Batrachotoxin alkaloids from passerine birds: a second toxic bird genus (Ifrita kowaldi) from New Guinea.
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Batrachotoxins, including many congeners not previously described, were detected, and relative amounts were measured by using HPLC-mass spectrometry, in five species of New Guinean birds of the genus Pitohui as well as a species of a second toxic bird genus, Ifrita kowaldi. The alkaloids, identified in feathers and skin, were batrachotoxinin-A cis-crotonate (1), an allylically rearranged 16-acetate (2), which can form from 1 by sigmatropic rearrangement under basic conditions, batrachotoxinin-A and an isomer (3 and 3a, respectively), batrachotoxin (4), batrachotoxinin-A 3'-hydroxypentanoate (5), homobatrachotoxin (6), and mono- and dihydroxylated derivatives of homobatrachotoxin. The highest levels of batrachotoxins were generally present in the contour feathers of belly, breast, or legs in Pitohui dichrous, Pitohui kirhocephalus, and Ifrita kowaldi. Lesser amounts are found in head, back, tail, and wing feathers. Batrachotoxin (4) and homobatrachotoxin (6) were found only in feathers and not in skin. The levels of batrachotoxins varied widely for different populations of Pitohui and Ifrita, a result compatible with the hypothesis that these birds are sequestering toxins from a dietary source. (+info)
Anesthetic-like interaction of the sleep-inducing lipid oleamide with voltage-gated sodium channels in mammalian brain.
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BACKGROUND: cis-9,10-Octadecenoamide (cOA) accumulates in cerebrospinal fluid during sleep deprivation and induces sleep in animals, but its cellular actions are poorly characterized. In earlier studies, like a variety of anesthetics, cOA modulated gamma-aminobutyric acidA receptors and inhibited transmitter release/burst firing in cultured neurones or synaptoneurosomes. METHODS: Here, radioligand binding ([3H]batrachotoxinin A 20-alpha-benzoate and mouse central nervous system synaptoneurosomes) and voltage clamp (whole cell recording from cultured NIE115 murine neuroblastoma) confirmed an interaction with neuronal voltage-gated sodium channels (VGSC). RESULTS: cOA stereoselectively inhibited specific binding of toxin to VGSC (inhibitor concentration that displaces 50% of specifically bound radioligand, 39.5 microm). cOA increased (4x) the Kd of toxin binding without affecting its binding maximum. Rate of dissociation of radioligand was increased without altering association kinetics, suggesting an allosteric effect (indirect competition at site 2 on VGSC). cOA blocked tetrodotoxin-sensitive sodium currents (maximal effect and affinity were significantly greater at depolarized potentials; P < 0.01). Between 3.2 and 64 microm, the block was concentration-dependent and saturable, but cOA did not alter the V50 for activation curves or the measured reversal potential (P > 0.05). Inactivation curves were significantly shifted in the hyperpolarizing direction by cOA (maximum, -15.4 +/- 0.9 mV at 32 microm). cOA (10 microm) slowed recovery from inactivation, with tau increasing from 3.7 +/- 0.4 ms to 6.4 +/- 0.5 ms (P < 0.001). cOA did not produce frequency-dependent facilitation of block (up to 10 Hz). CONCLUSIONS: These effects (and the capacity of oleamide to modulate gamma-aminobutyric acidA receptors in earlier studies) are strikingly similar to those of a variety of anesthetics. Oleamide may represent an endogenous ligand for depressant drug sites in mammalian brain. (+info)
Disparate role of Na(+) channel D2-S6 residues in batrachotoxin and local anesthetic action.
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Batrachotoxin (BTX) stabilizes the voltage-gated Na(+) channels in their open conformation, whereas local anesthetics (LAs) block Na(+) conductance. Site-directed mutagenesis has identified clusters of common residues at D1-S6, D3-S6, and D4-S6 segments within the alpha-subunit Na(+) channel that are critical for binding of these two types of ligands. In this report, we address whether segment D2-S6 is similarly involved in both BTX and LA actions. Thirteen amino acid positions from G783 to L795 of the rat skeletal muscle Na(+) channel ((mu)1/Skm1) were individually substituted with a lysine residue. Four mutants (N784K, L785K, V787K, and L788K) expressed sufficient Na(+) currents for further studies. Activation and/or inactivation gating was altered in mutant channels; in particular, mu1-V787K displays enhanced slow inactivation and exhibited use-dependent inhibition of peak Na(+) currents during repetitive pulses. Two of these four mutants, (mu)1-N784K and (mu)1-L788K, were completely resistant to 5 microM BTX. This BTX-resistant phenotype could be caused by structural perturbations induced by a lysine point mutation in the D2-S6 segment. However, these two BTX-resistant mutants remained quite sensitive to bupivacaine block with affinity for inactivated Na(+) channels (K(I)) of approximately 10 microM or less, which suggests that (mu)1-N784 and (mu)1-L788 residues are not in close proximity to the LA binding site. (+info)
The evolution of coloration and toxicity in the poison frog family (Dendrobatidae).
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The poison frogs (family Dendrobatidae) are terrestrial anuran amphibians displaying a wide range of coloration and toxicity. These frogs generally have been considered to be aposematic, but relatively little research has been carried out to test the predictions of this hypothesis. Here we use a comparative approach to test one prediction of the hypothesis of aposematism: that coloration will evolve in tandem with toxicity. Recently, we developed a phylogenetic hypothesis of the evolutionary relationships among representative species of poison frogs, using sequences from three regions of mitochondrial DNA. In our analysis, we use that DNA-based phylogeny and comparative analysis of independent contrasts to investigate the correlation between coloration and toxicity in the poison frog family (Dendrobatidae). Information on the toxicity of different species was obtained from the literature. Two different measures of the brightness and extent of coloration were used. (i) Twenty-four human observers were asked to rank different photos of each different species in the analysis in terms of contrast to a leaf-littered background. (ii) Color photos of each species were scanned into a computer and a computer program was used to obtain a measure of the contrast of the colors of each species relative to a leaf-littered background. Comparative analyses of the results were carried out with two different models of character evolution: gradual change, with branch lengths proportional to the amount of genetic change, and punctuational change, with all change being associated with speciation events. Comparative analysis using either method or model indicated a significant correlation between the evolution of toxicity and coloration across this family. These results are consistent with the hypothesis that coloration in this group is aposematic. (+info)
Antillatoxin is a marine cyanobacterial toxin that potently activates voltage-gated sodium channels.
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Antillatoxin (ATX) is a lipopeptide derived from the pantropical marine cyanobacterium Lyngbya majuscula. ATX is neurotoxic in primary cultures of rat cerebellar granule cells, and this neuronal death is prevented by either N-methyl-d-aspartate (NMDA) receptor antagonists or tetrodotoxin. To further explore the potential interaction of ATX with voltage-gated sodium channels, we assessed the influence of tetrodotoxin on ATX-induced Ca2+ influx in cerebellar granule cells. The rapid increase in intracellular Ca2+ produced by ATX (100 nM) was antagonized in a concentration-dependent manner by tetrodotoxin. Additional, more direct, evidence for an interaction with voltage-gated sodium channels was derived from the ATX-induced allosteric enhancement of [3H]batrachotoxin binding to neurotoxin site 2 of the alpha subunit of the sodium channel. ATX, moreover, produced a strong synergistic stimulation of [3H]batrachotoxin binding in combination with brevetoxin, which is a ligand for neurotoxin site 5 on the voltage-gated sodium channel. Positive allosteric interactions were not observed between ATX and either alpha-scorpion toxin or the pyrethroid deltamethrin. That ATX interaction with voltage-gated sodium channels produces a gain of function was demonstrated by the concentration-dependent and tetrodotoxin-sensitive stimulation of 22Na+ influx in cerebellar granule cells exposed to ATX. Together these results demonstrate that the lipopeptide ATX is an activator of voltage-gated sodium channels. The neurotoxic actions of ATX therefore resemble those of brevetoxins that produce neural insult through depolarization-evoked Na+ load, glutamate release, relief of Mg2+ block of NMDA receptors, and Ca2+ influx. (+info)
A phenylalanine residue at segment D3-S6 in Nav1.4 voltage-gated Na(+) channels is critical for pyrethroid action.
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Mammalian voltage-gated Na(+) channels were less sensitive to pyrethroids than their insect counterparts by 2 to 3 orders of magnitude. Deltamethrin at 10 microM elicited weak gating changes in rat skeletal muscle alpha-subunit Na(+) channels (Nav1.4) after > 30 min of perfusion. About 10% of the peak current was maintained during the 8-ms, +50-mV pulse and, upon repolarization to -140 mV, the amplitude of the slow tail current corresponded to less than 3% of total Na(+) channels modified by deltamethrin. A background mutation, Nav1.4-I687M (within D2:S4-S5 cytoplasmic linker), enhanced the deltamethrin-induced maintained current by approximately 2.5-fold, whereas Nav1.4-I687T, a homologous superkdr mutation, reduced it by approximately 2-fold. Repetitive pulses at 2 Hz further augmented the effects of deltamethrin on Nav1.4-I687M mutant channels so that approximately 75% of peak currents were maintained. A second mutation, Nav1.4-I687M/F1278I at the middle of D3-S6, rendered the channel greatly resistant to deltamethrin. This double mutant channel remained sensitive to batrachotoxin (BTX), even though nearby residues S1276 and L1280 were critical for BTX action. We hypothesize that the deltamethrin receptor and the BTX receptor are situated at the middle but opposite surface of the D3-S6 alpha-helical structure. Another mutant, Nav1.4-I687M/N784K, exhibited a partial deltamethrin-resistant phenotype but was completely resistant to BTX. Consistent with the BTX-resistant phenotype of N784K and the known adjacent kdr mutation at position L785F, deltamethrin and BTX were probably situated next to each other upon binding at D2-S6. Evidently, distinct residues from multiple S6 segments were critical for deltamethrin and BTX actions. (+info)
Activation of the action potential Na+ ionophore of cultured neuroblastoma cells by veratridine and batrachotoxin.
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The activation of the action potential Na+ ionophore by veratridine and batrachotoxin is time- and concentration-dependent and completely reversible. Batrachotoxin acts more slowly than veratridine. The concentration dependence of activation at equilibrium suggests reversible interaction of each toxin with a single class of independent sites having dissociation constants at physiologic ion concentrations of 80 plus or minus 13 muM for veratridine and 0.4 plus or minus muM for batrachotoxin. The maximum velocity of Na+ uptake at 50 mM Na+ is 128 plus or minus 12 nmol/min/mg in the presence of batrachotoxin compared to 48 plus or minus 4 nmol/min/mg in the presence of veratridine. Treatment of cells with excess veratridine in addition to batrachotoxin inhibits batrachotoxin-dependent 22-Na+ uptake. The concentration dependence of this inhibition suggests that it reflects competitive displacement of batrachotoxin from its binding site by veratridine. The activation by veratridine and batrachotoxin is inhibited in a competitive manner by divalent cations. The inhibition by divalent cations exhibits significant ion specificity with Mn-2+ greater than Co-2+ greater than Ni-2+ greater than Ca-2+ greater than Mg-2+ greater than Sr-2+. The inhibition constants (KI) for Ca-2+ are 0.84 mM for veratridine-dependent 22-Na+ uptake and 1.2 mM for batrachotoxin-dependent 22-Na+ uptake. The activation by veratridine and batrachotoxin is inhibited in a noncompetitive manner by tetrodotoxin. The apparent KD for tetrodotoxin as 11 plus or minus 1 nM in the presence of 150 mM Na+ and approximately 8.5 nM in 50 mM Na+. Divalent cations do not affect the apparent KD for tetrodotoxin. A hypothesis is presented which suggests that batrachotoxin, veratridine, and divalent cations interact with an activation site associated with the action potential Na+ ionophore, whereas tetrodotoxin interacts with a physically and functionally independent site involved in the transport of monovalent cations by the ionophore. (+info)
Comparison of aconitine-modified human heart (hH1) and rat skeletal (mu1) muscle Na+ channels: an important role for external Na+ ions.
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Neurotoxins such as aconitine (AC) bind to receptor site 2 on voltage-gated sodium channels and modify channel kinetics. Although AC modification typically induces hyperpolarizing shifts in sodium channel activation, the effects on channel inactivation seem to vary depending on the tissue origin of the channel. In the present study, the alpha subunits of human heart (hH1) and rat skeletal muscle (mu1) sodium channels were transiently expressed in human embryonic kidney (HEK293t) cells. Whole-cell currents were examined before and after AC modification of the channels to determine whether the toxin had isoform-specific effects on channel kinetics. The magnitudes of the hyperpolarizing shifts in steady-state current activation and inactivation were similar for AC-modified hH1 and mu1 channels, and AC modification did not alter the voltage dependence of macroscopic current decay of either channel subtype. There were two notable differences between hH1 and mu1 channels after AC modification. First, the steady-state availability of AC-modified mu1 channels decreased by 5-10% after very negative conditioning pulses. Second, AC-modified mu1 channels inactivated completely at all voltages, whereas AC-modified hH1 channels exhibited sustained inward currents at voltages near the threshold of current activation. Interestingly, AC-modified hH1 channels inactivated completely if the external solution did not contain sodium ions. The data demonstrate that AC modification affects the activation of hH1 and mu1 channels similarly but affects inactivation of the two channels distinctly. The results also imply that the reduced inactivation of AC-modified hH1 channels at least partially depends on the presence of extracellular sodium. (+info)