Cloning and sequencing of hen magnum cDNAs encoding vitelline membrane outer layer protein I (VMO-I).

Two cDNAs encoding hen vitelline membrane outer layer protein I (VMO-I), which is classified as a new type of multi-beta-sheet assembly, were cloned and sequenced. Northern blot analysis using vmo-I cDNA as a probe showed the presence of three mRNA species. Strikingly, expression of these mRNAs was restricted to a specific region of the hen oviduct, the area joining the infundibulum to the magnum.

A common ancestry for multiple catalytic antibodies generated against a single transition-state analog.

Immunization with a single haptenic transition-state analog generates a few catalytic antibodies among the dozens of antibodies capable of binding the hapten. The diversity of the immune response has raised some fundamental issues, such as How do catalytic and noncatalytic antibodies differ on a structural basis? To address this issue, the variable region primary sequences of 11 antibodies (including 6 catalytic and 5 noncatalytic antibodies) elicited against a single haptenic transition-state analog were deduced from cDNA sequences. Cluster analyses using phylogenetic trees constructed by the neighbor-joining method have revealed that the amino acid sequences of noncatalytic antibodies bear no relationship to one another, while the catalytic antibodies share significant structural identity.

Biological meaning, statistical significance, and classification of local spatial similarities in nonhomologous proteins.

We have completed an exhaustive search for the common spatial arrangements of backbone fragments (SARFs) in nonhomologous proteins. This type of local structural similarity, incorporating short fragments of backbone atoms, arranged not necessarily in the same order along the polypeptide chain, appears to be important for protein function and stability. To estimate the statistical significance of the similarities, we have introduced a similarity score.

Prediction of the structural similarity between spermidine/putrescine-binding protein and maltose-binding protein.

A structural similarity between spermidine/putrescine-binding protein and maltose-binding protein has been predicted by a sequence-structure compatibility method. The sequence alignment obtained by this method revealed a consensus sequence motif located on the surface loop between the first alpha-helix and the second beta-strand, and the further analysis identified a similar motif in iron-binding protein. The conservation of this motif among certain bacterial periplasmic binding proteins suggests a common functional role for this region as well as an evolutionary relationship between them.

Individual ionization constants of all the carboxyl groups in ribonuclease HI from Escherichia coli determined by NMR.

All of the individual carboxyl groups (the side-chain carboxyl groups of Asp and Glu, and the C-terminal alpha-carboxyl group) in Escherichia coli ribonuclease HI, which is an enzyme that cleaves the RNA strand of a RNA/DNA hybrid, were pH-titrated, and their ionization constants (pKa) were determined from an analysis of the pH-dependent chemical shifts of the carboxyl carbon resonances obtained from 1H-13C heteronuclear two-dimensional NMR. The pKa values in the enzyme varied widely among individual residues, for example, in the unusual pKa values for two important catalytic residues, Asp10 (pKa 6.1) and Asp70 (pKa 2.

Thermodynamic characterization of an artificially designed amphiphilic alpha-helical peptide containing periodic prolines: observations of high thermal stability and cold denaturation.

To investigate the structural stability of proteins, we analyzed the thermodynamics of an artificially designed 30-residue peptide. The designed peptide, NH2-EELLPLAEALAPLLEALLPLAEALAPLLKK-COOH (PERI COIL-1), with prolines at i + 7 positions, forms a pentameric alpha-helical structure in aqueous solution. The thermal denaturation curves of the CD at 222 nm (pH 7.

De novo design and creation of a stable artificial protein.

Protein de novo design has been performed, as an exercise of the inverse folding problem. A beta/alpha-barrel protein was designed and synthesized using the Escherichia coli expression system for the structural characterization. A tertiary model with a two-fold symmetry was built, based upon the geometrical parameters extracted from X-ray crystal structures of several beta/alpha-barrel proteins.

Dynamic structure of human lysozyme derived from X-ray crystallography: normal mode refinement.

X-ray crystallography provides a wealth of information about the dynamic as well as static protein structure. A new method of dynamic structure refinement of protein X-ray crystallography, normal mode refinement, is proposed. In this method, the Debye-Waller factor is expanded in terms of the low-frequency internal normal modes and external normal modes, whose amplitudes and couplings are optimized in the process of crystallographic refinement.

Site-specific O-glycosylation of cell adhesive lysozyme in yeast.

The cell adhesive protein RGD8 has been constructed using a yeast expression system by inserting eight amino acid residues (TGRGDSPA) between Val74 and Asn75 of human lysozyme [Yamada et al. (1993) J. Biol.

Processing and secretion of human growth hormone with an artificial signal sequence.

We examined the secretion of human growth hormone in yeast cells with the artificial signal sequence L8LP, which is functional for human lysozyme secretion. The precursor was cleaved efficiently and the mature protein was secreted into the periplasmic space, but the protein aggregated. These results suggest that L8LP is also functional for human growth hormone.

Protein disulfide isomerase associates with misfolded human lysozyme in vivo.

Wild-type human lysozyme (hLZM) is quantitatively secreted into the media when expressed in mouse fibroblast cells, but some misfolded hLZMs are retained and rapidly degraded in a pre-Golgi compartment (Omura, F., Otsu, M., Yoshimori, T.

Crystal structure of vitelline membrane outer layer protein I (VMO-I): a folding motif with homologous Greek key structures related by an internal three-fold symmetry.

The crystal structure of vitelline membrane outer layer protein I (VMO-I), which is isolated from the vitelline membrane outer layer of hen's eggs, has been determined by the multiple isomorphous replacement method and refined to an R-factor of 18.8% at 2.2 A resolution.

Investigating the role of conserved residue Asp134 in Escherichia coli ribonuclease HI by site-directed random mutagenesis.

The role of the conserved Asp134 residue in Escherichia coli ribonuclease HI, which is located at the center of the alpha V helix and lies close to the active site, was analyzed by means of site-directed random mutagenesis. Mutant rnhA genes encoding proteins with ribonuclease H activities were screened by their ability to suppress the ribonuclease-H-dependent, temperature-sensitive growth phenotype of E. coli strain MIC3001.

Characteristics of a de novo designed protein.

A series of 204 amino acid proteins intended to form TIM (triose phosphate isomerase) barrel structures were designed de novo. Each protein was synthesized by expression of the synthetic gene as a fusion protein with a portion of human growth hormone in an Escherichia coli host. After BrCN treatment, the protein was purified to homogeneity.

Solution structure of a de novo helical protein by 2D-NMR spectroscopy.

The de novo design of proteins represents a critical test for our knowledge of protein structure. However, no structure of a successfully designed protein has yet been reported. This paper reports the design and the tertiary structure of a de novo 35-residue helix-loop-helix protein (ALIN), with helices arranged in an anti-parallel manner.

Sequence-specific cleavage of RNA by a hybrid ribonuclease H.

Site-specific cleavage of the 22-, 132- and 534-base RNAs by the DNA/protein hybrid RNase H were examined. The 22-base RNA was chemically synthesized, and 132- and 534-base RNAs were prepared by run-off transcription. The hybrid enzyme cleaves these RNAs, which contain a single target sequence, primarily at the unique phosphodiester bond within the target sequence.

Involvement of two sulfur atoms of protein disulfide isomerase and one sulfur atom of the DsbA/PpfA protein in the oxidation of mutant human lysozyme.

Protein disulfide isomerase (PDI) and the DsbA/PpfA protein catalyze the oxidation of mutant human lysozyme, L79CC81A, which has two native disulfide bonds, Cys6-Cys128 and Cys30-Cys116, a non-native Cys79-Cys95, and 2 free cysteine residues at positions 65 and 77. Oxidation of L79CC81A (R-form) yielded two isomers, L79CC81A-a (A-form) with tandem-linked Cys65-Cys77 and Cys79-Cys95, and L79CC81A-b (B-form) with cross-linked Cys65-Cys79 and Cys77-Cys95 (Kanaya, E., Ishihara, K.