The duplication of the Hox gene clusters in teleost fishes*1

Prohaska, Sonja J.; Stadler, Peter F.

doi:10.1016/j.thbio.2004.03.004

Cited by 40 publications

(30 citation statements)

References 72 publications

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“…The identities of the PCR fragments were also investigated by reconstructing phylogenetic trees using different methods following the procedure outlined by Prohaska and Stadler (2004). Neighbor-joining (Saitou and Nei,'87), parsimony, and maximum likelihood analysis for each PG was performed using the Phylip package (Felsenstein,'89), using other teleost Hox homeobox fragments for comparison (D. rerio, Tetraodon nigroviridis, Takifugu rubripes, Oryzias latipes, and Fundulus heteroclitus).…”

Section: Methodsmentioning

confidence: 99%

“…In this regard, questions such as the characterization of evolutionary patterns after the FSGD including Hox gene retention/deletion, and evolution at the nucleotide level is of particular interest (Holland et al, '94;Malaga-Trillo and Meyer, 2001;Wagner et al, 2003;Prohaska and Stadler, 2004;Hoegg and Meyer, 2005;Crow et al, 2006;Kurosawa et al, 2006). Available DNA sequences from teleosts have shown a variety of gene retention and deletion patterns.…”

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confidence: 99%

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PCR survey of hox genes in the goldfish Carassius auratus auratus

Luo

Stadler

et al. 2006

J Exp Zool Pt B

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A tetraploidization event took place in the cyprinid lineage leading to goldfishes about 15 million years ago. A PCR survey for Hox genes in the goldfish Carassius auratus auratus (Actinopterygii: Cyprinidae) was performed to assess the consequences of this genome duplication. Not surprisingly, the genomic organization of the Hox gene clusters of goldfish is similar to that of the closely related zebrafish (Danio rerio). However, the goldfish exhibits a much larger number of recent pseudogenes, which are characterized by indels. These findings are consistent with the hypothesis that dosage effects cause selection pressure to rapidly silence crucial developmental regulators after a tetraploidization event.

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Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

PCR survey of hox genes in the goldfish Carassius auratus auratus

Luo

Stadler

et al. 2006

J Exp Zool Pt B

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“…After identifying many supernumerous Hox genes to the already known ones from tetrapods (Njolstad et al, 1988;Misof and Wagner, 1996;Aparicio et al, 1997), the 5 systematic evaluations of Hox genes revealed seven Hox clusters in zebrafish (Amores et al, 1998;Prince et al, 1998) as opposed to the four found in tetrapods. Although duplicated Hox genes have also been identified in other teleosts, it was initially not clear whether the increase in the number of Hox clusters is universal for teleosts (Prohaska and Stadler, 2004). Recently, duplicated Hox gene clusters were found in the two most basal extant groups of teleost fishes, the Elopomorpha (including eels and tarpons) (Guo et al, 2009;Henkel et al, 2012).…”

Section: Wgds Have Shaped Teleost Evolution a Wgd Took Place In The Cmentioning

confidence: 99%

Whole-genome duplication in teleost fishes and its evolutionary consequences

2014

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Whole-genome duplication (WGD) events have shaped the history of many evolutionary lineages. One such duplication has been implicated in the evolution of teleost fishes, by far the most species-rich vertebrate clade. After initial controversy, there is now solid evidence that such event took place in the common ancestor of all extant teleosts. It is termed teleost-specific (TS) WGD. After WGD, duplicate genes have different fates. The most likely outcome is non-functionalization of one duplicate gene due to the lack of selective constraint on preserving both. Mechanisms that act on preservation of duplicates are subfunctionalization (partitioning of ancestral gene functions on the duplicates), neofunctionalization (assigning a novel function to one of the duplicates) and dosage selection (preserving genes to maintain dosage balance between interconnected components). Since the frequency of these mechanisms is influenced by the genes' properties, there are over-retained classes of genes, such as highly expressed ones and genes involved in neural function. The consequences of the TS-WGD, especially its impact on the massive radiation of teleosts, have been matter of controversial debate. It is evident that gene duplications are crucial for generating complexity and that WGDs provide large amounts of raw material for evolutionary adaptation and innovation. However, it is less clear whether the TS-WGD is directly linked to the evolutionary success of teleosts and their radiation. Recent studies let us conclude that TS-WGD has been important in generating teleost complexity, but that more recent ecological adaptations only marginally related to TS-WGD might have even contributed more to diversification. It is likely, however, that TS-WGD provided teleosts with diversification potential that can become effective much later, such as during phases of environmental change. AbstractWhole genome duplication (WGD) events have shaped the history of many evolutionary lineages. One such duplication has been implicated in the evolution of teleost fishes, the by far most species-rich vertebrate clade. After initial controversy, evidence is now solid that such an event took place in the common ancestor of all extant teleosts, the so-called teleostspecific (TS) WGD. After WGD, duplicate genes have different fates. The most likely outcome is non-functionalization of one duplicate gene due to the lack of selective constraint on preserving both copies of the gene. Mechanisms that act on preservation of duplicates are subfunctionalization (partitioning of ancestral gene functions on the duplicates), neofunctionalization (assigning a novel function to one of the duplicates) and dosageselection (preserving genes to maintain dosage-balance between interconnected components).Since the frequency of these mechanisms is influenced by the gene's properties, there are over-retained classes of genes, such as highly expressed ones and genes involved in neural function. The consequences of the TS-WGD, especially its impact on the massi...

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“…Some have argued for a direct causal linkage such that genome duplication drives a geologically instantaneous burst of evolution (Sidow 1996;Wagner et al 2003), while others have argued for a more permissive role wherein genome duplication is a necessary prerequisite of organismal evolution, but the effect on organismal evolution unfolds gradually over a protracted period of time (Prohaska and Stadler 2004). The principal evidence marshaled in support of the evolutionary burst hypothesis is the observation that living vertebrates and gnathostomes are distinguished from living invertebrate chordates and jawless vertebrates, respectively, by very large inventories of anatomical and developmental characters-surely only genome duplication can explain the emergence of so many characters in concert?…”

Section: Genetic Drivers Of Vertebrate and Gnathostome Innovationmentioning

confidence: 99%

The Evolutionary Emergence of Vertebrates From Among Their Spineless Relatives

Donoghue

Purnell

2009

Evo Edu Outreach

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The evolutionary origin of vertebrates has been debated ad nauseam by anatomists, paleontologists, embryologists, and physiologists, but it is only now that molecular phylogenetics is providing a more rigorous framework for the placement of vertebrates among their invertebrate relatives that we can begin to arrive at concrete conclusions concerning the nature of ancient ancestors and the sequence in which characteristic anatomical features were acquired. Vertebrates tunicates and cephalochordates together comprise the chordate phylum, which along with echinoderms and hemichordates constitute the deuterostomes. The origin of vertebrates and of jawed vertebrates is characterized by a doubling of the vertebrate genome, leading to hypotheses that this genomic event drove organismal macroevolution. However, this perspective of evolutionary history, based on living organisms alone, is an artifact. Phylogenetic trees that integrate fossil vertebrates among their living relatives demonstrate the gradual and piecemeal assembly of the gnathostome body plan. Unfortunately, it has not been possible to demonstrate gradual assembly of the vertebrate body plan. This is not because vertebrates are irreducibly complex but because many of the characters that distinguish vertebrates from invertebrates are embryological and cellular and, therefore, inherently unfossilizable. Humans and all other back-boned animals-plus a few others that have no bone at all-comprise the vertebrates. Vertebrates are a clade, meaning that all members of the group have evolved from a common ancestor that they all share. This means that the deeper parts of our evolutionary history are entwined with the origin of the clade, and it should thus come as no surprise to discover, therefore, that the origin of vertebrates has been the subject of intense debate since the earliest days of evolutionary research. In his book Before the backbone, Henry Gee recounts a great number of theories that, over the last century and a half, have invoked almost every other major living animal group as the ancestors of vertebrates (Gee 1996). Mercifully, there is now much less equivocation over the relationships of vertebrates to their living relatives, none of which are thought of as being ancestral. Rather, vertebrates and their nearest kin-the invertebrate chordates, the hemichordates and the echinoderms-are more correctly perceived as living representatives of distinct genealogical lineages that separated one from another deep in geological time. It is the aim of many paleontologists, comparative anatomists, embryologists, and molecular biologists to uncover the genealogical relationships of these animals-their family tree-and to test this tree with evidence that bears on the question of how these distinct organismal designs. Explanations of the emerging evolutionary pattern range from traditional Darwinian gradualistic evolution to those that invoke explosive diversifications (seized upon by creationists and intelligent designers as evidence for irreducible compl...

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The duplication of the Hox gene clusters in teleost fishes*1

Cited by 40 publications

References 72 publications

PCR survey of hox genes in the goldfish Carassius auratus auratus

PCR survey of hox genes in the goldfish Carassius auratus auratus

Whole-genome duplication in teleost fishes and its evolutionary consequences

The Evolutionary Emergence of Vertebrates From Among Their Spineless Relatives

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