Guy P. Richardson

Presynaptic plasma membranes and synaptic vesicles of cholinergic nerve endings demonstrated by means of specific antisera

SummaryAntisera were raised to cholinergic presynaptic plasma membranes and synaptic vesicles isolated from the electric organ of Torpedo marmorata and tested by immunochemical and immunohistochemical methods. The antisera responded to many antigens not specific to nerve endings, but it was possible to eliminate these antibodies by means of simple absorption procedures with fractions containing the unwanted antigens. After absorption, staining of thin sections of electric organ by immunofluorescence was limited to the region of nerve endings in the tissue.The remaining antibodies responded in the case of the plasma membrane antisera predominantly to a 33,000 molecular-weight polypeptide and a chloroform/methanol-soluble antigen. In cross reactivity studies it was found that this antiserum not only stains cholinergic nerve endings in Torpedo but also those in mammalian tissue. The antigen responsible for the cross reactivity is restricted to the chloroform/methanol-soluble material.The vesicle antiserum labels cholinergic nerve endings in mammalian tissue as well; the relevant antigen in this case is different from the one described above and is likely to be a glycosaminoglycan. The antisera provide valuable markers for cholinergic nerve terminals. In addition, the vesicle antiserum may now be used to study axonal transport and the life cycle of this organelle in the cholinergic neurone.

Characterization and distribution of acetylcholine receptors and acetylcholinesterase during electric organ development in Torpedo marmorata

Abstract The changes that occur in the distribution and properties of the nicotinic acetylcholine receptor and acetylcholinesterase during the development of the electric organ of Torpedo marmorata have been investigated. At early stages of development, both proteins are distributed diffusely over the myotube surface and with differentiation of the myotubes into electrocytes, they become increasingly restricted to the ventral cell surface. This process occurs before axons contact the electrocytes. The concentrations of the acetylcholine receptor and acetylcholinesterase remain at rather low and stable levels during these developmental changes. The acetylcholine receptor concentration begins to increase rapidly as soon as electromotor axons begin to contact the electrocytes. No significant differences in the subunit composition, affinity for d -tubocurarine, isoelectric point or immunochemical properties of the embryonic acetylcholine receptors were detected when they were compared to the receptors of the adult electric organ. The onset of receptor accumulation occurs before the increase in the amount of 17 S acetylcholinesterase, suggesting that increases in acetylcholine receptor and in acetylcholinesterase are not regulated by the same mechanisms. The various molecular forms of acetylcholinesterase undergo characteristic changes during development. Sequential extraction of the esterase forms indicates that their interaction with cellular compartments changes during development. The solubility properties of the esterase forms suggest that most of the 17 S and 13 S acetylcholinesterase become strongly associated with cellular components via ionic interactions and that a hydrophobic 6 S form begins to accumulate at later embryonic stages when the number of mature presynaptic terminals is beginning to show its rapid phase of increase. The results show that events concerning the distribution and some properties of essential components of the electromotor synapse occur during early embryonic development before synaptogenesis, whereas the sequential accumulation of acetylcholine receptor and esterase begins after the axons start contacting the electrocytes. This suggests that the ingrowing nerves exert some regulative influence on the metabolic state of the electrocytes during development.

Organotypic culture of embryonic electromotor system tissues from Torpedo marmorata

Abstract An explant culture system has been used to study the electric organ and electric lobe tissues of Torpedo marmorata at different stages during the development of the electromotor system. The myotubes in tissue expiants, taken from the electric organ primordia of 33–38 mm body-length embryos prior to electrocyte differentiation, contract spontaneously on explantation and have electrogenic membranes. The myotubes subsequently lose these properties in vitro and can differentiate in the absence of neural tissue into immature electrocytes which have morphologically characteristic postsynaptic membranes. Isolated expiants of differentiated electric organ tissue from 60–100 mm body-length embryos can be maintained for 3 to 4 weeks in vitro but cellular outgrowth is minimal. In contrast, a rapid, dense outgrowth of cells and a subsequent regeneration of myotubes occurs when differentiated electric organ explants are co-cultured with electric lobe tissue from embryos of the same stage. Cellular outgrowth from differentiated electric-organ tissue expiants can be stimulated by spinal cord, medulla, cerebellum and heart tissues but a subsequent regeneration of myotubes has not been observed. Myotube regeneration in the presence of electric lobe tissue is maximal with tissue from 60–80 mm body-length embryos. The myotubes that regenerate from differentiated electric organ expiants have not been observed to differentiate into electrocytes. Neuritic outgrowth in vitro occurs with electric lobe tissue taken at two different embryonic stages. The first stage corresponds to a period when most of the neuroepithelial cells in the lobe anlagen are withdrawing from the mitotic cycle and projecting axons into the branchial arches. The second, later stage is when the electromotorneurones are normally generating axon collaterals that are invading the interelectrocyte space of electrocyte columns. Maximum neuritic outgrowth at this second, later stage is obtained with tissue from 60–80 mm body-length embryos. Although neuritic invasion of electrocyte column expiants can be obtained in electric organ—electric lobe co-cultures at this later stage, synapses similar to those observed during the early stages of synaptogenesis in the electric organs in vivo have not been observed in vitro .

Development of the electromotor system of Torpedo marmorata: Distribution of extracellular matrix and cytoskeletal components during acetylcholine receptor focalization

SummaryA combination of direct fluorescence and indirect immunofluorescence microscopy has been used to compare the distribution of the acetylcholine receptor with the distribution of major cytoskeletal and extracellular matrix components during electrocyte differentiation in the electric organs of Torpedo marmorata. Laminin, fibronectin and extracellular matrix proteoglycan are always more extensively distributed around the differentiating cell than the acetylcholine receptor-rich patch that forms on the ventral surface of the cell. The distribution of acetylcholinesterase within the ventral surface of the differentiating electrocyte closely resembles the distribution of the acetylcholine receptor. Areas of apparently high acetylcholine receptor density within the ventrally forming acetylcholine receptor-rich patch are always areas of apparently high extracellular matrix proteoglycan density but are not always areas of high laminin or fibronectin density. Desmin levels appear to increase at the onset of differentiation and desmin initially accumulates in the ventral pole of each myotube as it begins to form an electrocyte. During differentiation F-actin-positive filament bundles are observed that extend from the nuclei down to the ventrally forming acetylcholine receptorrich patch. Most filament bundles terminate in the acetylcholine receptor-rich region of the cell membrane. Electronmicroscopic autoradiography suggests that the filament bundles attach to the membrane at sites where small acetylcholine receptor clusters are found. The results of this study suggest that, out of the four extracellular matrix components studied, only the distribution of acetylcholinesterase (which may be both matrix- and membrane-bound at this stage) closely parallels that of the acetylcholine receptor, and that F-actin filament bundles terminate in a region of the cell that is becoming an area of high acetylcholine receptor density.

Torpedo electromotor system development: Biochemical differentiation of Torpedo electrocytes in vitro

The accumulation of 2 postsynaptic proteins--the acetylcholine receptor and acetylcholinesterase, total protein and lactate dehydrogenase levels, and the evolution of the multiple molecular forms of acetylcholinesterase (exhibiting apparent sedimentation coefficients of 17, 13, 11 and 6S) have been examined in aneural cultures of embryonic Torpedo electric organ explanted before, during or after electrocyte differentiation and the onset of synaptogenesis. During electrocyte differentiation in vitro, with explants taken before the 38 mm stage, the relative proportions of the 17, 13 and 11S forms change in vitro as in vivo but the 6S form remains abnormally dominant. In tissue explants taken from 38 to 47 mm stage embryos, the 4 major molecular forms of acetylcholinesterase differentiate in a manner identical to that observed in vivo. In explants taken after the onset of synaptogenesis (55-80 mm stages), the proportions of the acetylcholinesterase forms change as in vivo only during the first week in vitro whilst accumulation is occurring at the normal in vivo rate. The switch to the high acetylcholine receptor and acetylcholinesterase accumulation rate that occurs when synaptogenesis begins in vivo is not observed after any time lag in vitro with tissue explanted before the stage (55 mm) at which synaptogenesis begins. The effects on acetylcholinesterase and acetylcholine receptor accumulation of supplementing the medium with a neural tissue extract are described. The experiments were designed to elucidate the factors and mechanisms that regulate the differentiation and formation of chemical synapses using the electric organ of Torpedo marmorata as a model system. The results demonstrate that the complex changes occurring in the multiple molecular forms of acetylcholinesterase during electrocyte differentiation are not under direct neural control but that the switch to an increased acetylcholinesterase and acetylcholine receptor accumulation rate may be triggered by an external, possible neural factor.

Investigations into a bioelectric component of synaptogenesis

Synaptogenesis has been investigated in the electric organ of Torpedo marmorata with the objective of determining whether a bioelectric effect could be demonstrated. Answers to 3 questions were sought. (1) Are currents and/or fields present within the organ? (2) Can they be localized? (3) Are they involved with the synaptogenic process? Voltage measurements across pieces of electric organ revealed the presence of a dorsal positive potential in the low millivolt range. Injection of DC current against this dorsal positive dipole had the effect of reducing the percent of neuritic coverage on the ventral surface as measured by quantitative electron microscopy. These results indicate the presence of a field potential, dorsal positive which, when reversed, causes a retardation in the synaptogenic rate. They are consistent with published reports of neurites growing preferentially towards cathodal sources and implicate that bioelectric forces may be one component of the synaptogenesis process.

An ultrastructural analysis of electromotor cell death in Torpedo marmorata and its counterpart in vitro

SummaryNaturally occurring neuronal cell death has been investigated in the electromotor system of Torpedo marmorata and compared with neuronal death seen in expiant cultures of tissues from T. marmorata electric lobe. One objective of the study was to determine whether cell death in vitro was morphologically the same as cell death in vivo and to substantiate the validity of using in vitro models for studying naturally occurring cell death. Sequences of degeneration in vitro and in vivo have been established and compared: a single morphological sequence best represents this form of cell death in both conditions. In vivo, dying neurons are seen at all depths of the electric lobe indicating the involvement of different generations. Retrograde degeneration appears to be the first sign of cell death.