Growth inhibition of Trypanosoma cruzi and Leishmania donovani infantum by different snake venoms: preliminary identification of proteins from Cerastes cerastes venom which interact with the parasites

Venom from three different snake species was tested in vitro against the protozoan parasites Trypanosoma cruzi and Leishmania donovani infantum. Two of them, Cerastes cerastes and Naja haje, exerted a significant growth inhibition of T. cruzi and L. d. infantum parasites. Heating of the venoms abolished their activity, suggesting that the active factors are thermolabile. Incubation of parasites with 125I-labelled C. cerastes venom proteins allowed preliminary identification of components which interact preferentially with the pathogens.

Pro-inflammatory activities in elapid snake venoms

1. Snake venoms from the genera Micrurus (M. ibiboboca and M. spixii) and Naja (N. naja, N. melanoleuca and N. nigricollis) were analysed, using biological and immunochemical methods, to detect pro-inflammatory activities, cobra venom factor (COF), proteolytic enzymes, thrombin-like substances, haemorrhagic and oedema-producing substances. 2. The venoms of the five snake species activate the complement system (C) in normal human serum (NHS) in a dose-related fashion, at concentrations ranging from 5 micrograms to 200 micrograms ml-1 serum. Electrophoretic conversion of C3 was observed with all venoms in NHS containing normal concentrations of Ca2+ and Mg2+, but only by venoms from N. naja and N. melanoleuca when Ca2+ was chelated by adding Mg(2+)-EGTA. 3. Purified human C3 was electrophoretically converted, in the absence of other C components, by the venoms from N. naja, N. nigricollis and M. ibiboboca. However, only the venoms from N. naja and N. melanoleuca contained a 144 kDa protein revealed in Western blot with sera against COF or human C3. 4. All venoms, at minimum concentrations of 30 ng ml-1, were capable of lysing sheep red blood cells, also in a dose-related fashion, when incubated with these cells in presence of egg yolk as a source of lecithin. Although the venoms from M. spixii and N. nigricollis showed detectable thrombin-like activity, these and the other venoms were free of proteolytic activity when fibrin, gelatin and casein, were used as substrates. 5. When tested on mice skin, all five venoms were capable of inducing an increase in vascular permeability and oedema, but were devoid of haemorrhagic producing substances (haemorrhagins). 6. These data provide evidence indicating that Elapidae venoms contain various pro-inflammatory factors which may be important in the spreading of neurotoxins throughout the tissues of the prey or human victim.

Pharmacological characterization of five cloned voltage-gated K+ channels, types Kv1.1, 1.2, 1.3, 1.5, and 3.1, stably expressed in mammalian cell lines

We have analyzed the biophysical and pharmacological properties of five cloned K+ (Kv) channels (Kv1.1, Kv1.2, Kv1.3, Kv1.5, and Kv3.1) stably expressed in mammalian cell lines. Kv1.1 is biophysically similar to a K+ channel in C6 glioma cells and astrocytes, Kv1.3 and Kv3.1 have electrophysiological properties identical to those of the types n and l K+ channels in T cells, respectively, and Kv1.5 closely resembles a rapidly activating delayed rectifier in the heart. Each of these native channels may be formed from the homomultimeric association of the corresponding Kv subunits, and pharmacological compounds that selectively modulate them may be useful for the treatment of neurological, immune, and cardiac disorders. The cell lines described in this report could be used to identify such drugs and we have therefore embarked on a pharmacological characterization of the five cloned channels. The compounds tested in this study include 4-aminopyridine, capsaicin, charybdotoxin, cromakalim, dendrotoxin, diltiazem, D-sotalol, flecainide, kaliotoxin, mast cell degranulating peptide, nifedipine, noxiustoxin, resiniferatoxin, and tetraethylammonium.

Trypanosoma cruzi infection in rats induced early lesion of the heart noradrenergic nerve terminals by a complement-independent mechanism

The acute phase of the experimental Chagas' disease in rats induces extensive lesion of the heart sympathetic nerve terminals. Because of evidence indicating the involvement of immune reactions in neuron destruction provoked by Chagas' disease, we tested the effects of depleting the complement system by cobra venom factor upon the sympathetic denervation. The serum hemolytic activity against sensitized sheep erythrocytes ensured the efficacy of the anticomplementary treatment. Glyoxylic acid-induced histofluorescence and electron-microscopic methods allowed the study of the heart noradrenergic nerves. T. cruzi infection caused marked rarefaction of fluorescent nerve terminals at day 10 of infection and the ultrastructural study guaranteed that this rarefaction involved lesion of noradrenergic terminals. The complement depletion failed to prevent this early heart noradrenergic denervation, excluding the participation of complement-mediated lysis as a main mechanism.

Exposure of phosphatidylcholine and phosphatidylinositol in plasma membranes from rat brain synaptosomes treated with phospholipase A2 toxins (beta-bungarotoxin, notexin) and enzymes (Naja nigricollis, Naja naja atra)

Phospholipase A2 (PLA2) toxins act presynaptically to block acetylcholine release and are much more potent and specific in their actions than PLA2 enzymes even though they have lower enzymatic activity. Since their mechanism of action is not completely understood, it was of interest to examine the toxins' effects on phospholipid asymmetry as changes in asymmetry are associated with changes in membrane functioning. Rat brain synaptosomes were treated with the PLA2 toxins beta-bungarotoxin (beta-BuTx) and notexin and with the PLA2 enzymes Naja nigricollis and Naja naja atra under relatively non-disruptive conditions as judged by leakage of lactate dehydrogenase (LDH) and levels of phospholipid hydrolysis. The exposure of phosphatidylcholine (PC) and phosphatidylinositol (PI) on the synaptosomal surface was investigated by means of a specific PC-exchange protein (PCEP) and a PI-specific phospholipase C (PI-PLC), respectively. Treatment of the synaptosomes with N. nigricollis PLA2, beta-BuTx and notexin did not affect the availability of PC to exchange by PCEP, but significantly increased the exposure of PI to hydrolysis by PI-PLC. In contrast, N. n. atra PLA2 slightly decreased the exposure of PC and did not affect that of PI. The differences between N. n. atra PLA2, on the one hand, and N. nigricollis PLA2, beta-BuTx and notexin, on the other hand, parallel differences in their pharmacological activities. Our earlier studies showed that PLA2 enzymes, and possibly PLA2 toxins, have a pharmacological site separate from the enzymatic site. Since in the present study the effect on PI was abolished by EDTA, the presence of an enzymatic site in addition to the pharmacological site may be required or alternatively divalent cations may be required for the effects on PI asymmetry independent of the inhibition of PLA2 by EDTA.

Priming of phagocytes for reactive oxygen production during hepatic ischemia-reperfusion potentiates the susceptibility for endotoxin-induced liver injury

Plasma levels of glutathione disulfide (GSSG) as an indicator of a vascular oxidant stress, tumor necrosis factor-alpha (TNF-alpha) formation, and liver injury (alanine aminotransferase activity, histology) were monitored in male Fischer rats after 30 min of hepatic ischemia followed by up to 4 hr of reperfusion. The injection of 1 mg/kg Salmonella enteritidis endotoxin at 30 min of reflow potentiated the postischemic oxidant stress and liver injury. TNF-alpha levels increased from 10 +/- 7 pg/ml (baseline) to 3,553 +/- 738 pg/ml after ischemia-reperfusion followed by endotoxin, or to 3,670 +/- 508 pg/ml after endotoxin alone. Depletion of serum complement before ischemia attenuated the endotoxin-mediated increase of reactive oxygen formation by 70% but did not affect TNF-alpha levels. Complement activation with cobra venom factor (CVF) during reperfusion had an effect similar to that of endotoxin on the oxidant stress and liver injury. CVF did not increase TNF-alpha formation during reperfusion. Kupffer cells and neutrophils isolated from the postischemic liver 2.5 hr after endotoxin injection generated 600% and 400% more superoxide, respectively, than cells isolated from control livers. The results demonstrate a substantial priming of hepatic phagocytes for reactive oxygen production but not TNF-alpha formation, even after short periods of hepatic ischemia, and the vulnerability of the postischemic liver to severe endotoxin-induced injury. Activated complement seems to be mainly responsible for the effects. These results may explain the high risk for hepatic failure after extensive liver resection and hypovolemic shock.

Effects of systemic complement activation on renal circulation of rats

In a variety of immunopathological diseases activation of the complement cascade occurs either systemically or localized in the kidney. To elucidate the functional impact of complement activation upon the renal microcirculation, we administered cobra venom factor of Naja naja kaouthia (CVF) i.v. into thiobarbital anaesthetized female rats. CVF is a potent activator of the alternative pathway of complement by forming the C3-convertase CVF, Bb which cannot be downregulated by the natural inhibitor factors H and I and thereby leads to generation of the anaphylatoxins C3a and C5a and formation of the membrane attack complex (MAC). We utilized creatinine clearance and flowmeter measurements in the normal kidney and intravital microscopy of the split hydronephrotic rat kidney model to observe the microvascular changes. Bolus injection of CVF (100 U kg-1) resulted in an immediate reduction of RBF (-68% after 10 min), which remained decreased during the entire experiment (90 min). Systemic blood pressure was significantly reduced only in the early period (-23% of control: 126 mmHg after 10 min). After an initial anuric phase of 30 min duration, the glomerular filtration rate was significantly diminished by 47%. White cell count was decreased by about 50% after the experiments. Application of the competitive thromboxane A2-antagonist, BM 13505, reversed all renal and systemic CVF-effects. Continuous infusion of the competitive leukotriene D4-antagonist, ICI 198615, attenuated the late renal CVF-effects (i.e. 30 min after injection of CVF). Depletion of polymorphonuclear cells (PMN) attenuated the CVF-effects similar to BM 13505. Intravenous administration of CVF in the hydronephrotic kidney model resulted in a massive constriction of the interlobar and arcuate artery, with a fall in glomerular blood flow comparable to the reduction of RBF in the normal kidney. Diameters of the afferent arterioles--most sensitive to many vasoconstricting agents--were not significantly altered. Our results suggest that injection of CVF and the liberation of high amounts of the anaphylatoxins, C3a and C5a, induces the release of TXA2, which contributes to the early renal effects and the formation of cysteinyl-leukotrienes which play an important role in the late phase of systemic complement activation. Utilizing the split hydronephrotic kidney model we demonstrated the predominant action of complement activation on the large preglomerular vessels for the first time. PMN are seemingly involved in the liberation of secondary mediators which appear to reduce renal blood flow and glomerular filtration.

Differences in a K current in Schwann cells from normal and neurofibromatosis-infected damselfish

Patch clamp techniques were used to study whole cell ionic currents in Schwann cells (SC) from a tropical marine fish, the bicolor damselfish, Pomacentrus partitus. The bicolor damselfish is affected by a disease termed damselfish neurofibromatosis (DNF), being developed as an animal model of neurofibromatosis-type 1 (NF1) in humans. NF1 affects SC, fibroblasts, and perineurial cells. The sole depolarization-activated ionic current present in cultured SC from normal fish peripheral nerve and from neurofibromas of fish with induced or spontaneously occurring DNF was an inactivating K+ current (K current), with a strong dependence on the Nernst potential for K+. This K current activated at depolarizations to -40 mV and above and inactivated during a maintained test pulse (0.2-1 s), but inactivation was significantly greater in tumored SC. Both currents were inhibited by 4-aminopyridine (Kd approximately 1 mM) and by dendrotoxin (15 microM) but were insensitive to extracellular tetraethyammonium (< or = 150 mM), indicating that the whole cell currents were similar pharmacologically. The currents could be distinguished on the basis of their sensitivity to depolarized holding potential, with normal cells less sensitive. Half-inactivation of the current was -32 mV in normal cells and -38 mV in tumored cells. Inactivation curves constructed from the average normalized current for many SC were significantly different in normal and tumored cells. When the depolarized holding potential was maintained between test depolarizations, greater voltage-dependent inactivation in tumored cells was apparent. Normal cells maintained an average of 36% of peak current at a holding voltage of -40 mV, while in tumored cells this average was 12%, a significant difference.

Inhibition of a K+ current by beta-dendrotoxin in primary and subcultured vascular smooth muscle cells

beta-Dendrotoxin (beta-DTX), a polypeptide component of Eastern Green Mamba snake venom, inhibits a slow voltage-activated 86Rb efflux from synaptosomes, suggesting that beta-DTX inhibits K+ channels. The effects of beta-DTX on the K+ currents in primary cultured and subcultured (passages 8-12) rat tail artery vascular smooth muscle cells (VSMCs) were studied using the whole-cell patch-clamp technique. A delayed rectifier K+ current was observed in both types of cells. The current, which was relatively insensitive to tetraethylammonium, was activated at -40 to -30 mV and showed almost no inactivation. beta-DTX (1-1000 nM) decreased the outward K+ current. The effect was concentration dependent and reversible by washout but did not depend on the frequency of stimulation (use dependence) or the membrane potential. beta-DTX was more effective in primary cultured cells than in subcultured cells. K+ channels in primary cultured cells were maximally (45%) inhibited by 1 microM beta-DTX compared with 35% inhibition in subcultured cells. The concentration producing half-maximal inhibition was 5.1 x 10(-8) M for primary cells and 7.1 x 10(-8) M for subcultured cells. The delayed rectifier current was not affected by alpha-DTX, a blocker of the fast-inactivating outward K+ current (IA). These results clearly demonstrate that beta-DTX is a novel antagonist of the delayed rectifier K+ current in primary and subcultured rat tail artery VSMCs.

Proteinase inhibitor homologues as potassium channel blockers

We report here the NMR structure of dendrotoxin I, a powerful potassium channel blocker from the venom of the African Elapidae snake Dendroaspis polylepis polylepis (black mamba), calculated from an experimentally-derived set of 719 geometric restraints. The backbone of the toxin superimposes on bovine pancreatic trypsin inhibitor (BPTI) with a root-mean-square deviation of < 1.7 A. The surface electrostatic potential calculated for dendrotoxin I and BPTI, reveal an important difference which might account for the differences in function of the two proteins. These proteins may provide examples of adaptation for specific and diverse biological functions while at the same time maintaining the overall three-dimensional structure of a common ancestor.

Pharmacological enhancement of in vivo foreign gene expression in muscle

Intramuscular injection of naked plasmid DNA provides a means for gene transfer and expression in striated muscle. In this study, the effects of treating muscle with normal saline, etidocaine, mepivacaine, acetic anhydride, sodium bicarbonate, Notechis scutatus venom, cardiotoxin and bupivacaine before plasmid DNA injection on foreign gene expression were evaluated. Dose dependence, strain and species specificity, the time interval between pharmacological agent and plasmid DNA injection, the stability of gene expression and the fate of the injected plasmid DNA were studied using reporter gene expression, by histological examination and semi-quantitative polymerase chain reaction. Of the various agents tested, the best enhancement of foreign gene expression occurred in muscle treated with 0.75% bupivacaine five to seven days before plasmid DNA injection. Rat and mouse quadriceps muscle treated with 0.75% bupivacaine had levels of luciferase activity four- to 40-times greater than non-bupivacaine-treated muscle. Also, beta-galactosidase expressing myofibers were observed throughout the length of the muscle in samples treated with 0.75% bupivacaine before reporter gene injection. Muscle treated with 0.75% bupivacaine fully recovered from the degeneration caused by its injection with no long-term effects histologically. The heightened level of reporter gene expression persisted in 0.75% bupivacaine-treated muscle for one month, but decreased to that of non-bupivacaine-treated muscle by two months after plasmid DNA injection. Enhancement of foreign gene expression may be particularly advantageous in vaccination protocols employing intramuscular plasmid injection.

Contribution of a slowly inactivating potassium current to the transition to firing of neostriatal spiny projection neurons

1. Neostriatal spiny projection neurons display a prominent slowly depolarizing (ramp) potential and long latency to spike discharge in response to intracellular current pulses. The contribution of a slowly inactivating A-current (IAs) to this delayed excitation was investigated in a neostriatal slice preparation using current pulse protocols incorporating information based on the known voltage dependence, kinetics, and pharmacological properties of IAs. 2. Depolarizing intracellular current pulses evoked a slowly developing ramp potential that could last for seconds without reaching steady state and continued until either the pulse was terminated or spike threshold was reached. The slope of the ramp potential was dependent on the level of depolarization achieved by the membrane, and the apparent activation threshold for this ramp depolarization was approximately -65 mV. 3. Application of low concentrations of 4-aminopyridine (4-AP, 30-100 microM) or dendrotoxin (DTX, 30 nM), which are known to selectively block IAs, reduced both the slope of the ramp potential and the latency to first spike discharge. As has been described previously, blockade of inward Na+ and Ca2+ currents with tetrodotoxin (TTX, 1 microM) and cadmium (400 microM) also reduced the slope of the ramp depolarization. 4. A conditioning-test pulse protocol was used to examine the voltage dependence of inactivation of the ramp potential and long first spike latency. In the absence of a conditioning pulse, the test pulse evoked a slowly rising ramp potential and a spike with a long latency to discharge. A conditioning depolarization to approximately -60 mV decreased the slope of the ramp potential and the latency to first spike discharge evoked by the test pulse. A conditioning hyperpolarization to potentials below -100 mV, increased first spike latency. Application of a low concentration of 4-AP (100 microM) abolished the influence of prior membrane potential on the slope of the ramp depolarization and the latency to first spike discharge. 5. The kinetics of recovery from inactivation of the 4-AP-sensitive current were studied in the presence of TTX and cadmium by depolarizing cells to approximately -50 mV and then stepping to approximately -90 mV for increasing periods of time (0.5-5.0 s) before delivering a test pulse. The amplitude of the test pulse response decreased as a function of the hyperpolarizing step duration. When the test pulse response amplitudes were plotted against the hyperpolarizing step duration, the points reflected an exponential decay with an average time constant of 2.05 +/- 1.38 (SD) s.(ABSTRACT TRUNCATED AT 400 WORDS)

Primary structure of a beta subunit of alpha-dendrotoxin-sensitive K+ channels from bovine brain

Voltage-dependent cation channels are large heterooligomeric proteins. Heterologous expression of cDNAs encoding the alpha subunits alone of K+, Na+, or Ca2+ channels produces functional multimeric proteins; however, coexpression of those for the latter two with their auxiliary proteins causes dramatic changes in the resultant membrane currents. Fast-activating, voltage-sensitive K+ channels from brain contain four alpha and beta subunits, tightly associated in a 400-kDa complex; although molecular details of the alpha-subunit proteins have been determined, little is known about the beta-subunit constituent. Proteolytic fragments of a beta subunit from bovine alpha-dendrotoxin-sensitive neuronal K+ channels yielded nine different sequences. In the polymerase chain reaction, primers corresponding to two of these peptides amplified a 329-base-pair fragment in a lambda gt10 cDNA library from bovine brain; a full-length clone subsequently isolated encodes a protein of 367 amino acids (M(r) approximately 40,983). It shows no significant homology with any known protein. Unlike the channels' alpha subunits, the hydropathy profile of this sequence failed to reveal transmembrane domains. Several consensus phosphorylation motifs are apparent and, accordingly, the beta subunit could be phosphorylated in the intact K+ channels. These results, including the absence of a leader sequence and N-glycosylation, are consistent with the beta subunit being firmly associated on the inside of the membrane with alpha subunits, as speculated in a simplified model of these authentic K+ channels. Importantly, this first primary structure of a K(+)-channel beta subunit indicates that none of the cloned auxiliary proteins of voltage-dependent cation channels, unlike their alpha subunits, belong to a super-family of genes.

Prevention of complement-induced pulmonary hypertension and improvement of right ventricular function by selective thromboxane receptor antagonism

The effect of complement activation on the pulmonary vascular system and on right ventricular function was studied in sheep (n = 12) by injection of cobra venom factor. Animals were instrumented for measurement of pulmonary flow, mean pulmonary artery pressure, right ventricular stroke work, arterial blood gases, and systemic vascular resistance. Blood was sampled from the left atrium and pulmonary artery to measure thromboxane B2, the metabolite of thromboxane A2, by radioimmunoassay. After baseline measurements, animals were randomly assigned to receive a selective thromboxane receptor antagonist SQ30741 as a 10 mg/kg bolus with an infusion of 10 mg/kg per hour or else to receive vehicle. Cobra venom factor was then injected (30 U/kg) in all animals, and data were recorded at 15, 30, 60, 90, and 120 minutes. In control animals there was a 2.4-fold increase in mean pulmonary artery pressure and a 76% increase in right ventricular stroke work at 15 minutes from baseline (p < 0.05); these values remained elevated for 30 minutes and returned to baseline by 1 hour with no change in systemic vascular resistance. Arterial oxygenation decreased by 124% at 15 minutes and remained depressed through the experiment, but in treated animals oxygen tension remained unchanged from baseline. Thromboxane B2 increased 95% from baseline in the control group and 1.5 fold in treated animals and followed a similar time course as the functional measurements (p < 0.05). A pulmonary vascular thromboxane B2 gradient of approximately 1000 pg/ml was measured at 15 and 30 minutes in both control and treated groups. (p < 0.05) We conclude that after complement activation in this model pulmonary hypertension and decreased oxygen tension are mediated by thromboxane release from the pulmonary vascular bed. This increased afterload causes a stress on the right ventricle as demonstrated by the increased right ventricular stroke work. Selective thromboxane receptor antagonism may be a beneficial therapy for pulmonary hypertension in patients after cardiopulmonary bypass.

Both N- and C-terminal regions contribute to the assembly and functional expression of homo- and heteromultimeric voltage-gated K+ channels

The functional diversity of voltage-gated K+ channels may be partially determined by the mechanisms that permit or limit the assembly of molecularly diverse K+ channel subunits. To determine possible amino acid sequence domains required for subunit assembly and expression, we have constructed 15 N- and C-terminal interstitial or truncation deletion mutations in mKv1.1 (MBK1), a mouse Shaker-like K+ channel. We injected Xenopus oocytes with cRNA encoding each of these mutants and coinjected each mutant cRNA with cRNA for wild-type mKv1.3, another mouse Shaker-like K+ channel that can form heteromultimers with mKv1.1. We found that the last five amino acids of the C-terminus of mKv1.1 contribute to functional expression by (1) rescuing the function of mutants with a large truncation of the C-terminus (delta 424-495), and (2) contributing to the slow inactivation kinetics (time constant of 2-3 sec) of wild-type mKv1.1 whole-cell K+ currents. All C-terminal deletion mutants were able to express at least as heteromultimers with mKv1.3, suggesting that the C-terminus is not required for channel assembly. In contrast, nine different interstitial or truncation mutants in which part of a highly conserved, large (80-99 amino acid residues) domain within the N-terminus had been deleted were unable to express either homomultimers or heteromultimers. The relatively small sizes and nonoverlapping distributions of the interstitial deletions enable us to suggest that the structural integrity of this entire N-terminal domain is required for subunit assembly and functional expression of this and probably other Shaker-like K+ channel proteins.

Antibodies specific for distinct Kv subunits unveil a heterooligomeric basis for subtypes of alpha-dendrotoxin-sensitive K+ channels in bovine brain

The authentic subunit compositions of neuronal K+ channels purified from bovine brain were analyzed using a monoclonal antibody (mAb 5), reactive exclusively with the Kv1.2 subunit of the latter and polyclonal antibodies specific for fusion proteins containing C-terminal regions of four mammalian Kv proteins. Western blotting of the K+ channels isolated from several brain regions, employing the selective blocker alpha-dendrotoxin (alpha-DTX), revealed the presence in each of four different Kvs. Variable amounts of Kv1.1 and 1.4 subunits were observed in the K+ channels purified from cerebellum, corpus striatum, hippocampus, cerebral cortex, and brain stem; on the other hand, contents of Kv1.6 and 1.2 subunits appeared uniform throughout. Each Kv-specific antibody precipitated a different proportion (anti-Kv1.2 > 1.1 >> 1.6 > 1.4) of the channels detectable with radioiodinated alpha-DTX in every brain region, consistent with a widespread distribution of these oligomeric subtypes. Such heterooligomeric combinations were further documented by the lack of additivity upon their precipitation with a mixture of antibodies to Kv1.1 and Kv1.2; moreover, cross-blotting of the multimers precipitated by mAb 5 showed that they contain all four Kv proteins. Collectively, these findings demonstrate that subtypes of alpha-DTX-susceptible K+ channels are prevalent throughout mammalian brain which are composed of different Kv proteins assembled in complexes, shown previously to also contain auxiliary beta-subunits [Parcej, D. N., Scott, V. E. S., & Dolly, J.O. (1992) Biochemistry 31, 11084-11088].

Pancreatic-type phospholipase A2 induces group II phospholipase A2 expression and prostaglandin biosynthesis in rat mesangial cells

The effect of pancreatic group I phospholipase A2 (PLA2-I) on receptor-mediated expression of arthritic group II phospholipase A2 (PLA2-II) and its correlation with prostaglandin E2 (PGE2) synthesis were examined in cultured rat mesangial cells. Scatchard analysis using 125I-PLA2-I revealed the existence of a single class of specific binding sites for PLA2-I in rat mesangial cells with an equilibrium dissociation constant (Kd) of 1.6 nM and a maximum binding capacity of 10.1 fmol/10(6) cells. The mammalian mature type of PLA2-I specifically recognized this binding site, whereas its inactive zymogen and mammalian PLA2-II showed much lower affinities. PLA2-I markedly increased PLA2-II mRNA levels as well as PLA2-II secretion from the cells in a time- and dose-dependent manner that was closely correlated with PGE2 production. Both PLA2-II expression and PGE2 synthesis were completely suppressed by pretreatment of the cells with actinomycin D, cycloheximide, or dexamethasone. These results strongly suggest that there may be crosstalk between PLA2-I and PLA2-II via the specific PLA2-I receptor that elicits PGE2 synthesis.

Tityustoxin K alpha blocks voltage-gated noninactivating K+ channels and unblocks inactivating K+ channels blocked by alpha-dendrotoxin in synaptosomes

Two nonhomologous polypeptide toxins, tityustoxin K alpha (TsTX-K alpha) and tityustoxin K beta (TsTX-K beta), purified from the venom of the Brazilian scorpion Tityus serrulatus, selectively block voltage-gated noninactivating K+ channels in synaptosomes (IC50 values of 8 nM and 30 nM, respectively). In contrast, alpha-dendrotoxin (alpha-DTX) and charybdotoxin (ChTX) block voltage-gated inactivating K+ channels in synaptosomes (IC50 values of 90 nM and 40 nM, respectively). We studied interactions among these toxins in 125I-alpha-DTX binding and 86Rb efflux experiments. Both TsTX-K alpha and ChTX completely displaced specifically bound 125I-alpha-DTX from synaptic membranes, but TsTX-K beta had no effect on bound alpha-DTX. TsTX-K alpha and TsTX-K beta blocked the same noninactivating component of 100 mM K(+)-stimulated 86Rb efflux in synaptosomes. Both alpha-DTX and ChTX blocked the same inactivating component of the K(+)-stimulated 86Rb efflux in synaptosomes. Both the inactivating and the noninactivating components of the 100 mM K(+)-stimulated 86Rb efflux were completely blocked when 200 nM TsTX-K beta and either 600 nM alpha-DTX or 200 nM ChTX were present. The effects of TsTX-K alpha and ChTX on 86Rb efflux were also additive. When TsTX-K alpha was added in the presence of alpha-DTX, however, only the noninactivating component of the K(+)-stimulated efflux was blocked. The inactivating component could then be blocked by ChTX, which is structurally homologous to TsTX-K alpha. We conclude that TsTX-K alpha unblocks the voltage-gated inactivating K+ channels in synaptosomes when they are blocked by alpha-DTX, but not when they are blocked by ChTX. TsTX-K alpha binds to a site on the inactivating K+ channel that does not occlude the pore; its binding apparently prevents alpha-DTX (7054 Da), but not ChTX (4300 Da), from blocking the pore. The effects of TsTX-K alpha on 125I-alpha-DTX binding and 86Rb efflux are mimicked by noxiustoxin, which is homologous to TsTX-K alpha and ChTX.

Selective block by alpha-dendrotoxin of the K+ inward rectifier at the Vicia guard cell plasma membrane

The efficacy and mechanism of alpha-dendrotoxin (DTX) block of K+ channel currents in Vicia stomatal guard cells was examined. Currents carried by inward- and outward-rectifying K+ channels were determined under voltage clamp in intact guard cells, and block was characterized as a function of DTX and external K+ (K+o) concentrations. Added to the bath, 0.1-30 nM DTX blocked the inward-rectifying K+ current (IK,in), but was ineffective in blocking current through the outward-rectifying K+ channels (IK,out) even at concentrations of 30 nM. DTX block was independent of clamp voltage and had no significant effect on the voltage-dependent kinetics for IK,in, neither altering its activation at voltages negative of -120 mV nor its deactivation at more positive voltages. No evidence was found for a use dependence to DTX action. Block of IK,in followed a simple titration function with an apparent K1/2 for block of 2.2 nM in 3 mM K+o. However, DTX block was dependent on the external K+ concentration. Raising K+o from 3 to 30 mM slowed block and resulted in a 60-70% reduction in its efficacy (apparent Ki = 10 mM in 10 nM DTX). The effect of K+ in protecting IK,in was competitive with DTX and specific for permeant cations. A joint analysis of IK,in block with DTX and K+ concentration was consistent with a single class of binding sites with a Kd for DTX of 240 pM. A Kd of 410 microM for extracellular K+ was also indicated. These results complement previous studies implicating a binding site requiring extracellular K+ (K1/2 approximately 1 mM) for IK,in activation; they parallel features of K+ channel block by DTX and related peptide toxins in many animal cells, demonstrating the sensitivity of plant plasma membrane K+ channels to nanomolar toxin concentrations under physiological conditions; the data also highlight one main difference: in the guard cells, DTX action appears specific to the K+ inward rectifier.

The inactivation behaviour of voltage-gated K-channels may be determined by association of alpha- and beta-subunits

Voltage-gated K-channels of the Shaker related subfamily have two subunits, membrane integrated alpha- and peripheral beta-subunits. alpha-Subunits may assemble as tetramers and form in in vitro expression systems functional K-channels. beta-Subunits cannot from channels by themselves. Like for alpha-subunits, the rat nervous system apparently expresses a family of beta-subunit proteins. We have demonstrated that one rat K-channel beta-subunit, Kv beta 1, contains an inactivating domain. Upon association of alpha- and Kv beta 1-subunits, delayed-rectifier type K-channels are converted to rapidly inactivating A-type K-channels. The beta-subunit inactivation domain acts via a ball and chain type mechanism previously proposed for N-type inactivation of alpha-subunits. The association of alpha- and beta-subunits endows the nervous system with an unprecedented flexibility and diversity of K-channels which may play an important role in the regulation of nervous excitability.

Hippocampal damage produced in rats by alpha-dendrotoxin--a selective K+ channel blocker--involves non-NMDA receptor activation

The epileptogenic and neurodegenerative effects induced by intra-hippocampal injection of a selective K+ channel inhibitor, alpha-dendrotoxin (DTx), were investigated in normal rats and those bearing a monolateral surgical lesion of the Schaffer collaterals that causes degeneration of their nerve terminals and also, isolates the CA3 area. In addition, these effects have also been studied in rats pretreated with NBQX, an AMPA receptor antagonist. Injection of DTx (35 pmol) into one dorsal hippocampus induced motor and electrocortical (ECoG) seizures in all the treated animals that were rapid in onset (within 2-3 min). The seizures were accompanied at 24 h by significant neuronal cell loss which occurred in the CA1, CA3 and CA4 pyramidal cell layers of the hippocampus, ipsilateral to the side of injection. This neuronal loss was paralleled by a significant decrease in the density of radioiodinated DTx labelled acceptors. Lesioning of the excitatory afferents to the CA1 pyramidal cells, gave a substantial reduction in the density of radioiodinated DTx labelled acceptors in the strata oriens and radiatum, revealing that a proportion of these K+ channels are present on the Schaffer collateral terminals. Under these conditions, motor and ECoG seizures persisted. As expected, the lesion prevented loss of the isolated CA3 pyramids, normally produced by the administration of DTx, leaving unaffected CA1 and CA4 pyramidal cell damage, consistent with an observed diminution of DTx binding sites in the latter areas. In unlesioned rats pre-treated with NBQX (30 mg/kg i.p.), subsequent injection of DTx evoked epileptogenic effects after a latency of 15 min and caused significant cell loss in the CA1 but not in the CA3 and CA4 pyramidal cell layers, ipsilateral to the side of toxin injection. A lower dose of NBQX (15 mg/kg i.p.) proved ineffective. In conclusion, these data together with our published results on NMDA antagonists indicate that motor and ECoG seizures and CA1 pyramidal cell loss elicited by intra-hippocampal injection of the K+ channel blocker, DTx, are independent from mechanisms involving glutamate-mediated excitotoxicity whereas CA3 and CA4 pyramidal cell loss may be the consequence of excessive activation of AMPA receptors.

[Analysis of cardiac function of discordant heart xenografts using a blood-perfused, isolated, supported heart model]

Changes in cardiac function during hyperacute rejection are not fully understood because of lack of appropriate models. In this study, a blood-perfused, isolated, supported heart model was employed for the analysis of cardiac function in discordant heart xenografts.

METHODS

Experiment 1: Changes in left ventricular end-systolic pressure (LVESP) and coronary perfusion pressure (CPP) were measured for 120 min. Dry heart weight after perfusion was measured in the following 4 groups: group A; isolated rat heart perfused with blood from support rat, group B; guinea pig heart, support guinea pig, group C; guinea pig heart, support rat, and group D; guinea pig heart, support rat with cobra venom factor (CVF) pretreatment. Complement C3 of support rat serum in group C and group D was measured by single radial immunodiffusion (SRID). Experiment 2: Fifteen guinea pig hearts perfused with blood from untreated support rats were analyzed for correlation between survival time and LVESP, and CPP as well.

RESULTS

In groups A and B, LVESP and CPP was stable up to 120 min. In group C, 4 out of 6 hearts were stopped beating within 120 min. The difference between LVESP at 10 min in group C and that in group B was not obtained, possibly due to high variation of values in group C, whereas CPP in group C was higher than that in group B (p < 0.05). In group D, CVF was shown to deplete complement C3. Group D showed constant LVESP and CPP, similar to non-xenograft groups. Dry heart weight of group C was larger than those of group B and D. There were positive correlations between survival time and LVESP at 10 min, and increasing rate of LVESP after 10 min as well. A negative correlation between survival time and CPP at 10 min was observed, while no correlation was obtained between survival time and increasing rate of CPP after 10 min.

CONCLUSIONS

1) Decreases in LVESP and increases in CPP in xenograft group are considered to be due to hyperacute rejection. 2) These changes can be abolished by depletion of C3. 3) Guinea pig hearts can work well in xenograft condition as in allograft condition in certain circumstances, i.e. depletion of C3. 4) The blood-perfused, isolated, supported heart model is useful for the analysis of cardiac function in discordant xenografts.