Ion selectivity of the Kat1 K+ channel pore

Kat1 is a highly selective inward-rectifying K⁺ channel that opens for extended periods under conditions of extreme hyperpolarization. Over 200 point mutants in the pore region of the Kat1 K⁺ channel were generated and examined in the yeast Saccharomyces cerevisiae and Xenopus oocytes to assess the effect of the mutations on ion selectivity. Substitutions at the tyrosine of the signature sequence G-Y-G resulted in the most significant alterations in ion selectivity, consistent with its role in the selectivity filter. However, greater than 80% of the mutations throughout the greater pore region also conferred a defect in selectivity demonstrating that the entire pore of Kat1 contributes to the ion selectivity of this channel. Surprisingly, we identified a novel class of mutant channel that conferred enhanced selectivity of K⁺ over Na⁺. Mutants of this class frequently displayed sensitivity to the competing ion Cs⁺. This finding has led us to speculate that the Kat1 channel pore has evolved to balance not only K⁺/Na⁺ selectivity, but selectivity over Cs⁺, and possibly a wide spectrum of potential competing ions.     

N type rapid inactivation in human Kv1.4 channels: functional role of a putative C-terminal helix

Voltage gated potassium channels are tetrameric membrane proteins, which have a central role in cellular excitability. Human Kv1.4 channels open on membrane depolarization and inactivate rapidly by a ‘ball and chain’ mechanism whose molecular determinants have been mapped to the cytoplasmic N terminus of the channel. Here we show that the other terminal end of the channel also plays a role in channel inactivation. Swapping the C-terminal residues of hKv1.4 with those from two non-inactivating channels (hKv1.1 and hKv1.2) affects the rates of inactivation, as well as the recovery of the channel from the inactivated state. Secondary structure predictions of the hKv1.4 sequence reveal a helical structure at its distal C-terminal. Complete removal or partial disruption of this helical region results in channels with remarkably slowed inactivation kinetics. The ionic selectivity and voltage-dependence of channel opening were similar to hKv1.4, indicative of an unperturbed channel pore. These results demonstrate that fast inactivation is modulated by structural elements in the C-terminus, suggesting that the process involves the concerted action of the N- and C-termini.     

Der Mengen- und Spurenelementgehalt des Rinderhaares als Indikator der Calcium-, Magnesium-, Phosphor-, Kalium-, Natrium-, Eisen-, Zink-, Mangan-, Kupfer-, Molybdän- und Kobaltversorgung

Beyond the energy requirement of maintenance, the assimilated energy, occurring in bioproducts, is linearly proportional to the intake of metabolizable energy in non‐underfed conditions. In contrast, resting metabolic rate is differing between individuals within a population of an animal species. As adaptability to changed environmental conditions may play a role, young bulls were exposed to thermoneutral (18°C) and low (4°C) ambient temperatures and were fed at two feeding levels (1.0 and 1.6 times energy requirement in maintenance) to produce metabolic rate differences, using the same animals, metabolic rate was altered by reducing the sympathetic outflow in each case. Expression of sulfonylurea receptors in circulating mononuclear leukocytes and cells from skeletal muscle (m. semitendinosus) was studied by flow cytom‐etry. Changes of metabolic rate at rest corresponded to the portion of cells with sulfonylurea receptors expression. The data from reducing the sympathetic outflow and those from sulfonylurea receptors expression are useful to explain metabolic rate differences among individuals of an animal population.     

Determinants of frequency-dependent regulation of Kv1.2-containing potassium channels

Voltage-gated potassium channels are important regulators of electrical excitation in many tissues, with Kv1.2 standing out as an essential contributor in the CNS. Genetic deletion of Kv1.2 invariably leads to early lethality in mice. In humans, mutations affecting Kv1.2 function are linked to epileptic encephalopathy and movement disorders. We have demonstrated that Kv1.2 is subject to a unique regulatory mechanism in which repetitive stimulation leads to dramatic potentiation of current. In this study, we explore the properties and molecular determinants of this use-dependent potentiation/activation. First, we examine how alterations in duty cycle (depolarization and repolarization/recovery times) affect the onset and extent of use-dependent activation. Also, we use trains of repetitive depolarizations to test the effects of a variety of Thr252 (S2-S3 linker) mutations on use-dependent activation. Substitutions of Thr with some sterically similar amino acids (Ser, Val, and Met, but not Cys) retain use-dependent activation, while bulky or charged amino acid substitutions eliminate use-dependence. Introduction of Thr at the equivalent position in other Kv1 channels (1.1, 1.3, 1.4), was not sufficient to transfer the phenotype. We hypothesize that use-dependent activation of Kv1.2 channels is mediated by an extrinsic regulator that binds preferentially to the channel closed state, with Thr252 being necessary but not sufficient for this interaction to alter channel function. These findings extend the conclusions of our recent demonstration of use-dependent activation of Kv1.2-containing channels in hippocampal neurons, by adding new details about the molecular mechanism underlying this effect.     

The MlotiK1 channel transports ions along the canonical conduction pore

Although the cyclic nucleotide-modulated potassium channel from Mesorhizobium loti, MlotiK1, is easily studied using a 86Rb+ flux assay, its comparatively low activity raises serious concerns about the integrity of the purified protein. We investigated the pathway of uptake using a multi-pronged approach. First, we probed the conduction pathway using quaternary ammonium compounds known to block conduction in eukaryotic K+ channels. Second, we examined the effect of chemical modification of putative pore-lining residues. Our results are consistent with ions traversing MlotiK1 along a conduction pathway like that of the eukaryotic channels, but at a much slower rate.     

蜂胶乙醇提取物(EEP)对豚鼠胸主动脉的舒张作用

目的:探讨蜂胶水提物(WEP)和乙醇提物(EEP)的血管舒张作用。方法:以离体豚鼠胸主动脉环为材料,采用离体实验方法记录血管收缩张力。结果:对于PE(PE,1μM)和KC1(60mM)预收缩的主动脉环,EEP可以剂量依赖地使其舒张。去除内皮后舒张作用减弱,所以这种作用是内皮依赖性的;使用NO合酶抑制剂N-硝基-L-精氨酸(L-NNA,10μM)、鸟苷酸环化酶抑制剂(methylene blue,10μM)或者前列腺素合成酶抑制剂(indomethacin,10μM)预处理,血管舒张作用也减弱。这提示EEP的作用可能与血管内皮释放的一氧化氮和前列腺素有关;K~ 通道通用抑制剂TEA(tetraethylammonium chloride,1 mM)的处理对EEP的舒血管作用没有影响,显示EEP对豚鼠动脉环的舒张作用与K~ 通道无关;另外,EEP能使CaCl_2的量效曲线下移,说明EEP可以抑制细胞外Ca~(2 )的内流,同时EEP还可以抑制细胞内Ca~(2 )的释放。结论:蜂胶乙醇提取物EEP能剂量依赖地引起离体豚鼠动脉环舒张。这种舒张作用与K~ 通道无关,但受内皮NO-鸟苷酸环化酶途径和前列腺素调控,最终通过降低细胞内Ca~(2 )的浓度舒张血管。     

Combined effect of salicylic acid and potassium mitigates drought stress through the modulation of physio-biochemical attributes and key antioxidants in wheat

Improving physio-biochemical traits in wheat under drought stress conditions has received more research attention in recent years for better adaptability and higher yield. In this study, we explored the potential bio-physiological mechanisms underlying improved plant growth and water use efficiency in wheat following soil application of potassium (0 and 100 kg ha^?1) and seed primed salicylic acid (SA) (150 mg per L) and SA foliar application (100 mg per L) under drought stresses (100%, 60% and 30% FC). Two years' average data revealed that inducing drought stress resulted in a decrease in plant pigments content, growth traits, and plant water status however, the influence was substantially reduced with the combined application of K and SA under drought stress conditions. The SA foliar spray in combination with K had increased chlorophyll a (174% and 83%), chl b (130% and 192%), chl a + b (156% and 120), carotenoid (22% and 11%), proline contents (24% and 29%) leaf relative water content (24% and 29%) while reduced leaf WSD (17% and 20%), WRC (6% and 7%), and WUC (23% and 28%) under mild and severe drought stresses, respectively. The increase in grain yield by 41% and 37% with enhanced water use efficiency was obtained with combined foliar SA and K under mild and severe drought stress, respectively indicating its vital role in overcoming the deleterious effects of drought via regulation of osmotic and metabolic processes and stabilizes cell components. RDA analysis revealed that the studied traits were completely discriminated under severe stress than mild or no drought stress. A positive and significant association was found between plant pigments with seed yield whereas a negative and significant correlation existed between water leaf traits and plant pigments. It was concluded that both foliar SA and seed primed SA with K fertilization combat the adverse effects of drought and improved plant water status as well as growth and bio-physiological traits of wheat under drought stress conditions.     

Autophagy protects against redox-active trace metal-induced cell death in rabbit synovial fibroblasts through Toll-like receptor 4 activation

Reactive oxygen species (ROS) are implicated to play a role in initiating rheumatoid arthritis (RA) pathogenesis. We have investigated the mechanism(s) by which essential redox-active trace metals (RATM) may induce cell proliferation and cell death in rabbit synovial fibroblasts. These fibroblast-like synovial (FLS) cells, which express Toll-like receptor 4 (TLR4), were used as a model system that plays a role in potentially initiating RA through oxidative stress. Potassium peroxychromate (PPC, [Cr⁵⁺]), ferrous chloride (FeCl₂, [Fe²⁺]), and cuprous chloride (CuCl, [Cu⁺]) in the indicated valency states were used as exogenous pro-oxidants that can induce oxidative stress through TLR4 coupled activation that also causes HMGB1 release. We measured the proliferation index (PI) of FLS, and examined the effect of RATM oxidants on apoptosis and autophagy by fluorescence cell-sorting flow cytometry (FC). Cell cycle was analysed by FC and autophagy-related protein expression levels were measured by western blot. Our data showed that as RATM as prooxidants increased intracellular ROS (iROS) that can induce oxidative stress. Whereas iROS increased PI in FLS, these reactive species also protected cells against apoptosis by inducing autophagy. Our results indicate that ROS/TLR4-coupled activation may contribute to the pathogenesis of RA in FLS by induction of autophagy. The signalling pathway by which inflammation and its tissue destructive sequel may occur in RA underlies the need for developing therapeutic agents that can inhibit release of tissue-damaging high mobility group box 1 (HMGB1), cytokines, and possess both trace metal chelating capacity and oxidant scavenging properties in a directed combinatorial therapy for RA.     

Two Kinds of Transient Outward Currents, I A and I Adepol , in F76 and D1 Soma Membranes of the Subesophageal Ganglia of Helix aspersa

Transient outward currents were characterized with twin electrode voltage clamp techniques in isolated F76 and D1 neuronal membranes (soma only) of Helix aspersa subesophageal ganglia. In this study, in addition to the transient outward current (A-current, I _A ) described by Connor and Stevens (1971b), another fast outward current, referred to as I _Adepol here, is described for the first time. This is similar to the current component characterized in Aplysia (Furukawa, Kandel & Pfaffinger, 1992). The separation of these two current components was based on activation and steady-state inactivation curves, holding potentials and sensitivity to 4-aminopyridine (4-AP). In contrast to I _A , I _Adepol did not require hyperpolarizing conditioning pulses to remove inactivation; it was evoked from a holding potential of −40 mV, at which I _A is completely inactivated. I _Adepol shows noticeable activation at around −5 mV, whereas I _A activates at around −50 mV. The time courses of I _Adepol activation and inactivation were similar but slower than I _A . It was found that I _Adepol was more sensitive than I _A to 4-AP. 4-AP at a concentration of 1 mm blocked I _Adepol completely, whereas 5–6 mm 4-AP was needed to block I _A completely. This current is potentially very important because it may, like other A currents, regulate firing frequency but notably, it does not require a period of hyperpolarization to be active. Received: 12 May 2000/Revised: 12 October 2000     

Potassium conductances in isolated single cells from Xenopus laevis colonic epithelium

The patch-clamp technique was employed in whole cells to analyze K⁺ conductances of amphibian colonic cells. Xenopus laevis colonic epithelium was dissected, and single epithelial cells were isolated using Ca²⁺-free solution and mild enzyme treatment. Vital epithelial cells had a round shape, and a distinction between apical and basolateral poles was no longer possible. Their epithelial origin was, however, verified by antibodies against keratin. The average resting potential of the colonocytes was −37.6 ± 1 mV (n = 220) and the resulting membrane current was strongly potassium selective. Further characterization of this conductance was achieved by current-voltage relationship in the presence and absence of various K⁺ channel blockers. Barium and cesium showed pronounced voltage-dependent blockage, with interaction at about 35% inside the pores. Lidocain, as well as quinine and quinidine also blocked, but with different kinetics and binding characteristics. Both TEA and verapamil were ineffective. We also explored the effects of extra- (pH_o) and intracellular pH (pH_i) on the K⁺ conductance. An increase of pH_o, as well as pH_i, caused membrane hyperpolarization, and the shift of the current-voltage relationship indicates a stimulation of K⁺ channels by decreasing external and/or internal H⁺ concentration. The results provide the first whole-cell measurements on isolated amphibian colonic epithelial cells and demonstrate the presence of various K⁺ channel types in this preparation. Accepted: 15 January 1999