Properties of histamine-activated chloride channels in the large monopolar cells of the dipteran compound eye: a comparative study

The large monopolar cells (LMCs) of the first optic neuropil (lamina) in insects respond to the photoreceptor neurotransmitter histamine with an increase in chloride conductance. We have compared the properties of this conductance from a range of diptera from different visual environments: Tipula paludosa (slow flying, crepuscular), Drosophila melanogaster (slow-flying diurnal), and 3 fast-flying diurnal species Musca domestica, Calliphora vicina and Lucilia sericata. In whole-cell recordings of dissociated LMCs, histamine-induced currents were elicited using a multichannel parallel perfusion device, allowing rapid determination of the dose-response function, characterised by affinity (K _d) and Hill coefficient (n). Calliphora, Lucilia and Musca had the steepest dose response curves (n = 2.8) and the lowest affinity for histamine (K _d 35–50 M); the crepuscular Tipula had a significantly higher affinity (K _d = 16 M) and lower Hill coefficient (n = 1.8). Drosophila had a high affinity (K _d 24 M), and a high Hill coefficient (n = 2.5). In excised inside-out patch recordings all species showed similar single channel properties (conductance 40–60 pS, mean open time < 1 ms). The low Hill coefficient in Tipula would be expected to result in lower synaptic gain. We suggest this may be an adaptation to prevent the LMC's response bandwidth being filled with the high levels of photon noise typical of photoreceptors adapted for low light levels. The lower affinity for histamine found in the more photopic species suggests that the concentration of histamine (and therefore presumably number of synaptic vesicles released from the photoreceptors) should be higher. This might improve signal-to-noise ratio by decreasing the contribution of the shot event noise introduced by stochastic release of synaptic vesicles.Abbreviations LMC large monopolar cell - TES N Tris-(hydroxymethyl)-methyl-2-amino-ethane-sulphonic acid - K _D slow delayed rectifier - K _A transient A current - K _a apparent dissociation constant     

Sodium Metabisulfite Modulation of Potassium Channels in Pain-Sensing Dorsal Root Ganglion Neurons

The effects of sodium metabisulfite (SMB), a general food preservative, on potassium currents in rat dorsal root ganglion (DRG) neurons were investigated using the whole-cell patch-clamp technique. SMB increased the amplitudes of both transient outward potassium currents and delayed rectifier potassium current in concentration- and voltage-dependent manner. The transient outward potassium currents (TOCs) include a fast inactivating (A-current or I _A) current and a slow inactivating (D-current or I _D) current. SMB majorly increased I_A, and I_D was little affected. SMB did not affect the activation process of transient outward currents (TOCs), but the inactivation curve of TOCs was shifted to more positive potentials. The inactivation time constants of TOCs were also increased by SMB. For delayed rectifier potassium current (I _K), SMB shifted the activation curve to hyperpolarizing direction. SMB differently affected TOCs and I _K, its effects major on A-type K⁺ channels, which play a role in adjusting pain sensitivity in response to peripheral redox conditions. SMB did not increase TOCs and I _K when adding DTT in pipette solution. These results suggested that SMB might oxidize potassium channels, which relate to adjusting pain sensitivity in pain-sensing DRG neurons.     

Depolarization-induced automaticity in rat ventricular cardiomyocytes is based on the gating properties of L-type calcium and slow Kv channels

Depolarization-induced automaticity (DIA) of cardiomyocytes is the property of those cells to generate pacemaker cell-like spontaneous electrical activity when subjected to a depolarizing current. This property provides a candidate mechanism for generation of pathogenic ectopy in cardiac tissue. The purpose of this study was to determine the biophysical mechanism of DIA in terms of the ion conductance properties of the cardiomyocyte membrane. First, we determined, by use of the conventional whole-cell patch-clamp technique, the membrane conductance and DIA properties of ventricular cardiomyocytes isolated from adult rat heart. Second, we reproduced and analysed DIA properties by using an adapted version of the experimentally based mathematical cardiomyocyte model of Pandit et al. (Biophys J 81:3029–3051 2001, Biophys J 84:832–841 2003) and Padmala and Demir (J Cardiovasc Electrophysiol 14:990–995 2003). DIA in 23 rat cardiomyocytes was a damped membrane potential oscillation with a variable number of action potentials and/or waves, depending on the strength of the depolarizing current and the particular cell. The adapted model was used to reconstruct the DIA properties of a particular cardiomyocyte from its whole-cell voltage-clamp currents. The main currents involved in DIA were an L-type calcium current (I _CaL) and a slowly activating and inactivating Kv current (I _ss), with linear (I _B) and inward rectifier (I _K1) currents acting as background currents and I _Na and I _t as modulators. Essential for DIA is a sufficiently large window current of a slowly inactivating I _CaL combined with a critically sized repolarizing current I _ss. Slow inactivation of I _ss makes DIA transient. In conclusion, we established a membrane mechanism of DIA primarily based on I _CaL, I _ss and inward rectifier properties; this may be helpful in understanding cardiac ectopy and its treatment.     

The voltage-dependent potassium-uptake channel of corn coleoptiles has permeation properties different from other K+ channels

The initial response of coleoptile cells to growth hormones and light is a rapid change in plasma-membrane polarization. We have isolated protoplasts from the cortex of maize (Zea mays L.) coleoptiles to study the electrical properties of their plasma membrane by the patch-clamp techniqueUsing the whole-cell configuration and cell-free membrane patches we could identify an H⁺-ATPase, hyperpolarizing the membrane potential often more negative than -150 mV, and a voltage-dependent, inward-rectifying K⁺ channel (unit conductance 5–7 pS) as the major membrane conductan-ces Potassium currents through this channel named CKC1_in (for Coleoptile K ⁺ Channel inward rectifier) were elicited upon voltage steps negative to -80 mV, characterized by a half-activation potential of -112 mV. The kinetics of activation, well described by a double-exponential process, were strongly dependent on the degree of hyperpolarization and the cytoplasmic Ca²⁺ level. Whereas at nanomolar Ca²⁺ concentrations K⁺ currents increased with a t_1/2=16 ms (at -180 mV), higher calcium levels slowed the activation process about fourto fivefoldUpon changes in the extracellular K⁺ concentration the reversal potential of the K⁺ channel followed the Nernst potential for potassium with a 56-mV shift for a tenfold increaseThe absence of a measurable conductance for Na⁺, Rb⁺, Cs⁺ and a permeability ratio P_{NH 4} ⁺ /P_K+ around 0.25 underlines the high selectivity of CKC1_in for K⁺In contrast to Cs⁺, which at submillimolar concentration blocks the channel in a voltage-dependent manner, Rb⁺, often used as a tracer for K+, does not permeate this type of K⁺ channelThe lack of Rb⁺ permeability is unique with respect to other K⁺ transporters. Therefore, future molecular analysis of CKC1_in, considered as a unique variation of plant inward rectifiers, might help to understand the permeation properties of K⁺ channels in general.Abbreviations CKC1_in Coleoptile K ⁺ Channel inward rectifier - U membrane voltage - I_ss steady-state currents - I_tail tail currents Experiments were conducted in the laboratory of F.G. during the stay of RHas a guest professor sponsored by Special Project RAISA, subproject N2.1, paper N2155.     

Simulations of voltage clamping poorly space-clamped voltage-dependent conductances in a uniform cylindrical neurite

Significant error is made by using a point voltage clamp to measure active ionic current properties in poorly space-clamped cells. This can even occur when there are no obvious signs of poor spatial control. We evaluated this error for experiments that employ an isochronal I(V) approach to analyzing clamp currents. Simulated voltage clamp experiments were run on a model neuron having a uniform distribution of a single voltage-gated inactivating ionic current channel along an elongate, but electrotonically compact, process. Isochronal Boltzmann I(V) and kinetic parameter values obtained by fitting the Hodgkin-Huxley equations to the clamp currents were compared with the values originally set in the model. Good fits were obtained for both inward and outward currents for moderate channel densities. Most parameter errors increased with conductance density. The activation rate parameters were more sensitive to poor space clamp than the I(V) parameters. Large errors can occur despite normal-looking clamp curves.     

The Androctonus australis garzoni scorpion venom contains toxins that selectively affect voltage-dependent K+-channels in cerebellum granular cells

A purified peptide from Androctonus australis Garzoni venom (AaG) affects selectively a K⁺-current recorded from cerebellum granular cells. This current is characterized by fast activating and inactivating kinetics similar to an I_A-type current. Addition of 2 μm peptide Aa1 (from Androctonus australis, toxin 1) to the external side of the channel suppressed completely and in a selective manner the I_A-type current, with an IC50 value of 130 nm, whereas in the same conditions, the other potassium current, identified as delayed rectifier (I_d), was not affected. Additionally, we show that another partially purified peptide (III-12) from the same venom was able to block reversibly both K⁺-currents. Received: 10 February 1997 / Accepted: 7 August 1997     

Models of membrane resonance in pigeon semicircular canal type II hair cells

Pigeon vestibular semicircular canal type II hair cells often exhibit voltage oscillations following current steps that depolarize the cell membrane from its resting potential. Currents active around the resting membrane potential and most likely responsible for the observed resonant behavior are the Ca⁺⁺-insensitive, inactivating potassium conductance I _A (A-current) and delayed rectifier potassium conductance I _K. Several equivalent circuits are considered as representative of the hair cell membrane behavior, sufficient to explain and quantitatively fit the observed voltage oscillations. In addition to the membrane capacitance and frequency-independent parallel conductance, a third parallel element whose admittance function is of second order is necessary to describe and accurately predict all of the experimentally obtained current and voltage responses. Even though most voltage oscillations could be fitted by an equivalent circuit in which the second order admittance term is overdamped (i.e., represents a type of current with two time constants, one of activation and the other of inactivation), the sharpest quality resonance obtained with small current steps (around 20 pA) from the resting potential could be satisfactorily fit only by an underdamped term.     

Alanine-stimulated exocytosis in<Emphasis Type="Italic"> Aplysia</Emphasis> enterocytes: effect of Na<Superscript>+</Superscript> transport and requirement for actin filaments

We used the Aplysia californica intestinal epithelium to investigate the effect of alanine-stimulated Na⁺ absorption on apical membrane exocytosis and whether stimulated exocytosis requires intact actin filaments. The fluid-phase marker fluorescein dextran was used to determine rates of apical membrane exocytosis. L-alanine significantly increased apical exocytosis by ~30% compared to controls, and there is a modest, positive correlation between alanine-stimulated exocytosis and short-circuit current (I _SC). Thus, apical exocytosis is modulated to some extent by the magnitude of Na⁺ and alanine entry across the apical membrane. Apical exocytosis is also responsive to virtually any increase in Na⁺ and alanine entry because increments in alanine-stimulated I _SC as small as 1 A/cm² stimulated exocytosis. We used D-alanine to determine which parameter (sensitivity to transport vs. magnitude of transport) was most important in activation of apical exocytosis. D-alanine-stimulated I _SC was one-sixth that of L-alanine, but stimulated exocytosis was only 29% less than that of L-alanine. Therefore, the apical exocytic system is more responsive to small increases in transport than to the magnitude of transport. Latrunculin A (Lat-A) disrupts the actin cytoskeleton and reduced constitutive apical exocytosis by ~65% and completely abolished alanine-stimulated exocytosis. Hence, constitutive exocytosis and alanine-stimulated exocytosis require actin filaments for recruitment of vesicles to the apical membrane. During nutrient absorption, actin filament-regulated apical exocytosis may represent a negative feedback system that modulates apical membrane tension.Abbreviations alaASW ASW containing alanine - C _m membrane capacitance - ASW artificial seawater - ETOH ethanol - fCa apical membrane fractional capacitance - FD fluorescein dextran - G _K plasma membrane potassium conductance - G _K,a apical membrane potassium conductance - HRP horseradish peroxidase - I _SC short-circuit current - J _Na transcellular net sodium flux - K _D dissociation constant - Lat-A latrunculin A - manASW ASW containing mannitol - PT proximal tubule - RFU relative fluorescence units - V _a apical membrane potential Communicated by L.C.-H. Wang     

Plasmalemmal,voltage-dependent ionic currents from excitable pulvinar motor cells ofMimosa pudica

Summary Plasmalemmal ionic currents from excitable motor cells of the primary pulvinus ofMimosa pudica were investigated by patch-clamp techniques. In almost all of the enzymatically isolated protoplasts, a delayed rectifier potassium current was activated by depolarization, while no currents were detected upon hyperpolarization. This sustained outward current was reversibly blocked by Ba and TEA and serves to repolarize the membrane potential. Outward single channel currents that very likely underly the macroscopic outward potassium current had an elementary conductance of 20 pS. In addition, in a few protoplasts held at hyperpolarized potentials, depolarization-activated transient inward currents were observed, and under current clamp, action potential-like responses were triggered by depolarizing current injections or by mechanical perturbations. The activation characteristics of both inward currents and spikes showed striking similarities compared to those of action potentialsin situ.     

DIDS increases K+ secretion through an I sKchannel in apical membrane of vestibular dark cell epithelium of gerbil

Vestibular dark cell epithelium secretes K⁺ via I _sKchannels in the apical membrane. The previous observation that disulfonic stilbenes increased the equivalent short circuit current (I _sc) suggested that these agents might be useful investigative tools in this tissue. The present experiments were conducted to determine if the increase in I _scwas associated with an increase in K⁺ flux and if the effect was directly on the I _sKchannel or indirectly via a cytosolic intermediary. Measurements of transepithelial K⁺ flux with the K⁺-selective vibrating probe and of changes in net cellular solute flux by measurements of epithelial cell height showed that 4,4-diisothiocyanatostilbene-2,2-disulfonic acid (DIDS) increased K⁺ flux by a factor of 1.96±0.71 and caused net solute efflux. The apical membrane was partitioned with a macropatch pipette and DIDS was applied either to the membrane outside the pipette, inside the pipette or to the entire apical membrane. DIDS inside the pipette increased the current across the patch, the membrane conductance, the slowly-inactivating (I _sK) component of the membrane current and shifted the reversal voltage toward the equilibrium potential for K⁺. DIDS outside the patch decreased the patch current and conductance, consistent with shunting of current away from the membrane patch. These findings strongly support the notion that DIDS increases K⁺ secretion through I _sKchannels in the apical membrane of vestibular dark cell epithelium by acting directly on the channels or on a tightly colocalized membrane component.We thank Dr. Peter J.S. Smith and Alan Shipley of the National Vibrating Probe Facility at the Marine Biological Laboratory at Woods Hole, MA for their support and assistance in the measurements of K⁺ flux. This work was supported by National Institutes of Health grants R01-DC00212, R29-DC1098 and P41-RR01395.     

Basolateral K channel activated by carbachol in the epithelial cell line T84

Cholinergic stimulation of chloride secretion involves the activation of a basolateral membrane potassium conductance, which maintains the electrical gradient favoring apical Cl efflux and allows K to recycle at the basolateral membrane. We have used transepithelial short-circuit current (I _SC), fluorescence imaging, and patch clamp studies to identify and characterize the K channel that mediates this response in T₈₄ cells. Carbachol had little effect on I _SC when added alone but produced large, transient currents if added to monolayers prestimulated with cAMP. cAMP also enhanced the subsequent I _SC response to calcium ionophores. Carbachol (100 m) transiently elevated intracellular free calcium ([Ca²⁺] _i ) by 3-fold in confluent cells cultured on glass coverslips with a time course resembling the I _sc response of confluent monolayers that had been grown on porous supports. In parallel patch clamp experiments, carbachol activated an inwardly rectifying potassium channel on the basolateral aspect of polarized monolayers which had been dissected from porous culture supports. The same channel was transiently activated on the surface of subconfluent monolayers during stimulation by carbachol. Activation was more prolonged when cells were exposed to calcium ionophores. The conductance of the inward rectifier in cell-attached patches was 55 pS near the resting membrane potential (–54 mV) with pipette solution containing 150 mm KCl (37°C). This rectification persisted when patches were bathed in symmetrical 150 mm KCl solutions. The selectivity sequence was 1 K > 0.88 Rb > 0.18 Na Cs based on permeability ratios under bi-ionic conditions. The channel exhibited fast block by external sodium ions, was weakly inhibited by external TEA, was relatively insensitive to charybdotoxin, kaliotoxin, 4-aminopyridine and quinidine, and was unaffected by external 10 mm barium. It is referred to as the K_BIC channel based on its most distinctive properties (Ba-insensitive, inwardly rectifying, Ca-activated). Like single K_BIC channels, the carbachol-stimulated I _SC was relatively insensitive to several blockers on the basolateral side and was unaffected by barium. These comparisons between the properties of the macroscopic current and single channels suggest that the K_BIC channel mediates basolateral membrane K conductance in T₈₄ cell monolayers during stimulation by cholinergic secretagogues.We thank Dr. Marcel Crest (Laboratoire de Neurobiologie, CNRS, Marseille) for providing a sample of kaliotoxin. This work was supported by the Canadian Cystic Fibrosis Foundation and the Respiratory Health Network of Centres of Excellence. J.W.H. is a Chercheur-Boursier of the Fonds de la recherche en santé du Québec.     

Bifurcation Analysis of Genetically Engineered Pacemaking in Mammalian Heart

Genetically engineered pacemaking in ventricular cells has been achieved by down-regulation of the time independent inward rectifying current (I _K1), or insertion of the hyperpolarisation-activated funny current (I _f). We analyse the membrane system (i.e. ionic concentrations clamped) of an epicardial Luo-Rudy dynamic cell model using continuation algorithms with the maximum conductance () of I _K1 and I _f as bifurcation parameters. Pacemaker activity can be induced either via Hopf or homoclinic bifurcations. As _K1 is decreased by ≈74%, autorhythmicity emerged via a homoclinic bifurcation, i.e., the periodicity first appear with infinitely large periods. In contrast, the insertion of _f induced periodicity via a subcritical Hopf bifurcation at _f≈ 0.25 mSμF⁻¹. Stable autorhythmic action potentials occurred at _f > 0.329 mSμF⁻¹.     

Changes in the kinetics of phosphate and potassium absorption in nutrient-deficient barley roots measured by a solution-depletion technique

From measurements of the rates of depletion of labelled ions from solution in the low concentration range, we described the phosphate and potassium uptake characteristics of the roots of intact barley plants in terms of the kinetic parameters, K _m and I _max (the maximum rate of uptake). In relatively young (13 d) and older (42 d) plants, cessation of phosphate supply for 4 d or more caused a marked increase in I _max (up to four times), without concomitant change in K _m, which remained between 5 and 7 M. By contrast, 1 d of potassium starvation with 14-d plants caused a decline in the K _m (i.e. an increased apparent affinity for potassium) from 53 M to 11 M, without alteration to I _max. After longer periods of potassium starvation, I _max increased (about two times) while the K _m remained at the same low value. Growth of shoots and roots were unaffected by these treatments, so that concentrations of ions in the tissues declined after 1 d or more of nutrient starvation, but we could not identify a characteristic endogenous concentration for either nutrient at which changes in kinetic parameters were invariably induced. The possible mechanisms regulating carriermediated transport, and the importance of changes induced in kinetic parameters in ion uptake from solution and soil are discussed.Symbol I _max the maximum rate of absorption at saturating concentrations     

GABA-gated anion channels in intact crayfish opener muscle fibres and stretch-receptor neurons are neither activated nor desensitized by glutamate

Summary The influence of glutamate on the GABA-activated Cl^- conductance was studied in the slowly adapting stretch-receptor neuron and dactylopodite opener muscle fibre of the crayfish (Astacus astacus) using a two-microelectrode and a three-microelectrode voltage clamp, respectively. Glutamate (0.5–1.0 mM) had no effect on the GABA-activated conductance in either preparation. This indicates that the availability of the inhibitory channels for activation of GABA is not influenced by glutamate. The present results are in sharp contrast to those obtained by Franke et al. (J Comp Physiol A 159:591–609, 1986) in experiments on excised membrane patches, which suggested that glutamate is capable of both activating and desensitizing inhibitory postsynaptic channels in the crayfish opener muscle fibre.Abbreviations GABA -aminobutyric acid - G_GABA and G _GABA ^p GABA-gated conductance and peak conductance - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulphonic acid - I current - SRN stretch-receptor neuron - V_m and V_l membrane voltage in two- and three-microelectrode voltage clamp, respectively     

The toxin helothermine affects potassium currents in newborn rat cerebellar granule cells

Helothermine, a recently isolated toxin from the venom of the Mexican beaded lizard Heloderma horridum horridum was tested on K⁺ currents of newborn rat cerebellar granule cells. In whole-cell voltageclamp experiments, cerebellar granule neurons exhibited at least two different K⁺ current components: a first transient component which is similar to an I _A-type current, is characterized by fast activating and inactivating kinetics and blocked by 4-aminopyridine; a second component which is characterized by noninactivating kinetics, is blocked by tetraetylammonium ions and resembles the classical delayed-rectifier current. When added to the standard external solution at concentrations ranging between 0.1 and 2 m helothermine reduced the pharmacologically isolated I _A-type current component in a voltage- and dose-dependent way, with a half-maximal inhibitory concentration (IC₅₀) of 0.52 m. A comparison between control and nelothermine-modified peak transient currents shows a slowdown of activation and inactivation kinetics. The delayed-rectifier component inhibition was concentration dependent (IC₅₀ = 0.86 m) but not voltage dependent. No frequency-or use-dependent block was observed on both K⁺ current types. Perfusing the cells with control solution resulted in quite a complete current recovery. We conclude that helothermine acts with different affinities on two types of K⁺ current present in central nervous system neurons.     

Aldosterone regulation of active sodium chloride transport in the lizard colon (Gallotia galloti)

Summary Bioelectrical parameters and unidirectional sodium and chloride fluxes were measured under voltageclamp conditions in groups of lizards submitted to single or chronic aldosterone treatment. Both acute (AT) and chronic (CT) treatment induced significant increases in the short-circuit current (I _sc), as well as in the mucosa-to-serosa (J _m-s ^Na ) and net sodium flux (J _net ^Na ). In AT tissues, aldosterone did not change net chloride flux (J _net ^Cl ) but did so in CT tissues. Amiloride reduced the aldosterone-increased I _sc in AT and CT tissues, inhibited J _net ^Na in AT tissues and abolished it in CT colons. J _net ^Cl was also reduced by the diuretic in the group of AT colons, whereas no changes were observed in the CT tissues. Addition of luminal DIDS reduced Na⁺ absorption and totally inhibited Cl^- absorption in the AT tissues, but did not change I _sc. However, in CT tissues neither Na⁺ nor Cl^- transport were affected by DIDS. A good relationship between I _sc and J _m-s ^Na was apparent after DIDS treatment in AT tissues. In this group, simultaneous addition of DIDS and amiloride totally abolished J _net ^Na and reduced I _sc to untreated control values. Addition of serosal ouabain abolished I _sc and Na⁺ absorption in AT and CT colons, but Cl^- absorption was only altered in AT tissues. These results support the hypothesis that aldosterone induces an electrogenic, amiloride-sensitive sodium absorption, and in a dose-dependent fashion suppresses electroneutral NaCl absorption in the lizard colon.Abbreviations AT acutely treated - CT chronically treated animals - DIDS 4-4-diisothiocyanatostibene-2-2-disulfonic acid - DMSO dimethylsulphoxide - G _t tissue conductance - I _sc short circuit current - PD transepithelial potential difference - SITS 4-acetamido-4-isothiocyanatostilbene-2-2-disulfonic acid - UC untreated controls Preliminary results of this paper were presented at the X ^th meeting of the European Intestinal Transport Group (EITG), Askov Hojskole, Denmark, 16–19 September 1990     

The early stages of the intracellular transport of membrane proteins: clinical and pharmacological implications

Intracellular transport mechanisms ensure that integral membrane proteins are delivered to their correct subcellular compartments. Efficient intracellular transport is a prerequisite for the establishment of both cell architecture and function. In the past decade, transport processes of proteins have also drawn the attention of clinicians and pharmacologists since many diseases have been shown to be caused by transport-deficient proteins. Membrane proteins residing within the plasma membrane are transported via the secretory (exocytotic) pathway. The general transport routes of the secretory pathway are well established. The transport of membrane proteins starts with their integration into the ER membrane. The ribosomes synthesizing membrane proteins are targeted to the ER membrane, and the nascent chains are co-translationally integrated into the bilayer, i.e., they are inserted while their synthesis is in progress. During ER insertion, the orientation (topology) of the proteins in the membrane is determined. Proteins are folded, and their folding state is checked by a quality control system that allows only correctly folded forms to leave the ER. Misfolded or incompletely folded forms are retained, transported back to the cytosol and finally subjected to proteolysis. Correctly folded proteins are transported in the membranes of vesicles through the ER/Golgi intermediate compartment (ERGIC) and the individual compartments of the Golgi apparatus (cis, medial, trans) to the plasma membrane. In this review, the current knowledge of the first stages of the intracellular trafficking of membrane proteins will be summarized. This early secretory pathway includes the processes of ER insertion, topology determination, folding, quality control and the transport to the Golgi apparatus. Mutations in the genes of membrane proteins frequently lead to misfolded forms that are recognized and retained by the quality control system. Such mutations may cause inherited diseases like cystic fibrosis or retinitis pigmentosa. In the second part of this review, the clinical implications of the early secretory pathway will be discussed. Finally, new pharmacological strategies to rescue misfolded and transport-defective membrane proteins will be outlined.Abbreviations AP1 Clathrin-associated adaptor protein complex 1 - AQP Aquaporin - ARF ADP-ribosylation factor - AVP 8-Arginine-vasopressin;BiP immunoglobulin heavy chain binding protein - CFTR Cystic fibrosis transmembrane conductance regulator - CLQTS Congenital long QT syndrome - CMT Charcot-Marie-Tooth syndrome - CNX Calnexin - COPI Coat protein complex I - COPII Coat protein complex II - CPX 8-Cyclopentyl-1,2-dipropylxanthine - CRT Calreticulin - CSID Congenital sucrose-isomaltase deficiency - Cx Connexin - cGMP Cyclic 3:5 guanosine monophosphate - ECL Extracellular loop - EndoH Endoglycosidase H - ER Endoplasmic reticulum - ERAD ER-associated degradation - ERGIC ER/Golgi intermediate compartment - ERp ER protein - ET_BR Human endothelin B receptor - FH Familial hypercholesterolemia - GABA Gamma amino butyric acid - GFP Green fluorescent protein - GH Growth hormone - GHIS Growth hormone insensitivity syndrome - GLCase Glucosidase - GlcNac N-acetylglucosamine - GPCR G protein-coupled receptor - GPI Glycosylphosphatidylinositol - G protein GTP-binding protein - GRP Glucose-regulated protein - HA Hemagglutinin - Hdj-2 Human DnaJ-2 protein - HFE Human hemochromatosis protein - HH Hereditary hemochromatosis - HEK 293 cells Human embryonic kidney 293 cells - HERG Human ether-a-go-go-related protein - Hsc70 Heat shock cognate 70 protein - ICL Intracellular loop - IGF-I Insulin-like growth factor-1 - I_Kr Rapidly activating delayed rectifier potassium current - I_Ks Slowly activating delayed rectifier potassium current - JAK Janus kinase - LDL Low-density lipoprotein - LH Luteinizing hormone/choriogonadotropin - LS Laron syndrome - MATP Membrane associated transporter protein - MDCK cells Madin-Darby canine kidney epithelial cells - MHC Major histocompatibility complex - MiRP1 minK-related peptide 1 - NDI Congenital nephrogenic diabetes insipidus - NMDA N-methyl-d-aspartate - OCA Oculocutaneous albinism - PDI Protein disulfide isomerase - Pgp P-glycoprotein - PKA Protein kinase A - PLP Proteolipid protein - PMP22 Peripheral myelin protein 22 - RP Primary retinitis pigmentosa - SI Sucrase-isomaltase - SNARE Ethylmaleimide-sensitive factor attachment protein - SRP Signal recognition particle - TCR T-cell antigen receptor - TM Transmembrane domain - TRAM Translocating chain-associated membrane protein - Tyr Tyrosinase - Tyrp1 Tyrosinase-related protein-1 - UGGT UDP-glucose:glycoprotein glucosyltransferase - VIP Vesicular-integral membrane protein - V₂R Vasopressin V₂ receptor - VSV Vesicular stomatitis virus     

Inhibition of Mg2+ current by single-gene mutation in Paramecium

Eccentric is a newly-isolated mutant of Paramecium tetraurelia that fails to swim backwards in response to Mg²⁺. In the wild type, this backward swimming results from Mg²⁺ influx via a Mg²⁺-specific ion conductance (I _Mg. Voltage-clamp analysis confirmed that, as suspected, step changes in membrane potential over a physiological range fail to elicit I _Mg from eccentric. Further electrophysiological investigation revealed a number of additional ion-current defects in eccentric: (i) The Ca²⁺ current activated upon depolarization inactivates more slowly in eccentric than in the wild type, and it requires longer to recover from this inactivation. (ii) The Ca²⁺-dependent Na⁺ current deactivates significantly faster in the mutant, (iii) The two K⁺ currents observed upon hyperpolarization are reduced by >60% in eccentric. It is difficult to envision how these varied pleiotropic effects could result from loss of a single ion current. Rather, they suggest that the eccentric mutation affects a global regulatory system. Two plausible hypotheses are discussed.We are grateful to Dr. Yoshiro Saimi for his comments and suggestions on this work, and for the support of the Lucille P. Markey Charitable trust and the National Institutes of Health (GM22714 and GM38646).     

Identifying populations useful for improving parents of a single cross based on net transfer of alleles

Summary Theory and methods for identifying populations (P _y ) with the highest frequency of favorable dominant alleles not present in an elite single cross (I ₁× I ₂) have been developed recently. During selection, new favorable alleles can be transferred from P _y to either I ₁ or I ₂ only at the risk of losing favorable alleles already present in the single cross. A net improvement (NI) statistic, which estimates the relative number of favorable alleles that can be gained from P _y minus the relative number of favorable alleles that can be lost from I ₁ or I ₂, is presented. NI is calculated as maximum [(I ₁×P _y –I ₁×I ₂)/2,(I ₂×P _y –I ₁×I ₂)/2]. Because I ₁ × I ₂ is constant in an experiment, the method reduces to choosing P _y populations with the best mean performance in combination with either I ₁ or I ₂. For a set of maize (Zea mays L.) grain yield data, NI was highly correlated to three other statistics proposed for choosing populations, namely: (1) minimally biased estimate (l ) of the relative number of favorable dominant alleles present in P _y but not in I ₁ and I ₂; (2) minimum upper bound on l ; and (3) predicted performance of the three-way cross [P _y (I ₁× I ₂)]. While l estimates potential improvement likely to be achieved only through long-term recurrent selection, NI is probably a better predictor of short-term improvement in single-cross performance.A contribution from Lifaco Genetics, a subsidiary of Groupe Limagrain     

Pump and K+ inward rectifiers in the plasmalemma of wheat root protoplasts

An electrogenic pump, a slowly activating K⁺ inward rectifier and an intermittent, spiky, K⁺ inward rectifier, have been identified in the plasmalemma of whole protoplasts from root cortical cells of wheat (Triticum) by the use of patch clamping techniques. Even with high external concentrations of K⁺ of 100 m m, the pump can maintain the membrane potential difference (PD) down to –180 mV, more negative than the electrochemical equilibrium potentials of the various ions in the system. The slowly activating K⁺ inward rectifier, apparent in about 23% of protoplasts, allows inward current flow when the membrane PD becomes more negative than the electrochemical equilibrium potential for K⁺ by about 50 mV. The current usually consists of two exponentially rising components, the time constant of one about 10 times greater than the other. The longer time constant is voltage dependent, while the smaller time constant shows little voltage dependence. The rectifier deactivates, on return of the PD to less negative levels, with a single exponential time course, whose time constant is strongly voltage dependent. The spiky K⁺ inward rectifier, present in about 68% of protoplasts, allows intermittent current, of considerable magnitude, through the plasmalemma at PDs usually more negative than about –140 mV. Patch clamp experiments on detached outside-out patches show that a possibly multi-state K⁺ channel, with maximum conductance greater than 400 pS, may constitute this rectifier. The paper also considers the role of the pump and the K⁺ inward rectifiers in physiological processes in the cell.We thank Don Mackenzie and Kay Morris for their valuable technical assistance, particularly in the preparation of protoplasts. The project is funded by the Australian Research Council.