Role of the NO-cGMP cascade in regulation of L-type Ca2+ currents in isolated cardiomyocytes

Regulatory mechanisms of voltage-dependent L-type Ca²⁺ channels involving the cyclic nucleotide system of mammalian cardiomyocytes have been studied. Activation of cGMP-dependent phosphorylation in the presence of 1 mM arginine in all experimental media resulted in inhibition of amplitudes of basal L-type Ca²⁺ currents in rat ventricular myocytes. Effects of compounds regulating the activity of different compoments of the NO-cGMP cascade on L-type Ca²⁺ currents were investigated. It was found that endogenous (arginine, 5 mM) and exogenous (sodium nitroprusside, 1 mM) NO sources decreased the Ca²⁺ current amplitude by 30 ± 10%. The nonspecific NO synthase blocker 7NI (2 μM) abolished the effect of arginine, while the soluble guanylyl cyclase blocker ODQ (50 μM) eliminated the effects of both arginine and sodium nitroprusside. The fact that inhibitory effects of arginine, sodium nitroprusside and 8Br-cGMP disappeared in the presence of the protein kinase G blocker KT5823 (0.5, 1 μM) provides direct evidence in favor of activating effect of these compounds on PKG-dependent phosphorylation. Inhibition of L-type Ca²⁺ currents can also be due to activation of phosphodiesterase II. However, the selective phosphodiesterase II blocker EHNA (30 μM) failed to abolish inhibitory effects of arginine and sodium nitroprusside on Ca²⁺ currents. Isoproterenol (0.1 μM)-activated L-type Ca²⁺ currents were only partly blocked by acetylcholine (0.1 mM). Contrary to basal currents, the NO-cGMP cascade agonists arginine and sodium nitroprusside (SNP), like 8Br-cGMP, had no effect on isoproterenol-induced currents. Full inhibition of isoproterenol-induced currents was achieved through combination of acetylcholine with NO-cGMP cascade agonists.     

Comparative analysis of the kinetic characteristics of L-type calcium channels in cardiac cells of hibernators.

An undefined property of L-type Ca2+ channels is believed to underlie the unique phenotype of hibernating hearts. Therefore, L-type Ca2+ channels in single cardiomyocytes isolated from hibernating versus awake ground-squirrels (Citellus undulatus) were compared using the perforated mode of the patch-clamp technique, and interpreted by way of a kinetic model of Ca2+ channel behavior based upon the concept of independence of the activation and inactivation processes. We find that, in hibernating ground-squirrels, the cardiac L-type Ca2+ current is lower in magnitude when compared to awake animals. Both in the awake or hibernating states, kinetics of L-type Ca2+ channels could be described by a d2f1(2)f2 model with an activation and two inactivation processes. The activation (or d) process relates to the movement of the gating charge. The slow (or f1) inactivation is associated with movement of gating charge and is current-dependent. The rapid (or f2) inactivation is a complex process which cannot be represented as a single-step conformational transition induced by the gating charge movement, and is regulated by beta-adrenoceptor stimulation. When compared to awake animals, the kinetic properties of Ca2+ channels from hibernating ground-squirrels differed in the following parameters: (1) pronounced shift (15-20 mV) toward depolarization in the normalized conductance of both inactivation components, and moderate shift in the activation component; (2) 1.5-2-fold greater time constants; and (3) two-fold greater activation gating charge. Thus, L-type Ca2+ channels apparently switch their phenotype during the hibernating transition. Stimulation of beta-adrenoceptors by isoproterenol, reversed the hibernating kinetic- (but not amplitude-) phenotype toward the awake type. Therefore, an aberrance in the beta-adrenergic system can not fully explain the observed changes in the L-type Ca2+ current. This suggests that during hibernation additional mechanisms may reduce the single Ca2+ channel-conductance and/or keep a fraction of the cardiac L-type Ca2+ channel population in a non-active state.     

Effect of avermectns on Ca(2+)-dependent chloride currents in plasmalemma of Chara corallina cells]

A natural complex of avermectins, aversectin C, and a component of this complex, avermectin A1, were shown to change the conductivity of Ca(2+)-dependent chloride channels of plasmalemma of Chara corallina cells by acting only from the outer side of the cellular membrane. Low concentrations of aversectin C and avermectin A1 increased the chloride current: K1/2 = 3.5 x 10(-5) mg/ml for the whole complex and K1/2 = 2.1 x 10(-3) mg/ml for A1. Relatively high concentrations of the compounds suppressed the chloride current: K1/2 = 2.2 x 10(-3) mg/ml for aversectin C and K1/2 = 4.2 x 10(-6) mg/ml for A1. The Hill coefficients for the interaction of avermectin A1 with the corresponding targets for stimulation and suppression of the chloride current were 2.8 and 2.5 respectively. Bicuculine, a non-specific inhibitor of the GABA alpha-receptors, did not influence stimulation of chloride currents caused by action of low concentrations of avermectins, but at the same time blocked suppression of the chloride currents associated with the action of high doses of avermectins. Avermectins A2, B1 (abamectin), B2 and 22,23-dihydroavermectin B1 (vermectin) in the concentration range studied, did not affect the chloride currents of Chara corallina cells.     

Selective cytostatic and cytotoxic effects of avermectins]

A natural avermectin complex, aversectin C, was shown to be capable of exerting selective cytostatic effect. It killed proliferating neuroblastoma B 103 cells but was non-toxic for differentiated cells of this culture. The activity of aversectin C was related neither to activation of the GABA alpha-receptors nor to their blocking and was at a large extent due to the action of avermectin A1, a component of aversectin C.     

The paradoxically high reactivity of septal neurons in hibernating ground squirrels to endogenous neuropeptides is lost after chronic deafferentation of the septum from the preopticohypothalamic areas

The effect of neuropeptides (TSKYR, TSKY and DY) and neurotransmitters (serotonin and noradrenaline) on the activity of medial septum (MS) neurons from the brain of summer wakening ground squirrels (WGS), hibernating ground squirrels (HGS), and hibernating ground squirrels with the undercut septum (UHGS) was studied. It was shown that in HGS, the neuropeptides were substantially more effective in modulating the spontaneous activity of MS neurons than in WGS. The undercutting of MS led to the disappearance of the increased responsiveness to the neuropeptides: in UHGS, neuropeptide-induced changes in the spontaneous activity became nearly identical to those in WGS. The decrease in MS responsiveness in UHGS is due mainly to pacemaker neurons, which cease to respond to the peptides. It was shown that the neuropeptides have a dual effect: they change the level of spontaneous activity through direct modulation of pacemaker potential and control responses to electrical stimulation by modulating the synaptic transmission. Contrary to neuropeptides, neurotransmitters were highly effective in neurons of all groups of animals. Presumably, the enhanced excitability of MS during hibernation, which is necessary for performing the 'sentry post' function, is formed under the influence of the preopticohypothalamic area, and this influence is mediated by peptides.     

The regulation of L-type Ca2+ currents in cardiac myocytes of hibernating animals

The action of isoproterenol and BAY K 8644 on voltage-dependent Ca2+ currents in isolated ground squirrel cardiac myocytes was studied in two (active and hibernating) states of the animal. In cardiac myocytes of active animals the effect of both drugs was shown to depend on the holding potential. At Vh of about -50 mV both isoproterenol and BAY K 8644 increased the Ca2+ current and their action was additive. At Vh of about -20 mV, both drugs inhibited the Ca2+ current. In cardiac myocytes from hibernating animals, isoproterenol increased the Ca2+ current at any holding potentials, while the effect of BAY K 8644 did not differ significantly from its effect on active animals. The combined action of the two drugs caused the inhibition of the Ca2+ current at high holding potentials. In terms of the two-site Ca2+ channel model, this means that one of the two pathways of channel phosphorylation is blocked in hibernating animal cardiac cells, and BAY K 8644 restores this pathway.     

Two modes of longe-range orientation of DNA bases realized upon compaction.

Formation of compact particles from linear DNA-anthracycline complexes is accompanied by appearance of intense bands in the CD spectra in the region of absorption of DNA bases (UV-region) and in the region of absorption of anthracycline chromophores (visible region). The intense (positive or negative) bands in the region of anthracycline absorption demonstrate an ordered helical location of anthracycline molecules on the DNA template. This fact, in its turn, is related to formation of the DNA superstructure in PEG-containing water-salt solutions with a long-range orientation of nitrogen bases. Possible types of DNA superstructures and the relation between the local- and the long-range order of bases in the DNA superstructure are discussed.     

Selective Cytostatic and Neurotoxic Effects of Avermectins and Activation of the GABAα Receptors

A natural avermectin complex, aversectin C, was shown to be capable of exerting selective cytostatic and neurotoxic effects on mammalian cells. Specifically, it killed proliferating neuroblastoma B103 cells but was non-toxic for differentiated cells of this culture. The anti-proliferation action of aversectin C was not inhibited by bicuculline or picrotoxin, antagonists of the GABA receptors, and was partly due to the action of avermectin A₁, a component of aversectin C. Aversectin C irreversibly suppressed activity of 60% neurons in medial septal slices of the rat brain. More than 55% of them were the GABA- and B₁-sensitive neurons whereas the rest, about 45% neurons, were the GABA-insensitive and the neurotoxic effect of aversectin C was caused mainly by the B₂ component.