Showing papers on "Ion channel published in 1986"

Expression of functional sodium channels from cloned cDNA

Abstract: The voltage-gated sodium channel is a transmembrane protein essential for the generation of action potentials in excitable cells. It has been reported that sodium channels purified from the electric organ of the electric eel, Electrophorus electricus, and from chick cardiac muscle consist of a single polypeptide of relative molecular mass (Mr) approximately 260,000, whereas those purified from rat brain and from rat and rabbit skeletal muscle contain, in addition to the large polypeptide, one or two smaller polypeptides of Mr 33,000-43,000. The primary structures of the Electrophorus sodium channel and two distinct sodium channel large polypeptides (designated as sodium channels I and II) from rat brain have been elucidated by cloning and sequencing the complementary DNAs. The purified sodium channel preparations from Electrophorus electroplax and from mammalian muscle and brain, when reconstituted into lipid vesicles or planar lipid bilayers, exhibit some functional activities. The successful reconstitution with the Electrophorus preparation would imply that the large polypeptide alone is sufficient to form functional sodium channels. However, studies with the rat brain preparation suggest that the smaller polypeptide of Mr 36,000 is also required for the integrity of the saxitoxin (STX) or tetrodotoxin (TTX) binding site of the sodium channel. Here we report that the messenger RNAs generated by transcription of the cloned cDNAs encoding the rat brain sodium channel large polypeptides, when injected into Xenopus oocytes, can direct the formation of functional sodium channels.

Ion Channel Reconstitution

Abstract: I Basics- 1 The Physical Nature of Planar Bilayer Membranes- 2 Ion Channel Electrostatics and the Shapes of Channel Proteins- 3 Superoxide Dismutase as a Model Ion Channel- 4 Single-Channel Enzymology- 5 How to Set Up a Bilayer System- 6 Fusion of Liposomes to Planar Bilayers- 7 Incorporation of Ion Channels by Fusion- II Nicotinic Acetylcholine Receptor- 8 The Reconstituted Acetylcholine Receptor- 9 Immunologic Analysis of the Acetylcholine Receptor- 10 Function of Acetylcholine Receptors in Reconstituted Liposomes- III Sodium Channel- 11 Skeletal Muscle Sodium Channels: Isolation and Reconstitution- 12 Reconstitution of the Sodium Channel from Electrophorus electricus- 13 The Reconstituted Sodium Channel from Brain- 14 Gating of Batrachotoxin-Activated Sodium Channels in Lipid Bilayers- 15 Ion Conduction Through Sodium Channels in Planar Lipid Bilayers- 16 Blocking Pharmacology of Batrachotoxin-Activated Sodium Channels- IV Other Channels in Model Membranes- 17 The Large Calcium-Activated Potassium Channel- 18 The Sarcoplasmic Reticulum Potassium Channel: Lipid Effects- 19 Characterization of Dihydropyridine-Sensitive Calcium Channels from Purified Skeletal Muscle Transverse Tubules- 20 Calcium Channels- 21 Phosphorylation of a Reconstituted Potassium Channel- 22 Voltage Gating in VDAC: Toward a Molecular Mechanism- 23 Analysis and Chemical Modification of Bacterial Porins

Calcium-activated potassium channels in single smooth muscle cells of rabbit jejunum and guinea-pig mesenteric artery.

Abstract: Single-channel studies were made using the patch-clamp technique of K channels in dispersed single smooth muscle cells from rabbit longitudinal jejunal muscle and guinea-pig small (less than 0.2 mm o.d.) mesenteric arteries. In isolated inside-out patches from these two types of smooth muscle cell there was a population of K channels which had single-channel conductances of about 100 pS in near physiological K gradients and about 200 pS with symmetrical 126 mM-K solutions. Their conductance and other properties distinguish them from a K channel of smaller conductance which we have previously described in these cells. The relative permeability of the channel with respect to K was 1.4 Tl:1.0 K:0.7 Rb: less than 0.05 Na: less than 0.05 Cs. Cs (1 mM applied to the outside of the membrane) interfered with inward K movement when the membrane was hyperpolarized. Rb conductance of the channel when both sides of the membrane were exposed to 126 mM-Rb was 30 pS. When the Ca concentration on the inside of the membrane ([Ca]i) was about 10(-9) M, K channel opening was rarely observed and then only at strongly positive potentials. At [Ca]i between 10(-9) M and 10(-7) M mean channel open time increased and the probability of channel opening increased steeply; both were further increased by increasing membrane positivity. At [Ca]i between 10(-6) M and 2.5 mM the channel was mainly in the open state and the probability of channel conducting state often declined with increasing membrane positivity. The effects of varying [Ca]i from 10(-7) M to 2.5 mM on the kinetic activity of a single channel was studied largely in mesenteric artery patches containing one active channel. The distribution of open times could be fitted by a single exponential at low (less than 10(-6) M) [Ca]i but a component of fast openings (to less than 1.0 ms) was observed at all potentials at [Ca]i 2.5 mM. Closed time distribution required the sum of three exponentials to fit it all [Ca]i greater than 10(-7) M; at [Ca]i 10(-6) M or greater evidence of a fourth component, probably caused by Ca block of open channels, was obtained. Raising [Ca]i increased the mean duration of the (long) open state and decreased or had no effect on the duration of short, intermediate, and long mean closed states.

A metabolite-regulated potassium channel in rat pancreatic B cells.

Abstract: In B cells from dispersed rat islet of Langerhans we have identified an inward rectifying voltage-independent K+ channel whose behavior parallels the metabolically regulated potassium permeability (PK) found in tracer flux and microelectrode recording studies. In cell-attached patches of membrane, the channel is closed when any one of several substrates (glucose, mannose, leucine, or glyceraldehyde) is added to the cell's bathing solution but is reopened on addition of an appropriate metabolic inhibitor, which prevents utilization of that substrate. In inside-out excised patches, a K+ channel with nearly identical kinetic features is closed by addition of micromolar concentrations of ATP to the "cytoplasmic" solution. The ATP sensitivity of channel activity is modified by addition of ADP, suggesting competition at a nucleotide binding site. These results suggest the presence of a metabolically regulated K+ channel gated by intracellular concentrations of ATP or the ratio of ATP/ADP concentrations.

Two types of calcium channels in guinea pig ventricular myocytes.

Abstract: In cardiac muscle, Ca2+ plays a key role in regulation of numerous processes, including generation of the action potential and development of tension. The entry of Ca2+ into the cell is regulated primarily by voltage-gated channels in the membrane. Until recently, it was felt that only one type of Ca2+ channel existed in cardiac ventricular muscle. Experiments reported here suggest that in isolated guinea pig ventricular myocytes, there are two distinct types of Ca2+ channels with markedly different activation thresholds, inactivation kinetics, and sensitivities to inorganic and organic Ca2+ channel blockers. The channels were also distinguished based on their response to increased frequency of clamping such that the current through the low-threshold channel decreased while that through the high-threshold channel increased. In a few cells, the current through both channels was enhanced by isoproterenol, a beta-adrenergic agonist, but only the high-threshold channel was enhanced by the Ca2+-channel agonist Bay K 8644. Thus, isolated guinea pig ventricular myocytes appear to have two types of Ca2+ channels distinguished by various criteria.

Misread protein creates membrane channels: an essential step in the bactericidal action of aminoglycosides

Abstract: Among the pleiotropic effects of aminoglycosides, their irreversible uptake and their blockade of initiating ribosomes have appeared to explain their bactericidal action, while the contributions of translational misreading and membrane damage and the mechanism of that damage have remained uncertain. We now present evidence that incorporation of misread proteins into the membrane can account for the membrane damage. The bactericidal action thus appears to result from the following sequence, in which each step is essential: slight initial entry of the antibiotic; interaction with chain-elongating ribosomes, resulting in misreading; incorporation of misread protein into the membrane, creating abnormal channels; increased (and irreversible) entry through these channels, and hence increased misreading and formation of channels; and, finally, blockade of initiating ribosomes. This mechanism can account for several previously unexplained observations: that streptomycin uptake requires protein synthesis during, but not after, the lag before the membrane damage; that streptomycin-resistant cells, which fail to take up streptomycin, can do so after treatment by another aminoglycoside; and that puromycin at moderate concentrations accelerates streptomycin uptake, while high concentrations (which release shorter chains) prevent it. In addition, puromycin, prematurely releasing polypeptides of normal sequence, also evidently creates channels, since it is reported to promote streptomycin uptake even in streptomycin-resistant cells. These findings imply that normal membrane proteins must be selected not only for a hydrophobic anchoring surface, but also for a tight fit in the membrane.

Block of calcium channels by enkephalin and somatostatin in neuroblastoma-glioma hybrid NG108-15 cells.

Abstract: Leucine-enkephalin, methionine-enkephalin, and morphine caused a reversible block of Ca2+ channel currents in neuroblastoma-glioma hybrid cells (NG108-15). The long-lasting (type 2) component of the Ca2+ channel current was blocked by leucine-enkephalin, while the transient (type 1) component was not affected. The enkephalin-induced blocking action was antagonized by naloxone and appears to be mediated by delta-opiate receptors. Two different aspects of the blocking effect were detected, a resting block and a recovery from block during prolonged depolarizing pulses. Recovery from block was more complete, and its time course was more rapid, with depolarization to more positive potentials. The dose dependence of the type 2 channel block at rest indicated a one-to-one binding stoichiometry, with an apparent dissociation constant of 8.8 nM. Somatostatin exerted a similar selective blocking action on the type 2 Ca2+ channel. The time- and voltage-dependent block of type 2 Ca2+ channels may provide a mechanism underlying the enkephalinergic presynaptic inhibition of transmitter release and the somatostatin block of pituitary growth hormone release.

Endfeet of retinal glial cells have higher densities of ion channels that mediate K+ buffering.

Abstract: A major function of glial cells in the central nervous system is to buffer the extracellular potassium concentration, [K+]o. A local rise in [K+]o causes potassium ions to enter glial cells, which have membranes that are highly permeable to K+; potassium then leaves the glial cells at other locations where [K+]o has not risen. We report here the first study of the individual ion channels mediating potassium buffering by glial cells. The patch-clamp technique was employed to record single channel currents in Muller cells, the radial glia of the vertebrate retina. Those cells have 94% of their potassium conductance in an endfoot apposed to the vitreous humour, causing K+ released from active retinal neurones to be buffered preferentially to the vitreous. Recordings from patches of endfoot and cell body membrane show that a single type of inward-rectifying K+ channel mediates potassium buffering at both cell locations. The non-uniform density of K+ conductance is due to a non-uniform distribution of one type of K+ channel, rather than to the cell expressing high conductance channels at the endfoot and low conductance channels elsewhere on the cell.

IgE-mediated degranulation of mast cells does not require opening of ion channels

Abstract: Rat peritoneal mast cells respond to antigenic stimulation by releasing histamine through exocytosis. The dynamics of exocytosis can be investigated by dialysing single cells with patch pipettes using the whole-cell recording configuration of the patch-clamp technique1,2. However, dialysed cells fail to respond to external stimuli such as compound 48/80 or antigens, suggesting that essential cytoplasmic components have been washed out. We have developed a new patch-clamp configuration in which the patch under the pipette tip is not disrupted but instead permeabilized, preventing the diffusion of large molecules out of the cell. In this configuration the cell responds to external stimulation, and the capacitance as well as the conductance of the cell membrane can be recorded during degranulation. On antigenic stimulation, the cell capacitance (proportional to plasma membrane area), after an initial delay, increases by a factor of about 3. This increase in capacitance is often preceded by a transient increase in conductance. Agents that block Ca-activated channels inhibit this conductance change without affecting the amplitude and time course of degranulation. We therefore conclude that, in contrast to excitable secretory cells such as chromaffin cells2, mast cells do not use ion channels in stimulus-secretion coupling.

The molecular neurobiology of the acetylcholine receptor

Abstract: The acetylcholine receptor (AChR) is the most thoroughly characterized component ofthe neuromuscular transduction process. Earlier reviews that summarize the structural and biochemical features of the AChR include Popot & Changeux (1984), Stroud (1983), Conti-Tronconi & Raftery (1982), and Karlin (1980). This receptor translates the binding of the neurotrans­ mitter, acetylcholine (ACh), into a rapid increase and subsequent decrease in the permeability of the endplate membrane to the passage of cations. Inward flux of ions through the channel is passive, driven by elec­ trochemical gradients across the receptor-containing membrane. The physiological effect is to temporarily depolarize the endplate, a response that is translated into muscular contraction in the case of a neuromuscular junction, or potentiation of electric tissue in the stacked asymmetric cells of electric organs in Torpedo (a marine elasmobranch) or Electrophorus (a freshwater teleost). The availability of acetylcholine receptors from electric tissue was a fundamental key to molecular characterization. The subunit stoichiometry of the four identified polypeptides has been unequivocally established as 1X2/3yb, and the funnel shape of the molecule has been well characterized with respect to position of the ion channel. Distribution of protein relative to the phospholipid bilayer and some aspects ofthe subunit arrangements in a quasipentameric structure around the ion channel have also been established. The genes for the four subunits that constitute the

Pore formation by LamB of Escherichia coli in lipid bilayer membranes.

Abstract: Lipid bilayer experiments were performed in the presence of different Escherichia coli LamB preparations. These LamB preparations formed two types of pores in the membranes. Large pores, which had a single-channel conductance of 2.7 nS and comprised about 1 to 6% of the total pores, were presumably contaminants which might have been induced together with LamB. LamB itself formed small pores with a single-channel conductance of 160 pS in 1 M KCl. These pores could be completely blocked by the addition of maltose and maltodextrins. Titration of the pore conductance with maltotriose suggested that there was a binding site inside the pores with a Ks of 2.5 X 10(-4) M for maltotriose. On the basis of our data we concluded that the structure of the LamB channels is quite different from the structures of the channels of general diffusion porins, such as OmpF and OmpC.

Functional differences between two classes of sodium channels in developing rat skeletal muscle

Abstract: Excitability is generated in developing skeletal muscle by the incorporation of sodium-selective ion channels into the surface membrane. Whole-cell and patch voltage-clamp recording from myotubes and their embryologic precursors, myoblasts, indicated that voltage-activated sodium current in myoblasts was more resistant to block by tetrodotoxin (TTX) than that in myotubes. Single-channel recording from both cell types showed two classes of sodium channels. One class had a lower single-channel conductance, activated at more hyperpolarized voltages, and was more resistant to TTX than the other. The proportion of TTX-resistant to TTX-sensitive sodium channels was higher in myoblasts than in myotubes. Thus, the difference in TTX sensitivity between myoblasts and myotubes can be explained by a difference in the proportion of the two classes of sodium channels. In addition, the lower conductance of TTX-resistant channels provides insight into the relationship between the TTX binding site and the external mouth of the sodium channel.

Ion channels in yeast

Abstract: Voltage-dependent ion channels have been found in the plasma membrane of the yeast Saccharomyces cerevisiae. Ion channel activities were recorded from spheroplasts or patches of plasma membrane with the patch-clamp technique. The most prominent activities came from a set of potassium channels with the properties of activation by positive but not negative voltages, high selectivity for potassium over sodium ion, unit conductance of 20 picosiemens, inhibition by tetraethylammonium or barium ions, and bursting kinetics.

A patch-clamp study of histamine-secreting cells.

Abstract: The ionic conductances in rat basophilic leukemia cells (RBL-2H3) and rat peritoneal mast cells were investigated using the patch-clamp technique. These two cell types were found to have different electrophysiological properties in the resting state. The only significant conductance of RBL-2H3 cells was a K+-selective inward rectifier. The single channel conductance at room temperature increased from 2-3 pS at 2.8 mM external K+ to 26 pS at 130 mM K+. This conductance, which appeared to determine the resting potential, could be blocked by Na+ and Ba2+ in a voltage-dependent manner. Rat peritoneal mast cells had a whole-cell conductance of only 10-30 pS, and the resting potential was close to zero. Sometimes discrete openings of channels were observed in the whole-cell configuration. When the Ca2+ concentration on the cytoplasmic side of the membrane was elevated, two types of channels with poor ion specificity appeared. A cation channel, observed at a Ca2+ concentration of approximately 1 microM, had a unit conductance of 30 pS. The other channel, activated at several hundred micromolar Ca2+, was anion selective and had a unit conductance of approximately 380 pS in normal Ringer solution and a bell-shaped voltage dependence. Antigenic stimulation did not cause significant changes in the ionic conductances in either cell type, which suggests that these cells use a mechanism different from ionic currents in stimulus-secretion coupling.

Different types of Ca2+ channels in mammalian skeletal muscle cells in culture.

Abstract: This paper describes the existence of two pharmacologically distinct types of Ca2+ channels in rat skeletal muscle cells (myoballs) in culture. The first class of Ca2+ channels is insensitive to the dihydropyridine (DHP) (+)-PN 200-110; the second class of Ca2+ channels is blocked by low concentrations of (+)-PN 200-110. The two pharmacologically different Ca2+ channels are also different in their voltage and time dependence. The threshold for activation of the DHP-insensitive Ca2+ channel is near -65 mV, whereas the threshold for activation of the DHP-sensitive Ca2+ channel is near -30 mV. Current flowing through the DHP-insensitive Ca2+ channel is transient with relatively fast kinetics. Half-maximal inactivation for the DHP-insensitive Ca2+ channel is observed at a holding potential Vh0.5 = -78 mV and the channel is completely inactivated at -60 mV. Two different behaviors have been found for DHP-sensitive channels with two different kinetics of inactivation (one being about 16 times faster than the other at -2 mV) and two different voltage dependencies. These two different behaviors are often observed in the same myoball and may correspond to two different subtypes of DHP-sensitive Ca2+ channels or to two different modes of expression of one single Ca2+ channel protein.

Acetylcholine activation of K+ channels in cell-free membrane of atrial cells

Abstract: The activation mechanisms of K+ channels by muscarinic acetylcholine (m-ACh) receptors were examined in isolated atrial cells by use of patch-recording technique. In "cell-attached" patch recordings, ACh, present in the pipette, activated an inwardly rectifying K+ channel. In "inside-out" patches, activation of the K+ channel by ACh diminished with time following excision of the patch, but it resumed when GTP was present in the solution bathing the intracellular side of the membrane. The A protomer of pertussis toxin, together with NAD, inhibited the channel activation in the presence of GTP. Since pertussis toxin specifically ADP-ribosylates GTP-binding proteins Ni and No, which can interact with m-ACh receptors, and inhibits their functions, it was concluded that m-ACh receptors communicate with the K+ channel via GTP-binding proteins, probably Ni and/or No, in atrial cell membrane.

Biophysics of mechanoreception.

Abstract: Several types of cells' skeletal, muscle, nerve, epithelia, and heart have been shown to contain ion channels which are sensitive to membrane tension. In chick skeletal muscle, the transduction persists in excised patches and involves no chemical messengers. Quantitative analysis of single channel records reveals that the sensitivity to stretch can be described by a linear four state model with three closed (C) and one open (O) state: (Formula: see text). Only the rate constant k12 is sensitive to tension (and membrane potential) following the law: k12 = kO12 exp/(theta T2 + alpha V) where theta is a constant describing the sensitivity to tension, T, and alpha is a constant describing the sensitivity to voltage, V, and kO12 is a constant. The form of the tension sensitivity can be accounted for by a model in which strain energy is used to gate the channel. Analysis of strain sensitivity, theta, indicates that the channel must concentrate energy from a large (ca. 500-nm diameter) area of membrane which suggests that the channel is in series with a component of the cytoskeleton. Treatment with cytochalasins suggests that actin is mechanically in parallel with the channel. When a channel with the above properties is incorporated into a simple model of mechanical transduction in hair cells, the resulting model is capable of explaining the kinetic features and the sensitivity found in the cochlear-vestibular system. The proposed gating mechanism of mechanical transduction appears to be general and can account for existing data on a variety of systems.

Interactions of divalent cations with single calcium channels from rat brain synaptosomes.

Abstract: Voltage-dependent calcium channels from a rat brain membrane preparation ("synaptosomes") were incorporated into planar lipid bilayers. The effects of calcium, barium, strontium, manganese, and cadmium ions on the amplitudes and kinetics of single channel currents were examined. The order of single channel conductances was gBa greater than gSr greater than gMn, which was the inverse of the order of the mean channel open times: TMn greater than TCa = TSr greater than TBa. In contrast, the identity of the charge carrier had little or no effect on the mean closed times of the channel. Manganese, in the absence of other permeant ions, can pass through single channels (gMn = 4 pS). However, when added to a solution that contained another type of permeant divalent cation, manganese reduced the single channel current in a voltage-dependent manner. Cadmium, a potent blocker of macroscopic "ensemble" calcium currents in many preparations, reduced the current through an open channel in a manner consistent with Cd ions both not being measurably permeant and interacting with a single site. The permeant ions competed with cadmium for this site with the following order: Mn greater than Sr = Ca greater than Ba. These results are consistent with the existence of no less than one divalent cation binding site in the channel that regulates ion permeation.

Effects of the external pH on Ca channels: experimental studies and theoretical considerations using a two-site, two-ion model

Abstract: Some effects of the external pH on Ca channels were studied in a hybridoma cell line (mAb-7B), by using the whole-cell configuration of the patch-clamp technique. As the pH was lowered, both the activation and the inactivation curves shifted toward less negative membrane potentials, suggesting a pH-induced decrease of an external negative surface potential, sensed by the mechanism of gating. The potential for half-activation, V1/2, and that for half-inactivation, Vh, were related by a straight line with a slope of one. The inward current varied exponentially with V1/2, as would be expected if the field inside the channel and the Ca2+ concentration at the entrance were sensitive to the surface potential. However, the reversal potential and the outward current were unaltered by changes in the pH. Under the hypothesis that the channel senses the surface potential, all these results, as well as the nernstian behavior of the reversal potential with respect to Ca2+, observed in previous studies, are accounted for by a three-barrier, two-ion model for a channel, provided it is assumed that the potential in the channel drops almost entirely across the barrier adjacent to the external solution.

Channel properties of an insect neuronal acetylcholine receptor protein reconstituted in planar lipid bilayers.

Abstract: A pentameric membrane protein composed of four types of polypeptide has been identified as the minimal structural unit responsible for the electrogenic action of acetylcholine on electrocytes and muscle cells1–3. Because many populations of central and peripheral neurones also have nicotinic acetylcholine receptors (AChRs), considerable effort has recently gone into identifying the neuronal receptor4,5. The central nervous tissue of insects contains very high concentrations of nicotinic AChRs6,7, and we have recently purified an α-toxin binding protein, a putative AChR, from neuronal membranes of locusts8,9. It is a component of high relative molecular mass, clearly composed of identical subunits, a structure predicted for an ancestral AChR protein10,11. To verify that the purified polypeptides not only represent ligand binding sites but that they are indeed functional receptors, we have now reconstituted the isolated protein in a planar lipid bilayer. We show that in this system cholinergic agonists activate functional ion channels, that have properties comparable to those exhibited by the peripheral AChRs in vertebrates; thus, for the first time a functional acetylcholine receptor channel has been indentified in nerve cells.

Two calcium currents in a smooth muscle cell line

Abstract: Membrane currents in small cells of a smooth muscle cell line (A10) derived from embryonic rat thoracic aorta were monitored by the patch electrode whole-cell voltage clamp technique. Three currents, two divalent cation currents, and a Ca2+-activated K+ current have been observed. The latter is readily abolished pharmacologically, allowing the characterization of the divalent cation currents. With a holding potential of -50 mV, a single divalent current, which inactivates slowly, is elicited on depolarization of the membrane potential to values positive to ca. -10 mV. The second divalent cation current is only observed when the holding potential is negative to -55 mV and the membrane is pulsed to values positive to ca. -35 mV. This current is rapidly inactivating, peaking in approximately 5 ms and decaying with a t1/2 of ca. 15 ms at 0 mV when conveyed by Ba2+. The rapidly inactivating divalent cation current is depressed by substitution of Ba2+ for Ca2+ in the bathing solution and is highly insensitive to organic Ca2+ channel blockers. The slowly inactivating channel has more typical characteristics of Ca2+ channels; it is more permeable to Ba2+ than to Ca2+ and is sensitive to modulation by dihydropyridines. These data demonstrate the presence of two distinctly different Ca2+ channels in A10 cells.

The selectivity filter of voltage-dependent channels formed by phosphoporin (PhoE protein) from E. coli.

Abstract: Phosphoporin, an Escherichia coli outer membrane-spanning protein re-incorporated in phospholipid planar bilayers generates aqueous channels similar to those of matrix porin One phosphoporin trimer contains three pores which are induced simultaneously but fluctuate separately between open and closed states Membrane potential shifts this two-state equilibrium in favour of closed channels This negative resistance occurs at lower potentials than with matrix porin channels The phosphoporin channel is poorly anion selective for small solutes Polyphosphates and other phosphorylated molecules specifically inhibit phosphoporin pore conductance to small ions, a property which is specific to phosphoporin There is an excellent correlation between the effect of such solutes measured in planar bilayers and their inhibitory effect on beta-lactam antibiotic uptake in vivo by phosphoporin It is concluded that the phosphoporin channel contains a selectivity filter which is only efficient for larger molecules, most probably through basic residues

Functional Channel Formation Associated With Cytotoxic T-cell Granules

Abstract: Lymphocyte granules from cytotoxic T-lymphocyte lines A2, A11, and R8 were enriched by subcellular fractionation using a Percoll gradient. Granule-enriched fractions showed potent hemolytic activity in the presence of Ca2+. Isolated granules induced rapid Ca2+-dependent membrane depolarization of J774 macrophage-like cells. When tested in planar bilayers, granules induced the formation of Ca2+-dependent functional ion channels of large conductance steps of 1-6 nS in 0.1 M NaCl. Granule-induced channels were resistant to closing by an increase in transmembrane potential, with few channels shifting to the closed state only at voltages of greater than 70 mV, following a Poisson process. These channels showed poor ion selectivity and were permeable to all monovalent and divalent ions (K+, Na+, Li+, Cl-, Ca2+, Mg2+, Zn2+, Ba2+). Ultrastructural examination of soluble granule proteins incubated for 48 hr at 37 degrees C in the presence of Ca2+ revealed ring-like structures of 150-200 A. Structural and functional channel formation may be involved in cytolysis induced by cytotoxic T lymphocytes.