh. Instead, analyses of a combined dataset containing 86 alleles of Adh reveal purifying selection on the Adh gene, especially within its intron sequences. Frequency spectra of derived unpreferred variants at synonymous sites indicate that these sites are affected by weak purifying selection, but the deviation from neutrality is less drastic than observed for derived variants in noncoding introns. This contrast further supports the notion that noncoding sites in Drosophila are often subject to stronger selection pressures than synonymous sites.