Voltage-dependent activation and inactivation of calcium channels in PC12 cells. Correlation with neurotransmitter release

The existence and mechanisms of inactivation of voltage-gated Ca2+ channels are important, but still debatable, physiological problems. By using the Ca2+ indicators quin2 and fura-2, we demonstrate that in PC12 cells voltage-gated Ca2+ channels undergo inactivation dependent on both voltage and [Ca2+]i. Inactivation, however, is never complete and a small number of channels remains open during prolonged depolarization, explaining the steady state elevation of [Ca2+]i observed in cells depolarized with high KCl. A close parallel exists between Ca2+ channel inactivation and the transient nature of neurotransmitter release: secretion is rapidly stimulated during the first 30 s of depolarization, when a transient overshoot in [Ca2+]i can be demonstrated, while it is negligible during the following period, despite the persistence of an elevated [Ca2+]i; predepolarization in Ca2+-free medium and subsequent addition of Ca2+ (a condition which allows the development of the voltage inactivation) abolishes the fast phase of secretion, while not modifying the steady state [Ca2+]i eventually attained; and increases in the intracellular Ca2+ buffering decreases the amplitude of the fast secretion phase induced by KCl without altering the steady state [Ca2+]i. We suggest that localized [Ca2+]i gradients form close to the plasma membrane shortly after depolarization and that the [Ca2+]i reached in these regions is the relevant parameter in the regulation of secretion.     

Regulation of glucose transport by insulin, bombesin, and bradykinin in Swiss 3T3 fibroblasts: involvement of protein kinase C-dependent and -independent mechanisms

Glucose transport stimulation by insulin, bombesin, and bradykinin in Swiss 3T3 fibroblasts was compared with the phosphoinositide hydrolysis effects of the same stimulants in a variety of experimental paradigms known to affect generation and/or functioning of intracellular second messengers: short- and long-term treatments with phorbol dibutyrate, that cause activation and down-regulation of protein kinase C, respectively; cell loading with high [quin2], that causes clamping of [Ca2+]i near the resting level; poisoning with pertussis toxin, that affects the GTP binding proteins of the Go/Gi class; treatment with Ca2+ ionophores. Glucose transport stimulation by maximal [insulin] was affected by neither pertussis toxin nor protein kinase C down-regulation. The latter, however, partially blocked the action of suboptimal [insulin]; moreover, acute phorbol dibutyrate treatment caused responses more than additive at all [insulin]. Thus, the insulin action on glucose transport in 3T3 cells appears to be synergistically potentiated by a protein kinase C-dependent mechanism, and not directly mediated by the enzyme. This result correlates with the lack of effect of insulin on phosphoinositide hydrolysis. In contrast, part of the glucose transport responses induced by bombesin and bradykinin appeared to be mediated by protein kinase C in proportion with the stimulation induced by these peptides on the phosphoinositide hydrolysis. The protein kinase C-independent portion of the response to bradykinin was found to be inhibitable by pertussis toxin. This latter result might suggest an interaction between the bradykinin receptor and a glucose transporter, mediated by a protein of the Go/Gi class.     

Calcium channels in undifferentiated PC12 rat pheochromocytoma cells

Undifferentiated rat pheochromocytoma PC12 cells were voltage clamped using the whole cell technique. After blockade of outward currents, calcium currents were elicited from -40 and -100 mV. A subpopulation of cells displayed only one current component activated at -10 mV and slowly decaying. In other cells this current coexisted with a component activated around -40 mV and decaying with a faster time constant. We conclude that undifferentiated PC12 cells can express two types of calcium channels, L (long-lasting) and N (neuronal)-type channels.     

Intracellular Ca2+ stores in neurons. Identification and functional aspects.

Various aspects of the rapidly exchanging intracellular Ca2+ stores of neurons and nerve cells are reviewed: their multiplicity, with separate sensitivity to either the second messenger, inositol 1,4,5-trisphosphate, or ryanodine-caffeine (the latter stores are probably activated via Ca(2+)-induced Ca2+ release); their control of the plasma membrane Ca2+ permeability, via the activation of a peculiar type of cation channels; their ability to sustain localized heterogeneities of the [Ca2+]i that could be of physiological key-importance. Finally, the molecular composition of these stores is discussed. They are shown (by high resolution immunocytochemistry and subcellular fractionation) to express: i) a Ca2+ ATPase responsible for the accumulation of the cation; ii) Ca2+ binding protein(s) of low affinity and high capacity to keep Ca2+ stored; and iii) a Ca2+ channel, activated by either one of the mechanisms mentioned above, to release Ca2+ to the cytosol. Results obtained in Purkinje neurons document the heterogeneity of the stores and the strategical distribution of the corresponding organelles (calciosomes; specialized portions of the ER) within the cell body, dendrites and dendritic spines.     

PDGF-induced receptor phosphorylation and phosphoinositide hydrolysis are unaffected by protein kinase C activation in mouse Swiss 3T3 and human skin fibroblasts

Short (1-10 min) pretreatment of intact cells with activators of protein kinase C (e.g. phorbol-12 myristate, 13-acetate, PMA) affects the activity of a variety of surface receptors (for growth factors, hormones and neurotransmitters), with inhibition of transmembrane signal generation. In two types of fibroblasts we demonstrate that the PDGF receptor is unaffected by PMA. Exposure to PMA at concentrations up to 100 nM for 10 min failed to inhibit either one of the agonist-induced, receptor-coupled responses of PDGF: the autophosphorylation of receptor molecules at tyrosine residues, and the hydrolysis of membrane polyphosphoinositides. In contrast, the EGF receptor autophosphorylation (in A 431 cells) and the bombesin-induced phosphoinositide hydrolysis were readily inhibited by PMA. Feed-back inhibition of surface receptors by protein kinase C-mediated phosphorylation is therefore not general, and cannot be the only process responsible for the attenuation of receptor-mediated responses in eukaryotic cells.     

COMPOSITION OF CELLULAR MEMBRANES IN THE PANCREAS OF THE GUINEA PIG : II. Lipids

The lipid composition of rough and smooth microsomal membranes, zymogen granule membranes, and a plasmalemmal fraction from the guinea pig pancreatic exocrine cell has been determined. As a group, membranes of the smooth variety (i.e., smooth microsomes, zymogen granule membranes, and the plasmalemma) were similar in their content of phospholipids, cholesterol and neutral lipids, and in the ratio of total lipids to membrane proteins. In contrast, rough microsomal membranes contained much less sphingomyelin and cholesterol and possessed a smaller lipid/protein ratio. All membrane fractions were unusually high in their content of lysolecithin (up to ~20% of the total phospholipids) and of neutral lipids, especially fatty acids. The lysolecithin content was shown to be due to the hydrolysis of membrane lecithin by pancreatic lipase; the fatty acids, liberated by the action of lipase on endogenous triglyceride stores, are apparently scavenged by the membranes from the suspending media. Similar artifactually high levels of lysolecithin and fatty acids were noted in hepatic microsomes incubated with pancreatic postmicrosomal supernatant. E 600, an inhibitor of lipase, largely prevented the appearance of lysolecithin and fatty acids in pancreatic microsomes and in liver microsomes treated with pancreatic supernatant.     

Rapidly exchanging Ca2+ stores: Role in the control of Ca2+ homeostasis and [Ca2+] in oscillations

The rapidly exchanging intracellular calcium stores play an important role in control of cytoplasmic calcium homeostasis and in generation of intracellular calcium signals. These stores are specific intracellular compartments which are able to accumulate and release calcium in response to appropriate stimuli. Two types of stores can be distinguished in nonmuscle cells based on substances discharging these stores: (1) Ca²⁺-sensitive and (2) inositol-1,4,5-trisphosphate-sensitive intracellular depots. These two depots can be either separate intracellular compartments or a single compartment that shares both releasing mechanisms. The state of the art of our understanding of the cytoplasmic calcium release is the focus of this review.Neirofiziologiya/Neurophysiology, Vol. 26, No. 1, pp. 9–15, January–February, 1994.     

Neurotransmitter release: fusion or 'kiss-and-run'?

The clear synaptic vesicles of neurons release their contents at the presynaptic membrane and are then quickly retrieved. However, it is unclear whether a complete cycle of exocytosis and endocytosis is always involved or whether neurotransmitter can be released by a transient interaction. Recent findings in chromaffin and mast cells suggest that exocytosis is preceded by the formation of a pore that has similar conductance properties to ion channels. The content of the secretory organelle partially escapes at this early step, but the pore can close before the vesicle fuses fully. This article looks at the evidence that quantal release of neurotransmitter from clear synaptic vesicles may occur by a similar 'kiss-and-run' mechanism.     

The control of Ca2+ homeostasis: role of intracellular rapidly exchanging Ca2+ stores.

The role of rapidly exchanging intracellular Ca²⁺ stores in the control of Ca²⁺ homeostasis is reviewed. The following issues are discussed: the reasons why such stores exist in eukaryotic cells; the differences between the terminal cisternae of the skeletal muscle sarcoplasmic reticulum, which have direct, physical connection with the T tubules of the plasmalemma, and the Ca²⁺ stores located in the depth of the cytoplasm, which are stimulated by second messengers; the cytological nature (subcompartments of the ER) of the rapidly exchanging Ca²⁺ stores and their functional significance. The conclusions introduce recent developments in which intracellular Ca²⁺ stores have been investigated also by molecular biology techniques.