Genetic Alterations That Inhibit in Vivo Pressure-overload Hypertrophy Prevent Cardiac Dysfunction Despite Increased Wall Stress

Overview

Journal Circulation

Specialty Cardiology & Vascular Diseases

Date 2002 Jan 5

PMID 11772881

Citations 102

Authors

Giovanni Esposito

Antonio Rapacciuolo

Sathyamangla V Naga Prasad

Hideyuki Takaoka

Steven A Thomas

Walter J Koch

Howard A Rockman

Affiliations

Soon will be listed here.

Abstract

Background: A long-standing hypothesis has been that hypertrophy is compensatory and by normalizing wall stress acts to maintain normal cardiac function. Epidemiological data, however, have shown that cardiac hypertrophy is associated with increased mortality, thus casting doubt on the validity of this hypothesis.

Methods And Results: To determine whether cardiac hypertrophy is necessary to preserve cardiac function, we used 2 genetically altered mouse models that have an attenuated hypertrophic response to 8 weeks of pressure overload. End-systolic wall stress (sigma(es)) obtained by sonomicrometry after 1 week of pressure overload showed complete normalization of sigma(es) in pressure-overloaded wild-type mice (287+/-39 versus sham, 254+/-34 g/cm2), whereas the blunted hypertrophic response in the transgenic mice was inadequate to normalize sigma(es) (415+/-81 g/cm2, P<0.05). Remarkably, despite inadequate normalization of sigma(es), cardiac function as measured by serial echocardiography showed little deterioration in either of the pressure-overloaded genetic models with blunted hypertrophy. In contrast, wild-type mice with similar pressure overload showed a significant increase in chamber dimensions and progressive deterioration in cardiac function. Analysis of downstream signaling pathways in the late stages of pressure overload suggests that phosphoinositide 3-kinase may play a pivotal role in the transition from hypertrophy to heart failure.

Conclusions: These data suggest that under conditions of pressure overload, the development of cardiac hypertrophy and normalization of wall stress may not be necessary to preserve cardiac function, as previously hypothesized.

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