Low-voltage-activated (T-type) calcium channels control proliferation of human pulmonary artery myocytes.

While Ca2+ influx is essential for activation of the cell cycle machinery, the processes that regulate Ca2+ influx in this context have not been fully elucidated. Electrophysiological and molecular studies have identified multiple Ca2+ channel genes expressed in mammalian cells. Ca(v)3.x gene family members, encoding low voltage-activated (LVA) or T-type channels, were first identified in the central nervous system and subsequently in non-neuronal tissue. Reports of a potential role for T-type Ca2+ channels in controlling cell proliferation conflict. The present study tested the hypothesis that T-type Ca2+ channels, encoded by Ca(v)3.x genes, control pulmonary artery smooth muscle cell proliferation and cell cycle progression. Using quantitative RT/PCR, immunocytochemistry, and immunohistochemistry we found that Ca(v)3.1 was the predominant Ca(v)3.x channel expressed in early passage human pulmonary artery smooth muscle cells in vitro and in the media of human pulmonary arteries, in vivo. Selective blockade of Ca(v)3.1 expression with small interfering RNA (siRNA) and pharmacological blockade of T-type channels completely inhibited proliferation in response to 5% serum and prevented cell cycle entry. These studies establish that T-type voltage-operated Ca2+ channels are required for cell cycle progression and proliferation of human PA SMC.

Pulmonary hypertension in transgenic mice expressing a dominant-negative BMPRII gene in smooth muscle.

Bone morphogenetic peptides (BMPs), a family of cytokines critical to normal development, were recently implicated in the pathogenesis of familial pulmonary arterial hypertension. The type-II receptor (BMPRII) is required for recognition of all BMPs, and targeted deletion of BMPRII in mice results in fetal lethality before gastrulation. To overcome this limitation and study the role of BMP signaling in postnatal vascular disease, we constructed a smooth muscle-specific transgenic mouse expressing a dominant-negative BMPRII under control of the tetracycline gene switch (SM22-tet-BMPRII(delx4+) mice). When the mutation was activated after birth, mice developed increased pulmonary artery pressure, RV/LV+S ratio, and pulmonary arterial muscularization with no increase in systemic arterial pressure. Studies with SM22-tet-BMPRII(delx4+) mice support the hypothesis that loss of BMPRII signaling in smooth muscle is sufficient to produce the pulmonary hypertensive phenotype.

Tumor necrosis factor-related apoptosis-inducing ligand can induce apoptosis in subsets of premalignant cells.

During the transformation from a normal to a malignant cell, several mutations are required to bypass the pathways responsible for controlling proliferation. Premalignant cells have acquired some, but not all of these mutations and consequently have not yet attained a malignant phenotype characterized by tumor formation in vivo. Tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) can induce apoptosis in malignant cells while sparing normal ones and is currently being considered as adjuvant therapy for various human malignancies. Whether TRAIL is effective in inducing apoptosis in premalignant cells is unclear, however. We studied the effect of TRAIL on two human premalignant cell lines the SV7tert and HA1E cells. Both cell lines had been immortalized by the addition of simian virus 40 large T antigen and the telomerase subunit hTERT, but had not been transformed into malignant cells. TRAIL initiated apoptosis by activating both the mitochondrial-independent and -dependent apoptotic pathways in both cell lines at relatively low doses whereas it had no effect on normal human pulmonary artery smooth muscle cells even at high doses. These results suggest that TRAIL can induce apoptosis in premalignant cells and suggests a novel therapy for the treatment of premalignant lesions in vivo.