D.C. Boisvert scite author profile

The crystal structure of Escherichia coli GroEL shows a porous cylinder of 14 subunits made of two nearly 7-fold rotationally symmetrical rings stacked back-to-back with dyad symmetry. The subunits consist of three domains: a large equatorial domain that forms the foundation of the assembly at its waist and holds the rings together; a large loosely structured apical domain that forms the ends of the cylinder; and a small slender intermediate domain that connects the two, creating side windows. The three-dimensional structure places most of the mutationally defined functional sites on the channel walls and its outward invaginations, and at the ends of the cylinder.

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The 2.4 Å crystal structure of the bacterial chaperonin GroEL complexed with ATPγS

Boisvert

Wang

Otwinowski

et al. 1996

Nat Struct Mol Biol

254

242

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GroEL is a bacterial chaperonin of 14 identical subunits required to help fold newly synthesized proteins. The crystal structure of GroEL with ATP gamma S bound to each subunit shows that ATP binds to a novel pocket, whose primary sequence is highly conserved among chaperonins. Interaction of Mg2+ and ATP involves phosphate oxygens of the alpha-, beta- and gamma-phosphates, which is unique for known structures of nucleotide-binding proteins. Although bound ATP induces modest conformational shifts in the equatorial domain, the stereochemistry that functionally coordinates GroEL's affinity for nucleotides, polypeptide, and GroES remains uncertain.

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Structural Basis for GroEL-assisted Protein Folding from the Crystal Structure of (GroEL-KMgATP)14 at 2.0Å Resolution

Wang

Boisvert

2003

Journal of Molecular Biology

119

140

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Comparison of three different crystal forms shows HIV-1 reverse transcriptase displays an internal swivel motion

et al. 1994

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From the differences in the four RT structures we infer that the molecule has a specific flexibility that allows rotation of the polymerase active site relative to the rest of the molecule. The observed swivelling motion of RT may allow the polymerase to accommodate the rotational and translational movements of the growing nucleic acid duplex, which present an especial problem for RT because it uses an asymmetric molecule (tRNA(Ly3)) as a primer for first strand synthesis.

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SU9516: biochemical analysis of cdk inhibition and crystal structure in complex with cdk2

Moshinsky¹,

Bellamacina²,

Boisvert³

et al. 2003

Biochemical and Biophysical Research Communications

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Crystal Structure of MJ1247 Protein from M. jannaschii at 2.0 Å Resolution Infers a Molecular Function of 3-Hexulose-6-Phosphate Isomerase

et al. 2002

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The crystal structure of the hypothetical protein MJ1247 from Methanococccus jannaschii at 2 A resolution, a detailed sequence analysis, and biochemical assays infer its molecular function to be 3-hexulose-6-phosphate isomerase (PHI). In the dissimilatory ribulose monophosphate (RuMP) cycle, ribulose-5-phosphate is coupled to formaldehyde by the 3-hexulose-6-phosphate synthase (HPS), yielding hexulose-6-phosphate, which is then isomerized to fructose-6-phosphate by the enzyme 3-hexulose-6-phosphate isomerase. MJ1247 is an alpha/beta structure consisting of a five-stranded parallel beta sheet flanked on both sides by alpha helices, forming a three-layered alpha-beta-alpha sandwich. The fold represents the nucleotide binding motif of a flavodoxin type. MJ1247 is a tetramer in the crystal and in solution and each monomer has a folding similar to the isomerase domain of glucosamine-6-phosphate synthase (GlmS).

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Real-time dynamic single-molecule protein sequencing on an integrated semiconductor device

Reed

Meyer

Abramzon³

et al. 2022

Science

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Studies of the proteome would benefit greatly from methods to directly sequence and digitally quantify proteins and detect posttranslational modifications with single-molecule sensitivity. Here, we demonstrate single-molecule protein sequencing using a dynamic approach in which single peptides are probed in real time by a mixture of dye-labeled N-terminal amino acid recognizers and simultaneously cleaved by aminopeptidases. We annotate amino acids and identify the peptide sequence by measuring fluorescence intensity, lifetime, and binding kinetics on an integrated semiconductor chip. Our results demonstrate the kinetic principles that allow recognizers to identify multiple amino acids in an information-rich manner that enables discrimination of single amino acid substitutions and posttranslational modifications. With further development, we anticipate that this approach will offer a sensitive, scalable, and accessible platform for single-molecule proteomic studies and applications.

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Real-time dynamic single-molecule protein sequencing on an integrated semiconductor device

Reed

Meyer

Abramzon

et al. 2022

Preprint

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Proteins are the main structural and functional components of cells, and their dynamic regulation and post-translational modifications (PTMs) underlie cellular phenotypes. Next-generation DNA sequencing technologies have revolutionized our understanding of heredity and gene regulation, but the complex and dynamic states of cells are not fully captured by the genome and transcriptome. Sensitive measurements of the proteome are needed to fully understand biological processes and changes to the proteome that occur in disease states. Studies of the proteome would benefit greatly from methods to directly sequence and digitally quantify proteins and detect PTMs with single-molecule sensitivity and precision. However current methods for studying the proteome lag behind DNA sequencing in throughput, sensitivity, and accessibility due to the complexity and dynamic range of the proteome, the chemical properties of proteins, and the inability to amplify proteins. Here, we demonstrate single-molecule protein sequencing on a compact benchtop instrument using a dynamic sequencing by stepwise degradation approach in which single surface-immobilized peptide molecules are probed in real-time by a mixture of dye-labeled N-terminal amino acid recognizers and simultaneously cleaved by aminopeptidases. By measuring fluorescence intensity, lifetime, and binding kinetics of recognizers on an integrated semiconductor chip we are able to annotate amino acids and identify the peptide sequence. We describe the expansion of the number of recognizable amino acids and demonstrate the kinetic principles that allow individual recognizers to identify multiple amino acids in a highly information-rich manner that is sensitive to adjacent residues. Furthermore, we demonstrate that our method is compatible with both synthetic and natural peptides, and capable of detecting single amino acid changes and PTMs. We anticipate that with further development our protein sequencing method will offer a sensitive, scalable, and accessible platform for studies of the proteome.

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D.C. Boisvert

The crystal structure of the bacterial chaperonln GroEL at 2.8 Å

The 2.4 Å crystal structure of the bacterial chaperonin GroEL complexed with ATPγS

Structural Basis for GroEL-assisted Protein Folding from the Crystal Structure of (GroEL-KMgATP)14 at 2.0Å Resolution

Comparison of three different crystal forms shows HIV-1 reverse transcriptase displays an internal swivel motion

SU9516: biochemical analysis of cdk inhibition and crystal structure in complex with cdk2

Crystal Structure of MJ1247 Protein from M. jannaschii at 2.0 Å Resolution Infers a Molecular Function of 3-Hexulose-6-Phosphate Isomerase

Real-time dynamic single-molecule protein sequencing on an integrated semiconductor device

Real-time dynamic single-molecule protein sequencing on an integrated semiconductor device

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