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J Thorac Cardiovasc Surg 2004;127:746-754
© 2004 The American Association for Thoracic Surgery

Surgery for congenital heart disease

Gene expression profiles in children undergoing cardiac surgery for right heart obstructive lesions¹

^a Division of Cardiovascular Surgery and Division of Cardiology, Hospital for Sick Children, Toronto General Hospital, Toronto, Ontario, Canada
^b Max Bell Research Centre, University of Toronto, Toronto, Ontario, Canada

Read at the Eighty-third Annual Meeting of The American Association for Thoracic Surgery, Boston, Mass, May 4-7, 2003.

Received for publication May 5, 2003; revisions received June 17, 2003; revisions received August 8, 2003; accepted for publication August 26, 2003.

^* Address for reprints: J. G. Coles, MD, Division of Cardiovascular Surgery, Hospital for Sick Children, 555 University Ave, Toronto, ON , M5G 1X8, Canada
john.coles{at}sickkids.ca

BACKGROUND: The global myocardial stress response during cardiac surgery has not been systematically studied, nor is it known whether the response of the neonatal myocardium is intrinsically different from that of older children. To determine the age-related molecular basis of this response, we conducted microarray-based differential gene expression profiling on right ventricular tissue samples acquired in patients of varying ages with right ventricular outflow tract obstruction.

METHODS: We studied gene expression profiles in 24 patients during operations for lesions involving right ventricular outflow tract obstruction age stratified into group I (7 patients, aged 5 to 66 days; mean, 30 days) and group II (17 patients, aged 4 months to 12.5 years; mean, 2.8 years). Myocardial samples were taken from the right ventricular outflow tract after aortic occlusion and archived in liquid nitrogen. RNA isolation, fluorescence labeling of complementary DNA, hybridization to spotted arrays containing 19,008 characterized or unknown human complementary DNAs, and quantitative fluorescence scanning of gene-expression intensity were performed at the University of Toronto Health Network Microarray Centre. Data were analyzed with the Significance Analysis for Microarrays program. Minimum Information About Microarray Experiments–compliant, log2-normalized data sets were compared to ascertain potential statistical differences in gene expression between patient groups.

RESULTS: There were no hospital deaths or major postoperative morbid events. We identified 50 transcripts differentially expressed in the neonatal group (the predicted false discovery rate was <0.8 transcripts). The neonatal pattern of gene expression (group I) was dominated by genes with literature-validated cardioprotective, antihypertrophic, and antiproliferative properties, including increases in atrial natriuretic peptide, protein phosphatase 2A, small GTPase rap1, and protein inhibitor of activated STAT protein, PIASy. Several transcripts have not been previously reported in heart.

CONCLUSIONS: Neonatal myocardium has a unique pattern of gene expression, which may result from developmental (age-related) differences or reflect a more severe disease phenotype independent of age effects per se. The neonatal transcript profile seems to reflect a stress-induced protective program composed of genes with functions diametrically opposed to those expected to be related to the pathogenesis of critical right ventricular outflow tract obstruction, thus revealing a novel and compensatory antidisease transcriptional response in the neonatal heart.

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