P. S. R. Anjaneyulu scite author profile

N‐Hydroxysulfosuccinimide esters are reactive functional groups employed in a variety of protein modification reagents, especially cross‐linking reagents. For these compounds, hydrolysis is the most important reaction competing for reaction of the esters with nucleophilic groups in proteins. We have employed model compounds to investigate the rates of hydrolysis of N‐hydroxysulfosuccinimide esters and their reactions with the α‐amino group and the side chains of naturally occurring amino acids, under conditions comparable to those used for protein modification studies. The rates of hydrolysis observed were found to be very low, as compared with their rates of reaction with nitrogen nucleophiles found in proteins. Further, within the ranges investigated, the rate of aminolysis was observed to increase more rapidly than the rate of hydrolysis with increasing pH or with increasing temperature. Four amino acid side chains and the α‐amino group were found to react measurably with N‐hydroxysulfosuccinimide esters. At pH 7.4 and room temperature, the order of reactivity was found to be Nα‐Cbz‐histidine < Nα‐Cbz‐lysine ≤ phenylalanine (α‐amino group) ˜N‐acetylcysteine ˜N‐acetyltyrosine; however, the acylimidazole adduct formed with the side chain of histidine was found to be a transient product, subject to hydrolysis or reaction with another nucleophile.

show abstract

Bis(sulfo-N-succinimidyl) doxyl-2-spiro-5'-azelate: synthesis, characterization, and reaction with the anion-exchange channel in intact human erythrocytes

Anjaneyulu¹,

Beth²,

Cobb³

et al. 1989

Biochemistry

View full text Add to dashboard Cite

We have synthesized and characterized bis(sulfo-N-succinimidyl) doxyl-2-spiro-5'-azelate (BSSDA), a membrane-impermeant bifunctional spin-labeling reagent. BSSDA is a nine carbon backbone homologue of bis(sulfo-N-succinimidyl) doxyl-2-spiro-4'-pimelate [BSSDP; Beth et al. (1986) Biochemistry 25, 3824-3832]. Due to its longer backbone, BSSDA can span longer distances between reactive groups on a protein than can BSSDP. However, the purpose of the bifunctional design of these reagents is to provide a tight motional coupling of the spin labels to the surface of a target protein. To test whether the longer backbone of BSSDA results in a greater local flexibility and thereby undermines the effects of bidentate attachment, we have labeled with BSSDA anion-exchange channels of intact human erythrocytes at the same site as we have previously labeled them with BSSDP. Linear and saturation-transfer EPR spectra of BSSDA-labeled anion-exchange channels in intact cells closely approximate the corresponding spectra from BSSDP-labeled channels. Thus, the longer backbone of BSSDA relative to BSSDP does not give rise to significant local flexibility, even when BSSDA is bound to a site that can be spanned by the shorter reagent.

show abstract

Bis(sulfo-n-succinimidyl) [15N,2H16]doxyl-2-spiro-4'-pimelate, a stable isotope-substituted, membrane-impermeant bifunctional spin label for studies of the dynamics of membrane proteins: application to the anion-exchange channel in intact human erythrocytes

Anjaneyulu¹,

Beth²,

Sweetman³

et al. 1988

Biochemistry

View full text Add to dashboard Cite

We have synthesized and characterized an isotopically substituted homologue of the membrane-impermeant bifunctional spin label bis(sulfo-N-succinimidyl) doxyl-2-spiro-4'-pimelate (BSSDP) [Beth et al. (1986) Biochemistry 25, 3824-3832] in which the nitroxide N is substituted with 15N and all of the protons in the doxylpimelate moiety are replaced by deuterons ([15N,2H16]BSSDP). Like its normal isotope homologue, [15N,2H16]BSSDP reacts with the anion-exchange channel in intact human erythrocytes at a site that spans the single extracytoplasmic chymotryptic cleavage site and that overlaps the stilbenedisulfonate site. The narrower line widths in the EPR spectrum of [15N,2H16]BSDP-labeled anion channels allow calculation of a minimum separation of 16 A between spin labels bound at the functionally important stilbenedisulfonate sites on adjacent subunits of an anion channel dimer. The 15N and 2H isotopic substitutions also provide substantial improvement in signal to noise of motionally sensitive regions of the ST-EPR spectrum of [15N,2H16]BSSDP-labeled anion channels in intact erythrocytes. [15N,2H16]BSSDP-labeled anion channels in intact erythrocytes were cross-linked to covalent dimers in the extracytoplasmic domain with the membrane-impermeant cross-linking reagent bis(sulfo-N-succinimidyl) suberate [Staros (1982) Biochemistry 21, 3950-3955], and the saturation-transfer EPR spectrum of these cells was compared with that of cells treated with [15N,2H16]BSSDP but not subsequently cross-linked. The spectra were essentially identical, supporting the hypothesis that anion channel subunits form stable dimers in the membranes of intact erythrocytes.

show abstract

The Tetrahymena Ribozyme Cleaves a 5‘-Methylene Phosphonate Monoester ∼10²-fold Faster Than a Normal Phosphate Diester: Implications for Enzyme Catalysis of Phosphoryl Transfer Reactions

et al. 2001

View full text Add to dashboard Cite

Single-atom substrate modifications have revealed an intricate network of transition state interactions in the Tetrahymena ribozyme reaction. So far, these studies have targeted virtually every oxygen atom near the reaction center, except one, the 5'-bridging oxygen atom of the scissile phosphate. To address whether interactions with this atom play any role in catalysis, we used a new type of DNA substrate in which the 5'-oxygen is replaced with a methylene (-CH2-) unit. Under (kcat/Km)S conditions, the methylene phosphonate monoester substrate dCCCUCUT(mp)TA4 (where mp indicates the position of the phosphonate linkage) unexpectedly reacts approximately 10(3)-fold faster than the analogous control substrates lacking the -CH2- modification. Experiments with DNA-RNA chimeric substrates reveal that the -CH2- modification enhances docking of the substrates into the catalytic core of the ribozyme by approximately 10-fold and stimulates the chemical cleavage by approximately 10(2)-fold. The docking effect apparently arises from the ability of the -CH2- unit to suppress inherently deleterious effects caused by the thymidine residue that immediately follows the cleavage site. To analyze the -O- to -CH2- modification in the absence of this thymidine residue, we prepared oligonucleotide substrates containing methyl phosphate or ethyl phosphonate at the reaction center, thereby eliminating the 3'-terminal TA4 nucleotidyl group. In this context, the -O- to -CH2-modification has no effect on docking but retains the approximately 10(2)-fold effect on the chemical step. To investigate further the stimulatory influence on the chemical step, we measured the "intrinsic" effect of the -O- to -CH2- modification in nonenzymatic reactions with nucleophiles. We found that in solution, the -CH2- modification stimulates chemical reactivity of the phosphorus center by <5-fold, substantially lower in magnitude than the stimulatory effect in the catalytic core of the ribozyme. The greater stimulatory effect of the -CH2- modification in the active site compared to in solution may arise from fortuitous changes in molecular geometry that allow the ribozyme to accommodate the phosphonate transition state better than the natural phosphodiester transition state. As the -CH2- unit lacks lone pair electrons, its effectiveness in the ribozyme reaction suggests that the 5'-oxygen of the scissile phosphate plays no role in catalysis via hydrogen bonding or metal ion coordination. Finally, we show by analysis of physical organic data that such interactions in general provide little catalytic advantage to RNA and protein phosphoryl transferases because the 5'-oxygen undergoes only a small buildup of negative charge during the reaction. In addition to its mechanistic significance for the Tetrahymena ribozyme reaction and phosphoryl transfer reactions in general, this work suggests that phosphonate monoesters may provide a novel molecular tool for determining whether the chemical step limits the rate of an enzymatic reaction. As methylene phosphonate mono...

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

P. S. R. Anjaneyulu

Reactions of N‐hydroxysulfosuccinimide active esters*

Bis(sulfo-N-succinimidyl) doxyl-2-spiro-5'-azelate: synthesis, characterization, and reaction with the anion-exchange channel in intact human erythrocytes

Bis(sulfo-n-succinimidyl) [15N,2H16]doxyl-2-spiro-4'-pimelate, a stable isotope-substituted, membrane-impermeant bifunctional spin label for studies of the dynamics of membrane proteins: application to the anion-exchange channel in intact human erythrocytes

The Tetrahymena Ribozyme Cleaves a 5‘-Methylene Phosphonate Monoester ∼10²-fold Faster Than a Normal Phosphate Diester: Implications for Enzyme Catalysis of Phosphoryl Transfer Reactions

Contact Info

Product

Resources

About

P. S. R. Anjaneyulu

Reactions of N‐hydroxysulfosuccinimide active esters*

Bis(sulfo-N-succinimidyl) doxyl-2-spiro-5'-azelate: synthesis, characterization, and reaction with the anion-exchange channel in intact human erythrocytes

Bis(sulfo-n-succinimidyl) [15N,2H16]doxyl-2-spiro-4'-pimelate, a stable isotope-substituted, membrane-impermeant bifunctional spin label for studies of the dynamics of membrane proteins: application to the anion-exchange channel in intact human erythrocytes

The Tetrahymena Ribozyme Cleaves a 5‘-Methylene Phosphonate Monoester ∼102-fold Faster Than a Normal Phosphate Diester: Implications for Enzyme Catalysis of Phosphoryl Transfer Reactions

Contact Info

Product

Resources

About

The Tetrahymena Ribozyme Cleaves a 5‘-Methylene Phosphonate Monoester ∼10²-fold Faster Than a Normal Phosphate Diester: Implications for Enzyme Catalysis of Phosphoryl Transfer Reactions