Vapor-phase modification of sulfhydryl groups in proteins

Proteins and peptides are readily and specifically modified at their sulfhydryl groups by the vapors of a mixture of 4-vinylpyridine and tributylphosphine. The phenylthiohydantoin derivative of S-beta-(4-pyridylethyl)cysteine formed during sequence analysis is easily detectable in current identification systems.     

In vitro amplification of protease-resistant prion protein requires free sulfhydryl groups

Prions, the infectious agents of transmissible spongiform encephalopathies, are composed primarily of a misfolded protein designated PrP(Sc). Prion-infected neurons generate PrP(Sc) from a host glycoprotein designated PrP(C) through a process of induced conformational change, but the molecular mechanism by which PrP(C) undergoes conformational change into PrP(Sc) remains unknown. We employed an in vitro PrP(Sc) amplification technique adapted from protein misfolding cyclic amplification (PMCA) to investigate the mechanism of prion-induced protein conformational change. Using this technique, PrP(Sc) from diluted scrapie-infected brain homogenate can be amplified >10-fold without sonication when mixed with normal brain homogenate under nondenaturing conditions. PrP(Sc) amplification in vitro exhibits species and strain specificity, depends on both time and temperature, only requires membrane-bound components, and does not require divalent cations. In vitro amplification of Syrian hamster Sc237 PrP(Sc) displays an optimum pH of approximately 7, whereas amplification of CD-1 mouse RML PrP(Sc) is optimized at pH approximately 6. The thiolate-specific alkylating agent N-ethylmaleimide (NEM) as well as the reversible thiol-specific blockers p-hydroxymercuribenzoic acid (PHMB) and mersalyl acid inhibited PrP(Sc) amplification in vitro, indicating that the conformational change from PrP(C) to PrP(Sc) requires a thiol-containing factor. Our data provide the first evidence that a reactive chemical group plays an essential role in the conformational change from PrP(C) to PrP(Sc).     

2-Vinylquinoline, a reagent to determine protein sulfhydryl groups spectrophotometrically

A reagent has been sought for the selective derivatization of protein sulfhydryl groups that will allow the spectrophotometric determination of the cysteine and cystine content of intact proteins. 2-Vinylquinoline appears to be that reagent. Protein sulfhydryl groups were reacted with 2-vinylquinoline to yield the protein-linked S-2-(2-quinolylethyl)-l-cysteine (Qe-cysteine). After urea and other excess reagents were removed, the modified proteins were examined spectrophotometrically. The extinction coefficient (10,000) and absorption maximum (318 mμ) of the protein-linked vinylquinoline derivatives were identical to those of the model Qe-cysteine. Optimum conditions for the reaction require an equimolar concentration of 2-vinylquinoline to all sulfhydryls and a 4 hr reaction period. The total cysteine and cysteine contents of the proteins, when determined under these conditions, were in excellent agreement with standard literature values.     

Assay of sulfhydryl groups in cardiac myofibrillar proteins: effect of oxygen radicals in vitro

Myofibrils from rat hearts were prepared in conditions maintaining their redox state, and their sulfhydryl groups were measured using a solution of urea and sodium dodecyl sulfate (SDS) as denaturant. The sulfhydryl content was 92 n mol/mg of protein, indicating that cysteins are in reduced form. In the presence of superoxide radicals generated in vitro with purine and xanthine oxidase, the myofibrillar sulfhydryl groups were oxidized.     

Synthesis and application of two reagents for the introduction of sulfhydryl groups into proteins

Two reagents are described which can be used for the introduction of sulfhydryl groups into proteins. Mercaptopropionylhydrazide modifies specifically periodate-oxidized N termini of proteins, provided that the N-terminal residue is serine or threonine. 3-(Phenyldithio)propionimidate introduces a disulfide bond at lysine residues of proteins. Reduction converts the disulfide into a sulfhydryl group. The imidate compound was found to react with a high specificity with only one lysine residue of ribosomal protein L7/L12.     

Fluorimetric determination of sphingosine and its application to natural mixtures of glycosphingolipids

A sensitive estimation of sphingosine, by measurement of the fluorescence of a complex formed with 1-naphthylamino-4-sulfonic acid, is described. The practical range is 5-35 nmoles sphingosine. The method is used to estimate, in terms of sphingosine, amounts of ceramide and glycosphingolipids. The isolation of microamounts (5-30 micro g) of individual glycosphingolipids from a mixture, and their quantitative estimation is described. The percentage composition of a glycosphingolipid mixture from the kidneys of adult C57/BL male mice is given.     

Reaction of S-nitrosoglutathione with sulfhydryl groups in protein

The covalent modification of sulfhydryl groups by S-nitrosoglutathione has been examined using model compounds. S-Nitrosoglutathione and thiol compounds causing extremely fast transnitrosation reaction and subsequent production of mixed disulfide. Yeast alcohol dehydrogenase is rapidly inactivated by S-nitrosoglutathione. The reversibility and Ellman test demonstrate that the inactivation is the result of covalent modification of sulfhydryl groups in this enzyme.     

A sensitive gel filtration method for determination of protein sulfhydryl groups with 14C-chloromercuribenzoate

A gel filtration method employing ¹⁴C-chloromercuribenzoic acid is described for the quantitative determination of sulfhydryl groups in microgram quantities of protein. The method has been applied to several native proteins, hemoglobin, monoamine oxidase, and yeast cytochrome c. In all cases values in close agreement with known literature values were obtained. Horse heart cytochrome c and lysozyme, which have no sulfhydryl groups, did not bind the mercurial reagent. Modifications of the method are described for determining the sulfhydryl content of denatured proteins in the presence of sodium lauryl sulfate. The precision of the method was found to be compatible with known methods for determining the sulfhydryl composition of proteins.     

Detergent quantification in membrane protein samples and its application to crystallization experiments

The structural characterization of membrane proteins remains a challenging field, largely because the use of stabilizing detergents is required. Researchers must first select a suitable detergent for the solubility and stability of their protein during in vitro studies. In addition, an appropriate concentration of detergent in membrane protein samples can be essential for protein solubility, stability, and experimental success. For example, in membrane protein crystallography, detergent concentration in the crystallization drop can be a critical parameter influencing crystal growth. Over the past decade, multiple techniques have been developed for the measurement of detergent concentration using a wide variety of strategies. These methods include colorimetric reactions, which target specific detergent classes, and analytical techniques applicable to a wide variety of detergents. This review will summarize and discuss the available options. It will be a useful resource to those selecting a strategy that best fits their experimental requirements and available instruments.     

Development of a liquid chromatography method for the determination of linezolid and its application to in vitro and human microdialysis samples

Linezolid is a new, promising antibacterial agent to treat severe infections. A rapid HPLC assay using UV detection for the determination in microdialysate and human plasma was developed. After sample preparation, using acetonitrile for plasma and water for microdialysate, 20 microl was injected and separated on a RP-18 column. Overall, the assay exhibited good precision and accuracy. The diffusion properties of linezolid investigated in in vitro microdialysis experiments revealed a mean relative recovery of 77.5% (CV: 5.4%; delivery and recovery experiments). Following characterization of linezolid in in vitro microdialysis, the setting is suitable for application in clinical studies.