1. Synapsin I was injected into a vertebrate presynaptic axon to analyze its action on quantal synaptic transmission. Two microelectrodes were used for simultaneous intracellular recording from pairs of identified neurons in the goldfish brain. The postsynaptic electrode was placed in a cranial relay neuron (CRN) within 100 microns of its synapse with the Mauthner neuron. The presynaptic electrode impaled the Mauthner axon (M-axon) 50-200 microns from the first electrode. 2. Spontaneous miniature excitatory postsynaptic potentials (mEPSPs) and evoked postsynaptic potentials (EPSPs) were recorded at steady states before and after synapsin I was microinjected into the presynaptic M-axon. Responses were digitized and subsequently analyzed by computer for quantal parameters. 3. In 12 experiments, injection of synapsin I resulted in a reduction in transmission. The decrease in EPSP amplitude began approximately 30 s after the injection, reached a plateau within 10 min, and appeared to be reversible and dose dependent. 4. Injection of synapsin I decreased quantal content (m), with no effect on postsynaptic receptor sensitivity or on amount of transmitter per quantum. Further analysis based on the simplest binomial model for quantal release revealed that synapsin I consistently reduced the number of quantal units available for release (n) although the probability of release (p) was either unchanged or slightly increased. Injected synapsin I may thus bind to presynaptic vesicles and prevent transmitter quanta from entering a pool subject to evoked release.
1. Although it is generally agreed that Ca2+ couples depolarization to the release of neurotransmitters, hypertonic saline and ethanol (ETOH) evoke neurosecretion independent of extracellular Ca2+. One possible explanation is that these agents release Ca2+ from an intracellular store that then stimulates Ca(2+)-dependent neurosecretion. An alternative explanation is that these agents act independently of Ca2+. 2. This work extends previous observations on the action of ETOH and hypertonic solutions (HOSM) on neurons to include effects on [Ca2+]i. We have looked for Ca(2+)-independent or -dependent neurosecretion evoked by these agents in parasympathetic postganglionic neurons dissociated from chick ciliary ganglia and maintained in tissue culture. The change in concentration of free Ca2+ in the micromolar range inside neurons ([Ca2+]i) was measured with indo-1 with the use of a Meridian ACAS 470 laser scanning microspectrophotometer. 3. Elevated concentration of extracellular KCl increased [Ca2+]i and the frequency of quantal events. Also, a twofold increase in osmotic pressure (HOSM) produced a similar increase in quantal release and a significant rise in [Ca2+]i; however, the Ca2+ appeared to come from intracellular stores. 4. In contrast, ETOH stimulated quantal neurosecretion without a measurable change in [Ca2+]i. It appears the alcohol exerts its influence on some stage in the process of exocytosis that is distal to or independent of the site of Ca2+ action. 5. The effects of high [KCl]o and osmotic pressure were occlusive. This is explained in part by the observation that hypertonicity reduced Ca2+ current, but an action on Ca2+ stores is also likely.(ABSTRACT TRUNCATED AT 250 WORDS)
Opportunistic viruses are a major problem for immunosuppressed individuals, particularly following organ or stem cell transplantation. Current treatments are non-existent or suffer from problems such as high toxicity or development of resistant strains. We previously published that a trafficking inhibitor that targets a host protein greatly reduces the replication of human cytomegalovirus. This inhibitor was also shown to be moderately effective against polyomaviruses, another family of opportunistic viruses. We have developed a panel of analogues for this inhibitor and have shown that these analogues maintain their high efficacy against HCMV, while substantially lowering the concentration required to inhibit polyomavirus replication. By targeting a host protein these compounds are able to inhibit the replication of two very different viruses. These observations open up the possibility of pan-viral inhibitors for immunosuppressed individuals that are effective against multiple, diverse opportunistic viruses.
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