Richard B. Cooley scite author profile

Bioorthogonal ligation methods with improved reaction rates and less obtrusive components are needed for site-specifically labeling proteins without catalysts. Currently no general method exists for in vivo site-specific labeling of proteins that combines fast reaction rate with stable, nontoxic and chemoselective reagents. To overcome these limitations we have developed a tetrazine-containing amino acid, 1, that is stable inside living cells. We have site-specifically genetically encoded this unique amino acid in response to an amber codon allowing a single 1 to be placed at any location in a protein. We have demonstrated that protein containing 1 can be ligated to a conformationally strained trans-cyclooctene, 2, in vitro and in vivo with reaction rates significantly faster than most commonly used labeling methods.

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Evolutionary Origin of a Secondary Structure: π-Helices as Cryptic but Widespread Insertional Variations of α-Helices That Enhance Protein Functionality

Cooley

Arp

Karplus

2010

Journal of Molecular Biology

159

180

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Formally annotated π-helices are rare in protein structure but have been correlated with functional sites. Here, we analyze protein structures to show that π-helices are the same as structures known as α-bulges, α-aneurisms, π-bulges, and looping-outs and are evolutionarily derived by the insertion of a single residue into an α-helix. This newly discovered evolutionary origin explains both why π-helices are cryptic, being rarely annotated despite occurring in 15% of known proteins, and why they tend to be associated with function. An analysis of the π-helices in the diverse ferritin-like superfamily illustrates their tendency to be conserved in protein families, and identifies a putative π-helix-containing primordial precursor, a “missing link” intermediary form of the ribonucleotide reductase family, vestigial π-helices, and a novel function for π-helices we term peristaltic-like shifts. This new understanding of π-helices paves the way for this generally overlooked motif to become a noteworthy feature that will aid tracing the evolution of many protein families, guide investigations of protein and π-helix functionality, and contribute additional tools to the protein engineering toolkit.

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Cysteine Dioxygenase Structures from pH4 to 9: Consistent Cys-Persulfenate Formation at Intermediate pH and a Cys-Bound Enzyme at Higher pH

Driggers

Cooley

Sankaran

et al. 2013

Journal of Molecular Biology

134

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Mammalian cysteine dioxygenase (CDO) is a mononuclear non-heme iron protein that catalyzes the conversion of cysteine (Cys) to cysteine sulfinic acid (CSA) by an unclarified mechanism. One structural study revealed a Cys-persulfenate (or Cys-persulfenic acid) formed in the active site, but quantum mechanical calculations have been used to support arguments that it is not an energetically feasible reaction intermediate. Here, we report a series of high-resolution structures of CDO soaked with Cys at pH values from 4 to 9. Cys binding is minimal at pH≤5 and persulfenate formation is consistently seen at pH values between 5.5 and 7. Also, a structure determined using laboratory-based X-ray diffraction shows that the persulfenate, with an apparent average O-O separation distance of ~1.8 Å is not an artifact of synchrotron radiation. At pH≥8, the active site iron shifts from 4- to 5-coordinate, and Cys soaks reveal a complex with Cys, but no dioxygen, bound. This ‘Cys-only’ complex differs in detail from a previously published ‘Cys-only’ complex which we reevaluate and conclude is not reliable. The high-resolution structures presented here do not resolve the CDO mechanism, but do imply that an iron-bound persulfenate (or persulfenic acid) is energetically accessible in the CDO active site, and that CDO active site chemistry in the crystals is influenced by protonation/deprotonation events with effective pKa values near ~5.5 and ~7.5 that influence Cys binding and oxygen binding/reactivity, respectively. Furthermore, this work provides reliable ligand-bound models for guiding future mechanistic considerations.

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A Highly Versatile Expression System for the Production of Multiply Phosphorylated Proteins

et al. 2019

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Genetic Code Expansion (GCE) can use TAG stop codons to guide site-specific incorporation of phosphoserine (pSer) into proteins. To eliminate prematurely truncated peptides, improve yields, and enhance the production of multiphosphorylated proteins, Release Factor 1 (RF1)-deficient expression hosts were developed, yet these grew slowly and their use was associated with extensive misincorporation of natural amino acids instead of pSer. Here, we merge a healthy RF1-deficient E. coli cell line with a highefficiency pSer GCE translation system to produce a versatile pSer GCE platform in which only trace misincorporation of natural amino acids is detected even when five phosphoserines were introduced into one protein. Approximately 400 and 200 mg of singly and doubly phosphorylated GFP per liter of culture were obtained. Importantly, the lack of truncated protein permits expression of oligomeric proteins and the use of N-terminal solubility-enhancing proteins to aid phospho-protein expression and purification. To illustrate the enhanced utility of this system, we produce doubly phosphorylated STING (Stimulator of Interferon Genes), as well as triply phosphorylated BAD (Bcl2-associated agonist of cell death) complexed with 14−3−3, in quantity, purity, and homogeneity sufficient for structural biology applications. We anticipate that the facile access to phosphoproteins enabled by this system, which we call pSer-3.1G, will expand studies of the phospho-proteome.

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Richard B. Cooley

Genetically Encoded Tetrazine Amino Acid Directs Rapid Site-Specific in Vivo Bioorthogonal Ligation with trans-Cyclooctenes

Evolutionary Origin of a Secondary Structure: π-Helices as Cryptic but Widespread Insertional Variations of α-Helices That Enhance Protein Functionality

Cysteine Dioxygenase Structures from pH4 to 9: Consistent Cys-Persulfenate Formation at Intermediate pH and a Cys-Bound Enzyme at Higher pH

A Highly Versatile Expression System for the Production of Multiply Phosphorylated Proteins

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