H. Tonie Wright

Nonenzymatic Deamidation of Asparaginyl and Glutaminyl Residues in Protein

Some asparagine and glutamine residues in proteins undergo deamidation to aspartate and glutamate with rates that depend upon the sequence and higher-order structure of the protein. Functional groups within the protein can catalyze this reaction, acting as general acids, bases, or stabilizers of the transition state. Information from specific proteins that deamidate and analysis of protein sequence and structure data bases suggest that asparagine and glutamine lability has been a selective pressure in the evolution of protein sequence and folding. Asparagine and glutamine deamidation can affect protein structure and function in natural and engineered mutant sequences, and may play a role in the regulation of protein folding, protein breakdown, and aging.

Crystal structure of plakalbumin, a proteolytically nicked form of ovalbumin

The crystal structure of plakalbumin, a proteolytically nicked form of ovalbumin, has been determined to a resolution of 2.8 A by the isomorphous replacement method and preliminary refinement. The structure closely resembles that of the cleaved form of alpha-1-proteinase inhibitor, with some important exceptions. The disposition of the new carboxyl chain terminus liberated by proteolysis is different with respect to the central beta-sheet A in the structures of these two molecules. In alpha-1-proteinase inhibitor, the new chain terminus inserts in beta-sheet A to add a middle strand to the sheet. In plakalbumin, this strand remains free near the site at which the cleavage occurs. A structural basis for this difference in behavior is proposed from the structures and sequences of these two molecules and other members of the serpin family. The structures and positions of the putative signal peptide of ovalbumin, the several post-translational modifications, and the relationship of the intron-exon patterns of plakalbumin and alpha-1-proteinase inhibitor to their protein structures are also described.

Evolution of a family ofN-acetylglucosamine binding proteins containing the disulfide-rich domain of wheat germ agglutinin

SummaryA disulfide-rich domain, first identified in wheat germ agglutinin, has now been identified in the amino acid and DNA sequences of a large number of other chitin-binding proteins. This 43-residue domain includes eight disulfide-linked cysteines and has been implicated in the binding ofN-acetylglucosamine and its polymers. This study used 12 complementary DNA sequences and 1 amino acid sequence of proteins with one, two, and four copies of this domain to infer a 44-amino acid residue ancestor sequence for this domain, and to derive an evolutionary tree relating these domains in the different proteins. The tree relating these single-domain sequences is divided into two major branches, one consisting of the multidomain dimeric lectins, which we have earlier suggested arose by duplication of a single copy of the disulfide-rich domain, and the other branch consisting of the monomeric chitinases and wound-inducible proteins, which have a single copy of the domain fused to a larger polypeptide. Reference to the three-dimensional structure of WGA and its saccharide complexes shows that the saccharide-binding residues as well as cysteine and glycine residues are conserved among all available sequences. In contrast, many residues at the dimer interface of the domains of WGA are not conserved in those proteins with a single domain, implying that the aggregation state of the domains in these proteins differs from that of the grass lectins. Also, the base compositions of the four-domain and one-domain branches of the tree differ, indicating distinct selective pressures at the level of both protein structure and the gene or its transcript.

Proteolytically cleaved mutant antithrombin‐Hamilton has high stability to denaturation characteristic of wild type inhibitor serpins

The serpin family of proteins consists primarily of proteinase inhibitors which form tight complexes with target proteinases. Inhibitor serpins are cleaved by proteinase and undergo a large conformational change in which the polypeptide segment terminating at the target reactive site, at which cleavage takes place, inserts itself as an additional strand, s4A, in the center of a preexisting β‐sheet. This change in conformation increases the stability towards denaturation of the cleaved serpin relative to the native uncleaved form. Mutant serpins with single amino acid changes in the s4A strand have been identified, and in most cases these are proteinase substrates but not inhibitors. We have measured the stability to denaturation of one of these non‐inhibitor substrate mutants, antithrombin‐Hamilton, which has an Ala → Thr change at position P12 in strand s4A. We find that it undergoes the transformation to the more stable form which is observed for inhibitor serpins, from which we conclude that the Ala → Thr change in antithrombin‐Hamilton does not prevent insertion of s4A into β‐sheet A in the cleaved form.

Structure-Based Mechanism for Early PLP-Mediated Steps of Rabbit Cytosolic Serine Hydroxymethyltransferase Reaction

Serine hydroxymethyltransferase catalyzes the reversible interconversion of L-serine and glycine with transfer of one-carbon groups to and from tetrahydrofolate. Active site residue Thr254 is known to be involved in the transaldimination reaction, a crucial step in the catalytic mechanism of all pyridoxal 5′-phosphate- (PLP-) dependent enzymes, which determines binding of substrates and release of products. In order to better understand the role of Thr254, we have expressed, characterized, and determined the crystal structures of rabbit cytosolic serine hydroxymethyltransferase T254A and T254C mutant forms, in the absence and presence of substrates. These mutants accumulate a kinetically stable gem-diamine intermediate, and their crystal structures show differences in the active site with respect to wild type. The kinetic and crystallographic data acquired with mutant enzymes permit us to infer that conversion of gem-diamine to external aldimine is significantly slowed because intermediates are trapped into an anomalous position by a misorientation of the PLP ring, and a new energy barrier hampers the transaldimination reaction. This barrier likely arises from the loss of the stabilizing hydrogen bond between the hydroxymethyl group of Thr254 and the ε-amino group of active site Lys257, which stabilizes the external aldimine intermediate in wild type SHMTs.

Scintillation proximity assay for measurement of RNA methylation

Methylation of RNA by methyltransferases is a phylogenetically ubiquitous post-transcriptional modification that occurs most extensively in transfer RNA (tRNA) and ribosomal RNA (rRNA). Biochemical characterization of RNA methyltransferase enzymes and their methylated product RNA or RNA–protein complexes is usually done by measuring the incorporation of radiolabeled methyl groups into the product over time. This has traditionally required the separation of radiolabeled product from radiolabeled methyl donor through a filter binding assay. We have adapted and optimized a scintillation proximity assay (SPA) to replace the more costly, wasteful and cumbersome filter binding assay and demonstrate its utility in studies of three distinct methyltransferases, RmtA, KsgA and ErmC’. In vitro, RmtA and KsgA methylate different bases in 16S rRNA in 30S ribosomal particles, while ErmC’ most efficiently methylates protein-depleted or protein-free 23S rRNA. This assay does not utilize engineered affinity tags that are often required in SPA, and is capable of detecting either radiolabeled RNA or RNA–protein complex. We show that this method is suitable for quantitating extent of RNA methylation or active RNA methyltransferase, and for testing RNA-methyltransferase inhibitors. This assay can be carried out with techniques routinely used in a typical biochemistry laboratory or could be easily adapted for a high throughput screening format.

3-Dimensional Structures of Rabbit Cytosolic and E. Coli Serine Hydroxymethyltransferase

The 3-dimensional structure of rabbit liver cytosolic serine hydroxymethyltransferase was determined in the absence of any ligands and with the external aldimine reduced to a secondary amine by sodium borohydride. The 3-dimensional structure ofE. coliserine hydroxymethyltransferase was determined as a ternary complex with glycine and 5-formyltetrahydrofolate bound at the active site. The structures were used to elucidate the role of active site residues in the mechanism of the enzyme whose properties had previously been determined by kinetic studies of site mutants.