Ca2+ dependence of alpha-adrenergic effects on the contractile properties and Ca2+ homeostasis of cardiac myocytes.

alpha-Adrenergic stimulation is known to enhance myocardial contractility. Adult rat left ventricular myocytes bathed in 1 mM [Ca2+] (Ca0) and electrically stimulated at 0.2 Hz responded to alpha-adrenergic stimulation with 50 microM phenylephrine and 1 microM propranolol with an increase in twitch amplitude to 177.

Effects of serosal hypertonicity on water permeability in toad urinary bladder.

We studied in toad urinary bladder the effects of serosal hypertonicity on tissue water permeability, granular cell luminal membrane water permeability, and granular cell luminal membrane particle aggregates and compared them with effects of antidiuretic hormone (ADH). In tissues challenged by a hypertonic (447 mosmol/kgH2O) serosal bath, luminal membrane aggregates were structurally similar to those caused by ADH. The tissue water permeability increase induced by serosal hypertonicity was much less than that caused by a maximally stimulating concentration of ADH on tissue in isotonic serosal baths with approximately the same transmural gradient.

Variability of cellular responsiveness to ADH stimulation in toad urinary bladder.

The hydrosmotic response of toad bladder to antidiuretic hormone (ADH) is quantitatively linked to the induced fusion of aggrephores with, and the appearance of aggregates of tightly packed intramembrane particles in the luminal membrane of granular cells. We used these morphological indexes of hormonally induced cell activation 1) to assess the variability of individual cell responsiveness to a maximally stimulating concentration of ADH and 2) to compare cell response patterns in paired tissues where the extent of whole tissue stimulation, as evidenced by transtissue water flow, was either maximal or submaximal. The results indicate that individual cell responsiveness within the same tissue to standardized maximal ADH treatment varies between two- and sevenfold, depending on the morphological endpoint measured.

Cytochalasin B inhibition of toad bladder apical membrane responses to ADH.

The possible role of actin microfilaments in antidiuretic hormone (ADH)-induced increases in apical membrane water permeability was investigated in studies that evaluate inhibition by cytochalasin B of both permeability and membrane structural responses in the toad urinary bladder. Experiments were carried out in the absence of a transepithelial osmotic gradient to eliminate possible flow-induced distortions of the response. Measurements of osmotic water permeability after a brief tissue fixation with glutaraldehyde show that cytochalasin B reduces the permeability response to ADH by approximately one-third.