Architecture of a microRNA-controlled gene regulatory network that diversifies neuronal cell fates.

Architecture of a microRNA-controlled gene regulatory network that diversifies neuronal cell fates. Research Abstract Details 

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Architecture of a microRNA-controlled gene regulatory network that diversifies neuronal cell fates. Abstract Text:

O Hobert,

Individual cell types are defined by the expression of specific gene batteries. Regulatory networks that control cell-type-specific gene expression programs in the nervous system are only beginning to be understood. This paper summarizes a complex gene regulatory network, composed of several transcription factors and microRNAs (miRNAs), that controls neuronal subclass specification in the nervous system of the nematode Caenorhabditis elegans.

Architecture of a microRNA-controlled gene regulatory network that diversifies neuronal cell fates. Publishing Authors By Initials

O Hobert,

For similar nervous system: neurons research abstracts see: nervous system: neurons research

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Architecture of a microRNA-controlled gene regulatory network that diversifies neuronal cell fates. Journal Published:

PUBLICATION TYPE: Review

Journal: Cold Spring Harbor symposia on quantitative biolog

VOLUME: 71

Page Numbers: 181-8

Journal Abbreviation: Cold Spring Harb. Symp. Quant.

ISSN: 0091-7451

DAY: 3

MONTH: 12

YEAR: 2006

Architecture of a microRNA-controlled gene regulatory network that diversifies neuronal cell fates. Information

Number of References: 35

LANGUAGE: eng

NlmUniqueID: 1256107

Architecture of a microRNA-controlled gene regulatory network that diversifies neuronal cell fates. Keywords Mesh Terms:

KEYWORDS: Neurons

MESH TERMS: metabolism

Chemical & Substance for Abstract: Architecture of a microRNA-controlled gene regulatory network that diversifies neuronal cell fates. Information

Substance Name: MicroRNAs

Registry Number: 0

Grant and Affiliation Information for Architecture of a microRNA-controlled gene regulatory network that diversifies neuronal cell fates.

AFFILIATION: Howard Hughes Medical Institute, Department of Biochemistry and Molecular Biophysics, Columbia University Medical Center, New York, New York 10032, USA.

Country: United States

AGENCY: United States NINDS

GRANT: 5R01NS050266-02

ACRONYM: NS

MEDLINETA: Cold Spring Harb Symp Quant Bi

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