Vertebrate-like regeneration in the invertebrate chordate amphioxus

Somorjai, Ildikó Maureen Lara; Somorjai, R. L.; Garcia‐Fernàndez, Jordi; Escrivà, Héctor

doi:10.1073/pnas.1100045109

Cited by 77 publications

(110 citation statements)

References 49 publications

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“…Zhang and colleagues (2009) use posterior blastemas in lieu of embryos to successfully make metaphase spreads for chromosome counts, but otherwise do not discuss regeneration in these species. In contrast, the recent, more detailed analyses of B. lanceolatum show that it has considerable tail regeneration capacity (Bone 1992; Pegeta 1992; Somorjai et al, 2012a), even after multiple rounds of amputation (Somorjai et al, 2012b). Interestingly, Bone (1992) states that animals allowed to bury in the gravel or maintained in the dark do not regenerate, in stark contrast to the successful regenerates observed by Pegeta (1992) and Somorjai et al, 2012a, b) under the aforementioned conditions.…”

Section: Regenerative Ability In Cephalochordatescontrasting

confidence: 43%

“…Of the small B. lanceolatum (2.3 cm) amputated anteriorly, wound healing was observed in only a single small adult lancelet, and none at all in larger (2.8 cm) animals (Biberhofer 1906). Recent work confirms that only extreme anterior axial amputations result in any appreciable regeneration, even under prime conditions that promote complete tail regeneration (Somorjai et al, 2012a), suggesting this is not an artefact of environmental or physiological conditions. Exceptions to this are the oral cirri, the non-mineralised skeletal rods surrounding the mouth opening, which regenerate well in both B. japonicum and B. lanceolatum (Kaneto and Wada 2011;Somorjai et al, 2012a).…”

Section: Regenerative Ability In Cephalochordatesmentioning

confidence: 56%

“…Recent work confirms that only extreme anterior axial amputations result in any appreciable regeneration, even under prime conditions that promote complete tail regeneration (Somorjai et al, 2012a), suggesting this is not an artefact of environmental or physiological conditions. Exceptions to this are the oral cirri, the non-mineralised skeletal rods surrounding the mouth opening, which regenerate well in both B. japonicum and B. lanceolatum (Kaneto and Wada 2011;Somorjai et al, 2012a). Data are lacking on anterior regeneration outside Branchiostoma, and no regenerative abilities have been reported for the third cephalochordate genus, Epigonichthys.…”

Section: Regenerative Ability In Cephalochordatesmentioning

confidence: 65%

“…He documents the caudal regenerative ability in this species, indicating a full recovery of all structures including the notochord and nerve cord (Andrews 1893). Direct or indirect evidence of posterior regeneration in Branchiostoma has also been shown in recent years in B. lanceolatum (Bone 1992;Pegeta 1992;Somorjai et al, 2012a), B. platae (Silva et al, 1998), B. japonicum (previously conflated with B. belcheri) and B. belcheri (Zhang et al, 2009). Zhang and colleagues (2009) use posterior blastemas in lieu of embryos to successfully make metaphase spreads for chromosome counts, but otherwise do not discuss regeneration in these species.…”

Section: Regenerative Ability In Cephalochordatesmentioning

confidence: 99%

“…The cellular events occurring during regeneration have been described in most detail during post-anal tail regeneration in the European species, B. lanceolatum (Somorjai et al, 2012a). After posterior amputation, humoral fluids are released, and cellular debris around the amputation plane, including fragments of transected muscle fibres, are sloughed away (stage 0).…”

Section: Tail Regenerationmentioning

confidence: 99%

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Amphioxus regeneration: evolutionary and biomedical implications

Somorjai

2017

Int. J. Dev. Biol.

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Regeneration is a variable trait in chordates, with some species capable of impressive abilities, and others of only wound healing with scarring. Regenerative capacity has been reported in the literature for 5 species from two cephalochordate genera, Branchiostoma and Asymmetron. Its cellular and molecular bases have been studied in some detail in only two species: tail regeneration in the European amphioxus B. lanceolatum; and oral cirrus regeneration in the Asian species B. japonicum. Gene expression analyses of germline formation and posterior elongation in cephalochordate embryos provide some insight into regulation of progenitor and stem cell function. When combined with functional studies of gene function, including overexpression and knockdown, these will open the door to amphioxus as a good model not only for understanding the evolution of regeneration, but also for biomedical purposes.

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Section: Regenerative Ability In Cephalochordatescontrasting

confidence: 43%

Section: Regenerative Ability In Cephalochordatesmentioning

confidence: 56%

Section: Regenerative Ability In Cephalochordatesmentioning

confidence: 65%

Section: Regenerative Ability In Cephalochordatesmentioning

confidence: 99%

Section: Tail Regenerationmentioning

confidence: 99%

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Amphioxus regeneration: evolutionary and biomedical implications

Somorjai

2017

Int. J. Dev. Biol.

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My Favorite Animal, Amphioxus: Unparalleled for Studying Early Vertebrate Evolution

Escrivà

2018

BioEssays

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Amphioxus represents the most basally divergent group in chordates and probably the best extant proxy to the ancestor of all chordates including vertebrates. The amphioxus, or lancelets, are benthic filter feeding marine animals and their interest as a model in research is due to their phylogenetic position and their anatomical and genetic stasis throughout their evolutionary history. From the first works in the 19th century to the present day, enormous progress is made mainly favored by technical development at different levels, from spawning induction and husbandry techniques, through techniques for studies of gene function or of the role of different signalling pathways through embryonic development, to functional genomics techniques. Together, these advances foretell a plethora of interesting developments in the world of research with the amphioxus model. Here, the discovery and development of amphioxus as a superb model organism in evolutionary and evolutionary‐developmental biology are reviewed.

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Head regeneration in hemichordates is not a strict recapitulation of development

Luttrell

Gotting

Ross

et al. 2016

Developmental Dynamics

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Background: Head or anterior body part regeneration is commonly associated with protostome, but not deuterostome invertebrates. However, it has been shown that the solitary hemichordate Ptychodera flava possesses the remarkable capacity to regenerate their entire nervous system, including their dorsal neural tube and their anterior head‐like structure, or proboscis. Hemichordates, also known as acorn worms, are marine invertebrate deuterostomes that have retained chordate traits that were likely present in the deuterostome ancestor, placing these animals in a vital position to study regeneration and chordate evolution. All acorn worms have a tripartite body plan, with an anterior proboscis, middle collar region, and a posterior trunk. The collar houses a hollow, dorsal neural tube in ptychoderid hemichordates and numerous chordate genes involved in brain and spinal cord development are expressed in a similar anterior–posterior spatial arrangement along the body axis. Results: We have examined anterior regeneration in the hemichordate Ptychodera flava and report the spatial and temporal morphological changes that occur. Additionally, we have sequenced, assembled, and analyzed the transcriptome for eight stages of regenerating P. flava, revealing significant differential gene expression between regenerating and control animals. Conclusions: Importantly, we have uncovered developmental steps that are regeneration‐specific and do not strictly follow the embryonic program. Developmental Dynamics 245:1159–1175, 2016. © 2016 The Authors. Developmental Dynamics published by Wiley Periodicals, Inc. on behalf of American Association of Anatomists

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Vertebrate-like regeneration in the invertebrate chordate amphioxus

Cited by 77 publications

References 49 publications

Amphioxus regeneration: evolutionary and biomedical implications

Amphioxus regeneration: evolutionary and biomedical implications

My Favorite Animal, Amphioxus: Unparalleled for Studying Early Vertebrate Evolution

Head regeneration in hemichordates is not a strict recapitulation of development

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