Determinants of the calcium permeation of ligand-gated cation channels.

Fast synaptic transmission in the vertebrate brain is mediated by ligand-gated channel receptors. As some of these receptors have been implicated in learning and memory, it is important to understand their mechanism of action at a molecular level. Excitatory receptors are members of large gene families of related channels that are gated by acetylcholine, serotonin, and the most abundant neurotransmitter, glutamate. Within the last year, a number of important studies have focused on the ability of these channels to flux calcium ions. Calcium entry into neurons through some of these channels triggers biochemical cascades, which can lead to changes in synaptic efficacy, presumed to be a requisite for memory formation, or if it occurs in excess, to cell death. Recent studies that attempt to determine the channel structures responsible for this calcium conductance will be discussed.     

Complete amino acid sequence of steer liver microsomal NADH-cytochrome b5 reductase

The complete covalent structure of liver microsomal NADH-cytochrome b5 reductase from steer liver microsomes was determined. Cleavage at methionyl bonds gave 10 peptides accounting for all the residues of the protein. Acid cleavage of the reductase at the Asp-Pro bonds gave three peptides accounting for all the CNBr peptides in the molecule. Subfragmentation of these peptides by chemical and enzymatic cleavage provided overlaps which established all the fragments in an unambiguous sequence of 300 residues, corresponding to Mr 34,110. Limited tryptic digestion cleaved reductase at residues 28 and 119, yielding a preparation having two noncovalently linked peptides having a conformation which binds flavin and retains the structural features essential for NADH-cytochrome b5 activity. A model for the secondary structure of cytochrome b5 reductase is proposed that is based on computer-assisted analysis of the amino acid sequence. In this model the beta-turns are predominant and there is some 25% alpha and 30% beta structure.     

Degradation of acetylcholine receptor in diaphragms of rats with experimental autoimmune myasthenia gravis.

The degradation of acetylcholine receptor observed in denervated and innervated normal rat diaphragms in organ culture is stimulated by exogenous antireceptor serum. In this paper we demonstrate that diaphragms from rats with experimental autoimmune myasthenia gravis contain reduced amounts of acetylcholine receptor. Acetylcholine receptor from myasthenic, but not from normal, rats has antibody bound to it and is degraded at an accelerated rate. We conclude that in the chronic phase of experimental autoimmune myasthenia gravis increased acetylcholine receptor degradation can be accounted for by a mechanism involving antigenic modulation, and that such a process can contribute to the clinical symptoms of impaired neuromuscular transmission.     

RNase T1 mutant Glu46Gln binds the inhibitors 2'GMP and 2'AMP at the 3' subsite.

On the basis of molecular dynamics and free-energy perturbation approaches, the Glu46Gln (E46Q) mutation in the guanine-specific ribonuclease T1 (RNase T1) was predicted to render the enzyme specific for adenine. The E46Q mutant was genetically engineered and characterized biochemically and crystallographically by investigating the structures of its two complexes with 2'AMP and 2'GMP. The ribonuclease E46Q mutant is nearly inactive towards dinucleoside phosphate substrates but shows 17% residual activity towards RNA. It binds 2'AMP and 2'GMP equally well with dissociation constants of 49 microM and 37 microM, in contrast to the wild-type enzyme, which strongly discriminates between these two nucleotides, yielding dissociation constants of 36 microM and 0.6 microM. These data suggest that the E46Q mutant binds the nucleotides not to the specific recognition site but to the subsite at His92. This was confirmed by the crystal structures, which also showed that the Gln46 amide is hydrogen bonded to the Phe100 N and O atoms, and tightly anchored in this position. This interaction may either have locked the guanine recognition site so that 2'AMP and 2'GMP are unable to insert, or the contribution to guanine recognition of Glu46 is so important that the E46Q mutant is unable to function in recognition of either guanine and adenine.     

Crystal and molecular structure of the sulfhydryl protease calotropin DI at 3·2 Å resolution

The three-dimensional structure of the sulfhydryl protease calotropin DI from the madar plant, Calotropis gigantea, has been determined at 3·2 Å resolution using the multiple isomorphous replacement method with five heavy atom derivatives. A Fourier synthesis based on protein phases with a mean figure of merit of 0·857 was used for model building. The polypeptide backbone of calotropin DI is folded to form two distinct lobes, one of which is comprised mainly of α-helices, while the other is characterized by a system of all antiparallel pleated sheets. The overall molecular architecture closely resembles those found in the sulfhydryl proteases papain and actinidin.Despite the unknown amino acid sequence of calotropin DI a number of residues around its active center could be identified. These amino acid side-chains were found in a similar arrangement as the corresponding ones in papain and actinidin. The polypeptide chain between residues 1 and 18 of calotropin DI folds in a unique manner, providing a possible explanation for the unusual inability of calotropin DI to hydrolyze those synthetic substrates that papain and actinidin act upon.     

Step reductions in extracellular Ca2+ activate a transient inward current in chick dorsal root ganglion cells.

We investigated whether transient step reductions in divalent cations would produce detectable changes in neuronal excitability similar to those reported in the total absence of divalent cations. Using cultured chick dorsal root ganglion cells as a model system, our results indicate that a step reduction in divalent cations induces a transient inward current. This response is mediated by a tetrodotoxin-resistant, Na+-permeable, cation channel that is blocked by cadmium. This, and our observation that the response is abolished by verapamil, suggests that the current passes through calcium channels. This transient inward current was estimated to be activated by decreases in extracellular calcium ([Ca2+]o) as small as 0.5-0.8 mM and thus represents a different response from the one previously observed when steady-state [Ca2+]o levels were reduced to micromolar levels.     

Ds transposition mediated by transient transposase expression in Heiracium aurantiacum

The feasibility of using transient transposase expression to mobilize Ds elements for gene tagging in Hieracium aurantiacum was evaluated. A T-DNA construct carrying the Ac transposase gene and either a visible marker gene (uidA) or the conditionally-lethal marker gene (codA) was transferred to H. aurantiacum leaf discs (previously transformed with a Ds element) by co-cultivation with Agrobacterium tumefaciens. Shoots were regenerated directly from the co-cultivated leaf discs under selection for antibiotic resistance resulting from Ds excision. Most regenerants carried unique transposition events. Of 84 regenerated plants, twenty one (25%) did not express the marker gene and the DNA coding sequence of the transposase could not be detected in seven (8.3%). Potential advantages of this method over conventional gene-tagging methods are: rapid recovery of individual transposition events; regenerated plants are isogenic; and the transient nature of transposase expression should facilitate the stabilisation of the transposed element.