Localization of the Nucleic Acid Channel Regulatory Subunit, Cytosolic Malate DehydrogenaseHanss, Basil; Leal-Pinto, Edgar; Teixeira, Avelino; Tran, Baohuong; Lee, Chun-Hui; Henderson, Scott; Klotman, Paul
doi: 10.1007/s00232-008-9133-5pmid: 19015805
NACh is a nucleic acid–conducting channel found in apical membrane of rat kidney proximal tubules. It is a heteromultimeric complex consisting of at least two proteins: a 45-kDa pore-forming subunit and a 36-kDa regulatory subunit. The regulatory subunit confers ion selectivity and influences gating kinetics. The regulatory subunit has been identified as cytosolic malate dehydrogenase (cMDH). cMDH is described in the literature as a soluble protein that is not associated with plasma membrane. Yet a role for cMDH as the regulatory subunit of NACh requires that it be present at the plasma membrane. To resolve this conflict, studies were initiated to determine whether cMDH could be found at the plasma membrane. Before performing localization studies, a suitable model system that expressed NACh was identified. A channel was identified in LLC-PK1 cells, a line derived from pig proximal tubule, that is selective for nucleic acid and has a conductance of approximately 10 pS. It exhibits dose-dependent blockade by heparan sulfate or l-malate. These characteristics are similar to what has been reported for NACh from rat kidney and indicate that NACh is present in LLC-PK1 cells. LLC-PK1 cells were therefore used as a model system for immunolocalization of cMDH. Both immunofluorescence and immunoelectron microscopy demonstrated cMDH at the plasma membrane of LLC-PK1 cells. This finding supports prior functional data that describe a role for cMDH as the regulatory subunit of NACh.
Membrane Lipids Determine the Antibiotic Activity of the Lantibiotic GalliderminChrist, Katrin; Al-Kaddah, Saad; Wiedemann, Imke; Rattay, Bernd; Sahl, Hans-Georg; Bendas, Gerd
doi: 10.1007/s00232-008-9134-4pmid: 19009315
Lantibiotics, a group of lanthionine-containing peptides, display their antibiotic activity by combining different killing mechanisms within one molecule. The prototype lantibiotic nisin was shown to possess both inhibition of peptidoglycan synthesis and pore formation in bacterial membranes by interacting with lipid II. Gallidermin, which shares the lipid II binding motif with nisin but has a shorter molecular length, differed from nisin in pore formation in several strains of bacteria. To simulate the mode of action, we applied cyclic voltammetry and quartz crystal microbalance to correlate pore formation with lipid II binding kinetics of gallidermin in model membranes. The inability of gallidermin to form pores in DOPC (1,2-dioleoyl-sn-glycero-3-phosphocholine) (C18/1) and DPoPC (1,2-dipalmitoleoyl-sn-glycero-3-phosphocholine) (C16/1) membranes was related to the membrane thickness. For a better simulation of bacterial membrane characteristics, two different phospholipids with branched fatty acids were incorporated into the DPoPC matrix. Phospholipids with methyl branches in the middle of the fatty acid chains favored a lipid II–independent DPoPC permeabilization by gallidermin, while long-branched phospholipids in which the branch is placed near the hydrophilic region induced an identical lipid II–dependent pore formation of gallidermin and nisin. Obviously, the branched lipids altered lipid packing and reduced the membrane thickness. Therefore, the duality of gallidermin activity (pore formation and inhibition of the cell wall synthesis) seems to be balanced by the bacterial membrane composition.
Stretch-Activated Potassium Channels in Hypotonically Induced Blebs of Atrial MyocytesLiu, Xuxia; Huang, Haixia; Wang, Wei; Wang, Jun; Sachs, Frederick; Niu, Weizhen
doi: 10.1007/s00232-008-9135-3pmid: 19015804
Stress in the lipids of the cell membrane may be responsible for activating stretch-activated channels (SACs) in nonspecialized sensory cells such as cardiac myocytes, where they are likely to play a role in cardiac mechanoelectric feedback. We examined the influence of the mechanical microenvironment on the gating of stretch-activated potassium channels (SAKCs) in rat atrial myocytes. The goal was to examine the role of the cytoskeleton in the gating process. We recorded from blebs that have minimal cytoskeleton and cells treated with cytochalasin B (cyto-B) to disrupt filamentous actin. Histochemical and electron microscopic techniques confirmed that the bleb membrane was largely free of F-actin. Channel currents showed mechanosensitivity and potassium selectivity and were activated by low pH and arachidonic acid, similar to properties of TREK-1. Some patches showed a time-dependent decrease in current that may be adaptation or inactivation, and since this decrease appeared in control cells and blebs, it is probably not the result of adaptation in the cytoskeleton. Cyto-B treatment and blebbing caused an increase in background channel activity, suggesting a transfer of stress from actin to bilayer and then to the channel. The slope sensitivity of gating before and after cyto-B treatment was similar to that of blebs, implying the characteristic change of dimensions associated with channel gating was the same in the three mechanical environments. The mechanosensitivity of SAKCs appears to be the result of interaction with membrane lipids and not of direct involvement of the cytoskeleton.
Two Distinct Mechanisms of Transport Through the Plasmodial Surface Anion ChannelBokhari, Abdullah; Solomon, Tsione; Desai, Sanjay
doi: 10.1007/s00232-008-9136-2pmid: 19050955
The plasmodial surface anion channel (PSAC) is a voltage-dependent ion channel on erythrocytes infected with malaria parasites. To fulfill its presumed function in parasite nutrient acquisition, PSAC is permeant to a broad range of charged and uncharged solutes; it nevertheless excludes Na+ as required to maintain erythrocyte osmotic stability in plasma. Another surprising property of PSAC is its small single-channel conductance (<3 pS in isotonic Cl−) in spite of broad permeability to bulky solutes. While exploring the mechanisms underlying these properties, we recently identified interactions between permeating solutes and PSAC inhibitors that suggest the channel has more than one route for passage of solutes. Here, we explored this possibility with 22 structurally diverse solutes and found that each could be classified into one of two categories based on effects on inhibitor affinity, the temperature dependence of these effects and a clear pattern of behavior in permeant solute mixtures. The clear separation of these solutes into two discrete categories suggests two distinct mechanisms of transport through this channel. In contrast to most other broad-permeability channels, selectivity in PSAC appears to be complex and cannot be adequately explained by simple models that invoke sieving through rigid, noninteracting pores.
Implications of the Alternating Access Model for Organic Anion Transporter KineticsEraly, Satish
doi: 10.1007/s00232-008-9137-1pmid: 19015803
Many transport proteins, including the clinically important organic anion transporters (OATs), appear to function via an “alternating access” mechanism. In analyzing the kinetics of these transporters, the terms K
m and V
max are often treated in the field as denoting, respectively, the affinity of the substrate for the transporter and the turnover (conformational switch) rate of the substrate–transporter complex. In fact, the expressions for both these parameters have very complex forms comprising multiple rate constants from conformational switch as well as association/dissociation steps in the cycling of the transporter and, therefore, do not have straightforward physical meanings. However, if the rapid equilibrium assumption is made (namely, that the association/dissociation steps occur far more rapidly than the conformational switch steps), these expressions become greatly simplified and their physical meaning clear, though still distinct from the conventional interpretations. V
max will be a function of not just the rate of substrate–transporter complex turnover but also the rate of the “return” conformational switch and will vary largely with the slower of these two steps (the rate-limiting step). K
m will be seen to be related to substrate affinity by a term that varies inversely with the substrate–transporter complex turnover rate, essentially because the greater this rate, the greater the extent to which transporters will be distributed in a conformation inaccessible to substrate. Here, an intuitive approach is presented to demonstrate these conclusions. The phenomena of trans-stimulation and trans-inhibition are discussed in the context of this analysis.
Voltage-Activated Elementary Calcium Release Events in Isolated Mouse Skeletal Muscle FibersCsernoch, Laszlo; Pouvreau, Sandrine; Ronjat, Michel; Jacquemond, Vincent
doi: 10.1007/s00232-008-9138-0pmid: 19015802
The elementary Ca2+-release events underlying voltage-activated myoplasmic Ca2+ transients in mammalian muscle remain elusive. Here, we looked for such events in confocal line-scan (x,t) images of fluo-3 fluorescence taken from isolated adult mouse skeletal muscle fibers held under voltage-clamp conditions. In response to step depolarizations, spatially segregated fluorescence signals could be detected that were riding on a global increase in fluorescence. These discrete signals were separated using digital filtering in the spatial domain; mean values for their spatial half-width and amplitude were 1.99 ± 0.09 μm and 0.16 ± 0.005 ΔF/F
0
(n = 151), respectively. Under control conditions, the duration of the events was limited by the pulse duration. In contrast, in the presence of maurocalcine, a scorpion toxin suspected to disrupt the process of repolarization-induced ryanodine receptor (RyR) closure, events uninterrupted by the end of the pulse were readily detected. Overall results establish these voltage-activated low-amplitude local Ca2+ signals as inherent components of the physiological Ca2+-release process of mammalian muscle and suggest that they result from the opening of either one RyR or a coherently operating group of RyRs, under the control of the plasma membrane polarization.