The amplification and evolution of orthologous 22-kDa α-prolamin tandemly arrayed genes in <Emphasis Type="Italic">coix</Emphasis>, sorghum and maize genomes

Tandemly arrayed genes (TAGs) account for about one-third of the duplicated genes in eukaryotic genomes. They provide raw genetic material for biological evolution, and play important roles in genome evolution. The 22-kDa prolamin genes in cereal genomes represent typical TAG organization, and provide the good material to investigate gene amplification of TAGs in closely related grass genomes. Here, we isolated and sequenced the Coix 22-kDa prolamin (coixin) gene cluster (283 kb), and carried out a comparative analysis with orthologous 22-kDa prolamin gene clusters from maize and sorghum. The 22-kDa prolamin gene clusters descended from orthologous ancestor genes, but underwent independent gene amplification paths after the separation of these species, therefore varied dramatically in sequence and organization. Our analysis indicated that the gene amplification model of 22-kDa prolamin gene clusters can be divided into three major stages. In the first stage, rare gene duplications occurred from the ancestor gene copy accidentally. In the second stage, rounds of gene amplification occurred by unequal crossing over to form tandem gene array(s). In the third stage, gene array was further diverged by other genomic activities, such as transposon insertions, segmental rearrangements, etc. Unlike their highly conserved sequences, the amplified 22-kDa prolamin genes diverged rapidly at their expression capacities and expression levels. Such processes had no apparent correlation to age or order of amplified genes within TAG cluster, suggesting a fast evolving nature of TAGs after gene amplification. These results provided insights into the amplification and evolution of TAG families in grasses.     

Detection of gene duplications and block duplications in eukaryotic genomes

Several eukaryotic genomes have been completely sequenced and this provides an opportunity to investigate the extent and characteristics (e.g., single gene duplication, block duplication, etc.) of gene duplication in a genome. Detecting duplicate genes in a genome, however, is not a simple problem because of several complications such as domain shuffling, the existence of isoforms derived from alternative splicing, and annotational errors in the databases. We describe a method for overcoming these difficulties and the extents of gene duplication in the genomes of Drosophila melanogaster, Caenorhabditis elegans, and yeast inferred from this method. We also describe a method for detecting block duplications in a genome. Application of this method showed that block duplication is a common phenomenon in both yeast and nematode. The patterns of block duplication in the two species are, however, markedly different. Yeast shows much more extensive block duplication than nematode, with some chromosomes having more than 40% of the duplications derived from block duplications. Moreover, in yeast the majority of block duplications occurred between chromosomes, while in nematode most block duplications occurred within chromosomes.     

Early vertebrate chromosome duplications and the evolution of the neuropeptide Y receptor gene regions

Background  

One of the many gene families that expanded in early vertebrate evolution is the neuropeptide (NPY) receptor family of G-protein coupled receptors. Earlier work by our lab suggested that several of the NPY receptor genes found in extant vertebrates resulted from two genome duplications before the origin of jawed vertebrates (gnathostomes) and one additional genome duplication in the actinopterygian lineage, based on their location on chromosomes sharing several gene families. In this study we have investigated, in five vertebrate genomes, 45 gene families with members close to the NPY receptor genes in the compact genomes of the teleost fishes Tetraodon nigroviridis and Takifugu rubripes. These correspond to Homo sapiens chromosomes 4, 5, 8 and 10.     

Genome of papaya, a fast growing tropical fruit tree

Papaya is a major fruit crop in tropical and subtropical regions worldwide. It has long been recognized as a nutritious and healthy fruit rich in vitamins A and C. Its small genome, unique aspects of nascent sex chromosomes, and agricultural importance are justifications for sequencing the genome. A female plant of the transgenic variety SunUp was selected for sequencing its genome to avoid the complication of assembling the XY chromosomes in a male or hermaphrodite plant. The draft genome revealed fewer genes than sequenced genomes of flowering plants, partly due to its lack of genome wide duplication since the ancient triplication event shared by eudicots. Most gene families have fewer members in papaya, including significantly fewer disease resistance genes. However, striking amplifications in gene number were found in some functional groups, including MADS-box genes, starch synthases, and volatiles that might affect the speciation and adaptation of papaya. The draft genome was used to clone a gene controlling fruit flesh color and to accelerate the construction of physical maps of sex chromosomes in papaya. Finishing the papaya genome and re-sequencing selected genomes in the family will further facilitate papaya improvement and the study of genome and sex chromosome evolution in angiosperms, particularly in Caricaceae.     

Conserved synteny between the Ciona genome and human paralogons identifies large duplication events in the molecular evolution of the insulin-relaxin gene family

The aims of the study were to outline the sequence of eventsthat gave rise to the vertebrate insulin-relaxin gene familyand the chromosomal regions in which they reside. We analyzedthe gene content surrounding the human insulin/relaxin geneswith respect to what family they belonged to and if the duplicationhistory of investigated families parallels the evolution ofthe insulin-relaxin family members. Markov Clustering and phylogeneticanalysis were used to determine family identity. More than 15%of the genes belonged to families that have paralogs in theregions, defining two sets of quadruplicate paralogy regions.Thereby, the localization of insulin/relaxin genes in humansis in accordance with those regions on human chromosomes 1,11, 12, 19q (insulin/insulin-like growth factors) and 1, 6p/15q,9/5, 19p (insulin-like factors/relaxins) were formed duringtwo genome duplications. We compared the human genome with thatof Ciona intestinalis, a species that split from the vertebratelineage before the two suggested genome duplications. Two insulin-likeorthologs were discovered in addition to the already describedCi-insulin gene. Conserved synteny between the Ciona regionshosting the insulin-like genes and the two sets of human paralogonsimplies their common origin. Linkage of the two human paralogons,as seen in human chromosome 1, as well as the two regions hostingthe Ciona insulin-like genes suggests that a segmental duplicationgave rise to the region prior to the genome doublings. Thus,preserved gene content provides support that genome duplication(s)in addition to segmental and single-gene duplications shapedthe genomes of extant vertebrates.     

Genomic exploration of the hemiascomycetous yeasts: 20. Evolution of gene redundancy compared to Saccharomyces cerevisiae

We have evaluated the degree of gene redundancy in the nuclear genomes of 13 hemiascomycetous yeast species. Saccharomyces cerevisiae singletons and gene families appear generally conserved in these species as singletons and families of similar size, respectively. Variations of the number of homologues with respect to that expected affect from 7 to less than 24% of each genome. Since S. cerevisiae homologues represent the majority of the genes identified in the genomes studied, the overall degree of gene redundancy seems conserved across all species. This is best explained by a dynamic equilibrium resulting from numerous events of gene duplication and deletion rather than by a massive duplication event occurring in some lineages and not in others.     

OrthoParaMap: Distinguishing orthologs from paralogs by integrating comparative genome data and gene phylogenies

Background  

In eukaryotic genomes, most genes are members of gene families. When comparing genes from two species, therefore, most genes in one species will be homologous to multiple genes in the second. This often makes it difficult to distinguish orthologs (separated through speciation) from paralogs (separated by other types of gene duplication). Combining phylogenetic relationships and genomic position in both genomes helps to distinguish between these scenarios. This kind of comparison can also help to describe how gene families have evolved within a single genome that has undergone polyploidy or other large-scale duplications, as in the case of Arabidopsis thaliana – and probably most plant genomes.     

杨树基因组中染色体基因丰度分化及EST序列对基因覆盖度的检测(英文)

高等植物基因组中,大部分序列为非表达序列,基因序列所占的比例很小,了解基因在基因组中的分布是研究基因组结构的一个重要方面。在美国能源部资助下,一个毛果杨无性系的基因组测序已经完成并对公众发布。杨树全基因组序列的完成,为我们了解林木基因组中基因的分布提供了一个特例。在本文中,我们利用泊松分析对杨树基因组中基因在各个染色体上的密度进行了检测,结果表明杨树基因组中各条染色体的基因含量存在显著差异。杨树全基因组测序项目揭示现代杨树基因组起源于一次古全基因组复制事件(称为杨柳科基因组复制),所以杨树基因组不同染色体间存在很大的同源复制片段。但是我们的研究显示,杨树基因组中大多数高度同源的染色体上基因的密度与染色体间的同源性没有明显关系,这说明杨柳科全基因组复制事件后,各个高度同源染色体上的基因发生了流失,且基因流失的速率是不一样的。同时本文还对近九万条毛果杨EST序列进行了比对分析,结果显示这些EST序列覆盖的基因仅占杨树基因组中基因总数的16.8%左右。EST测序虽然是发现基因的一个重要手段,但小规模EST测序对基因的覆盖度很低,所以小规模EST测序的应用价值是有限的。     

Phylogenetic tests of the hypothesis of block duplication of homologous genes on human chromosomes 6, 9, and 1

There are 10 gene families that have members on both human chromosome 6 (6p21.3, the location of the human major histocompatibility complex [MHC]) and human chromosome 9 (mostly 9q33-34). Six of these families also have members on mouse chromosome 17 (the mouse MHC chromosome) and mouse chromosome 2. In addition, four of these families have members on human chromosome 1 (1q21-25 and 1p13), and two of these have members on mouse chromosome 1. One hypothesis to explain these patterns is that members of the 10 gene families of human chromosomes 6 and 9 were duplicated simultaneously as a result of polyploidization or duplication of a chromosome segment ("block duplication"). A subsequent block duplication has been proposed to account for the presence of representatives of four of these families on human chromosome 1. Phylogenetic analyses of the 9 gene families for which data were available decisively rejected the hypothesis of block duplication as an overall explanation of these patterns. Three to five of the genes on human chromosomes 6 and 9 probably duplicated simultaneously early in vertebrate history, prior to the divergence of jawed and jawless vertebrates, and shortly after that, all four of the genes on chromosomes 1 and 9 probably duplicated as a block. However, the other genes duplicated at different times scattered over at least 1.6 billion years. Since the occurrence of these clusters of related genes cannot be explained by block duplication, one alternative explanation is that they cluster together because of shared functional characteristics relating to expression patterns.      

Updating the str and srj (stl) families of chemoreceptors in Caenorhabditis nematodes reveals frequent gene movement within and between chromosomes

The seven transmembrane receptor (str) and srj (renamed from stl) families of chemoreceptors have been updated and the genes formally named following completion of the Caenorhabditis elegans genome sequencing project. Analysis of gene locations revealed that 84% of the 320 genes and pseudogenes in these two families reside on the large chromosome V. Movements to other chromosomes, especially chromosome IV, have nevertheless been relatively common, but only one has led to further gene family diversification. Comparisons with homologs in C. briggsae indicated that 22.5% of these genes have been newly formed by gene duplication since the species split, while also showing that four have been lost by large deletions. These patterns of gene evolution are similar to those revealed by analysis of the equally large srh family of chemoreceptors, and are likely to reflect general features of nematode genome dynamics. Thus large random deletions presumably balance the rapid proliferation of genes and their degeneration into pseudogenes, while gene movement within and between chromosomes keeps these nematode genomes in flux.     

The random versus fragile breakage models of chromosome evolution: a matter of resolution

Conserved synteny––the sharing of at least one orthologous gene by a pair of chromosomes from two species––can, in the strictest sense, be viewed as sequence conservation between chromosomes of two related species, irrespective of whether coding or non-coding sequence is examined. The recent sequencing of multiple vertebrate genomes indicates that certain chromosomal segments of considerable size are conserved in gene order as well as underlying non-coding sequence across all vertebrates. Some of these segments lost genes or non-coding sequence and/or underwent breakage only in teleost genomes, presumably because evolutionary pressure acting on these regions to remain intact were relaxed after an additional round of whole genome duplication. Random reporter insertions into zebrafish chromosomes combined with computational genome-wide analysis indicate that large chromosomal areas of multiple genes contain long-range regulatory elements, which act on their target genes from several gene distances away. In addition, computational breakpoint analyses suggest that recurrent evolutionary breaks are found in “fragile regions” or “hotspots”, outside of the conserved blocks of synteny. These findings cannot be accommodated by the random breakage model and suggest that this view of genome and chromosomal evolution requires substantial reassessment.     

Analysis of lamprey and hagfish genes reveals a complex history of gene duplications during early vertebrate evolution

It has been proposed that two events of duplication of the entire genome occurred early in vertebrate history (2R hypothesis). Several phylogenetic studies with a few gene families (mostly Hox genes and proteins from the MHC) have tried to confirm these polyploidization events. However, data from a single locus cannot explain the evolutionary history of a complete genome. To study this 2R hypothesis, we have taken advantage of the phylogenetic position of the lamprey to study the history of gene duplications in vertebrates. We selected most gene families that contain several paralogous genes in vertebrates and for which lamprey genes and an out-group are known in databases. In addition, we isolated members of the nuclear receptor superfamily in lamprey. Hagfish genes were also analyzed and found to confirm the lamprey gene analysis. Consistent with the 2R hypothesis, the phylogenetic analysis of 33 selected gene families, dispersed through the whole genome, revealed that one period of gene duplication arose before the lamprey-gnathostome split and this was followed by a second period of gene duplication after the lamprey-gnathostome split. Nevertheless, our analysis suggests that numerous gene losses and other gene-genome duplications occurred during the evolution of the vertebrate genomes. Thus, the complexity of all the paralogy groups present in vertebrates should be explained by the contribution of genome duplications (2R hypothesis), extra gene duplications, and gene losses.     

Seventy million years of concerted evolution of a homoeologous chromosome pair, in parallel, in major Poaceae lineages

Whole genome duplication ~70 million years ago provided raw material for Poaceae (grass) diversification. Comparison of rice (Oryza sativa), sorghum (Sorghum bicolor), maize (Zea mays), and Brachypodium distachyon genomes revealed that one paleo-duplicated chromosome pair has experienced very different evolution than all the others. For tens of millions of years, the two chromosomes have experienced illegitimate recombination that has been temporally restricted in a stepwise manner, producing structural stratification in the chromosomes. These strata formed independently in different grass lineages, with their similarities (low sequence divergence between paleo-duplicated genes) preserved in parallel for millions of years since the divergence of these lineages. The pericentromeric region of this homeologous chromosome pair accounts for two-thirds of the gene content differences between the modern chromosomes. Both intriguing and perplexing is a distal chromosomal region with the greatest DNA similarity between surviving duplicated genes but also with the highest concentration of lineage-specific gene pairs found anywhere in these genomes and with a significantly elevated gene evolutionary rate. Intragenomic similarity near this chromosomal terminus may be important in hom(e)ologous chromosome pairing. Chromosome structural stratification, together with enrichment of autoimmune response-related (nucleotide binding site-leucine-rich repeat) genes and accelerated DNA rearrangement and gene loss, confer a striking resemblance of this grass chromosome pair to the sex chromosomes of other taxa.     

The revolution of the biology of the genome

Sequence data of entire eukaryotic genomes and their detailed comparison have provided new evidence on genome evolution. The major mechanisms involved in the increase of genome sizes are polyploidization and gene duplication.Subsequent gene silencing or mutations, preferentially in regulatory sequences of genes, modify the genome and permit the development of genes with new properties. Mechanisms such as lateral gene transfer, exon shuffling or the creation of new genes by transposition contribute to the evolution of a genome, but remain of relatively restricted relevance.Mechanisms to decrease genome sizes and, in particular, to remove specific DNA sequences, such as blocks of satellite DNAs, appear to involve the action of RNA interference (RNAi). RNAi mechanisms have been proven to be involved in chromatin packaging related with gene inactivation as well as in DNA excision during the macronucleus development in ciliates.     

From genomes to morphology: a view from amphioxus

Holland, P.W.H. 2010. From genomes to morphology: a view from amphioxus. —Acta Zoologica (Stockholm) 91 : 81–86 As complete genome sequences are determined from an ever‐increasing number of animal species, new opportunities are arising for comparative biology. For zoologists interested in the evolution of shape and form, however, there is a problem. The link between genome sequence and morphology is not direct and is obfuscated by complex and evolving genetic pathways, even when conserved regulatory genes are considered. Nonetheless, a large‐scale comparison of genome sequences between extant chordates reveals an intriguing parallel between genotypic and phenotypic evolution. Tunicates have highly altered genomes, with loss of ancestral genes and shuffled genetic arrangements, while vertebrate genomes are also derived through gene loss and genome duplication. The recently sequenced amphioxus genome, in contrast, reveals much greater stasis on the cephalochordate lineage, in parallel to a less derived body plan. The opportunities and challenges for relating genome evolution to morphological evolution are discussed.     

After the duplication: gene loss and adaptation in Saccharomyces genomes

The ancient duplication of the Saccharomyces cerevisiae genome and subsequent massive loss of duplicated genes is apparent when it is compared to the genomes of related species that diverged before the duplication event. To learn more about the evolutionary effects of the duplication event, we compared the S. cerevisiae genome to other Saccharomyces genomes. We demonstrate that the whole genome duplication occurred before S. castellii diverged from S. cerevisiae. In addition to more accurately dating the duplication event, this finding allowed us to study the effects of the duplication on two separate lineages. Analyses of the duplication regions of the genomes indicate that most of the duplicated genes (approximately 85%) were lost before the speciation. Only a small amount of paralogous gene loss (4-6%) occurred after speciation. On the other hand, S. castellii appears to have lost several hundred genes that were not retained as duplicated paralogs. These losses could be related to genomic rearrangements that reduced the number of chromosomes from 16 to 9. In addition to S. castellii, other Saccharomyces sensu lato species likely diverged from S. cerevisiae after the duplication. A thorough analysis of these species will likely reveal other important outcomes of the whole genome duplication.     

基因倍增研究进展

基因倍增是指DNA片段在基因组中复制出一个或更多的拷贝,这种DNA片段可以是一小段基因组序列、整条染色体,甚至是整个基因组。基因倍增是基因组进化最主要的驱动力之一,是产生具有新功能的基因和进化出新物种的主要原因之一。本文综述了脊椎动物、模式植物和酵母在进化过程中基因倍增研究领域的最新进展,并讨论了基因倍增研究的发展方向。     

On the Origins of a Vibrio Species

Thirty-two genome sequences of various Vibrionaceae members are compared, with emphasis on what makes V. cholerae unique. As few as 1,000 gene families are conserved across all the Vibrionaceae genomes analysed; this fraction roughly doubles for gene families conserved within the species V. cholerae. Of these, approximately 200 gene families that cluster on various locations of the genome are not found in other sequenced Vibrionaceae; these are possibly unique to the V. cholerae species. By comparing gene family content of the analysed genomes, the relatedness to a particular species is identified for two unspeciated genomes. Conversely, two genomes presumably belonging to the same species have suspiciously dissimilar gene family content. We are able to identify a number of genes that are conserved in, and unique to, V. cholerae. Some of these genes may be crucial to the niche adaptation of this species.     

Evolutionary analyses of non‐family genes in plants

There are a large number of ‘non‐family’ (NF) genes that do not cluster into families with three or more members per genome. While gene families have been extensively studied, a systematic analysis of NF genes has not been reported. We performed comparative studies on NF genes in 14 plant species. Based on the clustering of protein sequences, we identified ~94 000 NF genes across these species that were divided into five evolutionary groups: Viridiplantae wide, angiosperm specific, monocot specific, dicot specific, and those that were species specific. Our analysis revealed that the NF genes resulted largely from less frequent gene duplications and/or a higher rate of gene loss after segmental duplication relative to genes in both low‐copy‐number families (LF; 3–10 copies per genome) and high‐copy‐number families (HF; >10 copies). Furthermore, we identified functions enriched in the NF gene set as compared with the HF genes. We found that NF genes were involved in essential biological processes shared by all plant lineages (e.g. photosynthesis and translation), as well as gene regulation and stress responses associated with phylogenetic diversification. In particular, our analysis of an Arabidopsis protein–protein interaction network revealed that hub proteins with the top 10% most connections were over‐represented in the NF set relative to the HF set. This research highlights the roles that NF genes may play in evolutionary and functional genomics research.