297Osteoglycin regulates cardiac fibrosis in the pressure-overloaded heart

Hypertension and/or aging impose stress on the heart with consecutive cardiac hypertrophy, inflammation and fibrosis, processes that lead to heart failure. Our group has previously shown that non-structural matrix proteins such as TSP-2 and SPARC are critical during hypertension, fibrosis, and age-related cardiac dysfunction. Osteoglycin (OGN) is a class III member of the small leucine rich proteoglycans, and was recently identified as a marker of increased left ventricular mass in a study using genomics in recombinant inbred hypertensive rat strains. Its precise biological role in cardiac remodeling, however, remains unclear. We hypothesize that OGN will influence cardiac hypertrophy and fibrosis and hence is critical in the cardiac response during hypertension and aging. We show in young adult mice (3 months old) that hypertension-induced pressure overload of the heart causes two phases of cardiac fibrosis, following 28 days of angiotensin-II (AngII) infusion. The first phase develops between days 3 to 7 after the AngII-treatment and consists of diffuse interstitially deposited loose fibers. During the second wave of fibrosis, which starts at 14 days, these loose fibers transition into more localized scars of denser collagens. Interestingly, the expression of OGN mRNA also shows a biphasic response, significantly decreasing prior to each phase of fibrosis, at day 1 (96% decrease, p=0.002) and day 14 (84% decrease, p=0.004) respectively. Moreover, hypertension causes exaggerated cardiac fibrosis (7.54±1.58 vs. 3.65±0.62 %, p=0.04) and increased heart weight to body weight ratios (6.39±0.31 vs. 5.42±0.17 mg/g, p=0.01) in young adult OGN null mice when compared to WT littermates, but no differences in the amount of infiltrating leukocytes (31.48±9.82 vs. 36.32±18.75 cells/mm2), after 28 days of AngII infusion. In addition, aging results in decreased cardiac function, as measured by ejection fraction, in 18 months versus 3 months old OGN null mice (42.65±2.74 vs. 58.05±1.37 %, p=0.0001), which is absent in WT mice (51.01±3.11 vs. 53.01±1.67 %, p=0.62). Furthermore, a follow-up study in WT and OGN null mice showed a decrease in stroke volume over time in the OGN null mice (39.30±2.90 μl at 6 months, 35.54±1.95 μl at 12 months and 31.13±1.29 μl at 18 months, p=0.04 between 6 and 18 months) but not in the WT mice (41.61±2.02 μl at 6 months, 39.04±1.95 μl at 12 months and 41.04±3.05 μl at 18 months). Collectively, these data suggest that OGN regulates cardiac fibrosis during pressure overload and is therefore important in the remodeling response to hypertension and aging.