Tempo and mode of evolution of a primate-specific retrotransposon belonging to the LINE 1 family

L1P_MA2 is a primate-specific subfamily of L1 retrotransposons. The consensus sequence of this element differs from the canonical L1 consensus by the presence of a 3800-bp region in 5' (L1M1_5). Part of this region has been proposed to be involved in a dystrophin mutation affecting the correct splicing of the gene and causing an X-linked dilated cardiomyopathy. In consideration of the potential involvement in splicing regulation of this element and also because of its atypical structure, we investigated its evolutionary history by analyzing the inter- and intraspecific divergence of L1P_MA2 sequences in various species of primates. The resulting phylogenetic trees show long terminal branches and short basal internodes, as expected for a rapid event of diversification that occurred in the past. The phylogenetic analysis and the intraspecific divergence estimates revealed a pattern of evolution for this element similar in all primates with the exception of lemurs, thus suggesting that the major wave of expansion of L1P_MA2 in primate genomes occurred after the divergence between Prosimiae and Anthropoidea. These results clearly indicate that a phylogenetic approach is more appropriate than methods based on sequence data from a single species, when investigating time and mode of evolution of retro-elements.     

Origin and evolution of a placental-specific microRNA family in the human genome

Background  

MicroRNAs (miRNAs) are a class of short regulatory RNAs encoded in the genome of DNA viruses, some single cell organisms, plants and animals. With the rapid development of technology, more and more miRNAs are being discovered. However, the origin and evolution of most miRNAs remain obscure. Here we report the origin and evolution dynamics of a human miRNA family.     

GAGE基因家族的分子进化特征的研究

GAGE基因通常表达于睾丸组织和部分恶性肿瘤组织中, 被认为可能是理想的癌症诊断的标记和治疗的靶位。我们对GAGE基因家族作了生物信息学分析, 发现它们在X染色体上串联成簇排列, 为灵长类所独有, 各拷贝序列趋异度很低。在人类有15个以上的拷贝, 在黑猩猩和猕猴分别有3个和4个。对GAGE基因家族构建进化树, 并估算了复制事件发生的时间, 结果显示在近400万年内陆续发生。用两种方法计算了GAGE各拷贝间的Ka/Ks值, 结果为显著大于1, 表明该基因家族受到正选择作用。这些结果提示该基因可能与灵长类的特征有关, 其在进化上的地位和在配子发育和肿瘤发生中承担的功能值得深入研究。     

Molecular evolution of a multigene family in group A streptococci

The emm genes are members of a gene family in group A streptococci (GAS) that encode for antiphagocytic cell-surface proteins and/or immunoglobulin-binding proteins. Previously sequenced genes in this family have been named "emm," "fcrA," "enn," "arp," "protH," and "mrp"; herein they will be referred to as the "emm gene family." The genes in the emm family are located in a cluster occupying 3-6 kb between the genes mry and scpA on the chromosome of Streptococcus pyogenes. Most GAS strains contain one to three tandemly arranged copies of emm-family genes in the cluster, but the alleles within the cluster vary among different strains. Phylogenetic analysis of the conserved sequences at the 3' end of these genes differentiates all known members of this family into four evolutionarily distinct emm subfamilies. As a starting point to analyze how the different subfamilies are related evolutionarily, the structure of the emm chromosomal region was mapped in a number of diverse GAS strains by using subfamily-specific primers in the polymerase chain reaction. Nine distinct chromosomal patterns of the genes in the emm gene cluster were found. These nine chromosomal patterns support a model for the evolution of the emm gene family in which gene duplication followed by sequence divergence resulted in the generation of four major-gene subfamilies in this locus.      

Molecular evolution of the ankyrin gene family

Ankyrins are membrane adaptor molecules that play important roles in coupling integral membrane proteins to the spectrin-based cytoskeleton network. Human mutations of ankyrin genes lead to severe genetic diseases such as fatal cardiac arrhythmias and hereditary spherocytosis. To elucidate the evolutionary history of ankyrins, we have identified novel ankyrin sequences in insect, fish, frog, chicken, dog, and chimpanzee genomes and explored the phylogenetic relationships of the ankyrin gene family. Our data demonstrate that duplication of ankyrin genes occurred at two different stages. The first duplication resulted from an independent evolution event specific in Arthropoda after its divergence from Chordata. Following the separation from Urochordata, expansion of ankyrins in vertebrates involved ancestral genome duplications. We did not find evidence of coordinated arrangements of gene families of ankyrin-associated membrane proteins on paralogous chromosomes. In addition, evolution of the 24 ANK-repeats strikingly correlated with the exon boundary sites of ankyrin genes, which might have occurred before its duplication in vertebrates. Such correlation is speculated to bring functional diversity and complexity. Moreover, based on the phylogenetic analysis of the ANK-repeat domain, we put forward a novel model for the putative primordial ankyrin that contains the fourth six-ANK-repeat subdomain and the spectrin-binding domain. These findings will provide guides for future studies concerning structure, function, evolutionary origins of ankyrins, and possibly other cytoskeletal proteins.     

Molecular evolution of the EGF-CFC protein family

The epidermal growth factor-Cripto-1/FRL-1/Cryptic (EGF-CFC) proteins, characterized by the highly conserved EGF and CFC domains, are extracellular membrane associated growth factor-like glycoproteins. These proteins are essential components of the Nodal signaling pathway during early vertebrate embryogenesis. Homologs of the EGF-CFC family have also been implicated in tumorigenesis in humans. Yet, little is known about the mode of molecular evolution in this family. Here we investigate the origin, extent of conservation and evolutionary relationships of EGF-CFC proteins across the metazoa. The results suggest that the first appearance of the EGF-CFC gene occurred in the ancestor of the deuterostomes. Phylogenetic analysis supports the classification of the family into distinct subfamilies that appear to have evolved through lineage-specific duplication and divergence. Site-specific analyses of evolutionary rate shifts between the two major mammalian paralogous subfamilies, Cripto and Cryptic, reveal critical amino acid sites that may account for the observed functional divergence. Furthermore, estimates of functional divergence suggest that rapid change of evolutionary rates at sites located mainly in the CFC domain may contribute towards distinct functional properties of the two paralogs.     

Molecular evolution of the synapsin gene family

Synapsins, a family of synaptic vesicle proteins, play a crucial role in the regulation of neurotransmission and synaptogenesis. They have been identified in a variety of invertebrate and vertebrate species, including human, rat (Rattus norvegicus), cow (Bos taurus), longfin squid (Loligo pealei), and fruit fly (Drosophila melanogaster). Here, synapsins were cloned from three additional species: frog (Xenopus laevis), lamprey (Lampetra fluviatilis), and nematode (Caenorhabditis elegans). Synapsin protein sequences from all these species were then used to explore the molecular phylogeny of these important neuronal phosphoproteins. The ancestral condition of a single synapsin gene probably gave rise to the vertebrate synapsin gene family comprised of at least three synapsin genes (I, II, and III) in higher vertebrates. Synapsins possess multiple domains, which have evolved at different rates throughout evolution. In invertebrate synapsins, the most conserved domains are C and E. During the evolution of vertebrates, at least two gene duplication events are hypothesized to have given rise to the synapsin gene family. This was accompanied by the emergence of an additional conserved domain, termed A. J. Exp. Zool. ( Mol. Dev. Evol. ) 285:360-377, 1999.     

microRNA evolution in a human transcription factor and microRNA regulatory network

Background  

microRNAs (miRNAs) are important cellular components. The understanding of their evolution is of critical importance for the understanding of their function. Although some specific evolutionary rules of miRNAs have been revealed, the rules of miRNA evolution in cellular networks remain largely unexplored. According to knowledge from protein-coding genes, the investigations of gene evolution in the context of biological networks often generate valuable observations that cannot be obtained by traditional approaches.     

Molecular evolution of the HSP70 multigene family

Eukaryotic genomes encode multiple 70-kDa heat-shock proteins (HSP70s). The Saccharomyces cerevisiae HSP70 family is comprised of eight members. Here we present the nucleotide sequence of the SSA3 and SSB2 genes, completing the nucleotide sequence data for the yeast HSP70 family. We have analyzed these yeast sequences as well as 29 HSP70s from 24 additional eukaryotic and prokaryotic species. Comparison of the sequences demonstrates the extreme conservation of HSP70s; proteins from the most distantly related species share at least 45% identity and more than one-sixth of the amino acids are identical in the aligned region (567 amino acids) among all proteins analyzed. Phylogenetic trees constructed by two independent methods indicate that ancient molecular and cellular events have given rise to at least four monophyletic groups of eukaryotic HSP70 proteins. Each group of evolutionarily similar HSP70s shares a common intracellular localization and is presumed to be comprised of functional homologues; these include heat-shock proteins of the cytoplasm, endoplasmic reticulum, mitochondria, and chloroplasts. HSP70s localized in mitochondria and plastids are most similar to the DnaK HSP70 homologues in purple bacteria and cyanobacteria, respectively, which is consistent with the proposed prokaryotic origin of these organelles. The analyses indicate that the major eukaryotic HSP70 groups arose prior to the divergence of the earliest eukaryotes, roughly 2 billion years ago. In some cases, as exemplified by the SSA genes encoding the cytoplasmic HSP70s of S. cerevisiae, more recent duplication events have given rise to subfamilies within the major groups. The S. cerevisiae SSB proteins comprise a unique subfamily not identified in other species to date. This subfamily appears to have resulted from an ancient gene duplication that occurred at approximately the same time as the origin of the major eukaryotic HSP70 groups. Correspondence to: E.A. Craig     

Molecular evolution of a Y-chromosomal repetitive sequence family in the genus Mus

A 522-base-long Y-chromosomal sequence was isolated from a BALB/c genomic library and was designated "BF046." It is repeated about 200 times in the male genome, and a difference was detected between the Mus musculus musculus and the M. m. domesticus type Y chromosomes. BF046- related sequences were present over the entire length of the Y chromosome as visualized by in situ hybridization. Southern blot analysis against DNAs isolated from eight species in the genus Mus showed that BF046-related sequences were amplified in the Y chromosomes of three closely related species: M. musculus, M. spicilegus, and M. spretus. To gain insight into the stability of the BF046 sequence family, we isolated 18 additional clones from these three mouse species and compared their sequences. The M. musculus sequences differed from the M. spicilegus and M. spretus sequences by two indels. The remaining parts of the sequences were very similar, but both parsimony and distance-based analytical methods divided the sequences into the same four subgroups, with each species having its own subgroup(s). Thus, the Y chromosomes of M. musculus, M. spicilegus, and M. spretus can be distinguished from one another.      

Molecular evolution of the MAGUK family in metazoan genomes

Background  

Development, differentiation and physiology of metazoans all depend on cell to cell communication and subsequent intracellular signal transduction. Often, these processes are orchestrated via sites of specialized cell-cell contact and involve receptors, adhesion molecules and scaffolding proteins. Several of these scaffolding proteins important for synaptic and cellular junctions belong to the large family of membrane-associated guanylate kinases (MAGUK). In order to elucidate the origin and the evolutionary history of the MAGUKs we investigated full-length cDNA, EST and genomic sequences of species in major phyla.     

Molecular evolution of flavonoid dioxygenases in the family Apiaceae

Plant species of the family Apiaceae are known to accumulate flavonoids mainly in the form of flavones and flavonols. Three 2-oxoglutarate-dependent dioxygenases, flavone synthase or flavanone 3 beta-hydroxylase and flavonol synthase are involved in the biosynthesis of these secondary metabolites. The corresponding genes were cloned recently from parsley (Petroselinum crispum) leaves. Flavone synthase I appears to be confined to the Apiaceae, and the unique occurrence as well as its high sequence similarity to flavanone 3beta-hydroxylase laid the basis for evolutionary studies. In order to examine the relationship of these two enzymes throughout the Apiaceae, RT-PCR based cloning and functional identification of flavone synthases I or flavanone 3beta-hydroxylases were accomplished from Ammi majus, Anethum graveolens, Apium graveolens, Pimpinella anisum, Conium maculatum and Daucus carota, yielding three additional synthase and three additional hydroxylase cDNAs. Molecular and phylogenetic analyses of these sequences were compatible with the phylogeny based on morphological characteristics and suggested that flavone synthase I most likely resulted from gene duplication of flavanone 3beta-hydroxylase, and functional diversification at some point during the development of the apiaceae subfamilies. Furthermore, the genomic sequences from Petroselinum crispum and Daucus carota revealed two introns in each of the synthases and a lack of introns in the hydroxylases. These results might be explained by intron losses from the hydroxylases occurring at a later stage of evolution.     

Molecular systematics and evolution of the aphid family Lachnidae

The aphid family Lachnidae (c. 320 spp.)-sister-group to the economically devastating family Aphididae (c. 3300 spp.)-encompasses a diverse array of associations with hostplants and attendant hymenopterans and of life histories, including potentially long-term parthenogenesis. Most-parsimonious phylogenetic trees were inferred from partial (905-coding-bp) sequences of elongation factor 1alpha (EF-1alpha) and complete (675-bp) sequences of cytochrome oxidase 2 (CO2). The EF-1alpha, CO2, and combined analyses did not conflict with each other. Most tribes and infratribal relationships were robustly supported; intertribal relationships were mostly unresolved in the separate analysis and only weakly supported in the combined analysis. Both genes indicated a close relationship between the genera Nippolachnus and Tuberolachnus, both of which include species with the unusual habit of feeding along the midrib of leaves of Eriobotrya and which are here referred to the tribe Tuberolachnini Mamontova. A sister-group relationship between Tuberolachnini and the putatively ancient asexual tribe Tramini is supported. The combined analysis provides support (albeit weak) for the hypothesis that conifer-feeding is ancestral in Lachninae, which in turn implies that conifer-feeding may be a homologous and uninterrupted habit across disparate families of aphidoids (e.g., Adelgidae, Mindaridae, Drepanosiphidae, and Lachnidae).     

杨树MIR169基因家族分子进化分析

MicroRNA(miRNA)是真核生物中普遍存在的一类参与基因表达调控的小分子RNA。ptc-MIR169基因家族有33个成员, 是杨树中规模最大的miRNA基因家族。研究MIR169基因家族的进化对揭示杨树miRNA基因的进化机制具有重要的意义。文章对毛果杨MIR169基因家族的分子系统发育、基因倍增模式、表达分化和靶基因进行了分析。结果表明, 染色体大片段重复和串联重复在毛果杨MIR169基因家族扩张中均具有重要作用; MIR169基因家族在表达方式上已经出现了较大的分化; MIR169基因家族可能在杨树中已经形成了复杂的调控网络, 对杨树的生长发育和适应性等具有重要的调控作用。文章为杨树及杨柳科相关植物中miRNA基因家族的分子进化研究提供了参考。