Reduced in vivo high-energy phosphates precede adriamycin-induced cardiac dysfunction.

Adriamycin (ADR) is an established, life-saving antineoplastic agent, the use of which is often limited by cardiotoxicity. ADR-induced cardiomyopathy is often accompanied by depressed myocardial high-energy phosphate (HEP) metabolism. Impaired HEP metabolism has been suggested as a potential mechanism of ADR cardiomyopathy, in which case the bioenergetic decline should precede left ventricular (LV) dysfunction. We tested the hypothesis that murine cardiac energetics decrease before LV dysfunction following ADR (5 mg/kg ip, weekly, 5 injections) in the mouse. As a result, the mean myocardial phosphocreatine-to-ATP ratio (PCr/ATP) by spatially localized (31)P magnetic resonance spectroscopy decreased at 6 wk after first ADR injection (1.79 + or - 0.18 vs. 1.39 + or - 0.30, means + or - SD, control vs. ADR, respectively, P < 0.05) when indices of systolic and diastolic function by magnetic resonance imaging were unchanged from control values. At 8 wk, lower PCr/ATP was accompanied by a reduction in ejection fraction (67.3 + or - 3.9 vs. 55.9 + or - 4.2%, control vs. ADR, respectively, P < 0.002) and peak filling rate (0.56 + or - 0.12 vs. 0.30 + or - 0.13 microl/ms, control vs. ADR, respectively, P < 0.01). PCr/ATP correlated with peak filling rate and ejection fraction, suggesting a relationship between cardiac energetics and both LV systolic and diastolic dysfunction. In conclusion, myocardial in vivo HEP metabolism is impaired following ADR administration, occurring before systolic or diastolic abnormalities and in proportion to the extent of eventual contractile abnormalities. These observations are consistent with the hypothesis that impaired HEP metabolism contributes to ADR-induced myocardial dysfunction.

Soluble human complement receptor type 1: in vivo inhibitor of complement suppressing post-ischemic myocardial inflammation and necrosis.

The complement system is an important mediator of the acute inflammatory response, and an effective inhibitor would suppress tissue damage in many autoimmune and inflammatory diseases. Such an inhibitor might be found among the endogenous regulatory proteins of complement that block the enzymes that activate C3 and C5. Of these proteins, complement receptor type 1 (CR1; CD35) has the most inhibitory potential, but its restriction to a few cell types limits its function in vivo. This limitation was overcome by the recombinant, soluble human CR1, sCR1, which lacks the transmembrane and cytoplasmic domains. The sCR1 bivalently bound dimeric forms of its ligands, C3b and methylamine-treated C4 (C4-ma), and promoted their inactivation by factor I. In nanomolar concentrations, sCR1 blocked complement activation in human serum by the two pathways. The sCR1 had complement inhibitory and anti-inflammatory activities in a rat model of reperfusion injury of ischemic myocardium, reducing myocardial infarction size by 44 percent. These findings identify sCR1 as a potential agent for the suppression of complement-dependent tissue injury in autoimmune and inflammatory diseases.

Pathologic changes in the cardiac interstitium of mice infected with encephalomyocarditis virus.

Patients with myocarditis often develop dilated cardiomyopathy and congestive heart failure. Histologically, myocarditis is manifested by rare foci of myocyte necrosis with interstitial inflammation, while cardiomyopathy is characterized by diffuse interstitial fibrosis, myocyte hypertrophy, and an absence of active interstitial inflammation. The relationship between myocardial inflammation and interstitial fibrosis is poorly understood. This relationship was examined in mice that developed a diffuse interstitial inflammation of the heart over a period of 21 days following infection with encephalomyocarditis virus. Typical early lesions (day 7) included focal zones of myocytolysis containing mononuclear and polymorphonuclear inflammatory cells that were associated with the focal loss of reticular fibers. Later pathology (days 14-21) was characterized by a sparse, diffuse interstitial myocarditis with little ongoing necrosis. Changes within the myocardial interstitium remote from healing necrotic foci were marked by reticular fiber thickening and disorganization, often associated with pleomorphic fibroblasts. Reticulin fiber deposition was quantitatively increased in sparsely inflamed regions of hearts from infected animals as compared to noninflamed regions from the same hearts (p < 0.005) or hearts of control animals (p < 0.001). Scanning electron microscopy revealed interstitial changes that were more extensive than indicated by routine staining with hematoxylin and eosin for Masson's trichrome. The progressive changes within the cardiac interstitium during the development of postmyocarditic cardiomyopathy suggest that direct viral infection of fibroblasts or an interaction between the interstitium and inflammatory cells and their secreted products may contribute to pathologic changes within the interstitial collagen matrix.

A method to reconstruct myocardial sarcomere lengths and orientations at transmural sites in beating canine hearts.

The ability to measure cyclic changes in myocardial sarcomere lengths and orientations during cardiac ejection and filling would improve our understanding of how the cellular processes of contraction relate to the pumping of the whole heart. Previously, only postmortem sarcomere measurements were possible after arresting the heart in one state and fixing it for histology. By combining such histological measurements with direct observations of the deformation experienced by the same myocardial region while the heart was beating, we have developed a method to reconstruct sarcomere lengths and orientations throughout the cardiac cycle and at several transmural layers. A set of small (1 mm) radiopaque beads was implanted in approximately 1 cm3 of the left ventricular free wall. Using biplane cineradiography, we tracked the motion of these markers through various cardiac cycles. To quantify local myocardial deformation (as revealed by the relative motion of the markers), we calculated the local deformation gradient tensors. As the heart deforms, these describe how any short vectorial line segment alters its length and orientation relative to a reference state. Specifically, by choosing the reference state to be the arrested and fixed heart and by measuring the sarcomere vector in that state, we could then use the deformation gradient tensors to reconstruct the sarcomere vector that would exist in the beating heart. As ventricular chamber volume varied over its normal range of operation, the range of reconstructed sarcomere lengths (approximately 1.7-2.4 microns) was comparable to other histological studies and to measurements of sarcomere length in excised papillary muscles or trabeculae. The pattern of sarcomere length changes was markedly different, however, during ejection vs. filling.

Recombinant soluble CR1 suppressed complement activation, inflammation, and necrosis associated with reperfusion of ischemic myocardium.

In summary, conversion of wild-type CR1 to a soluble form (sCR1) creates a potent inhibitor of complement activation by both the classical and alternative pathways by inhibiting the C3/C5 convertases. In the rat reperfusion infarct model, sCR1 significantly suppresses complement activation at the endothelial surface of capillaries and venules. This suppression of complement activation is accompanied by reduced accumulation of leukocytes within the infarct zone, perhaps because of reduction of the generation of C5a, which promotes expression of leukocyte adhesion receptors and leukocyte chemotaxis. In addition, formation of the C5b-9 attack complex, which may contribute to direct endothelial injury, was suppressed by sCR1. The inhibition of complement activation and leukocyte infiltration by sCR1 explains the observed significant reduction in myocardial necrosis after ischemia and reperfusion. These studies have identified sCR1 as a potential agent for therapeutic intervention in diseases associated with complement-dependent tissue injury.