The Human Red Cell Voltage-regulated Cation Channel. The Interplay with the Chloride Conductance,the Ca<Superscript>2+</Superscript>-activated K<Superscript>+</Superscript> Channel and the Ca<Superscript>2+</Superscript> Pump

Electrocytes from the electric organ of Electrophorus electricus exhibited sodium action potentials that have been proposed to be repolarized by leak currents and not by outward voltage-gated potassium currents. However, patch-clamp recordings have suggested that electrocytes may contain a very low density of voltage-gated K⁺ channels. We report here the cloning of a K⁺ channel from an eel electric organ cDNA library, which, when expressed in mammalian tissue culture cells, displayed delayed-rectifier K⁺ channel characteristics. The amino-acid sequence of the eel K⁺ channel had the highest identity to Kv1.1 potassium channels. However, different important functional regions of eel Kv1.1 had higher amino-acid identity to other Kv1 members, for example, the eel Kv1.1 S4-S5 region was identical to Kv1.5 and Kv1.6. Northern blot analysis indicated that eel Kv1.1 mRNA was expressed at appreciable levels in the electric organ but it was not detected in eel brain, muscle, or cardiac tissue. Because electrocytes do not express robust outward voltage-gated potassium currents we speculate that eel Kv1.1 channels are chronically inhibited in the electric organ and may be functionally recruited by an unknown mechanism.     

Morphological variation in the electric organ of the little skate (Leucoraja erinacea) and its possible role in communication during courtship

Skates discharge an electrical current too weak to be used for predation or defense, and too infrequent and irregular to be used for electrolocation. Additionally, skates possess a specialized sensory system that can detect electrical stimuli at the same strength at which they discharge their organs. These two factors are suggestive of a communicative role for the electric organ in skates, a role that has been demonstrated in similarly weakly electric teleosts (e.g., mormyrids and gymnotiforms). There is evidence that the sexual and ontogenetic variations in the electric organ discharge (EOD) in these other weakly electric fishes are linked to morphological variations in electric organs and the electrogenerating cells of the organs, the electrocytes. Little work has been done to examine possible sexual and ontogenetic variations in skate EODs or variations in the electrocytes responsible for those discharges. Electric organs and electrocyte morphology of male and female, and mature and immature little skates, Leucoraja erinacea, are characterized here. Female electric organs were bigger than male electric organs. This is suggestive of a sexually dimorphic EOD waveform or amplitude, which might be used as a sex-specific identification signal during courtship. The shapes of electrocytes that make up the organ were found to be significantly different between mature and immature individuals and, in some cases, posterior membrane surface area of the electrocytes increased at the onset of maturity due to the formation of membrane surface invaginations and papillae. This is evidence that the EOD of skates may differ in its waveform or amplitude or frequency between mature and immature skates, and act as a signal for readiness to mate. This study supports a communicative role during courtship for the weak electric organs of little skates, but studies that characterize skate EOD dimorphisms are needed to corroborate this speculation before conclusions can be drawn about the role the electric organ plays in communication during courtship.     

Purification of acetylcholine receptors from the muscle of Electrophorus electricus

Muscle from the electric eel Electrophorus electricus contains acetylcholine receptors at 50 times the concentration of normal mammalian muscle and fully one-tenth the concentration of receptors in its electric organ tissue. Receptor is organized much more diffusely over the surface of Electrophorus muscle cells than is the case in normally innervated mammalian skeletal muscle. Receptor was purified from Electrophorus muscle by affinity chromatography on cobra toxin-agarose and found to contain subunits which correspond immunochemically to the alpha, beta, gamma, and delta subunits of receptor from electric organ tissue of Torpedo californica. Receptor purified from Electrophorus muscle appears virtually identical with receptor purified from Electrophorus electric organ tissue.     

Acetylcholinesterases.

Acetylcholinesterase (E.C.3.1.1.7) is a widely distributed enzyme, particularly in excitable tissues such as muscle, nerve, and electric organs but also found in erythrocytes and snake venoms. The function of the enzyme at postsynaptic sites in excitable tissues is considered to be termination of synaptic transmission via the hydrolytic inactivation of acetylcholine. The functional role of the enzyme at extrajunctional sites of excitable tissues, in nerve endings and in the erythrocyte has not been established. In the past five or six years substantial progress has been made in terms of our understanding of acetylcholinesterases (AChE) particularly with regard to their molecular characterization, their subunit structure and their immunological properties. These advances have been due in part to successful purification of enzymes from various tissues by the application of affinity chromatography techniques. In addition, some progress has been made regarding physiological aspects of the development and regulation of AChE in excitable tissues. This review will focus on these aspects of AChE by reference to work utilizing the enzyme from the following sources: electric tissue of the eel, $\text{Electrophorus electricus}$, or electric fish, $\text{Torpedo}$, species; mammalian and avian skeletal muscle; neural tissues, particularly mammalian brain; and the mammalian erythrocyte. For more comprehensive reviews of AChE readers are referred to the following references (1, 2).     

The case for sequencing the genome of the electric eel Electrophorus electricus

A substantial international community of biologists have proposed the electric eel Electrophorus electricus (Teleostei: Gymnotiformes) as an important candidate for genome sequencing. In this study, the authors outline the unique advantages that a genome sequencing project of this species would offer society for developing new ways of producing and storing electricity. Over tens of millions of years, electric fish have evolved an exceptional capacity to generate a weak (millivolt) electric field in the water near their body from specialized muscle‐derived electric organs, and simultaneously, to sense changes in this field that occur when it interacts with foreign objects. This electric sense is used both to navigate and orient in murky tropical waters and to communicate with other members of the same species. Some species, such as the electric eel, have also evolved a strong voltage organ as a means of stunning prey. This organism, and a handful of others scattered worldwide, convert chemical energy from food directly into workable electric energy and could provide important clues on how this process could be manipulated for human benefit. Electric fishes have been used as models for the study of basic biological and behavioural mechanisms for more than 40 years by a large and growing research community. These fishes represent a rich source of experimental material in the areas of excitable membranes, neurochemistry, cellular differentiation, spinal cord regeneration, animal behaviour and the evolution of novel sensory and motor organs. Studies on electric fishes also have tremendous potential as a model for the study of developmental or disease processes, such as muscular dystrophy and spinal cord regeneration. Access to the genome sequence of E. electricus will provide society with a whole new set of molecular tools for understanding the biophysical control of electromotive molecules, excitable membranes and the cellular production of weak and strong electric fields. Understanding the regulation of ion channel genes will be central for efforts to induce the differentiation of electrogenic cells in other tissues and organisms and to control the intrinsic electric behaviours of these cells. Dense genomic sequence information of E. electricus will also help elucidate the genetic basis for the origin and adaptive diversification of a novel vertebrate tissue. The value of existing resources within the community of electric fish research will be greatly enhanced across a broad range of physiological and environmental sciences by having a draft genome sequence of the electric eel.     

Determinants of time-dependent membrane conductance. The nonrole of classical ion-membrane molecule interactions

We have examined the steady-state and time-dependent electrical properties of a model membrane system. The model assumes that the directed velocity and energy of ions moving through the membrane are determined by the applied electric field, ionic diffusion forces, and central elastic collisions between ions and membrane molecules. A simple analysis of the steady-state electrical properties of the model yields results identical with ones obtained previously using a more complex analysis procedure. The time-dependent conductance changes of the model in response to a step change in electric field strength when there is solution symmetry display three qualitative patterns dependent on the nature of the ion-membrane molecule interaction. One of the patterns of conductance change is quite similar to that observed in the sodium conductance system of a number of excitable tissues: an initial conductance rise to a maximum (activation) followed by a decay to a final steady-state value (inactivation). However, the correspondence between the time-dependent model behavior and known experimental behavior of excitable systems is only qualitative. We conclude that the classical ion-membrane molecule interactions we consider are not involved in determining time-dependent conductance processes in the excitable systems for which comparison is possible.     

Pre-steady-state charge translocation in NaK-ATPase from eel electric organ

Time-resolved measurements of charge translocation and phosphorylation kinetics during the pre-steady state of the NaK-ATPase reaction cycle are presented. NaK-ATPase-containing microsomes prepared from the electric organ of Electrophorus electricus were adsorbed to planar lipid bilayers for investigation of charge translocation, while rapid acid quenching was used to study the concomitant enzymatic partial reactions involved in phosphoenzyme formation. To facilitate comparison of these data, conditions were standardized with respect to pH (6.2), ionic composition, and temperature (24 degrees C). The different phases of the current generated by the enzyme are analyzed under various conditions and compared with the kinetics of phosphoenzyme formation. The slowest time constant (tau 3(-1) approximately 8 s-1) is related to the influence of the capacitive coupling of the adsorbed membrane fragments on the electrical signal. The relaxation time associated with the decaying phase of the electrical signal (tau 2(-1) = 10-70 s-1) depends on ATP and caged ATP concentration. It is assigned to the ATP and caged ATP binding and exchange reaction. A kinetic model is proposed that explains the behavior of the relaxation time at different ATP and caged ATP concentrations. Control measurements with the rapid mixing technique confirm this assignment. The rising phase of the electrical signal was analyzed with a kinetic model based on a condensed Albers-Post cycle. Together with kinetic information obtained from rapid mixing studies, the analysis suggests that electroneutral ATP release, ATP and caged ATP binding, and exchange and phosphorylation are followed by a fast electrogenic E1P-->E2P transition. At 24 degrees C and pH 6.2, the rate constant for the E1P-- >E2P transition in NaK-ATPase from eel electric organ is > or = 1,000 s- 1.     

Identification and distribution of chondroitin sulfate in the three electric organs of the electric eel, Electrophorus electricus (L.)

The electrogenic tissue of the electric eel Electrophorus electricus (L.) is distributed in three well-defined electric organs, the Main electric organ, Sach's organ and Hunter's organ. Sulfated glycosaminoglycan (GAG) composition was characterized in the three electric organs of the electric eel. Sulfated GAGs were analyzed in the electric organs using metachromatic staining, biochemical analysis including electrophoresis before and after specific enzymatic or chemical degradations, and immunostaining with an antibody against chondroitin sulfate (CS). Our results showed in the three electric organs that CS was the main sulfated GAG species detected, accompanied by small and diminutive amounts of CS/dermatan sulfate hybrid chains and heparan sulfate (HS), respectively. However, HS was not detected in the Sach's organ. CS was predominantly detected in the innervated membrane face of the electroplaques in the three electric organs. Our findings extend previous observations on the GAG composition in the electric organs of E. electricus and provide new information regarding the tissue distribution and location of CS.     

Involvement of ion channels and active transport in osmoregulation and signaling of higher plant cells

The transport of inorganic and organic ions across the plasma membrane and organelle membranes of higher plants by ion channels, electrogenic pumps and co-transporters is essential to vital processes such as osmoregulation, growth, development, signal transduction and the storage of solutes. Recent studies have led to the identification of specialized transport proteins in the plasma membrane and vacuolar membrane of higher plant cells. Here we have integrated the functional aspects of these membrane proteins into a model which proposes a novel basis for ion transport processes involved in the regulation of gas exchange in leaves.     

Scanning electron microscopy of the electric organs of Electrophorus electricus L

Summary The surfaces of the organs of Sachs and Hunter of Electrophorus electricus L. were examined by scanning electron microscopy. Special attention was directed to morphological details of the electrocyte to provide a better understanding of its anterior and posterior faces. Some aspects of the microanatomy of these organs, which differ markedly from those of the main electric organ, provide new information on the structure as revealed previously by light and transmission electron microscopy. The relief, mainly expressed by papillae, is related to the actual membrane area, which is important for calculations of specific resistance and conductance. Information is also presented on the general organization of the tissue, in particular the distribution of the connective elements and external configuration of synaptic terminals. Shrinkage in preparation of tissue was evaluated and correction made whenever necessary. Correction factors for actual membrane area were calculated for anterior and posterior faces of electrocytes from both organs.     

Eel electric organ: hyperexpressing calmodulin system.

The electroplax of the electric eel Electrophorus electricus is the most abundant source of the calcium-binding protein calmodulin. The electroplax has 250 times the amount of calmodulin and its mRNA than eel skeletal muscle. Our data suggest that there is no major difference in gene copies, the degree of methylation, or genome rearrangement of the calmodulin gene in DNAs from eel electroplax and muscle. Differences in the calmodulin-binding proteins in electroplax and muscle suggest a differential role for the functional expression of calmodulin in cellular regulation.     

A hormone-sensitive communication system in an electric fish

The electric communication system includes both special muscle-derived cells or electrocytes that produce species-typical electric signals, or electric organ discharges (EODs), and specialized sensory receptors, or electroreceptors, that encode the electric fields set up by EODs. Steroid hormones can influence the characteristic properties of both EODs and electroreceptors. Steroids appear to directly effect the anatomy and physiology of the electrocytes that generate an EOD. In contrast, the steroid effect on electroreceptors may be predominantly via an indirect mechanism whereby changes in the spectral characteristics of the EOD appear to induce changes in the spectral sensitivity of electroreceptors. Continued studies of electrosensory and electromotor systems will offer insights into the cellular bases for the development and evolution of steroid-sensitive pathways in the vertebrate nervous system.     

Role of protein phosphorylation in neuronal signal transduction

Protein phosphorylation is involved in the regulation of a wide variety of physiological processes in the nervous system. Studies in which purified protein kinases or kinase inhibitors have been microinjected into defined cells while a specific response is monitored have demonstrated that protein phosphorylation is both necessary and sufficient to mediate responses of excitable cells to extracellular signals. The precise molecular mechanisms involved in neuronal signal transduction processes can be further elucidated by identification and characterization of the substrate proteins for the various protein kinases. The roles of three such substrate proteins in signal transduction are described in this article: 1) synapsin I, whose phosphorylation increases neurotransmitter release and thereby modulates synaptic transmission presynaptically; 2) the nicotinic acetylcholine receptor, whose phosphorylation increases its rate of desensitization and thereby modulates synaptic transmission postsynaptically; and 3) DARPP-32, whose phosphorylation converts it to a protein phosphatase inhibitor and which thereby may mediate interactions between dopamine and other neurotransmitter systems. The characterization of the large number of additional phosphoproteins that have been found in the nervous system should elucidate many additional molecular mechanisms involved in signal transduction in neurons.     

Lipid rafts and the control of neurotrophic factor signaling in the nervous system: variations on a theme

Lipid rafts are specialized, liquid-ordered subdomains of the plasma membrane. Through their ability to promote specific compartmentalization of lipids and membrane proteins, lipid rafts have emerged as membrane platforms specialized for signal transduction. In recent years, signaling by neurotrophic factors and their receptors has been shown to depend upon the integrity and function of lipid rafts and associated components. It has also been shown that these microdomains play critical roles in selective axon-dendritic sorting and the proteolytic processing of several neurotrophic ligands and receptors in neuronal cells. The available evidence supports an important role for lipid rafts in the initiation, propagation and maintenance of signal transduction events triggered by different neurotrophic factors and their receptors in the nervous system.     

CORRELATION BETWEEN ELECTRICAL ACTIVITY AND SPLITTING OF PHOSPHOLIPIDS BY SNAKE VENOM IN THE SINGLE ELECTROPLAX

Abstract— Cottonmouth moccasin snake venom (SV) was applied to the innervated membrane of the isolated single cell of the Sachs electric organ (electroplax) of the electric eel, Electrophorus electricus. Concentrations as low as 0.05 μg/ml irreversibly antagonized depolarization by carbamylcholine, whereas concentrations of 0.1 mg/ml or higher were required to directly and irreversibly depolarize and block electrical excitation. The active component of the venom was stable to boiling at acid pH, destroyed by boiling at alkaline pH and nondialyzable and corresponded to those fractions containing maximum phospholipase A activity demonstrable when isolated by paper electrophoresis and Sephadex filtration. Phospholipase C and lysolecithin in concentrations of 1 mg/ml and 0.2 mg/ml, respectively, depolarized and blocked electrical excitation, whereas lower concentrations did not antagonize depolarization by carbamylcholine. Triton X-100 (0.01 mg/ml) antagonized carbamylcholine, whereas 10-fold higher concentrations directly blocked electrical excitation. Hyaluronidase had no effect on resting or action potential but decreased the depolarizing response to carbamylcholine. At minimal concentrations which blocked the depolarizing response to carbamylcholine, SV caused only slight splitting of phospholipids in single cells of the Sachs organ. A concentration (1 mg/ml) of SV which blocked electrical excitation caused 80–100 per cent splitting of lecithin, phosphatidylethanolamine and phosphatidylserine, the three principal phospholipids of the electric tissue. Similar percentages of splitting of the latter two phospholipids but only about one-third of the lecithin occurred at SV concentration of 0.1 mg/ml. These results indicate that electrical excitability in the eel electroplax can be maintained in the presence of extensive phospholipid splitting. Depolarization and block of electrical excitation by relatively high concentrations of SV may have resulted from splitting of phospholipids, especially lecithin, or may have reflected action of lysophosphatide detergents produced as a result of the action of phospholipase A upon membranal phospholipids.     

Lipid rafts as platforms for sphingosine 1-phosphate metabolism and signalling

Spontaneous segregation of cholesterol and sphingolipids as a liquid-ordered phase leads to their clustering in selected membrane areas, the lipid rafts. These specialized membrane domains enriched in gangliosides, sphingomyelin, cholesterol and selected proteins involved in signal transduction, organize and determine the function of multiprotein complexes involved in several aspects of signal transduction, thus regulating cell homeostasis. Sphingosine 1-phosphate, an important biologically active mediator, is involved in several signal transduction processes regulating a plethora of cell functions and, not only several of its downstream effectors tend to localize in lipid rafts, some of the enzymes involved in its pathway, of receptors involved in its signalling and its transporters have been often found in these membrane microdomains. Considering this, in this review we address what is currently known regarding the relationship between sphingosine 1-phosphate metabolism and signalling and plasma membrane lipid rafts.     

气孔功能的结构基础

近年来,国际上十分关注气孔运动的调控机理,在保卫细胞内外的信息传递和转导途径的研究方面取得重要进展。保卫细胞的特殊结构和气孔功能密切相关,对保卫细胞壁特性、质膜上的各种结合蛋白、质膜和液泡膜上的离子通道的研究,以及对细胞骨架和气孔运动的关系的探索为阐明气孔运动的机理提供了更多的依据。     

BIOMEMBRANE EXCITABILITY STUDIED WITHIN A WIDE-BAND FREQUENCY OF AN INTERACTING EXOGENOUS ELECTRIC FIELD

There does exist increasing experimental and theoretical evidence that supports the existence of a coupling between exogenous electromagnetic fields and ion channels located within the membrane of excitable cells. One of the most tantalizing consequences of such interactions points to a resonant-like behavior of this class of electrical non-linear systems leading to an optimized information transfer along excitable membranes. Herein, we present novel evidence showing that action potentials may occur in biomembranes within even the subthreshold excitation range, provided that concomitantly with the depolarizing stimulus, an exogenous low-amplitude oscillatory electric field of proper frequency (centered around 10 kHz) interacts with the biomembrane. As we present it, this phenomenon may be explained if one takes into consideration the resonant-like electrical properties of the linearized, small-signal impedance of the simplified, equivalent electrical representation of the studied biomembrane.     

Lateral organization of biological membranes

The lateral organization of biological membranes is of great importance in many biological processes, both for the formation of specific structures such as super-complexes and for function as observed in signal transduction systems. Over the last years, AFM studies, particularly of bacterial photosynthetic membranes, have revealed that certain proteins are able to segregate into functional domains with a specific organization. Furthermore, the extended non-random nature of the organization has been suggested to be important for the energy and redox transport properties of these specialized membranes. In the work reported here, using a coarse-grained Monte Carlo approach, we have investigated the nature of interaction potentials able to drive the formation and segregation of specialized membrane domains from the rest of the membrane and furthermore how the internal organization of the segregated domains can be modulated by the interaction potentials. These simulations show that long-range interactions are necessary to allow formation of membrane domains of realistic structure. We suggest that such possibly non-specific interactions may be of great importance in the lateral organization of biological membranes in general and in photosynthetic systems in particular. Finally, we consider the possible molecular origins of such interactions and suggest a fundamental role for lipid-mediated interactions in driving the formation of specialized photosynthetic membrane domains. We call these lipid-mediated interactions a ‘lipophobic effect.’     

气孔功能的结构基础

近年来,国际上十分关注气孔动动的调控机理,在保卫细胞内外的信息传递和转导途径的研究方面取得重要进展。保卫细胞的特殊结构和气孔功能密切相关,对保卫细胞壁特性、质膜上的各种结合蛋白、质膜和液泡膜上的离子通道的研究,以及对细胞骨架和气孔运动的关系的探索为阐明气孔运动的机理提供了更多的依据。