MluI site-dependent transcriptional regulation of the Candida albicans dUTPase gene

Linking uracil base excision repair and 5-fluorouracil toxicity in yeast

5-fluorouracil (5-FU) is a widely used anticancer drug that disrupts pyrimidine nucleotide pool balances and leads to uracil incorporation in DNA, which is then recognized and removed by the uracil base excision repair (BER) pathway. Using complementary biochemical and genetic approaches we have examined the role of uracil BER in the cell killing mechanism of 5-FU. A yeast strain lacking the enzyme uracil DNA glycosylase (Ung1), which excises uracil from the DNA backbone leaving an abasic site, showed significant protection against the toxic effects of 5-FU, a G1/S cell cycle arrest phenotype, and accumulated massive amounts of U/A base pairs in its genome (approximately 4% of T/A pairs were now U/A). A strain lacking the major abasic site endonuclease of Saccharomyces cerevisiae (Apn1) showed significantly increased sensitivity to 5-FU with G2/M arrest. Thus, efficient processing of abasic sites by this enzyme is protective against the toxic effects of 5-FU. However, contrary to expectations, the Apn1 deficient strain did not accumulate intact abasic sites, indicating that another repair pathway attempts to process these sites in the absence Apn1, but that this process has catastrophic effects on genome integrity. These findings suggest that new strategies for chemical intervention targeting BER could enhance the effectiveness of this widely used anticancer drug.

Identification and function of a shrimp white spot syndrome virus (WSSV) gene that encodes a dUTPase

The ORF wsv112 of shrimp white spot syndrome virus (WSSV) was predicted to encode a protein with five conserved motifs at its N-terminus characteristics of dUTPases. The transcription of the gene named as wdut was analyzed by RT-PCR and RACE. The C-terminal end of the putative WSSV dUTPase bore very low similarity to the reported dUTPases and any other known proteins. Therefore, the 5'-terminal region (528-bp) of wdut gene was expressed in E. coli. The recombinant WSSV dUTPase (WDUT) with a molecular mass of 23 kDa could catalyze the hydrolysis of dUTP into dUMP and was highly specific for dUTP with an apparent Km of 1.2 microM. Furthermore, gel filtration results revealed that this enzyme was a trimer.

Developmental regulation of dUTPase in Drosophila melanogaster

dUTPase prevents uracil incorporation into DNA by strict regulation of the cellular dUTP:dTTP ratio. Lack of the enzyme initiates thymineless cell death, prompting studies on enzyme regulation. We investigated expression pattern and localization of Drosophila dUTPase. Similarly to human, two isoforms of the fly enzyme were identified at both mRNA and protein levels. During larval stages, a drastic decrease of dUTPase expression was demonstrated at the protein level. In contrast, dUTPase mRNAs display constitutive character throughout development. A putative nuclear localization signal was identified in one of the two isoforms. However, immunohistochemistry of ovaries and embryos did not show a clear correlation between the presence of this signal and subcellular localization of the protein, suggesting that the latter may be perturbed by additional factors. Results are in agreement with a multilevel regulation of dUTPase in the Drosophila proteome, possibly involving several interacting protein partners of the enzyme. Using independent approaches, the existence of such macromolecular partners was verified.

Kinetic properties and inhibition of the dimeric dUTPase-dUDPase from Leishmania major

Kinetic properties of the dimeric enzyme dUTPase from Leishmania major were studied using a continuous spectrophotometric method. dUTP was the natural substrate and dUMP and PPi the products of the hydrolysis. The trypanosomatid enzyme exhibited a low K(m) value for dUTP (2.11 microM), a k(cat) of 49 s(-1), strict Michaelis-Menten kinetics and is a potent catalyst of dUDP hydrolysis, whereas in other dUTPases described, this compound acts as a competitive inhibitor. Discrimination is achieved for the base and sugar moiety showing specificity constants for different dNTPs similar to those of bacterial, viral, and human enzymes. In the alkaline range, the K(m) for dUTP increases with the dissociation of ionizable groups showing pK(a) values of 8.8, identified as the uracil moiety of dUTP and 10, whereas in the acidic range, K(m) is regulated by an enzyme residue exhibiting a pK(a) of 7.1. Activity is strongly inhibited by the nucleoside triphosphate analog alpha-beta-imido-dUTP, indicating that the enzyme can bind triphosphate analogs. The existence of specific inhibition and the apparent structural and kinetic differences (reflected in different binding strength of dNTPs) with other eukaryotic dUTPases suggest that the present enzyme might be exploited as a target for new drugs against leishmaniasis.

Cell cycle regulation of a DNA ligase-encoding gene (CaLIG4) from Candida albicans

A DNA ligase (CaLIG4) (formerly CaCDC9) of the human pathogen, Candida albicans, has been characterized. The encoded protein displayed a significant similarity to ligase IV from both Saccharomyces cerevisiae and humans. In addition, whereas CaLIG4 did not complement a S. cerevisiae cdc9 mutant, it re-established non-homologous end-joining of DNA double-strand breaks in a S. cerevisiae lig4 deletant. CaLIG4 was assigned to chromosome 2. Several cis-acting effector sequences were identified in the promoter region of the CaLIG4, including the DNA sequence element ACGNG, which is required for periodic transcription of several DNA-replicating genes in S. cerevisiae. The level of transcription of CaLIG4 in C. albicans varies during the yeast cell cycle. Newly formed cells contained basal levels of transcript which increased to a maximum level when cells were in late G(1). Thereafter, levels of transcript dropped as DNA replication was initiated. Our results suggest that CaLIG4 may perform an important role during the mitotic cycle of C. albicans.

Disruption of the varicella-zoster virus dUTPase and the adjacent ORF9A gene results in impaired growth and reduced syncytia formation in vitro

Varicella-zoster virus (VZV) open reading frame 8 (ORF8) is predicted to encode the viral dUTPase and the adjacent gene, ORF9A, is thought to encode a membrane protein homologous to HSV-1 UL49.5. A fusion protein, in which the amino portion of glutathione-S-transferase was fused to amino acids 5 to 396 of VZV ORF8 protein, had dUTPase activity in vitro. Construction of a mutant VZV with stop codons or a deletion in the ORF8 gene resulted in loss of viral dUTPase activity. Antibody to VZV ORF9A protein demonstrated a 7-kDa protein located in the membranes of virus-infected cells. Insertion of stop codons into VZV ORF9A resulted in VZV that produced smaller plaques than parental virus. Inactivation of both VZV ORF8 and ORF9A resulted in a virus that grew to lower titers and was impaired for syncytia formation when compared to parental virus. In contrast, a similar mutation in HSV-1 has no effect on growth of the virus in vitro. These results identify loci in the VZV genome that are required for a syncytial phenotype in vitro.

The human dUTPase gene encodes both nuclear and mitochondrial isoforms. Differential expression of the isoforms and characterization of a cDNA encoding the mitochondrial species

We have previously identified distinct nuclear and mitochondrial isoforms of dUTPase in human cells, reporting the cDNA sequence of the nuclear isoform (DUT-N). We now report a cDNA corresponding to the mitochondrial isoform (DUT-M). The DUT-M cDNA contains an 252-amino acid open reading frame, encoding a protein with a predicted Mr of 26,704. The amino-terminal region of the protein contains an arginine-rich, 69-residue mitochondrial targeting presequence that is absent in the mature protein. In vitro transcription and translation of the DUT-M cDNA results in the production of a precursor protein with an apparent molecular mass of 31 kDa as judged by SDS-polyacrylamide gel electrophoresis. The DUT-M precursor is enzymatically active and immunoreacts with a dUTPase-specific monoclonal antibody. Mitochondrial import and processing studies demonstrate that the DUT-M precursor is processed into a 23-kDa protein and imported into mitochondria in vitro. Isoelectric focusing experiments demonstrate that the DUT-N has a pI of 6.0, while the processed form of DUT-M has a more basic pI of 8.1, measurements that are in agreement with predicted values. Studies aimed at understanding the expression of these isoforms were performed utilizing quiescent and replicating 34Lu human lung fibroblasts as a model cell culture system. Northern blot analysis, employing an isoform-specific probe, demonstrates that DUT-N and DUT-M are encoded by two distinct mRNA species of 1.1 and 1.4 kilobases, respectively. Western and Northern blot analysis reveal that DUT-M protein and mRNA are expressed in a constitutive fashion, independent of cell cycle phase or proliferation status. In contrast, DUT-N protein and mRNA levels are tightly regulated to coincide with nuclear DNA replication status. Because DUT-N and DUT-M have identical amino acid and cDNA sequences in their overlapping regions, we set out to determine if they were encoded by the same gene. The 5' region of the gene encoding dUTPase was isolated and characterized by a combination of Southern hybridization and DNA sequencing. These analyses demonstrate that the dUTPase isoforms are encoded by the same gene with isoform-specific transcripts arising through the use of alternative 5' exons. This finding represents the first example in humans of alternative 5' exon usage to generate differentially expressed nuclear and mitochondrial specific protein isoforms.

A DNA-binding protein from Candida albicans that binds to the RPG box of Saccharomyces cerevisiae and the telomeric repeat sequence of C. albicans

Electromobility shift assays with a DNA probe containing the Saccharomyces cerevisiae ENO1 RPG box identified a specific DNA-binding protein in total protein extracts of Candida albicans. The protein, named Rbf1p (RPG-box-binding protein 1), bound to other S. cerevisiae RPG boxes, although the nucleotide recognition profile was not completely the same as that of S. cerevisiae Rap 1p (repressor-activator protein 1), an RPG-box-binding protein. The repetitive sequence of the C. albicans chromosomal telomere also competed with RPG-box binding to Rbf1p. For further analysis, we purified Rbf1p 57,600-fold from C. albicans total protein extracts, raised mAbs against the purified protein and immunologically cloned the gene, whose ORF specified a protein of 527 aa. The bacterially expressed protein showed RPG-box-binding activity with the same profile as that of the purified one. The Rbf1p, containing two glutamine-rich regions that are found in many transcription factors, showed transcriptional activation capability in S. cerevisiae and was predominantly observed in nuclei. These results suggest that Rbf1p is a transcription factor with telomere-binding activity in C. albicans.

Kinetic characterization of dUTPase from Escherichia coli

The enzyme dUTPase catalyzes the hydrolysis of dUTP to dUMP and pyrophosphate, thereby preventing a deleterious incorporation of uracil into DNA. The best known dUTPase is that from Escherichia coli, which, like the human enzyme, consists of three identical subunits. In the present work, the catalytic properties of the E. coli dUTPase were investigated in the pH range 5-11. The enzyme was found to be highly specific for dUTP and discriminated both base and sugar as well as the phosphate moiety (bound dUDP was not hydrolyzed). The second best substrate among the nucleotides serving as building blocks for DNA was dCTP, which was hydrolyzed an astonishing 10(5) times less efficiently than dUTP, a decline largely accounted for by a higher Km for dCTP. With dUTP.Mg as substrate, kcat was found to vary little with pH and to range from 6 to 9 s-1. Km passed through a broad minimum in the neutral pH range with values approaching 10(-7) M. It increased with deprotonation of the uracil moiety of dUTP and showed dependence on two ionizations in the enzyme, exhibiting pKa values of 5.8 and 10.3. When excess dUTPase was reacted with dUTP middle dotMg at pH 8, the two protons transferred to the reaction medium were released in a concerted mode after the rate-limiting step. The Mg2+ ion enhances binding to dUTPase of dUTP by a factor of 100 and dUDP by a factor of 10. Only one enantiomer of the substrate analog 2'-deoxyuridine-5'-(alpha-thio)-triphosphate was hydrolyzed by the enzyme. These results are interpreted to favor a catalytic mechanism involving magnesium binding to the alpha-phosphate, rate-limiting hydrolysis by a shielded and activated water molecule and a fast ordered desorption of the products. The results are discussed with reference to recent data on the structure of the E. coli dUTPase.UDP complex.

Purification and characterization of the vaccinia virus deoxyuridine triphosphatase expressed in Escherichia coli

The deoxyuridine triphosphatase gene of vaccinia virus, encoded by the open reading frame F2L, was cloned into Escherichia coli and expressed under the control of a bacteriophage T7 promoter. After induction of T7 RNA polymerase by isopropyl beta-D-thiogalactopyranoside, a 16.5-kDa peptide accumulated to high levels. This 16.5-kDa protein was purified to homogeneity and characterized. Gel filtration of the purified protein revealed a trimeric native structure. Biochemical analysis revealed the enzyme to be a metalloenzyme; enzymatic activity is inhibited by EDTA. This inhibition was reversed by the addition of Mg2+, Mn2+, or Zn2+. While the enzyme activity was highly specific for dUTP with an apparent Km of 0.94 microM, inhibition studies show that 8-azido-ATP acted as a competitive inhibitor of dUTP with a Ki of approximately 173 microM. Also, protection studies demonstrated that nucleotide competitors inhibit photoincorporation of the photoaffinity analogues [gamma-32P]5-azido-dUTP and [gamma-32P]8-azido-ATP. This suggests that while catalytic activity is limited to dUTP, other nucleotides can bind the active site.

Synthesis of 2'-deoxyuridine 5'-(alpha,beta-imido) triphosphate: a substrate analogue and potent inhibitor of dUTPase

The dUDP analogue, 2'-deoxyuridine 5'-(alpha,beta-imido)diphosphate (dUPNP) was synthesized. The corresponding triphosphate analogue (dUPNPP) was prepared by enzymic phosphorylation of dUPNP using the enzyme pyruvate kinase and phosphoenolpyruvate as the phosphate donor. This method was successful in phosphorylating the imidodiphosphate analogue of 2'-deoxythymidine (dTPNP) to 2'-deoxythymidine 5'-(alpha, beta-imido)triphosphate (dTPNPP), in contradiction to a previous report. The properties of dUPNPP have been tested using the enzyme dUTPase from Escherichia coli. This enzyme, having a crucial role in nucleotide metabolism, is strictly specific for its substrate (dUTP) and catalyzes the hydrolysis of the alpha, beta-bridge, resulting in dUMP and pyrophosphate. Replacement of the alpha, beta-bridging oxygen in dUTP with an imido group resulted in a nonhydrolyzable substrate analogue and a potent competitive inhibitor of dUTPase (Ki = 5 microM). The analogue prepared (dUPNPP) may be utilized in crystallographic studies of the active site of dUTPase to provide knowledge about specific interactions involved in substrate binding and as a parental compound in design of dUTPase inhibition for medical purposes.