Mechanism of Activation of AMPK by Cordycepin.

Cordycepin (3'-deoxyadenosine) is a major bioactive agent in Cordyceps militaris, a fungus used in traditional Chinese medicine. It has been proposed to have many beneficial metabolic effects by activating AMP-activated protein kinase (AMPK), but the mechanism of activation remained uncertain. We report that cordycepin enters cells via adenosine transporters and is converted by cellular metabolism into mono-, di-, and triphosphates, which at high cordycepin concentrations can almost replace cellular adenine nucleotides. AMPK activation by cordycepin in intact cells correlates with the content of cordycepin monophosphate and not other cordycepin or adenine nucleotides. Genetic knockout of AMPK sensitizes cells to the cytotoxic effects of cordycepin. In cell-free assays, cordycepin monophosphate mimics all three effects of AMP on AMPK, while activation in cells is blocked by a γ-subunit mutation that prevents activation by AMP. Thus, cordycepin is a pro-drug that activates AMPK by being converted by cellular metabolism into the AMP analog cordycepin monophosphate.

Base selectivity is impaired by mutants that perturb hydrogen bonding networks in the RB69 DNA polymerase active site.

To investigate the molecular basis for the selective utilization of nucleoside triphosphates complementary to templating bases, by RB69 DNA polymerase (RB69 pol), we constructed a set of mutants that we predicted would perturb the "floor" of the nascent base-pairing interface in the enzyme. We then determined the pre-steady-state kinetic parameters for the incorporation of complementary and noncomplementary dNTPs by the exo(-) form of RB69 pol and its mutants. We found that the Y567A mutant had the same K(d) and k(pol) values for incorporation of C versus G as the wild-type exo(-) enzyme; however, the k(pol)/K(d) ratio for G versus G incorporation with the Y567A mutant was 10 times higher than the k(pol)/K(d) efficiency of G versus G incorporation using the exo(-) RB69 pol. The reduced level of discrimination by the Y567A mutant against incorporation of mismatched bases was also seen with the Y391A mutant. Stopped-flow fluorescence was also employed to monitor rates of putative conformational changes with the exo(-) RB69 pol and its mutants using a primer-template complex containing 2-aminopurine. The rates of fluorescence changes were equal to or greater than the rates of the rapid chemical quench, indicating that we were monitoring a process occurring before or during the phosphoryl transfer reaction. We have interpreted our results within the context of the crystal structure of the RB69 pol ternary complex [Franklin, M. C., et al. (2001) Cell 105, 657-667].

Suppressive effect of viscous dietary fiber on elevations of uric acid in serum and urine induced by dietary RNA in rats is associated with strength of viscosity.

This study was performed to clarify how dietary fiber (DF) with different viscosities would be associated with dietary RNA metabolism. Male Wistar strain rats, four weeks old, were fed diets containing a 3% (w/w) yeast RNA and a 5% (w/w) viscous DF for five days. Viscosity of DF samples used, in order of strength, were xanthan gum (XG) > guar gum (GG) > locust bean gum (LBG) > karaya gum (KG) > pectin (PE) = arabic gum (AG) > CM-cellulose (CMC) = inulin (IN). The serum uric acid concentration in the viscous DF groups significantly decreased as compared with that in the cellulose (CL) group. The urinary excretions of uric acid and allantoin in the respective groups given AG, GG, IN, KG, PE, and XG were significantly suppressed as compared with those in the CL group. The fecal RNA excretion was markedly increased in the IN, KG, PE, and XG groups in comparison to the CL group. The DF with high viscosity significantly suppressed RNA digestion by RNase A and decreased uptakes of 14C-labeled adenosine and adenosine 5'-monophosphate (5'-AMP) in rat jejunum. The results reveal that the suppressive effect of DF on elevation of serum uric acid concentration induced by dietary RNA in rats is associated with the strength of DF viscosity. The mechanism by which this is accomplished is suggested to be attributed to the inhibitions of digestion for dietary RNA and/or absorption of the hydrolyzed compounds.

Identification of a domain conferring nucleotide binding to the N-acetyl-d-glucosamine 2-epimerase (Renin binding protein).

Renin binding protein (RnBP), a cellular renin inhibitor, has been identified as the enzyme N-acetyl-D-glucosamine (GlcNAc) 2-epimerase. Our recent studies demonstrated that rat GlcNAc 2-epimerase has a ten-times higher affinity for ATP, dATP, and ddATP than the human enzyme [Takahashi, S. et al. (2001) J. Biochem. 130, 815-821]. To identify the domain conferring nucleotide binding to GlcNAc 2-epimerase, we constructed a series of chimeric enzymes successively replacing the three domains of the human enzyme (N-terminal, middle, and C-terminal domains) with the corresponding domains of the rat enzyme. Chimeras were expressed in Escherichia coli JM109 cells under the control of the Taq promoter. The purified chimeric enzymes had GlcNAc 2-epimerase activity and inhibited renin activity in a dose-dependent manner. The recombinant human and rat enzymes required catalytic amounts of ATP with apparent K(m) values of 73 and 5.5 microM, respectively. Chimeric enzymes of HHR, RHH, and RHR (H, human type domain; R, rat type domain) had nearly the same nucleotide specificity as the human GlcNAc 2-epimerase. On the other hand, HRR, HRH, and RRH chimeras had the same nucleotide specificity as the rat enzyme. These results indicate that the middle domain of the GlcNAc 2-epimerase molecule participates in the specificity for and binding of nucleotides, and that nucleotides are essential to form the catalytic domain of the enzyme.

A mechanism of AZT resistance: an increase in nucleotide-dependent primer unblocking by mutant HIV-1 reverse transcriptase.

Mutations in HIV-1 reverse transcriptase (RT) give rise to 3'-azido-3'-deoxythymidine (AZT) resistance by a mechanism that has not been previously reproduced in vitro. We show that mutant RT has increased ability to remove AZTMP from blocked primers through a nucleotide-dependent reaction, producing dinucleoside polyphosphate and extendible primer. In the presence of physiological concentrations of ATP, mutant RT extended 12% to 15% of primers past multiple AZTMP termination sites versus less than 0.5% for wild type. Although mutant RT also unblocked ddAMP-terminated primers more efficiently than wild-type RT, the removal of ddAMP was effectively inhibited by the next complementary dNTP (IC50 approximately equal to 12 microM). In contrast, the removal of AZTMP was not inhibited by dNTPs except at nonphysiological concentrations (IC50 > 200 microM).

Differential cytostatic effects of NO donors and NO producing cells.

A 3-h exposure to NO donors (spermine-NO, DETA-NO, or SNAP), or to NOS II-expressing cells (activated macrophages or EMT6 cells) reversibly inhibited DNA synthesis in K562 tumor cells. In GSH-depleted K562 cells, cytostasis remained reversible when induced by DETA-NO or NOS II activity, but became irreversible after exposure to spermine-NO or SNAP. Only SNAP and spermine-NO efficiently inhibited GAPDH, an enzyme with a critical thiol, in GSH-depleted cells. Thus, the irreversible cytostasis induced in GSH-depleted cells by spermine-NO or SNAP can be tentatively attributed to S-nitrosating or oxidizing species derived from NO. However, these species did not contribute significantly to the early antiproliferative effects of macrophages. Ribonucleotide reductase, a key enzyme in DNA synthesis. has been shown to be inhibited by NO. Supplementation of the medium with deoxyribonucleosides to bypass RNR inhibition restored DNA synthesis in target cells exposed to DETA-NO and NO-producing cells, but was inefficient for GSH-depleted cells previously submitted to spermine-NO or SNAP. These cells also exhibited a persistent depletion of the dATP pool. In conclusion, GSH depletion reveals striking qualitative differences in the nature of the toxic effectors released by various NO sources, questioning the significance of S-nitrosating or oxidizing nitrogen oxides in NOS II-dependent cytostasis.

DNA polymerase photoprobe 2-[(4-azidophenacyl)thio]-2'-deoxyadenosine 5'-triphosphate labels an Escherichia coli DNA polymerase I Klenow fragment substrate binding site.

The nucleotide photoprobe 2-[(4-azidophenacyl)thio]-2'-deoxyadenosine 5'-triphosphate (1) was evaluated as a photoaffinity label of the DNA polymerase I Klenow fragment. Photolabel [3H]-1 covalently labeled the Klenow fragment with photolysis at 300 nm, reaching saturation at an approximate 1:1 mole ratio at 5.7 microM and with an EC50 (the effective concentration at 50% maximum photoincorporation) of about 0.74 microM. Saturating concentrations of poly(dA).(T)10 protect the Klenow fragment from [3H]-1 photoincorporation, and TTP at a concentration approximately equal to its KD for the free enzyme form shifts the dose-response curve for photoincorporation of [3H]-1 into the Klenow fragment by a factor of 2, indicating a competitive relationship between TTP and 1. Additionally, the photoincorporation of [3H]-1 into the Klenow fragment has an absolute requirement for magnesium, with no significant photoincorporation observed at concentrations of 1 up to 10 microM in the absence of magnesium. These results demonstrate that, as designed, photoprobe 1 binds to both the dNTP and a portion of the template-primer binding sites on the Klenow fragment. Photoaffinity labeling of the Klenow fragment by 1 yielded a single radiolabeled tryptic fragment which was isolated by HPLC; sequence analysis identified Asp732 in the peptide fragment Asp732-Ile733-His734-Arg735 as the site of covalent modification. Molecular modeling and complementary NMR analysis of the conformation of 1 indicated preferred C3'-exo and C2'-exo-C3'-endo symmetrical twist furanose ring puckers, with a high antibase conformation and a +sc C-5 torsional angle. Docking studies using Asp732 as an anchor point for the azide alpha-nitrogen on the photolabel indicate that the dNTP binding site is at the edge of the DNA binding cleft opposite the exonuclease site and that the template binding site includes helix O in the finger motif of the Klenow fragment.

Ratio of 2'-deoxyadenosine-5'-triphosphate/thymidine-5'-triphosphate influences the commitment of human colon carcinoma cells to thymineless death.

In colon cancers induction of a thymineless state following inhibition of thymidylate synthase (TS) by 5-fluorouracil combined with leucovorin can initiate a cytotoxic response. Using a 5-fluorouracil-leucovorin-treated human colon carcinoma cell line (GC3/cl) and a clonally derived TS- mutant, initiation events that dictate the onset of and commitment to thymineless death have been examined. Initial events related to a temporally associated decrease in dTTP and elevation in the dATP pools; no depletion of dGTP or elevation in dCTP was detected. Nucleosomal degradation of DNA commenced at 24 h in TS- and 49 h in GC3/c1, and was associated with the more rapid development of an imbalance in the dATP and dTTP pools and a higher dATP:dTTP ratio in TS- cells. The contribution of elevated dATP or depleted dTTP pools to thymineless death was subsequently determined by treatment of GC3/cl or TS- cells with deoxyadenosine to elevate the dATP pool either under thymidine-replete or thymineless conditions. Thus, deoxyadenosine supplementation under dTTP-replete conditions elevated the dATP pool for 16 h and was cytotoxic to cells. During dTTP depletion elevated dATP was maintained, and cytotoxicity was significantly and rapidly enhanced by deoxyadenosine but could be reversed by thymidine. Data suggest that maintenance of elevated dATP and the dATP:dTTP ratio are essential initiation events in the commitment of colon carcinoma cells to thymineless death.

DNA sequence analysis with a modified bacteriophage T7 DNA polymerase. Effect of pyrophosphorolysis and metal ions.

Pyrophosphorolysis by bacteriophage T7 DNA polymerase leads to the degradation of specific dideoxynucleotide-terminated fragments on DNA sequencing gels. This reaction can be prevented by pyrophosphatase. It is also inhibited by a high concentration of dNTPs; only the dNTP complementary to the next base in the template is an effective inhibitor, suggesting the formation of a stable polymerase-primer-template-nucleotide complex despite the absence of a 3' hydroxyl group on the primer. The use of pyrophosphatase, a genetically modified T7 DNA polymerase that lacks exonuclease activity, and Mn2+ rather than Mg2+ to eliminate discrimination between dideoxynucleotides and deoxynucleotides (Tabor, S., and Richardson, C. C. (1989) Proc. Nat. Acad. Sci. U. S. A. 86, 4076-4080) generates bands of uniform intensity on a DNA sequencing gel. Uniform band intensities simplify the analysis of a DNA sequence, particularly with automated procedures. For example, when genomic DNA is sequenced directly, heterozygotic sequences are readily detected because their bands have half the intensity of homozygotic sequences. A procedure for automated DNA sequencing is described that exploits the uniformity. A single reaction with a single labeled primer is carried out using four different ratios of dideoxynucleotides to deoxynucleotides; after gel electrophoresis in a single lane, the sequence is determined by the relative intensity of each band.

[Template-primer-dependent inactivation of DNA polymerase alpha from human placenta by 2',3'-epoxyadenosine-5'-triphosphate]. / Matritsa-praimerzavisimaia inaktivatsiia DNK-polimerazy alpha iz platsenty cheloveka 2',3'-époksiadenozin-5'-trifosfatom.

Modification of the human placenta DNA polymerase alpha by 2',3'-epoxyadenosine 5'-triphosphate (eATP) was investigated. The latter binds to the protein both in absence and in presence of template-primer complex. However for inactivation of the enzyme, reagent-complementary template, primer and Me2(+)-ions are required. The inactivation is apparently due to the affinity modification of dNTP-binding site by eATP; covalent binding of the reagent off the enzyme's active site without affecting the DNA polymerase activity is also suggested. The enzyme inactivation by eATP and its protection from inactivation in the presence of dATP were used to determine Kd values of complexes of the enzyme with eATP (90 microM) and dATP (1 microM), the latter value being 13-times lower than Km for dATP (13 microM) in the polymerisation reaction. Using the dependence of the DNA polymerase inactivation by eATP on the primer concentration, Kd for enzyme-primer complexes were estimated. The Kd value for d(pA)10 (0.33 microM) was close to Km value (0.43 microM) for this primer. eATP was concluded to be a useful reagent for estimating the efficiency of the complex formation of different ligands with dNTP- and primer-binding sites of DNA polymerase.

Purine triphosphate beta-gamma bond hydrolysis requirements for RNA polymerase II transcription initiation and elongation.

RNA polymerase II-specific transcription requires, in addition to auxiliary protein factors, the hydrolysis of the beta-gamma phosphate bond of ATP. The nonhydrolyzable analog of ATP, imidoadenosine triphosphate does not suffice for specific in vitro transcription (Bunick, D., Zandomeni, R., Ackerman, S., and Weinmann, R. (1982) Cell 29, 877-886), although it can be incorporated into RNA. The experiments presented here suggest two energy-dependent steps in RNA polymerase II transcription. One of these steps is required at, or close to, the point of initiation, as determined by 5' end primer extension analysis. In vitro transcription occurs efficiently in vitro when imidoadenosine triphosphate is supplemented with dATP to fulfill the energy requirement. In the presence both of imidoadenosine triphosphate and imidoguanosine triphosphate, the concentration of dATP required for transcription initiation is dramatically increased. This suggests that ATP and GTP are co-substrates in transcription initiation, supporting the role of protein kinase II in this process (Zandomeni, R., Zandomeni, M. C., Shugar, D., and Weinmann, R. (1986) J. Biol. Chem. 261, 3414-3419). The concentration of dATP required for maximal initiation is inadequate for the production of full-length transcripts, suggesting a second energy-dependent step in the RNA elongation process. Since the elongation step is unaffected by the presence of imidoguanosine triphosphate, GTP beta-gamma phosphate bond hydrolysis appears to be required only for initiation.

Gentamicin nucleotidyltransferase. Stereochemical inversion at phosphorus in enzymatic 2'-deoxyadenylyl transfer to tobramycin.

Gentamicin nucleotidyltransferase-catalyzed reaction of (Sp)-[alpha-17O]dATP with tobramycin produced 2"-(2'-deoxyadenosine 5'-[17O]phosphoryl)tobramycin. The configuration at phosphorus in this product was shown to be Rp by chemical degradation to chiral [17O, 18O]dAMP using a stereochemically defined procedure, and determination of the configuration at phosphorus in this product. Periodate-base treatment of 2"-(2'-deoxyadenosine 5'-[17O]phosphoryl)tobramycin followed by NaBH4 reduction produced (2-glyceryl)-[17O]dAMP, which upon snake venom phosphodiesterase-catalyzed hydrolysis in H(2)18O produced [17O,18O] dAMP. The configuration at phosphorus in this product was shown to be S by enzymatic phosphorylation to [17O,18O]dATP, adenylylcyclase (Bordetella pertussis)-catalyzed cyclization to 3',5'-cyclic [17O,18O]dAMP, and 31P NMR analysis of the ethyl esters. Since snake venom phosphodiesterase-catalyzed hydrolyses proceed with retention of configuration at phosphorus, (Sp)-[17O,18O]dAMP must have been produced from (Rp)-(2-glyceryl)-[17O]dAMP; and since the chemical degradation to the latter compound did not involve cleavage of any bonds to phosphorus, the initial enzymatic product must have been (Rp)-2"-(2'-deoxyadenosine 5'-[17O]phosphoryl)tobramycin. Therefore, nucleotidyl transfer catalyzed by gentamicin nucleotidyl-transferase proceeds with inversion of configuration at phosphorus, and the reaction mechanism involves an uneven number of phosphotransfer steps. Inasmuch as this is an uncomplicated two-substrate group transfer reaction, the mechanism probably involves direct nucleotidyl transfer from the nucleoside triphosphate to the aminoglycoside. The B. pertussis adenylylcyclase reaction was shown to proceed with inversion at phosphorus, as has been established for other adenylylcyclases.