RESUMO
The interaction of insect-selective scorpion depressant ß-toxins (LqhIT2 and Lqh-dprIT3 from Leiurus quinquestriatus hebraeus) with the Blattella germanica sodium channel, BgNav1-1a, was investigated using site-directed mutagenesis, electrophysiological analyses, and structural modeling. Focusing on the pharmacologically defined binding site-4 of scorpion ß-toxins at the voltage-sensing domain II (VSD-II), we found that charge neutralization of D802 in VSD-II greatly enhanced the channel sensitivity to Lqh-dprIT3. This was consistent with the high sensitivity of the splice variant BgNav2-1, bearing G802, to Lqh-dprIT3, and low sensitivity of BgNav2-1 mutant, G802D, to the toxin. Further mutational and electrophysiological analyses revealed that the sensitivity of the WT = D802E < D802G < D802A < D802K channel mutants to Lqh-dprIT3 correlated with the depolarizing shifts of activation in toxin-free channels. However, the sensitivity of single mutants involving IIS4 basic residues (K4E = WT << R1E < R2E < R3E) or double mutants (D802K = K4E/D802K = R3E/D802K > R2E/D802K > R1E/D802K > WT) did not correlate with the activation shifts. Using the cryo-EM structure of the Periplaneta americana channel, NavPaS, as a template and the crystal structure of LqhIT2, we constructed structural models of LqhIT2 and Lqh-dprIT3-c in complex with BgNav1-1a. These models along with the mutational analysis suggest that depressant toxins approach the salt-bridge between R1 and D802 at VSD-II to form contacts with linkers IIS1-S2, IIS3-S4, IIIP5-P1 and IIIP2-S6. Elimination of this salt-bridge enables deeper penetration of the toxin into a VSD-II gorge to form new contacts with the channel, leading to increased channel sensitivity to Lqh-dprIT3.
Assuntos
Neópteros/metabolismo , Venenos de Escorpião/metabolismo , Escorpiões/metabolismo , Canais de Sódio/metabolismo , Animais , Sítios de Ligação/genética , Ativação do Canal Iônico/genética , Ativação do Canal Iônico/fisiologia , Potenciais da Membrana/genética , Potenciais da Membrana/fisiologia , Modelos Moleculares , Mutação , Neópteros/genética , Oócitos/metabolismo , Oócitos/fisiologia , Técnicas de Patch-Clamp/métodos , Ligação Proteica , Domínios Proteicos , Mapeamento de Interação de Proteínas , Venenos de Escorpião/química , Venenos de Escorpião/genética , Escorpiões/genética , Canais de Sódio/química , Canais de Sódio/genética , XenopusRESUMO
Voltage-dependent potassium channels (Kvs) gate in response to changes in electrical membrane potential by coupling a voltage-sensing module with a K+-selective pore. Animal toxins targeting Kvs are classified as pore blockers, which physically plug the ion conduction pathway, or as gating modifiers, which disrupt voltage sensor movements. A third group of toxins blocks K+ conduction by an unknown mechanism via binding to the channel turrets. Here, we show that Conkunitzin-S1 (Cs1), a peptide toxin isolated from cone snail venom, binds at the turrets of Kv1.2 and targets a network of hydrogen bonds that govern water access to the peripheral cavities that surround the central pore. The resulting ectopic water flow triggers an asymmetric collapse of the pore by a process resembling that of inherent slow inactivation. Pore modulation by animal toxins exposes the peripheral cavity of K+ channels as a novel pharmacological target and provides a rational framework for drug design.
Assuntos
Membrana Celular/efeitos dos fármacos , Proteínas de Drosophila/antagonistas & inibidores , Ativação do Canal Iônico/efeitos dos fármacos , Canal de Potássio Kv1.2/antagonistas & inibidores , Venenos de Moluscos/toxicidade , Superfamília Shaker de Canais de Potássio/antagonistas & inibidores , Animais , Membrana Celular/metabolismo , Cristalografia por Raios X , Proteínas de Drosophila/genética , Proteínas de Drosophila/isolamento & purificação , Proteínas de Drosophila/metabolismo , Desenho de Fármacos , Feminino , Ligação de Hidrogênio/efeitos dos fármacos , Canal de Potássio Kv1.2/genética , Canal de Potássio Kv1.2/isolamento & purificação , Canal de Potássio Kv1.2/metabolismo , Dose Letal Mediana , Simulação de Acoplamento Molecular , Simulação de Dinâmica Molecular , Venenos de Moluscos/química , Mutação , Oócitos , Proteínas Recombinantes/genética , Proteínas Recombinantes/isolamento & purificação , Proteínas Recombinantes/metabolismo , Superfamília Shaker de Canais de Potássio/genética , Superfamília Shaker de Canais de Potássio/isolamento & purificação , Superfamília Shaker de Canais de Potássio/metabolismo , Água/química , Água/metabolismo , Xenopus laevisRESUMO
Searching for compounds that inhibit the growth of photosynthetic organisms highlighted a prominent effect at micromolar concentrations of the nitroheteroaromatic thioether, 2-nitrothiophene, applied in the light. Since similar effects were reminiscent to those obtained also by radicals produced under excessive illumination or by herbicides, and in light of its redox potential, we suspected that 2-nitrothiophene was reduced by ferredoxin, a major reducing compound in the light. In silico examination using docking and tunneling computing algorithms of the putative interaction between 2-nitrothiophene and cyanobacterial ferredoxin has suggested a site of interaction enabling robust electron transfer from the iron-sulfur cluster of ferredoxin to the nitro group of 2-nitrothiophene. ESR and oximetry analyses of cyanobacterial cells (Anabaena PCC7120) treated with 50â µM 2-nitrothiophene under illumination revealed accumulation of oxygen radicals and peroxides. Gas chromatography mass spectrometry analysis of 2-nitrothiophene-treated cells identified cytotoxic nitroso and non-toxic amino derivatives. These products of the degradation pathway of 2-nitrohiophene, which initializes with a single electron transfer that forms a short-live anion radical, are then decomposed to nitrate and thiophene, and may be further reduced to a nitroso hydroxylamine and amino derivatives. This mechanism of toxicity is similar to that of nitroimidazoles (e.g. ornidazole and metronidazole) reduced by ferredoxin in anaerobic bacteria and protozoa, but differs from that of ornidazole in planta.
Assuntos
Anabaena/metabolismo , Ferredoxinas/metabolismo , Herbicidas/metabolismo , Fotossíntese/fisiologia , Tiofenos/metabolismo , Anabaena/efeitos dos fármacos , Ferredoxinas/farmacologia , Herbicidas/farmacologia , Fotossíntese/efeitos dos fármacos , Estrutura Terciária de Proteína , Tiofenos/químicaRESUMO
Ornidazole of the 5-nitroimidazole drug family is used to treat protozoan and anaerobic bacterial infections via a mechanism that involves preactivation by reduction of the nitro group, and production of toxic derivatives and radicals. Metronidazole, another drug family member, has been suggested to affect photosynthesis by draining electrons from the electron carrier ferredoxin, thus inhibiting NADP+ reduction and stimulating radical and peroxide production. Here we show, however, that ornidazole inhibits photosynthesis via a different mechanism. While having a minute effect on the photosynthetic electron transport and oxygen photoreduction, ornidazole hinders the activity of two Calvin cycle enzymes, triose-phosphate isomerase (TPI) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH). Modeling of ornidazole's interaction with ferredoxin of the protozoan Trichomonas suggests efficient electron tunneling from the iron-sulfur cluster to the nitro group of the drug. A similar docking site of ornidazole at the plant-type ferredoxin does not exist, and the best simulated alternative does not support such efficient tunneling. Notably, TPI was inhibited by ornidazole in the dark or when electron transport was blocked by dichloromethyl diphenylurea, indicating that this inhibition was unrelated to the electron transport machinery. Although TPI and GAPDH isoenzymes are involved in glycolysis and gluconeogenesis, ornidazole's effect on respiration of photoautotrophs is moderate, thus raising its value as an efficient inhibitor of photosynthesis. The scarcity of Calvin cycle inhibitors capable of penetrating cell membranes emphasizes on the value of ornidazole for studying the regulation of this cycle.
Assuntos
Bactérias Anaeróbias/efeitos dos fármacos , Ornidazol/farmacologia , Fotossíntese/efeitos dos fármacos , Cianobactérias/efeitos dos fármacos , Ferredoxinas/metabolismo , Gliceraldeído-3-Fosfato Desidrogenase (Fosforiladora)/metabolismo , Gliceraldeído-3-Fosfato Desidrogenases/metabolismo , Glicólise , Metronidazol/farmacologia , Modelos Biológicos , Synechocystis/efeitos dos fármacos , Trichomonas/efeitos dos fármacos , Trichomonas/metabolismo , Triose-Fosfato Isomerase/metabolismoRESUMO
Av3 is a peptide neurotoxin from the sea anemone Anemonia viridis that shows specificity for arthropod voltage-gated sodium channels (Navs). Interestingly, Av3 competes with a scorpion α-toxin on binding to insect Navs and similarly inhibits the inactivation process, and thus has been classified as 'receptor site-3 toxin', although the two peptides are structurally unrelated. This raises questions as to commonalities and differences in the way both toxins interact with Navs. Recently, site-3 was partly resolved for scorpion α-toxins highlighting S1-S2 and S3-S4 external linkers at the DIV voltage-sensor module and the juxtaposed external linkers at the DI pore module. To uncover channel determinants involved in Av3 specificity for arthropods, the toxin was examined on channel chimaeras constructed with the external linkers of the mammalian brain Nav1.2a, which is insensitive to Av3, in the background of the Drosophila DmNav1. This approach highlighted the role of linker DI/SS2-S6, adjacent to the channel pore, in determining Av3 specificity. Point mutagenesis at DI/SS2-S6 accompanied by functional assays highlighted Trp404 and His405 as a putative point of Av3 interaction with DmNav1. His405 conservation in arthropod Navs compared with tyrosine in vertebrate Navs may represent an ancient substitution that explains the contemporary selectivity of Av3. Trp404 and His405 localization near the membrane surface and the hydrophobic bioactive surface of Av3 suggest that the toxin possibly binds at a cleft by DI/S6. A partial overlap in receptor site-3 of both toxins nearby DI/S6 may explain their binding competition capabilities.
Assuntos
Proteínas de Drosophila/química , Proteínas de Drosophila/metabolismo , Drosophila/química , Drosophila/metabolismo , Toxinas Marinhas/química , Anêmonas-do-Mar/metabolismo , Bloqueadores dos Canais de Sódio/química , Canais de Sódio/química , Canais de Sódio/metabolismo , Animais , Sítios de Ligação , Drosophila/efeitos dos fármacos , Drosophila/genética , Proteínas de Drosophila/genética , Toxinas Marinhas/metabolismo , Toxinas Marinhas/toxicidade , Neurotoxinas/química , Neurotoxinas/metabolismo , Neurotoxinas/toxicidade , Anêmonas-do-Mar/química , Bloqueadores dos Canais de Sódio/metabolismo , Bloqueadores dos Canais de Sódio/toxicidade , Canais de Sódio/genética , Xenopus laevisRESUMO
The α-scorpions toxins bind to the resting state of Na(+) channels and inhibit fast inactivation by interaction with a receptor site formed by domains I and IV. Mutants T1560A, F1610A, and E1613A in domain IV had lower affinities for Leiurus quinquestriatus hebraeus toxin II (LqhII), and mutant E1613R had ~73-fold lower affinity. Toxin dissociation was accelerated by depolarization and increased by these mutations, whereas association rates at negative membrane potentials were not changed. These results indicate that Thr1560 in the S1-S2 loop, Phe1610 in the S3 segment, and Glu1613 in the S3-S4 loop in domain IV participate in toxin binding. T393A in the SS2-S6 loop in domain I also had lower affinity for LqhII, indicating that this extracellular loop may form a secondary component of the receptor site. Analysis with the Rosetta-Membrane algorithm resulted in a model of LqhII binding to the voltage sensor in a resting state, in which amino acid residues in an extracellular cleft formed by the S1-S2 and S3-S4 loops in domain IV interact with two faces of the wedge-shaped LqhII molecule. The conserved gating charges in the S4 segment are in an inward position and form ion pairs with negatively charged amino acid residues in the S2 and S3 segments of the voltage sensor. This model defines the structure of the resting state of a voltage sensor of Na(+) channels and reveals its mode of interaction with a gating modifier toxin.
Assuntos
Venenos de Escorpião/metabolismo , Canais de Sódio/química , Canais de Sódio/metabolismo , Aminoácidos/metabolismo , Ativação do Canal Iônico , Cinética , Modelos Moleculares , Mutação/genética , Estrutura Terciária de Proteína , Receptores de Superfície Celular/química , Receptores de Superfície Celular/metabolismo , Proteínas Recombinantes/metabolismoRESUMO
Activation of voltage-gated sodium (Na(v)) channels initiates and propagates action potentials in electrically excitable cells. ß-Scorpion toxins, including toxin IV from Centruroides suffusus suffusus (CssIV), enhance activation of Na(V) channels. CssIV stabilizes the voltage sensor in domain II in its activated state via a voltage-sensor trapping mechanism. Amino acid residues required for the action of CssIV have been identified in the S1-S2 and S3-S4 extracellular loops of domain II. The extracellular loops of domain III are also involved in toxin action, but individual amino acid residues have not been identified. We used site-directed mutagenesis and voltage clamp recording to investigate amino acid residues of domain III that are involved in CssIV action. In the IIISS2-S6 loop, five substitutions at four positions altered voltage-sensor trapping by CssIV(E15A). Three substitutions (E1438A, D1445A, and D1445Y) markedly decreased voltage-sensor trapping, whereas the other two substitutions (N1436G and L1439A) increased voltage-sensor trapping. These bidirectional effects suggest that residues in IIISS2-S6 make both positive and negative interactions with CssIV. N1436G enhanced voltage-sensor trapping via increased binding affinity to the resting state, whereas L1439A increased voltage-sensor trapping efficacy. Based on these results, a three-dimensional model of the toxin-channel interaction was developed using the Rosetta modeling method. These data provide additional molecular insight into the voltage-sensor trapping mechanism of toxin action and define a three-point interaction site for ß-scorpion toxins on Na(V) channels. Binding of α- and ß-scorpion toxins to two distinct, pseudo-symmetrically organized receptor sites on Na(V) channels acts synergistically to modify channel gating and paralyze prey.
Assuntos
Ativação do Canal Iônico/efeitos dos fármacos , Canal de Sódio Disparado por Voltagem NAV1.2/metabolismo , Venenos de Escorpião/farmacologia , Substituição de Aminoácidos , Animais , Linhagem Celular , Ativação do Canal Iônico/genética , Mutação de Sentido Incorreto , Canal de Sódio Disparado por Voltagem NAV1.2/genética , Estrutura Secundária de Proteína , Estrutura Terciária de Proteína , RatosRESUMO
Scorpion ß-toxins bind to the extracellular regions of the voltage-sensing module of domain II and to the pore module of domain III in voltage-gated sodium channels and enhance channel activation by trapping and stabilizing the voltage sensor of domain II in its activated state. We investigated the interaction of a highly potent insect-selective scorpion depressant ß-toxin, Lqh-dprIT(3), from Leiurus quinquestriatus hebraeus with insect sodium channels from Blattella germanica (BgNa(v)). Like other scorpion ß-toxins, Lqh-dprIT(3) shifts the voltage dependence of activation of BgNa(v) channels expressed in Xenopus oocytes to more negative membrane potentials but only after strong depolarizing prepulses. Notably, among 10 BgNa(v) splice variants tested for their sensitivity to the toxin, only BgNa(v)1-1 was hypersensitive due to an L1285P substitution in IIIS1 resulting from a U-to-C RNA-editing event. Furthermore, charge reversal of a negatively charged residue (E1290K) at the extracellular end of IIIS1 and the two innermost positively charged residues (R4E and R5E) in IIIS4 also increased the channel sensitivity to Lqh-dprIT(3). Besides enhancement of toxin sensitivity, the R4E substitution caused an additional 20-mV negative shift in the voltage dependence of activation of toxin-modified channels, inducing a unique toxin-modified state. Our findings provide the first direct evidence for the involvement of the domain III voltage-sensing module in the action of scorpion ß-toxins. This hypersensitivity most likely reflects an increase in IIS4 trapping via allosteric mechanisms, suggesting coupling between the voltage sensors in neighboring domains during channel activation.
Assuntos
Blattellidae/metabolismo , Proteínas de Insetos/metabolismo , Ativação do Canal Iônico/efeitos dos fármacos , Venenos de Escorpião/farmacologia , Canais de Sódio/metabolismo , Regulação Alostérica/efeitos dos fármacos , Regulação Alostérica/fisiologia , Processamento Alternativo/fisiologia , Substituição de Aminoácidos , Animais , Blattellidae/química , Blattellidae/genética , Expressão Gênica , Proteínas de Insetos/química , Proteínas de Insetos/genética , Mutação de Sentido Incorreto , Estrutura Terciária de Proteína , Venenos de Escorpião/química , Escorpiões/química , Canais de Sódio/química , Canais de Sódio/genética , XenopusRESUMO
Neurotoxin receptor site-3 at voltage-gated Na(+) channels is recognized by various peptide toxin inhibitors of channel inactivation. Despite extensive studies of the effects of these toxins, their mode of interaction with the channel remained to be described at the molecular level. To identify channel constituents that interact with the toxins, we exploited the opposing preferences of LqhαIT and Lqh2 scorpion α-toxins for insect and mammalian brain Na(+) channels. Construction of the DIV/S1-S2, DIV/S3-S4, DI/S5-SS1, and DI/SS2-S6 external loops of the rat brain rNa(v)1.2a channel (highly sensitive to Lqh2) in the background of the Drosophila DmNa(v)1 channel (highly sensitive to LqhαIT), and examination of toxin activity on the channel chimera expressed in Xenopus oocytes revealed a substantial decrease in LqhαIT effect, whereas Lqh2 was as effective as at rNa(v)1.2a. Further substitutions of individual loops and specific residues followed by examination of gain or loss in Lqh2 and LqhαIT activities highlighted the importance of DI/S5-S6 (pore module) and the C-terminal region of DIV/S3 (gating module) of rNa(v)1.2a for Lqh2 action and selectivity. In contrast, a single substitution of Glu-1613 to Asp at DIV/S3-S4 converted rNa(v)1.2a to high sensitivity toward LqhαIT. Comparison of depolarization-driven dissociation of Lqh2 and mutant derivatives off their binding site at rNa(v)1.2a mutant channels has suggested that the toxin core domain interacts with the gating module of DIV. These results constitute the first step in better understanding of the way scorpion α-toxins interact with voltage-gated Na(+)-channels at the molecular level.
Assuntos
Venenos de Escorpião/metabolismo , Escorpiões/metabolismo , Canais de Sódio/química , Motivos de Aminoácidos , Sequência de Aminoácidos , Animais , Encéfalo/metabolismo , DNA Complementar/metabolismo , Drosophila , Conformação Molecular , Dados de Sequência Molecular , Mutagênese , Mutação , Neurotoxinas/metabolismo , Ratos , Anêmonas-do-Mar , Homologia de Sequência de Aminoácidos , XenopusRESUMO
Voltage-gated sodium (Na(v)) channels are the molecular targets of ß-scorpion toxins, which shift the voltage dependence of activation to more negative membrane potentials by a voltage sensor-trapping mechanism. Molecular determinants of ß-scorpion toxin (CssIV) binding and action on rat brain sodium channels are located in the S1-S2 (IIS1-S2) and S3-S4 (IIS3-S4) extracellular linkers of the voltage-sensing module in domain II. In IIS1-S2, mutations of two amino acid residues (Glu(779) and Pro(782)) significantly altered the toxin effect by reducing binding affinity. In IIS3-S4, six positions surrounding the key binding determinant, Gly(845), define a hot spot of high-impact residues. Two of these substitutions (A841N and L846A) reduced voltage sensor trapping. The other three substitutions (N842R, V843A, and E844N) increased voltage sensor trapping. These bidirectional effects suggest that the IIS3-S4 loop plays a primary role in determining both toxin affinity and efficacy. A high resolution molecular model constructed with the Rosetta-Membrane modeling system reveals interactions of amino acid residues in sodium channels that are crucial for toxin action with residues in CssIV that are required for its effects. In this model, the wedge-shaped CssIV inserts between the IIS1-S2 and IIS3-S4 loops of the voltage sensor, placing key amino acid residues in position to interact with binding partners in these extracellular loops. These results provide new molecular insights into the voltage sensor-trapping model of toxin action and further define the molecular requirements for the development of antagonists that can prevent or reverse toxicity of scorpion toxins.
Assuntos
Proteínas do Tecido Nervoso/química , Proteínas do Tecido Nervoso/metabolismo , Receptores de Superfície Celular/química , Receptores de Superfície Celular/metabolismo , Venenos de Escorpião/química , Venenos de Escorpião/metabolismo , Canais de Sódio/química , Canais de Sódio/metabolismo , Animais , Ativação do Canal Iônico , Modelos Moleculares , Proteínas Mutantes/química , Proteínas Mutantes/metabolismo , Canal de Sódio Disparado por Voltagem NAV1.2 , Ligação Proteica , Estrutura Terciária de Proteína , Ratos , Relação Estrutura-AtividadeRESUMO
Jellyfish, hydras, corals and sea anemones (phylum Cnidaria) are known for their venomous stinging cells, nematocytes, used for prey and defence. Here we show, however, that the potent Type I neurotoxin of the sea anemone Nematostella vectensis, Nv1, is confined to ectodermal gland cells rather than nematocytes. We demonstrate massive Nv1 secretion upon encounter with a crustacean prey. Concomitant discharge of nematocysts probably pierces the prey, expediting toxin penetration. Toxin efficiency in sea water is further demonstrated by the rapid paralysis of fish or crustacean larvae upon application of recombinant Nv1 into their medium. Analysis of other anemone species reveals that in Anthopleura elegantissima, Type I neurotoxins also appear in gland cells, whereas in the common species Anemonia viridis, Type I toxins are localized to both nematocytes and ectodermal gland cells. The nematocyte-based and gland cell-based envenomation mechanisms may reflect substantial differences in the ecology and feeding habits of sea anemone species. Overall, the immunolocalization of neurotoxins to gland cells changes the common view in the literature that sea anemone neurotoxins are produced and delivered only by stinging nematocytes, and raises the possibility that this toxin-secretion mechanism is an ancestral evolutionary state of the venom delivery machinery in sea anemones.
Assuntos
Venenos de Cnidários/metabolismo , Neurotoxinas/metabolismo , Anêmonas-do-Mar/fisiologia , Animais , Artemia , Evolução Biológica , Venenos de Cnidários/genética , Venenos de Cnidários/toxicidade , Imuno-Histoquímica , Neurotoxinas/genética , Neurotoxinas/toxicidade , Comportamento Predatório , Proteínas Recombinantes/genética , Proteínas Recombinantes/metabolismo , Proteínas Recombinantes/toxicidade , Anêmonas-do-Mar/anatomia & histologia , Anêmonas-do-Mar/genética , Peixe-ZebraRESUMO
Gating of voltage-dependent sodium channels involves coordinated movements of the voltage sensors in the voltage-sensing modules (VSMs) of the four domains (DI-DIV) in response to membrane depolarization. Zhu et al. have recently examined the effects of charge reversal substitutions at the VSM of domain III on the action of scorpion alpha- and beta-toxins that intercept the voltage sensors in domains IV and II, respectively. The increased activity of both toxin types on the mutant channels has suggested that the VSM module at domain III interacts allosterically with the VSM modules in domains IV and II during channel gating thus affecting indirectly the action of both scorpion toxin classes.
RESUMO
Scorpion ß-toxin 4 from Centruroides suffusus suffusus (Css4) enhances the activation of voltage-gated sodium channels through a voltage sensor trapping mechanism by binding the activated state of the voltage sensor in domain II and stabilizing it in its activated conformation. Here we describe the antagonist and partial agonist properties of a mutant derivative of this toxin. Substitution of seven different amino acid residues for Glu(15) in Css4 yielded toxin derivatives with both increased and decreased affinities for binding to neurotoxin receptor site 4 on sodium channels. Css4(E15R) is unique among this set of mutants in that it retained nearly normal binding affinity but lost its functional activity for modification of sodium channel gating in our standard electrophysiological assay for voltage sensor trapping. More detailed analysis of the functional effects of Css4(E15R) revealed weak voltage sensor trapping activity, which was very rapidly reversed upon repolarization and therefore was not observed in our standard assay of toxin effects. This partial agonist activity of Css4(E15R) is observed clearly in voltage sensor trapping assays with brief (5 ms) repolarization between the conditioning prepulse and the test pulse. The effects of Css4(E15R) are fit well by a three-step model of toxin action involving concentration-dependent toxin binding to its receptor site followed by depolarization-dependent activation of the voltage sensor and subsequent voltage sensor trapping. Because it is a partial agonist with much reduced efficacy for voltage sensor trapping, Css4(E15R) can antagonize the effects of wild-type Css4 on sodium channel activation and can prevent paralysis by Css4 when injected into mice. Our results define the first partial agonist and antagonist activities for scorpion toxins and open new avenues of research toward better understanding of the structure-function relationships for toxin action on sodium channel voltage sensors and toward potential toxin-based therapeutics to prevent lethality from scorpion envenomation.
Assuntos
Substituição de Aminoácidos , Ativação do Canal Iônico/efeitos dos fármacos , Modelos Biológicos , Venenos de Escorpião/genética , Venenos de Escorpião/farmacologia , Bloqueadores dos Canais de Sódio/farmacologia , Canais de Sódio/metabolismo , Animais , Sítios de Ligação , Mordeduras e Picadas/terapia , Células CHO , Cricetinae , Cricetulus , Relação Dose-Resposta a Droga , Camundongos , Mutação , Ratos , Ratos Wistar , Venenos de Escorpião/antagonistas & inibidores , Venenos de Escorpião/uso terapêutico , EscorpiõesRESUMO
Alpha-neurotoxins target voltage-gated sodium channels (Na(v)s) and constitute an important component in the venom of Buthidae scorpions. These toxins are short polypeptides highly conserved in sequence and three-dimensional structure, and yet they differ greatly in activity and preference for insect and various mammalian Na(v)s. Despite extensive studies of the structure-function relationship of these toxins, only little is known about their evolution and phylogeny. Using a broad data set based on published sequences and rigorous cloning, we reconstructed a reliable phylogenetic tree of scorpion alpha-toxins and estimated the evolutionary forces involved in the diversification of their genes using maximum likelihood-based methods. Although the toxins are largely conserved, four positions were found to evolve under positive selection, of which two (10 and 18; numbered according to LqhalphaIT and Lqh2 from the Israeli yellow scorpion Leiurus quinquestriatus hebraeus) have been previously shown to affect toxin activity. The putative role of the other two positions (39 and 41) was analyzed by mutagenesis of Lqh2 and LqhalphaIT. Whereas substitution P41K in Lqh2 did not alter its activity, substitution K41P in LqhalphaIT significantly decreased the activity at insect and mammalian Na(v)s. Surprisingly, not only that substitution A39L in both toxins increased their activity by 10-fold but also LqhalphaIT(A39L) was active at the mammalian brain channel rNa(v)1.2a, which otherwise is hardly affected by LqhalphaIT, and Lqh2(A39L) was active at the insect channel, DmNa(v)1, which is almost insensitive to Lqh2. Thus, position 39 is involved not only in activity but also in toxin selectivity. Overall, this study describes evolutionary forces involved in the diversification of scorpion alpha-toxins, highlights the key role of positions under positive selection for selectivity and potency, and raises new questions as to the toxin-channel face of interaction.
Assuntos
Aminoácidos/genética , Evolução Molecular , Venenos de Escorpião/genética , Venenos de Escorpião/farmacologia , Seleção Genética , Sequência de Aminoácidos , Substituição de Aminoácidos/efeitos dos fármacos , Substituição de Aminoácidos/genética , Animais , Sequência de Bases , Insetos , Ativação do Canal Iônico/efeitos dos fármacos , Funções Verossimilhança , Dados de Sequência Molecular , Proteínas Mutantes/química , Proteínas Mutantes/genética , Proteínas Mutantes/metabolismo , Proteínas Mutantes/farmacologia , Filogenia , Ratos , Venenos de Escorpião/química , Venenos de Escorpião/metabolismo , Escorpiões/classificação , Escorpiões/genética , Canais de Sódio/metabolismoRESUMO
Orthophosphate (Pi) stimulates the activation of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) while paradoxically inhibiting its catalysis. Of three Pi-binding sites, the roles of the 5P- and latch sites have been documented, whereas that of the 1P-site remained unclear. Conserved residues at the 1P-site of Rubisco from the cyanobacterium Synechocystis PCC6803 were substituted and the kinetic properties of the enzyme derivatives and effects on cell photosynthesis and growth were examined. While Pi-stimulated Rubisco activation diminished for enzyme mutants T65A/S and G404A, inhibition of catalysis by Pi remained unchanged. Together with previous studies, the results suggest that all three Pi-binding sites are involved in stimulation of Rubisco activation, whereas only the 5P-site is involved in inhibition of catalysis. While all the mutations reduced the catalytic turnover of Rubisco (K(cat)) between 6- and 20-fold, the photosynthesis and growth rates under saturating irradiance and inorganic carbon (Ci) concentrations were only reduced 40-50% (in the T65A/S mutants) or not at all (G404A mutant). Analysis of the mutant cells revealed a 3-fold increase in Rubisco content that partially compensated for the reduced K(cat) so that the carboxylation rate per chlorophyll was one-third of that in the wild type. Correlation between the kinetic properties of Rubisco and the photosynthetic rate (P(max)) under saturating irradiance and Ci concentrations indicate that a >60% reduction in K(cat) can be tolerated before P(max) in Synechocystsis PCC6803 is affected. These results indicate that the limitation of Rubisco activity on the rate of photosynthesis in Synechocystis is low. Determination of Calvin cycle metabolites revealed that unlike in higher plants, cyanobacterial photosynthesis is constrained by phosphoglycerate reduction probably due to limitation of ATP or NADPH.
Assuntos
Mutagênese , Fotossíntese/genética , Ribulose-Bifosfato Carboxilase/genética , Synechocystis/enzimologia , Synechocystis/crescimento & desenvolvimento , Substituição de Aminoácidos/genética , Sítios de Ligação , Biocatálise/efeitos dos fármacos , Clorofila/metabolismo , Ativação Enzimática/efeitos dos fármacos , Cinética , Mutagênese/efeitos dos fármacos , Proteínas Mutantes/metabolismo , Oxigênio/metabolismo , Fosfatos/farmacologia , Fotossíntese/efeitos dos fármacos , Ligação Proteica/efeitos dos fármacos , Ribulose-Bifosfato Carboxilase/metabolismo , Synechocystis/efeitos dos fármacos , Synechocystis/genética , Synechocystis/ultraestruturaRESUMO
Scorpion α-toxins bind at the pharmacologically-defined site-3 on the sodium channel and inhibit channel inactivation by preventing the outward movement of the voltage sensor in domain IV (IVS4), whereas scorpion ß-toxins bind at site-4 on the sodium channel and enhance channel activation by trapping the voltage sensor of domain II (IIS4) in its outward position. However, limited information is available on the role of the voltage-sensing modules (VSM, comprising S1-S4) of domains I and III in toxin actions. We have previously shown that charge reversing substitutions of the innermost positively-charged residues in IIIS4 (R4E, R5E) increase the activity of an insect-selective site-4 scorpion toxin, Lqh-dprIT3-c, on BgNav1-1a, a cockroach sodium channel. Here we show that substitutions R4E and R5E in IIIS4 also increase the activity of two site-3 toxins, LqhαIT from Leiurusquinquestriatus hebraeus and insect-selective Av3 from Anemonia viridis. Furthermore, charge reversal of either of two conserved negatively-charged residues, D1K and E2K, in IIIS2 also increase the action of the site-3 and site-4 toxins. Homology modeling suggests that S2-D1 and S2-E2 interact with S4-R4 and S4-R5 in the VSM of domain III (III-VSM), respectively, in the activated state of the channel. However, charge swapping between S2-D1 and S4-R4 had no compensatory effects on gating or toxin actions, suggesting that charged residue interactions are complex. Collectively, our results highlight the involvement of III-VSM in the actions of both site 3 and site 4 toxins, suggesting that charge reversing substitutions in III-VSM allosterically facilitate IIS4 or IVS4 voltage sensor trapping by these toxins.
Assuntos
Venenos de Cnidários/farmacologia , Drosophila melanogaster/genética , Proteínas de Insetos/genética , Venenos de Escorpião/farmacologia , Canais de Sódio/genética , Animais , Drosophila melanogaster/efeitos dos fármacos , Drosophila melanogaster/metabolismo , Proteínas de Insetos/metabolismo , Oócitos/efeitos dos fármacos , Oócitos/metabolismo , Canais de Sódio/metabolismoRESUMO
The voltage sensor is a four-transmembrane helix bundle (S1-S4) that couples changes in membrane potential to conformational alterations in voltage-gated ion channels leading to pore opening and ion conductance. Although the structure of the voltage sensor in activated potassium channels is available, the conformation of the voltage sensor at rest is still obscure, limiting our understanding of the voltage-sensing mechanism. By employing a heterologously expressed Bacillus halodurans sodium channel (NaChBac), we defined constraints that affect the positioning and depolarization-induced outward motion of the S4 segment. We compared macroscopic currents mediated by NaChBac and mutants in which E43 on the S1 segment and the two outermost arginines (R1 and R2) on S4 were substituted. Neutralization of the negatively charged E43 (E43C) had a significant effect on channel gating. A double-mutant cycle analysis of E43 and R1 or R2 suggested changes in pairing during channel activation, implying that the interaction of E43 with R1 stabilizes the voltage sensor in its closed/available state, whereas interaction of E43 with R2 stabilizes the channel open/unavailable state. These constraints on S4 dynamics that define its stepwise movement upon channel activation and positioning at rest are novel, to the best of our knowledge, and compatible with the helical-screw and electrostatic models of S4 motion.
Assuntos
Aminoácidos/metabolismo , Proteínas de Bactérias/química , Proteínas de Bactérias/metabolismo , Ativação do Canal Iônico , Canais de Sódio/química , Canais de Sódio/metabolismo , Sequência de Aminoácidos , Substituição de Aminoácidos/genética , Dados de Sequência Molecular , Proteínas Mutantes/química , Proteínas Mutantes/metabolismo , Mutação/genética , Estrutura Secundária de Proteína , Alinhamento de Sequência , Relação Estrutura-AtividadeRESUMO
The scorpion alpha-toxin Lqh2 (from Leiurus quinquestriatus hebraeus) is active at various mammalian voltage-gated sodium channels (Na(v)s) and is inactive at insect Na(v)s. To resolve the molecular basis of this preference we used the following strategy: 1) Lqh2 was expressed in recombinant form and key residues important for activity at the rat brain channel rNa(v)1.2a were identified by mutagenesis. These residues form a bipartite functional surface made of a conserved "core domain" (residues of the loops connecting the secondary structure elements of the molecule core), and a variable "NC domain" (five-residue turn and the C-tail) as was reported for other scorpion alpha-toxins. 2) The functional role of the two domains was validated by their stepwise construction on the similar scaffold of the anti-insect toxin LqhalphaIT. Analysis of the activity of the intermediate constructs highlighted the critical role of Phe(15) of the core domain in toxin potency at rNa(v)1.2a, and has suggested that the shape of the NC-domain is important for toxin efficacy. 3) Based on these findings and by comparison with other scorpion alpha-toxins we were able to eliminate the activity of Lqh2 at rNa(v)1.4 (skeletal muscle), hNa(v)1.5 (cardiac), and rNa(v)1.6 channels, with no hindrance of its activity at Na(v)1.1-1.3. These results suggest that by employing a similar approach the design of further target-selective sodium channel modifiers is imminent.
Assuntos
Ativação do Canal Iônico , Venenos de Escorpião/química , Venenos de Escorpião/metabolismo , Canais de Sódio/metabolismo , Animais , Humanos , Modelos Moleculares , Mutagênese , Proteínas Mutantes/metabolismo , Estrutura Secundária de Proteína , Ratos , Ratos Wistar , Propriedades de Superfície , XenopusRESUMO
Gene families, which encode toxins, are found in many poisonous animals, yet there is limited understanding of their evolution at the nucleotide level. The release of the genome draft sequence for the sea anemone Nematostella vectensis enabled a comprehensive study of a gene family whose neurotoxin products affect voltage-gated sodium channels. All gene family members are clustered in a highly repetitive approximately 30-kb genomic region and encode a single toxin, Nv1. These genes exhibit extreme conservation at the nucleotide level which cannot be explained by purifying selection. This conservation greatly differs from the toxin gene families of other animals (e.g., snakes, scorpions, and cone snails), whose evolution was driven by diversifying selection, thereby generating a high degree of genetic diversity. The low nucleotide diversity at the Nv1 genes is reminiscent of that reported for DNA encoding ribosomal RNA (rDNA) and 2 hsp70 genes from Drosophila, which have evolved via concerted evolution. This evolutionary pattern was experimentally demonstrated in yeast rDNA and was shown to involve unequal crossing-over. Through sequence analysis of toxin genes from multiple N. vectensis populations and 2 other anemone species, Anemonia viridis and Actinia equina, we observed that the toxin genes for each sea anemone species are more similar to one another than to those of other species, suggesting they evolved by manner of concerted evolution. Furthermore, in 2 of the species (A. viridis and A. equina) we found genes that evolved under diversifying selection, suggesting that concerted evolution and accelerated evolution may occur simultaneously.