Scorpion neurotoxin - a presynaptic toxin which affects both Na+ and K+ channels in axons.

A neurotoxin from the venom of the scorpion, $\text{Androctonus australis Hector}$, affects the closing of the Na⁺ channel and the opening of the K⁺ channel in giant axons of crayfish and lobster nerves. It blocks both Na⁺ and K⁺ conductances in $\text{Sepia}$ giant axons. Dose-response curves are markedly cooperative with all types of axons. Apparent dissociation constants for the receptor-toxin complexes are 0.25 μM, 0.7 μM and 2–4 μM for the crayfish, lobster and $\text{Sepia}$ axons, respectively. This toxin will be probably a useful tool for biochemical investigation of Na⁺ and K⁺ channels.     

Tetrodotoxin Blockage of Sodium Conductance Increase in Lobster Giant Axons

Previous studies suggested that tetrodotoxin, a poison from the puffer fish, blocks conduction of nerve and muscle through its rather selective inhibition of the sodium-carrying mechanism. In order to verify this hypothesis, observations have been made of sodium and potassium currents in the lobster giant axons treated with tetrodotoxin by means of the sucrose-gap voltage-clamp technique. Tetrodotoxin at concentrations of 1 x 10^-7 to 5 x 10^-9 gm/ml blocked the action potential but had no effect on the resting potential. Partial or complete recovery might have occurred on washing with normal medium. The increase in sodium conductance normally occurring upon depolarization was very effectively suppressed when the action potential was blocked after tetrodotoxin, while the delayed increase in potassium conductance underwent no change. It is concluded that tetrodotoxin, at very low concentrations, blocks the action potential production through its selective inhibition of the sodium-carrying mechanism while keeping the potassium-carrying mechanism intact.     

Concentration-dependent modulations of potassium and calcium currents of rat osteoblastic cells by arachidonic acid

We show that the voltage-gated K⁺ and Ca²⁺ currents of rat osteoblastic cells are strongly modulated by arachidonic acid (AA), and that these modulations are very sensitive to the AA concentration. At 2 or 3 μm, AA reduces the amplitude and accelerates the inactivation of the K⁺ current activated by depolarization; at higher concentrations (≥5 μm), AA still blocks this K⁺ current, but also induces a very large noninactivating K⁺ current. At 2 or 3 μm, AA enhances the T-type Ca²⁺ current, close to its threshold of activation, whereas at 10 μm, it blocks that current. AA (1–10 μm) also blocks the dihydropyridine-sensitive L-type Ca²⁺ current. Thus, the effect of AA on Ca²⁺ entry through voltage-gated Ca²⁺ channels can change qualitatively with the AA concentration: at 2 or 3 μm, AA will favor Ca²⁺ entry through T channels, both by lowering the voltage-gated K⁺ conductance and by increasing the T current, whereas at 10 μm, AA will prevent Ca²⁺ entry through voltage-gated Ca²⁺ channels, both by inducing a K⁺ conductance and by blocking Ca²⁺ channels.     

Separate,Ca2+-activated K+ and Cl− transport pathways in Ehrlich ascites tumor cells

Summary The net loss of KCl observed in Ehrlich ascites cells during regulatory volume decrease (RVD) following hypotonic exposure involves activation of separate conductive K⁺ and Cl^– transport pathways. RVD is accelerated when a parallel K⁺ transport pathway is provided by addition of gramicidin, indicating that the K⁺ conductance is rate limiting. Addition of ionophore A23187 plus Ca²⁺ also activates separate K⁺ and Cl^– transport pathways, resulting in a hyperpolarization of the cell membrane. A calculation shows that the K⁺ and Cl^– conductance is increased 14-and 10-fold, respectively. Gramicidin fails to accelerate the A23187-induced cell shrinkage, indicating that the Cl^– conductance is rate limiting. An A23187-induced activation of⁴²K and³⁶Cl tracer fluxes is directly demonstrated. RVD and the A23187-induced cell shrinkage both are: (i) inhibited by quinine which blocks the Ca²⁺-activated K⁺ channel. (ii) unaffected by substitution of NO ₃ ^– or SCN^– for Cl^–, and (iii) inhibited by the anti-calmodulin drug pimozide. When the K⁺ channel is blocked by quinine but bypassed by addition of gramicidin, the rate of cell shrinkage can be used to monitor the Cl^– conductance. The Cl^– conductance is increased about 60-fold during RVD. The volume-induced activation of the Cl^– transport pathway is transient, with inactivation within about 10 min. The activation induced by ionophore A23187 in Ca²⁺-free media (probably by release of Ca²⁺ from internal stores) is also transient, whereas the activation is persistent in Ca²⁺-containing media. In the latter case, addition of excess EGTA is followed by inactivation of the Cl^– transport pathway. These findings suggest that a transient increase in free cytosolic Ca²⁺ may account for the transient activation of the Cl^– transport pathway. The activated anion transport pathway is unselective, carrying both Cl^–, Br^–, NO ₃ ^– , and SCN^–. The anti-calmodulin drug pimozide blocks the volume- or A23187-induced Cl^– transport pathway and also blocks the activation of the K⁺ transport pathway. This is demonstrated directly by⁴²K flux experiments and indirectly in media where the dominating anion (SCN^–) has a high ground permeability. A comparison of the A23187-induced K⁺ conductance estimated from⁴²K flux measurements at high external K⁺, and from net K^– flux measurements suggests single-file behavior of the Ca²⁺-activated K⁺ channel. The number of Ca²⁺-activated K⁺ channels is estimated at about 100 per cell.     

Physicochemical and immunological characterization of the type E botulinum neurotoxin binding protein purified fromClostridium botulinum

Type E botulinum neurotoxin is produced byClostridium botulinum along with a neurotoxin binding protein which helps protect the neurotoxin from adversepH, temperature, and proteolytic conditions. The neurotoxin binding protein has been purified as a 118-kDa protein. Secondary structure content of the neurotoxin binding protein as revealed by far-UV circular dichroism spectroscopy was 19% α-helix, 50%β-sheets, 28% random coils, and 3%β-turns. This compared to 22% α-helix, 44%β-sheets, 34% random coils, and noβ-turns of the type E botulinum neurotoxin. The complex of the two proteins revealed 25%α-helix, 45%β-sheets, 27% random coils, and 3%β-turns, suggesting a significant alteration at least in theα-helical folding of the two proteins upon their interaction. Tyrosine topography is altered considerably (28%) when the neurotoxin and its binding protein are separated, indicating strong interaction between the two proteins. Gel filtration results suggested that type E neurotoxin binding protein clearly complexes with type E neurotoxin. The interaction is favored at lowpH as indicated by an initial binding rate of 8.4 min^?1 atpH 5.7 compared to 4.0 min^?1 atpH 7.5 as determined using a fiber optic-based biosensor. The neurotoxin and its binding protein apparently are of equivalent antigenicity, as both reacted equally on enzyme-linked immunosorbent assay to polyclonal antibodies raised against the toxoid of their complex.     

Time-irreversible Subconductance Gating Associated with Ba2+ Block of Large Conductance Ca2+-activated K+ Channels

Ba²⁺ block of large conductance Ca²⁺-activated K⁺ channels was studied in patches of membrane excised from cultures of rat skeletal muscle using the patch clamp technique. Under conditions in which a blocking Ba²⁺ ion would dissociate to the external solution (150 mM N-methyl-d-glucamine⁺ _o, 500 mM K⁺ _i, 10 μM Ba²⁺ _i, +30 mV, and 100 μM Ca²⁺ _i to fully activate the channel), Ba²⁺ blocks with a mean duration of ∼2 s occurred, on average, once every ∼100 ms of channel open time. Of these Ba²⁺ blocks, 78% terminated with a single step in the current to the fully open level and 22% terminated with a transition to a subconductance level at ∼0.26 of the fully open level (preopening) before stepping to the fully open level. Only one apparent preclosing was observed in ∼10,000 Ba²⁺ blocks. Thus, the preopenings represent Ba²⁺-induced time-irreversible subconductance gating. The fraction of Ba²⁺ blocks terminating with a preopening and the duration of preopenings (exponentially distributed, mean = 0.75 ms) appeared independent of changes in [Ba²⁺]_i or membrane potential. The fractional conductance of the preopenings increased from 0.24 at +10 mV to 0.39 at +90 mV. In contrast, the average subconductance level during normal gating in the absence of Ba²⁺ was independent of membrane potential, suggesting different mechanisms for preopenings and normal subconductance levels. Preopenings were also observed with 10 mM Ba²⁺ _o and no added Ba²⁺ _i. Adding K⁺, Rb⁺, or Na⁺ to the external solution decreased the fraction of Ba²⁺ blocks with preopenings, with K⁺ and Rb⁺ being more effective than Na⁺. These results are consistent with models in which the blocking Ba²⁺ ion either induces a preopening gate, and then dissociates to the external solution, or moves to a site located on the external side of the Ba²⁺ blocking site and acts directly as the preopening gate.     

Potassium currents in the giant axon of the crabCarcinus maenas

Summary Measurements were made of the kinetic and steadystate characteristics of the potassium conductance in the giant axon of the crabCarcinus maenas. These measurements were made in the presence of tetrodotoxin, using the feedback amplifier concept introduced by Dodge and Frankenhaeuser (J. Physiol. (London) 143:76–90). The conductance increase during depolarizing voltage-clamp pulses was analyzed assuming that two separate potassium channels exist in these axons. The first potassium channel exhibited activation and fast inactivation gating which could be fitted using them ³ h, Hodgkin-Huxley formalism. The second potassium channel exhibited the standardn ⁴ Hodgkin-Huxley kinetics. These two postulated channels are blocked by internal application of caesium, tetraethylammonium and sodium ions. External application of 4 amino-pyridine also blocks these channels.     

Electrophysiological properties of cellular and paracellular conductive pathways of the rabbit cortical collecting duct

Summary Microelectrode techniques were applied to the rabbit isolated perfused cortical collecting duct to provide an initial quantitation and characterization of the cell membrane and tight junction conductances. Initial studies demonstrated that the fractional resistance (ratio of the resistance of the apical cell membrane to the sum of the resistances of the apical and basolateral membranes) was usually independent of the point along the tubule of microelectrode impalement—implicating little cell-to-cell coupling—supporting the application of quantitative techniques to the cortical collecting duct. It was demonstrated that in the presence of amiloride, either reduction in the luminal pH or the addition of barium to the perfusate selectively reduced the apical membrane potassium conductance. From the changes inG ^te and fractional resistance upon reducing the luminal pH or addition of barium to the perfusate, the transepithelial, apical membrane, basolateral membrane and tight junction conductances were estimated to be 9.3, 6.7, 8.1 and 6.0 mS cm^–2, respectively. Ninety to ninety-five percent of the apical membrane conductance reflected the barium-sensitive potassium conductance in the presence of amiloride with an estimated potassium permeability of 1.1×10^–4 cm sec^–1. Reduction in the perfusate pH to 4.0 caused a 70% decrease in the apical membrane potassium conductance, implying a blocking site with an acidic group having a pK _a near 4.4. It is concluded that both the transcellular and paracellular pathways of the cortical collecting tubule have high ionic conductances, and that the apical membrane conductance primarily reffects a high potassium conductance. Furthermore, both reduction in the perfusate pH and addition of barium to the perfusate selectively block the apical potassium channels, although the site of inhibition likely differs since the two ions display markedly different voltage-dependent blocks of the channel.     

Phosphatase antagonist okadaic acid inhibits steady-state K+ currents in guard cells of Vicia faba

The effects of protein phosphatase inhibitors on steady-state K⁺ currents in the plasma membrane of Vicia faba guard cells were studied. Cells were impaled with double barrelled electrodes to monitor membrane voltage and K⁺ currents under voltage clamp. Okadaic acid (OA) (1 μM), a specific inhibitor of phosphatase 1 and 2A activity, blocks inward (l_K⁺_(in)) and outward (l_K⁺_(out)) rectifying K⁺ channels. Both currents decreased in parallel with a sigmoidal time course with 50% inhibition at about 8 min. With 0.2 μM OA inhibition became slower and more variable (4–34 min). Inhibition did not recover by washing cells ≤ 20 min in OA-free solution. In five out of seven cells OA also induced a rise in the background conductance, which lagged behind the inhibition of K⁺ current. Both decaying l_K*_(out) and rising leak conductance caused a depolarization. OA-induced inhibition of l_K⁺_(in) and l_K⁺_(out) was without a significant effect on the kinetics of voltage-dependent current activation and deactivation. In an alternative approach, guard cells were loaded from the voltage recording pipette with the non-specific phosphatase inhibitor naphthylphosphate. After an impalement of some minutes l_K⁺_(in) and l_K⁺_(out) were small or undetectable. In conclusion inward and outward K⁺ channels in guard cells have a common voltage-independent mode of control which is sensitive to phosphatase inhibitors. The known specificity of OA points to a mode of action in which a net increase of protein phosphorylation through inhibition of phosphatase 1 and/or 2A activity blocks conductance of both, l_K⁺_(in) and l_(out)     

Action of tetraethylammonium on calcium-activated potassium channels in pig pancreatic acinar cells studied by patch-clamp single-channel and whole-cell current recording

Summary The effects of tetraethylammonium ions on currents through high-conductance voltage- and Ca²⁺-activated K⁺ channels have been studied with the help of patch-clamp single-channel and whole-cell current recording on pig pancreatic acinar cells. In excised outside-out membrane patches TEA (1 to 2 mM) added to the bath solution virtually abolishes unitary current activity except at very positive membrane potentials when unitary currents corresponding to a markedly reduced conductance are observed. TEA in a lower concentration (0.2 mM) markedly reduces the open-state probability and causes some reduction of the single-channel conductance. In inside-out membrane patches bath application of TEA in concentrations up to 2 mM has no effect on single-channel currents. At a higher concentration (10 mM) slight reductions in single-channel conductance occur. In whole-cell current recording experiments TEA (1 to 2 mM) added to the bath solution completely suppresses the outward currents associated with depolarizing voltage jumps to membrane potentials of 0 mV and blocks the major part (70 to 90%) of the outward currents even at very positive membrane potentials (30 to 40 mV). In contrast TEA (2 mM) added to the cell interior (pipette solution) has no effect on the outward K⁺ current. Our results demonstrate that TEA in low concentrations (1 to 2 mM) acts specifically on the outside of the plasma membrane to block current through the high-conductance Ca²⁺- and voltage-activated K⁺ channels     

Reconstitution of High-Affinity Binding of a β-Scorpion Toxin to Neurotoxin Receptor Site 4 on Purified Sodium Channels

Abstract: Reconstitution of purified sodium channels into phospholipid vesicles restores many aspects of sodium channel function including high-affinity neurotoxin binding and action at neurotoxin receptor sites 1–3 and 5, but neurotoxin binding and action at receptor site 4 has not previously been demonstrated in purified and reconstituted preparations. Toxin IV from the venom of the American scorpion Centruroides suffusus suffusus (Css IV), a β-scorpion toxin, shifts the voltage dependence of sodium channel activation by binding with high affinity to neurotoxin receptor site 4. Sodium channels were purified from rat brain and reconstituted into phospholipid vesicles composed of phosphatidylcholine and phosphatidylethanolamine (65:35). ¹²⁵I-Css IV, purified by reversed-phase HPLC, bound rapidly and specifically to reconstituted sodium channels. Dissociation of the bound toxin was biphasic with half-times of 0.22 min^?1 and 0.015 min^?1. At equilibrium, the toxin bound to two classes of specific high-affinity sites, a variable minor class with K_D of ～0.1 nM and a major class with a K_D of ～5 nM. Approximately 0.8 mol ¹²⁵I-Css IV was bound per mole of reconstituted, right-side-out sodium channels, as assessed from comparison of binding of saxitoxin and Css IV. Binding of Css IV was unaffected by membrane potential or by neurotoxins that bind at sites 1–3 or 5, consistent with the characteristics of binding of β-scorpion toxins to sodium channels in cells and membrane preparations. Our results show that specific, high-affinity binding at neurotoxin receptor site 4 on purified sodium channels can be restored by reconstitution into phospholipid vesicles and provide an experimental approach to analysis of the peptide components of the toxin receptor site.     

Effect of oxytocin on transepithelial transport of water and Na+ in distinct ventral regions of frog skin (Rana catesbeiana)

Thoracic, abdominal, and pelvic fragments of ventral skin of Rana catesbeiana were analysed regarding the effect of oxytocin on: (1) transepithelial water transport; (2) short-circuit current; (3) skin conductance and electrical potential difference; (4) Na⁺ conductance and electrical potential difference; (4) Na⁺ conductance, the electromotive force of Na⁺ transport mechanism, and shunt conductance; (5) short-circuit current responses to fast Na⁺ by K⁺ replacement in the outer compartment, and (6) epithelial microstructure. Unstimulated water and Na⁺ permeabilities were low along the ventral skin. Hydrosmotic and natriferic responses to oxytocin increased from thorax to pelvis. Unstimulated Na⁺ conductance was greater in pelvis than in abdomen, the other electrical parameters being essentially similar in both skin fragments. Contribution of shunt conductance to total skin conductance was higher in abdominal than in pelvic skin. Oxytocin-induced increases of total skin conductance, Na⁺ conductance, and shunt conductance in pelvis were significantly larger than in abdomen. An oscillatory behaviour of the short-circuit current was observed only in oxytocin-treated pelvic skins. Decrease of epithelial thickness and increase of mitochondria-rich cell number were observed from thorax to pelvis. Oxytocin-induced increases of interspaces were more conspicuous in pelvis and abdomen than in thorax.Abbreviations E _Na electromotive force of sodium transport mechansim - G _KCI skin conductance with external KCI Ringer - G _Na sodium conductance (series conductance) - G _shunt shunt pathway conductance - G _total total skin conductance - J _v water flux (in units of volume per area per time) - MRC mitochondria-rich cells - PD potential difference across skin - R _shunt resistance of the shunt pathway - SCC short-circuit current     

Interaction of Heparins and Dextran Sulfates with a Mesoscopic Protein Nanopore

A mechanism of how polyanions influence the channel formed by Staphylococcus aureus α-hemolysin is described. We demonstrate that the probability of several types of polyanions to block the ion channel depends on the presence of divalent cations and the polyanion molecular weight and concentration. For heparins, a 10-fold increase in molecular weight decreases the half-maximal inhibitory concentration, IC₅₀, nearly 10⁴-fold. Dextran sulfates were less effective at blocking the channel. The polyanions are significantly more effective at reducing the conductance when added to the trans side of this channel. Lastly, the effectiveness of heparins on the channel conductance correlated with their influence on the ζ-potential of liposomes. A model that includes the binding of polyanions to the channel-membrane complex via Ca²⁺-bridges and the asymmetry of the channel structure describes the data adequately. Analysis of the single channel current noise of wild-type and site-directed mutant versions of α-hemolysin channels suggests that a single polyanion enters the pore due to electrostatic forces and physically blocks the ion conduction path. The results might be of interest for pharmacology, biomedicine, and research aiming to design mesoscopic pore blockers.     

Cloning and Function of the Rat Colonic Epithelial K+ Channel KVLQT1

K_VLQT1 (KCNQ1) is a voltage-gated K⁺ channel essential for repolarization of the heart action potential that is defective in cardiac arrhythmia. The channel is inhibited by the chromanol 293B, a compound that blocks cAMP-dependent electrolyte secretion in rat and human colon, therefore suggesting expression of a similar type of K⁺ channel in the colonic epithelium. We now report cloning and expression of K_VLQT1 from rat colon. Overlapping clones identified by cDNA-library screening were combined to a full length cDNA that shares high sequence homology to K_VLQT1 cloned from other species. RT-PCR analysis of rat colonic musoca demonstrated expression of K_VLQT1 in crypt cells and surface epithelium. Expression of rK_VLQT1 in Xenopus oocytes induced a typical delayed activated K⁺ current, that was further activated by increase of intracellular cAMP but not Ca²⁺ and that was blocked by the chromanol 293B. The same compound blocked a basolateral cAMP-activated K⁺ conductance in the colonic mucosal epithelium and inhibited whole cell K⁺ currents in patch-clamp experiments on isolated colonic crypts. We conclude that K_VLQT1 is forming an important component of the basolateral cAMP-activated K⁺ conductance in the colonic epithelium and plays a crucial role in diseases like secretory diarrhea and cystic fibrosis. Received: 17 July 2000/Revised: 25 October 2000     

Inhibition of the sodium channel by SK&F 96365, an inhibitor of the receptor-operated calcium channel,in mouse diaphragm

The effects of SK&F 96365, a blocker of the receptor-operated Ca²⁺ channel, on contractilities and the Na⁺ channel of mouse diaphragm were studied. SK&F 96365 (10–50 µM) reversibly inhibited twitches, tetanic contractions and muscle and nerve action potentials. The IC₅₀ was 17–24 µM. The inward Na⁺ current was suppressed and its recovery from inactivations delayed. Crotamine, a peptide toxin that binds to neurotoxin receptor site 3 of the muscle Na⁺ channel, enhanced the inhibitory effects of SK&F 96365 and reduced the IC₅₀ to about 4 µM. Veratridine had similar effects, although it was less effective than crotamine. On the other hand, the crotamine-induced membrane depolarizations and spontaneous discharges of muscle action potentials were inhibited by SK&F 96365 noncompetitively. The inhibitory effects of tetrodotoxin and tetracaine were additive with those of SK&F 96365 but were enhanced slightly by crotamine. The results suggested that SK&F 96365 acts on a distinct site and blocks the Na⁺ channel of excitable membranes at a concentration range that inhibits the receptor-operated calcium channel.     

Effects of antidiuretic hormone on cellular conductive pathways in mouse medullary thick ascending limbs of Henle: I. ADH increases transcellular conductance pathways

Summary This paper reports experiments designed to assess the relations between net salt absorption and transcellular routes for ion conductance in single mouse medullary thick ascending limbs of Henle microperfusedin vitro. The experimental data indicate that ADH significantly increased the transepithelial electrical conductance, and that this conductance increase could be rationalized in terms of transcellular conductance changes. A minimal estimate (G _c ^min ) of the transcellular conductance, estimated from Ba⁺⁺ blockade of apical membrane K⁺ channels, indicated thatG _c ^min was approximately 30–40% of the measured transepithelial conductance. In apical membranes, K⁺ was the major conductive species; and ADH increased the magnitude of a Ba⁺⁺-sensitive K⁺ conductance under conditions where net Cl^– absorption was nearly abolished. In basolateral membranes, ADH increased the magnitude of a Cl^– conductance; this ADH-dependent increase in basal Cl^– conductance depended on a simultaneous hormone-dependent increase in the rate of net Cl^– absorption. Cl^– removal from luminal solutions had no detectable effect onG _e , and net Cl^– absorption was reduced at luminal K⁺ concentrations less than 5mm; thus apical Cl^– entry may have been a Na⁺,K⁺,2Cl^– cotransport process having a negligible conductance. The net rate of K⁺ secretion was approximately 10% of the net rate of Cl^– absorption, while the chemical rate of net Cl^– absorption was virtually equal to the equivalent short-circuit current. Thus net Cl^– absorption was rheogenic; and approximately half of net Na⁺ absorption could be rationalized in terms of dissipative flux through the paracellular pathway. These findings, coupled with the observation that K⁺ was the principal conductive species in apical plasma membranes, support the view that the majority of K⁺ efflux from cell to lumen through the Ba⁺⁺-sensitive apical K⁺ conductance pathway was recycled into cells by Na⁺,K⁺,2Cl^– cotransport.     

北京山区侧柏林冠层-大气蒸腾导度模拟及环境因子响应

蒸腾导度模型是衡量冠层-大气界面水汽输出的重要阻力模型,研究其特征及对环境因子的响应,为揭示森林冠层-大气界面水汽输出阻力机制提供理论依据。以首都圈森林生态系统定位观测研究站侧柏林为研究对象,采用TDP热探针法测定侧柏林树干液流密度,同步监测光合有效辐射、饱和水汽压差、气温、风速等主要环境因子,分析冠层导度和空气动力学导度的动态变化,构建冠层-大气蒸腾导度模型并模拟,明确冠层-大气蒸腾导度对各环境因子的响应关系。结果表明:蒸腾导度季节变化表现为非生长季与冠层导度趋势一致,生长季与空气动力学导度趋势一致,全年均为单峰趋势。冬季蒸腾导度与冠层导度保持较稳定差值(45 mol m^(-2 )s^-1左右),其他季节蒸腾导度与冠层导度、空气动力学导度的最大差值,均在各季节冠层导度、空气动力学导度的峰值水平。全年日均蒸腾导度冬季最大(86.92 mol m^(-2 )s^-1),其他季节较小且稳定(40—50 mol m^(-2 )s^-1之间)。在非生长季各环境因子对蒸腾导度的影响与对冠层导度的影响基本一致,温度为主要影响因子(r=-0.198),其他环境因子影响较小(r<0.1);在生长季中风速为主要影响因子(r=0.488),光合有效辐射(r=0.228)和饱和水汽压差(r=-0.299)的影响明显升高,温度的影响降低(r=0.114)。蒸腾导度模型较好的模拟了冠层-大气界面侧柏蒸腾不同季节的变化规律,阐明了各环境因子和冠层导度、空气动力学导度对蒸腾导度的影响机制,证实在生长季应重视空气动力学导度对蒸腾的影响。     

Binding of scorpion and sea anemone neurotoxins to a common site related to the action potential Na+ ionophore in neuroblastoma cells.

The protein neurotoxin II from the venom of the scorpion $\text{Androctonus}\text{australis}$ Hector was labeled with ¹²⁵I by the lactoperoxidase method to a specific radioactivity of about 100 μCi/μg without loss of biological activity. The labeled neurotoxin binds specifically to a single class of non intereacting binding sites of high affinity (K_D = 0.3 – 0.6 nM) and low capacity (4000 – 8000 sites/cell) to electrically excitable neuroblastoma cells. Relation of these sites to the action potential Na⁺ channel is derived from identical concentration dependence of scorpion toxin binding and increase in duration and amplitude of action potential. The protein neurotoxin II from the sea anemone $\text{Anemona sulcata}$ also affects the closing of the action potential Na⁺ ionophore in nerve axons. The unlabelled sea anemone toxin modifies ¹²⁵I-labeled scorpion toxin II binding to neuroblastoma cells by increasing the apparent K_D for labeled scorpion toxin without modification of the number of binding sites. It is concluded that both $\text{Androctonus}$ scorpion toxin II and $\text{Anemona}$ sea anemone toxin II interact competitively with a regulatory component of the action potential Na⁺ channel.     

Turgor regulation in Lamprothamnium papulosum. I. I/V analysis and pharmacological dissection of the hypotonic effect

Current-voltage (I/V) analysis and pharmacological dissection were applied to membranes of Lamprothamnium at the time of hypotonic stress. At least three types of process were found to be involved in the response to this stress.

• 1 The first 10min of exposure to hypotonic medium resulted in a depolarization of about 50mV accompanied by a decrease or no change in conductance. This depolarization occurred with either K⁺ or Ca²⁺ (and consequently C^? channels inactivated.
• 2 The CI^? channels opened mainly in the first 15min of the hypotonic stress, increasing the membrane conductance by about an order of magnitude.
• 3 The K⁺ conductance rose as the Cl^? conductance started to diminish and reached a maximum after about 40 min.

Both types of channel were strongly potential-dependent with a conductance peak between -150 and 0mV. An inactivation of K⁺or CI^? channels resulted in moving the membrane potential away from the conductance maximum toward either E_K or E_CI, diminishing the ion efflux (and turgor regulation). The time courses of the conductance increases remained the same, suggesting that the conductance changes are not driven by feedback to some preset turgor level. The electrophysiology of the Lamprothamnium transporters is compared to that of salt-sensitive charophytes.     

High level expression,purification and immunogenicity analysis of a protective recombinant protein against botulinum neurotoxin type E

Botulinum neurotoxin type E heavy chain consists of two domains: N-terminal half as a translocation domain and C-terminal half (Hcc) as a binding domain. In this research a synthetic gene fragment encoding the binding domain of botulinum neurotoxin type E (BoNT/E-Hcc) was highly expressed in Escherichia coli by pGEX4T-1 vector. After purification, the recombinant BoNT/E-Hcc was evaluated by SDS-PAGE and western blot (immunoblot) analysis. Average yields obtained in this research were 3.7 mg recombinant BoNT/E-Hcc per liter of bacterial culture. The recombinant protein was injected in mice for study of its protection ability against botulinum neurotoxin type E challenges. The challenge studies showed that, vaccinated mice were fully protected against 10⁴ × minimum lethal dose of botulinum neurotoxin type E.