Immunoglobulin CH gene family in hominoids and its evolutionary history.

The organization of the human immunoglobulin CH gene suggests that a gene duplication involving the C gamma-C gamma-C epsilon-C alpha region has occurred during evolution. We previously showed that both chimpanzee and gorilla have two 5'-C epsilon-C alpha-3', as in human, and that orangutan, gibbon, and Old World monkeys have one C epsilon gene and one, two, and one C alpha gene(s), respectively. In addition to these clustered CH genes, there is one processed C epsilon pseudogene in each species. The present study revealed that orangutan and crab-eating macaque (an Old World monkey) both have one 5'-C epsilon-C alpha-3' and that gibbon has two 5'-C epsilon-C alpha-3', one C epsilon gene of which is completely deleted. By Southern analysis, the number of C gamma genes in all the nonhuman hominoids was estimated to be four to five, as in human, in comparison with two for crab-eating macaque. The C mu and C delta genes were estimated to be present as single copies in both hominoids and crab-eating macaque. Furthermore, it was proved that there are two copies of the C epsilon 5'-flanking region in both the orangutan and the gibbon genomes. These results show that gene duplication including the C gamma-C gamma-C epsilon-C alpha genes occurred in the common ancestor of hominoids and that subsequent deletion of the C epsilon gene (in orangutan, including one of the C alpha genes) occurred independently in each hominoid species.     

Evolution of the X-linked Zinc Finger Gene and the Y-linked Zinc Finger Gene in Primates

We have sequenced the partial exon of the zinc finger genes (ZFX and ZFY) in 5 hominoids, 2 Old World monkeys, 1 New World monkey, and 1 prosimian. Among these primate species, the percentage similarities of the nucleotide sequence of the ZFX gene were 96-100% and 91.2-99.7% for the ZFY gene. Of 397 sites in the ZFX and ZFY gene sequences, 20 for ZFX gene and 42 for ZFY gene were found to be variable. Substitution causes 1 amino acid change in ZFX, and 5 in ZFY, among 132 amino acids. The numbers of synonymous substitutions per site (Ks) between human and the chimpanzee, gorilla and orangutan for ZFY gene were 0.026, 0.033, and 0.085, respectively. In contrast, the Ks value between human and hominoid primates for the ZFX gene was 0.008 for each comparison. Comparison of the ZFX and ZFY genes revealed that the synonymous substitution levels were higher in hominoids than in other primates. The rates of synonymous substitution per site per year were higher in the ZFY exon than in the SRY exon, and higher in the ZFY exon than in the ZFY intron, in hominoid primates.     

Nucleotide sequences of immunoglobulin-epsilon pseudogenes in man and apes and their phylogenetic relationships

To understand the phylogenetic relationships between hominoids, the nucleotide sequences of immunoglobulin-epsilon processed pseudogenes from chimpanzee, gorilla and orangutan were determined. The basic structures of these processed pseudogenes agreed with their human counterpart. Although the degrees of nucleotide differences between man and the African apes had no statistical significance, all the analytical data examined supported the theory that chimpanzee is the closest relative of man. This result was consistent with that deduced by our recent qualitative study. Studies on the nucleotide sequences of globin genes have suggested that the molecular clock runs more slowly in hominoids than in non-hominoid primates. According to the present data, however, further retardation of the evolutionary rate was not observed in the human lineage. Assuming that orangutan diverged 14 million years ago and that the evolutionary rate between the orangutan lineage and the lineage leading to the other three species is constant, the divergence dates of chimpanzee and gorilla were estimated to be 4.9(+/- 0.9) and 5.9(+/- 0.9) million years ago, respectively.     

Simian homologues of human herpesvirus 8

Gamma-herpesviruses can be found in most primates including Old World an New World monkeys. The gamma-herpesvirinae are grouped into two classes: lymphocryptoviruses (gamma1) and rhadinoviruses (gamma2). The lymphocryptoviruses include Epstein-Barr virus, lymphocryptovirus of rhesus monkeys, and Herpesvirus papio of baboons. Rhadinoviruses that infect New World monkeys include Herpesvirus saimiri, whose natural host is the squirrel monkey, and Herpesvirus ateles, which infects spider monkeys. Rhadinoviruses that infect hominoids and Old World monkeys include Kaposi's sarcoma-associated herpesvirus, also known as HHV-8, and rhesus monkey rhadinovirus.     

Evolutionary rate variation in Old World monkeys

We analysed over 8 million base pairs of bacterial artificial chromosome-based sequence alignments of four Old World monkeys and the human genome. Our findings are as follows. (i) Genomic divergences among several Old World monkeys mirror those between well-studied hominoids. (ii) The X-chromosome evolves slower than autosomes, in accord with ‘male-driven evolution’. However, the degree of male mutation bias is lower in Old World monkeys than in hominoids. (iii) Evolutionary rates vary significantly between lineages. The baboon branch shows a particularly slow molecular evolution. Thus, lineage-specific evolutionary rate variation is a common theme of primate genome evolution. (iv) In contrast to the overall pattern, mutations originating from DNA methylation exhibit little variation between lineages. Our study illustrates the potential of primates as a model system to investigate genome evolution, in particular to elucidate molecular mechanisms of substitution rate variation.     

Alpha1,4-fucosyltransferase activity: a significant function in the primate lineage has appeared twice independently

In the animal kingdom the enzymes that catalyze the formation of alpha1,4 fucosylated-glycoconjugates are known only in apes (chimpanzee) and humans. They are encoded by FUT3 and FUT5 genes, two members of the Lewis FUT5-FUT3-FUT6 gene cluster, which had originated by duplications of an alpha3 ancestor gene. In order to explore more precisely the emergence of the alpha1,4 fucosylation, new Lewis-like fucosyltransferase genes were studied in species belonging to the three main primate groups. Two Lewis-like genes were found in brown and ruffed lemurs (prosimians) as well as in squirrel monkey (New World monkey). In the latter, one gene encodes an enzyme which transfers fucose only in alpha1,3 linkage, whereas the other is a pseudogene. Three genes homologous to chimpanzee and human Lewis genes were identified in rhesus macaque (Old World monkey), and only one encodes an alpha3/4-fucosyltransferase. The ability of new primate enzymes to transfer fucose in alpha1,3 or alpha1,3/4 linkage confirms that the amino acid R or W in the acceptor-binding motif "HH(R/W)(D/E)" is required for the type 1/type 2 acceptor specificity. Expression of rhesus macaque genes proved that fucose transfer in alpha1,4 linkage is not restricted to the hominoid family and may be extended to other Old World monkeys. Moreover, the presence of only one enzyme supporting the alpha1,4 fucosylation in rhesus macaque versus two enzymes in hominoids suggests that this function occurred twice independently during primate evolution.     

Telomere Biology and Cellular Aging in Nonhuman Primate Cells

To determine how cellular aging is conserved among primates, we analyzed the replicative potential and telomere shortening in skin fibroblasts of anthropoids and prosimians. The average telomere length of the New World primates Ateles geoffroyi (spider monkey) and Saimiri sciureus (squirrel monkey) and the Old World primates Macaca mulatta (rhesus monkey), Pongo pygmaeus (orangutan), and Pan paniscus (pigmy chimpanzee) ranged from 4 to 16 kb. We found that telomere shortening limits the replicative capacity of anthropoid fibroblasts and that the expression of human telomerase produced telomere elongation and the extension of their in vitro life span. In contrast the prosimian Lemur catta (ring-tailed lemur) had both long and short telomeres and telomere shortening did not provide an absolute barrier to immortalization. Following a transient growth arrest a subset of cells showing a reduced number of chromosomes overgrew the cultures without activation of telomerase. Here we show that the presence of continuous TTAGGG repeats at telomeres and rigorous control of replicative aging by telomere shortening appear to be conserved among anthropoid primates but is less effective in prosimian lemurs.     

DNA hybridization evidence of hominoid phylogeny: Results from an expanded data set

Summary The living hominoids are human, the two species of chimpanzees, gorilla, orangutan, and nine species of gibbons. The cercopithecoids (Old World monkeys) are the sister group of the hominoids. A consensus about the phylogeny of the hominoids has been reached for the branching order of the gibbons (earliest) and the orangutan (next earliest), but the branching order among gorilla, chimpanzees, and human remains in contention. In 1984 we presented DNA-DNA hybridization data, based on 183 DNA hybrids, that we interpreted as evidence that the branching order, from oldest to most recent, was gibbons, orangutan, gorilla, chimpanzees, and human. In the present paper we report on an expanded data set totaling 514 DNA hybrids, which supports the branching order given above. The ranges for the datings of divergence nodes are Old World monkeys, 25–34 million years (Myr) ago; gibbons, 16.4–23 Myr ago; orangutan, 12.2–17 Myr ago; gorilla, 7.7–11 Myr ago; chimpanzees-human, 5.5–7.7 Myr ago. The possible effects of differences in age at first breeding are discussed, and some speculations about average genomic rates of evolution are presented.     

人猿超科和旧大陆猴7种高等灵长类FKN全基因序列的测定及进化分析

测定人猿超科(人、黑猩猩、大猩猩、红毛猩猩和长臂猿)和旧大陆猴(猕猴和叶猴)7种高等灵长类FKN全基因序列, 探讨其系统进化分析。用简并引物PCR(Degenerated PCR)法分别扩增FKN的3个外显子, 其产物经琼脂糖凝胶回收、纯化后测序, 然后用BioEdit软件剪切拼接FKN基因全序列, 用DNAStar比对后比较基因和氨基酸序列同源性, Mega软件重构FKN基因进化树, 应用Datamonkey分析FKN的负选择位点。序列分析发现人猿超科较旧大陆猴FKN基因除了有散在的点突变外, 还有一明显的30 bp的核苷酸缺失突变; 人FKN基因序列与黑猩猩、大猩猩、红毛猩猩、长臂猿、猕猴和叶猴的同源性分别是99.2%、98.4%、98.1%、96.5%、95.9%和93.8%, 由此推导的氨基酸序列同源性分别是98.5%、98.0%、97.7%、94.7%、93.7%和90.5%; FKN基因进化树表明人与黑猩猩关系更近, FKN基因进化和通常认为的物种进化一致; Datamonkey分析结果显示FKN存在3个负选择位点53Q、84D、239N。成功获得人、黑猩猩、大猩猩、红毛猩猩、长臂猿、猕猴和叶猴7种高等灵长类物种FKN全基因序列, 为后续探讨FKN在高等灵长类物种进化过程中免疫学功能演变及其结构与功能的关系奠定基础。     

Comparative cytogenetics of human chromosome 3q21.3 reveals a hot spot for ectopic recombination in hominoid evolution

Fluorescence in situ hybridization mapping of fully integrated human BAC clones to primate chromosomes, combined with precise breakpoint localization by PCR analysis of flow-sorted chromosomes, was used to analyze the evolutionary rearrangements of the human 3q21.3-syntenic region in orangutan, siamang gibbon, and silvered-leaf monkey. Three independent evolutionary breakpoints were localized within a 230-kb segment contained in BACs RP11-93K22 and RP11-77P16. Approximately 200 kb of the human 3q21.3 sequence was not present on the homologous orangutan, siamang, and Old World monkey chromosomes, suggesting a genomic DNA insertion into the breakpoint region in the lineage leading to humans and African great apes. The breakpoints in the orangutan and siamang genomes were narrowed down to 12- and 20-kb DNA segments, respectively, which are enriched with endogenous retrovirus long terminal repeats and other repetitive elements. The inserted DNA segment represents part of an ancestral duplication. Paralogous sequence blocks were found at human 3q21, approximately 4 Mb proximal to the evolutionary breakpoint cluster region; at human 3p12.3, which contains an independent orangutan-specific breakpoint; and at the subtelomeric and pericentromeric regions of multiple human and orangutan chromosomes. The evolutionary breakpoint regions between human chromosome 3 and orangutan 2 as well their paralogous segments in the human genome coincide with breaks of chromosomal synteny in the mouse, rat, and/or chicken genomes. Collectively our data reveal reuse of the same short recombinogenic DNA segments in primate and vertebrate evolution, supporting a nonrandom breakage model of genome evolution.     

Plasticity of human chromosome 3 during primate evolution

Comparative mapping of more than 100 region-specific clones from human chromosome 3 in Bornean and Sumatran orangutans, siamang gibbon, and Old and New World monkeys allowed us to reconstruct ancestral simian and hominoid chromosomes. A single paracentric inversion derives chromosome 1 of the Old World monkey Presbytis cristata from the simian ancestor. In the New World monkey Callithrix geoffroyi and siamang, the ancestor diverged on multiple chromosomes, through utilizing different breakpoints. One shared and two independent inversions derive Bornean orangutan 2 and human 3, implying that neither Bornean orangutans nor humans have conserved the ancestral chromosome form. The inversions, fissions, and translocations in the five species analyzed involve at least 14 different evolutionary breakpoints along the entire length of human 3; however, particular regions appear to be more susceptible to chromosome reshuffling. The ancestral pericentromeric region has promoted both large-scale and micro-rearrangements. Small segments homologous to human 3q11.2 and 3q21.2 were repositioned intrachromosomally independent of the surrounding markers in the orangutan lineage. Breakage and rearrangement of the human 3p12.3 region were associated with extensive intragenomic duplications at multiple orangutan and gibbon subtelomeric sites. We propose that new chromosomes and genomes arise through large-scale rearrangements of evolutionarily conserved genomic building blocks and additional duplication, amplification, and/or repositioning of inherently unstable smaller DNA segments contained within them.     

Primate evolution of the alpha-globin gene cluster and its Alu-like repeats

The arrangement of alpha-globin genes in Old World and New World monkeys and a prosimian, galago, has been determined by restriction mapping. Recombinant DNAs containing galago and Old World monkey alpha-globin genes have been isolated and subjected to a partial sequence determination for comparison to alpha-globin genes in human, chimpanzee and non-primate mammals. The results of this extensive structural analysis are relevant to several topics concerning the evolution of primate alpha-globin genes and Alu family repeats. All orders of higher primates (i.e. Old and New World monkeys, chimpanzee and human) have the same arrangement of alpha-globin genes. In contrast, the arrangement and correction of galago alpha-globin genes differ from those of higher primates, but are similar to those of non-primate mammals. The 5' and 3'-flanking regions of the human alpha 1 gene are orthologous to the corresponding region in galago, identifying the human alpha 2 gene as the more recently duplicated gene. The human psi alpha 1 gene is found to be inactivated after divergence of the human and galago lineages but prior to the divergence of human and monkey. Orthologous Alu family members in human and monkey DNAs indicate that the dispersion of some Alu repeats occurred prior to the divergence of these lineages. However, the Alu-like repeats of prosimian and higher primates result from entirely independent events giving rise to different repeat elements inserted at distinct genomic positions.     

Human and ape molecular clocks and constraints on paleontological hypotheses

Although the relationships of the living hominoid primates (humans and apes) are well known, the relationships of the fossil species, times of divergence of both living and fossil species, and the biogeographic history of hominoids are not well established. Divergence times of living species, estimated from molecular clocks, have the potential to constrain hypotheses of the relationships of fossil species. In this study, new DNA sequences from nine protein-coding nuclear genes in great apes are added to existing datasets to increase the precision of molecular time estimates bearing on the evolutionary history of apes and humans. The divergence of Old World monkeys and hominoids at the Oligocene-Miocene boundary (approximately 23 million years ago) provides the best primate calibration point and yields a time and 95% confidence interval of 5.4 +/- 1.1 million years ago (36 nuclear genes) for the human-chimpanzee divergence. Older splitting events are estimated as 6.4 +/- 1.5 million years ago (gorilla, 31 genes), 11.3 +/- 1.3 million years ago (orangutan, 33 genes), and 14.9 +/- 2.0 million years ago (gibbon, 27 genes). Based on these molecular constraints, we find that several proposed phylogenies of fossil hominoid taxa are unlikely to be correct.     

On the loss of uricolytic activity during primate evolution--I. Silencing of urate oxidase in a hominoid ancestor

Urate oxidase activity is not detectable in liver homogenates from the gibbon, orangutan, chimpanzee, gorilla and human. Liver homogenates from five genera of Old World and two genera of New World monkeys have easily detectable levels of urate oxidase activity. There is no evidence for extant detectable intermediate steps in the loss of urate oxidase activity in the hominoids. Urate oxidase activity from Old World and New World monkeys is stable, a simple observation which debunks a long-standing myth. Urate oxidase activity was silenced in an ancestor to the five living genera of hominoids after divergence from the Old World monkeys.     

Retrovirus restriction by TRIM5alpha variants from Old World and New World primates

The TRIM5alpha proteins of humans and some Old World monkeys have been shown to block infection of particular retroviruses following virus entry into the host cell. Infection of most New World monkey cells by the simian immunodeficiency virus of macaques (SIVmac) is restricted at a similar point. Here we examine the antiretroviral activity of TRIM5alpha orthologs from humans, apes, Old World monkeys, and New World monkeys. Chimpanzee and orangutan TRIM5alpha proteins functionally resembled human TRIM5alpha, potently restricting infection by N-tropic murine leukemia virus (N-MLV) and moderately restricting human immunodeficiency virus type 1 (HIV-1) infection. Notably, TRIM5alpha proteins from several New World monkey species restricted infection by SIVmac and the SIV of African green monkeys, SIVagm. Spider monkey TRIM5alpha, which has an expanded B30.2 domain v3 region due to a tandem triplication, potently blocked infection by a range of retroviruses, including SIVmac, SIVagm, HIV-1, and N-MLV. Tandem duplications in the TRIM5alpha B30.2 domain v1 region of African green monkeys are also associated with broader antiretroviral activity. Thus, variation in TRIM5alpha proteins among primate species accounts for the observed patterns of postentry restrictions in cells from these animals. The TRIM5alpha proteins of some monkey species exhibit dramatic lengthening of particular B30.2 variable regions and an expanded range of susceptible retroviruses.     

Plasma and hepatic apoE isoproteins of nonhuman primates. Differences in apoE among humans, apes, and New and Old World monkeys

We have used two-dimensional polyacrylamide gel electrophoresis (PAGE) to study the plasma and hepatic apoE isoproteins of nonhuman primates and have compared them with their human counterparts. We have found that apoE obtained from fresh monkey or ape plasma, as well as nascent apoE synthesized by perfused monkey livers, is composed of several isoproteins that resemble the homozygous (beta) apoE phenotype observed in humans. The nonhuman primate plasma apoE pattern of 90 animals from nine different species consisted of a major isoprotein designated apoE3 and a few minor isoproteins. A group of acidic apoE isoproteins is eliminated after treatment with C. perfringens neuraminidase and has been designated sialo apoE (apoEs). Nonhuman primate liver apoE isoproteins comigrate with their plasma apoE isoprotein counterparts on two-dimensional PAGE, but hepatic apoE is enriched in sialo apoE isoproteins when compared to plasma apoE. The apparent molecular weight of asialo and sialo apoE obtained from Old World monkeys and apes is identical to the molecular weight of the corresponding human isoproteins (E3 = 38K, Es = 38.5-39.5K). However, the apparent molecular weight of apoE isoproteins obtained from New World monkeys is increased by approximately 0.5K (E3 = 38.5K, Es = 39.0-40.0K) as compared to the molecular weight of human and Old World monkey and ape isoproteins. The isoelectric points of apoE3 obtained from Old World monkeys, New World monkeys, chimpanzees, and gibbons are 5.74, 5.76, 5.95, and 5.89, respectively. The entire New or Old World monkey, chimpanzee, and gibbon apoE pattern is shifted by approximately -2.0, -0.5, and -1.0 charges, respectively, relative to the pattern of the corresponding human E3/3 phenotype. The molecular weight difference in apoE observed among New and Old World monkeys, as well as the molecular weight and/or charge differences observed among monkey, ape, and human apoE are consistent with structural changes in the apoE gene which have occurred following the divergence of the different species. The observation of only the homozygous apoE phenotypes in all animals studied suggests that the common apoE genetic polymorphism recently described in humans may not be present in nonhuman primates.     

Estimation of divergence times for major lineages of primate species

Although the phylogenetic relationships of major lineages of primate species are relatively well established, the times of divergence of these lineages as estimated by molecular data are still controversial. This controversy has been generated in part because different authors have used different types of molecular data, different statistical methods, and different calibration points. We have therefore examined the effects of these factors on the estimates of divergence times and reached the following conclusions: (1) It is advisable to concatenate many gene sequences and use a multigene gamma distance for estimating divergence times rather than using the individual gene approach. (2) When sequence data from many nuclear genes are available, protein sequences appear to give more robust estimates than DNA sequences. (3) Nuclear proteins are generally more suitable than mitochondrial proteins for time estimation. (4) It is important first to construct a phylogenetic tree for a group of species using some outgroups and then estimate the branch lengths. (5) It appears to be better to use a few reliable calibration points rather than many unreliable ones. Considering all these factors and using two calibration points, we estimated that the human lineage diverged from the chimpanzee, gorilla, orangutan, Old World monkey, and New World monkey lineages approximately 6 MYA (with a range of 5-7), 7 MYA (range, 6-8), 13 MYA (range, 12-15), 23 MYA (range, 21-25), and 33 MYA (range 32-36).     

Evolution of the tandem repeats in thymidylate synthase enhancer region (TSER) in primates

The upstream regulatory region of the human thymidylate synthase gene (thymidylate synthase enhancer region, TSER) is length polymorphic, attributable to variable numbers of tandemly repeated copies of a 28-bp fragment. It has been found that TSER length polymorphism is correlated to malignancy risk. To further our understanding of the origin and evolution of TSER, this region was investigated among different primates, including hominoids, two subfamilies of the Old World monkeys (OWMs): colobines and cercopithecines, and two species of the New World monkeys (NWMs). In addition to humans, our results show that length polymorphism in TSER is also present in some primate populations, although it appears that this region is length monomorphic in many other primates. We identified three unique repeat motifs in TSER and defined them as R1, R2, and R3, respectively, starting from the 3' end. The same repeat motifs from different species are more similar to each other than different repeat motifs within same species are. Such a paraphyletic pattern suggests that divergence of the three repeat motifs predated divergence of the OWMs/hominoids and the NWMs. The most recent common ancestor (MRCA) of hominoids and the OWMs probably possessed triple repeats but now double and triple repeats are two dominant types in hominoids and the OWMs. In addition, our results show that each of the three repeat motifs may be lost independently. We have also found clues that recombination was involved in formation of tandem repeat polymorphism in TSER.