Choline analogs as potential tools in developing selective animal models of central cholinergic hypofunction

A chronic deficiency in central cholinergic function has been implicated in a number of neuropsychiatric disease states. This deficiency most probably exists at the presynaptic nerve terminal in the brain, where acetylcholine metabolism is known to occur. To date there are no reports on animals that could simulate the neurochemical conditions which appear to cause these diseases in humans, as a result of a direct manipulation of the central cholinergic system. Several compounds related to choline have however been studied, which might be useful agents for developing such an animal model, through their specific action on the high-affinity choline transport system in the brain. This minireview presents an overview of results obtained with these potentially neurotoxic choline analogs, and provides a critical analysis of current knowledge in this area of investigation.     

TRP channels as target sites for insecticides: physiology,pharmacology and toxicology

Transient receptor potential (TRP) channels are attracting attention from various research areas including physiology, pharmacology and toxicology. Our group has focused on TRPA1 channels and revealed their expression pattern, ion channel kinetics and pharmacological characteristics. From Integrated Pest Management point of view, TRP channels could be a possible new target site of pest control agents as well as the primary or secondary target site for known insecticides. We have examined expressed TRPA1 channels using physiological and pharmacological methods to clarify the function of these channels. Here, we show that the TRPA1 is activated by the insecticide and natural toxin allyl isothiocyanate which is known as insecticide.     

Chloride channels of intracellular membranes

Proteins implicated as intracellular chloride channels include the intracellular ClC proteins, the bestrophins, the cystic fibrosis transmembrane conductance regulator, the CLICs, and the recently described Golgi pH regulator. This paper examines current hypotheses regarding roles of intracellular chloride channels and reviews the evidence supporting a role in intracellular chloride transport for each of these proteins.     

Chloride channels in toad skin

A study of the voltage and time dependence of a transepithelial Cl- current in toad skin (Bufo bufo) by the voltage-clamp method leads to the conclusion that potential has a dual role for Cl- transport. One is to control the permeability of an apical membrane Cl-pathway, the other is to drive Cl- ions through this pathway. Experimental analysis of the gating kinetics is rendered difficult owing to a contamination of the gated currents by cellular ion redistribution currents. To obtain insight into the effects of accumulation-depletion currents on voltage clamp currents of epithelial membranes, a mathematical model of the epithelium has been developed for computer analysis. By assuming that the apical membrane Cl- permeability is governed by a single gating variable (Hodgkin-Huxley kinetics), the model predicts fairly well steady-state current-voltage curves, the time course of current activations from a closed state, and the dependence of unidirectional fluxes on potential. Other predictions of the model do not agree with experimental findings, and it is suggested that the gating kinetics are governed by rate coefficients that also depend on the holding potential. Evidence is presented that Cl- transport through open channels does not obey the constant-field equation.     

Chloride channels in the nuclear membrane

Summary Chloride-selective ion channels were measured from isolated rat liver nuclei. Single ion channel currents were recorded in both nuclear-attached and in excised patches in the insideout configuration of the patch-clamp technique. Two types of chloride conductance were defined, a large conductance (150 pS;i _Cl.N ) channel with complex kinetics and multiple substates, and a second smaller conductance (58 pS;I _Cl.n ) channel sensitive to block by ATP. The channels were inhibited by pharmacological agents known to block chloride channels and were insensitive to internal and external changes in calcium and magnesium. Presumably the channels reside in the external membrane of the nuclear double membrane and may mediate charge balance in the release and uptake of calcium from the perinuclear space.     

Chloride channels in toad skeletal muscle fibers

Chloride currents were measured in short lumbricalis fibers of toads (Bufo arenarum) with voltage and patch clamp techniques. For the availability of chloride currents we applied a double-pulse technique in voltage-clamped fibers. When the test pulse was preceded by a positive prepulse, the initial current was larger than with a negative prepulse and exhibited a different rate of decline to its steady-state value. At the single-channel level we found that in most of the experiments with symmetrical 110 mM NaCl solutions, two levels of conductance, 20 (small channel) and 360 pS (maxi channel), occurred with the highest probabilities. The openings of the maxi channels were more frequent at potentials close to 0 mV, whereas for the small channels the openings were at negative potentials. In contrast with the results with the macroscopic currents, a change of 2 orders of magnitude in the pH, from 7.3 to 5, had only minor effects on the channels' conductance. As with some other anion channels, the selectivity of the channels described here is low, the p(Cl)/p(Na) ratio being 1.9 and 3.7 for the small and maxi Cl(-) channels, respectively. The behavior of these Cl(-) channels with a relative high Na(+) permeability could contribute to the relatively low resting membrane potential of the lumbricalis fibers measured in the standard 110 mM NaCl solution.     

Chloride channels: An emerging molecular picture

Chloride channels are probably found in every cell, from bacteria to mammals. Their physiological tasks range from cell volume regulation to stabilization of the membrane potential, signal transduction, transepithelial transport and acidification of intracellular organelles. These different functions require the presence of many distinct chloride channels, which are differentially expressed and regulated by various stimuli. These include various intracellular messengers (like calcium and cyclic AMP), pH, extracellular ligands and transmembrane voltage. Three major structural classes of chloride channels are known to date, but there may be others not yet identified. After an overview of the general functions of chloride channels, this review will focus on these cloned chloride channels: the CLC chloride channel family, which includes voltage-gated chloride channels, and the cystic fibrosis transmembrane regulator (CFTR), which performs other functions in addition to being a chloride channel. Finally, a short section deals with GABA and glycine receptors. Diseases resulting from chloride channel defects will be specially emphasized, together with the somewhat limited information about how these proteins work at the molecular level.     

Conotoxins as selective inhibitors of neuronal ion channels, receptors and transporters

Cone snails have evolved a vast array of peptide toxins for prey capture and defence. These peptides are directed against a wide variety of pharmacological targets, making them an invaluable source of ligands for studying the properties of these targets in normal and diseased states. A number of these peptides have shown efficacy in vivo, including inhibitors of calcium channels, the norepinephrine transporter, nicotinic acetylcholine receptors, NMDA receptors and neurotensin receptors, with several having undergone pre-clinical or clinical development for the treatment of pain.     

Glycopeptides as versatile tools for glycobiology

This review describes the recent advances in the field of glycopeptide and small glycoprotein synthesis. The strategies covered include chemical and chemoenzymatic synthesis, native chemical ligation (NCL), and expressed chemical ligation. The importance of glycopeptide synthesis is exemplified by giving the reader an overview of how versatile and important these well-defined glycopeptides are as tools in glycobiology.     

Aptamers as tools for target validation

Synthetic nucleic acid ligands, called aptamers, bind to protein targets with high specificity and affinity. They are very potent inhibitors of protein function and their application can greatly enhance the process of target validation and drug development. An important benefit of this technology is the recent development of rapidly identifying these sophisticated ligands for almost any target molecule in multi-parallel, automated workstations. The aptamer technology is thus well-suited to addressing the growing demand for high-throughput analysis and functional validation of potential drug targets. Numerous examples have shown the potency of aptamers in inhibiting the function of proteins in cell culture and in vivo models. The technology is complementary to genetic knockout or siRNA approaches as it provides highly valuable information at the proteomic level. In addition, the aptamer technology has recently been extended to developing aptamer drugs and identifying functionally equivalent small molecule leads.     

Electrophysiological evidence for 4-isobutyl-3-isopropylbicyclophosphorothionate as a selective blocker of insect GABA-gated chloride channels

Invertebrate γ-aminobutyric acid (GABA)-gated chloride channels (GABACls) and glutamate-gated chloride channels (GluCls), which function as inhibitory neurotransmitter receptors, are important targets of insecticides and antiparasitic agents. The antagonism of GABACls and GluCls by 4-isobutyl-3-isopropylbicyclophosphorothionate (PS-14) was examined in cultured cockroach and rat neurons using a whole-cell patch-clamp method. The results indicated that PS-14 selectively blocks cockroach GABACls relative to cockroach GluCls and rat GABACls. PS-14 represents a useful probe for the study of insect GABA receptors.     

Chloride channels and cystic fibrosis of the pancreas

Cystic fibrosis (CF) affects approximately 1 in 2000 people making it one of the commonest fatal, inherited diseases in the Caucasian population. CF is caused by mutations in a cyclic AMP-regulated chloride channel known as CFTR, which is found on the apical plasma membrane of many exocrine epithelial cells. In the CF pancreas, dysfunction of the CFTR reduces the secretory activity of the tubular duct cells, which leads to blockage of the ductal system and eventual fibrosis of the whole gland. One possible approach to treating the disease would be to activate an alternative chloride channel capable of bypassing defective CFTR. A strong candidate for this is a chloride channel regulated by intracellular calcium, which has recently been shown to protect the pancreas in transgenic CF mice. Pharmacological intervention directed at activating this calcium-activated Cl^– conductance might provide a possible therapy to treat the problems of pancreatic dysfunction in CF.     

Photochemical tools for remote control of ion channels in excitable cells

Various strategies have been developed recently for imparting light sensitivity onto normally insensitive cells. These include expression of natural photosensitive proteins, photolysis of caged agonists of native cell surface receptors and photoswitching of isomerizable tethered ligands that act on specially engineered ion channels and receptor targets. The development of chemical tools for optically stimulating or inhibiting signaling proteins has particular relevance for the nervous system, where precise, noninvasive control is an experimental and medical necessity.     

Chloride channels, Golgi pH and cystic fibrosis

Cystic fibrosis (CF) is associated with a defect in a cAMP-activated chloride channel in secretory epithelia, which leads to decreased fluid secretion. In addition, many mucus glycoproteins show decreased sialylation but increased sulphation. We have recently shown that the pH of intracellular organelles is elevated in CF cells, due to defective chloride conductance in the vesicle membranes. We postulate that this may affect the activity of sialyl-, fucosyl- and sulphotransferases, and thus explain the abnormal glycosylation. Defects in sialylation of glycolipids might also generate receptors for Pseudomonas, which infects the respiratory tract of CF patients.