Hemichordate models

Tagawa, Kunifumi

doi:10.1016/j.gde.2016.05.023

Cited by 17 publications

(13 citation statements)

References 59 publications

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“…Recent molecular analyses [107,108] clearly dismiss previous data [109] that the sedentary phylum Pterobranchia is a part of the clade of the free-living Enteropneusta. If Pterobranchia was really modified secondarily from the enteropneust-like groundplan, then the pterobranchs must be nested inside as an internal subclade of the enteropneusts, but pterobranchs instead are confirmed as merely a sister group to Enteropneusta [108]. There is also a large agreement currently that segmentation was not a property of the bilaterian ancestor, but emerged independently in several bilaterian lineages [110][111][112], that undermines a scenario of a free-living segmented last common bilaterian ancestor [113].…”

Section: Applications Of the Model Of Burrow-driven Paedomorphosis Inmentioning

confidence: 94%

“…A majority of the confirmed early Cambrian echinoderm representatives are sedentary or semisedentary with Ushaped gut, like modern pterobranchs, but not enteropneusts [104][105][106]. Recent molecular analyses [107,108] clearly dismiss previous data [109] that the sedentary phylum Pterobranchia is a part of the clade of the free-living Enteropneusta. If Pterobranchia was really modified secondarily from the enteropneust-like groundplan, then the pterobranchs must be nested inside as an internal subclade of the enteropneusts, but pterobranchs instead are confirmed as merely a sister group to Enteropneusta [108].…”

Section: Applications Of the Model Of Burrow-driven Paedomorphosis Inmentioning

confidence: 96%

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Multiple paedomorphic lineages of soft-substrate burrowing invertebrates: parallels in the origin of Xenocratena and Xenoturbella

et al. 2020

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Section: Applications Of the Model Of Burrow-driven Paedomorphosis Inmentioning

confidence: 94%

Section: Applications Of the Model Of Burrow-driven Paedomorphosis Inmentioning

confidence: 96%

Multiple paedomorphic lineages of soft-substrate burrowing invertebrates: parallels in the origin of Xenocratena and Xenoturbella

et al. 2020

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“…It has long been thought that the gill slits in hemichordates, amphioxus, tunicates and vertebrates are homologous, and thus that a pharynx perforated by gill slits existed before hemichordates branched from the chordates (Bateson, 1886); reviewed in (Tagawa, 2016). Molecular data have reinforced these homologies (Fig.…”

Section: Amphioxus In the Era Of Evolutionary Developmental Biology (mentioning

confidence: 98%

The ups and downs of amphioxus biology: a history

Holland¹,

Holland²

2017

Int. J. Dev. Biol.

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Humans (at least a select few) have long known about the cephalochordate amphioxus, first as something to eat and later as a subject for scientific study. The rate of publication on these animals has waxed and waned several times. The first big surge, in the late nineteenth century, was stimulated by Darwin's evolutionary ideas and by Kowalevsky's embryologic findings suggesting that an amphioxus-like creature might have bridged the gap between the invertebrates and the vertebrates. Interest declined sharply in the early twentieth century and remained low for the next 50 years. An important contributing factor (in addition to inhibition by two world wars and the Great Depression) was the indifference of the new evolutionary synthesis toward broad phylogenetic problems like the origin of the vertebrates. Then, during the 1960s and 1970s, interest in amphioxus resurged, driven especially by increased government support for basic science as well as opportunities presented by electron microscopy. After faltering briefly in the 1980s (electron microscopists were running out of amphioxus tissues to study), a third and still-continuing period of intensive amphioxus research began in the early 1990s, stimulated by the advent of evolutionary developmental biology (evo-devo) and genomics. The volume of studies peaked in 2008 with the publication of the genome of the Florida amphioxus. Since then, although the number of papers per year has dropped somewhat, sequencing of additional genomes and transcriptomes of several species of amphioxus (both in the genus Branchiostoma and in a second genus, Asymmetron) is providing the raw material for addressing the major unanswered question of the relationship between genotype and phenotype.

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“…In addition, a stomochord in the proboscis, a notochord, and a dorsal nerve cord forming a hollow tube in the mesosome, imply a close relationship between hemichordates and chordates. Although structural homologies of these organs are still controversial (Satoh et al., ; Tagawa, ), formation of gill slits and pharyngeal arches in deuterostomes is regulated by an orthologous gene cluster (Gillis, Fritzenwanker, & Lowe, ; Ogasawara, Wada, Peters, & Satoh, ; Simakov et al., ).…”

Section: Overview Of Hemichordates and Regenerationmentioning

confidence: 99%

Regeneration in the enteropneust hemichordate, Ptychodera flava, and its evolutionary implications

Arimoto

Tagawa

2018

Dev Growth Differ

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Hemichordates are marine invertebrates that are closely related to chordates, but while their body plans are comparable to those of chordates, they possess a remarkable capacity for regeneration, even as adults. A small fragment is sufficient to form a complete individual. Unlike echinoderms, their larvae transform directly into adults; therefore, hemichordate systems offer clear morphological and molecular parallels between regeneration and development. Morphological events in regeneration are generally similar to organogenesis in juveniles. Nonetheless, comparative analysis of gene expression in these two morphological phenomena suggests that hemichordate regeneration is regulated by regeneration-specific mechanisms, as well as by developmental mechanisms. Dependency upon resident pluripotent/multipotent stem cells is a significant difference in metazoan regeneration, and such stem cells are essential for regeneration in many lineages. Based on the present gene expression study, regeneration in acorn worms is more closely related to that in vertebrates, because it employs endogenous stem cell-independent transdifferentiation.

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Hemichordate models

Cited by 17 publications

References 59 publications

Multiple paedomorphic lineages of soft-substrate burrowing invertebrates: parallels in the origin of Xenocratena and Xenoturbella

Multiple paedomorphic lineages of soft-substrate burrowing invertebrates: parallels in the origin of Xenocratena and Xenoturbella

The ups and downs of amphioxus biology: a history

Regeneration in the enteropneust hemichordate, Ptychodera flava, and its evolutionary implications

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