The coenzyme B12 precursor 5,6-dimethylbenzimidazole is a flavin antagonist in Salmonella.

Salmonella enterica subsp. enterica sv. Typhimurium str. LT2 (hereafter S. Typhimurium) synthesizes adenosylcobalamin (AdoCbl, CoB12) de novo only under anoxic conditions, but it can assemble the lower ligand loop (a.k.a. the nucleotide loop) and can form the unique C-Co bond present in CoB12 in the presence or absence of molecular oxygen. During studies of nucleotide loop assembly in S. Typhimurium, we noticed that the growth of this bacterium could be arrested by the lower ligand nucleobase, namely 5,6-dimethylbenzimidazole (DMB). Here we report in vitro and in vivo evidence that shows that the structural similarity of DMB to the isoalloxazine moiety of flavin cofactors causes its deleterious effect on cell growth. We studied DMB inhibition of the housekeeping flavin dehydrogenase (Fre) and three flavoenzymes that initiate the catabolism of tricarballylate, succinate or D-alanine in S. Typhimurium. Notably, while growth with tricarballylate was inhibited by 5-methyl-benzimidazole (5-Me-Bza) and DMB, growth with succinate or glycerol was arrested by DMB but not by 5-Me-Bza. Neither unsubstituted benzimidazole nor adenine inhibited growth of S. Typhimurium at DMB inhibitory concentrations. Whole genome sequencing analysis of spontaneous mutant strains that grew in the presence of inhibitory concentrations of DMB identified mutations effecting the cycA (encodes D-Ala/D-Ser transporter) and dctA (encodes dicarboxylate transporter) genes and in the coding sequence of the tricarballylate transporter (TcuC), suggesting that increased uptake of substrates relieved DMB inhibition. We discuss two possible mechanisms of inhibition by DMB.

Structural studies of the phosphoribosyltransferase involved in cobamide biosynthesis in methanogenic archaea and cyanobacteria.

Cobamides (Cbas) are coenzymes used by cells across all domains of life, but de novo synthesis is only found in some bacteria and archaea. Five enzymes assemble the nucleotide loop in the alpha phase of the corrin ring. Condensation of the activated ring and nucleobase yields adenosyl-Cba 5'-phosphate, which upon dephosphorylation yields the biologically active coenzyme (AdoCba). Base activation is catalyzed by a phosphoribosyltransferase (PRTase). The structure of the Salmonella enterica PRTase enzyme (i.e., SeCobT) is well-characterized, but archaeal PRTases are not. To gain insights into the mechanism of base activation by the PRTase from Methanocaldococcus jannaschii (MjCobT), we solved crystal structures of the enzyme in complex with substrate and products. We determined several structures: (i) a 2.2 Å structure of MjCobT in the absence of ligand (apo), (ii) structures of MjCobT bound to nicotinate mononucleotide (NaMN) and α-ribazole 5'-phosphate (α-RP) or α-adenylyl-5'-phosphate (α-AMP) at 2.3 and 1.4 Å, respectively. In MjCobT the general base that triggers the reaction is an aspartate residue (Asp 52) rather than a glutamate residue (E317) as in SeCobT. Notably, the dimer interface in MjCobT is completely different from that observed in SeCobT. Finally, entry PDB 3L0Z does not reflect the correct structure of MjCobT.

Localization and interaction studies of the Salmonella enterica ethanolamine ammonia-lyase (EutBC), its reactivase (EutA), and the EutT corrinoid adenosyltransferase.

Some prokaryotes compartmentalize select metabolic capabilities. Salmonella enterica subspecies enterica serovar Typhimurium LT2 (hereafter S. Typhimurium) catabolizes ethanolamine (EA) within a proteinaceous compartment that we refer to as the ethanolamine utilization (Eut) metabolosome. EA catabolism is initiated by the adenosylcobalamin (AdoCbl)-dependent ethanolamine ammonia-lyase (EAL), which deaminates EA via an adenosyl radical mechanism to yield acetaldehyde plus ammonia. This adenosyl radical can be quenched, requiring the replacement of AdoCbl by the ATP-dependent EutA reactivase. During growth on ethanolamine, S. Typhimurium synthesizes AdoCbl from cobalamin (Cbl) using the ATP:Co(I)rrinoid adenosyltransferase (ACAT) EutT. It is known that EAL localizes to the metabolosome, however, prior to this work, it was unclear where EutA and EutT localized, and whether they interacted with EAL. Here, we provide evidence that EAL, EutA, and EutT localize to the Eut metabolosome, and that EutA interacts directly with EAL. We did not observe interactions between EutT and EAL nor between EutT and the EutA/EAL complex. However, growth phenotypes of a ΔeutT mutant strain show that EutT is critical for efficient ethanolamine catabolism. This work provides a preliminary understanding of the dynamics of AdoCbl synthesis and its uses within the Eut metabolosome.

Acinetobacter baumannii Catabolizes Ethanolamine in the Absence of a Metabolosome and Converts Cobinamide into Adenosylated Cobamides.

Acinetobacter baumannii is an opportunistic pathogen typically associated with hospital-acquired infections. Our understanding of the metabolism and physiology of A. baumannii is limited. Here, we report that A. baumannii uses ethanolamine (EA) as the sole source of nitrogen and can use this aminoalcohol as a source of carbon and energy if the expression of the eutBC genes encoding ethanolamine ammonia-lyase (EAL) is increased. A strain with an ISAba1 element upstream of the eutBC genes efficiently used EA as a carbon and energy source. The A. baumannii EAL (AbEAL) enzyme supported the growth of a strain of Salmonella lacking the entire eut operon. Remarkably, the growth of the above-mentioned Salmonella strain did not require the metabolosome, the reactivase EutA enzyme, the EutE acetaldehyde dehydrogenase, or the addition of glutathione to the medium. Transmission electron micrographs showed that when Acinetobacter baumannii or Salmonella enterica subsp. enterica serovar Typhimurium strain LT2 synthesized AbEAL, the protein localized to the cell membrane. We also report that the A. baumannii genome encodes all of the enzymes needed for the assembly of the nucleotide loop of cobamides and that it uses these enzymes to synthesize different cobamides from the precursor cobinamide and several nucleobases. In the absence of exogenous nucleobases, the most abundant cobamide produced by A. baumannii was cobalamin. IMPORTANCE Acinetobacter baumannii is a Gram-negative bacterium commonly found in soil and water. A. baumannii is an opportunistic human pathogen, considered by the CDC to be a serious threat to human health due to the multidrug resistance commonly associated with this bacterium. Knowledge of the metabolic capabilities of A. baumannii is limited. The importance of the work reported here lies in the identification of ethanolamine catabolism occurring in the absence of a metabolosome structure. In other bacteria, this structure protects the cell against damage by acetaldehyde generated by the deamination of ethanolamine. In addition, the ethanolamine ammonia-lyase (EAL) enzyme of this bacterium is unique in that it does not require a reactivase enzyme to remain active. Importantly, we also demonstrate that the A. baumannii genome encodes the functions needed to assemble adenosylcobamide, the coenzyme of EAL, from the precursor cobinamide.

A method for the isolation of α-ribazole from vitamin B12, and its enzymatic conversion to α-ribazole 5'-phosphate.

Cobamides (Cbas) are the largest coenzymes known and are used by cells in all domains of life. These molecules are characterized by a central cobalt-containing tetrapyrrole ring with two opposing axial ligands on the α and ß faces of the ring. All biologically active forms of Cbas have a 5'-deoxyadenosyl group as the upper (Coß) ligand that is covalently attached to the cobalt ion of the ring. In contrast, the lower ligand is a nucleobase of diverse chemical structure; however, nucleobases are usually derivatives of benzimidazole or purine. Phenol and p-cresol can also serve as the nucleobase, but they cannot form a coordination bond with the cobalt ion of the ring because they lack a free pair of electrons. The Cba incorporating 5,6-dimethylbenzimidazole (DMB) is known as cobalamin (Cbl), and the coenzymic form of cobalamin is known as adenosylcobalamin (AdoCbl). A common vitamer of cobalamin has a cyano group as the upper ligand. This vitamer is known as cyanocobalamin (CNCbl), which is commercially marketed as vitamin B12. Here, we describe a combination of chemical hydrolysis of cobalamin with the enzymatic dephosphorylation of the resulting α-R-3'-phosphate to yield α-R, which we enzymically convert to the pathway intermediate α-R-5'-phosphate (α-RP). The methods describe herein can be readily scaled up to generate large amounts of α-RP.

A method for the efficient adenosylation of corrinoids.

Adenosylcobamides (AdoCbas) are coenzymes required by organisms from all domains of life to perform challenging chemical reactions. AdoCbas are characterized by a cobalt-containing tetrapyrrole ring, where an adenosyl group is covalently attached to the cobalt ion via a unique Co-C organometallic bond. During catalysis, this bond is homolytically cleaved by AdoCba-dependent enzymes to form an adenosyl radical that is critical for intra-molecular rearrangements. The formation of the Co-C bond is catalyzed by a family of enzymes known as ATP:Co(I)rrinoid adenosyltransferases (ACATs). ACATs adenosylate Cbas in two steps: (I) they generate a planar, Co(II) four-coordinate Cba to facilitate the reduction of Co(II) to Co(I), and (II) they transfer the adenosyl group from ATP to the Co(I) ion. To synthesize adenosylated corrinoids in vitro, it is imperative that anoxic conditions are maintained to avoid oxidation of Co(II) or Co(I) ions. Here we describe a method for the enzymatic synthesis and quantification of specific AdoCbas.

Functional Studies of α-Riboside Activation by the α-Ribazole Kinase (CblS) from Geobacillus kaustophilus.

We report the initial characterization of the α-ribazole (α-R) kinase enzyme of Geobacillus kaustophilus (GkCblS), which converts α-R to α-R-phosphate (α-RP) during the synthesis of cobamides. We implemented a continuous spectrophotometric assay to obtain kinetic parameters for several potential substrates and to study the specificity of the enzyme for α-N-linked ribosides. The apparent Km values for α-R and ATP were 358 and 297 µM, respectively. We also report methods for synthesizing and quantifying non-commercially available α-ribosides and ß-ribazole (ß-R). Purified GkCblS activated α-R and other α-ribosides, including α-adenosine (α-Ado). GkCblS did not phosphorylate ß-N-linked glycosides like ß-adenosine or ß-R. Expression of G. kaustophilus cblS+ in a Salmonella enterica subsp. enterica sv Typhimurium LT2 (S. enterica) strain lacking the nicotinate mononucleotide:5,6-dimethylbenzimidazole phosphoribosyl transferase (CobT) enzyme resulted in the activation of various benzimidazole α-ribosides, and the synthesis of benzimidazolyl cobamides to levels that supported robust growth. Notably, α-Ado did not support growth under similar conditions, in spite of the fact that GkCblS phosphorylated α-Ado in vitro. When α-Ado was provided at a very high concentration, growth was observed. This result suggested that in S. enterica α-Ado transport may be inefficient. We conclude that GkCblS has specificity for α-N-glycosidic bonds, but not for the base in α-ribosides.

Insights into the Relationship between Cobamide Synthase and the Cell Membrane.

Cobamides are cobalt-containing cyclic tetrapyrroles used by cells from all domains of life but only produced de novo by some bacteria and archaea. The "late steps" of the adenosylcobamide biosynthetic pathway are responsible for the assembly of the nucleotide loop and are required during de novo synthesis and precursor salvaging. These steps are characterized by activation of the corrin ring and lower ligand base, condensation of the activated precursors to adenosylcobamide phosphate, and removal of the phosphate, yielding a complete adenosylcobamide molecule. The condensation of the activated corrin ring and lower ligand base is performed by an integral membrane protein, cobamide (5' phosphate) synthase (CobS), and represents an important convergence of two pathways necessary for nucleotide loop assembly. Interestingly, membrane association of this penultimate step is conserved among all cobamide producers, yet the physiological relevance of this association is not known. Here, we present the purification and biochemical characterization of the CobS enzyme of the enterobacterium Salmonella enterica subsp. enterica serovar Typhimurium strain LT2, investigate its association with liposomes, and quantify the effect of the lipid bilayer on its enzymatic activity and substrate affinity. We report a purification scheme that yields pure CobS protein, allowing in vitro functional analysis. Additionally, we report a method for liposome reconstitution of CobS, allowing for physiologically relevant studies of this inner membrane protein in a phospholipid bilayer. In vitro and in vivo data reported here expand our understanding of CobS and the implications of membrane-associated adenosylcobamide biosynthesis.IMPORTANCESalmonella is a human pathogen of worldwide importance, and coenzyme B12 is critical for the pathogenic lifestyle of this bacterium. The importance of the work reported here lies on the improvements to the methodology used to isolate cobamide synthase, a polytopic integral membrane protein that catalyzes the penultimate step of coenzyme B12 biosynthesis. This advance is an important step in the analysis of the proposed multienzyme complex responsible for the assembly of the nucleotide loop during de novo coenzyme B12 biosynthesis and for the assimilation of incomplete corrinoids from the environment. We proposed that cobamide synthase is likely localized to the cell membrane of every coenzyme B12-producing bacterium and archaeum sequenced to date. The new knowledge of cobamide synthase advances our understanding of the functionality of the enzyme in the context of the lipid bilayer and sets the foundation for the functional-structural analysis of the aforementioned multienzyme complex.

Mutational and Functional Analyses of Substrate Binding and Catalysis of the Listeria monocytogenes EutT ATP:Co(I)rrinoid Adenosyltransferase.

ATP:Co(I)rrinoid adenosyltransferases (ACATs) catalyze the transfer of the adenosyl moiety from co-substrate ATP to a corrinoid substrate. ACATs are grouped into three families, namely, CobA, PduO, and EutT. The EutT family of enzymes is further divided into two classes, depending on whether they require a divalent metal ion for activity (class I and class II). To date, a structure has not been elucidated for either class of the EutT family of ACATs. In this work, results of bioinformatics analyses revealed several conserved residues between the C-terminus of EutT homologues and the structurally characterized Lactobacillus reuteri PduO (LrPduO) homologue. In LrPduO, these residues are associated with ATP binding and formation of an intersubunit salt bridge. These residues were substituted, and in vivo and in vitro data support the conclusion that the equivalent residues in the metal-free (i.e., class II) Listeria monocytogenes EutT (LmEutT) enzyme affect ATP binding. Results of in vivo and in vitro analyses of LmEutT variants with substitutions at phenylalanine and tryptophan residues revealed that replacement of the phenylalanine residue at position 72 affected access to the substrate-binding site and replacement of a tryptophan residue at position 238 affected binding of the Cbl substrate to the active site. Unlike the PduO family of ACATs, a single phenylalanine residue is not responsible for displacement of the α-ligand. Together, these data suggest that while EutT enzymes share a conserved ATP-binding motif and an intersubunit salt bridge with PduO family ACATs, class II EutT family ACATs utilize an unidentified mechanism for Cbl lower-ligand displacement and reduction that is different from that of PduO and CobA family ACATs.

The l-Thr Kinase/l-Thr-Phosphate Decarboxylase (CobD) Enzyme from Methanosarcina mazei Gö1 Contains Metallocenters Needed for Optimal Activity.

The MM2060 (cobD) gene from Methanosarcina mazei strain Gö1 encodes a protein (MmCobD) with l-threonine kinase (PduX) and l-threonine-O-3-phosphate decarboxylase (CobD) activities. In addition to the unexpected l-Thr kinase activity, MmCobD has an extended carboxy-terminal (C-terminal) region annotated as a putative metal-binding zinc finger-like domain. Here, we demonstrate that the C-terminus of MmCobD is a ferroprotein containing ∼25 non-heme iron atoms per monomer of protein. The absence of the C-terminus substantially reduces, but does not abolish, enzymatic activities in vitro and in vivo. Single-residue substitutions of C-terminal putative Fe-binding cysteinyl and histidinyl residues resulted in the loss of Fe and changes in enzyme activity levels. Salmonella enterica ΔpduX and ΔcobD strains were used as heterologous hosts to assess coenzyme B12 biosynthesis as a function of 17 MmCobD variants tested. Some of the latter displayed 5-fold higher enzymatic activity in vitro and enhanced the growth rate of the S. enterica strains that synthesized them. Most of the MmCobD variants tested were up to 6-fold less active in vitro and supported slow growth rates of the S. enterica strains that synthesized them; some substitutions abolished enzyme activity. MmCobD exhibited an ultraviolet-visible absorption spectrum consistent with [4Fe-4S] clusters that appeared to be susceptible to oxidation by H2O2 and reduction by sodium dithionite. The presence of FeS clusters in MmCobD was corroborated by electron paramagnetic resonance and magnetic circular dichroism studies. Collectively, our results suggest that MmCobD contains one or more diamagnetic [4Fe-4S]2+ center(s) that may play a structural or regulatory role.

In Salmonella enterica, OatA (Formerly YjgM) Uses O-Acetyl-Serine and Acetyl-CoA to Synthesize N,O-Diacetylserine, Which Upregulates Cysteine Biosynthesis.

L-Cysteine biosynthesis has been extensively analyzed in Salmonella enterica. The cysteine regulon contains the genes whose protein products are necessary to convert sulfate to sulfide, which is eventually reacted with O-acetyl-serine (OAS) to generate cysteine. The LysR type regulator, CysB, is required for activation of the cysteine regulon, and its interaction with various cys genes has been thoroughly characterized. Results from previous studies by others, suggested that OAS undergoes a spontaneous O- to N- migration to produce N-acetyl-serine (NAS), and that NAS is the true signal sensed by CysB. It was unclear, however, whether such migration occurred spontaneously in vivo or if NAS was generated enzymatically. Work reported herein characterizes a S. enterica N-acetyltransferase, OatA (formerly YjgM), which acetylates the N α-amino group of OAS, producing N,O-diacetyl-serine (DAS) at the expense of acetyl-CoA. We isolated OatA to homogeneity and performed its initial biochemical characterization. The product of the OatA reaction was isolated by HPLC and confirmed by mass spectrometry to be DAS; OatA did not acetylate NAS, consistent with the conclusion that OatA is an N-acetyltransferase, not an O-acetyltransferase. Binding of OAS to OatA appears to be positively cooperative with the apparent K0.5 for OAS determined to be 0.74 mM, the kcat was 1.05 s-1, and the catalytic efficiency of the enzyme (k cat/K0.5 ) was 1.4 × 103 M-1 s-1. Size exclusion chromatography indicated that OatA was a monomer in solution. In S. enterica, overexpression of oatA led to shorter lag times on sulfate-limiting medium and that these delayed lag times were due to increased expression of the cysteine regulon, as indicated by RT-qPCR results. OatA is the first Gcn5-related N-acetyltransferase (aka GNAT) involved in the regulation of amino acid biosynthetic genes in Salmonella. On the basis of results of transcriptomics studies performed by other investigators, we hypothesize that DAS may play a role in biofilm formation in S. enterica and other bacteria.

A New Class of EutT ATP:Co(I)rrinoid Adenosyltransferases Found in Listeria monocytogenes and Other Firmicutes Does Not Require a Metal Ion for Activity.

ATP:Co(I)rrinoid adenosyltransferases (ACATs) are involved in de novo adenosylcobamide (AdoCba) biosynthesis and in salvaging complete and incomplete corrinoids from the environment. The ACAT enzyme family is comprised of three classes of structurally and evolutionarily distinct proteins (i.e., CobA, PduO, and EutT). The structure of EutT is unknown, and an understanding of its mechanism is incomplete. The Salmonella enterica EutT ( SeEutT) enzyme is the best-characterized member of its class and is known to be a ferroprotein. Here, we report the identification and initial biochemical characterization of an enzyme representative of a new class of EutTs that does not require a metal ion for activity. In vivo and in vitro evidence shows that the metal-free EutT homologue from Listeria monocytogenes ( LmEutT) has ACAT activity and that, unlike other ACATs, the biologically active form of LmEutT is a tetramer. In vitro studies revealed that LmEutT was more efficient than SeEutT and displayed positive cooperativity. LmEutT adenosylated cobalamin, but not cobinamide, showed specificity for ATP and 2'-deoxyATP and released a triphosphate byproduct. Bioinformatics analyses suggest that metal-free EutT ACATs are also present in other Firmicutes.

Spectroscopic Study of the EutT Adenosyltransferase from Listeria monocytogenes: Evidence for the Formation of a Four-Coordinate Cob(II)alamin Intermediate.

The EutT enzyme from Listeria monocytogenes ( LmEutT) is a member of the family of ATP:cobalt(I) corrinoid adenosyltransferase (ACAT) enzymes that catalyze the biosynthesis of adenosylcobalamin (AdoCbl) from exogenous Co(II)rrinoids and ATP. Apart from EutT-type ACATs, two evolutionary unrelated types of ACATs have been identified, termed PduO and CobA. Although the three types of ACATs are nonhomologous, they all generate a four-coordinate cob(II)alamin (4C Co(II)Cbl) species to facilitate the formation of a supernucleophilic Co(I)Cbl intermediate capable of attacking the 5'-carbon of cosubstrate ATP. Previous spectroscopic studies of the EutT ACAT from Salmonella enterica ( SeEutT) revealed that this enzyme requires a divalent metal cofactor for the conversion of 5C Co(II)Cbl to a 4C species. Interestingly, LmEutT does not require a divalent metal cofactor for catalytic activity, which exemplifies an interesting phylogenetic divergence among the EutT enzymes. To explore if this disparity in the metal cofactor requirement among EutT enzymes correlates with differences in substrate specificity or the mechanism of Co(II)Cbl reduction, we employed various spectroscopic techniques to probe the interaction of Co(II)Cbl and cob(II)inamide (Co(II)Cbi+) with LmEutT in the absence and presence of cosubstrate ATP. Our data indicate that LmEutT displays a similar substrate specificity as SeEutT and can bind both Co(II)Cbl and Co(II)Cbi+ when complexed with MgATP, though it exclusively converts Co(II)Cbl to a 4C species. Notably, LmEutT is the most effective ACAT studied to date in generating the catalytically relevant 4C Co(II)Cbl species, achieving a >98% 5C → 4C conversion yield on the addition of just over one mol equiv of cosubstrate MgATP.

Rhodobacterales use a unique L-threonine kinase for the assembly of the nucleotide loop of coenzyme B12.

Several of the enzymes involved in the conversion of adenosylcobyric acid (AdoCby) to adenosylcobamide (AdoCba) are yet to be identified and characterized in some cobamide (Cba)-producing prokaryotes. Using a bioinformatics approach, we identified the bluE gene (locus tag RSP_0788) of Rhodobacter sphaeroides 2.4.1 as a putative functional homolog of the L-threonine kinase enzyme (PduX, EC 2.7.1.177) of S. enterica. In AdoCba, (R)-1-aminopropan-2-ol O-phosphate (AP-P) links the nucleotide loop to the corrin ring; most known AdoCba producers derive AP-P from L-Thr-O-3-phosphate (L-Thr-P). Here, we show that RsBluE has L-Thr-independent ATPase activity in vivo and in vitro. We used 31 P-NMR spectroscopy to show that RsBluE generates L-Thr-P at the expense of ATP and is unable to use L-Ser as a substrate. BluE from R. sphaeroides or Rhodobacter capsulatus restored AdoCba biosynthesis in S. enterica ΕpduX and R. sphaeroides ΕbluE mutant strains. R. sphaeroides ΕbluE strains exhibited a decreased pigment phenotype that was restored by complementation with BluE. Finally, phylogenetic analyses revealed that bluE was restricted to the genomes of a few Rhodobacterales that appear to have a preference for a specific form of Cba, namely Coá´½-(á´½-5,6-dimethylbenzimidazolyl-Coᵦ-adenosylcobamide (a.k.a. adenosylcobalamin, AdoCbl; coenzyme B12 , CoB12 ).

The Methanosarcina mazei MM2060 Gene Encodes a Bifunctional Kinase/Decarboxylase Enzyme Involved in Cobamide Biosynthesis.

Cobamides (Cbas) are synthesized by many archaea, but some aspects of Cba biosynthesis in these microorganisms remain unclear. Here, we demonstrate that open reading frame MM2060 in the archaeum Methanosarcina mazei strain Gö1 encodes a bifunctional enzyme with l-threonine- O-3-phosphate (l-Thr-P) decarboxylase (EC 4.1.1.81) and l-Thr kinase activities (EC 2.7.1.177). In Salmonella enterica, where Cba biosynthesis has been extensively studied, the activities mentioned above are encoded by separate genes, namely, cobD and pduX, respectively. The activities associated with the MM2060 protein ( MmCobD) were validated in vitro and in vivo. In vitro, MmCobD used ATP and l-Thr as substrates and generated ADP, l-Thr-P, and ( R)-1-aminopropan-2-ol O-phosphate as products. Notably, MmCobD has a 111-amino acid C-terminal extension of unknown function, which contains a putative metal-binding motif. This C-terminal domain alone did not display activity either in vivo or in vitro. Although the C-terminal MmCobD domain was not required for l-Thr-P decarboxylase or l-Thr kinase activities in vivo, its absence negatively affected both activities. In vitro results suggested that this domain may have a regulatory or substrate-gating role. When purified under anoxic conditions, MmCobD displayed Michaelis-Menten kinetics and had a 1000-fold higher affinity for ATP and a catalytic efficiency 1300-fold higher than that of MmCobD purified under oxic conditions. To the best of our knowledge, MmCobD is the first example of a new class of l-Thr-P decarboxylases that also have l-Thr kinase activity. An archaeal protein with l-Thr kinase activity had not been identified prior to this work.

In Streptomyces lividans, acetyl-CoA synthetase activity is controlled by O-serine and Nɛ -lysine acetylation.

Protein acetylation is a rapid mechanism for control of protein function. Acetyl-CoA synthetase (AMP-forming, Acs) is the paradigm for the control of metabolic enzymes by lysine acetylation. In many bacteria, type I or II protein acetyltransferases acetylate Acs, however, in actinomycetes type III protein acetyltransferases control the activity of Acs. We measured changes in the activity of the Streptomyces lividans Acs (SlAcs) enzyme upon acetylation by PatB using in vitro and in vivo analyses. In addition to the acetylation of residue K610, residue S608 within the acetylation motif of SlAcs was also acetylated (PKTRSGK610 ). S608 acetylation rendered SlAcs inactive and non-acetylatable by PatB. It is unclear whether acetylation of S608 is enzymatic, but it was clear that this modification occurred in vivo in Streptomyces. In S. lividans, an NAD+ -dependent sirtuin deacetylase from Streptomyces, SrtA (a homologue of the human SIRT4 protein) was needed to maintain SlAcs function in vivo. We have characterized a sirtuin-dependent reversible lysine acetylation system in Streptomyces lividans that targets and controls the Acs enzyme of this bacterium. These studies raise questions about acetyltransferase specificity, and describe the first Acs enzyme in any organism whose activity is modulated by O-Ser and Nɛ -Lys acetylation.

Spectroscopic Studies of the EutT Adenosyltransferase from Salmonella enterica: Evidence of a Tetrahedrally Coordinated Divalent Transition Metal Cofactor with Cysteine Ligation.

The EutT enzyme from Salmonella enterica, a member of the family of ATP:cobalt(I) corrinoid adenosyltransferase (ACAT) enzymes, requires a divalent transition metal ion for catalysis, with Fe(II) yielding the highest activity. EutT contains a unique cysteine-rich HX11CCX2C(83) motif (where H and the last C occupy the 67th and 83rd positions, respectively, in the amino acid sequence) not found in other ACATs and employs an unprecedented mechanism for the formation of adenosylcobalamin. Recent kinetic and spectroscopic studies of this enzyme revealed that residues in the HX11CCX2C(83) motif are required for the tight binding of the divalent metal ion and are critical for the formation of a four-coordinate (4c) cob(II)alamin [Co(II)Cbl] intermediate in the catalytic cycle. However, it remained unknown which, if any, of the residues in the HX11CCX2C(83) motif bind the divalent metal ion. To address this issue, we have characterized Co(II)-substituted wild-type EutT (EutTWT/Co) by using electronic absorption, electron paramagnetic resonance, and magnetic circular dichroism (MCD) spectroscopies. Our results indicate that the reduced catalytic activity of EutTWT/Co relative to that of the Fe(II)-containing enzyme arises from the incomplete incorporation of Co(II) ions and, thus, a decrease in the relative population of 4c Co(II)Cbl. Our MCD data for EutTWT/Co also reveal that the Co(II) ions reside in a distorted tetrahedral coordination environment with direct cysteine sulfur ligation. Additional spectroscopic studies of EutT/Co variants possessing a single alanine substitution of either His67, His75, Cys79, Cys80, or Cys83 indicate that Cys80 coordinates to the Co(II) ion, while the additional residues are important for maintaining the structural integrity and/or high affinity of the metal binding site.

Salmonella enterica synthesizes 5,6-dimethylbenzimidazolyl-(DMB)-α-riboside. Why some Firmicutes do not require the canonical DMB activation system to synthesize adenosylcobalamin.

5,6-Dimethylbenzimidazolyl-(DMB)-α-ribotide [α-ribazole-5'-phosphate (α-RP)] is an intermediate in the biosynthesis of adenosylcobalamin (AdoCbl) in many prokaryotes. In such microbes, α-RP is synthesized by nicotinate mononucleotide (NaMN):DMB phosphoribosyltransferases (CobT in Salmonella enterica), in a reaction that is considered to be the canonical step for the activation of the base of the nucleotide present in adenosylcobamides. Some Firmicutes lack CobT-type enzymes but have a two-protein system comprised of a transporter (i.e., CblT) and a kinase (i.e., CblS) that can salvage exogenous α-ribazole (α-R) from the environment using CblT to take up α-R, followed by α-R phosphorylation by CblS. We report that Geobacillus kaustophilus CblT and CblS proteins restore α-RP synthesis in S. enterica lacking the CobT enzyme. We also show that a S. enterica cobT strain that synthesizes GkCblS ectopically makes only AdoCbl, even under growth conditions where the synthesis of pseudoCbl is favored. Our results indicate that S. enterica synthesizes α-R, a metabolite that had not been detected in this bacterium and that GkCblS has a strong preference for DMB-ribose over adenine-ribose as substrate. We propose that in some Firmicutes DMB is activated to α-RP via α-R using an as-yet-unknown route to convert DMB to α-R and CblS to convert α-R to α-RP.

Resonance Raman spectroscopic study of the interaction between Co(II)rrinoids and the ATP:corrinoid adenosyltransferase PduO from Lactobacillus reuteri.

The human-type ATP:corrinoid adenosyltransferase PduO from Lactobacillus reuteri (LrPduO) catalyzes the adenosylation of Co(II)rrinoids to generate adenosylcobalamin (AdoCbl) or adenosylcobinamide (AdoCbi(+)). This process requires the formation of "supernucleophilic" Co(I)rrinoid intermediates in the enzyme active site which are properly positioned to abstract the adeonsyl moiety from co-substrate ATP. Previous magnetic circular dichroism (MCD) spectroscopic and X-ray crystallographic analyses revealed that LrPduO achieves the thermodynamically challenging reduction of Co(II)rrinoids by displacing the axial ligand with a non-coordinating phenylalanine residue to produce a four-coordinate species. However, relatively little is currently known about the interaction between the tetradentate equatorial ligand of Co(II)rrinoids (the corrin ring) and the enzyme active site. To address this issue, we have collected resonance Raman (rR) data of Co(II)rrinoids free in solution and bound to the LrPduO active site. The relevant resonance-enhanced vibrational features of the free Co(II)rrinoids are assigned on the basis of rR intensity calculations using density functional theory to establish a suitable framework for interpreting rR spectral changes that occur upon Co(II)rrinoid binding to the LrPduO/ATP complex in terms of structural perturbations of the corrin ring. To complement our rR data, we have also obtained MCD spectra of Co(II)rrinoids bound to LrPduO complexed with the ATP analogue UTP. Collectively, our results provide compelling evidence that in the LrPduO active site, the corrin ring of Co(II)rrinoids is firmly locked in place by several amino acid side chains so as to facilitate the dissociation of the axial ligand.

Spectroscopic Studies of the EutT Adenosyltransferase from Salmonella enterica: Mechanism of Four-Coordinate Co(II)Cbl Formation.

EutT from Salmonella enterica is a member of a class of enzymes termed ATP:Co(I)rrinoid adenosyltransferases (ACATs), implicated in the biosynthesis of adenosylcobalamin (AdoCbl). In the presence of cosubstrate ATP, ACATs raise the Co(II)/Co(I) reduction potential of their cob(II)alamin [Co(II)Cbl] substrate by >250 mV via the formation of a unique four-coordinate (4c) Co(II)Cbl species, thereby facilitating the formation of a "supernucleophilic" cob(I)alamin intermediate required for the formation of the AdoCbl product. Previous kinetic studies of EutT revealed the importance of a HX11CCX2C(83) motif for catalytic activity and have led to the proposal that residues in this motif serve as the binding site for a divalent transition metal cofactor [e.g., Fe(II) or Zn(II)]. This motif is absent in other ACAT families, suggesting that EutT employs a distinct mechanism for AdoCbl formation. To assess how metal ion binding to the HX11CCX2C(83) motif affects the relative yield of 4c Co(II)Cbl generated in the EutT active site, we have characterized several enzyme variants by using electronic absorption, magnetic circular dichroism, and electron paramagnetic resonance spectroscopies. Our results indicate that Fe(II) or Zn(II) binding to the HX11CCX2C(83) motif of EutT is required for promoting the formation of 4c Co(II)Cbl. Intriguingly, our spectroscopic data also reveal the presence of an equilibrium between five-coordinate "base-on" and "base-off" Co(II)Cbl species bound to the EutT active site at low ATP concentrations, which shifts in favor of "base-off" Co(II)Cbl in the presence of excess ATP, suggesting that the base-off species serves as a precursor to 4c Co(II)Cbl.