Unraveling Tissue Regeneration Pathways Using Chemical Genetics

Unraveling Tissue Regeneration Pathways Using Chemical Genetics

Identifying the molecular pathways that are required for regeneration remains one of the great challenges of regenerative medicine. Although genetic mutations have been useful for identifying some molecular pathways, small molecule probes of regenerative pathways might offer some advantages, includi...

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Bibliographic Details
Published in:The Journal of biological chemistry Vol. 282; no. 48; pp. 35202 - 35210
Main Authors: Mathew, Lijoy K., Sengupta, Sumitra, Kawakami, Atsushi, Andreasen, Eric A., Löhr, Christiane V., Loynes, Catherine A., Renshaw, Stephen A., Peterson, Randall T., Tanguay, Robert L.
Format: Journal Article
Language:English
Published: United States Elsevier Inc 30-11-2007
American Society for Biochemistry and Molecular Biology
Subjects:
Animals
Anti-Inflammatory Agents - pharmacology
Cell Differentiation
Cell Movement
Cell Proliferation
Danio rerio
Dose-Response Relationship, Drug
Extremities - embryology
Freshwater
Genetic Techniques
Glucocorticoids - metabolism
Macrophages - cytology
Male
Models, Anatomic
Models, Biological
Neutrophils - metabolism
Regeneration
Signal Transduction
Wound Healing
Zebrafish
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Summary:Identifying the molecular pathways that are required for regeneration remains one of the great challenges of regenerative medicine. Although genetic mutations have been useful for identifying some molecular pathways, small molecule probes of regenerative pathways might offer some advantages, including the ability to disrupt pathway function with precise temporal control. However, a vertebrate regeneration model amenable to rapid throughput small molecule screening is not currently available. We report here the development of a zebrafish early life stage fin regeneration model and its use in screening for small molecules that modulate tissue regeneration. By screening 2000 biologically active small molecules, we identified 17 that specifically inhibited regeneration. These compounds include a cluster of glucocorticoids, and we demonstrate that transient activation of the glucocorticoid receptor is sufficient to block regeneration, but only if activation occurs during wound healing/blastema formation. In addition, knockdown of the glucocorticoid receptor restores regenerative capability to nonregenerative, glucocorticoid-exposed zebrafish. To test whether the classical anti-inflammatory action of glucocorticoids is responsible for blocking regeneration, we prevented acute inflammation following amputation by antisense repression of the Pu.1 gene. Although loss of Pu.1 prevents the inflammatory response, regeneration is not affected. Collectively, these results indicate that signaling from exogenous glucocorticoids impairs blastema formation and limits regenerative capacity through an acute inflammation-independent mechanism. These studies also demonstrate the feasibility of exploiting chemical genetics to define the pathways that govern vertebrate regeneration.
Bibliography:http://www.jbc.org/
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ISSN:0021-9258
1083-351X
DOI:10.1074/jbc.M706640200