Tissue inhibitor of metalloproteinase-4 instigates apoptosis in transformed cardiac fibroblasts.

Tumor cells become malignant, in part, because of their activation of matrix metalloproteinases (MMPs) and inactivation of tissue inhibitor of metalloproteinases (TIMPs). Myocardial tumors are rarely malignant. This raises the possibility that the MMPs and TIMPs are differentially regulated in the heart compared to other tissues. Therefore, we hypothesized that a tissue specific tumor suppressor exists in the heart. To test this hypothesis we prepared cardiac tissue extracts from normal (n = 4), ischemic cardiomypathic (ICM) [n = 5], and dilated cardiomyopathic (DCM) [n = 8] human heart end-stage explants. The level of cardiospecific TIMP-4 was determined by SDS-PAGE and Western-blot analysis. The results suggested reduced levels of TIMP-4 in ICM and DCM as compared to normal heart. TIMP-4 was purified by reverse phase HPLC and gelatin-sepharose affinity chromatography. Collagenase inhibitory activity of chromatographic peaks was determined using fluorescein-conjugated collagen as substrate and fluorescence spectroscopy. The activity of TIMP-4 (27 kDa) was characterized by reverse zymography. The role of TIMP-4 in cardiac fibroblast cell migration was examined using Boyden chamber analysis. The results suggested that TIMP-4 inhibited cardiac fibroblast cells migration and collagen gel invasion. To test whether TIMP-4 induces apoptosis, we cultured cardiac normal and polyomavirus transformed fibroblast cells in the presence and absence of TIMP-4. The number of cells were measured and DNA laddering was determined. The results suggested that TIMP-4 controlled normal cardiac fibroblast transformation and induced apoptosis in transformed cells. Cardiospecific TIMP-4 plays a significant role in regulating the normal cell phenotype. The reduced levels of TIMP-4 elicit cellular transformation and may lead to adverse extracellular matrix degradation (remodeling), cardiac hypertrophy and failure. This study suggests a possible protective role of TIMP-4 in other organs which are susceptible to malignancy.

Responses of vascular smooth muscle cell to extracellular matrix degradation.

Vessels remodel to compensate for increases in blood flow/pressure. The chronic exposure of blood vessels to increased flow and circulatory redox-homocysteine may injure vascular endothelium and disrupt elastic laminae. In order to understand the role of extracellular matrix (ECM) degradation in vascular structure and function, we isolated human vascular smooth muscle cells (VSMC) from normal and injured coronary arteries. The apparently normal vessels were isolated from explanted human hearts. The vessels were injured by inserting a blade into the lumen of the vessel, which damages the inner elastic laminae in the vessel wall and polarizes the VSMC by producing a pseudopodial phenotypic shift in VSMC. This shift is characteristic of migratory, invasive, and contractile nature of VSMC. We measured extracellular matrix metalloproteinases (MMPs), tissue plasminogen activator (tPA), tissue inhibitor of metalloproteinase (TIMP), and collagen I expression in VSMC by specific substrate zymography and Northern blot analyses. The injured and elastin peptide, val-gly-val-ala-pro-gly, treated VSMC synthesized active MMPs and reduced expression of TIMP. The level of tPA and collagen type I was induced in the injured, invasive VSMC and in the val-gly-val-ala-pro-gly treated cells. To demonstrate the angiogenic role of elastin peptide to VSMC we performed in vitro organ culture with rings from normal coronary artery. After 3 days in culture the vascular rings in the collagen gel containing elastin peptide elaborated MMP activity and sprouted and grew. The results suggest that val-gly-val-ala-pro-gly peptide generated at the site of proteolysis during vascular injury may have angiogenic activity.

The interactive effects of cocaine/gender on immune function in mice. An observation of in vivo acute cocaine exposure.

The present experiments used a mouse model including both sexes to study the impact of acute cocaine exposure on the function of four major immunocompetent cell types (T, B cells, NK, and macrophages). Cocaine hydrochloride, 5 mg or 40 mg/kg, was administrated by i.p. injection to C57BL/6 mice. Thymocytes and splenocytes were obtained 24 h after injection. Acute in vivo cocaine exposure inhibited the proliferation of T lymphocytes in response to Con-A in both thymocytes and splenocytes. However, the attenuated IL-2 production was only seen in thymocytes. These effects on T cells were greater in male mice than in female mice. The function of macrophages was also impaired by acute cocaine exposure; however, the impact was greater in female than in male mice. In conclusion, the effects of acute cocaine exposure altered the functions of immunocompetent cells and the effects varied with gender.