Preferential retention of the slowly evolving gene in pairs of duplicates in angiosperm genomes

Gene duplication provides raw material for functional innovation, but gene duplicability varies considerably. Previous studies have found widespread asymmetrical sequence evolution between paralogs. However, it remains unknown whether the rate of evolution among paralogs affects their propensity of being retained after another round of whole-genome duplication (WGD). In this study, we investigated gene groups that have experienced two successive WGDs to determine which of two older duplicates with different evolutionary rates was more likely to retain both younger duplicates. To uncouple the measurement of evolutionary rates from any assignment of duplicate or singleton status, we measured the evolutionary rates of singleton genes in out-lineages but classified these singleton genes according to whether they are retained or not in a crown group of species. We found that genes that retained younger duplicates in the crown group of genomes were more constrained prior to the younger duplication event than those that failed to leave duplicates. In addition, we also found that the retained clades have more genes in out-lineages. Subsequent analyses showed that genes in the retained clades were expressed more broadly and highly than genes in the singleton clades. We concluded that the set of repeatedly retained genes after two WGDs is biased toward slowly evolving genes in angiosperms, suggesting that the potential of genes for both functional conservation and divergence likely affects their propensity of being retained after WGD in angiosperms.     

A Population-Genetic Lens into the Process of Gene Loss Following Whole-Genome Duplication

Whole-genome duplications (WGDs) have occurred in many eukaryotic lineages. However, the underlying evolutionary forces and molecular mechanisms responsible for the long-term retention of gene duplicates created by WGDs are not well understood. We employ a population-genomic approach to understand the selective forces acting on paralogs and investigate ongoing duplicate-gene loss in multiple species of Paramecium that share an ancient WGD. We show that mutations that abolish protein function are more likely to be segregating in retained WGD paralogs than in single-copy genes, most likely because of ongoing nonfunctionalization post-WGD. This relaxation of purifying selection occurs in only one WGD paralog, accompanied by the gradual fixation of nonsynonymous mutations and reduction in levels of expression, and occurs over a long period of evolutionary time, “marking” one locus for future loss. Concordantly, the fitness effects of new nonsynonymous mutations and frameshift-causing indels are significantly more deleterious in the highly expressed copy compared with their paralogs with lower expression. Our results provide a novel mechanistic model of gene duplicate loss following WGDs, wherein selection acts on the sum of functional activity of both duplicate genes, allowing the two to wander in expression and functional space, until one duplicate locus eventually degenerates enough in functional efficiency or expression that its contribution to total activity is too insignificant to be retained by purifying selection. Retention of duplicates by such mechanisms predicts long times to duplicate-gene loss, which should not be falsely attributed to retention due to gain/change in function.     

Insights into Three Whole-Genome Duplications Gleaned from the Paramecium caudatum Genome Sequence

Paramecium has long been a model eukaryote. The sequence of the Paramecium tetraurelia genome reveals a history of three successive whole-genome duplications (WGDs), and the sequences of P. biaurelia and P. sexaurelia suggest that these WGDs are shared by all members of the aurelia species complex. Here, we present the genome sequence of P. caudatum, a species closely related to the P. aurelia species group. P. caudatum shares only the most ancient of the three WGDs with the aurelia complex. We found that P. caudatum maintains twice as many paralogs from this early event as the P. aurelia species, suggesting that post-WGD gene retention is influenced by subsequent WGDs and supporting the importance of selection for dosage in gene retention. The availability of P. caudatum as an outgroup allows an expanded analysis of the aurelia intermediate and recent WGD events. Both the Guanine+Cytosine (GC) content and the expression level of preduplication genes are significant predictors of duplicate retention. We find widespread asymmetrical evolution among aurelia paralogs, which is likely caused by gradual pseudogenization rather than by neofunctionalization. Finally, cases of divergent resolution of intermediate WGD duplicates between aurelia species implicate this process acts as an ongoing reinforcement mechanism of reproductive isolation long after a WGD event.     

水稻和其他禾本科植物基因组多倍体起源的证据

基因加倍(Gene duplication)被认为是进化的加速器。古老的基因组加倍事件已经在多个物种中被确定,包括酵母、脊椎动物以及拟南芥等。本研究发现水稻基因组同样存在全基因组加倍事件,大概发生在禾谷类作物分化之前,距今约7000万年。在水稻基因组中,共找到117个加倍区段(Duplicated block),分布在水稻的全部12条染色体,覆盖约60％的水稻基因组。在加倍区段,大约有20％的基因保留了加倍后的姊妹基因对(Duplicated pairs)。与此形成鲜明对照的是加倍区段的转录因子保留了60％的姊妹基因。禾本科植物全基因组加倍事件的确定对研究禾本科植物基因组的进化具有重要影响,暗示了多倍体化及随后的基因丢失、染色体重排等在禾谷类物种分化中扮演了重要角色。     

A Synergism between Adaptive Effects and Evolvability Drives Whole Genome Duplication to Fixation

Whole genome duplication has shaped eukaryotic evolutionary history and has been associated with drastic environmental change and species radiation. While the most common fate of WGD duplicates is a return to single copy, retained duplicates have been found enriched for highly interacting genes. This pattern has been explained by a neutral process of subfunctionalization and more recently, dosage balance selection. However, much about the relationship between environmental change, WGD and adaptation remains unknown. Here, we study the duplicate retention pattern postWGD, by letting virtual cells adapt to environmental changes. The virtual cells have structured genomes that encode a regulatory network and simple metabolism. Populations are under selection for homeostasis and evolve by point mutations, small indels and WGD. After populations had initially adapted fully to fluctuating resource conditions re-adaptation to a broad range of novel environments was studied by tracking mutations in the line of descent. WGD was established in a minority (≈30%) of lineages, yet, these were significantly more successful at re-adaptation. Unexpectedly, WGD lineages conserved more seemingly redundant genes, yet had higher per gene mutation rates. While WGD duplicates of all functional classes were significantly over-retained compared to a model of neutral losses, duplicate retention was clearly biased towards highly connected TFs. Importantly, no subfunctionalization occurred in conserved pairs, strongly suggesting that dosage balance shaped retention. Meanwhile, singles diverged significantly. WGD, therefore, is a powerful mechanism to cope with environmental change, allowing conservation of a core machinery, while adapting the peripheral network to accommodate change.     

GPCR genes are preferentially retained after whole genome duplication

One of the most interesting questions in biology is whether certain pathways have been favored during evolution, and if so, what properties could cause such a preference. Due to the lack of experimental evidence, whether select gene families have been preferentially retained over time after duplication in metazoan organisms remains unclear. Here, by syntenic mapping of nonchemosensory G protein-coupled receptor genes (nGPCRs which represent half the receptome for transmembrane signaling) in the vertebrate genomes, we found that, as opposed to the 8-15% retention rate for whole genome duplication (WGD)-derived gene duplicates in the entire genome of pufferfish, greater than 27.8% of WGD-derived nGPCRs which interact with a nonpeptide ligand were retained after WGD in pufferfish Tetraodon nigroviridis. In addition, we show that concurrent duplication of cognate ligand genes by WGD could impose selection of nGPCRs that interact with a polypeptide ligand. Against less than 2.25% probability for parallel retention of a pair of WGD-derived ligands and a pair of cognate receptor duplicates, we found a more than 8.9% retention of WGD-derived ligand-nGPCR pairs--threefold greater than one would surmise. These results demonstrate that gene retention is not uniform after WGD in vertebrates, and suggest a Darwinian selection of GPCR-mediated intercellular communication in metazoan organisms.     

Importance of lineage-specific expansion of plant tandem duplicates in the adaptive response to environmental stimuli

Plants have substantially higher gene duplication rates compared with most other eukaryotes. These plant gene duplicates are mostly derived from whole genome and/or tandem duplications. Earlier studies have shown that a large number of duplicate genes are retained over a long evolutionary time, and there is a clear functional bias in retention. However, the influence of duplication mechanism, particularly tandem duplication, on duplicate retention has not been thoroughly investigated. We have defined orthologous groups (OGs) between Arabidopsis (Arabidopsis thaliana) and three other land plants to examine the functional bias of retained duplicate genes during vascular plant evolution. Based on analysis of Gene Ontology categories, it is clear that genes in OGs that expanded via tandem duplication tend to be involved in responses to environmental stimuli, while those that expanded via nontandem mechanisms tend to have intracellular regulatory roles. Using Arabidopsis stress expression data, we further demonstrated that tandem duplicates in expanded OGs are significantly enriched in genes that are up-regulated by biotic stress conditions. In addition, tandem duplication of genes in an OG tends to be highly asymmetric. That is, expansion of OGs with tandem genes in one organismal lineage tends to be coupled with losses in the other. This is consistent with the notion that these tandem genes have experienced lineage-specific selection. In contrast, OGs with genes duplicated via nontandem mechanisms tend to experience convergent expansion, in which similar numbers of genes are gained in parallel. Our study demonstrates that the expansion of gene families and the retention of duplicates in plants exhibit substantial functional biases that are strongly influenced by the mechanism of duplication. In particular, genes involved in stress responses have an elevated probability of retention in a single-lineage fashion following tandem duplication, suggesting that these tandem duplicates are likely important for adaptive evolution to rapidly changing environments.     

Degree of Functional Divergence in Duplicates Is Associated with Distinct Roles in Plant Evolution

Gene duplication is a major mechanism to create new genes. After gene duplication, some duplicated genes undergo functionalization, whereas others largely maintain redundant functions. Duplicated genes comprise various degrees of functional diversification in plants. However, the evolutionary fate of high and low diversified duplicates is unclear at genomic scale. To infer high and low diversified duplicates in Arabidopsis thaliana genome, we generated a prediction method for predicting whether a pair of duplicate genes was subjected to high or low diversification based on the phenotypes of knock-out mutants. Among 4,017 pairs of recently duplicated A. thaliana genes, 1,052 and 600 are high and low diversified duplicate pairs, respectively. The predictions were validated based on the phenotypes of generated knock-down transgenic plants. We determined that the high diversified duplicates resulting from tandem duplications tend to have lineage-specific functions, whereas the low diversified duplicates produced by whole-genome duplications are related to essential signaling pathways. To assess the evolutionary impact of high and low diversified duplicates in closely related species, we compared the retention rates and selection pressures on the orthologs of A. thaliana duplicates in two closely related species. Interestingly, high diversified duplicates resulting from tandem duplications tend to be retained in multiple lineages under positive selection. Low diversified duplicates by whole-genome duplications tend to be retained in multiple lineages under purifying selection. Taken together, the functional diversities determined by different duplication mechanisms had distinct effects on plant evolution.     

Screening of duplicated loci reveals hidden divergence patterns in a complex salmonid genome

A whole‐genome duplication (WGD) doubles the entire genomic content of a species and is thought to have catalysed adaptive radiation in some polyploid‐origin lineages. However, little is known about general consequences of a WGD because gene duplicates (i.e., paralogs) are commonly filtered in genomic studies; such filtering may remove substantial portions of the genome in data sets from polyploid‐origin species. We demonstrate a new method that enables genome‐wide scans for signatures of selection at both nonduplicated and duplicated loci by taking locus‐specific copy number into account. We apply this method to RAD sequence data from different ecotypes of a polyploid‐origin salmonid (Oncorhynchus nerka) and reveal signatures of divergent selection that would have been missed if duplicated loci were filtered. We also find conserved signatures of elevated divergence at pairs of homeologous chromosomes with residual tetrasomic inheritance, suggesting that joint evolution of some nondiverged gene duplicates may affect the adaptive potential of these genes. These findings illustrate that including duplicated loci in genomic analyses enables novel insights into the evolutionary consequences of WGDs and local segmental gene duplications.     

Allelic divergence precedes and promotes gene duplication

One of the striking observations from recent whole-genome comparisons is that changes in the number of specialized genes in existing gene families, as opposed to novel taxon-specific gene families, are responsible for the majority of the difference in genome composition between major taxa. Previous models of duplicate gene evolution focused primarily on the role that neutral processes can play in evolutionary divergence after the duplicates are already fixed in the population. By instead including the entire cycle of duplication and divergence, we show that specialized functions are most likely to evolve through strong selection acting on segregating alleles at a single locus, even before the duplicate arises. We show that the fitness relationships that allow divergent alleles to evolve at a single locus largely overlap with the conditions that allow divergence of previously duplicated genes. Thus, a solution to the paradox of the origin of organismal complexity via the expansion of gene families exists in the form of the deterministic spread of novel duplicates via natural selection.     

Two-phase resolution of polyploidy in the Arabidopsis metabolic network gives rise to relative and absolute dosage constraints

The abundance of detected ancient polyploids in extant genomes raises questions regarding evolution after whole-genome duplication (WGD). For instance, what rules govern the preservation or loss of the duplicated genes created by WGD? We explore this question by contrasting two possible preservation forces: selection on relative and absolute gene dosages. Constraints on the relative dosages of central network genes represent an important force for maintaining duplicates (the dosage balance hypothesis). However, preservation may also result from selection on the absolute abundance of certain gene products. The metabolic network of the model plant Arabidopsis thaliana is a powerful system for comparing these hypotheses. We analyzed the surviving WGD-produced duplicate genes in this network, finding evidence that the surviving duplicates from the most recent WGD (WGD-α) are clustered in the network, as predicted by the dosage balance hypothesis. A flux balance analysis suggests an association between the survival of duplicates from a more ancient WGD (WGD-β) and reactions with high metabolic flux. We argue for an interplay of relative and absolute dosage constraints, such that the relative constraints imposed by the recent WGD are still being resolved by evolution, while they have been essentially fully resolved for the ancient event.     

Evolutionary dynamics of duplicated genes in plants

Gene duplication, arising from region-specific duplication or genome-wide polyploidization, is a prominent feature in plant genome evolution. Understanding the mechanisms generating duplicate gene copies and the subsequent dynamics among gene duplicates is vital because these investigations shed light on regional and genome-wide aspects of evolutionary forces shaping intra- and interspecific genome contents, evolutionary relationships, and interactions. This review discusses recent gene duplication analyses in plants, focusing on the molecular and evolutionary dynamics occurring at three different timescales following duplication: (1). initial establishment and persistence of cytotypes, (2). interactions among duplicate gene copies, and (3). longer term differentiation between duplicated genes. These relative time points are presented in terms of their potential adaptive significance and impact on plant evolutionary genomics research.     

Drosophila duplicate genes evolve new functions on the fly

Gene duplication is thought to play a key role in phenotypic innovation. While several processes have been hypothesized to drive the retention and functional evolution of duplicate genes, their genomic contributions have never been determined. We recently developed the first genome-wide method to classify these processes by comparing distances between expression profiles of duplicate genes and their ancestral single-copy orthologs. Application of our approach to spatial gene expression profiles in two Drosophila species revealed that a majority of young duplicate genes possess new functions, and that new functions are acquired rapidly—often within a few million years. Surprisingly, new functions tend to arise in younger copies of duplicate gene pairs. Moreover, we found that young duplicates are often specifically expressed in testes, whereas old duplicates are broadly expressed across several tissues, providing strong support for the hypothetical “out-of-testes” origin of new genes. In this Extra View, I discuss our findings in the context of theoretical predictions about gene duplication, with a particular emphasis on the importance of natural selection in the evolution of novel phenotypes.     

An ancient frame-shifting event in the highly conserved KPNA gene family has undergone extensive compensation by natural selection in vertebrates

One of the prevailing arguments in evolutionary theory is that the duplicates of genes can acquire novel functionality. This is because only one of the paralogs need maintain the ancestral function, leaving room for natural experimentation due to a respite in purifying selection. Although many duplicates can subsequently become disabled by nullifying mutations, a few may also go on to diverge along a novel evolutionary trajectory. Here, evidence is provided that demonstrates how this scenario may not always be true. Rather, in the case of the highly conserved KPNA importin family, an initial relaxation in selection induced a frameshift that was later suppressed and heavily compensated for as part of a reparative and optimizing process. Despite a resulting divergence, there remains a distinct preservation of both sequence and functionality among the paralogs. This would indicate that duplicates can be retained by selection for reasons related to their redundant functionality. It also shows that, even when positive selection is inferred in duplicate genes, this may be of a compensatory nature rather than one representing any biochemical innovation. Generally, this development would perhaps be a more common outcome for gene duplication than is currently maintained.     

Functional divergence of Populus MYB158 and MYB189 gene pair created by whole genome duplication

Whole genome duplication (WGD) providesnew genetic material for genome evolution. After a WGD event, some duplicates are lost, while other duplicates still persist and evolve diverse functions. A particular challenge is to understand how this diversity arises. This study identified two WGD-derived duplicates, MYB158 and MYB189, from Populus tomentosa. Populus MYB158 and MYB189 had expression divergence. Populus tomentosa overexpressing MYB158 or MYB189 had similar phenotypes: creep growth, decreased width of xylem and secondary cell wall thickness. Compared to wild-type, neither myb158 mutant nor myb158 myb189 double mutant showed obvious phenotypic variation in P. tomentosa. Although MYB158 and MYB189 proteins could repress the same structural genes involved in lignin, cellulose, and xylan biosynthesis, the two proteins had their own specific regulatory targets. Populus MYB158 could act as the upstream regulator of secondary cell wall NAC master switch and directly represses the expression of the SND1-B2 gene. Taken together, Populus MYB158 and MYB189 have retained similar functions in negatively regulating secondary cell wall biosynthesis, but have evolved partially distinct functions in direct regulation of NAC master switch, with MYB158 playing a more crucial role. Our findings provide new insights into the evolutionary and functional divergence of WGD-derived duplicate genes.     

Comparison of the starch synthesis genes between maize and rice: copies, chromosome location and expression divergence

Gene duplication and divergence are important evolutionary processes. It has been suggested that a whole genome duplication (WGD) event occurred in the Gramineae, predating its divergence, and a second WGD occurred in maize during its evolution. In this study we compared the fate of the genes involved in the core pathway of starch biosynthesis following the ancient and second WGDs in maize and rice. In total, thirty starch synthesis genes were detected in the maize genome, which covered all the starch synthesis gene families encoded by 27 genes in rice. All of these genes, except ZmGBSSIIb and ZmBEIII, are anchored within large-scale synteny blocks of rice and maize chromosomes. Previous findings and our results indicate that two of the current copies of many starch synthesis genes (including AGPL, AGPS, GBSS, SSII, SSIII, and BEII) probably arose from the ancient WGD in the Gramineae and are still present in the maize and rice genome. Furthermore, two copies of at least six genes (AGPS1, SSIIb, SSIIIb, GBSSII, BEI, and ISA3) appear to have been retained in the maize genome after its second WGD, although complete coding regions were only detected among the duplicate sets of AGPS1, SSIIb, and SSIIIb. The expression patterns of the remaining duplicate sets of starch synthesis genes (AGPL1/2, AGPS1/2, SSIIa/b, SSIIIa/b, GBSSI/II, and BEIIa/b) differ in their expression and could be classified into two groups in maize. The first group is mainly expressed in the endosperm, whereas the second is expressed in other organs and the early endosperm development. The four duplicate sets of ZmGBSSII, ZmSSIIb, ZmSSIIIb and AGPS1, which arose from the second WGD diverged in gene structure and/or expression patterns in maize. These results indicated that some duplicated starch synthesis genes were remained, whereas others diverged in gene structure and/or expression pattern in maize. For most of the duplicated genes, one of the copies has disappeared in the maize genome after the WGD and the subsequent “diploidization”. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.