Human rotavirus strain 69M has a unique VP4 as determined by amino acid sequence analysis

The group A rotavirus strain 69M has recently been classified as a new rotavirus serotype, G8, based on the antigenic specificity of its VP7 outer capsid glycoprotein. The fourth gene of 69M, which encodes the other outer capsid protein VP4, was sequenced. The gene is 2362 nucleotides in length and contains one long open reading frame beginning at the 10th nucleotide from the 5' end and terminating with a stop codon 22 bases from the 3' end. The encoded VP4 contains 776 amino acids. Comparative analysis of the deduced amino acid sequence with other rotavirus strains demonstrated that the VP4 of strain 69M shares 68.9 to 74.5% amino acid identity with the VP4 from strains known to represent four human rotavirus VP4 genetic alleles and 74.9 to 86.2% identity with VP4 from various animal rotaviruses. Northern blot hybridization with either radiolabeled ssRNA transcripts from 69M or cloned 69M gene 4 cDNA as probes indicated that the fourth gene of strain 69M is genetically distinct from any group A rotavirus gene 4 described thus far. These data suggest that at least one additional antigenic specificity of VP4 exists in circulating human group A rotavirus strains.

Determination of the three-dimensional structure of the Antennapedia homeodomain from Drosophila in solution by 1H nuclear magnetic resonance spectroscopy

The determination of the three-dimensional structure of the Antennapedia homeodomain from Drosophila in solution is described. The techniques used are 1H nuclear magnetic resonance spectroscopy for the data collection, and calculation of the protein structure with the program DISMAN followed by restrained energy minimization with a modified version of the program AMBER. A group of 19 conformers characterizes a well-defined structure for residues 7 to 59, with an average root-mean-square distance from the backbone atoms of 0.6 A relative to the mean of the 19 structures. The structure contains a helix from residues 10 to 21, a helix-turn-helix motif from residues 28 to 52, which is similar to those reported for several prokaryotic repressor proteins, and a somewhat flexible fourth helix from residues 53 to 59, which essentially forms an extension of the presumed recognition helix, residues 42 to 52. The helices enclose a structurally well-defined molecular core of hydrophobic amino acid side-chains.

Unfolding/refolding studies of smooth muscle tropomyosin. Evidence for a chain exchange mechanism in the preferential assembly of the native heterodimer

The thermal and the urea-induced unfolding profiles of the coiled-coil alpha-helix of native and refolded tropomyosin from chicken gizzard were studied by circular dichroism. Refolding of tropomyosin at low temperature from alpha + beta subunits, dissociated by guanidinium chloride, urea, or high temperature, predominantly produced alpha alpha + beta beta homodimers in agreement with earlier studies of refolding from guanidinium chloride (Graceffa, P. (1989) Biochemistry 28, 1282-1287). The presence of two unfolding transitions in low salt solutions with about equal helix loss verified the composition with the first unfolding transition of the homodimer mixture originating from alpha alpha. In contrast, refolding by equilibrating at temperatures close to physiological, however, produced the native alpha beta heterodimer, which unfolded in a single transition. The refolding kinetics of dissociated alpha + beta subunits indicated that beta beta homodimers form first, leading to alpha alpha homodimers both of which are relatively stable against chain exchange below approximately 25 degrees C. Equilibrating the homodimer mixture at 37-40 degrees C for long times, however, produced the native alpha beta molecule via chain exchange. The equilibria involved indicate that the free energy of formation from subunits of alpha beta is much less than that of (alpha alpha + beta beta)/2. In vivo folding of alpha beta from the two separate alpha and beta gene products is, therefore, thermodynamically favored over the formation of homodimers and biological factors need not be considered to explain the native preferred alpha beta composition.