The molecular logic for planarian regeneration along the anterior–posterior axis

Umesono, Yoshihiko; Tasaki, Junichi; Nishimura, Yui; Hrouda, Martina; Kawaguchi, Eri; Yazawa, Shogo; Nishimura, Osamu; Hosoda, Kazutaka; Inoue, Takeshi; Agata, Kiyokazu

doi:10.1038/nature12359

Cited by 155 publications

(158 citation statements)

References 24 publications

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“…However, our findings indicate that β-CATENIN-1 could be a component of both the anterior and the posterior organizers, and that it is the fine-tuning of β-CATENIN-1 that is essential for the organizing function in each pole. This is further supported by the observation that β-catenin-1 inhibition restores the ability to regenerate a head in anterior wounds in planarian species that cannot regenerate anteriorly (Liu et al, 2013;Sikes and Newmark, 2013;Umesono et al, 2013). Similarly, β-CATENIN-1 stabilization also restores the ability to regenerate anterior wounds in these animals, even though this experiment causes the expected polarity reversal and the planarians develop a two-tailed phenotype (Liu et al, 2013;Sikes and Newmark, 2013;Umesono et al, 2013).…”

Section: A Gradient Of β-Catenin-1 Along the Ap Axismentioning

confidence: 59%

“…This is further supported by the observation that β-catenin-1 inhibition restores the ability to regenerate a head in anterior wounds in planarian species that cannot regenerate anteriorly (Liu et al, 2013;Sikes and Newmark, 2013;Umesono et al, 2013). Similarly, β-CATENIN-1 stabilization also restores the ability to regenerate anterior wounds in these animals, even though this experiment causes the expected polarity reversal and the planarians develop a two-tailed phenotype (Liu et al, 2013;Sikes and Newmark, 2013;Umesono et al, 2013). Nevertheless, further work will be necessary to determine which specific upstream regulators generate this context-specific behavior and enable the differential roles of nuclear β-CATENIN-1 in anterior and posterior blastemas.…”

Section: A Gradient Of β-Catenin-1 Along the Ap Axismentioning

confidence: 65%

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Localization of planarian β-CATENIN-1 reveals multiple roles during anterior-posterior regeneration and organogenesis

2016

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The β-catenin-dependent Wnt pathway exerts multiple contextdependent roles in embryonic and adult tissues. In planarians, β-catenin-1 is thought to specify posterior identities through the generation of an anteroposterior gradient. However, the existence of such a gradient has not been directly demonstrated. Here, we use a specific polyclonal antibody to demonstrate that nuclear β-CATENIN-1 exists as an anteroposterior gradient from the pre-pharyngeal region to the tail of the planarian Schmidtea polychroa. High levels in the posterior region steadily decrease towards the pre-pharyngeal region but then increase again in the head region. During regeneration, β-CATENIN-1 is nuclearized in both anterior and posterior blastemas, but the canonical WNT1 ligand only influences posterior nuclearization. Additionally, β-catenin-1 is required for proper anterior morphogenesis, consistent with the high levels of nuclear β-CATENIN-1 observed in this region. We further demonstrate that β-CATENIN-1 is abundant in developing and differentiated organs, and is particularly required for the specification of the germline. Altogether, our findings provide the first direct evidence of an anteroposterior nuclear β-CATENIN-1 gradient in adult planarians and uncover novel, context-dependent roles for β-catenin-1 during anterior regeneration and organogenesis.

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Section: A Gradient Of β-Catenin-1 Along the Ap Axismentioning

confidence: 59%

Section: A Gradient Of β-Catenin-1 Along the Ap Axismentioning

confidence: 65%

Localization of planarian β-CATENIN-1 reveals multiple roles during anterior-posterior regeneration and organogenesis

2016

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“…However, the wealthiest accumulation of stem cells does not ensure that regeneration will take place. This concept is beautifully demonstrated by three separate studies of planarians with decreased regenerative capabilities (Sikes and Newmark, 2013;Umesono et al, 2013;Liu et al, 2013). These studies showed that the evolutionary loss of head regeneration observed in posterior fragments of some planarian species was not due to insufficient populations of stem cells, but by differences in expression levels of components in the conserved wnt/b-catenin developmental pathway.…”

Section: Labib Rouhana and Junichi Tasakimentioning

confidence: 80%

A primer on regeneration

Rouhana

Tasaki

2015

Preprint

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Centuries of observation have uncovered a diverse range of organisms capable of overcoming loss of tissue. The act of restoring lost anatomy and function is known as regeneration, and it is broadly represented in both plant and animal kingdoms. Cumulative studies have identified a series of events that take place during regeneration of complex animal structures. First, the organism recognizes damage and undergoes wound healing. Then, programmed cell death in the vicinity of the damaged tissue precedes proliferation and migration of cells that foster the development of replacement tissue. Finally, rearrangement of pre-existing tissue and integration with newly differentiated cells take place to restore the function and proportionality displayed previous to damage . Although the ability to regenerate is believed to be ancestrally common and lost throughout evolution, there is significant heterogeneity of some basic mechanisms displayed during regeneration in different animal species. Perhaps one of the most noticeable differences is the cellular source contributing to formation of the new tissue during regeneration. Organisms such as planarians and Hydra rely on active reservoirs of somatic pluripotent stem cells abundantly distributed throughout their bodies and maintained throughout their life. On the other hand, vertebrates rely mostly on progenitor cell activation and dedifferentiation, to regenerate cells with limited potential to regenerate specific structures. However, not all regenerative events rely on cellular replacement. Leading edge research has begun to uncover mechanisms involved in autonomous repair and functional regeneration of single cells – be it neurons or ciliated protozoa. The fact that organisms can achieve regeneration through diverse cellular sources is remarkable, but just as remarkable is the possibility that conserved molecular pathways could be activated to achieve regeneration in different species. Analysis of these pathways will contribute to understanding human development and potential avenues for regenerative medicine.

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“…A classic experiment by T. H. Morgan illustrated the remarkable whole-body regeneration capabilities in a planarian species: a tiny fragment just 1/279th of the original worm was able to regenerate an entire individual (Morgan, 1898). However, at least one dugesid (a species of Phagocata) is shown to fail to regenerate a new complete head following post-pharyngeal amputation (Umesono et al, 2013), suggesting a possible loss of head regeneration within this group (and possibly even within this genus, since other Phagocata species are known to regenerate a head). Among the triclads, several genera within the family Dendrocoelidae have been evaluated for regenerative ability and none are able to regenerate a complete head after amputation posterior to the pharynx (i.e., cutting within the posterior two-thirds of the primary body axis) (Lillie, 1901;Morgan, 1904;Brøndsted, 1969;Sikes and Newmark, 2013).…”

Section: * Indicates the Family Is Polyphyletic And † Indicates Thementioning

confidence: 99%

Regeneration in spiralians: evolutionary patterns and developmental processes

Bely¹,

Zattara²,

Sikes³

2014

Int. J. Dev. Biol.

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Animals differ markedly in their ability to regenerate, yet still little is known about how regeneration evolves. In recent years, important advances have been made in our understanding of animal phylogeny and these provide new insights into the phylogenetic distribution of regeneration. The developmental basis of regeneration is also being investigated in an increasing number of groups, allowing commonalities and differences across groups to become evident. Here, we focus on regeneration in the Spiralia, a group that includes several champions of animal regeneration, as well as many groups with more limited abilities. We review the phylogenetic distribution and developmental processes of regeneration in four major spiralian groups: annelids, nemerteans, platyhelminths, and molluscs. Although comparative data are still limited, this review highlights phylogenetic and developmental patterns that are emerging regarding regeneration in spiralians and identifies important avenues for future research.

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The molecular logic for planarian regeneration along the anterior–posterior axis

Cited by 155 publications

References 24 publications

Localization of planarian β-CATENIN-1 reveals multiple roles during anterior-posterior regeneration and organogenesis

Localization of planarian β-CATENIN-1 reveals multiple roles during anterior-posterior regeneration and organogenesis

A primer on regeneration

Regeneration in spiralians: evolutionary patterns and developmental processes

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