Gene Duplication and Gene Conversion in the Caenorhabditis elegans Genome

A comprehensive analysis of duplication and gene conversion for 7394 Caenorhabditis elegans genes (about half the expected total for the genome) is presented. Of the genes examined, 40% are involved in duplicated gene pairs. Intrachromosomal or cis gene duplications occur approximately two times more often than expected. In general the closer the members of duplicated gene pairs are, the more likely it is that gene orientation is conserved. Gene conversion events are detectable between only 2% of the duplicated pairs. Even given the excesses of cis duplications, there is an excess of gene conversion events between cis duplicated pairs on every chromosome except the X chromosome. The relative rates of cis and trans gene conversion and the negative correlation between conversion frequency and DNA sequence divergence for unconverted regions of converted pairs are consistent with previous experimental studies in yeast. Three recent, regional duplications, each spanning three genes are described. All three have already undergone substantial deletions spanning hundreds of base pairs. The relative rates of duplication and deletion may contribute to the compactness of the C. elegans genome. Received: 30 July 1998 / Accepted: 12 October 1998     

Exon duplication from a fork head to a homeodomain protein

The evolution of complex organisms such as animals requires a large expansion of the number of genes controlling developmental events. In addition, it is thought that domains are shuffled between genes to further increase the complexity and generate new types of genes and functions. Working with the Caenorhabditis elegans homeobox gene ceh-43, the orthologue of fly Distal-less (Dll), we observed sequence similarity to the C. elegans gene fkh-1. Now, with the complete genomic sequence available, we examined this similarity in detail. The region of similarity is confined essentially to one exon in the carboxy terminus of the two genes. Based on the gene structure, we think that an exon of fkh-1 was duplicated to the carboxy terminus of ceh-43, where it was incorporated as the last exon. This duplication event seems to have happened recently since the similarity on the nucleotide level is higher than the sequence similarity between fkh-1 of C. elegans and C. briggsae. Potentially the duplication event was mediated via a short region of sequence similarity between the two open reading frames of the genes. This duplication event clear shows that a part of a gene can successfully be juxtaposed to another gene. These events may perhaps not be rare. Received: 28 March 1999 / Accepted: 8 June 1999     

Germline Expression Influences Operon Organization in the Caenorhabditis elegans Genome

Operons are found across multiple kingdoms and phyla, from prokaryotes to chordates. In the nematode Caenorhabditis elegans, the genome contains >1000 operons that compose ~15% of the protein-coding genes. However, determination of the force(s) promoting the origin and maintenance of operons in C. elegans has proved elusive. Compared to bacterial operons, genes within a C. elegans operon often show poor coexpression and only sometimes encode proteins with related functions. Using analysis of microarray and large-scale in situ hybridization data, we demonstrate that almost all operon-encoded genes are expressed in germline tissue. However, genes expressed during spermatogenesis are excluded from operons. Operons group together along chromosomes in local clusters that also contain monocistronic germline-expressed genes. Additionally, germline expression of genes in operons is largely independent of the molecular function of the encoded proteins. These analyses demonstrate that mechanisms governing germline gene expression influence operon origination and/or maintenance. Thus, gene expression in a specific tissue can have profound effects on the evolution of genome organization.     

Molecular Evidence for Asymmetric Evolution of Sister Duplicated Blocks after Cereal Polyploidy

Polyploidy (genome duplication) is thought to have contributed to the evolution of the eukaryotic genome, but complex genome structures and massive gene loss during evolution has complicated detection of these ancestral duplication events. The major factors determining the fate of duplicated genes are currently unclear, as are the processes by which duplicated genes evolve after polyploidy. Fine-scale analysis between homologous regions may allow us to better understand post-polyploidy evolution. Here, using gene-by-gene and gene-by-genome strategies, we identified the S5 region and four homologous regions within the japonica genome. Additional phylogenomic analyses of the comparable duplicated blocks indicate that four successive duplication events gave rise to these five regions, allowing us to propose a model for this local chromosomal evolution. According to this model, gene loss may play a major role in post-duplication genetic evolution at the segmental level. Moreover, we found molecular evidence that one of the sister duplicated blocks experienced more gene loss and a more rapid evolution subsequent to two recent duplication events. Given that these two recent duplication events were likely involved in polyploidy, this asymmetric evolution (gene loss and gene divergence) may be one possible mechanism accounting for the diploidization at the segmental level. Supplementary material to this paper is available in electronic form at http://dx.doi.org/10.1007/s11103-005-4414-1     

MSOAR 2.0: Incorporating tandem duplications into ortholog assignment based on genome rearrangement

Background  

Ortholog assignment is a critical and fundamental problem in comparative genomics, since orthologs are considered to be functional counterparts in different species and can be used to infer molecular functions of one species from those of other species. MSOAR is a recently developed high-throughput system for assigning one-to-one orthologs between closely related species on a genome scale. It attempts to reconstruct the evolutionary history of input genomes in terms of genome rearrangement and gene duplication events. It assumes that a gene duplication event inserts a duplicated gene into the genome of interest at a random location (i.e., the random duplication model). However, in practice, biologists believe that genes are often duplicated by tandem duplications, where a duplicated gene is located next to the original copy (i.e., the tandem duplication model).     

Gene duplication and the evolution of phenotypic diversity in insect societies

Gene duplication is an important evolutionary process thought to facilitate the evolution of phenotypic diversity. We investigated if gene duplication was associated with the evolution of phenotypic differences in a highly social insect, the honeybee Apis mellifera. We hypothesized that the genetic redundancy provided by gene duplication could promote the evolution of social and sexual phenotypes associated with advanced societies. We found a positive correlation between sociality and rate of gene duplications across the Apoidea, indicating that gene duplication may be associated with sociality. We also discovered that genes showing biased expression between A. mellifera alternative phenotypes tended to be found more frequently than expected among duplicated genes than singletons. Moreover, duplicated genes had higher levels of caste‐, sex‐, behavior‐, and tissue‐biased expression compared to singletons, as expected if gene duplication facilitated phenotypic differentiation. We also found that duplicated genes were maintained in the A. mellifera genome through the processes of conservation, neofunctionalization, and specialization, but not subfunctionalization. Overall, we conclude that gene duplication may have facilitated the evolution of social and sexual phenotypes, as well as tissue differentiation. Thus this study further supports the idea that gene duplication allows species to evolve an increased range of phenotypic diversity.     

Evolutionary Dynamics of Recently Duplicated Genes: Selective Constraints on Diverging Paralogs in the <Emphasis Type="Italic">Drosophila pseudoobscura</Emphasis> Genome

Duplicated genes produce genetic variation that can influence the evolution of genomes and phenotypes. In most cases, for a duplicated gene to contribute to evolutionary novelty it must survive the early stages of divergence from its paralog without becoming a pseudogene. I examined the evolutionary dynamics of recently duplicated genes in the Drosophila pseudoobscura genome to understand the factors affecting these early stages of evolution. Paralogs located in closer proximity have higher sequence identity. This suggests that gene conversion occurs more often between duplications in close proximity or that there is more genetic independence between distant paralogs. Partially duplicated genes have a higher likelihood of pseudogenization than completely duplicated genes, but no single factor significantly contributes to the selective constraints on a completely duplicated gene. However, DNA-based duplications and duplications within chromosome arms tend to produce longer duplication tracts than retroposed and inter-arm duplications, and longer duplication tracts are more likely to contain a completely duplicated gene. Therefore, the relative position of paralogs and the mechanism of duplication indirectly affect whether a duplicated gene is retained or pseudogenized. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Phylogenetic Timing of the Fish-Specific Genome Duplication Correlates with the Diversification of Teleost Fish

For many genes, ray-finned fish (Actinopterygii) have two paralogous copies, where only one ortholog is present in tetrapods. The discovery of an additional, almost-complete set of Hox clusters in teleosts (zebrafish, pufferfish, medaka, and cichlid) but not in basal actinopterygian lineages (Polypterus) led to the formulation of the fish-specific genome duplication hypothesis. The phylogenetic timing of this genome duplication during the evolution of ray-finned fish is unknown, since only a few species of basal fish lineages have been investigated so far. In this study, three nuclear genes (fzd8, sox11, tyrosinase) were sequenced from sturgeons (Acipenseriformes), gars (Semionotiformes), bony tongues (Osteoglossomorpha), and a tenpounder (Elopomorpha). For these three genes, two copies have been described previously teleosts (e.g., zebrafish, pufferfish), but only one orthologous copy is found in tetrapods. Individual gene trees for these three genes and a concatenated dataset support the hypothesis that the fish-specific genome duplication event took place after the split of the Acipenseriformes and the Semionotiformes from the lineage leading to teleost fish but before the divergence of Osteoglossiformes. If these three genes were duplicated during the proposed fish-specific genome duplication event, then this event separates the species-poor early-branching lineages from the species-rich teleost lineage. The additional number of genes resulting from this event might have facilitated the evolutionary radiation and the phenotypic diversification of the teleost fish.[Reviewing Editor: Martin Kreitman]     

Gene Duplication and the Properties of Biological Networks

Patterns of network connection of members of multigene families were examined for two biological networks: a genetic network from the yeast Saccharomyces cerevisiae and a protein–protein interaction network from Caenorhabditis elegans. In both networks, genes belonging to gene families represented by a single member in the genome (“singletons”) were disproportionately represented among the nodes having large numbers of connections. Of 68 single-member yeast families with 25 or more network connections, 28 (44.4%) were located in duplicated genomic segments believed to have originated from an ancient polyploidization event; thus, each of these 28 loci was thus presumably duplicated along with the genomic segment to which it belongs, but one of the two duplicates has subsequently been deleted. Nodes connected to major “hubs” with a large number of connections, tended to be relatively sparsely interconnected among themselves. Furthermore, duplicated genes, even those arising from recent duplication, rarely shared many network connections, suggesting that network connections are remarkably labile over evolutionary time. These factors serve to explain well-known general properties of biological networks, including their scale-free and modular nature. [Reviewing Editor : Dr. Manyuan Long]     

Autosomal genes of autosomal/X-linked duplicated gene pairs and germ-line proliferation in Caenorhabditis elegans

We report molecular genetic studies of three genes involved in early germ-line proliferation in Caenorhabditis elegans that lend unexpected insight into a germ-line/soma functional separation of autosomal/X-linked duplicated gene pairs. In a genetic screen for germ-line proliferation-defective mutants, we identified mutations in rpl-11.1 (L11 protein of the large ribosomal subunit), pab-1 [a poly(A)-binding protein], and glp-3/eft-3 (an elongation factor 1-α homolog). All three are members of autosome/X gene pairs. Consistent with a germ-line-restricted function of rpl-11.1 and pab-1, mutations in these genes extend life span and cause gigantism. We further examined the RNAi phenotypes of the three sets of rpl genes (rpl-11, rpl-24, and rpl-25) and found that for the two rpl genes with autosomal/X-linked pairs (rpl-11 and rpl-25), zygotic germ-line function is carried by the autosomal copy. Available RNAi results for highly conserved autosomal/X-linked gene pairs suggest that other duplicated genes may follow a similar trend. The three rpl and the pab-1/2 duplications predate the divergence between C. elegans and C. briggsae, while the eft-3/4 duplication appears to have occurred in the lineage to C. elegans after it diverged from C. briggsae. The duplicated C. briggsae orthologs of the three C. elegans autosomal/X-linked gene pairs also display functional differences between paralogs. We present hypotheses for evolutionary mechanisms that may underlie germ-line/soma subfunctionalization of duplicated genes, taking into account the role of X chromosome silencing in the germ line and analogous mammalian phenomena.     

The evolution of teleost pigmentation and the fish‐specific genome duplication

Teleost fishes have evolved a unique complexity and diversity of pigmentation and colour patterning that is unmatched among vertebrates. Teleost colouration is mediated by five different major types of neural‐crest derived pigment cells, while tetrapods have a smaller repertoire of such chromatophores. The genetic basis of teleost colouration has been mainly uncovered by the cloning of pigmentation genes in mutants of zebrafish Danio rerio and medaka Oryzias latipes. Many of these teleost pigmentation genes were already known as key players in mammalian pigmentation, suggesting partial conservation of the corresponding developmental programme among vertebrates. Strikingly, teleost fishes have additional copies of many pigmentation genes compared with tetrapods, mainly as a result of a whole‐genome duplication that occurred 320–350 million years ago at the base of the teleost lineage, the so‐called fish‐specific genome duplication. Furthermore, teleosts have retained several duplicated pigmentation genes from earlier rounds of genome duplication in the vertebrate lineage, which were lost in other vertebrate groups. It was hypothesized that divergent evolution of such duplicated genes may have played an important role in pigmentation diversity and complexity in teleost fishes, which therefore not only provide important insights into the evolution of the vertebrate pigmentary system but also allow us to study the significance of genome duplications for vertebrate biodiversity.     

Investigating ancient duplication events in the Arabidopsis genome

The complete genomic analysis of Arabidopsis thaliana has shown that a major fraction of the genome consists of paralogous genes that probably originated through one or more ancient large-scale gene or genome duplication events. However, the number and timing of these duplications still remains unclear, and several different hypotheses have been put forward recently. Here, we reanalyzed duplicated blocks found in the Arabidopsis genome described previously and determined their date of divergence based on silent substitution estimations between the paralogous genes and, where possible, by phylogenetic reconstruction. We show that methods based on averaging protein distances of heterogeneous classes of duplicated genes lead to unreliable conclusions and that a large fraction of blocks duplicated much more recently than assumed previously. We found clear evidence for one large-scale gene or even complete genome duplication event somewhere between 70 to 90 million years ago. Traces pointing to a much older (probably more than 200 million years) large-scale gene duplication event could be detected. However, for now it is impossible to conclude whether these old duplicates are the result of one or more large-scale gene duplication events. abbreviations dA, fraction of amino acid substitutions; Kn, number of nonsynonymous substitutions per nonsynonymous site; Ks, number of synonymous substitutions per synonymous site; MYA, million years ago     

The Evolution of Histidine Biosynthesis in Archaea: Insights into the <Emphasis Type="Italic">his</Emphasis> Genes Structure and Organization in LUCA

The available sequences of genes encoding the enzymes associated with histidine biosynthesis suggest that this is an ancient metabolic pathway that was assembled prior to the diversification of Bacteria, Archaea, and Eucarya. Paralogous duplication, gene elongation, and fusion events of several different his genes have played a major role in shaping this biosynthetic route. We have analyzed the structure and organization of histidine biosynthetic genes from 55 complete archaeal genomes and combined it with phylogenetic inference in order to investigate the mechanisms responsible for the assembly of the his pathway and the origin of his operons. We show that a wide variety of different organizations of his genes exists in Archaea and that some his genes or entire his (sub-)operons have been likely transferred horizontally between Archaea and Bacteria. However, we show that, in most Archaea, his genes are monofunctional (except for hisD) and scattered throughout the genome, suggesting that his operons might have been assembled multiple times during evolution and that in some cases they are the result of recent evolutionary events. An evolutionary model for the structure and organization of his genes in LUCA is proposed.     

Epigenetic silencing may aid evolution by gene duplication

Gene duplication is commonly regarded as the main evolutionary path toward the gain of a new function. However, even with gene duplication, there is a loss-versus-gain dilemma: most newly born duplicates degrade to pseudogenes, since degenerative mutations are much more frequent than advantageous ones. Thus, something additional seems to be needed to shift the loss versus gain equilibrium toward functional divergence. We suggest that epigenetic silencing of duplicates might play this role in evolution. This study began when we noticed in a previous publication (Lynch M, Conery JS [2000] Science 291:1151–1155) that the frequency of functional young gene duplicates is higher in organisms that have cytosine methylation (H. sapiens, M. musculus, and A. thaliana) than in organisms that do not have methylated genomes (S. cerevisiae, D. melanogaster, and C. elegans). We find that genome data analysis confirms the likelihood of much more efficient functional divergence of gene duplicates in mammals and plants than in yeast, nematode, and fly. We have also extended the classic model of gene duplication, in which newly duplicated genes have exactly the same expression pattern, to the case when they are epigenetically silenced in a tissue- and/or developmental stage-complementary manner. This exposes each of the duplicates to negative selection, thus protecting from pseudogenization. Our analysis indicates that this kind of silencing (i) enhances evolution of duplicated genes to new functions, particularly in small populations, (ii) is quite consistent with the subfunctionalization model when degenerative but complementary mutations affect different subfunctions of the gene, and (iii) furthermore, may actually cooperate with the DDC (duplication– degeneration–complementation) process. Dedicated to the memory of Susumu Ohno     

Genome Duplication and Gene Loss Affect the Evolution of Heat Shock Transcription Factor Genes in Legumes

Whole-genome duplication events (polyploidy events) and gene loss events have played important roles in the evolution of legumes. Here we show that the vast majority of Hsf gene duplications resulted from whole genome duplication events rather than tandem duplication, and significant differences in gene retention exist between species. By searching for intraspecies gene colinearity (microsynteny) and dating the age distributions of duplicated genes, we found that genome duplications accounted for 42 of 46 Hsf-containing segments in Glycine max, while paired segments were rarely identified in Lotus japonicas, Medicago truncatula and Cajanus cajan. However, by comparing interspecies microsynteny, we determined that the great majority of Hsf-containing segments in Lotus japonicas, Medicago truncatula and Cajanus cajan show extensive conservation with the duplicated regions of Glycine max. These segments formed 17 groups of orthologous segments. These results suggest that these regions shared ancient genome duplication with Hsf genes in Glycine max, but more than half of the copies of these genes were lost. On the other hand, the Glycine max Hsf gene family retained approximately 75% and 84% of duplicated genes produced from the ancient genome duplication and recent Glycine-specific genome duplication, respectively. Continuous purifying selection has played a key role in the maintenance of Hsf genes in Glycine max. Expression analysis of the Hsf genes in Lotus japonicus revealed their putative involvement in multiple tissue-/developmental stages and responses to various abiotic stimuli. This study traces the evolution of Hsf genes in legume species and demonstrates that the rates of gene gain and loss are far from equilibrium in different species.     

Pervasive and persistent redundancy among duplicated genes in yeast

The loss of functional redundancy is the key process in the evolution of duplicated genes. Here we systematically assess the extent of functional redundancy among a large set of duplicated genes in Saccharomyces cerevisiae. We quantify growth rate in rich medium for a large number of S. cerevisiae strains that carry single and double deletions of duplicated and singleton genes. We demonstrate that duplicated genes can maintain substantial redundancy for extensive periods of time following duplication (~100 million years). We find high levels of redundancy among genes duplicated both via the whole genome duplication and via smaller scale duplications. Further, we see no evidence that two duplicated genes together contribute to fitness in rich medium substantially beyond that of their ancestral progenitor gene. We argue that duplicate genes do not often evolve to behave like singleton genes even after very long periods of time.     

The Ghost of Selection Past: Rates of Evolution and Functional Divergence of Anciently Duplicated Genes

The duplication of genes and even complete genomes may be a prerequisite for major evolutionary transitions and the origin of evolutionary novelties. However, the evolutionary mechanisms of gene evolution and the origin of novel gene functions after gene duplication have been a subject of many debates. Recently, we compiled 26 groups of orthologous genes, which included one gene from human, mouse, and chicken, one or two genes from the tetraploid Xenopus and two genes from zebrafish. Comparative analysis and mapping data showed that these pairs of zebrafish genes were probably produced during a fish-specific genome duplication that occurred between 300 and 450 Mya, before the teleost radiation (Taylor et al. 2001). As discussed here, many of these retained duplicated genes code for DNA binding proteins. Different models have been developed to explain the retention of duplicated genes and in particular the subfunctionalization model of Force et al. (1999) could explain why so many developmental control genes have been retained. Other models are harder to reconcile with this particular set of duplicated genes. Most genes seem to have been subjected to strong purifying selection, keeping properties such as charge and polarity the same in both duplicates, although some evidence was found for positive Darwinian selection, in particular for Hox genes. However, since only the cumulative pattern of nucleotide substitutions can be studied, clear indications of positive Darwinian selection or neutrality may be hard to find for such anciently duplicated genes. Nevertheless, an increase in evolutionary rate in about half of the duplicated genes seems to suggest that either positive Darwinian selection has occurred or that functional constraints have been relaxed at one point in time during functional divergence. Received: 4 January 2001 / Accepted: 29 March 2001