Chemical modification of tryptophan residues in Escherichia coli succinyl-CoA synthetase. Effect on structure and enzyme activity

Chemical Modification for the "off-/on" Regulation of Enzyme Activity

Enzymes with excellent catalytic performance play important roles in living organisms. Advances in strategies for enzyme chemical modification have enabled powerful strategies for exploring and manipulating enzyme functions and activities. Based on the development of chemical enzyme modifications, incorporating external stimuli-responsive features-for example, responsivity to light, voltage, magnetic force, pH, temperature, redox activity, and small molecules-into a target enzyme to turn "on" and "off" its activity has attracted much attention. The ability to precisely control enzyme activity using different approaches would greatly expand the chemical biology toolbox for clarification and detection of signal transduction and in vivo enzyme function and significantly promote enzyme-based disease therapy. This review summarizes the methods available for chemical enzyme modification mainly for the off-/on control of enzyme activity and particularly highlights the recent progress regarding the applications of this strategy. This article is protected by copyright. All rights reserved.

Chemical modifications of Bacillus subtilis tryptophanyl-tRNA synthetase

A concerted conformational change in Bacillus subtilis tryptophanyl-tRNA synthetase (TrpRS) was evident from previous fluorescence on the quenching of the single Trp residue Trp-92 in the 4FTrp-AMP complexed enzyme. In this study, chemical modifications of the B. subtilis TrpRS were employed to further characterize this conformational change, with the single Trp residue serving as a marker for monitoring the change. Modifications of the enzyme by means of the Trp-specific agent N-bromosuccinimide (NBS) or 3-bromo-3-methyl-2-(2-nitrophenylmercapto)-3H-indole (BNPS-skatole) inactivated the enzyme in accord with the essential role of Trp-92, as identified previously by site-directed mutagenesis. ATP sensitized TrpRS toward inactivation by NBS and BNPS-skatole, which suggested a conformational change that resulted in greater accessibility of Trp-92 toward modifications. In contrast, the cognate tRNATrp substrate exerted a specific protective effect against inactivation by both of the reagents, indicating that the TrpRS-tRNATrp interaction reduces the accessibility of Trp-92 under our experimental conditions. By comparison, modification of sulfhydryl groups by means of iodoacetamide did not reduce TrpRS activity. Observations on Trp-specific modification and substrate protection effects are discussed in the context of the Bacillus stearothermophilus TrpRS crystal structure.

Intrinsic fluorescence of succinyl-CoA synthetase and four tryptophan mutants. Tryptophan 76 and tryptophan 248 of the beta-subunit are responsive to CoA binding

Previous studies showed that modification of an average of one of the three tryptophan residues of succinyl-CoA synthetase of Escherichia coli abolished enzyme activity, but did not prevent phosphorylation of the enzyme by ATP [Ybarra, J., Prasad, A. R. S., & Nishimura, J.S. (1986) Biochemistry 25, 7174-7178]. In the present study, single mutations in which each of the three tryptophans (beta-Trp43, beta-Trp76, and beta-Trp248) has been changed to phenylalanine (designated W43F, W76F, and W248F) have been accomplished by the technique of site-directed mutagenesis and the mutant proteins isolated. In addition, a double mutant in which beta-Trp43 and beta-Trp248 were changed to phenylalanines (W43,248F) has also been isolated. Each of the mutant enzymes was practically as active as wild type. Since the emission spectrum of beta-Trp76 reflected a low fluorescence intensity for this residue, it was possible to obtain the emission spectrum of each tryptophan residue by using W43F, W248F, and W43,248F. From the positions of the emission maxima and the results of iodide quenching of fluorescence, it was deduced that beta-Trp248 is a surface residue, beta-Trp43 is buried, and beta-Trp76 is intermediate in location. Coenzyme A, but no other substrate, protected the fluorescence of beta-Trp76 and beta-Trp248, but not of beta-Trp43, against quenching by acrylamide. These results are consistent with an interaction between beta-Trp76 and beta-Trp248 and the binding site for CoA.

Overexpression and site-directed mutagenesis of the succinyl-CoA synthetase of Escherichia coli and nucleotide sequence of a gene (g30) that is adjacent to the suc operon

The succinyl-CoA synthetase of Escherichia coli is encoded by two genes, sucC (beta subunit) and sucD (alpha subunit), which are distal genes in the sucABCD operon. They are expressed from the suc promoter, which also expresses the dehydrogenase and dihydrolipoyl succinyl-transferase subunits of the 2-oxoglutarate dehydrogenase complex. Strategies have now been devised for the site-directed mutagenesis and independent expression of the succinyl-CoA synthetase (alpha 2 beta 2 tetramer) and the individual subunits. These involve (1) subcloning a promoterless sucCD fragment downstream of the lac promoter in M13mp10, and (2) precise splicing of the suc coding regions with the efficient atpE ribosome-binding site and expression from the thermoinducible lambda promoters in the pJLA503 vector. Succinyl-CoA synthetase specific activities were amplified 40-60-fold within 5 h of thermoinduction of the lambda promoters, and the alpha and beta subunits accounted for almost 30% of the protein in supernatant fractions of the cell-free extracts. Site-directed mutagenesis of potential CoA binding-site residues indicated that Trp-43 beta and His-50 beta are essential residues in the beta-subunit, whereas Cys-47 beta could be replaced by serine without inactivating the enzyme. No activity was detected after the histidine residue at the phosphorylation site of the alpha-subunit was replaced by aspartate (His-246 alpha----Asp), but this alteration seemed to have a deleterious effect on the accumulation of the enzyme in cell-free supernatant extracts. The nucleotide sequence of an unidentified gene (g30) that is adjacent to the sucABCD operon was defined by extending the sequence of the citric acid cycle gene cluster by 818 bp to 13379 bp: gltA-sdhCDAB-sucABCD-g30. This gene converges on the suc operon and encodes a product (P30) that contains 230 amino acids (Mr 27,251). Highly significant similarities were detected between the N-terminal region of P30 and those of GENA [the product of another unidentified gene (geneA) located upstream of the aceEF-lpd operon], and GNTR (a putative transcriptional repressor of the gluconate operon of Bacillus subtilis). Possible roles for GENA and P30 as transcriptional regulators of the adjacent operons encoding the pyruvate and 2-oxoglutarate dehydrogenase complexes are discussed.

Involvement of tryptophan residues at the coenzyme A binding site of carbon monoxide dehydrogenase from Clostridium thermoaceticum

Carbon monoxide dehydrogenase (CODH) from Clostridium thermoaceticum plays a central role in the newly discovered acetyl-CoA pathway [Wood, H.G., Ragsdale, S.W., & Pezacka, E. (1986) FEMS Microbiol. Rev. 39, 345-362]. The enzyme catalyzes the formation of acetyl-CoA from methyl, carbonyl, and CoA groups, and it has specific binding sites for these moieties. In this study, we have determined the role of tryptophans at these subsites. N-Bromosuccinimide (NBS) oxidation of the exposed and reactive tryptophans (5 out of a total of approximately 20) of CODH at pH 5.5 results in the partial inactivation of the exchange reaction (approximately 50%) involving carbon monoxide and the carbonyl group of the acetyl-CoA. Also, about 70% of the acetyl-CoA synthesis was abolished as a result of NBS modification. The presence of CoA (10 microM) produced complete protection against the partial inhibition of the exchange activity and the overall synthesis of acetyl-CoA caused by NBS. Additionally, none of the exposed tryptophans of CODH was modified in the presence of CoA. Ligands such as the methyl or the carbonyl groups did not afford protection against these inactivations or the modification of the exposed tryptophans. A significant fraction of the accessible fluorescence of CODH was shielded in the presence of CoA against acrylamide quenching. On the basis of these observations, it appears that certain tryptophans are involved at or near the CoA binding site of CODH.

Isolation, amino acid analyses and refolding of subunits of pig heart succinyl-CoA synthetase

For the first time, pig heart succinyl-CoA synthetase has been refolded from its isolated subunits after denaturation. Amino acid analyses of pig heart succinyl-CoA synthetase and its subunits were performed. Subunits were isolated by gel filtration in neutral 6 M-urea. The amino acid composition of the native enzyme bears a strong resemblance to that of the Escherichia coli enzyme. Application of the various methods for comparing amino acid compositions [Cornish-Bowden (1983) Methods Enzymol. 91, 60-75] shows that the degree of relatedness between the alpha-subunits of the pig heart and E. coli enzymes and between the beta-subunits of the two synthetases is intermediate between 'strong' and 'weak'. As for the E. coli synthetase, it is unlikely that the alpha-subunit arises from the larger beta-subunit by post-translational modification. The pig heart enzyme contains a single tryptophan residue, which is located in the beta-subunit. Excitation of the enzyme at 295 nm resulted in a typical tryptophan emission spectrum. Refolding of enzyme denatured in 6 M-guanidine hydrochloride or of alpha- and beta-subunits isolated in this solvent required the presence of either ethylene glycol or glycerol, optimally at 20-25% (v/v). GTP-Mg2+ did not stimulate reactivation of the enzyme, in contrast with the result obtained with ATP-Mg2+ in the reconstitution of the enzyme from E. coli. Yields of 60% and 40% were obtained in the refolding of denatured enzyme and isolated subunits respectively. The fluorescence spectrum of the refolded protein was essentially the same as that of native enzyme. Unrecovered activity could not be accounted for in the form of protein aggregates. The specific activity of refolded enzyme that had been separated from inactive protein on a Bio-Sil TSK 250 column was the same as that of native enzyme. Km values for GTP of 27 microM and 14 microM were determined for native and refolded enzyme respectively.