RHR转录因子家族起源、功能以及进化机制的研究进展

转录因子是一类能够通过与基因特异性序列进行结合,从而调控基因转录与表达的蛋白质,对细胞的生物学活性具有重要的调节作用。RHR (Rel-homology region,RHR)转录因子家族属于IF (immunoglobulin fold)转录因子超家族最主要的成员,其成员含有保守的Rel结构域和IPT (immunoglobulin-like fold)结构域。作为古老的转录因子家族,RHR家族成员随着物种演化,通过基因的复制、突变和沉默,不断分化出新型同源基因的同时也伴随着基因的丢失。自然选择导致了各家族成员不同的进化速率,并且在一些功能结构域上展现出了特殊的进化机制。然而,目前有关RHR家族起源和分化的综述比较少见。本文综述了RHR家族各成员的分布、分类、功能及家族进化等方面的研究成果,以期为研究整个转录因子家族的演化机制和物种之间的进化关系提供参考和新的思路。     

Evolution of the interferon alpha gene family in eutherian mammals

Interferon alpha (IFNA) genes code for proteins with important signaling roles during the innate immune response. Phylogenetically, IFNA family members in eutherians (placental mammals) cluster together in a species-specific manner except for closely related species (i.e. Homo sapiens and Pan troglodytes) where gene-specific clustering is evident. Previous research has been unable to clarify whether gene conversion or recent gene duplication accounts for gene-specific clustering, partly because the similarity of members of the IFNA family within species has made it historically difficult to identify the exact composition of IFNA gene families. IFNA gene families were fully characterized in recently available genomes from Canis familiaris, Macaca mulatta, P. troglodytes and Rattus norvegicus, and combined with previously characterized IFNA gene families from H. sapiens and Mus musculus, for the analysis of both whole and partial gene conversion events using a variety of statistical methods. Gene conversion was inferred in every eutherian species analyzed and comparison of the IFNA gene family locus between primate species revealed independent gene duplication in M. mulatta. Thus, both gene conversion and gene duplication have shaped the evolution of the IFNA gene family in eutherian species. Scenarios may be envisaged whereby the increased production of a specific IFN-alpha protein would be beneficial against a particular pathogenic infection. Gene conversion, similar to duplication, provides a mechanism by which the protein product of a specific IFNA gene can be increased.     

The highly conserved spermatophyte cell wall DUF642 protein family: phylogeny and first evidence of interaction with cell wall polysaccharides in vitro

The evolution of spermatophyte plants involved fundamental changes in cell wall structure and function which resulted from diversification of carbohydrates and proteins. Cell wall proteomic analyses identified a novel family of proteins of yet unknown function, the DUF642 (Domain of Unknown Function 642) proteins. To investigate the evolution of the DUF642 gene family, 154 gene sequences from 24 plant species were analyzed, and phylogenetic inferences were conducted using the Maximum Likelihood and Bayesian Inference methods. Orthologous genes were detected in spermatophyte species and absent in non-seed known plant genomes. Protein sequences shared conserved motifs that defined the signature of the family. Distribution of conserved motifs indicated an ancestral intragenic duplication event. Gene phylogeny documented paleoduplication events originating three or four clades, depending on root position. When based on mid-point rooting, it retrieved four monophyletic clades: A, B, C, and D. A glycosylphosphatidylinositol (GPI)-anchor site and one or two galactose-binding domains-like (GBDLs) could be predicted for some DUF642 proteins. The B, C, and D clades grouped the predicted GPI-anchored proteins. First evidence of in vitro interaction of a DUF642 protein with a cell wall polysaccharide fraction is provided. A competition assay with cellulose prevented this interaction. The degree of diversification and the conservation of the family suggested that DUF642 proteins are key components in seed plant evolution.     

Internal gene duplication in the evolution of prokaryotic transmembrane proteins

We investigated the evolution of transmembrane (TM) topology by detecting partial sequence repeats in TM protein sequences and analyzing them in detail. A total of 377 sequences that seem to have evolved by internal gene duplication events were found among 38,124 predicted TM protein sequences (except for single-spannings) from 87 prokaryotic genomes. Various types of internal duplication patterns were identified in these sequences. The majority of them are diploid-type (including quasi-diploid-type) duplication in which a primordial protein sequence was duplicated internally to become an extant TM protein with twice as many TM segments as the primordial one, and the remaining ones are partial duplications including triploid-type. The diploid-type repeats are recognized in many 8-tms, 10-tms and 12-tms TM protein sequences, suggesting the diploid-type duplication was a principle mechanism in the evolutionary development of these types of TM proteins. The "positive-inside" rule is satisfied in whole sequences of both 10-tms and 8-tms TM proteins and in both halves of 10-tms proteins while not necessarily in the second half of 8-tms proteins, providing fit examples of "internal divergent topology evolution" likely occurred after a diploid-type internal duplication event. From analyzing the partial duplication patterns, several evolutionary pathways were recognized for 6-tms TM proteins, i.e. from primordial 2-tms, 3-tms and 4-tms TM proteins to extant 6-tms proteins. Similarly, the duplication pattern analysis revealed plausible evolution scenarios that 7-tms TM proteins have arisen from 3-tms, 4-tms and 5-tms TM protein precursors via partial internal gene duplications.     

Phylogenetic analysis and positive-selection site detecting of vascular endothelial growth factor family in vertebrates

Vascular endothelial growth factor (VEGF), known to play an important role in vascular homeostasis, vascular integrity and angiogenesis, is little known about the evolutionary relationship of its five members especially the role of gene duplication and natural selection in the evolution of the VEGF family. In this study, seventy-five full-length cDNA sequences from 33 vertebrate species were extracted from the NCBI's GenBank, UniProt protein database and the Ensembl database. By phylogenetic analyses, we investigated the origin, conservation, and evolution of the VEGFs. Five VEGF family members in vertebrates might be formed by gene duplication. The inferred evolutionary transitions that separate members which belong to different gene clusters correlated with changes in functional properties. Selection analysis and protein structure analysis were combined to explain the relationship of the site-specific evolution in the vertebrate VEGF family. Eleven positive selection sites, one transmembrane region and the active sites were detected in this process.     

Alanyl-tRNA synthetase genes of Vanderwaltozyma polyspora arose from duplication of a dual-functional predecessor of mitochondrial origin

In eukaryotes, the cytoplasmic and mitochondrial forms of a given aminoacyl-tRNA synthetase (aaRS) are typically encoded by two orthologous nuclear genes, one of eukaryotic origin and the other of mitochondrial origin. We herein report a novel scenario of aaRS evolution in yeast. While all other yeast species studied possess a single nuclear gene encoding both forms of alanyl-tRNA synthetase (AlaRS), Vanderwaltozyma polyspora, a yeast species descended from the same whole-genome duplication event as Saccharomyces cerevisiae, contains two distinct nuclear AlaRS genes, one specifying the cytoplasmic form and the other its mitochondrial counterpart. The protein sequences of these two isoforms are very similar to each other. The isoforms are actively expressed in vivo and are exclusively localized in their respective cellular compartments. Despite the presence of a promising AUG initiator candidate, the gene encoding the mitochondrial form is actually initiated from upstream non-AUG codons. A phylogenetic analysis further revealed that all yeast AlaRS genes, including those in V. polyspora, are of mitochondrial origin. These findings underscore the possibility that contemporary AlaRS genes in V. polyspora arose relatively recently from duplication of a dual-functional predecessor of mitochondrial origin.     

Adrenergic receptor homologies in vertebrate and invertebrate species examined by DNA hybridization

The deduced protein sequences of the mammalian adrenergic receptors (ARs) suggest that these proteins have evolved by several ancient gene duplication events. To investigate in what species these events may have occurred DNA fragments encoding the family of adrenergic receptors from human (beta 1AR and alpha 2AR) and hamster (beta 2AR and alpha 1AR) were used to detect homologous sequences in other vertebrates, invertebrates and unicellular organisms by Southern blot hybridization analysis. Sequences homologous to hamster beta 2AR were detected in lower vertebrates, invertebrates and Dictyostelium, but not in yeast or bacteria. Within vertebrates, sequences strongly homologous to human beta 1AR and human platelet alpha 2AR were confined to the higher vertebrates only. In the invertebrates, only Drosophila contained sequences homologous to hamster alpha 1AR. Our results suggest that non-mammalian species may contain receptors homologous to the mammalian adrenergic receptors and that the sequences homologous to human beta 2AR have been the most strongly conserved.     

A basic helix-loop-helix protein with similarity to the fungal morphological regulators, Phd1p, Efg1p and StuA, controls conidiation but not dimorphic growth in Penicillium marneffei

Members of the APSES protein group are basic helix-loop-helix (bHLH) proteins that regulate processes such as mating, asexual sporulation and dimorphic growth in fungi. Penicillium marneffei is a human pathogen and is the only member of its genus to display a dimorphic growth transition. At 25 degrees C, P. marneffei grows with a filamentous morphology and produces asexual spores from multicellular con-idiophores. At 37 degrees C, the filamentous morphology is replaced by yeast cells that reproduce by fission. We have cloned and characterized an APSES protein-encoding gene from P. marneffei that has a high degree of similarity to Aspergillus nidulans stuA. Deletion of stuA in P. marneffei showed that it is required for metula and phialide formation during conidiation but is not required for dimorphic growth. This suggests that APSES proteins may control processes that require budding (formation of the metulae and phialides, pseudohyphal growth in Saccharomyces cerevisiae and dimorphic growth in Candida albicans) but not those that require fission (dimorphic growth in P. marneffei). The A. nidulans DeltastuA mutant has defects in both conidiation and mating. The P. marneffei stuA gene was capable of complementing the conidiation defect but could only inefficiently complement the sexual defects of the A. nidulans mutant. This suggests that the P. marneffei gene, which comes from an asexual species, has diverged significantly from the A. nidulans gene with respect to sexual but not asexual development.     

Evolutionary history of tissue kallikreins

The gene family of human kallikrein-related peptidases (KLKs) encodes proteins with diverse and pleiotropic functions in normal physiology as well as in disease states. Currently, the most widely known KLK is KLK3 or prostate-specific antigen (PSA) that has applications in clinical diagnosis and monitoring of prostate cancer. The KLK gene family encompasses the largest contiguous cluster of serine proteases in humans which is not interrupted by non-KLK genes. This exceptional and unique characteristic of KLKs makes them ideal for evolutionary studies aiming to infer the direction and timing of gene duplication events. Previous studies on the evolution of KLKs were restricted to mammals and the emergence of KLKs was suggested about 150 million years ago (mya). In order to elucidate the evolutionary history of KLKs, we performed comprehensive phylogenetic analyses of KLK homologous proteins in multiple genomes including those that have been completed recently. Interestingly, we were able to identify novel reptilian, avian and amphibian KLK members which allowed us to trace the emergence of KLKs 330 mya. We suggest that a series of duplication and mutation events gave rise to the KLK gene family. The prominent feature of the KLK family is that it consists of tandemly and uninterruptedly arrayed genes in all species under investigation. The chromosomal co-localization in a single cluster distinguishes KLKs from trypsin and other trypsin-like proteases which are spread in different genetic loci. All the defining features of the KLKs were further found to be conserved in the novel KLK protein sequences. The study of this unique family will further assist in selecting new model organisms for functional studies of proteolytic pathways involving KLKs.     

The novel flightless-I gene brings together two gene families, actin- binding proteins related to gelsolin and leucine-rich-repeat proteins involved in Ras signal transduction

The Drosophila melanogaster gene flightless-I, involved in gastrulation and muscle degeneration, has Caenorhabditis elegans and human homologues. In these highly conserved genes, two previously known gene families have been brought together, families encoding the actin- binding proteins related to gelsolin and the leucine-rich-repeat (LRR) group of proteins involved in protein-protein interactions. Both these gene families exhibit characteristics of molecular changes involving replication slippage and exon shuffling. Phylogenetic analyses of 19 amino acid sequences of 6 related protein types indicate that actin- associated proteins related to gelsolin are monophyletic to a common ancestor and include flightless proteins. Conversely, comparison of 24 amino acid sequences of LRR proteins including the flightless proteins indicates that flightless proteins are members of a structurally related subgroup. Included in the flightless cluster are human and mouse rsp-1 proteins involved in suppressing v-Ras transformation of cells and the membrane-associated yeast (Saccharomyces cerevisae) adenylate cyclase whose analogous LRRs are required for interaction with Ras proteins. There is a strong possibility that ligands for this group could be related and that flightless may have a similar role in Ras signal transduction. It is hypothesized that an ancestral monomeric gelsolin precursor protein has undergone at least four independent gene reorganization events to account for the structural diversity of the extant family of gelsolin-related proteins and that gene duplication and exon shuffling events occurred prior to or at the beginning of multicellular life, resulting in the evolution of some members of the family soon after the appearance of actin-type proteins.      

Molecular variation and evolution of the tyrosine kinase domains of insulin receptor <Emphasis Type="Italic">IRa</Emphasis> and <Emphasis Type="Italic">IRb</Emphasis> genes in Cyprinidae

The insulin receptor (IR) gene plays an important role in regulating cell growth, differentiation and development. In the present study, DNA sequences of insulin receptor genes, IRa and IRb, were amplified and sequenced from 37 representative species of the Cyprinidae and from five outgroup species from non-cyprinid Cypriniformes. Based on coding sequences (CDS) of tyrosine kinase regions of IRa and IRb, molecular evolution and phylogenetic relationships were analyzed to better understand the characteristics of IR gene divergence in the family Cyprinidae. IRa and IRb were clustered into one lineage in the gene tree of the IR gene family, reconstructed using the unweighted pair group method with arithmetic mean (UPGMA). IRa and IRb have evolved into distinct genes after IR gene duplication in Cyprinidae. For each gene, molecular evolution analyses showed that there was no significant difference among different groups in the reconstructed maximum parsimony (MP) tree of Cyprinidae; IRa and IRb have been subjected to similar evolutionary pressure among different lineages. Although the amino acid sequences of IRa and IRb tyrosine kinase regions were highly conserved, our analyses showed that there were clear sequence variations between the tyrosine kinase regions of IRa and IRb proteins. This indicates that IRa and IRb proteins might play different roles in the insulin signaling pathway.     

Insights into the molecular evolution of the PDZ/LIM family and identification of a novel conserved protein motif

The PDZ and LIM domain-containing protein family is encoded by a diverse group of genes whose phylogeny has currently not been analyzed. In mammals, ten genes are found that encode both a PDZ- and one or several LIM-domains. These genes are: ALP, RIL, Elfin (CLP36), Mystique, Enigma (LMP-1), Enigma homologue (ENH), ZASP (Cypher, Oracle), LMO7 and the two LIM domain kinases (LIMK1 and LIMK2). As conventional alignment and phylogenetic procedures of full-length sequences fell short of elucidating the evolutionary history of these genes, we started to analyze the PDZ and LIM domain sequences themselves. Using information from most sequenced eukaryotic lineages, our phylogenetic analysis is based on full-length cDNA-, EST-derived- and genomic- PDZ and LIM domain sequences of over 25 species, ranging from yeast to humans. Plant and protozoan homologs were not found. Our phylogenetic analysis identifies a number of domain duplication and rearrangement events, and shows a single convergent event during evolution of the PDZ/LIM family. Further, we describe the separation of the ALP and Enigma subfamilies in lower vertebrates and identify a novel consensus motif, which we call 'ALP-like motif' (AM). This motif is highly-conserved between ALP subfamily proteins of diverse organisms. We used here a combinatorial approach to define the relation of the PDZ and LIM domain encoding genes and to reconstruct their phylogeny. This analysis allowed us to classify the PDZ/LIM family and to suggest a meaningful model for the molecular evolution of the diverse gene architectures found in this multi-domain family.     

THE MOLECULAR EVOLUTION OF PITUITARY HORMONES

1. The pituitary hormones can be divided into 4 families; within each the members are structurally related and have probably evolved from a common ancestor by a process of gene duplication and divergence. 2. Recent structural studies have revealed much about the evolution of proteins. The roles of point mutation, gene duplication and partial gene duplication in molecular evolution have been highlighted, and the nature of the evolutionary forces involved has been extensively debated. The information available about the evolution of proteins in general provides a background for consideration of pituitary hormone evolution. 3. The structure and function of the mammalian neurohypophysial hormones (oxytocin and vasopressin) has been studied in detail. Related (structurally similar) peptides have been found in the neurohypophyses of lower vertebrates and have been Characterized in many instances. Several schemes have been proposed for the evolution of these hormones. 4. The vasopressins of the pig and its relatives show a genetic polymorphism. The roles of neurohypophysial hormones in lower vertebrates are very varied and not fully understood. 5. The ACTHs and MSHs are members of a second family of pituitary hormones. They are polypeptides of moderate size. Studies on amino-acid sequences have been carried out for ACTHs and MSHs from several mammals. α-MSH is identical in all cases studied in detail, but β-MSH and ACTH vary to some extent. There is considerable sequence homology between the hormones in this family - indicating a common phylogenetic origin and several gene duplications. 6. Dogfish MSH is the only non-mammalian hormone of the ACTH-MSH family to have been studied in detail. Two MSHs have been isolated from this species; both resemble the a-MSH of mammals in amino-acid sequence. ACTH-like and MSH-like hormones exist in many other vertebrate groups, but have not been characterized fully. 7. Structure-function relationships have been widely studied in the ACTH-MSH family, and have some interesting evolutionary implications. Polymorphism of P-MSHs is found in some mammals. 8. A third family of protein hormones includes pituitary prolactin and growth hormone, and placental lactogen. These are proteins of moderate size which have been shown to be widely distributed among the vertebrates. Species specificity can be recognized with regard to biological, immunological and structural properties. 9. Amino-acid sequences have been determined for growth hormones and prolactins from several mammals. There is sequence homology between growth hormone and prolactin. Human placental lactogen closely resembles human growth hormone. A phylogenetic tree has been constructed for this protein family. Rates of evolution within the group are rather variable. 10. The fourth family of pituitary hormones (FSH, LH, TSH and some related placental hormones) are all glycoproteins and have a subunit structure. Extensive sequence studies have been carried out on the hormones from some mammals, and show that there is considerable homology between the various subunits. The α-subunits of human TSH, LH and HCG (and probably FSH) are very similar. The β-subunits are different, but homologous. Evolution of this family clearly took place by a series of gene duplications followed by gene divergence. Schemes whereby this could have occurred have been discussed. Related hormones occur in lower vertebrates, but have not been fully characterized. Some lower vertebrates may possess only one gonado-trophin. 11. The pituitary hormones provide an interesting range of evolutionary problems, and are useful models for the study of molecular evolution. The evolutionary processes involved in their diversification have been discussed, with particular reference to the co-evolution of hormones and their receptors. Neutral mutations and gene duplications may have played a role in providing co-existing variation of hormones and receptors. 12. A speculative model for the evolution of neurohypophysial hormones is proposed, as an example of how molecular evolution may have operated in this and other hormone groups. 13. Homologies have been proposed between the various families of pituitary hormones, and between pituitary proteins and other entero-secretory proteins. The pituitary protein hormones were probably elaborated from smaller molecules by a process of partial gene duplication.     

KRAB型锌指蛋白的进化及在物种演化中的功能

C2H2型锌指蛋白家族是目前发现的哺乳动物中最大的转录/转录调控因子家族,由一小群古老的含有真核锌指结构的转录因子经过多次基因复制和功能分化演化而来。KRAB型锌指蛋白(KRAB-containing zinc finger proteins, KRAB-ZFPs)作为C2H2型锌指蛋白家族中最大的亚家族,最早出现在四足脊椎动物,并随物种的进化数量快速增长,在人类中占据C2H2型锌指蛋白的60%左右。在物种演化中,进化压力主要改变KRAB-ZFPs的DNA结合能力,而KRAB-ZFPs介导的转录抑制能力则稳定存在。同时,多种KRAB-ZFPs能够与KRAB相关蛋白1(KRAB-associated protein 1, KAP1)协同作用沉默哺乳动物中反转录元件的活性,并与之协同进化,严格限制反转录原件的跳跃能力。本文综述了KRAB-ZFPs的数量倍增、锌指结构的灵活多变、KRAB-ZFPs/KAP1的转录抑制能力和反转录元件的跳跃性在促进哺乳动物调控网络的差异、基因组稳定性的变化和物种进化中的作用,旨在进一步揭示KRAB-ZFPs在推动物种稳定演化中的特点和功能。     

Extensive and continuous duplication facilitates rapid evolution and diversification of gene families

The origin of novel gene functions through gene duplication, mutation, and natural selection represents one of the mechanisms by which organisms diversify and one of the possible paths leading to adaptation. Nonetheless, the extent, role, and consequences of duplications in the origins of ecological adaptations, especially in the context of species interactions, remain unclear. To explore the evolution of a gene family that is likely linked to species associations, we investigated the evolutionary history of the A-superfamily of conotoxin genes of predatory marine cone snails (Conus species). Members of this gene family are expressed in the venoms of Conus species and are presumably involved in predator-prey associations because of their utility in prey capture. We recovered sequences of this gene family from genomic DNA of four closely related species of Conus and reconstructed the evolutionary history of these genes. Our study is the first to directly recover conotoxin genes from Conus genomes to investigate the evolution of conotoxin gene families. Our results revealed a phenomenon of rapid and continuous gene turnover that is coupled with heightened rates of evolution. This continuous duplication pattern has not been observed previously, and the rate of gene turnover is at least two times higher than estimates from other multigene families. Conotoxin genes are among the most rapidly evolving protein-coding genes in metazoans, a phenomenon that may be facilitated by extensive gene duplications and have driven changes in conotoxin functions through neofunctionalization. Together these mechanisms led to dramatically divergent arrangements of A-superfamily conotoxin genes among closely related species of Conus. Our findings suggest that extensive and continuous gene duplication facilitates rapid evolution and drastic divergence in venom compositions among species, processes that may be associated with evolutionary responses to predator-prey interactions.     

Homology of lysozymes of bacterial and vertebrate origin

Theoretical analysis of structural and functional organization of vertebrate lysozymes, T4-phage lysozyme, lambda-phage endolysin and extracellular lysozyme of Chalaropsis species suggests a genetic relationship between the enzymes in question. It has been shown that the lysozyme sequences exhibit both inter- and intramolecular homology. The obtained data lend support to the concept postulating a common ancestor for the lysozyme family and subsequent divergent evolution of these proteins. The two-component primary structure of lysozymes can result from structural gene duplication and allows to explain similar catalytic activity and different substrate specificity of these enzymes by the differentiation and specialization of functions of the N- and C-components of the protein chains.