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.     

The natural history of class I primate alcohol dehydrogenases includes gene duplication, gene loss, and gene conversion

Background

Gene duplication is a source of molecular innovation throughout evolution. However, even with massive amounts of genome sequence data, correlating gene duplication with speciation and other events in natural history can be difficult. This is especially true in its most interesting cases, where rapid and multiple duplications are likely to reflect adaptation to rapidly changing environments and life styles. This may be so for Class I of alcohol dehydrogenases (ADH1s), where multiple duplications occurred in primate lineages in Old and New World monkeys (OWMs and NWMs) and hominoids.

Methodology/Principal Findings

To build a preferred model for the natural history of ADH1s, we determined the sequences of nine new ADH1 genes, finding for the first time multiple paralogs in various prosimians (lemurs, strepsirhines). Database mining then identified novel ADH1 paralogs in both macaque (an OWM) and marmoset (a NWM). These were used with the previously identified human paralogs to resolve controversies relating to dates of duplication and gene conversion in the ADH1 family. Central to these controversies are differences in the topologies of trees generated from exonic (coding) sequences and intronic sequences.

Conclusions/Significance

We provide evidence that gene conversions are the primary source of difference, using molecular clock dating of duplications and analyses of microinsertions and deletions (micro-indels). The tree topology inferred from intron sequences appear to more correctly represent the natural history of ADH1s, with the ADH1 paralogs in platyrrhines (NWMs) and catarrhines (OWMs and hominoids) having arisen by duplications shortly predating the divergence of OWMs and NWMs. We also conclude that paralogs in lemurs arose independently. Finally, we identify errors in database interpretation as the source of controversies concerning gene conversion. These analyses provide a model for the natural history of ADH1s that posits four ADH1 paralogs in the ancestor of Catarrhine and Platyrrhine primates, followed by the loss of an ADH1 paralog in the human lineage.     

Gene duplication,transfer, and evolution in the chloroplast genome

In addition to the nuclear genome, organisms have organelle genomes. Most of the DNA present in eukaryotic organisms is located in the cell nucleus. Chloroplasts have independent genomes which are inherited from the mother. Duplicated genes are common in the genomes of all organisms. It is believed that gene duplication is the most important step for the origin of genetic variation, leading to the creation of new genes and new gene functions. Despite the fact that extensive gene duplications are rare among the chloroplast genome, gene duplication in the chloroplast genome is an essential source of new genetic functions and a mechanism of neo-evolution. The events of gene transfer between the chloroplast genome and nuclear genome via duplication and subsequent recombination are important processes in evolution. The duplicated gene or genome in the nucleus has been the subject of several recent reviews. In this review, we will briefly summarize gene duplication and evolution in the chloroplast genome. Also, we will provide an overview of gene transfer events between chloroplast and nuclear genomes.     

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.     

A New Malaria Agent in African Hominids

Plasmodium falciparum is the major human malaria agent responsible for 200 to 300 million infections and one to three million deaths annually, mainly among African infants. The origin and evolution of this pathogen within the human lineage is still unresolved. A single species, P. reichenowi, which infects chimpanzees, is known to be a close sister lineage of P. falciparum. Here we report the discovery of a new Plasmodium species infecting Hominids. This new species has been isolated in two chimpanzees (Pan troglodytes) kept as pets by villagers in Gabon (Africa). Analysis of its complete mitochondrial genome (5529 nucleotides including Cyt b, Cox I and Cox III genes) reveals an older divergence of this lineage from the clade that includes P. falciparum and P. reichenowi (∼21±9 Myrs ago using Bayesian methods and considering that the divergence between P. falciparum and P. reichenowi occurred 4 to 7 million years ago as generally considered in the literature). This time frame would be congruent with the radiation of hominoids, suggesting that this Plasmodium lineage might have been present in early hominoids and that they may both have experienced a simultaneous diversification. Investigation of the nuclear genome of this new species will further the understanding of the genetic adaptations of P. falciparum to humans. The risk of transfer and emergence of this new species in humans must be now seriously considered given that it was found in two chimpanzees living in contact with humans and its close relatedness to the most virulent agent of malaria.     

Impaired cytotrophoblast cell-cell fusion is associated with reduced Syncytin and increased apoptosis in patients with placental dysfunction

Preeclampsia (PE), Hemolysis Elevated Liver Enzymes and Low Platelets (HELLP)-syndrome, and intrauterine growth restriction (IUGR) are associated with abnormal placentation. In early pregnancy, placental cytotrophoblasts fuse and form multinuclear syncytiotrophoblasts. The envelope gene of the human endogenous retrovirus-W, Syncytin, is a key factor for mediating cell-cell fusion of cytotrophoblasts. This study investigated clinical parameters of PE and HELLP-associated IUGR and analyzed the cell-cell fusion index and beta-human chorionic gonadotropin (beta-hCG) secretion of cytotrophoblasts isolated and cultured from placentas of these patients. In addition, we performed absolute quantitation of Syncytin and determined the apoptosis rate in both cultured cytotrophoblasts and placental tissues. Cultured cytotrophoblasts from PE and HELLP-associated IUGR correlated with a pronounced lower cell-cell fusion index, 1.8- and 3.6-fold; less nuclei per syncytiotrophoblast, 1.4- and 2.0-fold; a significantly decreased beta-hCG secretion, 4.3- and 17.2-fold and a reduction of Syncytin gene expression, 8.1 (P = 0.019) and 222.7-fold (P = 0.011) compared with controls, respectively. In contrast, a significantly 2.3-fold higher apoptosis rate was observed in cultured PE/IUGR cytotrophoblasts (P = 0.043). Importantly, Syncytin gene expression in primary placental tissues of PE/IUGR was 5.4-fold lower (P = 0.047) and in HELLP/IUGR 10.6-fold lower (P = 0.019) along with a 1.8- and 1.9-fold significant increase in the apoptosis rate compared with controls, respectively. Low Syncytin expression in both cultured cytotrophoblasts and primary tissues from pathological placentas supports an intrinsic placenta-specific deregulation of cell-cell fusion in the formation of syncytiotrophoblasts leading to increased apoptosis. These processes could contribute to the development and severity of PE and HELLP-associated IUGR.     

GENOMICS IN THE LIGHT OF EVOLUTIONARY TRANSITIONS

Molecular biology has entrenched the gene as the basic hereditary unit and genomes are often considered little more than collections of genes. However, new concepts and genomic data have emerged, which suggest that the genome has a unique place in the hierarchy of life. Despite this, a framework for the genome as a major evolutionary transition has not been fully developed. Instead, genome origin and evolution are frequently considered as a series of neutral or nonadaptive events. In this article, we argue for a Darwinian multilevel selection interpretation for the origin of the genome. We base our arguments on the multilevel selection theory of hypercycles of cooperative interacting genes and predictions that gene‐level trade‐offs in viability and reproduction can help drive evolutionary transitions. We consider genomic data involving mobile genetic elements as a test case of our view. A new concept of the genome as a discrete evolutionary unit emerges and the gene–genome juncture is positioned as a major evolutionary transition in individuality. This framework offers a fresh perspective on the origin of macromolecular life and sets the scene for a new, emerging line of inquiry—the evolutionary ecology of the genome.     

The involucrin gene of the owl monkey: origin of the early region

A large part of the coding region of the hominoid involucrin gene is of recent origin. This part of the gene, which we have called the modern segment, contains numerous repeats of a sequence of 10 codons, created by multiple duplications some of which consist of 3-12 repeats. We have sequenced two alleles of the involucrin gene in the owl monkey and found that the involucrin gene of this species also possesses a modern segment. By comparing the modern segment of the owl monkey with that of the hominoids, we find that only a part of this segment is shared by the two species. We call this part the early region because it must have originated in a common ancestor of the anthropoids. The rest of the hominoid modern segment does not correspond to any groups of repeats in the owl monkey and was therefore created after divergence of the two lineages. As in the hominoids, the latest additions to the modern segment of the owl monkey have been in its 5' half, which possesses different duplication patterns in the two alleles. Lineage divergences within the anthropoids can be detected at different sites within the modern segment.      

Reevaluation of the Coding Potential and Proteomic Analysis of the BAC-Derived Rhesus Cytomegalovirus Strain 68-1

Cytomegaloviruses are highly host restricted, resulting in cospeciation with their hosts. As a natural pathogen of rhesus macaques (RM), rhesus cytomegalovirus (RhCMV) has therefore emerged as a highly relevant experimental model for pathogenesis and vaccine development due to its close evolutionary relationship to human CMV (HCMV). Most in vivo experiments performed with RhCMV employed strain 68-1 cloned as a bacterial artificial chromosome (BAC). However, the complete genome sequence of the 68-1 BAC has not been determined. Furthermore, the gene content of the RhCMV genome is unknown, and previous open reading frame (ORF) predictions relied solely on uninterrupted ORFs with an arbitrary cutoff of 300 bp. To obtain a more precise picture of the actual proteins encoded by the most commonly used molecular clone of RhCMV, we reevaluated the RhCMV 68-1 BAC genome by whole-genome shotgun sequencing and determined the protein content of the resulting RhCMV virions by proteomics. By comparing the RhCMV genome to those of several related Old World monkey (OWM) CMVs, we were able to filter out many unlikely ORFs and obtain a simplified map of the RhCMV genome. This comparative genomics analysis suggests a high degree of ORF conservation among OWM CMVs, thus decreasing the likelihood that ORFs found only in RhCMV comprise true genes. Moreover, virion proteomics independently validated the revised ORF predictions, since only proteins that were conserved across OWM CMVs could be detected. Taken together, these data suggest a much higher conservation of genome and virion structure between CMVs of humans, apes, and OWMs than previously assumed.     

Full-length sequence analysis of the HLA-DRB1 locus suggests a recent origin of alleles

The HLA region harbors some of the most polymorphic loci in the human genome. Among them is the class II locus HLA-DRB1, with more than 400 known alleles. The age of the polymorphism and the rate at which new alleles are generated at HLA loci has caused much controversy over the years. Previous studies have mostly been restricted to the 270 base pairs that constitute the second exon and represent the most variable part of the gene. Here, we investigate the evolutionary history of the HLA-DRB1 locus on the basis of an analysis of 15 genomic full-length alleles (10-15 kb). In addition, the variation in 49 complete coding sequences and 322 exon 2 sequences were analyzed. When excluding exon 2 from the analysis, the diversity at the synonymous sites was found to be similar to the intron diversity. The overall diversity in noncoding region was also similar to the genome average. The DRB1*03 lineage has been found in human, chimpanzee, bonobo, gorilla, and orangutan. An ancestral "proto HLA-DRB1*03 lineage" appeared to have diverged in the last 5 million years into the human-specific lineages *08, *11, *13, and *14. With exception to exon 2, both the coding- and the noncoding diversity suggests a recent origin (<1 million years ago) for most of the alleles at the HLA-DRB1 locus. Sites encoding for amino acids involved in antigen binding [antigen recognizing sites (ARS)] appear to have a more ancient origin. Taken together, the recent origin of most alleles, the high diversity between allelic lineages, and the ancient origin of sequence motifs in exon 2, is consistent with a relatively rapid generation of novel alleles by gene conversion like events.     

Focusing on comparative ape population genetics in the post-genomic age

The initial human and chimpanzee genome sequences have been published, and additional primate genomes, including those of gorilla and orang-utan, are in progress. With these new resources, we can now address what makes our species unique, by focusing on the underlying genetic differences associated with phenotypes. Comparative primate population genomics, including studies of structural changes, mobile elements, gene expression and functional analyses, will shed light on how natural selection and population demography are involved in the processes that lead to differences among great apes. Historically, this research has focused on the human perspective; however, we will learn much about ourselves with a focus on genomic diversity in hominoids as a group.     

A new 5' sequence associated with mouse L1 elements is representative of a major class of L1 termini.

Full-length L1 elements have been shown to possess, at their 5' end, tandem repeats called "A" or "F" types. By sequencing the 5' region of two large L1 copies that did not hybridize to A or F probes, we have identified a new sequence that is found at the 5' end of many L1 elements and that we call "V." The element characterized has no 200-bp tandem repetitive structure, and the new 5' sequence is not similar to the A or F sequences. The study of the relationships between the V and L1 sequences has shown that only half of the V (i.e., V-specific 5') sequences in the genome are linked to the 5' end of L1 copies. In related rodent species, a comparative study by Southern blot and PCR analysis of the V sequence suggests that this L1 subfamily has an ancient origin and that V sequence isolated from the remainder of the L1 element has been amplified during the evolution of the mouse genome.     

The non-photosynthetic plastid in malarial parasites and other apicomplexans is derived from outside the green plastid lineage.

The discovery of a non-photosynthetic plastid genome in Plasmodium falciparum and other apicomplexans has provided a new drug target, but the evolutionary origin of the plastid has been muddled by the lack of characters, that typically define major plastid lineages. To clarify the ancestry of the plastid, we undertook a comprehensive analysis of all genomic characters shared by completely sequenced plastid genomes. Cladistic analysis of the pattern of plastid gene loss and gene rearrangements suggests that the apicomplexan plastid is derived from an ancestor outside of the green plastid lineage. Phylogenetic analysis of primary sequence data (DNA and amino acid characters) produces results that are generally independent of the analytical method, but similar genes (i.e., rpoB and rpoC) give similar topologies. The conflicting phylogenies in primary sequence data sets make it difficult to determine the the exact origin of the apicomplexan plastid and the apparent artifactual association of apicomplexan and euglenoid sequences suggests that DNA sequence data may be an inappropriate set of characters to address this phylogenetic question. At present we cannot reject our null hypothesis that the apicomplexan plastid is derived from a shared common ancestor between apicomplexans and dinoflagellates. During the analysis, we noticed that the Plasmodium tRNA-Met is probably tRNA-fMet and the tRNA-fMet is probably tRNA-Ile. We suggest that P. falciparum has lost the elongator type tRNA-Met and that similar to metazoan mitochondria there is only one species of methionine tRNA. In P. falciparum, this has been accomplished by recruiting the fMet-type tRNA to dually function in initiation and elongation. The tRNA-Ile has an unusual stem-loop in the variable region. The insertion in this region appears to have occurred after the primary origin of the plastid and further supports the monophyletic ancestory of plastids.     

Slow molecular clocks in Old World monkeys,apes, and humans

Two longstanding issues on the molecular clock hypothesis are studied in this article. First, is there a global molecular clock in mammals? Although many authors have observed unequal rates of nucleotide substitution among mammalian lineages, some authors have proposed a global clock for all eutherians, i.e., a single global rate of 2.2 x 10(-9) substitutions per nucleotide site per year. We reexamine this issue using noncoding, nonrepetitive DNA from Old World monkeys (OWMs), chimpanzee, and human. First, using the minimal date of 6 MYA for the human-chimpanzee divergence and more than 2.5 million base pairs of genomic sequences from human and chimpanzee, we estimate a maximal rate of 0.99 x 10(-9) for noncoding, nonrepetitive genomic regions for these two species. This estimate is less than half of the proposed global rate and much smaller than the commonly used rate (3.5 x 10(-9)) for eutherians. Further, using a minimal date of 23 MYA for the human-OWM divergence, we estimate a maximal rate of 1.5 x 10(-9) for both introns and fourfold degenerate sites in humans and OWMs. In addition, with the New World monkey (NWM) lineage as an outgroup, we estimate that the rate of substitution in introns is 30% higher in the OWM lineage than in the human lineage. Clearly, there is no global molecular clock in eutherians. Second, although many studies have indicated considerable variation in the mutation rate among regions of the mammalian genome, a recent study proposed a uniform rate. Using new and existing intron sequence data from higher primates, we find significant rate variation among genomic regions and a positive correlation between the rate of substitution and the GC content, refuting the claim of a uniform rate.     

CRISPR/Cas9系统的分子机制及其在人类疾病基因治疗中的应用

CRISPR/Cas系统是广泛存在于细菌和古生菌中的适应性免疫系统,用来抵抗外来病毒或质粒的入侵。近几年,由Ⅱ型CRISPR/Cas适应性免疫系统改造而来的CRISPR/ Cas9基因组编辑技术蓬勃发展,被广泛地应用于生命科学研究的各个领域,并取得了革命性的变化。文章主要综述了CRISPR/Cas9基因组编辑技术的起源与发展及在生命科学各研究领域的应用,重点介绍了该系统在人类疾病基因治疗方面的最新应用及脱靶效应,以期为相关领域的科研人员提供参考。     

Evolutionary rate of immunoglobulin alpha noncoding region is greater in hominoids than in Old World monkeys.

Recent studies on the molecular evolution of primates show that the evolutionary rate among hominoids is considerably slower than that among nonhominoid primates. However, this observation at the nucleotide-sequence level is restricted to the beta-globin family region. In this study, we sequenced orthologous immunoglobulin alpha (C alpha) genes of chimpanzee, gorilla, orangutan, and crab-eating macaque (an Old World monkey) and compared them with that of the human by using noncoding regions for analysis. Since significant differences in rates among hominoids were not found by using the relative rate test, we evaluated the ratio (R) of the evolutionary distance between Old World monkey and human to the distance between orangutan and human. The R value (1.12) for the C alpha gene was much smaller than the expected value (1.38-2.33), showing that the nucleotide substitution rate (= mutation rate per year under selective neutrality) of the C alpha gene is greater in the human lineage than in the Old World monkey lineage. We also did a similar analysis for the gamma 1-, gamma 2-, psi eta-, and delta-globin genes and found a considerable heterogeneity (1.12-2.37) among the R values, including that for the C alpha gene. This indicates that the hominoid slowdown of the evolutionary rate is not a universal phenomenon in primate evolution.     

灵长类比较基因组学的研究进展

随着人类和黑猩猩全基因组测序工作宣布完成,以及其他灵长类基因组测序工作的逐步开展,目前已经积累了大量的灵长类基因组数据,一个崭新的研究领域——灵长类比较基因组学应运而生。该文主要通过对人类和其他非人灵长类系统关系和基因组结构的比较,从系统进化、基因组结构和基因表达调控等方面评述该领域的研究进展,阐述人类、黑猩猩与其他非人灵长类之间的主要生物学差异,揭示人类进化的生物学机制。     

Mitochondrial DNA of Vitis vinifera and the issue of rampant horizontal gene transfer

The mitochondrial genome of grape (Vitis vinifera), the largestorganelle genome sequenced so far, is presented. The genomeis 773,279 nt long and has the highest coding capacity amongknown angiosperm mitochondrial DNAs (mtDNAs). The proportionof promiscuous DNA of plastid origin in the genome is also thelargest ever reported for an angiosperm mtDNA, both in absoluteand relative terms. In all, 42.4% of chloroplast genome of Vitishas been incorporated into its mitochondrial genome. In orderto test if horizontal gene transfer (HGT) has also contributedto the gene content of the grape mtDNA, we built phylogenetictrees with the coding sequences of mitochondrial genes of grapeand their homologs from plant mitochondrial genomes. Many incongruentgene tree topologies were obtained. However, the extent of incongruencebetween these gene trees is not significantly greater than thatobserved among optimal trees for chloroplast genes, the commonancestry of which has never been in doubt. In both cases, weattribute this incongruence to artifacts of tree reconstruction,insufficient numbers of characters, and gene paralogy. Thisfinding leads us to question the recent phylogenetic interpretationof Bergthorsson et al. (2003, 2004) and Richardson and Palmer(2007) that rampant HGT into the mtDNA of Amborella best explainsphylogenetic incongruence between mitochondrial gene trees forangiosperms. The only evidence for HGT into the Vitis mtDNAfound involves fragments of two coding sequences stemming fromtwo closteroviruses that cause the leaf roll disease of thisplant. We also report that analysis of sequences shared by bothchloroplast and mitochondrial genomes provides evidence fora previously unknown gene transfer route from the mitochondrionto the chloroplast.     

AN EVALUATION OF THE HYBRID SPECIATION HYPOTHESIS FOR XIPHOPHORUS CLEMENCIAE BASED ON WHOLE GENOME SEQUENCES

Once thought rare in animal taxa, hybridization has been increasingly recognized as an important and common force in animal evolution. In the past decade, a number of studies have suggested that hybridization has driven speciation in some animal groups. We investigate the signature of hybridization in the genome of a putative hybrid species, Xiphophorus clemenciae, through whole genome sequencing of this species and its hypothesized progenitors. Based on analysis of this data, we find that X. clemenciae is unlikely to have been derived from admixture between its proposed parental species. However, we find significant evidence for recent gene flow between Xiphophorus species. Although we detect genetic exchange in two pairs of species analyzed, the proportion of genomic regions that can be attributed to hybrid origin is small, suggesting that strong behavioral premating isolation prevents frequent hybridization in Xiphophorus. The direction of gene flow between species is potentially consistent with a role for sexual selection in mediating hybridization.     

Timing and mechanism of ancient vertebrate genome duplications -- the adventure of a hypothesis

Complete genome doubling has long-term consequences for the genome structure and the subsequent evolution of an organism. It has been suggested that two genome duplications occurred at the origin of vertebrates (known as the 2R hypothesis). However, there has been considerable debate as to whether these were two successive duplications, or whether a single duplication occurred, followed by large-scale segmental duplications. In this article, we review and compare the evidence for the 2R duplications from vertebrate genomes with similar data from other more recent polyploids.