Phosphopantothenoylcysteine synthetase from Escherichia coli. Identification and characterization of the last unidentified coenzyme A biosynthetic enzyme in bacteria.

Phosphopantothenoylcysteine synthase catalyzes the formation of (R)-4'-phospho-N-pantothenoylcysteine from 4'-phosphopantothenate and l-cysteine: this enzyme, involved in the biosynthesis of coenzyme A (CoA), has not previously been identified. Recently it was shown that the NH(2)-terminal domain of the Dfp protein from bacteria catalyzes the next step in CoA biosynthesis, the decarboxylation of (R)-4'-phospho-N-pantothenoylcysteine to form 4'-phosphopantetheine (Kupke, T., Uebele, M., Schmid, D., Jung, G., Blaesse, M., and Steinbacher, S. (2000) J. Biol. Chem. 275, 31838-31846). We have partially purified phosphopantothenoylcysteine decarboxylase from Escherichia coli and demonstrated that the protein encoded by the dfp gene, here renamed coaBC, also has phosphopantothenoylcysteine synthetase activity, using CTP rather than ATP as the activating nucleoside 5'-triphosphate. This discovery completes the identification of all the enzymes involved in the biosynthesis of coenzyme A in bacteria.

The biosynthesis of coenzyme A in bacteria.

Coenzyme A (I) and enzyme-bound phosphopantetheine (II) function as acyl carriers and as carbonyl activating groups for Claisen reactions as well as for amide-, ester-, and thioester-forming reactions in the cell. In so doing, these cofactors play a key role in the biosynthesis and breakdown of fatty acids and in the biosynthesis of polyketides and nonribosomal peptides. Coenzyme A is biosynthesized in bacteria in nine steps. The biosynthesis begins with the decarboxylation of aspartate to give beta-alanine. Pantoic acid is formed by the hydroxymethylation of alpha-ketoisovalerate followed by reduction. These intermediates are then condensed to give pantothenic acid. Phosphorylation of pantothenic acid followed by condensation with cysteine and decarboxylation gives 4'-phosphopantetheine. Adenylation and phosphorylation of 4'-phosphopantetheine completes the biosynthesis of coenzyme A. This review will focus on the mechanistic enzymology of coenzyme A biosynthesis in bacteria.

The enzymology of sulfur activation during thiamin and biotin biosynthesis.

The thiamin and biotin biosynthetic pathways utilize elaborate strategies for the transfer of sulfur from cysteine to cofactor precursors. For thiamin, the sulfur atom of cysteine is transferred to a 66-amino-acid peptide (ThiS) to form a carboxy-terminal thiocarboxylate group. This sulfur transfer requires three enzymes and proceeds via a ThiS-acyladenylate intermediate. The biotin synthase Fe-S cluster functions as the immediate sulfur donor for biotin formation. C-S bond formation proceeds via radical intermediates that are generated by hydrogen atom transfer from dethiobiotin to the adenosyl radical. This radical is formed by the reductive cleavage of S-adenosylmethionine by the reduced Fe-S cluster of biotin synthase.

Crystal structure of thiaminase-I from Bacillus thiaminolyticus at 2.0 A resolution.

Thiaminase-I catalyzes the replacement of the thiazole moiety of thiamin with a wide variety of nucleophiles, such as pyridine, aniline, catechols, quinoline, and cysteine. The crystal structure of the enzyme from Bacillus thiaminolyticus was determined at 2.5 A resolution by multiple isomorphous replacement and refined to an R factor of 0.195 (Rfree = 0.272). Two other structures, one native and one containing a covalently bound inhibitor, were determined at 2.0 A resolution by molecular replacement from a second crystal form and were refined to R factors of 0.205 and 0.217 (Rfree = 0.255 and 0.263), respectively. The overall structure contains two alpha/beta-type domains separated by a large cleft. At the base of the cleft lies Cys113, previously identified as a key active site nucleophile. The structure with a covalently bound thiamin analogue, which functions as a mechanism-based inactivating agent, confirms the location of the active site. Glu241 appears to function as an active site base to increase the nucleophilicity of Cys113. The mutant Glu241Gln was made and shows no activity. Thiaminase-I shows no sequence identity to other proteins in the sequence databases, but the three-dimensional structure shows very high structural homology to the periplasmic binding proteins and the transferrins.

Spore photoproduct lyase from Bacillus subtilis spores is a novel iron-sulfur DNA repair enzyme which shares features with proteins such as class III anaerobic ribonucleotide reductases and pyruvate-formate lyases.

The major photoproduct in UV-irradiated spore DNA is the unique thymine dimer 5-thyminyl-5,6-dihydrothymine, commonly referred to as spore photoproduct (SP). An important determinant of the high UV resistance of Bacillus subtilis spores is the accurate in situ reversal of SP during spore germination by the DNA repair enzyme SP lyase. To study the molecular aspects of SP lyase-mediated SP repair, the cloned B. subtilis splB gene was engineered to encode SP lyase with a molecular tag of six histidine residues at its amino terminus. The engineered six-His-tagged SP lyase expressed from the amyE locus restored UV resistance to spores of a UV-sensitive mutant B. subtilis strain carrying a deletion-insertion mutation which removed the entire splAB operon at its natural locus and was shown to repair SP in vivo during spore germination. The engineered SP lyase was purified both from dormant B. subtilis spores and from an Escherichia coli overexpression system by nickel-nitrilotriacetic acid (NTA) agarose affinity chromatography and was shown by Western blotting, UV-visible spectroscopy, and iron and acid-labile sulfide analysis to be a 41-kDa iron-sulfur (Fe-S) protein, consistent with its amino acid sequence homology to the 4Fe-4S clusters in anaerobic ribonucleotide reductases and pyruvate-formate lyases. SP lyase was capable of reversing SP from purified SP-containing DNA in an in vitro reaction either when present in a cell-free extract prepared from dormant spores or after purification on nickel-NTA agarose. SP lyase activity was dependent upon reducing conditions and addition of S-adenosylmethionine as a cofactor.

Thiamin biosynthesis in Escherichia coli. Identification of ThiS thiocarboxylate as the immediate sulfur donor in the thiazole formation.

ThiFSGH and ThiI are required for the biosynthesis of the thiazole moiety of thiamin in Escherichia coli. The overproduction, purification, and characterization of ThiFS and the identification of two of the early steps in the biosynthesis of the thiazole moiety of thiamin are described here. ThiS isolated from E. coli thiI+ is post-translationally modified by converting the carboxylic acid group of the carboxyl-terminal glycine into a thiocarboxylate. The thiI gene plays an essential role in the formation of the thiocarboxylate because ThiS isolated from a thiI- strain does not contain this modification. ThiF catalyzes the adenylation by ATP of the carboxyl-terminal glycine of ThiS. This reaction is likely to be involved in the activation of ThiS for sulfur transfer from cysteine or from a cysteine-derived sulfur donor.

Overexpression of recombinant proteins with a C-terminal thiocarboxylate: implications for protein semisynthesis and thiamin biosynthesis.

A facile and rapid method for the production of protein C-terminal thiocarboxylates on DNA-encoded polypeptides is described. This method, which relies on the mechanism of the cleavage reaction of intein-containing fusion proteins, can produce multi-milligram quantities of protein C-terminal thiocarboxylate quickly and inexpensively. The utility of this method for protein semisynthesis and implications for studies on the biosynthesis of thiamin are discussed.