ω-Phonetoxin-IIA: a calcium channel blocker from the spider Phoneutria nigriventer.

A peptide with neurotoxic effect on mammals, purified from the venom of the spider Phoneutria nigriventer, was studied regarding its primary structure and its effects on voltage-gated calcium channels. The peptide, named ω-phonetoxin-IIA, has 76 amino acids residues, with 14 Cys forming 7 disulphide bonds, and a molecular weight of 8362.7 Da. The neurotoxicity is a consequence of the peptide's blocking effects on high-voltage-activated (HVA) calcium channels. N-type HVA calcium channels of rat dorsal root ganglion neurons are blocked with affinity in the sub-nanomolar concentration range. The toxin also blocks L-type channels of rat ß pancreatic cells, with an affinity 40 times lower. Although not studied in detail, evidence indicates that the toxin also blocks other types of HVA calcium channels, such as P and Q. No effect was observed on low-voltage-activated, T-type calcium channels. The significant homologies between ω-phonetoxin-IIA and the peptides of the ω-agatoxin-III family, and the overlapping inhibitory effects on calcium channels are discussed in terms of the structure-activity relationship.

Mechanisms and regulation of H+ transport in distal tubule epithelial cells.

The mechanism of acidification in the cortical distal tubule of mammalian kidney was analysed by "in vivo" microperfusion and using MDCK cells in culture, by electrophysiological and by cell pH microfluorescence techniques. An electrogenic effect of the vacuolar H(+)-ATPase, which has been localized to the intercalated cells of the cortical distal tubule (connecting segment and initial collecting duct) was only observed after blocking Cl- channels by NPPB. In MDCK cells, the recovery of cell pH after an acid pulse in Na(+)-free medium was also depressed by NPPB, indicating that Cl- ions have an important role in the function of H+ ATPase. The regulation by hormonal agents of distal H+ transport due to Na+/H+ exchange and to vacuolar H+ ATPase, was also studied by microperfusion and cell pH techniques. Angiotensin and vasopressin at picomolar concentrations stimulated both transport mechanisms in late distal tubule, and only Na+/H+ exchange in the early segment. In MDCK cells, cell pH recovery in the presence of Na+ was stimulated by picomolar concentrations of angiotensin and vasopressin, and inhibited by micromolar levels, both effects being reverted by micromolar ANP. Studies with specific antagonists suggest that the luminal effect of angiotensin is mediated by AT1 receptors, and of vasopressin by V1 receptors. There is evidence that cell Ca2+ may have an important regulatory role in the action of these hormones.

Role of Cl- in electrogenic H+ secretion by cortical distal tubule.

The presence of an electrogenic H+-ATPase has been described in the late distal tubule, a segment which contains intercalated cells. The present paper studies the electrogenicity of this transport mechanism, which has been demonstrated in turtle bladder and in cortical collecting duct. Transepithelial PD (Vt) was measured by means of Ling-Gerard microelectrodes in late distal tubule of rat renal cortex during in vivo microperfusion. The tubules were perfused with electrolyte solutions to which 2 x 10(-7) M bafilomycin or 4.6 x 10(-8) M concanamycin were added. No significant increase in lumen-negative Vt upon perfusion with these inhibitors as compared to control, was observed as well as when 10(-3) m amiloride, 10(-5) M benzamil or 3 mM Ba2+ were perfused alone or in combination. The effect of an inhibition of electrogenic H+ secretion, i.e., increase in lumen-negative Vt by 2-4 mV, was observed only when Cl- channels were blocked by 10(-5) M 5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB). This blocker also reduced the rate of bicarbonate reabsorption in this segment from 1.21 +/- 0.14 (n = 8) to 0.62 +/- 0.03 (8) nmol.cm-2.sec-1 as determined by stationary microperfusion and pH measurement by ion-exchange resin microelectrodes. These results indicate that: (i) the participation of the vacuolar H+ ATPase in the establishment of cortical late distal tubule Vt is minor in physiological conditions, but can be demonstrated after blocking Cl- channels, thus suggesting a shunting effect of this anion; and, (ii) the rate of H+ secretion in this segment is reduced by a Cl- channel blocker, supporting coupling of H+-ATPase with Cl- transport.

Use of neurotoxins to study Ca2+ channel functions.

The article contains a brief review on the properties and classification of voltage-dependent Ca2+ channels and on the organic blockers of the different channel types. The effects of peptide toxins from the venoms of Conus sp and of the spider Agelenopsis aperta on high voltage-activated Ca2+ channels are discussed. In addition, we present preliminary data on a novel peptide toxin purified from the venom of the spider Phoneutria nigriventer, which is a powerful blocker of L- and N-type Ca2+ channels.

Use of neurotoxins to study Ca2+ channel functions

The article contains a brief review on the properties and classification of voltage-dependent Ca2+ channels and on the organic blockers of the different channel types. The effects of peptide toxins from the venoms of Conus sp and of the spider Agelenopsis aperta on high voltage-activated Ca2+ channels are discussed. In addition, we present preliminary data on a novel peptide toxin purified from the venom of the spider Phoneutria nigriventer, which is a powerful blocker of L-and N-type Ca2+ channels.

Effect of crude extract of roots of Bredemeyera floribunda Willd. I. Effect on arterial blood pressure and renal excretion in the rat.

The infusion of the dried roots of Bredemeyera floribunda Willd. is used in Brazilian popular medicine as a potent diuretic, especially in the treatment of hypertension and nephrolithiasis (renal calculi). Intravenous administration of crude root-extract (20-80 mg/kg) to anesthetized rats induces clear dose-dependent and reversible hypotensive responses. At higher doses the extract leads to bradycardia and death. In doses that do not alter the arterial blood pressure, the extract elicited immediate and dose-dependent reversible increase of water, sodium, and potassium renal excretion. The results, apart from indicating that the renal effect of the extract is not due to its systemic hypotensive action, support the folk therapeutic use of the infusion of the root-extract as a diuretic.

Vasopressin increases density of apical low-conductance K+ channels in rat CCD.

The effect of arginine vasopressin (AVP) on the low-conductance K+ channel in the apical membrane of rat cortical collecting duct (CCD) principal cells from animals on a control and high-K+ diet was studied using patch-clamp techniques. AVP stimulated apical low-conductance K+ channel activity in both control and high-K+ animals: application of 110-220 pM AVP induced a significant increase in the density of low-conductance K+ channels. In the presence of phosphodiesterase inhibitor (3-isobutyl-1-methylxanthine), administration of 22 pM AVP also increased channel activity. The action of AVP on low-conductance K+ channel activity was mimicked by simultaneous application of forskolin and 3-isobutyl-1-methylxanthine. Exogenously applied N6,2'-O-dibutyryladenosine 3',5'-cyclic monophosphate (dibutyryl-cAMP, 0.4-0.8 mM) also increased apical low-conductance K+ channel activity. Since channel open probability (Po) was almost saturated in the absence of AVP, the increase of channel activity induced by AVP, forskolin, and dibutyryl-cAMP resulted predominantly from stimulating previously silent K+ channels. We conclude that AVP induces an increase of low-conductance K+ channel activity of principal cells in rat CCD by the stimulation of cAMP-dependent protein kinase. The AVP-induced increase of low-conductance K+ channel activity can thus significantly contribute to the hormone-induced K+ secretion in the rat CCD.

Bicarbonate reabsorption and electrophysiology of proximal tubules in uninephrectomized rats.

1. The kinetics of acidification of luminal fluid in hypertrophied proximal tubules after unilateral nephrectomy was studied by stationary microperfusion and continuous measurement of luminal pH with antimony microelectrodes. 2. Trans-epithelial and basolateral membrane electrical potential differences were measured in order to detect modifications in electrogenic transport mechanisms under these conditions. 3. The values of stationary pH and HCO3- concentration were significantly lower, the mean acidification half-time was not different and net reabsorptive HCO3- fluxes in proximal tubules were significantly increased in uninephrectomized rats. According to an electrical analogue model, these results suggest (a) a reduction in the internal series resistance of the H+ pump, caused perhaps by an increased density of pump sites, and (b) an increase in the protonmotive force of the pump. 4. The trans-epithelial electrical potential difference measured in free flow conditions was significantly more lumen-positive in uninephrectomized rats. The trans-epithelial electrical potential difference measured during intraluminal perfusion with Ringer solution containing 30 mmol/l HCO3- was significantly more negative in all groups studied. In uninephrectomized rats treated with acetazolamide, the trans-epithelial electrical potential difference was more lumen-negative than that in untreated uninephrectomized rats. These results are compatible with a steeper transepithelial Cl- gradient as well as with electrogenic, active H+ secretion. 5. There was no significant difference in the basolateral electrical potential difference between control and uninephrectomized rats. 6. In conclusion, our data show an increase in the transport rates of HCO3- in the proximal tubule of uninephrectomized rats, which may be due to an increase in the density of transporters in the brush-border membrane, and an increased ability of the transport mechanism to create H+ gradients.

Lack of osmoregulation in Aplysia brasiliana: correlation with response of neuron R15 to osphradial stimulation.

The exposure of Aplysia brasiliana to dilute seawater (90 and 80%) caused an increase of the relative weight, which returned to the original values after a few hours. Both osmotic and chloride concentrations of the hemolymph decreased on exposure to 80 and 90% dilute seawater, and after 3-h exposure there were no differences between the hemolymph and external media osmotic and chloride concentrations. In contrast to the clear regulatory capabilities reported for A. californica, A. brasiliana cannot maintain the osmolality of its body fluid in dilute media. In A. californica, osphradial receptors and neuron R15 are apparently involved in this regulatory mechanism. Perfusion of osphradium of A. brasiliana with dilute seawater (95-80%) did not affect electrical activity of the bursting neuron R15; perfusion with 70 and 60% seawater caused a transient increase in the duration of the quiescent period. In contrast to the model established for A. californica, in A. brasiliana no relationship was found between exposure of the osphradium to dilute media and electrical activity in neuron R15, which is in accordance with the lack of an osmoregulatory mechanism in this species. Such differences may reflect inherent differences in salinity tolerance between the two species.

pH-stat experiments in proximal renal tubules.

The pH-stat technique has been used to measure H+ fluxes in gastric mucosa and urinary bladder "in vitro" while keeping mucosal pH constant. We now report application of this method in renal tubules. We perfused proximal tubules with double-barreled micropipettes, blocked luminal fluid columns with oil and used a double-barreled Sb/reference microelectrode to measure pH, and Sb or 1 N HC1-filled microelectrodes to inject OH- or H+ ions into the tubule lumen. By varying current injection, pH was kept constant at adjustable levels by an electronic clamping circuit. We could thus obtain ratios of current (nA) to pH change (apparent H(+)-ion conductance). These ratios were reduced after luminal 10(-4) M acetazolamide, during injection of OH-, but they increased during injection of H+. The point-like injection source causes pH to fall off with distance from the injecting electrode tip even in oil-blocked segments. Therefore, a method analogous to cable analysis was used to obtain H+ fluxes per cm2 epithelium. The relation between JH+ and pH gradient showed saturation kinetics of H fluxes, both during OH- and H+ injection. This kinetic behavior is compatible with inhibition of JH by luminal H+. It is also compatible with dependence on Na+ and H+ gradients of a saturable Na/H exchanger. H(+)-ion back-flux into the tubule lumen also showed saturation kinetics. This suggests that H+ flow is mediated by a membrane component, most likely the Na(+)-H+ exchanger.

Filtered load of buffer and renal H-ion secretion: mechanism of proximal tubule load dependence.

When the filtered load of buffers like bicarbonate or phosphate is increased by elevating GFR or buffer concentration in plasma, the overall renal reabsorption of bicarbonate or the formation of titratable acidity are markedly increased. The same happens when buffer concentration or flow rate are varied during proximal microperfusion. We have recently studied the mechanisms of this functional dependence. We have observed that the rate of bicarbonate reabsorption is always proportional to luminal buffer concentration when a stationary fluid column is injected into the proximal lumen. H-ion secretion is also proportional to luminal levels of non-bicarbonate buffers. Using a pH-stat technique adapted to renal tubules, we have shown that H-ion secretion is dependent on proximal pH independently of the used buffer species. A kinetic analysis of these data shows a non-linear relationship between luminal H+ and H+ secretion, compatible with carrier mediated transport.

Electrophysiological analysis of bicarbonate permeation across the peritubular cell membrane of rat kidney proximal tubule. II. Exclusion of HCO3(-)-effects on other ion permeabilities and of coupled electroneutral HCO3(-)-transport.

Cell membrane potentials of rat kidney proximal tubules were measured in response to peritubular ion substitutions in vivo with conventional and Cl- sensitive microelectrodes in order to test possible alternative explanations of the bicarbonate dependent cell potential transients reported in the preceding paper. Significant direct effects of bicarbonate on peritubular K+, Na+, and Cl- conductances could be largely excluded by blocking K+ permeability with Ba2+ and replacing all Na+ and Cl- by choline or respectively SO4(2-) isethionate, or gluconate. Under those conditions the cell membrane response to HCO3- was essentially preserved. In addition it was observed that peritubular Cl- conductance is negligibly small, that Cl-/HCO3- exchange - if present at all - is insignificant, and that rheogenic HCO3- flow with coupling to Na+ flow is also absent or insignificant. A transient disturbance of the Na+ pump or a transient unspecific increase of the membrane permeability was also excluded by experiments with ouabain and by the observation that SITS (4-acetamido-4'-isothiocyano-2,2' disulphonic stilbene) blocked the HCO3- response instantaneously. The data strongly support the notion that the potential changes in response to peritubular HCO3- concentration changes arise from passive rheogenic bicarbonate transfer across the peritubular cell membrane, and hence that this membrane has a high conductance for bicarbonate buffer.

The intracellular chloride activity of rat kidney proximal tubular cells.

The intracellular Cl- activity was determined in rat kidney proximal tubular cells in vivo, using single-barreled Cl- sensitive microelectrodes filled with Corning no. 477913 liquid ion exchanger resin to measure VCl and using - in separate experiments - conventional KCl-filled microelectrodes to measure the membrane potential, Vm. After correction for interference from other anions on VCl the intracellular Cl- activity averaged 13.1 mmol X l-1 SD +/- 4.5 mmol X l-1 (n = 96). This value is approximately two-fold higher than the intracellular equilibrium activity which can be calculated from the extracellular Cl- activity of 90-103 mmol X l-1 and Vm of -71.2 mV, SD +/- 4.9 mV (n = 23) to amount to 6.3 to 6.7 mmol X l-1. Since both cell membranes are permeable for Cl- ions, as concluded from luminal and/or peritubular Cl- substitution experiments, we conclude that the cellular Cl- accumulation above equilibrium results from transcellular active Cl- transport, the detailed mechanism of which is presently not known. From the slow decline of intracellular Cl- concentration after substitution of luminal Cl- by gluconate, however, we deduce that transcellular Cl- absorption is of minor importance in surface tubules of rat kidney under free flow and that the major part of transtubular Cl- flux is passive and paracellular.

Chloride activity in cells of isolated perfused cortical thick ascending limbs of rabbit kidney.

Rabbit cortical thick ascending limb segments were perfused in vitro, and intracellular Cl- activity was estimated in three types of experiments using conventional and chloride selective microelectrodes. In series 1 Ringer like solutions were present on the two epithelial sides. In series 2 limen Cl- was replaced by gluconate, and in series 3 furosemide, 10-20 . 10(-6) mol . 1-1, was added to the lumen perfusate. It was found that under control conditions intracellular Cl- activity, as estimated from the difference of the reading of the conventional (n = 53) and ion selective electrodes (n = 118) was 26 +/- 1 mmol . 1-1. Thi value is approximately three times higher than expected for passive distribution of Cl-. After removal of lumen Cl- (series 2) intracellular Cl- activity fell to 9 mmol . 1(-1) which is only some 4 mmol . 1(-1) above passive distribution. We argue that these 4 mmol . 1(-1) reflect mainly the interference with the Cl- electrode by other anions, such as phosphate. The above estimates for intracellular Cl- activity, have to be diminished by these 4 mmol . 1(-1), and, thus, are close to 22 mmol . 1(-1). In series 3 a rapid and reversible fall in intracellular Cl- from 23 to 7 mmol . 1(-1) was observed. We conclude that the Cl- activity in cTAL cells is clearly above equilibrium under control conditions and that it falls rapidly to values close to equilibrium when Cl- reabsorption is blocked by either removing lumen Cl- or by blocking the Cl- entry via the Na+-2 Cl--K+-carrier with furosemide.(ABSTRACT TRUNCATED AT 250 WORDS)

Mechansims and components of renal tubular acidification.

1. Renal cortical tubules of control and acetazolamide infused rats were perfused with 100 mM phosphate buffer at pH 5-5. The rate of alkalinization was measured by means of antimony micro-electrodes and was used to compute passive H ion fluxes from lumen to blood across the proximal and distal tubular epithelium. 2. The importance of other ionic movements that might contribute to pH changes of luminal buffers (chloride inflow into the lumen and bicarbonate diffusion across the epithelium) was assessed but found to be minor. H ion movements accounted for the majority of the observed pH changes. 3. H ion permeability of the tubular wall was calculated from the measured H fluxes and transepithelial concentration differences. It was 1-10 cm/sec, several orders of magnitude larger than those for other ions. However, such values are compatible with the mobility of protons in a medium of structure water within the limiting membrane. 4. A kinetic analysis of the mechanism of movement of H ions across the renal tubule is presented on the basis of experiments in which acidification and alkalinization of luminal buffers was followed in stationary microperfusions. The data are compatible with a pump-leak system in the proximal tubule, and with a model with low H ion permeability and a gradient dependent pump in the distal tubule.

Phosphate transfer and tubular pH during renal stopped flow microperfusion experiments in the rat.

The loss of 32P-phosphate salts by the luminal compartment of cortical tubules was studied in control and in acetazolamide-infused rats, during stopped-flow microperfusion with 100 mM phosphate-raffinose solutions. When the initial pH of the perfusion solution was low (5.5), phosphate was lost more rapidly from proximal tubules than at high initial pH (8.2). The average half-time of phosphate loss was 31.9 s during acid, and 66.0 s during alkaline perfusion in proximal tubules of control rats; in acetazolamide-infused rats half-times were 77.0 and 86.6 s for acid and alkaline perfusions. Thus acetazolamide infusion slows the rate of phosphate loss by proximal tubules, when the perfusion solution is acid, but has no significant effect if its pH is alkaline. These half-times compare to proximal acidification rates of 7.23 s in control and 13.2 s in acetazolamide-infused rats. In distal tubules of control rats no significant loss of phosphate was observed during the period of perfusion. It is concluded that the loss of phosphate, in proximal tubules, is markedly slower than the changes in tubular pH and so its effect on tubular acidification must be of minor importance. In distal tubules changes in pH are not due to transepithelial phosphate movement.