Insights into the serine protease mechanism from atomic resolution structures of trypsin reaction intermediates.

Atomic resolution structures of trypsin acyl-enzymes and a tetrahedral intermediate analog, along with previously solved structures representing the Michaelis complex, are used to reconstruct events in the catalytic cycle of this classic serine protease. Structural comparisons provide insight into active site adjustments involved in catalysis. Subtle motions of the catalytic serine and histidine residues coordinated with translation of the substrate reaction center are seen to favor the forward progress of the acylation reaction.

Role of the intramolecular hydrogen bond network in the inhibitory power of chymotrypsin inhibitor 2.

A series of mutants of chymotrypsin inhibitor 2 (CI2), at residues involved in intramolecular interactions that shape and constrain the binding loop, were studied to determine their relative importance for inhibition of the serine protease subtilisin BPN', and for resistance of the inhibitor to proteolysis. These functional properties were investigated in tandem with the crystal structures of the mutant inhibitor-enzyme complexes. A dense hydrogen bonding network that supports the binding loop in the vicinity of the scissile bond was found to be important both for enzyme affinity and for stability to proteolysis.

Binding, proteolytic, and crystallographic analyses of mutations at the protease-inhibitor interface of the subtilisin BPN'/chymotrypsin inhibitor 2 complex.

A series of mutants of chymotrypsin inhibitor 2 (CI2), at residues that interact with the inhibited enzyme subtilisin BPN', were studied to determine the relative importance of intermolecular contacts on either side of the scissile bond. Mutants were tested for inhibition of subtilisin, rates of hydrolysis by subtilisin, and ability to acylate subtilisin. Additionally, crystal structures of the mutant CI2 complexes with subtilisin were obtained.

The role of the protein core in the inhibitory power of the classic serine protease inhibitor, chymotrypsin inhibitor 2.

A synthetic cyclic peptide, reported to be a tight-binding inhibitor of serine proteases, is instead found to be a good substrate, as is the linear peptide of the same sequence. Both of the peptides, designed to mimic the binding loop of chymotrypsin inhibitor 2 (CI2), were cleaved by subtilisin primarily at the CI2 reactive-site Met-59-Glu-60 bond, revealing that the sequence, in the absence of the structural context of the inhibitor, provides sufficient specificity for hydrolysis of this bond. Insights from the crystal structure of the CI2/subtilisin complex, together with biochemical analysis of a CI2 Gly-83 deletion mutant, have allowed us to identify key features that make CI2 an effective inhibitor, while the cyclic and linear peptides are substrates.

Structural basis of multiple drug-binding capacity of the AcrB multidrug efflux pump.

Multidrug efflux pumps cause serious problems in cancer chemotherapy and treatment of bacterial infections. Yet high-resolution structures of ligand transporter complexes have previously been unavailable. We obtained x-ray crystallographic structures of the trimeric AcrB pump from Escherichia coli with four structurally diverse ligands.

The application and usefulness of the ratio k(cat)/K(M).

The ratio of two important constituents in enzyme action, k(cat) and K(M), has become of value and provides insight into enzymatic mechanisms and the functional effects of enzyme mutations. It is timely to examine how this ratio is used and where it can be effectively applied. It has been called on some occasions the "specificity constant" and on other occasions, the "performance constant," and it is of interest to examine which then is the most accurate and useful way to utilize this ratio.

A clogged gutter mechanism for protease inhibitors.

A classical peptide inhibitor of serine proteases that is hydrolyzed approximately 10(7) times more slowly than a good substrate is shown to form an acyl-enzyme intermediate rapidly. Despite this quick first step, further reaction is slowed dramatically because of tight and oriented binding of the cleaved peptide, preventing acyl-enzyme hydrolysis and favoring the reverse reaction. Moreover, this mechanism appears to be common to a large class of tight-binding serine protease inhibitors that mimic good substrates.

Differential effects of unnatural sialic acids on the polysialylation of the neural cell adhesion molecule and neuronal behavior.

In this study we have examined how unnatural sialic acids can alter polysialic acid expression and influence the adhesive properties of the neural cell adhesion molecule (NCAM). Unnatural sialic acids are generated by metabolic conversion of synthetic N-acyl mannosamines and are typically incorporated into cell-surface glycoconjugates. However, N-butanoylmannosamine and N-pentanoylmannosamine are effective inhibitors of polysialic acid (PSA) synthesis in stably transfected HeLa cells expressing NCAM and the polysialyltransferase STX.