Faculty Bibliography

Long-term potentiation (LTP) of synaptic transmission is a widely studied cellular example of synaptic plasticity. However, the identity, localization, and interplay among the biochemical signals underlying LTP remain unclear. Intracellular microelectrodes have been used to record synaptic potentials and deliver protein kinase inhibitors to postsynaptic CA1 pyramidal cells. Induction of LTP is blocked by intracellular delivery of H-7, a general protein kinase inhibitor, or PKC(19-31), a selective protein kinase C (PKC) inhibitor, or CaMKII(273-302), a selective inhibitor of the multifunctional Ca2+-calmodulin-dependent protein kinase (CaMKII). After its establishment, LTP appears unresponsive to postsynaptic H-7, although it remains sensitive to externally applied H-7. Thus both postsynaptic PKC and CaMKII are required for the induction of LTP and a presynaptic protein kinase appears to be necessary for the expression of LTP

In sympathetic neurons, catecholamines interact with prejunctional alpha-adrenergic receptors to reduce delivery of transmitter to postjunctional target organs. This autoinhibitory feedback is a general phenomenon seen in diverse neurons containing a variety of transmitters. The underlying mechanisms of alpha-adrenergic inhibition are not clear, although decreases in cyclic AMP and cAMP-mediated phosphorylation have been implicated. We have studied depolarization-induced catecholamine release and calcium-channel currents in frog sympathetic neurons. Here we show that alpha-adrenergic inhibition of transmitter release can be explained by inhibition of Ca2+-channel currents and not by modulation of intracellular proteins. Noradrenaline strongly reduces the activity of N-type Ca2+ channels, the dominant calcium entry pathway triggering sympathetic transmitter release, whereas L-type Ca2+ channels are not significantly inhibited. The down-modulation of N-type channels involves changes in rapid gating kinetics but not in unitary flux. This is the first detailed description of inhibition of a high-voltage activated neuronal Ca2+ channel at the single-channel level. The coupling between alpha-adrenergic receptors and N-type channels involves a G protein, but not a readily diffusible cytoplasmic messenger or protein kinase C, and may be well suited for rapid and spatially localized feedback-control of transmitter release

Voltage-gated Ca channels are very efficient pores: even while exhibiting strong ionic selectivity, they are highly permeant to divalent cations. Studies of the mechanism of selectivity and ion permeation have demonstrated that whole-cell Ca channel current in mixtures of Ca and Ba ions can be smaller than with equimolar concentrations of either ion alone. This anomalous mole fraction effect (AMFE) has provided an important impetus for proposed mechanisms of ion selectivity and permeation that invoke multiple ion binding sites. However, recordings of unitary L-type Ca currents did not demonstrate the AMFE [Marban, E. & Yue, D.T. (1988) Biophys. J. 55, 594a (abstr.)], raising doubts about whether it is an expression of ion permeation through open Ca channels. We have made patch-clamp recordings from single L-type Ca channels in PC-12 pheochromocytoma cells. Our results demonstrate a significant AMFE at the single-channel level but also indicate that the AMFE can only be found under restrictive conditions of permeant ion concentration and membrane potential. While the AMFE is clear at 0 mV when permeant ions are present at 10 mM, it is not evident when the divalent cation concentration is increased to 110 mM or the membrane potential is hyperpolarized to -40 mV. We compared our experimental observations with predictions of a single-file, two-binding-site model of the Ca channel. The model accounts for our experimental results. It predicts an AMFE under conditions that favor ion-ion interactions, as long as the outer binding site is not saturated due to high permeant ion concentration or negative membrane potential

These experiments provide a starting point for biochemical characterization of Ca channels from neuronal membranes, using omega-CgTX as a specific marker. The purification of the omega-CgTX receptors is far from complete. Each of the purification steps described results in only a two- to fivefold enrichment of the receptor proteins, and is accompanied by a loss of receptor concentration and stability, so the maximal specific activity achieved by a combination of these steps falls several orders of magnitude short of that of a large, homogeneous, active protein. Nevertheless, these studies have yielded important information about the omega-CgTX receptor. The Stokes' radius, determined from gel exclusion chromatography, is approximately 87 A, and the sedimentation coefficient, determined from sucrose gradient sedimentation, is approximately 19 S. These values are similar to those found for the DHP receptors solubilized in digitonin. We have also found that at least some of the omega-CgTX receptors have complex carbohydrate moieties that are recognized by WGA, together with evidence of heterogeneity of receptor glycosylation. Additionally, we have been able to use the solubilized, partially purified receptors in cross-linking experiments to tentatively identify the molecular weights of the omega-CgTX targets from rat brain. A large peptide of approximately 300 kDa, similar to that identified in photoaffinity studies, is very clearly labeled by the chemical incorporation of [125I]omega-CgTX into partially purified receptor preparations, but some ambiguity remains because of the faint labeling of peptides in the 120-170-kDa range. The approximately 300-kDa peptide is much larger than any single peptide component of DHP receptors from skeletal muscle, and it may be related to a molecular combination of the 170-kDa and 135-kDa subunits of the DHP receptor. Because [125I]omega-CgTX presumably labels both N- and L-type neuronal Ca channels, both channel types will probably be found in the purified preparations. Thus, at some time, it will be necessary to separate DHP-sensitive L-type channels from preparations of L- and N-type channels identified by omega-CgTX binding

Long-term potentiation (LTP) of synaptic transmission in the hippocampus is a much-studied example of synaptic plasticity. Although the role of N-methyl-D-aspartate (NMDA) receptors in the induction of LTP is well established, the nature of the persistent signal underlying this synaptic enhancement is unclear. Involvement of protein phosphorylation in LTP has been widely proposed, with protein kinase C (PKC) and calcium-calmodulin kinase type II (CaMKII) as leading candidates. Here we test whether the persistent signal in LTP is an enduring phosphoester bond, a long-lived kinase activator, or a constitutively active protein kinase by using H-7, which inhibits activated protein kinases and sphingosine, which competes with activators of PKC (ref. 17) and CaMKII (ref. 18). H-7 suppressed established LTP, indicating that the synaptic potentiation is sustained by persistent protein kinase activity rather than a stably phosphorylated substrate. In contrast, sphingosine did not inhibit established LTP, although it was effective when applied before tetanic stimulation. This suggests that persistent kinase activity is not maintained by a long-lived activator, but is effectively constitutive. Surprisingly, the H-7 block of LTP was reversible; evidently, the kinase directly underlying LTP remains activated even though its catalytic activity is interrupted indicating that such kinase activity does not sustain itself simply through continual autophosphorylation (see refs 9, 13, 15)