Dissecting planarian central nervous system regeneration by the expression of neural‐specific genes

Cebrià, Francesc; Nakazawa, Masumi; Mineta, Katsuhiko; Ikeo, Kazuho; Gojobori, Takashi; Agata, Kiyokazu

doi:10.1046/j.1440-169x.2002.00629.x

Cited by 133 publications

(138 citation statements)

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“…Also, transient structures like the blastema are not always useful for comparative studies across distant taxa. Where blastemas can be characterized by a mass of cells clustering in the area of the wound after closure, leading to growth and regeneration into new organs or new body parts, it has been shown that the histological nature of this mass of cells is different in different regenerative structures (Shibata et al, 1999;Cebrià et al, 2002;Bosch et al, 2008;Kragl et al, 2009;Wenemoser and Reddien, 2010;Aboobaker, 2011;Reddien, 2013;Bely et al, 2014). Additionally in some epimorphic regenerative events, i.e., where local stimulation of cell proliferation precedes the development of the new part, there is a lack of structures that resemble a blastema, such as during the Ciona intestinalis siphon regeneration (Auger et al, 2010) or the whole body regeneration in colonial ascidians (Brown et al, 2009b).…”

Section: Resultsmentioning

confidence: 99%

Reconsidering regeneration in metazoans: an evo-devo approach

Tiozzo

Copley

2015

Front. Ecol. Evol.

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Regeneration of body structures is an ability widely but unevenly distributed amongst the animal kingdom. Understanding regenerative biology in metazoans means understanding the multiplicity of the cellular and molecular mechanisms that lead to the differentiation, morphogenesis and ultimately the development of a particular regenerating unit. In this manuscript we critically assess the evolutionary considerations suggesting that regeneration is an ancestral trait rather than a mechanism independently evolved in different taxa. As a general method to test evolutionary hypothesis on regeneration, we propose mechanistically dissecting the regenerative processes according to its conserved chronological steps: wound healing, mobilization of cell precursors and morphogenesis. We then suggest interpreting regenerative biology from an evo-devo perspective, proposing a possible theoretical framework and experimental approaches without necessarily invoking a common origin or only multiple losses of regenerative capabilities.

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Section: Resultsmentioning

confidence: 99%

Reconsidering regeneration in metazoans: an evo-devo approach

Tiozzo

Copley

2015

Front. Ecol. Evol.

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“…We investigated precisely how the neurons in each domain are connected by analysing the projection patterns of each domain in detail by DiI/DiD tracing (Okamoto et al 2005). Also, we found that a planarian netrin homologue (Djnetrin) is expressed in the junctions between visual neurons and the brain as well as between the VNCs and the brain (Cebrià et al 2002c;Cebrià & Newmark 2005). These analyses suggested that a variety of external signals received by these sensory neurons may be integrated in the DjotxBexpressing domain, where dopaminergic neurons are concentrated (Nishimura et al 2007), and that these integrated signals may be transferred to the body muscles through the VNCs (Tazaki et al 1999).…”

Section: Structure Of the Planarian Brainmentioning

confidence: 99%

“…Interestingly, most of these genes are expressed in distinct domains of the intact brain and at distinct stages during the brain regeneration. They can be classified into four classes according to their expression timing during the process of brain regeneration: early; early-middle; late-middle; and late genes (Cebrià et al 2002c ). These results suggested that clathrin-mediated endocytic signals may be required not only for the maintenance of neurons after synaptic formation, but also for axonal extension at the early stage of brain regeneration.…”

Section: Screening Of Genes Involved In the Brain Regenerationmentioning

confidence: 99%

Brain regeneration from pluripotent stem cells in planarian

Agata

Umesono

2008

Phil. Trans. R. Soc. B

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How can planarians regenerate their brain? Recently we have identified many genes critical for this process. Brain regeneration can be divided into five steps: (1) anterior blastema formation, (2) brain rudiment formation, (3) pattern formation, (4) neural network formation, and (5) functional recovery. Here we will describe the structure and process of regeneration of the planarian brain in the first part, and then introduce genes involved in brain regeneration in the second part. Especially, we will speculate about molecular events during the early steps of brain regeneration in this review. The finding providing the greatest insight thus far is the discovery of the nou-darake (ndk; 'brains everywhere' in Japanese) gene, since brain neurons are formed throughout the entire body as a result of loss of function of the ndk gene. This finding provides a clue for elucidating the molecular and cellular mechanisms underlying brain regeneration. Here we describe the molecular action of the nou-darake gene and propose a new model to explain brain regeneration and restriction in the head region of the planarians.

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“…Large-scale expression analyses have revealed that many neural genes involved in vertebrate brain development and function are also expressed in distinct domains of the planarian CNS [13,14]. These results indicate that the planarian CNS is functionally regionalized according to a discrete expression of neural-specific genes.…”

Section: Da Neuronal Regeneration In Regenerative Animalsmentioning

confidence: 98%