Membrane voltage and neurotransmitter regulation of neuronal growth cone motility

The neurotransmitters serotonin and dopamine inhibit growth cone motility and neurite elongation of specific identified neurons of the pond snail Helisoma. Similarly, experimentally evoked action potentials inhibit motility of these growth cones. Here we explore the possibility that the motility- and elongation-inhibiting actions of serotonin and dopamine derive from the electrophysiological responses of the respective neurons. Evidence of three types in support of this hypothesis is presented: (1) Only those identified neurons for which motility is inhibited by serotonin or dopamine respond to the transmitter with sustained electrical excitation. (2) The magnitude of the electrical excitation response correlates with the degree of inhibition of growth cone motility. (3) The injection of hyperpolarizing current enables motility to continue as in the absence of transmitters. We conclude that membrane voltage is an important level of control of growth cone motility, at which neurotransmitters exert a regulatory influence.     

B lymphocytes in the guinea pig thymus are specifically localized in the central area.

Since the central area is an integral part of the guinea pig thymus, the cells in this area were compared with those in the thymic cortex and medulla in cryostat-sections by using methods for demonstration of E-, EA-, EAC-adherence and surface membrane immunoglobulins. In the extra cortical central area (ECCA) 15 to 25% of the lymphocytes showed EAC-adherence and 5 to 10% appeared to bear surface membrane immunoglobulins (SIg). In the lymph sinuses up to 70% of the lymphocytes were EAC- and SIg-positive. A small amount of EAC-adhering cells was present in the medulla of the central area. Cortical lymphocytes were EAC- and SIg-negative. From these results we conclude that in the guinea pig thymus B lymphocytes are specifically localized in the central area.     

The differential regulation of formation of chemical and electrical connections in Helisoma

Novel chemical and electrical connections form between neurons not normally connected in the buccal ganglia of the snail Helisoma. We examined the cellular and environmental conditions required for the formation of each type of connection. Previous work in situ showed that novel electrical connections could form in response to axotomy. We have now found that axotomy can evoke the formation of novel unidirectional chemical connections between neurons B5 and B4 in addition to a novel electrical connection. The novel chemical connections display all of the normal properties of chemical synapses in Helisoma ganglia. These connections, however, are transient in nature and break 4 days following axotomy. Previous work has shown that conjoint outgrowth is required for the formation of electrical connections. In cell culture we have investigated whether conjoint outgrowth is also required for chemical synaptogenesis. Using neurons B5 and B19 we have found that when neuron pairs make contact in cell culture, under conditions of synchronous neurite extension, both electrical and chemical synapses form. However, if one neuron has ceased extension prior to contact by a growing neuron, electrical synapses never form (Hadley et al., 1983, 1985) but chemical synapses do form. Furthermore, the addition of serotonin (10(-6) M) to culture medium to inhibit neurite extension of B19, but not that of B5, selectively prevents the formation of electrical connections while permitting the formation of chemical synapses. Thus, the timing of contact in relation to the state of neurite extension can specify the type of connection a given neuron can form.     

Connectivity changes in an isolated molluscan ganglion during in vivo culture

The stability of neuronal connections in the isolated buccal ganglia of Helisoma trivolvis was examined during in vivo culture for periods up to one month. After 4--8 days the characteristic IPSP input to protractor motoneurons (PMNs) was either abolished or reduced in efficacy. This is apparently due to reduced efficacy of chemical synapses, since the input resistance and resting potential of the motoneurons is unchanged and a fraction of spike-evoked IPSPs from premotor neurons (cyberchrons) onto PMNs was absent. PMNs lacking IPSP input nevertheless exhibit vigorous cyclical bursts of action potentials driven by electrical EPSPs. The IPSP of PMNs showed partial or full restoration after 14--32 days of culture despite the lack of reinnervation of normal targets. Existing electrical synapses were apparently more stable during culture, but electrical connections between cyberchrons and PMNs were strengthened. Probably because of the reinforcement of these electrical synapses, regenerative cycles of activity in both cyberchrons and PMNs may often be initiated by brief stimulating of a single PMN in cultured ganglia. This is in marked contrast to normal ganglia in which PMNs possess a limited ability to generate such activity. It is concluded that isolation of the buccal ganglia results in a predictable, functional alteration of its neuronal circuitry. Such a perturbation of connectivity indicates that a significant degree of plasticity can be exhibited by adult molluscan neurons.     

A comparison of calcium homeostasis in isolated and attached growth cones of the snail Helisoma

This study examines the capability of growth cones from identified neurons of the snail Helisoma trivolvis to perform calcium homeostasis. Calcium influx into the cytoplasm was eliminated or increased experimentally to alter [Ca]i, and the compensatory response of the growth cone was measured with the fluorescent calcium indicator Fura-2. Growth cones compensated for both increases and decreases in calcium influx by restoring [Ca]i towards basal levels under both types of challenges. The intrinsic ability of growth cones to control [Ca]i was examined in physically isolated growth cones. Isolated growth cones demonstrated essentially identical calcium homeostatic properties to their intact counterparts, indicating that mechanisms governing calcium homeostasis exist intrinsically in the growth cone. Such independence may add significantly to the growth cone's potential to locally interpret and respond to stimuli encountered en route to its appropriate target.     

Decreased CD8<Superscript>+</Superscript>T cell response to Epstein-Barr virus infected B cells in multiple sclerosis is not due to decreased HLA class I expression on B cells or monocytes

Background  

Patients with multiple sclerosis (MS) have a decreased frequency of CD8⁺ T cells reactive to their own Epstein-Barr virus (EBV) infected B cells. We have proposed that this might predispose to the development of MS by allowing EBV-infected autoreactive B cells to accumulate in the central nervous system. The decreased CD8⁺ T cell response to EBV results from a general CD8⁺ T cell deficiency and also a decreased proportion of EBV-specific T cells within the total CD8⁺ T cell population. Because decreased HLA class I expression on monocytes and B cells has been reported in MS and could influence the generation and effector function of EBV-specific CD8⁺ T cells, the present study was undertaken to measure the expression of HLA molecules on B cells and monocytes in patients with MS.