基因倍增和脊椎动物起源

有机体基因复制导致基因复杂性增加及其和脊椎动物起源的关系已经成为进化生物学研究的热点。20世纪70年代由Ohno提出后经Holland等修正的原始脊索动物经两轮基因组复制产生脊椎动物的假设目前已被广泛接受。脊椎动物起源和进化过程中发生过两轮基因组复制的主要证据有三点：（1）据估计脊椎动物基因组内编码基因数目大约相当于果蝇、海鞘等无脊椎动物的4倍;原口动物如果蝇和后口动物如头索动物文昌鱼的基因组大都只有单拷贝的基因,而脊椎动物的基因组则通常有4个同属于一个家族的基因。（2）无脊椎动物如节肢动物、海胆和头索动物文昌鱼都只有一个Hox基因簇,而脊椎动物除鱼类外,有7个具有Hox基因簇,其余都具有4个Hox基因簇。（3）基因作图证明,不但在鱼类和哺乳动物染色体广大片段上基因顺序相似,而且有证据显示哺乳动物基因组不同染色体之间存在相似性。据认为第一次基因倍增发生在脊椎动物与头索动物分开之后,第二次基因倍增发生在有颌类脊椎动物和无颌类脊椎动物分开以后。但是,基因是逐个发生倍增,还是通过基因组内某些DNA片段抑或整个基因组的加倍而实现的,目前还颇有争议。     

Negative regulators of programed cell death.

During animal development many cells undergo programed deaths. Recently, genes that suppress the cell-death program have been described in both vertebrates and invertebrates. These genes play a vital role in regulation of the molecules that kill cells, and disruption of this regulatory process can contribute to disease.     

Palaeophylogenomics of the vertebrate ancestor--impact of hidden paralogy on hagfish and lamprey gene phylogeny

In dissecting the transition from invertebrates to vertebrates at the molecular level, whole-genome duplications are recognized as a key event. This gave rise to more copies of genes in jawed vertebrates (gnathostomes), such as the four Hox clusters in the human, compared to the single ancestral cluster in invertebrates. To date, as the most early-branching lineages in vertebrates, cyclostomes (hagfishes and lampreys) have been used for comparative analyses of gene regulations and functions. However, assignment of orthology/paralogy for cyclostomes' genes is not unambiguously demonstrated. Thus, there is a high degree of incongruence in tree topologies between gene families, although whole genome duplications postulate uniform patterns in gene phylogeny. In this review, we demonstrate how expansion of an ancient genome before the cyclostome-gnathostome split, followed by reciprocal gene loss, can cause this incongruence. This is sometimes referred to as 'hidden paralogy'.     

Protein domains correlate strongly with exons in multiple eukaryotic genomes--evidence of exon shuffling?

We conducted a multi-genome analysis correlating protein domain organization with the exon-intron structure of genes in nine eukaryotic genomes. We observed a significant correlation between the borders of exons and domains on a genomic scale for both invertebrates and vertebrates. In addition, we found that the more complex organisms displayed consistently stronger exon-domain correlation, with substantially more significant correlations detected in vertebrates compared with invertebrates. Our observations concur with the principles of exon shuffling theory, including the prediction of predominantly symmetric phase of introns flanking the borders of correlating exons. These results suggest that extensive exon shuffling events during evolution significantly contributed to the shaping of eukaryotic proteomes.     

Molecular mechanisms of early neurogenesis in vertebrates

Recent studies revealed a great variety of genes which control the early development of the central nervous system in vertebrates, including neural induction and differentiation of primary neurons. Most of these genes were first identified inDrosophila melanogaster, then their structural and functional homologs were found in vertebrates. Modern data on the molecular-genetic mechanisms of vertebrate neurogenesis are reviewed. The neurogenetic mechanisms are compared for vertebrates and invertebrates. Widely discussed hypotheses are considered along with the commonly accepted mechanisms.     

Comparative study of the <Emphasis Type="Italic">P2X</Emphasis> gene family in animals and plants

P2X receptors are ligand-gated ion channels that can bind with the adenosine triphosphate (ATP) and have diverse functional roles in neuropathic pain, inflammation, special sense, and so on. In this study, 180 putative P2X genes, including 176 members in 32 animal species and 4 members in 3 species of lower plants, were identified. These genes were divided into 13 groups, including 7 groups in vertebrates and 6 groups in invertebrates and lower plants, through phylogenetic analysis. Their gene organization and motif composition are conserved in most predicted P2X members, while group-specific features were also found. Moreover, synteny relationships of the putative P2X genes in vertebrates are conserved while simultaneously experiencing a series of gene insertion, inversion, and transposition. Recombination signals were detected in almost all of the vertebrates and invertebrates, suggesting that intragenic recombination may play a significant role in the evolution of P2X genes. Selection analysis also identified some positively selected sites that acted on the evolution of most of the predicted P2X proteins. The phenomenon of alternative splicing occurred commonly in the putative P2X genes of vertebrates. This article explored in depth the evolutional relationship among different subtypes of P2X genes in animal and plants and might serve as a solid foundation for deciphering their functions in further studies.     

A putative helical cytokine functioning in innate immune signalling in Drosophila melanogaster

In invertebrates and vertebrates, innate immunity is considered the first line of defense mechanism against non-self material. In vertebrates, cytokines play a critical role in innate immune signalling. To date, however, the existence of genes encoding for invertebrate helical cytokines has been anticipated, but never demonstrated. Here, we report the first structural and functional evidence of a gene encoding for a putative helical cytokine in Drosophila melanogaster. Functional experiments demonstrate that its expression, as well as that of the antimicrobial factors defensin and cecropin A1, is significantly increased after immune stimulation. These observations suggest the involvement of helical cytokines in the innate immune response of invertebrates.     

Numerous peptidoglycan recognition protein genes expressed in the bacteriome of the green rice leafhopper Nephotettix cincticeps (Hemiptera,Cicadellidae)

Applied Entomology and Zoology - Peptidoglycan recognition proteins (PGRPs) contribute to the immune response of vertebrates and higher invertebrates. Animals have a varying number of PGRP genes: 4...     

A putative helical cytokine functioning in innate immune signalling in Drosophila melanogaster

In invertebrates and vertebrates, innate immunity is considered the first line of defense mechanism against non-self material. In vertebrates, cytokines play a critical role in innate immune signalling. To date, however, the existence of genes encoding for invertebrate helical cytokines has been anticipated, but never demonstrated. Here, we report the first structural and functional evidence of a gene encoding for a putative helical cytokine in Drosophila melanogaster. Functional experiments demonstrate that its expression, as well as that of the antimicrobial factors defensin and cecropin A1, is significantly increased after immune stimulation. These observations suggest the involvement of helical cytokines in the innate immune response of invertebrates.     

Evolutionary history of the vertebrate mitogen activated protein kinases family

Background

The mitogen activated protein kinases (MAPK) family pathway is implicated in diverse cellular processes and pathways essential to most organisms. Its evolution is conserved throughout the eukaryotic kingdoms. However, the detailed evolutionary history of the vertebrate MAPK family is largely unclear.

Methodology/Principal Findings

The MAPK family members were collected from literatures or by searching the genomes of several vertebrates and invertebrates with the known MAPK sequences as queries. We found that vertebrates had significantly more MAPK family members than invertebrates, and the vertebrate MAPK family originated from 3 progenitors, suggesting that a burst of gene duplication events had occurred after the divergence of vertebrates from invertebrates. Conservation of evolutionary synteny was observed in the vertebrate MAPK subfamilies 4, 6, 7, and 11 to 14. Based on synteny and phylogenetic relationships, MAPK12 appeared to have arisen from a tandem duplication of MAPK11 and the MAPK13-MAPK14 gene unit was from a segmental duplication of the MAPK11-MAPK12 gene unit. Adaptive evolution analyses reveal that purifying selection drove the evolution of MAPK family, implying strong functional constraints of MAPK genes. Intriguingly, however, intron losses were specifically observed in the MAPK4 and MAPK7 genes, but not in their flanking genes, during the evolution from teleosts to amphibians and mammals. The specific occurrence of intron losses in the MAPK4 and MAPK7 subfamilies might be associated with adaptive evolution of the vertebrates by enhancing the gene expression level of both MAPK genes.

Conclusions/Significance

These results provide valuable insight into the evolutionary history of the vertebrate MAPK family.     

Conserved signals in the 5' flanking region of eukaryotic nuclear tRNA genes.

The statistical analysis of 5' flanking regions of eukaryotic tRNA genes was done. The analysis of nucleotides in the sequence of fungi and invertebrates showed a high content of A and T in the flanking regions versus coding regions where G and C dominate. In contrast to these results in vertebrates sequences the preferences of any nucleotide in flanking regions was not observed. The analysis of tetrads showed five conserved signals: TTGT, (T/A)(T/A)ATA, A(C/T)(C/A)A in the tRNA genes of fungi, (A/T)TGA of invertebrates and (A/T)GAG of vertebrates. The analysis of 3' flanking regions did not show any conserved signals except well known poly-T tracks.     

Wg signaling in Drosophila heart development as a pioneering model

The heart is one of the first functional embryonic organs occurring during development. The fundamental developmental processes and genes involved in cardiogenesis are conserved between the invertebrates and vertebrates. In the past fifteen years, one of signaling pathways that has been best characterized in heart development in both invertebrates and vertebrates is the Wg/Wnt signaling pathways. Since our discovery of the Wg signaling required for the early heart development in Drosophila, the past fifteen years have witnessed tremendous progress in the understanding of specific Wnt signaling pathways in vertebrate cardiogenesis. This review will summarize the current state of knowledge of Wg signaling transduction in Drosophila heart development, which will benefit our understanding of vertebrate cardiogenesis and human congenital malformations.     

A comparison of vertebrate interferon gene families detected by hybridization with human interferon DNA

Cloned human interferon complementary DNAs were used as hybridization probes to detect interferon alpha and beta gene families in restriction endonuclease digests of total genomic DNA isolated from a wide range of vertebrates and invertebrates. A complex interferon-alpha multigene family was detected in all mammals examined, whereas there was little or no cross-hybridization of human interferon-alpha complementary DNA to non-mammalian vertebrates or invertebrates. In contrast, human interferon-beta complementary DNA detected one or two interferon-beta genes in all mammals tested, with the exception of the cow and the blackbuck, both of which possessed a complex interferon-beta multigene family which has presumably arisen by a recent series of gene duplications. Interferon-beta sequences could also be detected in non-mammalian vertebrates ranging from birds to bony fish. Detailed restriction endonuclease mapping of DNA sequences neighbouring the interferon-beta gene in a variety of primates indicated a strong evolutionary conservation of flanking sequences, particularly on the 3' side of the gene.