PUBLICATION

A dynamic spatiotemporal extracellular matrix facilitates epicardial-mediated vertebrate heart regeneration

Authors

Mercer, S., Odelberg, S.J., and Simon, H.G.

ID

ZDB-PUB-130903-31

Date

2013

Source

Developmental Biology 382(2): 457-469 (Journal)

Registered Authors

Keywords

heart, regeneration, extracellular matrix, newt, myocardial infarction

MeSH Terms

Animals
Embryo, Nonmammalian
Extracellular Matrix/metabolism*
Fibronectins/metabolism
Hyaluronic Acid/metabolism
Myocardium/metabolism
Myocytes, Cardiac/metabolism
Pericardium/metabolism*
Regeneration/physiology
Salamandridae/physiology*
Stem Cells/cytology
Stem Cells/metabolism
Tenascin/metabolism
Zebrafish/physiology

PubMed

23939298 Full text @ Dev. Biol.

Abstract

Unlike humans, certain adult vertebrates such as newts and zebrafish possess extraordinary abilities to functionally regenerate lost appendages and injured organs, including cardiac muscle. Here, we present new evidence that a remodeled extracellular matrix (ECM) directs cell activities essential for cardiac muscle regeneration. Comprehensive mining of DNA microarrays and Gene Ontology term enrichment analyses for regenerating newt and zebrafish hearts revealed that distinct ECM components and ECM-modifying proteases are among the most significantly enriched genes in response to local injury. In contrast, data analyses for mammalian cardiac injury models indicated that inflammation and metabolic processes are the most significantly activated gene groups. In the regenerating newt heart, we show dynamic spatial and temporal changes in tenascin-C, hyaluronic acid, and fibronectin ECM distribution as early as 3 days postamputation. Linked to distinct matrix remodeling, we demonstrate a myocardium-wide proliferative response and radial migration of progenitor cells. In particular, we report dramatic upregulation of a regeneration-specific matrix in the epicardium that precedes the accumulation and migration of progenitor cells. For the first time, we show that the regenerative ECM component tenascin-C significantly increases newt cardiomyocyte cell cycle reentry in vitro. Thus, the engineering of nature-tested extracellular matrices may provide new strategic opportunities for the enhancement of regenerative responses in mammals.

Genes / Markers

Figures

Expression

Phenotype

Mutations / Transgenics

Human Disease / Model

Sequence Targeting Reagents

Fish

Antibodies

Orthology

Engineered Foreign Genes

Mapping

Mercer et al., 2013 ZDB-PUB-130903-31 PMID:23939298

A dynamic spatiotemporal extracellular matrix facilitates epicardial-mediated vertebrate heart regeneration

Mercer et al., 2013

ZDB-PUB-130903-31
PMID:23939298