Mapping the interaction surface of scorpion ß-toxins with an insect sodium channel.

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.

[Safety toxicological evaluation of Wen Radix Codonopsis].

OBJECTIVE: To evaluate the toxicological safety of Wen Radix Codonopsis. METHODS: According to the national standards of food safety(GB 15193.3-2014, GB 15193.4-2014, GB 15193.5-2014, GB 15193.8-2014, GB 15193.13-2015), acute oral toxicity test, three genetic toxicity tests(including bacterial recovery mutation test, mammalian erythrocyte micronucleus test and mouse spermatocyte chromosome aberration test) and subchronic toxicity test were conducted in this study. RESULTS: The LD_(50) of Wen Radix Codonopsis to KM mouse was more than 38.72 g/kg, which was actually non-toxic according to the acute toxicity grading standard of mouse. The results of three genetic toxicity tests were negative and no obvious genotoxicity was observed. 90-day oral toxicity test showed that the overall growth condition of the rats in each group was good, and the test index result of each test group showed no statistical significance compared with the negative control group, and all of them were within the normal range in our laboratory. No abnormality was observed in gross anatomy, and no histopathological changes and specific lesions associated with the test substances were found. CONCLUSION: No obvious acute oral toxicity, genetic toxicity and subchronic toxicity were observed in Wen Radix Codonopsis under the present conditions.

Small heat shock protein 20 interacts with protein phosphatase-1 and enhances sarcoplasmic reticulum calcium cycling.

BACKGROUND: Heat shock proteins (Hsp) are known to enhance cell survival under various stress conditions. In the heart, the small Hsp20 has emerged as a key mediator of protection against apoptosis, remodeling, and ischemia/reperfusion injury. Moreover, Hsp20 has been implicated in modulation of cardiac contractility ex vivo. The objective of this study was to determine the in vivo role of Hsp20 in the heart and the mechanisms underlying its regulatory effects in calcium (Ca) cycling. METHODS AND RESULTS: Hsp20 overexpression in intact animals resulted in significant enhancement of cardiac function, coupled with augmented Ca cycling and sarcoplasmic reticulum Ca load in isolated cardiomyocytes. This was associated with specific increases in phosphorylation of phospholamban (PLN) at both Ser16 and Thr17, relieving its inhibition of the apparent Ca affinity of SERCA2a. Accordingly, the inotropic effects of Hsp20 were abrogated in cardiomyocytes expressing nonphosphorylatable PLN (S16A/T17A). Interestingly, the activity of type 1 protein phosphatase (PP1), a known regulator of PLN signaling, was significantly reduced by Hsp20 overexpression, suggesting that the Hsp20 stimulatory effects are partially mediated through the PP1-PLN axis. This hypothesis was supported by cell fractionation, coimmunoprecipitation, and coimmunolocalization studies, which revealed an association between Hsp20, PP1, and PLN. Furthermore, recombinant protein studies confirmed a physical interaction between AA 73 to 160 in Hsp20 and AA 163 to 330 in PP1. CONCLUSIONS: Hsp20 is a novel regulator of sarcoplasmic reticulum Ca cycling by targeting the PP1-PLN axis. These findings, coupled with the well-recognized cardioprotective role of Hsp20, suggest a dual benefit of targeting Hsp20 in heart disease.

Substitutions in the domain III voltage-sensing module enhance the sensitivity of an insect sodium channel to a scorpion beta-toxin.

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.

A negative charge in transmembrane segment 1 of domain II of the cockroach sodium channel is critical for channel gating and action of pyrethroid insecticides.

Voltage-gated sodium channels are the primary target of pyrethroids, an important class of synthetic insecticides. Pyrethroids bind to a distinct receptor site on sodium channels and prolong the open state by inhibiting channel deactivation and inactivation. Recent studies have begun to reveal sodium channel residues important for pyrethroid binding. However, how pyrethroid binding leads to inhibition of sodium channel deactivation and inactivation remains elusive. In this study, we show that a negatively charged aspartic acid residue at position 802 (D802) located in the extracellular end of transmembrane segment 1 of domain II (IIS1) is critical for both the action of pyrethroids and the voltage dependence of channel activation. Charge-reversing or -neutralizing substitutions (K, G, or A) of D802 shifted the voltage dependence of activation in the depolarizing direction and reduced channel sensitivity to deltamethrin, a pyrethroid insecticide. The charge-reversing mutation D802K also accelerated open-state deactivation, which may have counteracted the inhibition of sodium channel deactivation by deltamethrin. In contrast, the D802G substitution slowed open-state deactivation, suggesting an additional mechanism for neutralizing the action of deltamethrin. Importantly, Schild analysis showed that D802 is not involved in pyrethroid binding. Thus, we have identified a sodium channel residue that is critical for regulating the action of pyrethroids on the sodium channel without affecting the receptor site of pyrethroids.

Mechanism of action of sodium channel blocker insecticides (SCBIs) on insect sodium channels.

Sodium channel blocker insecticides (SCBIs) are a relatively new class of insecticides, with a mechanism of action different from those of other classes of insecticides that target voltage-gated sodium channels. These compounds have no effect at hyperpolarized membrane potentials, but cause a voltage-dependent, nearly irreversible block as the membrane potential is depolarized. The mechanism of action of SCBIs is similar to that of local anesthetics (LAs), class I anticonvulsants and class I antiarrhythmics. In this article, we review the physiological actions of these compounds on the whole animal, the nervous system and sodium channels, and also present the results from recent studies that elucidate the receptor site of SCBIs.

Migration of phthalates from plastic packages to convenience foods and its cumulative health risk assessments.

Convenience foods are commonly packaged with plastic materials. Many of the phthalate plasticizers (PAEs) in the packages may migrate into the foods and cause health hazards. In the present study, the contents of some PAEs were analyzed in 283 convenience foods and the plastic packaging materials. Health hazards were assessed for infants, children and young people. The contents of diethylhexyl phthalate (DEHP), found in the samples rich in fat, ranged from below the limit of detection to 5.23 mg/kg. The content of dibutylphthalate (DBP) ranged from 0.511 mg/kg in meat to 2.54 mg/kg in cake. The content of PAEs in convenience foods near their expiration date was much higher than that of just manufactured packages. Children are more prone to be adversely affected by the PAEs than the adults. In addition, females are more sensitive to the PAEs than males.

Molecular and functional characterization of voltage-gated sodium channel variants from Drosophila melanogaster.

Extensive alternative splicing and RNA editing have been documented for the transcript of DmNa(V) (formerly para), the sole sodium channel gene in Drosophila melanogaster. However, the functional consequences of these post-transcriptional modifications are not well understood. In this study we isolated 64 full-length DmNa(V) cDNA clones from D. melanogaster adults. Based on the usage of 11 alternative exons, 64 clones could be grouped into 29 splice types. When expressed in Xenopus oocytes, 33 DmNa(V) variants generated sodium currents large enough for functional characterization. Among these variants, DmNa(V)5-1 and DmNa(V)7-1 channels activated at the most hyperpolarizing potentials, whereas DmNa(V)1-6 and DmNa(V)19 channels activated at the most depolarizing membrane potentials. We identified an A-to-I editing event in DmNa(V)5-1 that is responsible for its uniquely low-voltage-dependent activation. The wide range of voltage dependence of gating properties exhibited by DmNa(V) variants represents a rich resource for future studies to determine the role of DmNa(V) in regulating sodium channel gating, pharmacology, and neuronal excitability in insects.

Molecular basis of differential sensitivity of insect sodium channels to DCJW, a bioactive metabolite of the oxadiazine insecticide indoxacarb.

Indoxacarb (DPX-JW062) was recently developed as a new oxadiazine insecticide with high insecticidal activity and low mammalian toxicity. Previous studies showed that indoxacarb and its bioactive metabolite, N-decarbomethoxyllated JW062 (DCJW), block insect sodium channels in nerve preparations and isolated neurons. However, the molecular mechanism of indoxacarb/DCJW action on insect sodium channels is not well understood. In this study, we identified two cockroach sodium channel variants, BgNa(v)1-1 and BgNa(v)1-4, which differ in voltage dependence of fast and slow inactivation, and channel sensitivity to DCJW. The voltage dependence of fast inactivation and slow inactivation of BgNa(v)1-4 were shifted in the hyperpolarizing direction compared with those of BgNa(v)1-1 channels. At the holding potential of -90 mV, 20 microM of DCJW reduced the peak current of BgNa(v)1-4 by about 40%, but had no effect on BgNa(v)1-1. However, at the holding potential of -60 mV, DCJW also reduced the peak currents of BgNa(v)1-1 by about 50%. Furthermore, DCJW delayed the recovery from slow inactivation of both variants. Substitution of E1689 in segment 4 of domain four (IVS4) of BgNa(v)1-4 with a K, which is present in BgNa(v)1-1, was sufficient to shift the voltage dependence of fast and slow inactivation of BgNa(v)1-4 channels to the more depolarizing membrane potential close to that of BgNa(v)1-1 channels. The E1689K change also eliminated the DCJW inhibition of BgNa(v)1-4 at the hyperpolarizing holding potentials. These results show that the E1689K change is responsible for the difference in channel gating and sensitivity to DCJW between BgNa(v)1-4 and BgNa(v)1-1. Our results support the notion that DCJW preferably acts on the inactivated state of the sodium channel and demonstrate that K1689E is a major molecular determinant of the voltage-dependent inactivation and state-dependent action of DCJW.

[The cytotoxicity of maitotoxin to LLC-PK(1) and its antagonism to calcium channel blocking agents].

OBJECTIVE: To study the cytotoxicity of maitotoxin (MTX) and its protective effects on calcium-channel blocking agents, so as to provide the data for control and treatment of MTX poisoning. METHODS: Cytotoxicity was measured by MTT detecting system, and cytoplasmic free [Ca(2+)]i was measured by F-4500 fluorometry. RESULTS: Incubation with 8 ng/ml MTX for 3 h reduced the survival ratio of LLC-PK(1) cells. The response was found in a time- and concentration-dependent manner, with significant differences as compared with the control group. The MTX-induced increase in [Ca(2+)]i was inhibited by Verapamil and Nifedipine at 5 x 10(-5) mol/L and 1 x 10(-4) mol/L respectively. Both of them significantly reduced the death of the LLC-PK(1) cells. CONCLUSIONS: Cytotoxicity of MTX may be caused by the elevated intracellular [Ca(2+)]i. Calcium-channel blocking agents could protect LLC-PK(1) cells from injury by MTX.

Low-dose bisphenol A and estrogen increase ventricular arrhythmias following ischemia-reperfusion in female rat hearts.

Bisphenol A (BPA) is an environmental estrogenic endocrine disruptor that may have adverse health impacts on a range of tissue/systems. In previous studies, we reported that BPA rapidly promoted arrhythmias in female rodent hearts through alteration of myocyte calcium handling. In the present study we investigated the acute effects of BPA on ventricular arrhythmias and infarction following ischemia-reperfusion in rat hearts. Rat hearts were subjected to 20 min of global ischemia followed by reperfusion. In female, but not male hearts, acute exposure to 1 nM BPA, either alone or combined with 1 nM 17ß-estradiol (E2), during reperfusion resulted in a marked increase in the duration of sustained ventricular arrhythmias. BPA plus E2 increased the duration ventricular fibrillation, and the duration of VF as a fraction of total duration of sustained ventricular arrhythmia. The pro-arrhythmic effects of estrogens were abolished by MPP combined with PHTPP, suggesting the involvements of both ERα and ERß signaling. In contrast to their pro-arrhythmic effects, BPA and E2 reduced infarction size, agreeing with previously described protective effect of estrogen against cardiac infarction. In conclusion, rapid exposure to low dose BPA, particularly when combined with E2, exacerbates ventricular arrhythmia following IR injury in female rat hearts.

Analysis of the action of lidocaine on insect sodium channels.

A new class of sodium channel blocker insecticides (SCBIs), which include indoxacarb, its active metabolite, DCJW, and metaflumizone, preferably block inactivated states of both insect and mammalian sodium channels in a manner similar to that by which local anesthetic (LA) drugs block mammalian sodium channels. A recent study showed that two residues in the cockroach sodium channel, F1817 and Y1824, corresponding to two key LA-interacting residues identified in mammalian sodium channels are not important for the action of SCBIs on insect sodium channels, suggesting unique interactions of SCBIs with insect sodium channels. However, the mechanism of action of LAs on insect sodium channels has not been investigated. In this study, we examined the effects of lidocaine on a cockroach sodium channel variant, BgNa(v)1-1a, and determined whether F1817 and Y1824 are also critical for the action of LAs on insect sodium channels. Lidocaine blocked BgNa(v)1-1a channels in the resting state with potency similar to that observed in mammalian sodium channels. Lidocaine also stabilized both fast-inactivated and slow-inactivated states of BgNa(v)1-1a channels, and caused a limited degree of use- and frequency-dependent block, major characteristics of LA action on mammalian sodium channels. Alanine substitutions of F1817 and Y1824 reduced the sensitivity of the BgNa(v)1-1a channel to the use-dependent block by lidocaine, but not to tonic blocking and inactivation stabilizing effects of lidocaine. Thus, similar to those on mammalian sodium channels, F1817 and Y1824 are important for the action of lidocaine on cockroach sodium channels. Our results suggest that the receptor sites for lidocaine and SCBIs are different on insect sodium channels.

Molecular characterization and functional expression of the DSC1 channel.

Drosophila Sodium Channel 1 (DSC1) was predicted to encode a sodium channel based on a high sequence similarity with vertebrate and invertebrate sodium channel genes. However, BSC1, a DSC1 ortholog in Blattella germanica, was recently shown to encode a cation channel with ion selectivity toward Ca(2+). In this study, we isolated a total of 20 full-length cDNA clones that cover the entire coding region of the DSC1 gene from adults of Drosophila melanogaster by reverse transcription-polymerase chain reaction. Sequence analysis of the 20 clones revealed nine optional exons, four of which contain in-frame stop codons; and 13 potential A-to-I RNA editing sites. The 20 clones can be grouped into eight splice types and represent 20 different transcripts because of unique RNA editing. Three variants generated DSC1 currents when expressed in Xenopus oocytes. Like the BSC1 channel, all three functional DSC1 channels are permeable to Ca(2+) and Ba(2+), and also to Na(+) in the absence of external Ca(2+). Furthermore, the DSC1 channel is insensitive to tetrodotoxin, a potent and specific sodium channel blocker. Our study shows that DSC1 encodes a voltage-gated cation channel similar to the BSC1 channel in B. germanica. Extensive alternative splicing and RNA editing of the DSC1 transcripts suggest the molecular and functional diversity of the DSC1 channel.

Bisphenol A and 17ß-estradiol promote arrhythmia in the female heart via alteration of calcium handling.

BACKGROUND: There is wide-spread human exposure to bisphenol A (BPA), a ubiquitous estrogenic endocrine disruptor that has been implicated as having potentially harmful effects on human heart health. Higher urine BPA concentrations have been shown to be associated with cardiovascular diseases in humans. However, neither the nature nor the mechanism(s) of BPA action on the heart are understood. METHODOLOGY/PRINCIPAL FINDINGS: The rapid (<7 min) effects of BPA and 17ß-estradiol (E2) in the heart and ventricular myocytes from rodents were investigated in the present study. In isolated ventricular myocytes from young adult females, but not males, physiological concentrations of BPA or E2 (10⁻9 M) rapidly induced arrhythmogenic triggered activities. The effects of BPA were particularly pronounced when combined with estradiol. Under conditions of catecholamine stimulation, E2 and BPA promoted ventricular arrhythmias in female, but not male, hearts. The cellular mechanism of the female-specific pro-arrhythmic effects of BPA and E2 were investigated. Exposure to E2 and/or BPA rapidly altered myocyte Ca²âº handling; in particular, estrogens markedly increased sarcoplasmic reticulum (SR) Ca²âº leak, and increased SR Ca²âº load. Ryanodine (10⁻7 M) inhibition of SR Ca²âº leak suppressed estrogen-induced triggered activities. The rapid response of female myocytes to estrogens was abolished in an estrogen receptor (ER) ß knockout mouse model. CONCLUSIONS/SIGNIFICANCE: Physiologically-relevant concentrations of BPA and E2 promote arrhythmias in a female-specific manner in rat hearts; the pro-arrhythmic actions of estrogens are mediated by ERß-signaling through alterations of myocyte Ca²âº handling, particularly increases in SR Ca²âº leak. Our study provides the first experimental evidence suggesting that exposure to estrogenic endocrine disrupting chemicals and the unique sensitivity of female hearts to estrogens may play a role in arrhythmogenesis in the female heart.

Persistent tetrodotoxin-sensitive sodium current resulting from U-to-C RNA editing of an insect sodium channel.

The persistent tetrodotoxin (TTX)-sensitive sodium current, detected in neurons of many regions of mammalian brains, is associated with many essential neuronal activities, including boosting of excitatory synaptic inputs, acceleration of firing rates, and promotion of oscillatory neuronal activities. However, the origin and molecular basis of the persistent current have remained controversial for decades. Here, we provide direct evidence that U-to-C RNA editing of an insect sodium channel transcript generates a sodium channel with a persistent current. We detected a persistent TTX-sensitive current in a splice variant of the cockroach sodium channel gene BgNa(v) (formerly para(CSMA)). Site-directed mutagenesis experiments revealed that an F-to-S change at the C-terminal domain of this variant was responsible for the persistent current. We demonstrated that this F-to-S change was the result of a U-to-C RNA editing event, which also occurred in the Drosophila para sodium channel transcript. Our work provides direct support for the hypothesis that posttranscriptional modification of a conventional transient sodium channel produces a persistent TTX-sensitive sodium channel.

Increased salt sensitivity induced by sensory denervation: role of superoxide.

AIM: To test the hypothesis that production of superoxide in mesenteric resistance arteries is increased and contributes to the development of hypertension induced by sensory denervation plus high salt intake. METHODS: Newborn Wistar rats were given capsaicin 50 mg/kg sc on the 1st and 2nd d of life. After weaning, male rats were grouped as follows and treated for 3 weeks with: capsaicin pretreatment plus normal sodium diet (0.5 %, CAP-NS), CAP plus high sodium diet (4 %, CAP-HS), control plus NS (CON-NS), or CON-HS. Both tail-cuff systolic blood pressure and mean arterial pressure (MAP) were measured in each of the groups. Western blot analysis was used for measurement of manganese superoxide dismutase (MnSOD) and endothelial nitric oxide synthase (eNOS) in the mesenteric resistance arteries. Lucigenin chemiluminescence assay was used for superoxide production in the mesenteric resistance arteries. The Griess method was used for measurement of nitrite/nitrate levels in plasma. RESULTS: Both tail-cuff pressure and MAP were higher in CAP-HS compared with CAP-NS, CON-HS, and CON-NS rats (P<0.05). Both MnSOD and eNOS in the mesenteric resistance arteries were increased in CAP-HS compared with CAP-NS, CON-HS, and CON-NS (P<0.05). However, nitrite/nitrate levels in plasma were not different among 4 groups. Acute iv administration of tempol, a membrane-permeable superoxide scavenger, decreased MAP in both CAP-HS and CON-HS when compared with their respective controls. However, the decreases of MAP between these two groups were not different. Chronic treatment with tempol failed to prevent the development of hypertension in CAP-HS rats. Superoxide production in the mesenteric resistance arteries was increased in CAP-HS compared with CAP-NS, CON-HS, and CON-NS (P<0.05). However, chronic treatment with tempol did not prevent the increase of mesenteric superoxide production in CAP-HS rats. CONCLUSIONS: Regardless of increased vascular MnSOD levels, salt sensitive hypertension induced by sensory degeneration is associated with increased vascular superoxide production. Although tempol is incapable of preventing the development of hypertension in sensory denervated rats fed a high salt diet, increased superoxide levels may contribute to exacerbated vascular impairment which may take longer time to develop. Given that superoxide may be produced by sources other than mitochondrion, future studies using other inhibitors (eg, inhibitors of NADPH oxidase and xanthine oxidase) may unveil the effectiveness of reducing superoxide on lowering blood pressure in this model.

RNA editing generates tissue-specific sodium channels with distinct gating properties.

Sodium channels play an essential role in generating the action potential in eukaryotic cells, and their transcripts, especially those in insects, undergo extensive A-to-I RNA editing. The functional consequences of RNA editing of sodium channel transcripts, however, have yet to be determined. We characterized 20 splice variants of the German cockroach sodium channel gene BgNa(v). Functional analysis revealed that these variants exhibited a broad range of voltage-dependent activation and inactivation. Further analysis of two variants, BgNa(v)1-1 and BgNa(v)1-2, which activate at more depolarizing membrane potentials than other variants, showed that RNA editing events were responsible for variant-specific gating properties. Two U-to-C editing sites identified in BgNa(v)1-1 resulted in a Leu to Pro change in segment 1 of domain III (IIIS1) and a Val to Ala change in IVS4. The Leu to Pro change shifted both the voltage dependence of activation and steady-state inactivation in the depolarizing direction. Two A-to-I editing events in BgNa(v)1-2 resulted in a Lys to Arg change in IS2 and an Ile to Met change in IVS3. The Lys to Arg change shifted the voltage dependence of activation in the depolarizing direction. Moreover, these RNA editing events occurred in a tissue-specific and development-specific manner. Our findings provide direct evidence that RNA editing is an important mechanism generating tissue-/cell type-specific functional variants of sodium channels.