Genomic structure of the sandworm, Perinereis vancaurica tetradentata, troponin C

Troponin C (TnC) superfamily genes essentially possess five introns, the positions of all but the fourth being highly conserved. The fourth intron is frequently absent from protostomian invertebrate genes, such as calmodulin or TnC. We previously proposed that the common ancestor of TnC superfamily genes never possessed an intron corresponding to today's fourth introns, and that members of the superfamily independently gained a fourth intron in the evolutionary pathway of each lineage. In the present study, we isolated the TnC cDNA from the sandworm, Perinereis vancaurica tetradentata and determined its genomic structure. Sandworm TnC appears to exist as a single copy gene consisting of six exons and five introns. The positions of the first, second, third and fifth introns are identical to other TnCs, but that of the fourth intron is unique. This is in good agreement with the above-mentioned scheme, i.e. the gain of the fourth intron of sandworm TnC might have occurred within the annelid lineage after annelida/mollusca divergence.     

Globin gene family evolution and functional diversification in annelids

Globins are the most common type of oxygen-binding protein in annelids. In this paper, we show that circulating intracellular globin (Alvinella pompejana and Glycera dibranchiata), noncirculating intracellular globin (Arenicola marina myoglobin) and extracellular globin from various annelids share a similar gene structure, with two conserved introns at canonical positions B12.2 and G7.0. Despite sequence divergence between intracellular and extracellular globins, these data strongly suggest that these three globin types are derived from a common ancestral globin-like gene and evolved by duplication events leading to diversification of globin types and derived functions. A phylogenetic analysis shows a distinct evolutionary history of annelid extracellular hemoglobins with respect to intracellular annelid hemoglobins and mollusc and arthropod extracellular hemoglobins. In addition, dehaloperoxidase (DHP) from the annelid, Amphitrite ornata, surprisingly exhibits close phylogenetic relationships to some annelid intracellular globins. We have characterized the gene structure of A. ornata DHP to confirm assumptions about its homology with globins. It appears that it has the same intron position as in globin genes, suggesting a common ancestry with globins. In A. ornata, DHP may be a derived globin with an unusual enzymatic function.     

Conservation of the positions of metazoan introns from sponges to humans

Sponges (phylum Porifera) are the phylogenetic oldest Metazoa still extant. They can be considered as reference animals (Urmetazoa) for the understanding of the evolutionary processes resulting in the creation of Metazoa in general and also for the metazoan gene organization in particular. In the marine sponge Suberites domuncula, genes encoding p38 and JNK kinases contain nine and twelve introns, respectively. Eight introns in both genes share the same positions and the identical phases. One p38 intron slipped for six bases and the JNK gene has three more introns. However, the sequences of the introns are not conserved and the introns in JNK gene are generally much longer. Introns interrupt most of the conserved kinase subdomains I-XI and are found in all three phases (0, 1 and 2). We analyzed in details p38 and JNK genes from human, Caenorhabditis elegans and Drosophila melanogaster and found in most genes introns at the positions identical to those in sponge genes. The exceptions are two p38 genes from D. melanogaster that have lost all introns in the coding sequence. The positions of 11 introns in each of four human p38 genes are fully conserved and ten introns occupy identical positions as the introns in sponge p38 or JNK genes. The same is true for nine, out of ten introns in the human JNK-1 gene. The introns in human p38 and JNK genes are on average more than ten times longer than corresponding introns in sponges. It was proposed that yeast HOG1-like kinases (from i.e. Saccharomyces cerevisiae and Emericella nidulans) and metazoan p38 and JNK kinases are orthologues. p38 and JNK genes were created after the split from fungi by the duplication and diversification of the HOG1-like progenitor gene. Our results further support the common origin of p38 and JNK genes and speak in favor of a very early time of duplication. The ancestral gene contained at least ten introns, which are still present at the very conserved positions in p38 and JNK genes of extant animals. Four of these introns are present at the same positions in the HOG-like gene in the fungus E. nidulans. The others probably entered the ancestral gene after the split of fungi, but before the duplication of the gene and before the creation of the common, urmetazoan progenitor of all multicellular animals. A second gene coding for an immune molecule is described, the allograft inflammatory factor, which likewise showed a highly conserved exon/intron structure in S. domuncula and in human. These data show that the intron/exon borders are highly conserved in genes from sponges to human.     

Flanking genes of an essential gene give information about the evolution of metazoa

We collected as much information as possible on new lamin genes and their flanking genes. The number of lamin genes varies from 1 to 4 depending more or less on the phylogenetic position of the species. Strong genome drift is recognised by fewer and unusually placed introns and a change in flanking genes. This applies to the nematode Caenorhabditis elegans, the insect Drosophila melanogaster, the urochordate Ciona intestinalis, the annelid Capitella teleta and the planaria Schmidtea mediterranea. In contrast stable genomes show astonishing conservation of the flanking genes. These are identical in the sea anemone Nematostella vectensis and the cephalochordate Branchiostoma floridae lamin B1 gene. Even in the lamin B1 genes from Xenopus tropicalis and man one of the flanking genes is conserved. Finally our analysis forms the basis for a molecular analysis of metazoan phylogeny.     

人管家基因启动子序列中的组合转录调控元件分析

研究表明,第一内含子可能参与基因转录调控.利用统计方法提取人管家基因上游至第一内含子序列中潜在的组合转录调控模体,分析模体间的距离、区域分布等特征,探讨内含子参与基因转录调控的可能性及其参与方式.在管家基因中共获得960对潜在转录调控模体对,其中57%与实验已知的具有转录相互作用的因子对吻合,共涉及12组因子对.分析发现,绝大多数模体对(80%)偏向于上游区域及"上游-内含子"区域,进一步支持了内含子参与基因转录调控的假设,并据此推测内含子与上游序列之间具有转录协同作用,模体在基因转录起始位点(TSS)附近较为集中,模体对的两个模体之间距离较近,60%左右距离在200 bp以内,特别地,65%的模体对特征距离在100 bp以内,短距离间隔有利于转录因子间的协同作用.这些结果将有助于对人基因转录调控机制及内含子功能的深入认识.     

Gene Structure and Molecular Phylogeny of the Linker Chains from the Giant Annelid Hexagonal Bilayer Hemoglobins

Giant extracellular hexagonal bilayer hemoglobin (HBL-Hb), found only in annelids, is an ∼3500-kDa heteropolymeric structure involved in oxygen transport. The HBL-Hbs are comprised of globin and linker chains, the latter being required for the assembly of the quaternary structure. The linker chains, varying in size from 225 to 283 amino acids, have a conserved cysteine-rich domain within their N-terminal moiety that is homologous to the cysteine-rich modules constituting the ligand binding domain of the low-density lipoprotein receptor (LDLR) protein family found in many metazoans. We have investigated the gene structure of linkers from Arenicola marina, Alvinella pompejana, Nereis diversicolor, Lumbricus terrestris, and Riftia pachyptila. We found, contrary to the results obtained earlier with linker genes from N. diversicolor and L. terrestris, that in all of the foregoing cases, the linker LDL-A module is flanked by two phase 1 introns, as in the human LDLR gene, with two more introns in the 3′ side whose positions varied with the species. In addition, we obtained 13 linker cDNAs that have been determined experimentally or found in the EST database LumbriBASE. A molecular phylogenetic analysis of the linker primary sequences demonstrated that they cluster into two distinct families of linker proteins. We propose that the common gene ancestor to annelid linker genes exhibited a four-intron and five-exon structure and gave rise to the two families subsequent to a duplication event.     

Comparative analysis of bacterial-origin genes for plant mitochondrial ribosomal proteins

Mitochondrial ribosomes contain bacterial-type proteins reflecting their endosymbiotic heritage, and a subset of these genes is retained within the mitochondrion in land plants. Variation in gene location is observed, however, because migration to the nucleus is still an ongoing evolutionary process in plants. To gain insights into adaptation events related to successful gene transfer, we have compiled data for bacterial-origin mitochondrial-type ribosomal protein genes from the completely sequenced Arabidopsis and rice genomes. Approximately 75% of such nuclear-located genes encode amino-terminal extensions relative to their Escherichia coli counterparts, and of that set, only about 30% have introns at (or near) the junction in support of an exon shuffling-type recruitment of upstream expression/targeting signals. We find that genes that were transferred to the nucleus early in eukaryotic evolution have, on average, about twofold higher density of introns within the core ribosomal protein sequences than do those that moved to the nucleus more recently. About 20% of such introns are at positions identical to those in human orthologs, consistent with their ancestral presence. Plant mitochondrial-type ribosomal protein genes have dispersed chromosomal locations in the nucleus, and about 20% of them are present in multiple unlinked copies. This study provides new insights into the evolutionary history of endosymbiotic bacterial-type genes that have been transferred from the mitochondrion to the nucleus.     

The compositional properties of human genes

Summary The present work represents the first attempt to study in greater detail previously proposed compositional correlations in genomes, based on a body of additional data relating to gene localizations as well as to extended flanking sequences extracted from gene banks. We have investigated the correlations that exist between (1) the GC levels of exons of human genes, and (2) the GC levels of either intergenic sequences or introns associated with the genes under consideration. In both cases, linear relationships with slopes close to unity were found. The similarity of the linear relationships indicates similar GC levels in intergenic sequences and introns located in the same isochores. Moreover, both intergenic sequences and introns showed GC levels 5–10% lower than the corresponding exons. The above findings considerably strengthen the previously drawn conclusion that coding and noncoding sequences (both inter- and intragenic) from the same isochores of the human genome are compositionally correlated. In addition, we find linear correlations between the GC levels of codon positions and of the intergenic sequences or introns associated with the corresponding genes, as well as among the GC levels of codon positions of genes.     

Where is the difference between the genomes of humans and annelids?

The first systematic investigation of an annelid genome has revealed that the genes of the marine worm Platynereis dumerilii are more closely related to those of vertebrates than to those of insects or nematodes. For hundreds of millions of years vertebrates have preserved exon-intron structures descended from their last common ancestor with the annelids.     

Intronic gene conversion in the evolution of human X-linked color vision genes

Human red and green visual pigment genes are X-linked duplicate genes. To study their evolutionary history, introns 2 and 4 (1,987 and 1,552 bp, respectively) of human red and green pigment genes were sequenced. Surprisingly, we found that intron 4 sequences of these two genes are identical and that the intron 2 sequences differ by only 0.3%. The low divergences are unexpected because the duplication event producing the two genes is believed to have occurred before the separation of the human and Old World monkey (OWM) lineages. Indeed, the divergences in the two introns are significantly lower than both the synonymous divergence (3.2% +/- 1.1%) and the nonsynonymous divergence (2.0% +/- 0.5%) in the coding sequences (exons 1-6). A comparison of partial sequences of exons 4 and 5 of human and OWM red and green pigment genes supports the hypothesis that the gene duplication occurred before the human-OWM split. In conclusion, the high similarities in the two intron sequences might be due to very recent gene conversion, probably during evolution of the human lineage.      

Complete genomic structure of human rpS3: identification of functional U15b snoRNA in the fifth intron

Analysis of the complete genomic structure of the human ribosomal protein S3 (rpS3) gene revealed the presence of a functional U15b snoRNA gene in its intron. Human ribosomal protein S3 (rpS3) gene of 6115 bp long has been identified to contain six introns and seven exons in this study. The first and fifth introns of human S3 gene contain functional U15 snoRNA genes. Although Xenopus and Fugu counterparts also have six introns and seven exons, S3 gene of Fugu contains two functional U15 snoRNAs in the fourth and sixth introns and two pseudo genes for U15 snoRNAs in the first and fifth introns. In Xenopus S1 gene encoding ribosomal protein S3, however, three of its six introns contain U15 snoRNA gene sequence. Sequence comparison of the U15 genes from Xenopus, Fugu and human revealed that the regions involved in binding to 28S rRNA and the consensus sequence (C, D and D' boxes) for snoRNAs are highly conserved among those genes from these three species. Human U15a and U15b RNAs which are derived from the first and the fifth introns, respectively, have been identified to be functional by microinjection of human U15a and U15b snoRNAs into Xenopus oocyte. Northern blot and primer extension analyses confirm that human U15b snoRNA is expressed in vivo.     

Functional characterization of spliceosomal introns and identification of U2, U4, and U5 snRNAs in the deep-branching eukaryote Entamoeba histolytica

Pre-mRNA splicing is essential to ensure accurate expression of many genes in eukaryotic organisms. In Entamoeba histolytica, a deep-branching eukaryote, approximately 30% of the annotated genes are predicted to contain introns; however, the accuracy of these predictions has not been tested. In this study, we mined an expressed sequence tag (EST) library representing 7% of amoebic genes and found evidence supporting splicing of 60% of the testable intron predictions, the majority of which contain a GUUUGU 5' splice site and a UAG 3' splice site. Additionally, we identified several splice site misannotations, evidence for the existence of 30 novel introns in previously annotated genes, and identified novel genes through uncovering their spliced ESTs. Finally, we provided molecular evidence for the E. histolytica U2, U4, and U5 snRNAs. These data lay the foundation for further dissection of the role of RNA processing in E. histolytica gene expression.     

Intron-exon structures of eukaryotic model organisms.

To investigate the distribution of intron-exon structures of eukaryotic genes, we have constructed a general exon database comprising all available intron-containing genes and exon databases from 10 eukaryotic model organisms: Homo sapiens, Mus musculus, Gallus gallus, Rattus norvegicus, Arabidopsis thaliana, Zea mays, Schizosaccharomyces pombe, Aspergillus, Caenorhabditis elegans and Drosophila. We purged redundant genes to avoid the possible bias brought about by redundancy in the databases. After discarding those questionable introns that do not contain correct splice sites, the final database contained 17 102 introns, 21 019 exons and 2903 independent or quasi-independent genes. On average, a eukaryotic gene contains 3.7 introns per kb protein coding region. The exon distribution peaks around 30-40 residues and most introns are 40-125 nt long. The variable intron-exon structures of the 10 model organisms reveal two interesting statistical phenomena, which cast light on some previous speculations. (i) Genome size seems to be correlated with total intron length per gene. For example, invertebrate introns are smaller than those of human genes, while yeast introns are shorter than invertebrate introns. However, this correlation is weak, suggesting that other factors besides genome size may also affect intron size. (ii) Introns smaller than 50 nt are significantly less frequent than longer introns, possibly resulting from a minimum intron size requirement for intron splicing.     

人与小鼠核糖体蛋白基因内含子中的转录调控位点分析

前期对酵母和果蝇核糖体蛋白(Ribosomal protein, RP)基因内含子序列中的寡核苷酸分析表明, 内含子中含有潜在的转录因子结合位点。为进一步发掘核糖体蛋白基因内含子参与转录调控的证据, 文章首先基于频率分析方法抽提出人和小鼠核糖体蛋白基因第一内含子中高频(Over-represented)出现的寡核苷酸片段 (亦称模体, Motif), 这些寡核苷酸中超过85%与已知的转录因子结合位点吻合, 是潜在的转录调控元件。对抽提出的寡核苷酸进行碱基组成分析, 发现95%以上的寡核苷酸富含碱基C和G, 而较少富含A和T。从寡核苷酸在内含子中的分布情况看, 它们相对靠近第一内含子的5′端, 即距离基因转录起始位点和上游区域较近。推测这些特征可能与基因转录调控有关。     

小鼠基因内含子中CpG岛和几个转录调控元件分析

内含子在基因转录调控中的作用已多次被实验报道,然而对其参与调控的普遍性还缺乏足够的理论支持。本研究利用计算分析方法,对小鼠基因内含子中的CpG岛(CpGisland)、TATA框(TATAbox)、CAAT框(CAATbox)以及GC框(GCbox)等元件的出现频率进行分析。结果发现,分别有56.01%、57.16%、65.88%和41.86%的第一内含子具有CpG岛、TATA框、CAAT框以及GC框,而它们在其它内含子中的平均出现频率则分别为14.07%、45.24%、49.91%和13.19%。即使考虑到不同位置的内含子,这些元件在第一内含子中的出现频率也显著高于它们在其它任何位置内含子中的出现频率。由于CpG岛、TATA框、CAAT框以及GC框均与基因的转录调控有关,据此推测小鼠第一内含子在基因转录调控过程中具有潜在的重要性。本研究结果为内含子参与转录调控提供了更多的理论依据。     

Mitochondrial genome and nuclear sequence data support myzostomida as part of the annelid radiation

The echinoderm symbionts Myzostomida are marine worms that show an enigmatic lophotrochozoan body plan. Historically, their phylogenetic origins were obscured due to disagreement about which morphological features are evolutionarily conserved, but now most morphological evidence points to annelid origins. In contrast, recent phylogenetic analyses using different molecular markers produced variable results regarding the position of myzostomids, but all suggested these worms are not derived annelids. To reexamine this issue, we analyzed data from nuclear genes (18S rDNA, 28S rDNA, Myosin II, and Elongation Factor-1alpha), and a nearly complete myzostomid mitochondrial genome. Here, we show that the molecular data are in agreement with the morphological evidence that myzostomids are part of the annelid radiation. This result is robustly supported by mitochondrial (gene order and sequence data) and nuclear data, as well as by recent ultrastructural investigations. Using Bayes factor comparison, alternative hypotheses are shown to lack support. Thus, myzostomids probably evolved from a segmented ancestor and gained a derived anatomy during their long evolutionary history as echinoderm symbionts.     

Protein and gene structure of a chlorocruorin chain of Eudistylia vancouverii

The polychaete annelid, Eudistylia vancouverii, contains as oxygen carrier a hexagonal bilayer (HBL) chlorocruorin. One of the globin chains, chain a1, has 142 amino acids (Mr 16,054.99) and its sequence deviates strongly from other nonvertebrate globin sequences. Unprecedented, it displays a Phe at the distal position E7 as well as at position B10, creating a very hydrophobic heme pocket probably responsible for the low oxygen affinity of the native molecule. Phylogenetic analysis of annelid globin chains clearly proves that globin chain a1 belongs to type I of globin chains having a pattern of 3 cysteine residues essential for the aggregation into a HBL structure. The gene coding for globin chain a1 is interrupted by 2 introns at the conserved positions B12.2 and G7.0. Based on protein and gene structure it can therefore be concluded that the globin chains of chlorocruorins are not fundamentally different from other annelid globin chains.