Andrew W. McMillan scite author profile

The quantum yield of tryptophan (Trp) fluorescence was measured in 30 designed miniproteins (17 β-hairpins and 13 Trp-cage peptides), each containing a single Trp residue. Measurements were made in D2O and H2O to distinguish between fluorescence quenching mechanisms involving electron and proton transfer in the hairpin peptides, and at two temperatures to check for effects of partial unfolding of the Trp-cage peptides. The extent of folding of all the peptides also was measured by NMR. The fluorescence yields ranged from 0.01 in some of the Trp-cage peptides to 0.27 in some hairpins. Fluorescence quenching was found to occur by electron transfer from the excited indole ring of the Trp to a backbone amide group or the protonated side chain of a nearby histidine, glutamate, aspartate, tyrosine or cysteine residue. Ionized tyrosine side chains quenched strongly by resonance energy transfer or electron transfer to the excited indole ring. Hybrid classical/quantum mechanical molecular dynamics simulations were performed by a method that optimized induced electric dipoles separately for the ground and excited states in multiple π–π* and charge-transfer (CT) excitations. Twenty 0.5-ns trajectories in the tryptophan's lowest excited singlet π–π* state were run for each peptide, beginning by projections from trajectories in the ground state. Fluorescence quenching was correlated with the availability of a CT or exciton state that was strongly coupled to the π–π* state and that matched or fell below the π–π* state in energy. The fluorescence yields predicted by summing the calculated rates of charge and energy transfer are in good accord with the measured yields.

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Rapid and simple protein-stability screens: application to membrane proteins

Yeh

McMillan

Stowell

2006

Acta Crystallogr D Biol Cryst

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Approximately 30% of the human genome, and likewise for other genomes, encodes membrane proteins. Also, the majority of known human pharmaceutical targets are membrane proteins. As a consequence, the future success of structure-based drug-design efforts will rely heavily on membrane-protein structural information. While a number of techniques are available to determine the structure of membrane proteins, crystallographic methods (either using two-dimensional or three-dimensional crystals) have been the most productive. Nonetheless, membrane-protein structure determination using crystallographic methods has encountered at least three serious bottlenecks: protein production, purification and crystallization. While a number of crystallization strategies for membrane proteins are available today, they all must ensure that the membrane protein of interest is thermodynamically stable for crystallization to be feasible. Thermodynamic stability is so fundamental to protein crystallization that it is often overlooked experimentally. Here, simple and effective protocols for determining the relative stabilities of membrane proteins using commercially available instruments and reagents are demonstrated. The results demonstrate suitability for the rapid screening of conditions that maximize protein stability using minimal amounts of reagents and protein.

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Role of an Active Site Loop in the Promiscuous Activities of Amycolatopsis sp. T-1-60 NSAR/OSBS

McMillan

Lopez

Zhu³

et al. 2014

Biochemistry

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The o-succinylbenzoate synthase (OSBS) family is part of the functionally diverse enolase superfamily. Many proteins in one branch of the OSBS family catalyze both OSBS and N-succinylamino acid racemization in the same active site. In some promiscuous NSAR/OSBS enzymes, NSAR activity is biologically significant in addition to or instead of OSBS activity. Identifying important residues for each reaction could provide insight into how proteins evolve new functions. We have made a series of mutations in Amycolatopsis sp. T-1-60 NSAR/OSBS in an active site loop, referred to as the 20s loop. This loop affects substrate specificity in many members of the enolase superfamily but is poorly conserved within the OSBS family. Deletion of this loop decreased OSBS and NSAR catalytic efficiency by 4500-fold and 25,000-fold, respectively, showing that it is essential. Most point mutations had small effects, changing the efficiency of both NSAR and OSBS activities <10-fold compared to that of the wild type. An exception was F19A, which reduced kcat/KM(OSBS) 200-fold and kcat/KM(NSAR) 120-fold. Mutating the surface residue R20E, which can form a salt bridge to help close the 20s loop over the active site, had a more modest effect, decreasing kcat/KM of OSBS and NSAR reactions 32- and 8-fold, respectively. Several mutations increased KM of the NSAR reaction more than that of the OSBS reaction. Thus, both activities require the 20s loop, but differences in how mutations affect OSBS and NSAR activities suggest that some substitutions in this loop made a small contribution to the evolution of NSAR activity, although additional mutations were probably required.

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Comparison of Alicyclobacillus acidocaldarius o-Succinylbenzoate Synthase to Its Promiscuous N-Succinylamino Acid Racemase/o-Succinylbenzoate Synthase Relatives

et al. 2018

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Studying the evolution of catalytically promiscuous enzymes like those from the N-succinylamino acid racemase/ o-succinylbenzoate synthase (NSAR/OSBS) subfamily can reveal mechanisms by which new functions evolve. Some enzymes in this subfamily have only OSBS activity, while others catalyze OSBS and NSAR reactions. We characterized several NSAR/OSBS subfamily enzymes as a step toward determining the structural basis for evolving NSAR activity. Three enzymes were promiscuous, like most other characterized NSAR/OSBS subfamily enzymes. However, Alicyclobacillus acidocaldarius OSBS (AaOSBS) efficiently catalyzes OSBS activity but lacks detectable NSAR activity. Competitive inhibition and molecular modeling show that AaOSBS binds N-succinylphenylglycine with moderate affinity in a site that overlaps its normal substrate. On the basis of possible steric conflicts identified by molecular modeling and sequence conservation within the NSAR/OSBS subfamily, we identified one mutation, Y299I, that increased NSAR activity from undetectable to 1.2 × 10 M s without affecting OSBS activity. This mutation does not appear to affect binding affinity but instead affects k, by reorienting the substrate or modifying conformational changes to allow both catalytic lysines to access the proton that is moved during the reaction. This is the first site known to affect reaction specificity in the NSAR/OSBS subfamily. However, this gain of activity was obliterated by a second mutation, M18F. Epistatic interference by M18F was unexpected because a phenylalanine at this position is important in another NSAR/OSBS enzyme. Together, modest NSAR activity of Y299I AaOSBS and epistasis between sites 18 and 299 indicate that additional sites influenced the evolution of NSAR reaction specificity in the NSAR/OSBS subfamily.

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The V108M mutation decreases the structural stability of catechol O-methyltransferase

Rutherford

Alphandéry

McMillan

et al. 2008

Biochimica et Biophysica Acta (BBA) - Proteins and Proteomics

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