Gammaherpesviruses encode functional dihydrofolate reductase activity

We overexpressed and purified from Escherichia coli the dihydrofolate reductase (DHFR) of the gammaherpesviruses human herpesvirus 8 (HHV-8), herpesvirus saimiri (HVS), and rhesus rhadinovirus (RRV). All three enzymes proved catalytically active. The K(m) value of HHV-8 DHFR for dihydrofolate (DHF) was 2.02+/-0.44 microM, that of HVS DHFR was 4.31+/-0.56 microM, and that of RRV DHFR is 7.09+/-0.11 microM. These values are approximately 5-15-fold higher than the K(m) value reported for the human DHFR. The K(m) value of HHV-8 DHFR for NADPH was 1.31+/-0.23 microM, that of HVS DHFR was 3.78+/-0.61 microM, and that of RRV DHFR was 7.47+/-0.59 microM. These values are similar or slightly higher than the corresponding K(m) value of the human enzyme. Methotrexate, aminopterin, trimethoprim, pyrimethamine, and N(alpha)-(4-amino-4-deoxypteroyl)-N(delta)-hemiphthaloyl-L-ornithine (PT523), all well-known folate antagonists, inhibited the DHFR activity of the three gammaherpesviruses competitively with respect to DHF but proved markedly less inhibitory to the viral than towards the human enzyme.     

Kinetic investigation of the functional role of phenylalanine-31 of recombinant human dihydrofolate reductase

The role of the active site residue phenylalanine-31 (Phe31) for recombinant human dihydrofolate reductase (rHDHFR) has been probed by comparing the kinetic behavior of wild-type enzyme (wt) with mutant in which Phe31 is replaced by leucine (F31L rHDHFR). At pH 7.65 the steady-state kcat is almost doubled, but the rate constant for hydride transfer is decreased to less than half that for wt enzyme, as is the rate of the obligatory isomerization of the substrate complex that precedes hydride transfer. Although steady-state measurements indicated that the mutation causes large increases in Km for both substrates, dissociation constants for many complexes are decreased. These apparent paradoxes are due to major mutation-induced decreases in rate constants (koff) for dissociation of folate, dihydrofolate, and tetrahydrofolate from all of their complexes. This results in a mechanism proceeding almost entirely by only one of the two pathways used by wt enzyme. Other consequences of these changes are a much altered dependence of steady-state kcat on pH, inhibition rather than activation by tetrahydrofolate, absence of hysteresis in transient-state kinetics, and a decrease in enzyme efficiency under physiological conditions. The results indicate that there is no quantitative correlation between dihydrofolate binding and the rate of hydride transfer for this enzyme.     

Dismutation of dihydrofolate by dihydrofolate reductase

Degradation of 7,8-dihydrofolate (H2folate) in the presence of dihydrofolate reductase (DHFR) has been shown due not to an oxygenase activity of the reductase as previously reported but to dismutation of H2folate to folate and 5,6,7,8-tetrahydrofolate (H4folate). The reaction can be followed spectrophotometrically or by analysis of the reaction mixture by high-performance liquid chromatography (HPLC). The products have also been isolated and characterized. Oxygen uptake during the reaction is much less than stoichiometric with H2folate disappearance and is attributed to autoxidation of the H4folate formed. The dismutation activity is a property of highly purified Streptococcus faecium DHFR isoenzyme 2 (but not isoenzyme 1) and of Lactobacillus casei DHFR, but not of bovine liver DHFR. The activity is dependent on tightly bound NADP+ and/or NADPH. Removal of the nucleotide results in loss of dismutation activity, which is restored by adding NADP+ or NADPH. Maximum activity is obtained when approximately 1 mol equiv of nucleotide is added per mol of DHFR. It is proposed that in the dismutation reaction bound NADP(H) is alternately reduced and oxidized by incoming molecules of H2folate with release of folate and H4folate, respectively. The relatively slow rate of folate formation presumably limits the rate of the overall reaction. The equilibrium constant for the dismutation reaction is 19.4 +/- 7.4 at 22 degrees C and pH 7.0. Calculation of standard oxidation-reduction potentials at pH 7 gave values of -0.230 V for the H2folate/H4 folate pair and -0.268 V for the folate/H2folate pair. The mechanism by which NADP+ is retained by the enzyme from some sources during purification procedures is unclear.(ABSTRACT TRUNCATED AT 250 WORDS)     

Integration and expression of the human dihydrofolate reductase gene in the Bacillus subtilis chromosome

Integration of functionally active human dihydrofolate reductase (hDHFR) gene into the Bacillus subtilis chromosome was performed. The clones obtained contained 1 to 7 copies of hDHFR gene per chromosome equivalent and were resistant to trimethoprim. In cell lysates of such clones a protein with the molecular mass of hDHFR was detected. The hDHFR gene was stably maintained in all clones having this gene integrated into the bacterial chromosome, when grown under non-selective conditions.     

二氢叶酸还原酶基因在斑马鱼咽弓发育过程中作用的研究

叶酸缺乏可导致胚胎先天性发育异常,二氢叶酸还原酶是叶酸生物学作用通路中的关键因子,其功能阻抑将抑制叶酸生物学作用的发挥.咽弓是脊椎动物胚胎发育中头面部结构、心脏流出道等的共同前体.在模式生物斑马鱼中,利用基因表达阻抑以及过表达技术,探讨二氢叶酸还原酶基因(DHFR)在斑马鱼咽弓发育过程中的作用.石蜡切片以及软骨染色结果显示,DHFR表达阻抑导致斑马鱼咽弓以及腭发育明显异常,而DHFR过表达可部分挽救上述发育异常表型.TBX1和HAND2在咽弓发育中有重要作用.通过胚胎整体原位杂交以及Real-timePCR技术检测TBX1和HAND2表达水平.DHFR表达阻抑后TBX1和HAND2的表达降低,DHFR过表达可使TBX1和HAND2的表达增加.上述结果表明,DHFR在斑马鱼咽弓发育过程中扮演重要角色,DHFR通过影响TBX1和HAND2的表达而调控咽弓的形成和分化.     

Crystal structure of human dihydrofolate reductase complexed with folate

The crystal structure of recombinant human dihydrofolate reductase with folate bound in the active site has been determined and the structural model refined at 0.2-nm resolution. Preliminary studies of the binding of the inhibitors methotrexate and trimethoprim to the human apoenzyme have been performed at 0.35-nm resolution. The conformations of the chemically very similar ligands folate and methotrexate, one a substrate the other a potent inhibitor, differ substantially in that their pteridine rings are in inverse orientations relative to their p-aminobenzoyl-L-glutamate moieties. Methotrexate binding is similar to that previously observed in two bacterial enzymes but is quite different from that observed in the enzyme from a mouse lymphoma cell line [Stammers et al. (1987) FEBS Lett. 218, 178-184]. The geometry of the polypeptide chain around the folate binding site in the human enzyme is not consistent with conclusions previously drawn with regard to the species selectivity of the inhibitor trimethoprim [Matthews et al. (1985) J. Biol. Chem. 260, 392-399].     

A dihydrofolate reductase gene from Candida albicans: molecular cloning

The dihydrofolate reductase gene from Candida albicans has been cloned and partially characterized. A genomic bank from C. albicans strain 10127/5 was constructed in Escherichia coli and screened for trimethoprim resistance. A plasmid pMF1, carrying the resistance marker was isolated and characterized by restriction mapping and Southern blotting. Cells harbouring pMF1 were as sensitive as the parental cells to a wide spectrum of antibacterial agents, except for trimethoprim; the dihydrofolate reductase activity from these cells was trimethoprim resistant.     

Novel DNA rearrangements are associated with dihydrofolate reductase gene amplification

We have employed the technique of chromosome "walking" to determine the structure of 240 kilobases of amplified DNA surrounding the dihydrofolate reductase gene in methotrexate-resistant mouse cell lines. Within this region, we have found numerous DNA rearrangements which occurred during the amplification process. DNA subclones from regions flanking the dihydrofolate reductase gene were also utilized as hybridization probes in other cell lines. Our results show that: 1) amplification-specific DNA rearrangements or junctions are unique to each cell line; 2) within a given cell line, multiple amplification-specific DNA sequence rearrangements are found; 3) the degree of amplification of sequences flanking the dihydrofolate reductase gene shows quantitative variation among and within cell lines; and 4) both the arrangement of amplified sequences as well as the magnitude of gene amplification may vary with prolonged culture even under maintenance selection conditions. These studies indicate that there is no static repetitive unit amplified in these cells. Rather, a dynamic and complex arrangement of the amplified sequences exists which is continually changing.     

An amplified insect dihydrofolate reductase gene contains a single intron

We have used methotrexate-resistant mosquito (Aedes albopictus) cells as the source of DNA for cloning an 8.5-kb EcoRI fragment containing an amplified dihydrofolate reductase (DHRF) gene. An estimated 1200 copies of the DHFR gene were represented in nuclear DNA from Mtx-5011-256 cells, which were 3000-fold more resistant to methotrexate than wild-type cells. Southern blot analysis indicated that all of the amplified DHFR genes were contained within a 1.8-kb AccI fragment represented in the cloned DNA. In contrast to mammalian DHFR genes which span approximately 30 kb, the complete amino acid coding sequence of the mosquito DHFR gene spanned 614 nucleotides, including a single 56-nucleotide intron that interrupted a conserved Arg codon at amino acid position 27. Additional introns characteristic of mammalian DHFR genes were absent; conservation of the first intron in the mosquito DHFR gene supports a regulatory role for this intron. The mosquito DHFR gene coded for a 186-amino-acid protein with 43-48% similarity to vertebrate DHFR.     

Nucleotide sequence of the dihydrofolate reductase gene of Saccharomyces cerevisiae

The nucleotide sequence of a DNA fragment that contained the Saccharomyces cerevisiae gene DFR coding for dihydrofolate reductase (DHFR) was determined. The DHFR was encoded by a 633-bp open reading frame, which specified an Mr24264 protein. The polypeptide was significantly related to the DHFRs of chicken liver and Escherichia coli. The yeast enzyme shared 60 amino acid (aa) residues with the avian enzyme and 51 aa residues with the bacterial enzyme. DHFR was overproduced about 40-fold in S. cerevisiae when the cloned gene was present in the vector YEp24. As isolated from the Saccharomyces library, the DFR gene was not expressed in E. coli. When the gene was present on a 1.8-kb BamHI-SalI fragment subcloned into the E. coli vector, pUC18, weak expression in E. coli was observed.     

Structure and genomic organization of the mouse dihydrofolate reductase gene

The genomic organization of the mouse dihydrofolate reductase gene has been determined by hybridization of specific cDNA sequences to restriction endonuclease-generated fragments of DNA from methotrexate-resistant S-180 cells. The dihydrofolate reductase gene contains a minimum of five intervening sequences (one in the 5′ untranslated region and four in the protein-coding region) and spans a minimum of 42 kilobase pairs on the genome. Genomic sequences at the junction of the intervening sequence and mRNA-coding sequence and at the polyadenylation site have been determined. A similar organization is found in independently isolated methotrexate-resistant cell lines, in the parental sensitive cell line and in several inbred mouse strains, indicating that this organization represents that of the natural gene.     

The organization of the dihydrofolate reductase gene of baby hamster kidney fibroblasts.

Using cloned DNA complementary to mouse dihydrofolate reductase (DHFR) mRNA, the organization of the hamster DHFR gene has been determined in two baby hamster kidney (BHK) cell lines, A5 and B1. A5 cells are highly methotrexate-resistant, containing 200-fold more copies of the DHFR gene than do the parental B1 cells. The DHFR gene has the same organization in A5 and B1 cells, suggesting that it has not been altered by the amplification process. The BHK DHFR gene spans a maximum of 10.7 kb and contains at least three introns. Thus the BHK DHFR gene is much smaller than the mouse DHFR gene, which has a minimum size of 42 kb and at least five introns. This striking size difference is probably due to much smaller introns in the BHK DHFR gene.