Gene duplications, robustness and evolutionary innovations

Wagner, Andreas

doi:10.1002/bies.20728

Cited by 118 publications

(94 citation statements)

References 89 publications

(85 reference statements)

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“…Given that the same CYC binding sites are found in the zygomorphic lineages of both Asterids and Rosids, with no such site detected in their respective ancestral actinomorphic lineages, and the establishment of floral zygomorphy frequently involves the dorsal-specific activities of a pair of CYC2 genes, we suggest that the double positive autoregulatory feedback loops revealed in Lamiales might have become established independently in the Asterids and Rosids, in accordance with the independent origins of several major zygomorphic lineages in the core eudicots (Donoghue et al, 1998;Cubas, 2004;Jabbour et al, 2009). A growing amount of evidence shows that many polyploids experience extensive and rapid genomic alterations even within the first few generations, and changes in the architecture of gene regulatory networks and in particular functional changes within cis-regulatory elements are frequently associated with evolutionary innovations (Adams and Wendel, 2005;Moore and Purugganan, 2005;Soltis, 2005;Prud'homme et al, 2006Prud'homme et al, , 2007Wagner, 2008). Therefore, this neofunctionalization (i.e., the double positive autoregulatory feedback loops underlain by a key regulatory change in CYC2 clade genes) might have been subsequent to the second WGD event in angiosperms that provided novel opportunities for the evolutionary success of the core eudicots.…”

Section: Evolutionary Significance Of the Autoregulatory Loops In Cycsupporting

confidence: 62%

Evolution of Double Positive Autoregulatory Feedback Loops in CYCLOIDEA2 Clade Genes Is Associated with the Origin of Floral Zygomorphy

et al. 2012

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Members of the CYCLOIDEA2 (CYC2) clade of the TEOSINTE BRANCHED1, CYCLOIDEA, and PCF transcription factor genes are widely involved in controlling floral zygomorphy, a key innovation in angiosperm evolution, depending on their persistently asymmetric expression in the corresponding floral domains. However, it is unclear how this asymmetric expression is maintained throughout floral development. Selecting Primulina heterotricha as a model, we examined the expression and function of two CYC2 genes, CYC1C and CYC1D. We analyzed the role of their promoters in protein-DNA interactions and transcription activation using electrophoresis mobility shift assays, chromatin immunoprecipitation, and transient gene expression assays. We find that CYC1C and CYC1D positively autoregulate themselves and cross-regulate each other. Our results reveal a double positive autoregulatory feedback loop, evolved for a pair of CYC2 genes to maintain their expression in developing flowers. Further comparative genome analyses, together with the available expression and function data of CYC2 genes in the core eudicots, suggest that this mechanism might have led to the independent origins of floral zygomorphy, which are associated with plant-insect coevolution and the adaptive radiation of angiosperms.

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Section: Evolutionary Significance Of the Autoregulatory Loops In Cycsupporting

confidence: 62%

Evolution of Double Positive Autoregulatory Feedback Loops in CYCLOIDEA2 Clade Genes Is Associated with the Origin of Floral Zygomorphy

et al. 2012

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“…Support to the generation of neutral genotypic diversity after gene duplication comes from the classic belief that after duplication gene copies suffer relaxed selective constraints that allow one or both copies tolerating many-fold more mutations than otherwise, a fact with extensive experimental and theoretical support [2,86,87]. This phenomenon is more obvious when analyzing genomes populated with duplicates originated by whole-genome duplication, in which younger duplicates still preserve signatures of their larger tolerance to mutations than older duplicates [79,84,88,89].…”

Section: Evolution By Gene Duplication: Robustness To Mutational Insultsmentioning

confidence: 99%

Survival and innovation: The role of mutational robustness in evolution

Fares

2015

Biochimie

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a b s t r a c tBiological systems are resistant to perturbations caused by the environment and by the intrinsic noise of the system. Robustness to mutations is a particular aspect of robustness in which the phenotype is resistant to genotypic variation. Mutational robustness has been linked to the ability of the system to generate heritable genetic variation (a property known as evolvability). It is known that greater robustness leads to increased evolvability. Therefore, mechanisms that increase mutational robustness fuel evolvability. Two such mechanisms, molecular chaperones and gene duplication, have been credited with enormous importance in generating functional diversity through the increase of system's robustness to mutational insults. However, the way in which such mechanisms regulate robustness remains largely uncharacterized. In this review, I provide evidence in support of the role of molecular chaperones and gene duplication in innovation. Specifically, I present evidence that these mechanisms regulate robustness allowing unstable systems to survive long periods of time, and thus they provide opportunity for other mutations to compensate the destabilizing effects of functionally innovative mutations. The findings reported in this study set new questions with regards to the synergy between robustness mechanisms and how this synergy can alter the adaptive landscape of proteins. The ideas proposed in this article set the ground for future research in the understanding of the role of robustness in evolution.

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“…For example, shortly after a duplication, the ratio of amino acid replacement to silent nucleotide changes is greatly elevated in duplicate genes 40,41 . Gene and genome duplications have been associated with some of the most striking evolutionary innovations in life's history, such as the diversification of the vertebrate body plan, the radiation of flowering plants, and the evolution of highly integrated organs, such as the four-chambered mammalian heart [42][43][44][45] . This association, although circumstantial, is fully consistent with the notion that the increased potential for neutral change caused by gene duplication facilitates evolutionary adaptation 46 .…”

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confidence: 99%

Neutralism and selectionism: a network-based reconciliation

2008

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Neutralism and selectionism: a network-based reconciliation . Neutralism and selectionism: a network-based reconciliation. Nature Reviews. Genetics, 9(12):965-974. Postprint available at: http://www.zora.uzh.ch Posted at the Zurich Open Repository and Archive, University of Zurich. http://www.zora.uzh.ch Originally published at: Nature Reviews. Genetics 2008, 9(12):965-974. Neutralism and selectionism: a network-based reconciliation Abstract Neutralism and selectionism are extremes of an explanatory spectrum for understanding patterns of molecular evolution and the emergence of evolutionary innovation. Although recent genome-scale data from protein-coding genes argue against neutralism, molecular engineering and protein evolution data argue that neutral mutations and mutational robustness are important for evolutionary innovation. Here I propose a reconciliation in which neutral mutations prepare the ground for later evolutionary adaptation. Key to this perspective is an explicit understanding of molecular phenotypes that has only become accessible in recent years. Summary: Neutralism and selectionism are extremes of an explanatory spectrum for patterns of molecular evolution. They also have broad implications for our understanding of evolutionary innovation. Neutralism maintains that most mutations with appreciable frequency in a population convey no benefit to their carrier. Selectionism maintains that a large fraction of such mutations do provide a benefit. While recent genome-scale data from protein-coding genes argue against neutralism, molecular engineering and protein evolution data argue that neutral mutations and mutational robustness are important for evolutionary innovation. In the reconciliation proposed here, neutral mutations prepare the ground for later evolutionary adaptation. Key to this perspective is an explicit understanding of molecular phenotypes that has only become accessible in recent years. 1 Neutralism and selectionism: a network-based reconciliation 2 Neutralism and SelectionismThe tension between neutralism and selectionism is at least as old as the field of molecular evolution 1 . Most of the historical neutralism-selectionism debate centered on explanations for genetic variation in populations. In this context, neutralists and selectionists agreed that deleterious mutations occur frequently in evolving molecules, but they profoundly disagreed on the relative importance of effectively neutral and beneficial mutations. To neutralism, beneficial mutations are rare. In the words of Motoo Kimura, one of neutralism's principal proponents "…random fixation of selectively neutral or slightly deleterious mutations occur far more frequently in evolution than positive Darwinian selection of definitely advantageous mutants" 2 . In contrast, according to selectionism, beneficial mutations are abundant. In consequence, most mutations that go to fixation in a population would be beneficial, or at least linked to abundantly occurring beneficial mutations. Selectionists such as Ernst Mayr dismis...

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Gene duplications, robustness and evolutionary innovations

Cited by 118 publications

References 89 publications

Evolution of Double Positive Autoregulatory Feedback Loops in CYCLOIDEA2 Clade Genes Is Associated with the Origin of Floral Zygomorphy

Evolution of Double Positive Autoregulatory Feedback Loops in CYCLOIDEA2 Clade Genes Is Associated with the Origin of Floral Zygomorphy

Survival and innovation: The role of mutational robustness in evolution

Neutralism and selectionism: a network-based reconciliation

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