Gene expression profiles in engineered cardiac tissues respond to mechanical loading and inhibition of tyrosine kinases

Engineered cardiac tissues (ECTs) are platforms to investigate cardiomyocyte maturation and functional integration, the feasibility of generating tissues for cardiac repair, and as models for pharmacology and toxicology bioassays. ECTs rapidly mature in vitro to acquire the features of functional ca...

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Bibliographic Details
Published in:Physiological reports 2013-10, Vol.1 (5), p.e00078-n/a
Main Authors: Ye, Fei, Yuan, Fangping, Li, Xiaohong, Cooper, Nigel, Tinney, Joseph P., Keller, Bradley B.
Format: Article
Language:English
Subjects:
BIRB796
Cardiac muscle
Cardiomyocytes
Cell culture
Cell death
DNA microarrays
engineered cardiac tissues
Enzyme inhibitors
Gene expression
Hypotheses
Kinases
MAP kinase
Maturation
Mechanical loading
Mechanical properties
Myocardium
Original Research
p38MAPK
Physiology
Polymerase chain reaction
Protein-tyrosine kinase
Proteins
Ribonucleic acid
RNA
Transcription
tyrosine kinases
Ventricle
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Summary:Engineered cardiac tissues (ECTs) are platforms to investigate cardiomyocyte maturation and functional integration, the feasibility of generating tissues for cardiac repair, and as models for pharmacology and toxicology bioassays. ECTs rapidly mature in vitro to acquire the features of functional cardiac muscle and respond to mechanical load with increased proliferation and maturation. ECTs are now being investigated as platforms for in vitro models for human diseases and for pharmacologic screening for drug toxicities. We tested the hypothesis that global ECT gene expression patterns are complex and sensitive to mechanical loading and tyrosine kinase inhibitors similar to the maturing myocardium. We generated ECTs from day 14.5 rat embryo ventricular cells, as previously published, and then conditioned constructs after 5 days in culture for 48 h with mechanical stretch (5%, 0.5 Hz) and/or the p38 MAPK (p38 mitogen‐activated protein kinase) inhibitor BIRB796. RNA was isolated from individual ECTs and assayed using a standard Agilent rat 4 × 44k V3 microarray and Pathway Analysis software for transcript expression fold changes and changes in regulatory molecules and networks. Changes in expression were confirmed by quantitative‐polymerase chain reaction (q‐PCR) for selected regulatory molecules. At the threshold of a 1.5‐fold change in expression, stretch altered 1559 transcripts, versus 1411 for BIRB796, and 1846 for stretch plus BIRB796. As anticipated, top pathways altered in response to these stimuli include cellular development, cellular growth and proliferation; tissue development; cell death, cell signaling, and small molecule biochemistry as well as numerous other pathways. Thus, ECTs display a broad spectrum of altered gene expression in response to mechanical load and/or tyrosine kinase inhibition, reflecting a complex regulation of proliferation, differentiation, and architectural alignment of cardiomyocytes and noncardiomyocytes within ECT. e00078 Changes in selected engineered cardiac tissue (ECT) transcript expression measured by microarray and quantitative‐polymerase chain reaction in response to mechanical stretch conditioning and/or p38MAP kinase inhibition with BIRB796.
ISSN:2051-817X
2051-817X
DOI:10.1002/phy2.78