Transforming growth factor beta 1 (TGF-beta 1) decreased the rate of proliferation of rat aortic vascular smooth muscle cells (VSMCs) stimulated with serum showing a maximal effect at > 5 ng/ml (200 pM). However, it did not reduce the proportion of cells which passed through S phase (> 90%) and entry into S phase was delayed by less than 3 h. The proportion of cells passing through M phase (> 90%) was also unaffected, but entry into mitosis was delayed by approx. 24 h. This increase in cell cycle time was therefore due mainly to an increase in the G2 to mitotic metaphase period. Addition of TGF-beta 1 late in G1 or late in S phase failed to delay the onset of mitosis, but the presence of TGF-beta 1 between 0 and 12 h after the addition of serum to quiescent cells was sufficient to cause the maximal delay in mitosis of approx. 24 h. The role of cyclic AMP in the mechanism of the TGF-beta 1 effects on the cell cycle was examined. Entry into mitosis was preceded by a transient 2-fold increase in cyclic AMP concentration and TGF-beta 1 delayed both this increase in cyclic AMP and entry into mitosis to the same extent. Addition of forskolin or 8-(4-chlorophenylthio)-cyclic AMP to cells 30 h after stimulation with serum completely reversed the increase in duration of G2 in the presence of TGF-beta 1, suggesting that the rise in cyclic AMP levels which precedes mitosis might trigger entry of the VSMCs into M phase. Addition of forskolin late in S phase (26 h after stimulation with serum) advanced the entry of the cells into M phase and they divided prematurely. This effect was unaffected by the addition of cycloheximide with the forskolin; however, the effect of forskolin on cell division was completely inhibited when cycloheximide was added late in G1. TGF-beta 1 prevented the loss of smooth-muscle-specific myosin heavy chain (SM-MHC), which occurs in primary VSMC cultures in the presence or absence of serum, and the cells proliferated while maintaining a differentiated phenotype. However, TGF-beta 1 did not cause re-differentiation of subcultured VSMCs which contained very low amounts of SM-MHC and the effect of TGF-beta 1 in extending the G2 phase of the cell cycle is exerted independently of its effect on differentiation.
We investigated the mechanisms by which spontaneously beating cultured rat ventricular cells regulate intracellular pH (pHi). Specifically, the relative contributions of the Na+/H+ antiport, Cl-/HCO3- exchange, ATP, and calmodulin-dependent processes in regulating the pHi of cells loaded with the intracellular fluorescent pH indicator BCECF were investigated. The pHi of ventricular cells bathed in HEPES-buffered medium averaged 7.30 +/- 0.02. Subsequent exposure of the cells to CO2-HCO3- -buffered medium resulted in intracellular acidification followed by recovery to pHi levels approximately 0.1 pH units lower than in controls. Recovery was inhibited by the Na+/H+ antiport inhibitor 5-(N-ethyl-N-isopropyl)amiloride (EIPA). The recovery from intracellular acidification, induced by a 15-mM ammonium chloride prepulse, was also dependent solely upon activation of the Na+/H+ antiport. Recovery was dependent upon extracellular sodium, was completely inhibited by EIPA, and could be modulated by changes in extracellular pH (pHo). At low pHo values (6.3) the recovery of pHi was greatly attenuated, while at high pHo (8.0) the recovery process was accelerated. The final pHi to which the cells recovered was also dependent upon pHo. Preincubation of the cells with 2-deoxy-D-glucose to deplete cellular ATP levels reduced pHi by approximately 0.2 pH units and greatly impaired the cells' ability to recover from 15-mM ammonium chloride-induced acid load. Similarly, preincubation of cells with the calmodulin inhibitors W-7 and trifluoperazine also impaired their ability to recover from the acid load. The Cl- -HCO3- exchange played no role in the cells' ability to recover from intracellular acidosis. However, the presence of HCO3- significantly increased the resistance of myocardial cells to changes in pHi by approximately doubling their buffer capacity. These results demonstrated that a Na+/H+ antiport is the major pHi-regulating system in spontaneously beating rat ventricular cells. The ability of the Na+/H+ antiport to regulate myocardial pHi is dependent upon the cells' ability to maintain adequate levels of ATP. The antiport's dependency on ATP, in conjunction with its dependency on calmodulin, suggests that activation of the antiport in ventricular cells involves phosphorylation processes.
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