Electrical activity in non-neuronal cells can be induced by altering the membrane potential and eliciting action potentials. For example, hormones, nutrients and neurotransmitters act on excitable endocrine cells. In an attempt to correlate such electrical activity with regulation of cell activation, we report here direct measurements of cytosolic free Ca2+ changes coincident with action potentials. This was achieved by the powerful and novel combination of two complex techniques, the patch clamp and microfluorimetry using fura 2 methodology. Changes in intracellular calcium concentration were monitored in single cells of the pituitary line GH3B6. We show that a single action potential leads to a marked transient increase in cytosolic free calcium. The size of these short-lived maxima is sufficient to evoke secretory activity. The striking kinetic features of these transients enabled us to identify oscillations in intracellular calcium concentration in unperturbed cells resulting from spontaneous action potentials, and hence provide an explanation for basal secretory activity. Somatostatin, an inhibitor of pituitary function, abolishes the spontaneous spiking of free cytosolic Ca2+ which may explain its inhibitory effect on basal prolactin secretion. Our data therefore demonstrate that electrical activity can stimulate Ca2+-dependent functions in excitable non-neuronal cells.
Filtered inorganic phosphate (Pi) is largely reabsorbed in the proximal tubule. Na-Pi cotransport, with a stoichiometry of at least 2:1, mediates uphill transport at the apical membrane; at the basolateral membrane different types of transport systems can be involved in efflux and uptake of Pi from the interstitium. Regulation of transcellular Pi flux involves alteration of the apical Na-Pi cotransport; at least three different cellular control/sensing systems seem to participate in this regulation and are exemplified by parathyroid hormone (PTH)-dependent inhibition, Pi deprivation-dependent increase, and insulin-like growth factor I (IGF-I)-dependent increase in Na-Pi cotransport. For PTH inhibition, recent evidence suggests a role of the phospholipase C/protein kinase C-dependent regulatory cascade in inhibition of Na-Pi cotransport, at least at low PTH concentrations. In addition, an endocytic mechanism seems to be involved in this PTH action. Little is known of the cellular mechanisms in Pi deprivation-dependent and/or IGF-I-dependent increases in Na-Pi cotransport; they are dependent on de novo protein synthesis. Recent experiments involving an expression in Xenopus laevis oocytes led to the identification of an approximately 50 kDa membrane protein that is a good candidate for being involved in brush-border membrane Na-Pi cotransport activity.
The cytosolic free calcium concentration, [Ca2+]i, was monitored in single rat lactotrophs in primary culture with the fluorescent probe Fura 2. It was found that lactotrophs are very heterogeneous in their [Ca2+]i response to TRH and dopamine, the major physiological regulators of PRL secretion. While in most lactotrophs TRH raises [Ca2+]i, the kinetics of this rise and the magnitude of its first and second phases vary considerably. For dopamine two clearly divergent response types can be observed. In part of the lactotrophs dopamine causes a lowering of [Ca2+]i from elevated levels, whereas in about 40% of the lactotrophs dopamine leads to a transient rise of [Ca2+]i. The present study reveals subclasses of lactotrophs with distinct [Ca2+]i response characteristics. It is suggested that such response type heterogeneity is a means of optimizing the secretory response to the complex regulatory influences on the pituitary.
Abstract. Endocytic vesicles that are involved in the vasopressin-stimulated recycling of water channels to and from the apical membrane of kidney collecting duct principal cells were isolated from rat renal papilla by differential and Percoll density gradient centrifugation. Fluorescence quenching measurements showed that the isolated vesicles maintained a high, HgCI2-sensitive water permeability, consistent with the presence of vasopressin-sensitive water channels. They did not, however, exhibit ATP-dependent luminal acidification, nor any N-ethylmaleimide-sensitive ATPase activity, properties that are characteristic of most acidic endosomal compartments. Western blotting with specific antibodies showed that the 31-and 70-kD cytoplasmically oriented subunits of the vacuolar proton pump were not detectable in these apical endosomes from the papilla, whereas they were present in endosomes prepared in parallel from the cortex. In contrast, the 56-kD subunit of the proton pump was abundant in papillary endosomes, and was localized at the apical pole of principal cells by immunocytochemistry. Finally, an antibody that recognizes the 16-kD transmembrane subunit of oat tonoplast ATPase crossreacted with a distinct 16-kD band in cortical endosomes, but no 16-kD band was detectable in endosomes from the papilla. This antibody also recognized a 16-kD band in affinity-purified H § ATPase preparations from bovine kidney medulla. Therefore, early endosomes derived from the apical plasma membrane of collecting duct principal cells fail to acidify because they lack functionally important subunits of a vacuolartype proton pumping ATPase, including the 16-kD transmembrane domain that serves as the protonconducting channel, and the 70-kD cytoplasmic subunit that contains the ATPase catalytic site. This specialized, non-acidic early endosomal compartment appears to be involved primarily in the hormonally induced recycling of water channels to and from the apical plasma membrane of vasopressin-sensitive cells in the kidney collecting duct.T HE water permeability of the kidney collecting duct epithelium is regulated by vasopressin-induced recycling of water channels between an intracellular vesicular compartment and the plasma membrane of principal ceils. An analogous mechanism exists in other vasopressinsensitive epithelia such as the toad urinary bladder and the amphibian epidermis (7,25,29,31,60). We have demonstrated recently that these endosomes are specialized intracellular vesicles which are not acidic, and that they appear to function primarily to recycle membrane components, including water channels, back to the apical membrane during hormonal stimulation. Using FITC-dextran as a marker of endocytosis and acidification, coupled with co-localization of a lysosomal glycoprotein, LGP120, our data showed that most of the internalized fluorescent probe does not move into lysosomes and that it remains in an apical, non-acidic compartment (36). The passive proton permeability of these endosomes is not sufficiently different from...
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