Long-term enhancement of synaptic transmission by synthetic mast cell degranulating peptide and its localization of binding sites in hippocampus

The nociceptive and anti-nociceptive effects of bee venom injection and therapy: a double-edged sword

Bee venom injection as a therapy, like many other complementary and alternative medicine approaches, has been used for thousands of years to attempt to alleviate a range of diseases including arthritis. More recently, additional theraupeutic goals have been added to the list of diseases making this a critical time to evaluate the evidence for the beneficial and adverse effects of bee venom injection. Although reports of pain reduction (analgesic and antinociceptive) and anti-inflammatory effects of bee venom injection are accumulating in the literature, it is common knowledge that bee venom stings are painful and produce inflammation. In addition, a significant number of studies have been performed in the past decade highlighting that injection of bee venom and components of bee venom produce significant signs of pain or nociception, inflammation and many effects at multiple levels of immediate, acute and prolonged pain processes. This report reviews the extensive new data regarding the deleterious effects of bee venom injection in people and animals, our current understanding of the responsible underlying mechanisms and critical venom components, and provides a critical evaluation of reports of the beneficial effects of bee venom injection in people and animals and the proposed underlying mechanisms. Although further studies are required to make firm conclusions, therapeutic bee venom injection may be beneficial for some patients, but may also be harmful. This report highlights key patterns of results, critical shortcomings, and essential areas requiring further study.

The synaptic activation of NMDA receptors and Ca2+ signalling in neurons

Long-term potentiation (LTP) in the hippocampus is a model system for understanding the synaptic basis of learning and memory. We have studied the mechanism of induction of LTP using voltage-clamp techniques and confocal imaging of Ca2+ in rat hippocampal slices. In the Schaffer collateral-commissural pathway the neurotransmitter L-glutamate activates two classes of ionotropic receptor, named after the selective ligands AMPA (alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate) and NMDA (N-methyl-D-aspartate). During low frequency transmission the excitatory postsynaptic potential (EPSP) is mediated predominantly by AMPA receptors. NMDA receptors play a minor role because their ion channels are substantially blocked by Mg2+, and this block is intensified by GABA-mediated synaptic inhibition. During high frequency transmission the GABA-mediated inhibition is depressed, by mechanisms initiated by GABAB autoreceptors. This allows a greater contribution from the NMDA receptors, through which Ca2+ enters the dendrites of the postsynaptic neurons to initiate a cascade of biochemical processes which ultimately result in enhanced synaptic efficiency.

Regionally selective alterations in local cerebral glucose utilization evoked by charybdotoxin, a blocker of central voltage-activated K+-channels

The quantitative [14C]-2-deoxyglucose autoradiographic technique was employed to investigate the effect of charybdotoxin, a blocker of certain voltage-activated K+ channels, on functional activity, as reflected by changes in local rates of cerebral glucose utilization in rat brain. Intracerebroventricular administration of charybdotoxin, at doses below those producing seizure activity, produced a heterogeneous effect on glucose utilization throughout the brain. Out of the 75 brain regions investigated, 24 displayed alterations in glucose utilization. The majority of these changes were observed with the intermediate dose of charybdotoxin administered (12.5 pmol), with the lower (6.25 pmol) and higher (25 pmol) doses of charybdotoxin producing a much more restricted pattern of change in glucose utilization. In brain regions which displayed alterations in glucose at all doses of charybdotoxin administered, no dose dependency in terms of the magnitude of change was observed. The 21 brain regions which displayed altered functional activity after administration of 12.5 pmol charybdotoxin were predominantly limited to the hippocampus, limbic and motor structures. In particular, glucose utilization was altered within three pathways implicated within learning and memory processes, the septohippocampal pathway, Schaffer collaterals within the hippocampus and the Papez circuit. The nigrostriatal pathway also displayed altered local cerebral glucose utilization. These data indicate that charybdotoxin produces alterations in functional activity within selected pathways in the brain. Furthermore the results raise the possibility that manipulation of particular subtypes of Kv1 channels in the hippocampus and related structures may be a means of altering cognitive processes without causing global changes in neural activity throughout the brain.

GTP-binding protein activation underlies LTP induction by mast cell degranulating peptide

Mast cell degranulating peptide (MCD) induces long-term potentiation (LTP) in the CA1 region of the hippocampus. MCD has been shown to bind to a voltage-dependent A-type potassium channel with high-affinity (less than 1 nM). However, the concentration necessary to induce LTP is more than 500 nM, suggesting that some other functions of MCD are also fundamental to LTP induction. The concentration of MCD required for LTP induction was greatly reduced by preactivating G proteins. This fact suggests that G protein activation by MCD also plays an important role in LTP induction. MCD-binding proteins were purified from rat brain. G proteins were found to exist in a non-denatured state in this affinity-purified fraction. When reconstituted into a planar lipid bilayer membrane, a potassium-selective and voltage-dependent current could be observed. This channel was blocked by MCD at a high concentration equal to the effective concentration for G protein activation. Addition of GTP-gamma-S significantly blocked the reconstituted current. Thus, we identified a pathway for LTP induction by MCD in which high concentrations of MCD activate G protein which in turns leads to blocking of a potassium channel.

K+ channel involvement in induction of synaptic enhancement by mast cell degranulating (MCD) peptide

A bee venom, mast cell degranulating peptide (MCD), which induces long-term potentiation (LTP) of synaptic transmission in hippocampal slices, was found to possess multiple functions. They include (1) binding and thereby inhibiting a voltage-dependent K(+)-channel in brain membranes, (2) incorporation in a lipid bilayer to form voltage-dependent and cation-selective channels by itself, and (3) activation of a pertussis toxin (Ptx)-sensitive GTP-binding proteins. In this study, we prepared several derivatives and analogues of MCD and investigated which function is more closely related to the induction of LTP. Another bee venom, apamin, formed ion channels in a lipid bilayer which were indistinguishable from those formed by MCD. D-MCD, an optical isomer of MCD, activated a Ptx-sensitive GTP-binding protein. However, these peptides did not induce LTP in the hippocampal slices. A snake venom, dendrotoxin-I (DTX-I), bound to the same K(+)-channels as MCD and did induce LTP. These results suggest that the most potent aspect of MCD involved in LTP inducibility is its interaction with the voltage-dependent K(+)-channel.

Mast cell degranulating (MCD) peptide and its optical isomer activate GTP binding protein in rat mast cells

The MCD peptide in bee venom induces degranulation in mast cells. The internal calcium concentration of mast cells increased and remained high following MCD stimulation. This calcium increase was blocked by pertussis toxin (Ptx) treatment, suggesting that MCD peptide activates Ptx-sensitive G-protein. Even in the absence of external calcium in the incubation medium, the calcium concentration increased by MCD treatment, but soon returned to the original level. D-MCD, the optical isomer of the MCD peptide, also increased the internal calcium concentration through a Ptx-sensitive pathway. We suggest that cationic clusters at one side of the surface are more important in activating the G-protein than the alpha-helix conformation.

Direct activation of GTP-binding proteins by venom peptides that contain cationic clusters within their alpha-helical structures

Direct interactions of venom peptides that contained a cysteine-stabilized alpha-helical motif within their internal molecules with alpha beta gamma-trimeric GTP-binding proteins (G proteins) were studied in reconstituted phospholipid vesicles. Mast cell-degranulating (MCD) peptide stimulated the steady-state rate of GTP hydrolysis catalyzed by the reconstituted G proteins. Synthetic D-MCD peptide, the optical isomer of MCD peptide, was also effective in the activation of G proteins as L-MCD peptide. The stimulations by L- and D-peptides were both abolished in G proteins that had been ADP-ribosylated by pertussis toxin. Charybdotoxin also stimulated, though slightly, the GTPase activity of G proteins. Such a stimulation was, however, not observed upon the incubation of G proteins with other venom peptides such as apamin, sarafotoxin and endothelin. Thus, in comparison of the amino acid sequences of their venom peptides, the extent of the activation of G proteins appeared to be correlated with the number of basic amino acid residues around the alpha-helix. These results suggest that cationic clusters at one side of the alpha-helical surface are more important in the direct activation of G proteins than a specific, alpha-helical structure.

Mast Cell Degranulating Peptide Increases the Frequency of Spontaneous Miniature Postsynaptic Currents in CA3 Rat Hippocampal Neurons

Mast cell degranulating peptide (MCDP) is a neurotoxic agent isolated from bee venom. It produces a long-term potentiation in the hippocampus. We now report that MCDP, at nanomolar concentrations, induces a reduction of a transient voltage-dependent potassium current (ID) in CA3 rat pyramidal neurons and a persistent (>30 min) enhancement of the frequency of spontaneous miniature excitatory and inhibitory postsynaptic currents (m.e.p.s.c.s. and m.i.p.s.c.s.). M.e.p.s.c.s. and m.i.p.s.c.s. were recorded in the presence of bicuculline (30 microM) and 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 10 microM), respectively. The increased frequency of m.e.p.s.c.s. (408 +/- 60%) and m.i.p.s.c.s. (583 +/- 553%) was independent of the reduction of ID because 4-aminopyridine (4-AP, 30 microM - 2 mM) blocked ID but had no effects on m.e.p.s.c.s. and m.i.p.s.c.s. In the presence of the calcium channel blocker manganese (3 mM), MCDP still enhanced the frequency of m.e.p.s.c.s. (326 +/- 162%). It is concluded that MCDP augments the release of excitatory and inhibitory transmitter by an action, which is independent of calcium influx, through voltage-dependent channels.