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Regeneration in Annelids: Cell Sources, Tissue Remodeling, and Differential Gene Expression. / Nikanorova, D.D.; Kupriashova, E.E.; Kostyuchenko, R.P.

In: Russian Journal of Developmental Biology, Vol. 51, No. 3, 05.2020, p. 148–161.

Research output: Contribution to journalReview articlepeer-review

Harvard

Nikanorova, DD, Kupriashova, EE & Kostyuchenko, RP 2020, 'Regeneration in Annelids: Cell Sources, Tissue Remodeling, and Differential Gene Expression', Russian Journal of Developmental Biology, vol. 51, no. 3, pp. 148–161. https://doi.org/10.1134/S1062360420030042

APA

Nikanorova, D. D., Kupriashova, E. E., & Kostyuchenko, R. P. (2020). Regeneration in Annelids: Cell Sources, Tissue Remodeling, and Differential Gene Expression. Russian Journal of Developmental Biology, 51(3), 148–161. https://doi.org/10.1134/S1062360420030042

Vancouver

Nikanorova DD, Kupriashova EE, Kostyuchenko RP. Regeneration in Annelids: Cell Sources, Tissue Remodeling, and Differential Gene Expression. Russian Journal of Developmental Biology. 2020 May;51(3):148–161. https://doi.org/10.1134/S1062360420030042

Author

Nikanorova, D.D. ; Kupriashova, E.E. ; Kostyuchenko, R.P. / Regeneration in Annelids: Cell Sources, Tissue Remodeling, and Differential Gene Expression. In: Russian Journal of Developmental Biology. 2020 ; Vol. 51, No. 3. pp. 148–161.

BibTeX

@article{4675e7e1b71e431eb5cc1e9cbe632fdc,
title = "Regeneration in Annelids: Cell Sources, Tissue Remodeling, and Differential Gene Expression",
abstract = "Recent studies have shown that, despite stereotypical cleavage, annelids show the ability for embryonic regulation, including the formation of germline cells. However, the widest variety of regulative processes is presented in the postlarval development of annelids. The ability to regenerate, which is probably an ancestral feature, manifests itself variously among these animals. Some species are unable to regenerate lost segments. However, most species replace lost posterior body parts, many are able to reestablish missing head segments and structures, and some develop the entire body de novo even on the basis of one or two segments. Most of the regenerated structures are formed due to a set of undifferentiated cells arising from the division of dedifferentiated and/or stem cells. Moreover, the regeneration process often involves remodeling of survived body fragments and may thus be associated not only with local changes but also require a response at the level of the whole organism. In this review, we summarize many recent studies on the molecular and cellular mechanisms of regeneration in annelids. Special attention is paid to the regeneration of the digestive and nervous systems and integuments as well as to the involvement of stem and undifferentiated cells in the development of blastema and in replacing the lost gonads. Accumulation and analysis of recent findings about the diversity of cellular sources and mechanisms of annelid regeneration may shed light on the most evolutionarily conserved programs for maintaining regeneration ability and processes leading to the loss (limitation) of one of the ancestral features of animals.",
keywords = "Regeneration, Dedifferentiation, multipotent cells, stem cells, Germ cells, Gene Expression, Digestive system, Gut morphogenesis, Nervous system, homeobox genes, tissue remodeling, Annelida, Regeneration, Dedifferentiation, multipotent cells, Stem cells, Germ cells, Gene Expression, Germline/Multipotency Program genes, homeobox genes, Digestive system, Gut morphogenesis, Nervous system, tissue remodeling, Annelida, digestive system, regeneration, annelids, dedifferentiation, FUNCTIONAL-ROLE, PROLIFERATION, POSTERIOR REGENERATION, LUMBRICULUS-VARIEGATUS, PLATYNEREIS-DUMERILII, FISSION, germ cells, ENCHYTRAEUS-JAPONENSIS OLIGOCHAETA, stem cells, STEM-CELLS, ASEXUAL REPRODUCTION, nervous system, CAUDAL REGENERATION, gene expression",
author = "D.D. Nikanorova and E.E. Kupriashova and R.P. Kostyuchenko",
note = "Nikanorova, D.D., Kupriashova, E.E. & Kostyuchenko, R.P. Regeneration in Annelids: Cell Sources, Tissue Remodeling, and Differential Gene Expression. Russ J Dev Biol 51, 148–161 (2020). https://doi.org/10.1134/S1062360420030042",
year = "2020",
month = may,
doi = "https://doi.org/10.1134/S1062360420030042",
language = "English",
volume = "51",
pages = "148–161",
journal = "Russian Journal of Developmental Biology",
issn = "1062-3604",
publisher = "МАИК {"}Наука/Интерпериодика{"}",
number = "3",

}

RIS

TY - JOUR

T1 - Regeneration in Annelids: Cell Sources, Tissue Remodeling, and Differential Gene Expression

AU - Nikanorova, D.D.

AU - Kupriashova, E.E.

AU - Kostyuchenko, R.P.

N1 - Nikanorova, D.D., Kupriashova, E.E. & Kostyuchenko, R.P. Regeneration in Annelids: Cell Sources, Tissue Remodeling, and Differential Gene Expression. Russ J Dev Biol 51, 148–161 (2020). https://doi.org/10.1134/S1062360420030042

PY - 2020/5

Y1 - 2020/5

N2 - Recent studies have shown that, despite stereotypical cleavage, annelids show the ability for embryonic regulation, including the formation of germline cells. However, the widest variety of regulative processes is presented in the postlarval development of annelids. The ability to regenerate, which is probably an ancestral feature, manifests itself variously among these animals. Some species are unable to regenerate lost segments. However, most species replace lost posterior body parts, many are able to reestablish missing head segments and structures, and some develop the entire body de novo even on the basis of one or two segments. Most of the regenerated structures are formed due to a set of undifferentiated cells arising from the division of dedifferentiated and/or stem cells. Moreover, the regeneration process often involves remodeling of survived body fragments and may thus be associated not only with local changes but also require a response at the level of the whole organism. In this review, we summarize many recent studies on the molecular and cellular mechanisms of regeneration in annelids. Special attention is paid to the regeneration of the digestive and nervous systems and integuments as well as to the involvement of stem and undifferentiated cells in the development of blastema and in replacing the lost gonads. Accumulation and analysis of recent findings about the diversity of cellular sources and mechanisms of annelid regeneration may shed light on the most evolutionarily conserved programs for maintaining regeneration ability and processes leading to the loss (limitation) of one of the ancestral features of animals.

AB - Recent studies have shown that, despite stereotypical cleavage, annelids show the ability for embryonic regulation, including the formation of germline cells. However, the widest variety of regulative processes is presented in the postlarval development of annelids. The ability to regenerate, which is probably an ancestral feature, manifests itself variously among these animals. Some species are unable to regenerate lost segments. However, most species replace lost posterior body parts, many are able to reestablish missing head segments and structures, and some develop the entire body de novo even on the basis of one or two segments. Most of the regenerated structures are formed due to a set of undifferentiated cells arising from the division of dedifferentiated and/or stem cells. Moreover, the regeneration process often involves remodeling of survived body fragments and may thus be associated not only with local changes but also require a response at the level of the whole organism. In this review, we summarize many recent studies on the molecular and cellular mechanisms of regeneration in annelids. Special attention is paid to the regeneration of the digestive and nervous systems and integuments as well as to the involvement of stem and undifferentiated cells in the development of blastema and in replacing the lost gonads. Accumulation and analysis of recent findings about the diversity of cellular sources and mechanisms of annelid regeneration may shed light on the most evolutionarily conserved programs for maintaining regeneration ability and processes leading to the loss (limitation) of one of the ancestral features of animals.

KW - Regeneration

KW - Dedifferentiation

KW - multipotent cells

KW - stem cells

KW - Germ cells

KW - Gene Expression

KW - Digestive system

KW - Gut morphogenesis

KW - Nervous system

KW - homeobox genes

KW - tissue remodeling

KW - Annelida

KW - Regeneration

KW - Dedifferentiation

KW - multipotent cells

KW - Stem cells

KW - Germ cells

KW - Gene Expression

KW - Germline/Multipotency Program genes

KW - homeobox genes

KW - Digestive system

KW - Gut morphogenesis

KW - Nervous system

KW - tissue remodeling

KW - Annelida

KW - digestive system

KW - regeneration

KW - annelids

KW - dedifferentiation

KW - FUNCTIONAL-ROLE

KW - PROLIFERATION

KW - POSTERIOR REGENERATION

KW - LUMBRICULUS-VARIEGATUS

KW - PLATYNEREIS-DUMERILII

KW - FISSION

KW - germ cells

KW - ENCHYTRAEUS-JAPONENSIS OLIGOCHAETA

KW - stem cells

KW - STEM-CELLS

KW - ASEXUAL REPRODUCTION

KW - nervous system

KW - CAUDAL REGENERATION

KW - gene expression

UR - https://rdcu.be/b411t

UR - https://www.mendeley.com/catalogue/71acdbd8-3dbb-34a9-a427-5009da0bcce1/

U2 - https://doi.org/10.1134/S1062360420030042

DO - https://doi.org/10.1134/S1062360420030042

M3 - Review article

VL - 51

SP - 148

EP - 161

JO - Russian Journal of Developmental Biology

JF - Russian Journal of Developmental Biology

SN - 1062-3604

IS - 3

ER -

ID: 60048524