Vasopressin-induced morphological changes in polarized rat hepatocyte multiplets: dual calcium-dependent effects.

Calcium-mobilizing hormones and neurotransmitters are known to affect cell morphology and function including cell differentiation or division. In this study, we examined vasopressin (AVP)-induced morphological changes in a polarized system of rat hepatocytes. Light and electron microscope observations showed that AVP induced microvilli formation and a remodeling of the isolated hepatocyte F-actin submembrane cytoskeleton, these two events being correlated. We showed that these effects were rapid, reversible, observed at nanomolar AVP concentration and mediated by the V(1a) receptor. On polarized multicellular systems of hepatocytes, we observed a rapid reduction of the bile canaliculi lumen at the apical pole and micovilli formation at the basolateral domain with an enlarged F-actin cytoskeleton. Neither activation of protein kinase C nor A via phorbol ester or dibutyryl cAMP induced such rapid morphological changes, at variance with ionomycin, suggesting that AVP-induced intracellular calcium rise plays a crucial role in those effects. By using spectrofluorimetry and cytochemistry, we showed that calcium release from intracellular stores was involved in bile canaliculus contraction, while calcium entry from the extracellular space controlled microvilli formation. Taken together, AVP and calcium-mobilizing agonists differentially regulate physiological hepatocyte plasma membrane events at the basal and the apical domains via topographically specialized calcium-dependent mechanisms.

Hormone receptor gradients supporting directional Ca2+ signals: direct evidence in rat hepatocytes.

BACKGROUND/AIMS: In the liver, InsP(3)-dependent agonists such as vasopressin and noradrenaline induce tightly coordinated sequences of intracellular Ca(2+) increases, leading to apparent unidirectional Ca(2+) waves. In previous works, we have postulated that cell-to-cell differences in hormone receptor density create a cellular sensitivity gradient that determines which cell initiates the intercellular Ca(2+) wave and the direction of propagation of the Ca(2+) signal. The aim of this study was to test directly this hypothesis. METHODS: Lobular distribution of V1a vasopressin receptors and alpha1 adrenergic receptors were observed by autoradiography in rat liver sections. Cell-to-cell differences in the number of these receptors were evaluated on hepatocyte multiplets using specific fluorescent probes. RESULTS: The relative amount of fluorescence associated with the V1a receptor differed significantly between cells within multiplets. The 'cell-after-cell' Ca(2+) increase induced by vasopressin was correlated with the number of V1a receptors. These observations may be more general, as autoradiography revealed similar lobular distributions of V1a receptors and alpha1 adrenergic receptors; the amounts of both were greatest in hepatocytes surrounding central veins. CONCLUSIONS: These data confirm that a fine gradient along liver cell plates contributes to the molecular basis of the unidirectional hormone-induced Ca(2+) signalling observed in the liver lobule.