Matthew Rosenow scite author profile

The crystal structure of a colorless variant of green fluorescent protein (GFP) containing the Y66L substitution has been determined to 1.5 A. Crystallographic evidence is presented for the formation of a trapped intermediate on the pathway of chromophore maturation, where the peptide backbone of residues 65-67 has condensed to form a five-membered heterocyclic ring. The hydroxyl leaving group remains attached to the ring as confirmed by high-resolution electrospray mass spectrometry. The alpha-carbon of residue 66 exhibits trigonal planar geometry, consistent with ring oxidation by molecular oxygen. Side chain positions of surrounding residues are not perturbed, in contrast to structural results obtained for the GFPsol-S65G/Y66G variant [Barondeau, D. P., Putnam, C. D., Kassmann, C. J., Tainer, J. A., and Getzoff, E. D. (2003) Proc. Natl. Acad. Sci. U.S.A. 100, 12111-12116]. The data are in accord with a reaction pathway in which dehydration is the last of three chemical steps in GFP chromophore formation. A novel mechanism for chromophore biosynthesis is proposed: when the protein folds, the backbone condenses to form a cyclopentyl tetrahedral intermediate. In the second step, the ring is oxidized by molecular oxygen. In the third and final step, elimination of the hydroxyl leaving group as water is coupled to a proton transfer reaction that may proceed via hydrogen-bonded solvent molecules. Replacement of the aromatic Tyr66 with an aliphatic residue appears to have a profound effect on the efficiency of ring dehydration. The proposed mechanism has important implications for understanding the factors that limit the maturation rate of GFP.

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Sperm Proteome Maturation in the Mouse Epididymis

Skerget

Rosenow

Pétritis

et al. 2015

PLoS ONE

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In mammals, transit through the epididymis, which involves the acquisition, loss and modification of proteins, is required to confer motility and fertilization competency to sperm. The overall dynamics of maturation is poorly understood, and a systems level understanding of the complex maturation process will provide valuable new information about changes occurring during epididymal transport. We report the proteomes of sperm collected from the caput, corpus and cauda segments of the mouse epididymis, identifying 1536, 1720 and 1234 proteins respectively. This study identified 765 proteins that are present in sperm obtained from all three segments. We identified 1766 proteins that are potentially added (732) or removed (1034) from sperm during epididymal transit. Phenotypic analyses of the caput, corpus and cauda sperm proteomes identified 60 proteins that have known sperm phenotypes when mutated, or absent from sperm. Our analysis indicates that as much as one-third of proteins with known sperm phenotypes are added to sperm during epididymal transit. GO analyses revealed that cauda sperm are enriched for specific functions including sperm-egg recognition and motility, consistent with the observation that sperm acquire motility and fertilization competency during transit through the epididymis. In addition, GO analyses revealed that the immunity protein profile of sperm changes during sperm maturation. Finally, we identified components of the 26S proteasome, the immunoproteasome, and a proteasome activator in mature sperm.

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Structural Insights into the Evolution of a Non-Biological Protein: Importance of Surface Residues in Protein Fold Optimization

Smith

Rosenow²,

Wang³

et al. 2007

PLoS ONE

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Phylogenetic profiling of amino acid substitution patterns in proteins has led many to conclude that most structural information is carried by interior core residues that are solvent inaccessible. This conclusion is based on the observation that buried residues generally tolerate only conserved sequence changes, while surface residues allow more diverse chemical substitutions. This notion is now changing as it has become apparent that both core and surface residues play important roles in protein folding and stability. Unfortunately, the ability to identify specific mutations that will lead to enhanced stability remains a challenging problem. Here we discuss two mutations that emerged from an in vitro selection experiment designed to improve the folding stability of a non-biological ATP binding protein. These mutations alter two solvent accessible residues, and dramatically enhance the expression, solubility, thermal stability, and ligand binding affinity of the protein. The significance of both mutations was investigated individually and together, and the X-ray crystal structures of the parent sequence and double mutant protein were solved to a resolution limit of 2.8 and 1.65 Å, respectively. Comparative structural analysis of the evolved protein to proteins found in nature reveals that our non-biological protein evolved certain structural features shared by many thermophilic proteins. This experimental result suggests that protein fold optimization by in vitro selection offers a viable approach to generating stable variants of many naturally occurring proteins whose structures and functions are otherwise difficult to study.

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Oxidative Chemistry in the GFP Active Site Leads to Covalent Cross-Linking of a Modified Leucine Side Chain with a Histidine Imidazole: Implications for the Mechanism of Chromophore Formation^,

2005

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The mechanism of chromophore biosynthesis in green fluorescent protein (GFP) is triggered by a spontaneous main chain cyclization reaction of residues 65-67. Here, we demonstrate that the initially colorless Y66L variant, designed to trap chromophore precursor states, is oxidatively modified to generate yellow chromophores that absorb at 412 and 374 nm. High- and low-pH crystal structures determined to 2.0 and 1.5 A resolution, respectively, are consistent with pi-orbital conjugation of a planar Leu66-derived adduct with the imidazolinone ring, which is approximately 90 and 100% dehydrated, respectively. Time-, base-, and oxygen-dependent optical properties suggest that the yellow chromophores are generated from a 338 nm-absorbing intermediate, interpreted to be the Y66L analogue of the wild-type GFP chromophore. Generation of this species is catalyzed by a general base such as formate, and proceeds via a cyclization-oxidation-dehydration mechanism. The data suggest that a hydration-dehydration equilibrium exists in the cyclic form of the peptide, and that dehydration is favored upon extensive conjugation with the modified side chain. We conclude that the mechanism of GFP chromophore biosynthesis is not driven by the aromatic character of residue 66. In the low-pH X-ray structure, a highly unusual cross-link is observed between His148 and the oxidized Leu66 side chain, suggesting a conjugate addition reaction of the imidazole nitrogen to the highly electrophilic diene group of the yellow chromophore. The reactivity described here further expands the chemical diversity observed in the active site of GFP-like proteins, and may allow for covalent attachment of functional groups to the protein scaffold for catalytic purposes.

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The Old and the New: Discovery Proteomics Identifies Putative Novel Seminal Fluid Proteins in Drosophila

Karr

Southern

Rosenow

et al. 2019

Molecular & Cellular Proteomics

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We used discovery, bottom up proteomics to provide the first in-depth accessory gland proteome in D. pseudoobscura. Computational bioinformatics identified Ͼ500 proteins in the secretory pathway of which 163 were annotated as extracellular., and therefore candidate, seminal fluid proteins. We further compared molecular rates of evolution between intra-and extracellular proteins, showing a hierarchy of rapid evolution with putative seminal fluid proteins evolving more rapidly than other secreted proteins, and those proteins evolving more rapidly than intra-cellular proteins. Graphical Abstract Highlights• First deep proteomic coverage of an accessory gland proteome in Drosophila.• Discovery proteomics identified Ͼ3000 proteins of the D. pseudoobscura accessory gland proteome.• Identified 132 putative novel seminal fluid proteins in this species.• Demonstrated the exoproteome as the most rapidly evolving subcellular component of the proteome.

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Matthew Rosenow

The Crystal Structure of the Y66L Variant of Green Fluorescent Protein Supports a Cyclization−Oxidation−Dehydration Mechanism for Chromophore Maturation^,

Sperm Proteome Maturation in the Mouse Epididymis

Structural Insights into the Evolution of a Non-Biological Protein: Importance of Surface Residues in Protein Fold Optimization

Oxidative Chemistry in the GFP Active Site Leads to Covalent Cross-Linking of a Modified Leucine Side Chain with a Histidine Imidazole: Implications for the Mechanism of Chromophore Formation^,

The Old and the New: Discovery Proteomics Identifies Putative Novel Seminal Fluid Proteins in Drosophila

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Matthew Rosenow

The Crystal Structure of the Y66L Variant of Green Fluorescent Protein Supports a Cyclization−Oxidation−Dehydration Mechanism for Chromophore Maturation,

Sperm Proteome Maturation in the Mouse Epididymis

Structural Insights into the Evolution of a Non-Biological Protein: Importance of Surface Residues in Protein Fold Optimization

Oxidative Chemistry in the GFP Active Site Leads to Covalent Cross-Linking of a Modified Leucine Side Chain with a Histidine Imidazole: Implications for the Mechanism of Chromophore Formation,

The Old and the New: Discovery Proteomics Identifies Putative Novel Seminal Fluid Proteins in Drosophila

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Product

Resources

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The Crystal Structure of the Y66L Variant of Green Fluorescent Protein Supports a Cyclization−Oxidation−Dehydration Mechanism for Chromophore Maturation^,

Oxidative Chemistry in the GFP Active Site Leads to Covalent Cross-Linking of a Modified Leucine Side Chain with a Histidine Imidazole: Implications for the Mechanism of Chromophore Formation^,