Rapid additive-free selenocystine-selenoester peptide ligation.

We describe an unprecedented reaction between peptide selenoesters and peptide dimers bearing N-terminal selenocystine that proceeds in aqueous buffer to afford native amide bonds without the use of additives. The selenocystine-selenoester ligations are complete in minutes, even at sterically hindered junctions, and can be used in concert with one-pot deselenization chemistry. Various pathways for the transformation are proposed and probed through a combination of experimental and computational studies. Our new reaction manifold is also showcased in the total synthesis of two proteins.

Redesigning the PheA domain of gramicidin synthetase leads to a new understanding of the enzyme's mechanism and selectivity.

The PheA domain of gramicidin synthetase A, a non-ribosomal peptide synthetase, selectively binds phenylalanine along with ATP and Mg2+ and catalyzes the formation of an aminoacyl adenylate. In this study, we have used a novel protein redesign algorithm, K*, to predict mutations in PheA that should exhibit improved binding for tyrosine. Interestingly, the introduction of two predicted mutations to PheA did not significantly improve KD, as measured by equilibrium fluorescence quenching. However, the mutations improved the specificity of the enzyme for tyrosine (as measured by kcat/KM), primarily driven by a 56-fold improvement in KM, although the improvement did not make tyrosine the preferred substrate over phenylalanine. Using stopped-flow fluorometry, we examined binding of different amino acid substrates to the wild-type and mutant enzymes in the pre-steady state in order to understand the improvement in KM. Through these investigations, it became evident that substrate binding to the wild-type enzyme is more complex than previously described. These experiments show that the wild-type enzyme binds phenylalanine in a kinetically selective manner; no other amino acids tested appeared to bind the enzyme in the early time frame examined (500 ms). Furthermore, experiments with PheA, phenylalanine, and ATP reveal a two-step binding process, suggesting that the PheA-ATP-phenylalanine complex may undergo a conformational change toward a catalytically relevant intermediate on the pathway to adenylation; experiments with PheA, phenylalanine, and other nucleotides exhibit only a one-step binding process. The improvement in KM for the mutant enzyme toward tyrosine, as predicted by K*, may indicate that redesigning the side-chain binding pocket allows the substrate backbone to adopt productive conformations for catalysis but that further improvements may be afforded by modeling an enzyme:ATP:substrate complex, which is capable of undergoing conformational change.

Probing the role of the C-terminus of Bacillus subtilis chorismate mutase by a novel random protein-termination strategy.

A novel strategy combining random protein truncation and genetic selection has been developed to identify dispensable C-terminal segments of an enzyme. This approach, which entails the random introduction of premature termination codons, was applied to the last 17 residues of chorismate mutase from Bacillus subtilis (BsCM). Although structurally ill-defined, the C-terminus of BsCM has been proposed to cap the active site upon substrate binding and affect catalysis. However, sequence patterns of 178 selected gene variants show that the final 11 residues of the protein can be mutated and even removed without significantly impairing activity in vivo. In fact, none of the randomized residues is absolutely required, but a preference for wild-type Lys111, Ala112, Leu115, and Arg116 is apparent. These residues are part of a C-terminal 3(10)-helix and provide contacts with the rest of the protein or its ligands. The kinetic parameters of selected enzyme variants show that truncations and mutations do not significantly impair catalytic turnover (k(cat)) but substantially decrease k(cat)/K(m). Thus, while the 17 C-terminal residues of BsCM do not participate directly in the chemical rearrangement, they appear to contribute to enzymatic efficiency via uniform binding of the substrate and transition state.