Your search keyword '"Chalmers GR"' showing total 2 results

1. NMR characterization of HtpG, the E. coli Hsp90, using sparse labeling with 13 C-methyl alanine.

Author

Pederson K, Chalmers GR, Gao Q, Elnatan D, Ramelot TA, Ma LC, Montelione GT, Kennedy MA, Agard DA, and Prestegard JH

Subjects

Methylation, Models, Molecular, Protein Domains, Protein Structure, Secondary, Alanine metabolism, Carbon Isotopes metabolism, Escherichia coli Proteins metabolism, HSP90 Heat-Shock Proteins metabolism, Nuclear Magnetic Resonance, Biomolecular methods, Staining and Labeling

Abstract

A strategy for acquiring structural information from sparsely isotopically labeled large proteins is illustrated with an application to the E. coli heat-shock protein, HtpG (high temperature protein G), a 145 kDa dimer. It uses 13 C-alanine methyl labeling in a perdeuterated background to take advantage of the sensitivity and resolution of Methyl-TROSY spectra, as well as the backbone-centered structural information from 1 H- 13 C residual dipolar couplings (RDCs) of alanine methyl groups. In all, 40 of the 47 expected crosspeaks were resolved and 36 gave RDC data. Assignments of crosspeaks were partially achieved by transferring assignments from those made on individual domains using triple resonance methods. However, these were incomplete and in many cases the transfer was ambiguous. A genetic algorithm search for consistency between predictions based on domain structures and measurements for chemical shifts and RDCs allowed 60% of the 40 resolved crosspeaks to be assigned with confidence. Chemical shift changes of these crosspeaks on adding an ATP analog to the apo-protein are shown to be consistent with structural changes expected on comparing previous crystal structures for apo- and complex- structures. RDCs collected on the assigned alanine methyl peaks are used to generate a new solution model for the apo-protein structure.

Published

2017

2. NMR assignments of sparsely labeled proteins using a genetic algorithm.

Author

Gao Q, Chalmers GR, Moremen KW, and Prestegard JH

Subjects

Animals, Binding Sites, Carbon Isotopes, Humans, Nerve Tissue Proteins chemistry, Nitrogen Isotopes, Proteins chemistry, Receptors, Immunologic chemistry, Roundabout Proteins, Algorithms, Glycoproteins chemistry, Isotope Labeling, Nuclear Magnetic Resonance, Biomolecular methods

Abstract

Sparse isotopic labeling of proteins for NMR studies using single types of amino acid ( 15 N or 13 C enriched) has several advantages. Resolution is enhanced by reducing numbers of resonances for large proteins, and isotopic labeling becomes economically feasible for glycoproteins that must be expressed in mammalian cells. However, without access to the traditional triple resonance strategies that require uniform isotopic labeling, NMR assignment of crosspeaks in heteronuclear single quantum coherence (HSQC) spectra is challenging. We present an alternative strategy which combines readily accessible NMR data with known protein domain structures. Based on the structures, chemical shifts are predicted, NOE cross-peak lists are generated, and residual dipolar couplings (RDCs) are calculated for each labeled site. Simulated data are then compared to measured values for a trial set of assignments and scored. A genetic algorithm uses the scores to search for an optimal pairing of HSQC crosspeaks with labeled sites. While none of the individual data types can give a definitive assignment for a particular site, their combination can in most cases. Four test proteins previously assigned using triple resonance methods and a sparsely labeled glycosylated protein, Robo1, previously assigned by manual analysis, are used to validate the method and develop a criterion for identifying sites assigned with high confidence.

Published

2017