Toxin and kinetic profile of rat brain type III sodium channels expressed in Xenopus oocytes.

Sodium (Na+) channels are members of a multigene family and are responsible for generation and propagation of the action potential in excitable cells. We have assembled, in a transcription-competent vector, a full-length cDNA clone encoding the rat brain type III Na+ channel. Xenopus oocytes microinjected with in vitro synthesized mRNA expressed functional rat brain Na+ channels from such 'cloned' RNA transcripts. We found that type III Na+ currents in whole cell microelectrode voltage clamp and in cell-attached patch recordings decayed much more slowly than any other reported Na+ current. In addition, we saw typical and additive effects of alpha- and beta-scorpion toxins, suggesting that the Na+ channel alpha-subunit itself contains functional and distinct toxin binding sites.

m1-toxin.

The venom of the Eastern green mamba from Africa, Dendroaspis angusticeps, contains a number of toxins which block the binding of 3H-antagonists to genetically-defined m1 and m4 muscarinic acetylcholine receptors. Most of the anti-muscarinic activity of the venom is due to the presence of a newly-isolated toxin, "m1-toxin", which has 64 amino acids and a molecular mass of 7361 Daltons. At present m1-toxin is the only ligand which is known to be capable of fully blocking m1 receptors without affecting m2-m5 receptors. It binds very rapidly, specifically and pseudoirreversibly to the extracellular face of m1 receptors on cells, in membranes or in solution, whether or not the primary receptor site is occupied by an antagonist. Bound toxin can either prevent the binding and action of agonists or antagonists, or prevent the dissociation of antagonists. The toxin is useful for identifying m1 receptors during anatomical and functional studies, for recognizing and stabilizing receptor complexes, and for occluding m1 receptors so that other receptors are more readily studied.

Generation of a uniform 3' end RNA of murine leukemia virus.

Using the S1 nuclease mapping technique, we demonstrated that the majority of Moloney murine leukemia RNA molecules, isolated either from the nucleus or cytoplasm of infected mouse cells, share a uniform 3' end located at the border of the R and U-5 regions of the long terminal repeat. When the long terminal repeat sequences were inserted in the pSV plasmid downstream of the simian virus 40 late promoter, the 3' end of the viral RNA was also generated close to the R region of the long terminal repeat. These results demonstrate that the long terminal repeat signals the generation of an authentic 3' end when situated downstream of an actively transcribed region.