Mediation of hippocampal mossy fiber long-term potentiation by cyclic AMP.

Repetitive activation of hippocampal mossy fibers evokes a long-term potentiation (LTP) of synaptic responses in pyramidal cells in the CA3 region that is independent of N-methyl-D-aspartate receptor activation. Previous results suggest that the site for both the induction and expression of this form of LTP is presynaptic. Experimental elevation of cyclic adenosine 3',5'-monophosphate (cAMP) both mimics and interferes with tetanus-induced mossy fiber LTP, and blockers of the cAMP cascade block mossy fiber LTP. It is proposed that calcium entry into the presynaptic terminal may activate Ca(2+)-calmodulin-sensitive adenylyl cyclase I which, through protein kinase A, causes a persistent enhancement of evoked glutamate release.

The opioid peptide dynorphin mediates heterosynaptic depression of hippocampal mossy fibre synapses and modulates long-term potentiation.

The mossy fibre pathway in the hippocampus uses glutamate as a neurotransmitter, but also contains the opioid peptide dynorphin. Synaptic release of dynorphin causes a presynaptic inhibition of neighbouring mossy fibres and inhibits the induction and expression of mossy fibre long-term potentiation. These findings demonstrate a physiological role for a neuropeptide in the central nervous system, provide a functional basis for the coexistence of a neuropeptide with classic neurotransmitters and demonstrate the very different roles played by these two classes of signalling molecules.

Mossy fiber long-term potentiation shows specificity but no apparent cooperativity.

Specificity in long-term potentiation (LTP) means that synapses onto a postsynaptic cell can potentiate independently of one another. Cooperativity refers to a requirement that some threshold number of afferents be co-activated to evoke LTP with a high-frequency stimulus. The induction of long-term potentiation (LTP) at the associational/commissural synapses onto hippocampal CA3 pyramidal cells shows clear cooperativity. LTP of mossy fiber inputs to these cells does not. Mossy fiber LTP does show synapse specificity. These results bear on the cellular mechanisms and the functions of mossy fiber LTP.

Comparison of two forms of long-term potentiation in single hippocampal neurons.

In invertebrate nervous systems, some long-lasting increases in synaptic efficacy result from changes in the presynaptic cell. In the vertebrate nervous system, the best understood long-lasting change in synaptic strength is long-term potentiation (LTP) in the CA1 region of the hippocampus. Here the process is initiated postsynaptically, but the site of the persistent change is unresolved. Single CA3 hippocampal pyramidal cells receive excitatory inputs from associational-commissural fibers and from the mossy fibers of dentate granule cells and both pathways exhibit LTP. Although the induction of associational-commissural LTP requires in the postsynaptic cell N-methyl-D-aspartate (NMDA) receptor activation, membrane depolarization, and a rise in calcium, mossy fiber LTP does not. Paired-pulse facilitation, which is an index of increased transmitter release, is unaltered during associational-commissural LTP but is reduced during mossy fiber LTP. Thus, both the induction and the persistent change may be presynaptic in mossy fiber LTP but not in associational-commissural LTP.

The physiology of somatostatin in the rabbit retina.

The neuropeptide somatostatin (SS) has been localized to neurons of the rabbit retina by immunochemical and biochemical methods (Sagar et al., 1982, 1986; Marshak and Yamada 1984). We examined the effects of bath-applied SS on neurons of the rabbit retina, using intra- and extracellular electrophysiological techniques in an in vitro retina eyecup preparation. All commonly encountered ganglion cell receptive field types were affected by SS, and the effects were of 3 kinds: The first was a general excitation, occurring with a threshold concentration of about 100 nM; the onset of the excitation was too slow (seconds) for SS to participate in any rapid light-evoked responses. The second SS effect was an increase in the "signal-to-noise ratio," defined here as the ratio of light-evoked to spontaneous spiking, which resulted from a decrease in spontaneous activity and, usually, a concomitant increase in light-evoked spiking. The third effect was a shift in center-surround balance towards a more dominant center. The signal-to-noise and center-surround effects were evident at concentrations as low as 0.5 nM; both were slow onset (tens of seconds) and long lasting (tens of minutes). SS acted at multiple levels within the retinal circuitry to produce the observed changes in ganglion cell output. These effects included direct actions on ganglion and amacrine cells, and a decrease in the efficiency with which horizontal cells could drive the retinal network. At least part of these SS actions on third-order neurons resulted from a decrease in conductance to ions with an equilibrium potential more positive than dark membrane potential. The degradation-resistant SS agonist SMS201-995 had effects qualitatively and quantitatively similar to those of SS, suggesting that SS may be degraded slowly enough to act at a distance from its sites of release. While no adequate SS antagonist is available, the greater sensitivity to exogenous SS, in retinas depleted of their SS content (with cysteamine), suggests a role for endogenous SS. The potency of SS also reinforces this view. The results of this study suggest that SS may be a neuromodulator in the rabbit retina, producing long-lasting changes in the "signal-to-noise" discharge pattern and center-surround balance of ganglion cells.

The physiology of substance P in the rabbit retina.

The neuropeptide substance P (SP) has been localized to amacrine and ganglion cells in the rabbit retina. We have examined the effects of SP and related peptides on rabbit retinal neurons using bath application and intra- and extra-cellular electrophysiological methods in an in vitro retina eyecup preparation. Substance P, at concentrations as low as 25 nM, moderately excited most brisk ganglion cells. SP excited some ganglion cells directly during cobalt block of synaptic transmission. Intracellular recordings from amacrine cells demonstrated that some, but not all, were depolarized by SP; pharmacological evidence suggested GABAergic amacrines were probably among those sensitive to SP. SP did not affect horizontal cells or the ERG, suggesting that the effects of this peptide are confined to the inner retina. The effects of SP were strongly potentiated by peptidase inhibitors, raising the possibility that endogenously released SP may act quite locally in the rabbit retina. The relative potencies of SP and the related peptides substance K and eledoisin on different cells suggest that more than one tachykinin receptor subtype is present in the rabbit retina. The responses of ganglion cells to SP desensitized with repeated or prolonged applications. Comparison of a cell's light responses before and after the receptors were desensitized revealed no qualitative changes in receptive field characteristics, but quantitative changes in excitability were apparent. SP antagonist analogs, although not potent, specifically blocked the effects of SP on some ganglion cells. The effects of these antagonists on light responses reinforced the inferences from desensitization paradigms regarding the role of endogenous SP.(ABSTRACT TRUNCATED AT 250 WORDS)

A perfused rabbit retina preparation suitable for pharmacological studies.

We present a method for maintaining the isolated retina-eyecup of the rabbit in a manner which permits the introduction of pharmacological agents at a controlled concentration. As judged by physiological criteria, the retina is well maintained under these conditions. The stability of the preparation is excellent; intracellular or extracellular recordings from single cells can be maintained through multiple solution changes. By using Co2+ to block synaptic transmission, we can distinguish direct from transsynaptic effects. Use of this preparation should facilitate the investigation of neurotransmission in the mammalian retina.

Neurotensin actions in the retina: mechanisms and variability.

The effects of neurotensin on mudpuppy retinal cells were studied using extracellular and intracellular electrophysiological recording techniques and bath application of the peptide. Ganglion and amacrine cells (but not bipolar or horizontal cells) were reversibly depolarized by low micromolar concentrations of neurotensin. Depolarizations also occurred with neurotensin application during cobalt block of synaptic transmission and were accompanied by decreased input resistances. This suggests neurotensin may act directly on amacrine and ganglion cells as a conventional excitatory transmitter. However, in many retinas, cells responded to light stimuli and to other drugs but not to neurotensin. These negative results are important in considering the peptide's normal role in retinal function.