Unexpected species diversity in electric eels with a description of the strongest living bioelectricity generator.

Is there only one electric eel species? For two and a half centuries since its description by Linnaeus, Electrophorus electricus has captivated humankind by its capacity to generate strong electric discharges. Despite the importance of Electrophorus in multiple fields of science, the possibility of additional species-level diversity in the genus, which could also reveal a hidden variety of substances and bioelectrogenic functions, has hitherto not been explored. Here, based on overwhelming patterns of genetic, morphological, and ecological data, we reject the hypothesis of a single species broadly distributed throughout Greater Amazonia. Our analyses readily identify three major lineages that diverged during the Miocene and Pliocene-two of which warrant recognition as new species. For one of the new species, we recorded a discharge of 860 V, well above 650 V previously cited for Electrophorus, making it the strongest living bioelectricity generator.

Nonhuman genetics. Genomic basis for the convergent evolution of electric organs.

Little is known about the genetic basis of convergent traits that originate repeatedly over broad taxonomic scales. The myogenic electric organ has evolved six times in fishes to produce electric fields used in communication, navigation, predation, or defense. We have examined the genomic basis of the convergent anatomical and physiological origins of these organs by assembling the genome of the electric eel (Electrophorus electricus) and sequencing electric organ and skeletal muscle transcriptomes from three lineages that have independently evolved electric organs. Our results indicate that, despite millions of years of evolution and large differences in the morphology of electric organ cells, independent lineages have leveraged similar transcription factors and developmental and cellular pathways in the evolution of electric organs.

The untold story of the caudal skeleton in the electric eel (ostariophysi: gymnotiformes: electrophorus).

Alternative hypotheses had been advanced as to the components forming the elongate fin coursing along the ventral margin of much of the body and tail from behind the abdominal region to the posterior margin of the tail in the Electric Eel, Electrophorus electricus. Although the original species description indicated that this fin was a composite of the caudal fin plus the elongate anal fin characteristic of other genera of the Gymnotiformes, subsequent researchers proposed that the posterior region of the fin was formed by the extension of the anal fin posteriorly to the tip of the tail, thereby forming a "false caudal fin." Examination of ontogenetic series of the genus reveal that Electrophorus possesses a true caudal fin formed of a terminal centrum, hypural plate and a low number of caudal-fin rays. The confluence of the two fins is proposed as an additional autapomorphy for the genus. Under all alternative proposed hypotheses of relationships within the order Gymnotiformes, the presence of a caudal fin in Electrophorus optimized as being independent of the occurence of the morphologically equivalent structure in the Apteronotidae. Possible functional advantages to the presence of a caudal fin in the genus are discussed.

Electrocyte (Na(+),K(+))ATPase inhibition induced by zinc is reverted by dithiothreitol.

The Mg(2+)-dependent (Na(+),K(+))ATPase maintains several cellular processes and is essential for cell excitability. In view of the importance of the enzyme activity, the interaction and binding affinities to substrates and metal ions have been studied. We determined the effect of Zinc ion (Zn(2+)) on the (Na(+),K(+))ATPase activity present in both conducting (non-innervated) and post-synaptic (innervated) membranes of electrocyte from Electrophorus electricus (L.). Zn(2+) is involved in many biological functions and is present in pre-synaptic nerve terminals. This metal, which has affinity for thiol groups, acted as a potent competitive inhibitor of (Na(+),K(+))ATPase of both membrane fractions, which were obtained by differential centrifugation of the E. electricus main electric organ homogenate. We tried to recover the enzyme activity using dithiothreitol, a reducing agent. Kinetic analysis showed that dithiothreitol acted as a non-essential non-competitive activator of (Na(+),K(+))ATPase from both membrane fractions and was able to revert the Zn(2+) inhibition at mM concentrations. In the presence of dithiothreitol, this metal behaved as a competitive inhibitor of (Na(+),K(+))ATPase in the non-innervated membrane fractions and presented a non-competitive inhibition of (Na(+),K(+))ATPase in innervated membrane fractions. This difference may be attributed to formation of a Zn-dithiothreitol complex, as well as the involvement of other binding sites for both agents. The consequences of the enzyme inhibition by Zn(2+) may be considered in regard to its neurotoxic effects.

The cytoskeleton of the electric tissue of Electrophorus electricus, L.

The electric eel Electrophorus electricus is a fresh water teleost showing an electrogenic tissue that produces electric discharges. This electrogenic tissue is distributed in three well-defined electric organs which may be found symmetrically along both sides of the eel. These electric organs develop from muscle and exhibit several biochemical properties and morphological features of the muscle sarcolema. This review examines the contribution of the cytoskeletal meshwork to the maintenance of the polarized organization of the electrocyte, the cell that contains all electric properties of each electric organ. The cytoskeletal filaments display an important role in the establishment and maintenance of the highly specialized membrane model system of the electrocyte. As a muscular tissue, these electric organs expresses actin and desmin. The studies that characterized these cytoskeletal proteins and their implications on the electrophysiology of the electric tissues are revisited.

Electrophorus electricus as a model system for the study of membrane excitability.

The stunning sensations produced by electric fish, particularly the electric eel, Electrophorus electricus, have fascinated scientists for centuries. Within the last 50 years, however, electric cells of Electrophorus have provided a unique model system that is both specialized and appropriate for the study of excitable cell membrane electrophysiology and biochemistry. Electric tissue generates whole animal electrical discharges by means of membrane potentials that are remarkably similar to those of mammalian neurons, myocytes and secretory cells. Electrocytes express ion channels, ATPases and signal transduction proteins common to these other excitable cells. Action potentials of electrocytes represent the specialized end function of electric tissue whereas other excitable cells use membrane potential changes to trigger sophisticated cellular processes, such as myofilament cross-bridging for contraction, or exocytosis for secretion. Because electric tissue lacks these functions and the proteins associated with them, it provides a highly specialized membrane model system. This review examines the basic mechanisms involved in the generation of the electrical discharge of the electric eel and the membrane proteins involved. The valuable contributions that electric tissue continues to make toward the understanding of excitable cell physiology and biochemistry are summarized, particularly those studies using electrocytes as a model system for the study of the regulation of membrane excitability by second messengers and signal transduction pathways.

[Morphological study of the heart of Electrophorus electricus]. / L'étude morphologique du coeur du "poraquê" (Electrophorus electricus).

Hearts of 7 Electrophorus electricus have been investigated on macroscopical and microscopical levels. Generally, the structure of the heart exhibits relative similarities with the other studied teleosts. The ventricular myocardium is mainly spongy and suggests that these structural features can offer an additional contraction power.

[The morphological study of the respiratory organ of Electrophorus electricus]. / Contribution à l'étude morphologique de l'organe respiratoire de l'Electrophorus electricus.

The respiratory organ of Electrophorus electricus is located in the oral cavity and is formed by papillar structures. The papilla consists basically of a cartilaginous central nucleus and is bounded by a connective layer. The results reveal structural adaptations for the respiration among fishes which have efficient respiratory circulation related with the venous blood.

A structural and dynamic molecular model for the sodium channel of Electrophorus electricus.

Chemical logic and single group rotation (SGR) theory are applied to the primary structure determined by Noda et al. [(1984) Nature 312, 121-127] to construct a molecular model of the sodium channel of Electrophorus electricus. Both structural and dynamic aspects of the channel are accounted for, including gating current, sensitivity to changes in membrane potential, channel opening, a binding site for sodium, selectivity for sodium over potassium, capacity for rapid sodium flow, sensitivity to batrachotoxin (or other toxins) and inactivation.

Immunochemical properties and cytochemical localization of the voltage-sensitive sodium channel from the electroplax of the eel (Electrophorus electricus).

Immunochemical methods have been used to investigate questions concerning the relatedness of sodium channels from different sources and their distribution in the eel electroplax. The reagents employed were two monoclonal antibodies, 5D10 (Moore, H. -P. H., L. C. Fritz, M. A. Raftery, and J. P. Brockes (1982) Proc. Natl. Acad. Sci. U.S.A. 79: 1673-1677) and 5F3, and a rabbit antiserum; all three were directed against determinants present on the 250,000-dalton component of the eel sodium channel. In quantitative adsorption assays, the three reagents were effectively adsorbed by eel electroplax membranes but not by brain membranes from rat, frog, or chick. The rabbit antiserum bound to immobilized membranes of rat brain at a level only approximately 0.1% of that seen with electroplax membranes. The reactivity of the three reagents with the eel electroplax was further investigated by indirect immunofluorescence on frozen sections. Whereas 5D10 showed no detectable reactivity, the rabbit antiserum and, especially, 5F3 stained the electrically excitable caudal face of the electrocytes but not the inexcitable rostral face. The reactivity of 5F3 was examined in greater detail and showed occasional abrupt discontinuities where the membrane was not stained. The presence of positive 5F3 immunoreactivity appeared to be correlated with extracellular filamentous material.

Observations on the innervated face of the electrocyte of the main organ of the electric eel (Electrophorus electricus L.).

The innervated face of electrocytes in the main electric organ of Electrophorus electricus L. was examined by light microscopy, both conventional and with Nomarski contrast, and by transmission and scanning electron microscopy. Acetylcholinesterase cytochemistry was used in the demonstration of the greater density of synapses over the caudal papillae. The various techniques contributed to a better understanding of the distribution and form of papillae and synapses at the posterior face of the electrocyte. Caudal papillae are longer and thinner than those at the rostral face, but it was not possible to recognize a different type sometimes referred to in the literature as small papillae. The contact of nerve endings with the electrocyte seems to be made predominantly on the terminal half of caudal papillae, however a smaller number occur elsewhere on the posterior face. Synaptic terminals frequently appear as round profiles, but may be also elongated, with or without bulges, usually occupying a depression, and separated from the post-synaptic membrane by a space of 60-100 nm, where an expansion may be found.

Ultrastructural localization of calcium-binding sites in the electrocyte of Electrophorus electricus (L.).

Calcium-binding sites were detected in the electrocyte of Electrophorus electricus (L.) using the Oschman & Wall technique, in which CaCl2 was added to the fixative and washing solutions. Deposits were seen scattered along the plasma membrane of the electrocyte, inside mitochondria, associated with the post-synaptic membrane and the membrane of synaptic vesicles.

Biochemical and cytochemical localization of ATPases on the membranes of the electrocyte of Electrophorus electricus.

The localization of (Na+-K+) ATPase in the intact electrocyte of the electric organ of Electrophorus electricus (L.) and its subcellular fractions was investigated by biochemical and cytochemical methods. The distribution of AChE activity in the subcellular fractions was also comparatively analysed with this enzyme serving as a marker of the innervated membranes of the electrocyte. After application of cytochemical method of Farquhar and Palade to glutaraldehyde-fixed tissue, reaction was observed only at the membranes of vesicles localized at the periphery of the electrocyte. Previously fixed electrocytes, incubated in Ernst's medium showed reaction only at the vesicles whereas in unfixed tissue reaction also appeared at other membranes (surface and invaginations) of the anterior and posterior faces. This reaction was significantly inhibited in the presence of ouabain or in the absence of K+. Inhibition of Na+-K+-ATPase by glutaraldehyde fixation was also confirmed by biochemical analysis.

An electron microscopic investigation of the surface coat of the electrocyte of electrophorus electricus.

The surface coat of the electrocyte of the main electric organ of Electrophorus electricus was studied using cytochemical methods (periodic acid-silver methanamine, periodic acid-chromic acid-silver methenamine, periodic acid-thiosemicarbazide-silver proteinate, Concanavalin A - horseradish peroxidase, ruthenium red, Alcian-blue lanthanum nitrate, colloidal iron hydroxide and cationized ferritin). The surface of the electrocyte presents perpendicularly oriented tubular invaginations of the cell membrane. The fibrous coat 50-100 nm thick, penetrates into the lumen of the invaginations. It is also observed in the synaptic clefts existent in the posterior face of the electrolyte. The coating of the surface membrane gives a positive reaction with all techniques used. Binding of colloidal iron hydroxide particles was observed only in the outer layer of the coat. With the Alcian-blue lanthanum nitrate technique , microtubules were observed in the cytoplasm of the electrocyte. The results indicate that the surface coat of the electrocyte contains mucopolysaccharides, glycoproteins, acid mucopolysaccharides and anionic sites detected at low (colloidal iron hydroxyde) and neutral (cationized ferritin) pH.