Divergent non-heme iron enzymes in the nogalamycin biosynthetic pathway.

Nogalamycin, an aromatic polyketide displaying high cytotoxicity, has a unique structure, with one of the carbohydrate units covalently attached to the aglycone via an additional carbon-carbon bond. The underlying chemistry, which implies a particularly challenging reaction requiring activation of an aliphatic carbon atom, has remained enigmatic. Here, we show that the unusual C5''-C2 carbocyclization is catalyzed by the non-heme iron α-ketoglutarate (α-KG)-dependent SnoK in the biosynthesis of the anthracycline nogalamycin. The data are consistent with a mechanistic proposal whereby the Fe(IV) = O center abstracts the H5'' atom from the amino sugar of the substrate, with subsequent attack of the aromatic C2 carbon on the radical center. We further show that, in the same metabolic pathway, the homologous SnoN (38% sequence identity) catalyzes an epimerization step at the adjacent C4'' carbon, most likely via a radical mechanism involving the Fe(IV) = O center. SnoK and SnoN have surprisingly similar active site architectures considering the markedly different chemistries catalyzed by the enzymes. Structural studies reveal that the differences are achieved by minor changes in the alignment of the substrates in front of the reactive ferryl-oxo species. Our findings significantly expand the repertoire of reactions reported for this important protein family and provide an illustrative example of enzyme evolution.

Divergent evolution of an atypical S-adenosyl-l-methionine-dependent monooxygenase involved in anthracycline biosynthesis.

Bacterial secondary metabolic pathways are responsible for the biosynthesis of thousands of bioactive natural products. Many enzymes residing in these pathways have evolved to catalyze unusual chemical transformations, which is facilitated by an evolutionary pressure promoting chemical diversity. Such divergent enzyme evolution has been observed in S-adenosyl-L-methionine (SAM)-dependent methyltransferases involved in the biosynthesis of anthracycline anticancer antibiotics; whereas DnrK from the daunorubicin pathway is a canonical 4-O-methyltransferase, the closely related RdmB (52% sequence identity) from the rhodomycin pathways is an atypical 10-hydroxylase that requires SAM, a thiol reducing agent, and molecular oxygen for activity. Here, we have used extensive chimeragenesis to gain insight into the functional differentiation of RdmB and show that insertion of a single serine residue to DnrK is sufficient for introduction of the monooxygenation activity. The crystal structure of DnrK-Ser in complex with aclacinomycin T and S-adenosyl-L-homocysteine refined to 1.9-Å resolution revealed that the inserted serine S297 resides in an α-helical segment adjacent to the substrate, but in a manner where the side chain points away from the active site. Further experimental work indicated that the shift in activity is mediated by rotation of a preceding phenylalanine F296 toward the active site, which blocks a channel to the surface of the protein that is present in native DnrK. The channel is also closed in RdmB and may be important for monooxygenation in a solvent-free environment. Finally, we postulate that the hydroxylation ability of RdmB originates from a previously undetected 10-decarboxylation activity of DnrK.

Crystal structure of the DNA polymerase III ß subunit (ß-clamp) from the extremophile Deinococcus radiodurans.

BACKGROUND: Deinococcus radiodurans is an extremely radiation and desiccation resistant bacterium which can tolerate radiation doses up to 5,000 Grays without losing viability. We are studying the role of DNA repair and replication proteins for this unusual phenotype by a structural biology approach. The DNA polymerase III ß subunit (ß-clamp) acts as a sliding clamp on DNA, promoting the binding and processivity of many DNA-acting proteins, and here we report the crystal structure of D. radiodurans ß-clamp (Drß-clamp) at 2.0 Å resolution. RESULTS: The sequence verification process revealed that at the time of the study the gene encoding Drß-clamp was wrongly annotated in the genome database, encoding a protein of 393 instead of 362 amino acids. The short protein was successfully expressed, purified and used for crystallisation purposes in complex with Cy5-labeled DNA. The structure, which was obtained from blue crystals, shows a typical ring-shaped bacterial ß-clamp formed of two monomers, each with three domains of identical topology, but with no visible DNA in electron density. A visualisation of the electrostatic surface potential reveals a highly negatively charged outer surface while the inner surface and the dimer forming interface have a more even charge distribution. CONCLUSIONS: The structure of Drß-clamp was determined to 2.0 Å resolution and shows an evenly distributed electrostatic surface charge on the DNA interacting side. We hypothesise that this charge distribution may facilitate efficient movement on encircled DNA and help ensure efficient DNA metabolism in D. radiodurans upon exposure to high doses of ionizing irradiation or desiccation.

Structure-based engineering of angucyclinone 6-ketoreductases.

Angucyclines are tetracyclic polyketides produced by Streptomyces bacteria that exhibit notable biological activities. The great diversity of angucyclinones is generated in tailoring reactions, which modify the common benz[a]anthraquinone carbon skeleton. In particular, the opposite stereochemistry of landomycins and urdamycins/gaudimycins at C-6 is generated by the short-chain alcohol dehydrogenases/reductases LanV and UrdMred/CabV, respectively. Here we present crystal structures of LanV and UrdMred in complex with NADP(+) and the product analog rabelomycin, which enabled us to identify four regions associated with the functional differentiation. The structural analysis was confirmed in chimeragenesis experiments focusing on these regions adjacent to the active site cavity, which led to reversal of the activities of LanV and CabV. The results surprisingly indicated that the conformation of the substrate and the stereochemical outcome of 6-ketoreduction appear to be intimately linked.

Structural and biophysical analysis of interactions between cod and human uracil-DNA N-glycosylase (UNG) and UNG inhibitor (Ugi).

Uracil-DNA N-glycosylase from Atlantic cod (cUNG) shows cold-adapted features such as high catalytic efficiency, a low temperature optimum for activity and reduced thermal stability compared with its mesophilic homologue human UNG (hUNG). In order to understand the role of the enzyme-substrate interaction related to the cold-adapted properties, the structure of cUNG in complex with a bacteriophage encoded natural UNG inhibitor (Ugi) has been determined. The interaction has also been analyzed by isothermal titration calorimetry (ITC). The crystal structure of cUNG-Ugi was determined to a resolution of 1.9 Šwith eight complexes in the asymmetric unit related through noncrystallographic symmetry. A comparison of the cUNG-Ugi complex with previously determined structures of UNG-Ugi shows that they are very similar, and confirmed the nucleotide-mimicking properties of Ugi. Biophysically, the interaction between cUNG and Ugi is very strong and shows a binding constant (Kb) which is one order of magnitude larger than that for hUNG-Ugi. The binding of both cUNG and hUNG to Ugi was shown to be favoured by both enthalpic and entropic forces; however, the binding of cUNG to Ugi is mainly dominated by enthalpy, while the entropic term is dominant for hUNG. The observed differences in the binding properties may be explained by an overall greater positive electrostatic surface potential in the protein-Ugi interface of cUNG and the slightly more hydrophobic surface of hUNG.

Structural and functional analysis of angucycline C-6 ketoreductase LanV involved in landomycin biosynthesis.

Angucyclines are biologically active natural products constructed around a common benz[a]anthraquinone carbon frame. One key branching point in the biosynthesis of angucyclines is the ketoreduction at C-6, which results in the opposite stereochemistry of landomycins and urdamycins/gaudimycins. Here we present the 1.65 Å resolution crystal structure of LanV from Streptomyces cyanogenus S136 that is responsible for the 6R stereochemistry of landomycins. The enzyme displays the common architectural fold of short-chain alcohol dehydrogenases/reductases and contains bound nicotinamide adenine dinucleotide phosphate. Determination of the structure of LanV in complex with 11-deoxylandomycinone at 2.0 Å resolution indicated that substrate binding does not induce large conformational changes and that substrate recognition occurs mainly through hydrophobic interactions. Analysis of the electron density map of the ternary complex revealed that the catalytic reaction had most likely proceeded backward in the crystal, because the data could be best fit with a compound harboring a carbonyl group at C-6. A coordinated water molecule was atypically identified between the ligand and the conserved Tyr160 residue, which was confirmed to be critical for the catalytic activity by site-directed mutagenesis. A catalytic triad of Ser147, Tyr160, and Lys164 could be recognized on the basis of the crystal structure, and stereoselective labeling studies demonstrated that the transfer of hydride from reduced nicotinamide adenine dinucleotide phosphate to the substrate occurs from the 4-pro-S side of the cosubstrate. Importantly, Ser192 was identified as being involved in controlling the stereochemistry of the reaction, as assays with single mutant Ser192Ile led to accumulation of gaudimycin C with 6S stereochemistry as a minor product.

Structural basis for C-ribosylation in the alnumycin A biosynthetic pathway.

Alnumycin A is an exceptional aromatic polyketide that contains a carbohydrate-like 4'-hydroxy-5'-hydroxymethyl-2',7'-dioxane moiety attached to the aglycone via a carbon-carbon bond. Recently, we have identified the D-ribose-5-phosphate origin of the dioxane unit and demonstrated that AlnA and AlnB are responsible for the overall C-ribosylation reaction. Here, we provide direct evidence that AlnA is a natural C-glycosynthase, which catalyzes the attachment of D-ribose-5-phosphate to prealnumycin by formation of the C(8)-C(1') bond as demonstrated by the structure of the intermediate alnumycin P. This compound is subsequently dephosphorylated by AlnB, an enzyme of the haloacid dehalogenase superfamily. Structure determination of the native trimeric AlnA to 2.1-Å resolution revealed a highly globular fold encompassing an α/ß/α sandwich. The crystal structure of the complex with D-ribose-5-phosphate indicated that the phosphosugar is bound in the open-chain configuration. Identification of residues E29, K86, and K159 near the C-1 carbonyl of the ligand led us to propose that the carbon-carbon bond formation proceeds through a Michael-type addition. Determination of the crystal structure of the monomeric AlnB in the open conformation to 1.25-Å resolution showed that the protein consists of core and cap domains. Modeling of alnumycin P inside the cap domain positioned the phosphate group next to a Mg(2+) ion present at the junction of the domains. Mutagenesis data were consistent with the canonical reaction mechanism for this enzyme family revealing the importance of residues D15 and D17 for catalysis. The characterization of the prealnumycin C-ribosylation illustrates an alternative means for attachment of carbohydrates to natural products.

Thermal unfolding studies of cold adapted uracil-DNA N-glycosylase (UNG) from Atlantic cod (Gadus morhua). A comparative study with human UNG.

Uracil-DNA N-glycosylase (UNG; EC 3.2.2.27) from Atlantic cod (cUNG) possesses cold adapted features like increased catalytic efficiency and reduced temperature optimum for activity compared to its warm-adapted homologue human UNG (hUNG). Here, we present the first thermal stability analysis of cUNG and hUNG by differential scanning calorimetry (DSC), and the results showed that cUNG is less stable than hUNG and unfolds at a melting temperature (T(m)) 9° lower than its warm-adapted homologue. In addition, an ion-pair (D183-K302) suggested to be crucial for global stability of hUNG was investigated by biochemical characterization and DSC of four mutants (cUNG G183D and cUNG G183D-R302K, hUNG D183G and hUNG D183G-K302R). The hUNG mutants with an expected disruption of the ion-pair showed a slight increase in stability with concomitant reduction in the enzyme activity, while the apparent introduction of the ion-pair in cUNG caused a reduction in the enzyme activity but no increase in stability. Because the mutants did not behave as expected, the phenomenon was further investigated by crystal structure determination. Indeed, the crystal structure of the hUNG D183G-K302R mutant revealed that compensating interactions for the loss of the ion-pair were generated close to and in regions distant from the mutation site. In conclusion, the reduced stability of cUNG supports the suggested requirement of a flexible structure for improved activity at low temperatures. Furthermore, the lack of a direct correlation between enzyme activity and global stability of the mutants supports the significance of distributing locally flexible and/or rigid regions for modulation of enzyme activity.

Effects of salt on the kinetics and thermodynamic stability of endonuclease I from Vibrio salmonicida and Vibrio cholerae.

Adaptation to extreme environments affects the stability and catalytic efficiency of enzymes, often endowing them with great industrial potential. We compared the environmental adaptation of the secreted endonuclease I from the cold-adapted marine fish pathogen Vibrio salmonicida (VsEndA) and the human pathogen Vibrio cholerae (VcEndA). Kinetic analysis showed that VsEndA displayed unique halotolerance. It retained a considerable amount of activity from low concentrations to at least 0.6 m NaCl, and was adapted to work at higher salt concentrations than VcEndA by maintaining a low K(m) value and increasing k(cat). In differential scanning calorimetry, salt stabilized both enzymes, but the effect on the calorimetric enthalpy and cooperativity of unfolding was larger for VsEndA, indicating salt dependence. Mutation of DNA binding site residues (VsEndA, Q69N and K71N; VcEndA, N69Q and N71K) affected the kinetic parameters. The VsEndA Q69N mutation also increased the T(m) value, whereas other mutations affected mainly DeltaH(cal). The determined crystal structure of VcEndA N69Q revealed the loss of one hydrogen bond present in native VcEndA, but also the formation of a new hydrogen bond involving residue 69 that could possibly explain the similar T(m) values for native and N69Q-mutated VcEndA. Structural analysis suggested that the stability, catalytic efficiency and salt tolerance of EndA were controlled by small changes in the hydrogen bonding networks and surface electrostatic potential. Our results indicate that endonuclease I adaptation is closely coupled to the conditions of the habitats of natural Vibrio, with VsEndA displaying a remarkable salt tolerance unique amongst the endonucleases characterized so far.

Comparative studies of endonuclease I from cold-adapted Vibrio salmonicida and mesophilic Vibrio cholerae.

Endonuclease I is a periplasmic or extracellular enzyme present in many different Proteobacteria. The endA gene encoding endonuclease I from the psychrophilic and mildly halophilic bacterium Vibrio salmonicida and from the mesophilic brackish water bacterium Vibrio cholerae have been cloned, over-expressed in Escherichia coli, and purified. A comparison of the enzymatic properties shows large differences in NaCl requirements, optimum pH, temperature stability and catalytic efficiency of the two proteins. The V. salmonicida EndA shows typical cold-adapted features such as lower unfolding temperature, lower temperature optimum for activity, and higher specific activity than V. cholerae EndA. The thermodynamic activation parameters confirm the psychrophilic nature of V. salmonicida EndA with a much lower activation enthalpy. The optimal conditions for enzymatic activity coincide well with the corresponding optimal requirements for growth of the organisms, and the enzymes function predominantly as DNases at physiological concentrations of NaCl. The periplasmic or extracellular localization of the enzymes, which renders them constantly exposed to the outer environment of the cell, may explain this fine-tuning of biochemical properties.

Comparative expression study to increase the solubility of cold adapted Vibrio proteins in Escherichia coli.

Functional and structural studies require gene overexpression and purification of soluble proteins. We wanted to express proteins from the psychrophilic bacterium Vibrio salmonicida in Escherichia coli, but encountered solubility problems. To improve the solubility of the proteins, we compared the effects of six N-terminal fusion proteins (Gb1, Z, thioredoxin, GST, MBP and NusA) and an N-terminal His6-tag. The selected test set included five proteins from the fish pathogen V. salmonicida and two related products from the mesophilic human pathogen Vibrio cholerae. We tested the expression in two different expression strains and at three different temperatures (16, 23 and 37 degrees C). His6-tag was the least effective tag, and these vector constructs were also difficult to transform. MBP and NusA performed best, expressing soluble proteins with all fusion partners in at least one of the cell types. In some cases MBP, GST and thioredoxin fusions resulted in products of incorrect size. The effect of temperature is complex: in most cases level of expression increased with temperature, whereas the effect on solubility was opposite. We found no clear connection between the preferred expression temperature of the protein and the temperature of the original host organism's natural habitat.

Effects of active site mutations on the metal binding affinity, catalytic competence, and stability of the family II pyrophosphatase from Bacillus subtilis.

Family II inorganic pyrophosphatases (PPases) have been recently found in a variety of bacteria. Their primary and tertiary structures differ from those of the well-known family I PPases, although both have a binuclear metal center directly involved in catalysis. Here, we examined the effects of mutating one Glu, four His, and five Asp residues forming or close to the metal center on Mn(2+) binding affinity, catalysis, oligomeric structure, and thermostability of the family II PPase from Bacillus subtilis (bsPPase). Mutations H9Q, D13E, D15E, and D75E in two metal-binding subsites caused profound (10(4)- to 10(6)-fold) reductions in the binding affinity for Mn(2+). Most of the mutations decreased k(cat) for MgPP(i) by 2-3 orders of magnitude when measured with Mn(2+) or Mg(2+) bound to the high-affinity subsite and Mg(2+) bound to both the low-affinity subsite and pyrophosphate. In the E78D variant, the k(cat) for the Mn-bound enzyme was decreased 120-fold, converting bsPPase from an Mn-specific to an Mg-specific enzyme. K(m) values were less affected by the mutations, and, interestingly, were decreased in most cases. Mutations of His(97) and His(98) residues, which lie near the subunit interface, greatly destabilized the bsPPase dimer, whereas most other mutations stabilized it. Mn(2+), in sharp contrast to Mg(2+), conferred high thermostability to wild-type bsPPase, although this effect was reduced by all of the mutations except D203E. These results indicate that family II PPases have a more integrated active site structure than family I PPases and are consequently more sensitive to conservative mutations.