In vivo characterization of the dTDP-D-desosamine pathway of the megalomicin gene cluster from Micromonospora megalomicea

In vivo reconstitution of the dTDP-D-desosamine pathway of the megalomicin gene cluster from Micromonospora megalomicea was achieved by expression of the genes in Escherichia coli. LC/MS/MS analysis of the dTDP-sugar intermediates produced by operons containing different sets of genes showed that production of dTDP-D-desosamine from dtdp-4-keto-6-deoxy-D-glucose requires only four biosynthetic steps, catalysed by MegCIV, MegCV, MegDII and MegDIII, and that MegCII is not involved. Instead, bioconversion studies demonstrated that MegCII is needed together with MegCIII to catalyse transfer of D-desosamine to 3-alpha-mycarosylerythronolide B.

Site-specific replacement of Y356 with 3,4-dihydroxyphenylalanine in the beta2 subunit of E. coli ribonucleotide reductase

E. coli ribonucleotide reductase (RNR), composed of the homodimeric subunits alpha2 and beta2, catalyzes the conversion of nucleotides to deoxynucleotides via complex radical chemistry. The radical initiation process involves a putative proton-coupled electron transfer (PCET) pathway over 35 A between alpha2 and beta2. Y356 in beta2 has been proposed to lie on this pathway. To test this model, intein technology has been used to make beta2 semi-synthetically in which Y356 is replaced with a DOPA-amino acid. Analysis of this mutant with alpha2 and various combinations of substrate and effector by SF UV-vis spectroscopy and EPR methods demonstrates formation of a DOPA radical concomitant with disappearance of the tyrosyl radical, which initiates the reaction. The results reveal that Y356 lies on the PCET pathway and demonstrate the first kinetically competent conformational changes prior to ET. They further show that substrate binding brings about rapid conformational changes which place the complex into its active form(s) and suggest that the RNR complex is asymmetric.

Tri-nucleotide threading for parallel amplification of minute amounts of genomic DNA

Efforts to correlate genetic variations with phenotypic differences are intensifying due to the availability of high-density maps of single nucleotide polymorphisms (SNPs) and the development of high throughput scoring methods. These recent advances have led to an increased interest for improved multiplex preparations of genetic material to facilitate such whole genome analyses. Here we propose a strategy for the parallel amplification of polymorphic loci based on a reduced set of nucleotides. The technique denoted Tri-nucleotide Threading (TnT), allows SNPs to be amplified via controlled linear amplification followed by complete removal of the target material and subsequent amplification with a pair of universal primers. A dedicated software tool was developed for this purpose and variable positions in genes associated with different forms of cancer were analyzed using sub-nanogram amounts of starting material. The amplified fragments were then successfully scored using a microarray-based PrASE technique. The results of this study, in which 75 SNPs were analyzed, show that the TnT technique circumvents potential problems associated with multiplex amplification of SNPs from minute amounts of material. The technique is specific, sensitive and can be readily adapted to equipment and genotyping techniques used in other research laboratories without requiring changes to the preferred typing method.

Differentiation of estriol glucuronide isomers by chemical derivatization and electrospray tandem mass spectrometry

This paper describes a way of differentiating between the three isomers of estriol glucuronide by the use of chemical derivatization and liquid chromatography/electrospray tandem mass spectrometry (MS/MS). In their native form, these isomers gave rise to almost identical product ion spectra, involving the neutral loss of 176 Da (i.e. monodehydrated glucuronic acid), which made it impossible to determine the position of conjugation by MS/MS alone. In order to change the fragmentation pathways, positive charges were introduced into the analytes by chemical derivatization. The following reagents were tested: 2-chloro-1-methylpyridinium iodide, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide and 2-picolylamine. Interestingly, derivatization using a combination of all three reagents gave a selective fragmentation pattern that could differentiate between the isomers estriol-16-glucuronide and estriol-17-glucuronide. Estriol-3-glucuronide, which lacks a free phenolic group, could be differentiated through a different type of reaction product when exposed to 2-chloro-1-methylpyridinium iodide. Furthermore, in order to assist structural assignment of the fragments, their accurate masses were determined using a hybrid quadrupole time-of-flight mass spectrometer and fragmentation pathways were elucidated by the use of MS3 on an ion trap mass spectrometer.

Kinetic evidence for interaction of human immunodeficiency virus type 1 reverse transcriptase with the 3'-OH of the incoming dTTP substrate

Two previously identified human immunodeficiency virus type 1 (HIV-1) reverse transcriptase (RT) mutants, Q151N and V148I, are known to have reduced dNTP binding affinity but possess wild-type chemical catalysis rates. Structural modeling based on the crystal structure of the HIV-1 RT ternary complex with dTTP proposes that Q151N loses the interaction with the 3'-OH of the incoming dTTP and that V148I disrupts positioning of Q151 for this interaction. On the basis of this, we predicted that while wild-type (WT) HIV-1 RT would have decreased binding affinity to dTTP analogues lacking 3'-OH, compared to dTTP, the Q151N and V148I RT mutants should have decreased but similar affinity to both dTTP and dTTP analogues. Pre-steady-state kinetics on WT RT showed 14- and 53-fold higher K(d) values for the 3'-OH lacking ddTTP and acyTTP, compared to dTTP. In contrast, the Q151N and V148I mutants, which were predicted to have lost H-bonding interaction with the 3'-OH of dTTP, showed higher but similar K(d) values for dTTP, ddTTP, and acyTTP. Interestingly, the Q151N and V148I RTs bound to AZTTP approximately 12 and 18 times more tightly than to dTTP, respectively. Our structure modeling suggests that these RT mutants can interact with the azido moiety of AZTTP, which is 1.4 A longer than the 3'-OH of dTTP. The kinetic data presented in this report demonstrate the functional role of the Q151 residue in HIV-1 RT interaction with dTTP and its analogues containing chemical modifications at the 3'-C of the sugar moiety.

Synthesis of carbocyclic nucleotides as potential substrates for thymidylate kinase

Enantiomerically pure carbocyclic 2'-deoxy-3'-azidothymidine monophosphate (AZTMP) and carba-2'deoxy-3'-thiocyanatothymidine monophosphate were synthesized to study their behavior toward their phosphorylation by thymidylate kinase. The nucleotides were synthesized starting from the parent nucleosides by an alkaline hydrolysis of the corresponding cycloSal-phosphate triesters.

Synthesis of 5-(1-propynyl)-2'-deoxyuridine 5'-(alpha-P-borano)triphosphate and kinetic characterization as a substrate for mmlv reverse transcriptase

In order to introduce pyrimidine C5-propynyl modification into boranophosphate oligodeoxyribonucleotides (BP- ODNs), 5-(1-propynyl)-2'-deoxyuridine 5'-(alpha-P-borano) triphosphate (d5PUTPalphaB) was synthesized. The two diastereomers were separated by reverse-phase HPLC. Kinetic studies showed that the Rp isomer was a slightly better substrate for MMLV reverse transcriptase than thymidine triphosphate or Rp-thymidine 5'-(alpha-P-borano)triphosphate. Using the Rp isomers of d5PUTPalphaB and the other three 5'-(alpha-P-borano) triphosphates, a DNA primer could be extended to the full length of the template.

Four-color multiplex reverse transcription polymerase chain reaction--overcoming its limitations

Quantitative reverse transcription polymerase chain reaction (qRT-PCR) conducted in real time is a powerful tool for measuring messenger RNA (mRNA) levels in biological samples. Multiplex PCR is defined as the simultaneous amplification of two or more DNA (cDNA) targets in a single reaction vessel and may be carried out only using uniquely labeled probes for each target. Up to four genes can be detected in a multiplex 5' nuclease assay when using the appropriate instrument and the right combination of fluorophores. One of the more important advantages of multiplexing is a reduced sample requirement, which is especially important when sample material is scarce. Additional benefits are saving time on reaction setup and lower cost compared to singleplex reactions. Although multiplexing has several advantages over singleplex qRT-PCR, limited work has been done to show its feasibility. Few publications on four-color multiplex qRT-PCR have been reported, and to our knowledge no work has been done to explore the assay's limitations. In this paper, we report the first in-depth analysis of a four-gene multiplex qRT-PCR. To achieve a better understanding of the potential limitations of the qRT-PCR assay, we used in vitro transcribed RNA derived from four human genes. To emulate gene expression experiments, we developed a model system in which the in vitro transcripts were spiked with plant total RNA. This model allowed us to develop an artificial system closely resembling differential gene expression levels varying up to a million fold. We identified a single "universal" reaction condition that enabled optimal amplification in real time of up to four genes over a wide range of template concentrations. This study shows that multiplexing is a feasible approach applicable to most qRT-PCR assays performed with total RNA, independent of the expression levels of the genes under scrutiny.

Sodium chloride-induced self-assembly of microfibers from nanofiber components

Self-assembly of a nucleotide bolaamphiphile, terminated with two nucleotide moieties including thymine, deoxyribose, and phosphodiester at both ends of the C20 oligomethylene chain, in sodium chloride aqueous solutions has been studied by SEM, LSM, FE-SEM, micro-FTIR, and zeta-potential measurement. The self-assembly behavior of the nucleotide bolaamphiphile was strongly dependent on the concentration of sodium chloride added. The nucleotide bolaamphiphile was found to hierarchically self-assemble to form micrometer-sized fibers (microfibers) consisting of bundles of entangled nanometer-sized fibers (nanofibers) under certain conditions of sodium chloride concentration (approximately 44 mM). The zeta-potential measurement suggested that the surface-charge tuning of the nanofibers induce the hierarchical self-assembly of the microfibers.

Novel synthesis and characterization of bioconjugate block copolymers having oligonucleotides

Novel and efficient synthesis of polymers terminated with nucleotides via the phosphoramidite method has been developed. A hydroxyl-terminated polymer was converted into a polymer capped with a nucleotide in three steps, where the conversion of the reactions was very high, almost 100%. By repetition of this synthetic method, a block copolymer composed of a synthetic polymer, polystyrene, and biological oligonucleotides with thymidine units has been successfully synthesized. A microphase-separated structure of this block copolymer was observed by both transmission electron microscopy and small-angle X-ray scattering, and a cylindrical structure was confirmed.

Effect of DNA polymerase beta loop variants on discrimination of O6-methyldeoxyguanosine modification present in the nucleotide versus template substrate

We have examined the mechanism of DNA polymerase beta (pol beta) lesion discrimination using alkylated dNTP versus alkylated DNA template substrates and the pol beta variants R253M and E249K. Both of these amino acid variants are located in the loop region of the palm domain and are known to play a role in pol beta fidelity and discrimination of 3'-azido-3'-deoxythymidine triphosphate substrates. We observed that these variants affect O(6)-methyldeoxyguanosine- (m6G-) modified dNTP discrimination without affecting m6G template translesion synthesis. Under steady-state conditions, the ratio of inherent reactivity values for the m6dGTP substrate relative to the dGTP substrate was greater for both variant polymerases than for wild-type (WT) pol beta. Biochemical assays of translesion synthesis using m6G lesion-containing templates demonstrated no significant differences between the variants and WT. Using N-methyl-N-nitrosourea- (MNU-) modified DNA templates in the HSV-tk in vitro assay, no difference among the enzymes in the frequency of alkylation-induced G to A transition mutations was observed. However, differences among the polymerases in the frequency of alkylation-induced C to A transversions were observed, consistent with a mutator tendency for E249K and an antimutator tendency for R253M. We conclude that a specific interaction at the loop of the palm domain is involved in pol beta discrimination of the m6G lesion when present on the incoming dNTP substrate but not when present in the DNA template. Our data support a role for the flexible loop in pol beta error discrimination.

An enzyme module system for the synthesis of dTDP-activated deoxysugars from dTMP and sucrose

A flexible enzyme module system is presented that allows preparative access to important dTDP-activated deoxyhexoses from dTMP and sucrose. The strategic combination of the recombinant enzymes dTMP-kinase and sucrose synthase (SuSy), and the enzymes RmlB (4,6-dehydratase), RmlC (3,5-epimerase) and RmlD (4-ketoreductase) from the biosynthetic pathway of dTDP-beta-L-rhamnose was optimized. The SuSy module (dTMP-kinase, SuSy, +/-RmlB) yielded the precursor dTDP-alpha-D-glucose (2) or the biosynthetic intermediate dTDP-6-deoxy-4-keto-alpha-D-glucose (3) on a 0.2-0.6 g scale with overall yields of 62 % and 72 %, respectively. A two-step strategy in which the SuSy module was followed by the deoxysugar module (RmlC and RmlD) resulted in the synthesis of dTDP-beta-L-rhamnose (4; 24.1 micromol, overall yield: 35.9 %). Substitution of RmlC by DnmU from the dTDP-beta-L-daunosamine pathway of Streptomyces peucetius in this module demonstrated that DnmU acts in vitro as a 3,5-epimerase with 3 as substrate to yield 4 (32.2 mumol, overall yield: 44.7 %). Chemical reduction of 3 with NaBH4 gave a mixture of the C-4 epimers dTDP-alpha-D-quinovose (6) and dTDP-alpha-D-fucose (7) in a ratio of 2:1. In summary, the modular character of the presented enzyme system provides valuable compounds for the biochemical characterization of deoxysugar pathways playing a major role in microbial producers of antibiotic and antitumour agents.

The use of thymidine analogs to improve the replication of an extra DNA base pair: a synthetic biological system

Synthetic biology based on a six-letter genetic alphabet that includes the two non-standard nucleobases isoguanine (isoG) and isocytosine (isoC), as well as the standard A, T, G and C, is known to suffer as a consequence of a minor tautomeric form of isoguanine that pairs with thymine, and therefore leads to infidelity during repeated cycles of the PCR. Reported here is a solution to this problem. The solution replaces thymidine triphosphate by 2-thiothymidine triphosphate (2-thioTTP). Because of the bulk and hydrogen bonding properties of the thione unit in 2-thioT, 2-thioT does not mispair effectively with the minor tautomer of isoG. To test whether this might allow PCR amplification of a six-letter artificially expanded genetic information system, we examined the relative rates of misincorporation of 2-thioTTP and TTP opposite isoG using affinity electrophoresis. The concentrations of isoCTP and 2-thioTTP were optimal to best support PCR amplification using thermostable polymerases of a six-letter alphabet that includes the isoC–isoG pair. The fidelity-per-round of amplification was found to be ∼98% in trial PCRs with this six-letter DNA alphabet. The analogous PCR employing TTP had a fidelity-per-round of only ∼93%. Thus, the A, 2-thioT, G, C, isoC, isoG alphabet is an artificial genetic system capable of Darwinian evolution.

Mechanochemistry of t7 DNA helicase

The bacteriophage T7 helicase is a ring-shaped hexameric motor protein that unwinds double-stranded DNA during DNA replication and recombination. To accomplish this it couples energy from the nucleotide hydrolysis cycle to translocate along one of the DNA strands. Here, we combine computational biology with new biochemical measurements to infer the following properties of the T7 helicase: (1) all hexameric subunits are catalytic; (2) the mechanical movement along the DNA strand is driven by the binding transition of nucleotide into the catalytic site; (3) hydrolysis is coordinated between adjacent subunits that bind DNA; (4) the hydrolysis step changes the affinity of a subunit for DNA allowing passage of DNA from one subunit to the next. We construct a numerical optimization scheme to analyze transient and steady-state biochemical measurements to determine the rate constants for the hydrolysis cycle and determine the flux distribution through the reaction network. We find that, under physiological and experimental conditions, there is no dominant pathway; rather there is a distribution of pathways that varies with the ambient conditions. Our analysis methods provide a systematic procedure to study kinetic pathways of multi-subunit, multi-state cooperative enzymes.

[Photoreactive dTTP analogues as substrates for thermostable DNA polymerase from Thermus thermophilus B35]

Substrate properties of several dTTP analogues bearing a photoreactive 2-nitro-5-azidobenzoyl (NAB) group attached at position 5 of uracil through linkers of various lengths, dTTP-NAB-x-dUTP (where x = 2, 4, 7-13 is the number of atoms in the linker), were studied. All the analogues are substrates for thermostable Thermus thermophilus B35 DNA polymerase in the elongation reaction of the 5'-32P-labeled primer-template complex. The kinetic parameters of some of the analogues were determined and compared with those of natural dTTP. It was shown that an increase in the linker length results in a higher efficiency of the analogue. The incorporation of NAB-x-dUMP residues into the 3'-primer end did not impede a further elongation of the chain in the presence of natural dNTP.

[The study of coupling agents for the phosphorylation of 3'-azido-3'-deoxythymidine with (P32)orthophosphoric acid]

The kinetics of 3'-azido-3'-deoxythymidine phosphorylation with [32P]orthophosphoric acid was studied in the presence of various coupling agents. The most effective method with the use of BrCN provided the isolation of the target 3'-azido-3'-deoxythymidine 5'-[32P]monophosphate in 46% yield and a high specific radioactivity (>100 Ci/mmol).

Evidence for Watson-Crick and not Hoogsteen or wobble base pairing in the selection of nucleotides for insertion opposite pyrimidines and a thymine dimer by yeast DNA pol eta

We have recently reported that pyrene nucleotide is preferentially inserted opposite an abasic site, the 3'-T of a thymine dimer, and most undamaged bases by yeast DNA polymerase eta (pol eta). Because pyrene is a nonpolar molecule with no H-bonding ability, the unusually high efficiencies of dPMP insertion are ascribed to its superior base stacking ability, and underscore the importance of base stacking in the selection of nucleotides by pol eta. To investigate the role of H-bonding and base pair geometry in the selection of nucleotides by pol eta, we determined the insertion efficiencies of the base-modified nucleotides 2,6-diaminopurine, 2-aminopurine, 6-chloropurine, and inosine which would make a different number of H-bonds with the template base depending on base pair geometry. Watson-Crick base pairing appears to play an important role in the selection of nucleotide analogues for insertion opposite C and T as evidenced by the decrease in the relative insertion efficiencies with a decrease in the number of Watson-Crick H-bonds and an increase in the number of donor-donor and acceptor-acceptor interactions. The selectivity of nucleotide insertion is greater opposite the 5'-T than the 3'-T of the thymine dimer, in accord with previous work suggesting that the 5'-T is held more rigidly than the 3'-T. Furthermore, insertion of A opposite both Ts of the dimer appears to be mediated by Watson-Crick base pairing and not by Hoogsteen base pairing based on the almost identical insertion efficiencies of A and 7-deaza-A, the latter of which lacks H-bonding capability at N7. The relative efficiencies for insertion of nucleotides that can form Watson-Crick base pairs parallel those for the Klenow fragment, whereas the Klenow fragment more strongly discriminates against mismatches, in accord with its greater shape selectivity. These results underscore the importance of H-bonding and Watson-Crick base pair geometry in the selection of nucleotides by both pol eta and the Klenow fragment, and the lesser role of shape selection in insertion by pol eta due to its more open and less constrained active site.

Dissecting the effects of DNA polymerase and ribonuclease H inhibitor combinations on HIV-1 reverse-transcriptase activities

Although HIV-1 reverse transcriptase (RT) DNA polymerase and ribonuclease H (RNase H) activities reside in spatially distinct domains of the enzyme, inhibitors that bind in the RT polymerase domain can affect RNase H activity. We used both gel assays and a real-time FRET assay to analyze the impact of three mechanistically distinct RT polymerase inhibitors on RNase H activity in vitro. The nucleoside analogue 3'-azido-3'-deoxythymidine triphosphate (AZT-TP) had no effect, whereas the pyrophosphate analogue phosphonoformate (PFA) inhibited RNase H activity in a concentration-dependent manner. Nonnucleoside RT inhibitors (NNRTIs) enhanced RNase H catalysis, but the cleavage products differed substantially for RNA/DNA hybrid substrates of different lengths. A comparison of 61 different RT crystal structures revealed that NNRTI binding opened the angle between the polymerase and RNase H domains of the p66 subunit and reduced the relative motion of the thumb and RNase H regions, suggesting that NNRTI enhancement of RNase H cleavage may result from increased accessibility of the RNase H active site to the RNA/DNA hybrid duplex. We also examined the effects of combining a diketo acid (DKA) RNase H inhibitor with various RT polymerase inhibitors on polymerase-independent RNase H cleavage, RNA-dependent DNA polymerization, and in reverse-transcription assays. Interestingly, although the NNRTI decreased DKA potency in polymerase-independent RNase H assays, NNRTI/DKA combinations were synergistic in inhibiting reverse transcription overall, indicating that regimens incorporating both NNRTI and RNase H inhibitors may be therapeutically beneficial.

Functional characterizations of novWUS involved in novobiocin biosynthesis from Streptomyces spheroides

NovW, novU, and novS gene products represent dTDP-4-keto-6-deoxy-D-glucose 3,5 epimarase, C-methyltransferase and dTDP-glucose-4-ketoreductase involved in noviose biosynthetic pathway, respectively. We have expressed three genes to elucidate the functions of NovW, NovU, and NovS in Escherichia coli. NovW and NovU catalyze the formation of dTDP-4-keto-6-deoxy-5-C-methyl-L-lyxo-hexose from dTDP-4-keto-6-deoxy-D-glucose. NovS reduces the product formed from the reaction of NovW with dTDP-4-keto-6-deoxy-D-glucose in the presence of NADH to result in dTDP-l-rhamnose. Furthermore, a pathway for the biosynthesis of noviose is proposed.

Biochemical characterization of TT1383 from Thermus thermophilus identifies a novel dNTP triphosphohydrolase activity stimulated by dATP and dTTP

The HD domain motif is found in a superfamily of proteins in bacteria, archaea and eukaryotes. A few of these proteins are known to have metal-dependant phosphohydrolase activity, but the others are functionally unknown. Here we have characterized an HD domain-containing protein, TT1383, from Thermus thermophilus HB8. This protein has sequence similarity to Escherichia coli dGTP triphosphohydrolase, however, no dGTP hydrolytic activity was detected. The hydrolytic activity of the protein was determined in the presence of more than two kinds of deoxyribonucleoside triphosphates (dNTPs), which were hydrolyzed to their respective deoxyribonucleosides and triphosphates, and was found to be strictly specific for dNTPs in the following order of relative activity: dCTP > dGTP > dTTP > dATP. Interestingly, this dNTP triphosphohydrolase (dNTPase) activity requires the presence of dATP or dTTP in the dNTP mixture. dADP, dTDP, dAMP, and dTMP, which themselves were not hydrolyzed, were nonetheless able to stimulate the hydrolysis of dCTP. These results suggest the existence of binding sites specific for dATP and dTTP as positive modulators, distinct from the dNTPase catalytic site. This is, to our knowledge, the first report of a non-specific dNTPase that is activated by dNTP itself.

A novel method for the preparation of nucleoside triphosphates from activated nucleoside phosphoramidates

[reaction: see text] A novel method for the preparation of nucleoside triphosphates has been developed. The strategy employs a highly reactive pyrrolidinium phosphoramidate zwitterion intermediate that undergoes efficient coupling with tris(tetra-n-butylammonium) hydrogen pyrophosphate to generate nucleoside triphosphate.

Inhibition of phosphorolysis catalyzed by HIV-1 reverse transcriptase is responsible for the synergy found in combinations of 3'-azido-3'-deoxythymidine with nonnucleoside inhibitors

In spite of the growing attention to the combined chemotherapy in the treatment of AIDS, the molecular mechanisms underlying the antiviral synergy of combinations of reverse transcriptase (RT) inhibitors are in most cases unknown. Most combinations of nonnucleoside inhibitors (NNRTI) with nucleoside analogues synergistically inhibit HIV-1 replication in cell culture, though they fail to show synergy in enzymatic assays. In this work we have examined the mechanisms mediating the synergy in combinations of AZTTP with NNRTIs on HIV-1 RT and their possible relevance in antiretroviral therapy. We found that if two inhibitors bind either to different sites on the RT or to the same site but to different mechanistic forms, it is always possible to find conditions in which their combination results in synergistic inhibition of DNA polymerase activity. Though these analyses are interesting from a biochemical point of view, this kind of synergy is unlikely to play any role in vivo, since this positive interaction is lost under the conditions present in viral replication. Here we describe that the synergy found for combinations of NNRTI with AZT is due not to the inhibition of the DNA polymerase activity but to the inhibition of the RT-catalyzed phosphorolysis by the NNRTI. While phosphorolytical removal of the AZT-terminated primer has been related to the mechanism of resistance toward AZT, our data suggest that a basal phosphorolysis occurs even with the wild-type enzyme, and that the inhibition of this activity could explain the synergy found in antiviral assays.

Structure of a type II thymidine kinase with bound dTTP

The structure of human cytosolic thymidine kinase in complex with its feedback inhibitor 2'-deoxythymidine-5'-triphosphate was determined. This structure is the first representative of the type II thymidine kinases found in several pathogens. The structure deviates strongly from the known structures of type I thymidine kinases such as the Herpes simplex enzyme. It contains a zinc-binding domain with four cysteines complexing a structural zinc ion. Interestingly, the backbone atoms of the type II enzyme bind thymine via hydrogen-bonds, in contrast to type I, where side chains are involved. This results in a specificity difference exploited for antiviral therapy. The presented structure will foster the development of new drugs and prodrugs for numerous therapeutic applications.

Abnormalities in uridine homeostatic regulation and pyrimidine nucleotide metabolism as a consequence of the deletion of the uridine phosphorylase gene

We report in the present study the critical role of uridine phosphorylase (UPase) in uridine homeostatic regulation and pyrimidine nucleotide metabolism, employing newly developed UPase-/- mice. Our data demonstrate that the abrogation of UPase activity led to greater than a 6-fold increase in uridine concentrations in plasma, a 5-6-fold increase in lung and gut, and a 2-3-fold increase in liver and kidney, as compared with wild type mice. Urine uridine levels increased 24-fold normal in UPase-/- mice. Uridine half-life and the plasma retention of pharmacological doses of uridine were significantly prolonged. Further, in these UPase-/- mice, abnormal uridine metabolism led to disorders of various nucleotide metabolisms. In the liver, gut, kidney, and lung of UPase-/- mice, total uridine ribonucleotide concentrations increased 2-3 times as compared with control mice. Cytidine ribonucleotides and adenosine and guanosine ribonucleotides also increased, although to a lesser extent, in these organs. Most significant deoxyribonucleotide changes were present in the gut and lung of UPase-/- mice. In these tissues, dTTP concentration increased more than 4-fold normal, and dCTP, dGTP, and dATP concentrations rose 1-2 times normal. In kidney, dTTP concentration increased 2-fold normal, and dCTP and dGTP concentrations rose less than 1-fold normal. In addition, the accumulated uridine in plasma and tissues efficiently reduced 5-fluorouracil host toxicity and altered the anesthetic effect of pentobarbital. These data indicate that UPase is a critical enzyme in the regulation of uridine homeostasis and pyrimidine nucleotide metabolism, and 5-fluorouracil activity.

The crystal structure of Mycobacterium tuberculosis thymidylate kinase in complex with 3'-azidodeoxythymidine monophosphate suggests a mechanism for competitive inhibition

Tuberculosis (TB) is the primary cause of mortality among infectious diseases. Mycobacterium tuberculosis thymidylate kinase (TMPK(Mtub)) catalyzes the ATP-dependent phosphorylation of deoxythymidine 5'-monophosphate (dTMP). Essential to DNA replication, this enzyme represents a promising target for developing new drugs against TB, because the configuration of its active site is unique within the TMPK family. Indeed, it has been proposed that, as opposed to other TMPKs, catalysis by TMPK(Mtub) necessitates the transient binding of a magnesium ion coordinating the phosphate acceptor. Moreover, 3'-azidodeoxythymidine monophosphate (AZTMP) is a competitive inhibitor of TMPK(Mtub), whereas it is a substrate for human and other TMPKs. Here, the crystal structures of TMPK(Mtub) in complex with deoxythymidine (dT) and AZTMP were determined to 2.1 and 2.0 A resolution, respectively, and suggest a mechanism for inhibition. The azido group of AZTMP perturbs the induced-fit mechanism normally adopted by the enzyme. Magnesium is prevented from binding, and the resulting electrostatic environment precludes phosphoryl transfer from occurring. Our data provide a model for drug development against tuberculosis.