Mu opioid receptors participate in the excitatory effect of opiates in the hippocampal slice

The effects of the opioid peptides morphiceptin and [N-MePhe3-D-Pro4]morphiceptin (PL017), both mu receptor agonists, were examined by electrophysiological techniques in the rat hippocampal slice and ligand binding techniques in hippocampal membrane preparations. The electrophysiological actions of the mu agonists were similar to those of the previously studied delta receptor agonist [D-Ala2, D-Leu5]enkephalin. Thus, for a given size field excitatory postsynaptic potential the amplitude of both population spike and intracellular excitatory postsynaptic potential was increased by morphiceptin. These effects were concentration dependent and reversed by naloxone. The EC50 for morphiceptin was 1.6 microM, which is consistent with the mu-selective binding properties of this peptide. Similar results were obtained with the more potent analog PL017. Morphiceptin and morphine had similar displacement profiles in competition experiments performed with hippocampal membranes and a variety of radioligands. In Tris buffer morphiceptin potently inhibited the binding of the mu receptor marker [125I]FK 33,824 but displayed the expected shallow displacement isotherm against binding of the delta receptor marker [125I][D-Ala2, D-Leu5]enkephalin. A significant interaction of either morphiceptin or morphine with kappa binding sites is improbable since neither agonist could fully displace binding of [3H]ethylketocyclazocine or [3H]diprenorphine. The potency of morphiceptin in displacing [3H]naloxone from mu binding sites was reduced by inclusion of 100 mM NaCl or 100 microM GTP in the assay. The dissociation constant of morphiceptin for mu binding sites in physiological saline was 0.78 microM, comparable to its EC50 determined in electrophysiological experiments. It appears, therefore, that the electrophysiological properties of opioid peptides in the hippocampal slice may be mediated by both mu and delta receptors.(ABSTRACT TRUNCATED AT 250 WORDS)

Filling of the lateral canal. Report of two cases

In this article two cases, each involving an inflamed lateral canal, are reported. The lateral canals were fully filled with Oxpara paste by slight overfilling. The management principles of lateral and accessory canals are briefly mentioned as well.

Dynamics and time-averaged chemical potential of proteins: importance in oligomer association

The chemical potential of a protein is a time-averaged quantity whose value depends upon the fractions of time spent in the different conformations and therefore upon the protein dynamics. If the monomer involved in an association equilibrium undergoes unfolding limited by its lifetime, its chemical potential as well as that of the associated form will not be constant and the free energy of association will be a diminishing function of the degree of dissociation. For a unique free energy of association, the logarithm of the protein concentration must change by 2.86 units to increase the degree of dissociation from 0.1 to 0.9. The dissociation of enolase appears to take place over a significantly smaller range (1.7 units), and dansyl conjugates of enolase show an even narrower range (0.9 unit). A simple descriptive theory is developed, and this shows that the values observed are explained by a difference in free energy of 1-3 kcal/mol (1 cal = 4.18 J) between the conformations present at negligible and almost complete dissociation.

NAD+ analogs in formation of new fluorophores on ultraviolet irradiation with D-glyceraldehyde-3-phosphate dehydrogenase

A number of NAD+ analogs have been tested in their ability to form fluorescent derivatives when UV irradiated with the active site Cys-149 carboxymethylated GAPDH and this has been compared with their properties of acting as hydrogen acceptors and forming the Racker band. Among the analogs tested, NHD+, NGD+, APAD+ and epsilon NAD+ give positive results in all the above-mentioned reactions whereas alpha NAD+, NMN+ and CPAD+ are all negative. FPAD+ forms a fluorescent derivative on UV irradiation with the carboxymethylated enzyme but is inactive as a hydrogen acceptor and does not form the Racker band. This is probably due to thiohemiacetal formation of the pyridine 3-aldehyde of this derivative with the active site SH group required for both the latter 2 reactions. TPAD+, although active active as a hydrogen acceptor, does not form either a fluorescent derivative or a Racker band. The fact that for the great majority of the analogs, the property of forming fluorescent derivatives is in parallel with their hydrogen acceptor activity seems to show that the formation of the fluorescent derivative is indeed at the active site, and hence can be used as an intrinsic probe for the study of the conformation of the active site of this enzyme.