The smaller human VH gene families display remarkably little polymorphism.

We report the nucleotide sequence of 30 distinct human VH gene segments from the VHIV, VHV and VHVI gene families. When these sequences were compared to previously published sequences from these smaller human VH families a surprisingly low level of polymorphism was noted. Two VHIV gene segments from unrelated individuals were identical to two previously published VHIV sequences. Five VHV sequences were identical and seven VHVI gene segments were identical. Where differences were found between the sequences, allele specific oligonucleotide probes were used to verify the germline nature of the change and to test for segregation in several large kindreds. These data provide evidence that at least some human VH gene segments are remarkably stable.     

Different selective pressures shape the molecular evolution of color vision in chimpanzee and human populations

A population genetic analysis of the long-wavelength opsin (OPN1LW, "red") color vision gene in a global sample of 236 human nucleotide sequences had previously discovered nine amino acid replacement single nucleotide polymorphisms, which were found at high frequencies in both African and non-African populations and associated with an unusual haplotype diversity. Although this pattern of nucleotide diversity is consistent with balancing selection, it has been argued that a recombination "hot spot" or gene conversion within and between X-linked color vision genes alone may explain these patterns. The current analysis investigates a closely related primate with trichromatism to determine whether color vision gene amino acid polymorphism and signatures of adaptive evolution are characteristic of humans alone. Our population sample of 56 chimpanzee (Pan troglodytes) OPN1LW sequences shows three singleton amino acid polymorphisms and no unusual recombination or linkage disequilibrium patterns across the approximately 5.5-kb region analyzed. Our comparative population genetic approach shows that the patterns of OPN1LW variation in humans and chimpanzees are consistent with positive and purifying selection within the two lineages, respectively. Although the complex role of color vision has been greatly documented in primate evolution in general, it is surprising that trichromatism has followed very different selective trajectories even between humans and our closest relatives.     

β-Defensin 1 gene variability among non-human primates

Defensins are a recently described family of peptides that play an important role in innate immunity. Recent studies have shown that defensins exhibit a broad spectrum of antimicrobial activities against bacteria and fungi. Three families have been identified so far in mammals, alpha-defensins, beta-defensins and theta-defensins, presumably derived from a common ancestral defensin. A long-term study on the evolution of these multigene families among primates has been undertaken to investigate: (1) the degree of interspecific differentiation; (2) the genetic mechanisms responsible for the variability of these molecules; and (3) the possible role of different environmental factors in their evolution. Nucleotide sequences have been obtained from great and lesser apes, several African and Asian catarrhine monkeys and one New World monkey. A comparison of rates of synonymous and nonsynonymous (amino-acid changing) nucleotide substitution indicates that the primate beta-defensin 1 gene evolved under a pattern of random nucleotide substitution as predicted by the neutral theory of molecular evolution. These results are not consistent with the hypothesis that the primate beta-defensin 1 gene has diversified in response to changes in the microbial species to which a given host is exposed. Analyses of interpecific variability have yielded some insights about the pattern of molecular evolution of the gene among primates. Humans and great apes present high levels of sequence similarity, differing in only one amino acid residue in the mature peptide. Compared with these taxa, hylobatids and cercopithecids exhibit 3-4 amino acid substitutions, some of which increase the net charge of the active molecule.     

Forty Million Years of Independent Evolution: A Mitochondrial Gene and Its Corresponding Nuclear Pseudogene in Primates

Sequences from nuclear mitochondrial pseudogenes (numts) that originated by transfer of genetic information from mitochondria to the nucleus offer a unique opportunity to compare different regimes of molecular evolution. Analyzing a 1621-nt-long numt of the rRNA specifying mitochondrial DNA residing on human chromosome 3 and its corresponding mitochondrial gene in 18 anthropoid primates, we were able to retrace about 40 MY of primate rDNA evolutionary history. The results illustrate strengths and weaknesses of mtDNA data sets in reconstructing and dating the phylogenetic history of primates. We were able to show the following. In contrast to numt-DNA, (1) the nucleotide composition of mtDNA changed dramatically in the different primate lineages. This is assumed to lead to significant misinterpretations of the mitochondrial evolutionary history. (2) Due to the nucleotide compositional plasticity of primate mtDNA, the phylogenetic reconstruction combining mitochondrial and nuclear sequences is unlikely to yield reliable information for either tree topologies or branch lengths. This is because a major part of the underlying sequence evolution model — the nucleotide composition — is undergoing dramatic change in different mitochondrial lineages. We propose that this problem is also expressed in the occasional unexpected long branches leading to the “common ancestor” of orthologous numt sequences of different primate taxa. (3) The heterogeneous and lineage-specific evolution of mitochondrial sequences in primates renders molecular dating based on primate mtDNA problematic, whereas the numt sequences provide a much more reliable base for dating.[Reviewing Editor: Dr. Rafael Zardoya]     

Origin and divergence of tandem repeats of primate D4 dopamine receptor genes

Human D4 dopamine receptor (D4DR) is polymorphic in terms of the repeat, numbers of the 48-base pairs (bp) sequence located in the third cytoplasmic loop of the receptor. The repeated sequence and its polymorphism in D4DR genes have also been identified in higher non-human primates, suggesting that the structure of D4DR has been maintained during primate evolution. To clarify the origin and divergence of the polymorphism in the D4DR gene, we determined the nucleotide sequence of this region of the D4DR gene in several species of prosimians and the tree shrew, a species which is closely related to primates. Prosimians except the tarsier had one or two unit(s) of the 48-bp sequence, and conserved sequences were recognized in most of the units of the prosimians. The tree shrew had only one unit of the 48-bp sequence, and its sequence was 71–75% identical to those of the nuits of galago, loris, and lemur. These findings suggest that the ancestral primate presumably had one 48-bp unit, and duplication of the unit occurred at the stage of prosimians. Tarsiers appeared to be distinct from other prosimians and simians because of the high repeat numbers of units and their sequences.     

Molecular evolution of the zinc-containing long-chain alcohol dehydrogenase genes

Phylogenetic relationships and rates of nucleotide substitution were studied for alcohol dehydrogenase (ADH) genes by using DNA sequences from mammals and plants. Mammalian ADH sequences include the three class I genes and a class II gene from humans and one gene each from baboon, rat, and mouse. Plant sequences include two ADH genes each from maize and rice, three genes from barley, and one gene each from wheat and two dicots, Arabidopsis and pea. Phylogenetic trees show that relationships among ADH genes are generally consistent with taxonomic relationships: mammalian and plant ADH genes are classified into two distinct groups; primate class I genes are clustered; and two dicot sequences are clustered separately from monocot sequences. Accelerated evolution has been detected among the duplicated ADH genes in plants, in which synonymous substitutions occurred more often within the coenzyme-binding domain than within the catalytic domains.     

Structure and evolution of primate cytochrome c oxidase subunit II gene

The sequence of cytochrome oxidase subunit II (COII) mRNA from the cynomolgus macaque has been determined. Availability of the sequence from a non-human primate has allowed examination of the evolution of the COII gene and protein along the primate lineage. Comparison with existing protein and DNA sequences, combined with estimates of divergence derived from calculations designed to compensate for multiple mutation and reversion events, indicates that although the rate of fixation of nucleotide substitutions at silent sites is somewhat lower in primates than non-primates, the rate of fixation at replacement sites is 4-5-fold higher. The data also suggest that the rate of divergence at replacement sites along the primate lineage has not been uniform, but has decreased 2-2.5-fold since the higher primate branch point, in the absence of a comparable change in the rate substitution at silent sites. Both primate mRNAs differ from their non-primate homologues in having 3'-untranslated regions of 20-25 nucleotides. Examination of the monkey and human untranslated sequences suggests that these regions have evolved by duplication events occurring in both cases within 2-3 nucleotides following the translational stop codon. The primate mRNAs are also exceptional in that both can form stable stem and loop structures immediately preceding the postulated duplication site that may have played a role in facilitating the mutational events involved. Comparison of the human and monkey protein sequences has revealed regions conserved in primates that are significantly more hydrophobic than their non-primate counterparts. The possible effects of these alterations on the interaction between COII and cytochrome c are discussed.     

Diversifying selection of the tumor-growth promoter angiogenin in primate evolution

Diversifying selection drives the rapid differentiation of gene sequences and is one of the main forces behind adaptive evolution. Most genes known to be shaped by diversifying selection are those involved in host-pathogen or male-female interactions characterized as molecular "arms races." Here we report the unexpected detection of diversifying selection in the evolution of a tumor-growth promoter, angiogenin (ANG). A comparison among 11 primate species demonstrates that ANG has a significantly higher rate of nucleotide substitution at nonsynonymous sites than at synonymous sites, a hallmark of positive selection acting at the molecular level. Furthermore, we observed significant charge diversity at the molecular surface, suggesting the presence of selective pressures in the microenvironment of ANG, including its binding molecules. A population survey of ANG in chimpanzees, however, reveals no polymorphism, which may have resulted from a recent selective sweep of a charge-altering substitution in chimpanzee evolution. Functional assays of recombinant ANGs from the human and owl monkey indicate that primate ANGs retain angiogenic activity despite rapid evolution. Our study, together with findings of similar selection in the primate breast cancer suppressor gene, BRCA1, reveals an intriguing phenomenon of unusual selective pressures on, and adaptive evolution of, cancer-related genes in primate evolution.     

Molecular characterization of the A/J J558 family of heavy chain variable region gene segments

The nucleotide sequences of the coding as well as the flanking regions of 11 A/J J558 heavy chain variable region (VH) gene segments are presented. Among these J558 VH segments was the unrearranged germline VH gene segment recruited in the predominant A strain-specific anti-arsonate response. Three other VH gene segments that are greater than 92% related to the p-azophenylarsenate (Ars) A VH gene segment were also isolated. Detailed analysis of the nucleotide sequences of these as well as the remaining seven J558 VH gene segments reveal that the J558 VH gene family is composed of distinct, but related, J558 VH subfamilies. Deletion mapping analyses were used to position the Ars A VH gene segment proximally with respect to the DH-JH clusters within the J558 VH gene family and distally with respect to its own J558 subfamily. The documentation of J558 VH subfamilies is discussed in the context of J558 VH family evolution and diversification.     

Rate of divergence of cellular sequences homologous to segments of Moloney sarcoma virus.

The RNA genome of the Moloney isolate of murine sarcoma virus (M-MSV) consists of two parts--a sarcoma-specific region with no homology to known leukemia viral RNAs, and a shared region present also in Moloney murine leukemia virus RNA. Complementary DNA was isolated which was specific for each part of the M-MSV genome. The DNA of a number of mammalian species was examined for the presence of nucleotide sequences homologous with the two M-MSV regions. Both sets of viral sequences had homologous nucleotide sequences present in normal mouse cellular DNA. MSV-specific sequences found in mouse cellular DNA closely matched those nucleotide sequences found in M-MSV as seen by comparisons of thermal denaturation profiles. In all normal mouse cells tested, the cellular set of M-MSV-specific nucleotide sequences was present in DNA as one to a few copies per cell. The rate of base substitution of M-MSV nucleotide sequences was compared with the rate of evolution of both unique sequences and the hemoglobin gene of various species. Conservation of MSV-specific nucleotide sequences among species was similar to that of mouse globin gene(s) and greater than that of average unique cellular sequences. In contrast, cellular nucleotide sequences that are homologous to the M-MSV-murine leukemia virus "common" nucleotide region were present in multiple copies in mouse cells and were less well matched, as seen by reduced melting profiles of the hybrids. The cellular common nucleotide sequences diverged very rapidly during evolution, with a base substitution rate similar to that reported for some primate and avian endogenous virogenes. The observation that two sets of covalently linked viral sequences evolved at very different rates suggests that the origin of M-MSV may be different from endogenous helper viruses and that cellular sequences homologous to MSV-specific nucleotide sequences may be important to survival.     

Molecular evolution of growth hormone gene family in old world monkeys and hominoids

Growth hormone is a classic molecule in the study of the molecular clock hypothesis as it exhibits a relatively constant rate of evolution in most mammalian orders except primates and artiodactyls, where dramatically enhanced rate of evolution (25–50-fold) has been reported. The rapid evolution of primate growth hormone occurred after the divergence of tarsiers and simians, but before the separation of old world monkeys (OWM) from new world monkeys (NWM). Interestingly, this event of rapid sequence evolution coincided with multiple duplications of the growth hormone gene, suggesting gene duplication as a possible cause of the accelerated sequence evolution. Here we determined 21 different GH-like sequences from four species of OWM and hominoids. Combining with published sequences from OWM and hominoids, our analysis demonstrates that multiple gene duplications and several gene conversion events both occurred in the evolutionary history of this gene family in OWM/hominoids. The episode of recent duplications of CSH-like genes in gibbon is accompanied with rapid sequence evolution likely resulting from relaxation of purifying selection. GHN genes in both hominoids and OWM are under strong purifying selection. In contrast, CSH genes in both lineages are probably not. GHV genes in OWM and hominoids evolved at different evolutionary rates and underwent different selective constraints. Our results disclosed the complex history of the primate growth hormone gene family and raised intriguing questions on the consequences of these evolutionary events.     

Codon conservation in the influenza A virus genome defines RNA packaging signals

Genome segmentation facilitates reassortment and rapid evolution of influenza A virus. However, segmentation complicates particle assembly as virions must contain all eight vRNA species to be infectious. Specific packaging signals exist that extend into the coding regions of most if not all segments, but these RNA motifs are poorly defined. We measured codon variability in a large dataset of sequences to identify areas of low nucleotide sequence variation independent of amino acid conservation in each segment. Most clusters of codons showing very little synonymous variation were located at segment termini, consistent with previous experimental data mapping packaging signals. Certain internal regions of conservation, most notably in the PA gene, may however signify previously unidentified functions in the virus genome. To experimentally test the bioinformatics analysis, we introduced synonymous mutations into conserved codons within known packaging signals and measured incorporation of the mutant segment into virus particles. Surprisingly, in most cases, single nucleotide changes dramatically reduced segment packaging. Thus our analysis identifies cis-acting sequences in the influenza virus genome at the nucleotide level. Furthermore, we propose that strain-specific differences exist in certain packaging signals, most notably the haemagglutinin gene; this finding has major implications for the evolution of pandemic viruses.     

Accelerated Evolution of Cytochrome b in Simian Primates: Adaptive Evolution in Concert with Other Mitochondrial Proteins?

We have sequenced the cytochrome b gene of Horsfield's tarsier, Tarsius bancanus, to complete a data set of sequences for this gene from representatives of each primate infraorder. These primate cytochrome b sequences were combined with those from representatives of three other mammalian orders (cat, whale, and rat) in an analysis of relative evolutionary rates. The nonsynonymous nucleotide substitution rate of the cytochrome b gene has increased approximately twofold along lineages leading to simian primates compared to that of the tarsier and other primate and nonprimate mammalian species. However, the rate of transversional substitutions at fourfold degenerate sites has remained uniform among all lineages. This increase in the evolutionary rate of cytochrome b is similar in character and magnitude to that described previously for the cytochrome c oxidase subunit II gene. We propose that the evolutionary rate increase observed for cytochrome b and cytochrome c oxidase subunit II may underlie an episode of coadaptive evolution of these two proteins in the mitochondria of simian primates. Received: 15 December 1997 / Accepted: 24 February 1998     

A molecular view of primate phylogeny and important systematic and evolutionary questions

Phylogenetic analysis of extensive nucleotide sequence data from primate beta-globin gene clusters elucidates the systematics and evolution of the order Primates and reveals that rates of accumulation of mutations vary by as much as a factor of seven among different primate lineages. The picture of primate phylogeny from DNA sequences clarifies many ambiguities of the morphological picture. In the molecular picture, dwarf and brown lemurs group together into superfamily Lemuroidea, Lemuroidea and Lorisoidea into suborder Strepsirhini, and Tarsius and Anthropoidea into suborder Haplorhini. The molecular picture also provides both significant evidence for a human-chimpanzee clade that narrowly excludes gorilla and overwhelming evidence for the gorilla-chimpanzee-human clade within Hominoidea. Rates of DNA sequence evolution appear to have been fastest in the early primates ancestral to Anthropoidea and next fastest on the lorisoid branch. Rates were slowest over the past 25 Myr of hominoid descent, suggesting that mechanisms lowering the mutation rate evolved in correlation with lengthened life spans.     

Pentatricopeptide repeat proteins constrain genome evolution in chloroplasts

Higher plants encode hundreds of pentatricopeptide repeat proteins (PPRs) that are involved in several types of RNA processing reactions. Most PPR genes are predicted to be targeted to chloroplasts or mitochondria, and many are known to affect organellar gene expression. In some cases, RNA binding has been directly demonstrated, and the sequences of the cis-elements are known. In this work, we demonstrate that RNA cis-elements recognized by PPRs are constrained in chloroplast genome evolution. Cis-elements for two PPR genes and several RNA editing sites were analyzed for sequence changes by pairwise nucleotide substitution frequency, pairwise indel frequency, and maximum likelihood (ML) phylogenetic distances. All three of these analyses demonstrated that sequences within the cis-element are highly conserved compared with surrounding sequences. In addition, we have compared sequences around chloroplast editing sites and homologous sequences in species that lack an editing site due to the presence of a genomic T. Cis-elements for RNA editing sites are highly conserved in angiosperms; by contrast, comparable sequences around a genomically encoded T exhibit higher rates of nucleotide substitution, higher frequencies of indels, and greater ML distances. The loss in requirement for editing to create the ndhD start codon has resulted in the conversion of the PPR gene responsible for editing that site to a pseudogene. We show that organellar dependence on nuclear-encoded PPR proteins for gene expression has constrained the evolution of cis-elements that are required at the level of RNA processing. Thus, the expansion of the PPR gene family in plants has had a dramatic effect on the evolution of plant organelle genomes.     

Is There Selection for the Pace of Successive Inactivation of the arpAT Gene in Primates?

Pseudogenes have classically been considered inactive sequences evolving under neutrality. In recent years, however, a growing body of evidence is favoring the appearance of hypotheses attributing a functional role to pseudogenes. One of these hypotheses is that the silencing of a gene could produce a loss of function that could have been favored by natural selection. Here, we analyzed the pace of pseudogenization of arpAT, an L-DOPA transporter related to the neurotransmitter function of this amino acid in the brain. While active in rodent, dog, and chicken, arpAT has been silenced during primate evolution. Given the high number of inactivating mutations described in humans, it is possible that there have been selective pressures favoring this silencing. Through analysis of orthologous sequences in several primate species, we show that the silencing of arpAT occurred approximately 77 million to 90 million years ago, and that the observed mutation pattern is likely a consequence of its antiquity.     

Isolation and sequence analysis of the human corticotropin-releasing factor precursor gene.

A human genomic DNA segment containing the gene for the corticotropin-releasing factor precursor has been isolated by screening a gene library with an ovine cDNA probe. The cloned DNA segment has been subjected to restriction endonuclease mapping and nucleotide sequence analysis. Comparison of the nucleotide sequence of the gene with that of the ovine cDNA indicates that an intron of 800 bp is inserted in the segment encoding the 5'-untranslated region of the mRNA. The segment corresponding to the protein-coding and the 3'-untranslated region of the mRNA is uninterrupted. The mRNA and amino acid sequences of the human corticotropin-releasing factor precursor have been deduced from the corresponding gene sequence. The deduced amino acid sequence of human corticotropin-releasing factor exhibits seven amino acid substitutions in comparison with the ovine counterpart.     

Structure and evolution of the human involucrin gene

Involucrin is a keratinocyte protein that first appears in the cell cytosol, but ultimately becomes cross-linked to membrane proteins by transglutaminase. The gene for human involucrin has now been cloned and sequenced. The central segment of the coding region contains 39 repeats of a 30 nucleotide sequence whose ten encoded amino acids include three glutamines and two glutamic acids. This segment must have originated by successive duplications. Later duplications of modified sequences within the central segment can also be identified. Flanking the central segment lie shorter coding segments, a part of which must have given rise to the central segment. The flanking segments also show homology to a simpler 30 nucleotide sequence from which they likely originated. The evolution of involucrin as a substrate of transglutaminase and an envelope precursor was evidently made possible by this process of repeated mutation and duplication.