Study of the interaction of Na+,K+-ATPase protomers using the molecular target method

The radiation inactivation analysis of Na+, K+-ATPase, (EC 3.6.1.37) from two different sources was carried out using ATP, CTP, GTP and p-NPP as substrates. In the case of Na+, K+-ATPase from the bovine brain the relation between the logarithm of the residual activity and the radiation dose is strictly linear, which permits calculating 75-90 kDa (for 3 mM GTP and 10 mM p-NPP). Duck salt glands Na+, K+-ATPase reveals larger target sizes: 350 kDa for ATP hydrolysis in saturating concentrations and 145-190 kDa in the case of GTP and p-NPP or low concentration of ATP (30 microM). A conclusion is drawn that while hydrolyzing substrates with complex kinetics (ATP and CTP) the enzyme functions like oligomer. The interaction of nucleotide with substrate-binding site of low affinity induces the aggregation of monomers.     

Nucleoside triphosphate binding to DNA polymerase III holoenzyme of Escherichia coli. A direct photoaffinity labeling study

The physical basis of ATP binding and activation of DNA polymerase III holoenzyme was studied by an ultraviolet irradiation cross-linking technique. ATP and dATP were photocrosslinked to the alpha, tau, gamma, and delta subunits of holoenzyme; photocrosslinking of dATP was competitively inhibited by ATP. No photocrosslinking was observed with GTP or CTP, nor did GTP, CTP, or UTP inhibit cross-linking of ATP. ADP and adenosine 5'-O-(3-thio)-triphosphate, both potent inhibitors of ATP activation of holoenzyme, inhibited cross-linking of ATP to tau, gamma, and delta subunits, but not to the alpha subunit, suggesting that one or more of these subunits are ATP (or dATP)-binding sites. Photocrosslinking of dTTP to the ATP-activated holoenzyme was exclusively to the epsilon subunit, the dnaQ ( mutD ) gene product; dCTP and dGTP were not photocrosslinked to any subunit. Binding of dTTP was enhanced by ATP, but by no other nucleotide (or deoxynucleotide). This binding of dTTP to epsilon, a subunit likely responsible for regulation of proofreading by the holoenzyme, may function in the control of the fidelity of replication.     

Effect of nucleotide structure on cardiac myosin subfragment 1 transient kinetics

Transient kinetic data of the hydrolysis of several nucleotides (TTP, CTP, UTP, GTP) by cardiac myosin subfragment 1 (S1) were analyzed to obtain values for the equilibrium constant for nucleotide binding and rate constants for the S1-nucleotide isomerization and the subsequent nucleotide hydrolysis as well as the magnitudes of the relative fluorescence enhancements of the myosin that occur upon isomerization and hydrolysis. These data are compared with data from a previous study with ATP. Nucleotide binding is found to be relatively insensitive to nucleotide ring structure, being affected most by the group at position C6. Isomerization and hydrolysis are more sensitive to nucleotide structure, being inhibited by the presence of a bulky group at position C2. Kinetic parameters decrease as follows: for binding, GTP greater than UTP approximately TTP greater than ATP greater than CTP; for isomerization, ATP greater than UTP approximately TTP approximately CTP greater than GTP; for hydrolysis, ATP greater than TTP greater than CTP approximately UTP greater than GTP. Fluorescence enhancements appear to be most dependent upon the relative values of the individual rate constants.     

Structural requirements for the activation of Escherichia coli CTP synthase by the allosteric effector GTP are stringent, but requirements for inhibition are lax

Cytidine 5'-triphosphate synthase catalyzes the ATP-dependent formation of CTP from UTP using either NH(3) or l-glutamine (Gln) as the source of nitrogen. GTP acts as an allosteric effector promoting Gln hydrolysis but inhibiting Gln-dependent CTP formation at concentrations of >0.15 mM and NH(3)-dependent CTP formation at all concentrations. A structure-activity study using a variety of GTP and guanosine analogues revealed that only a few GTP analogues were capable of activating Gln-dependent CTP formation to varying degrees: GTP approximately 6-thio-GTP > ITP approximately guanosine 5'-tetraphosphate > O(6)-methyl-GTP > 2'-deoxy-GTP. No activation was observed with guanosine, GMP, GDP, 2',3'-dideoxy-GTP, acycloguanosine, and acycloguanosine monophosphate, indicating that the 5'-triphosphate, 2'-OH, and 3'-OH are required for full activation. The 2-NH(2) group plays an important role in binding recognition, whereas substituents at the 6-position play an important role in activation. The presence of a 6-NH(2) group obviates activation, consistent with the inability of ATP to substitute for GTP. Nucleotide and nucleoside analogues of GTP and guanosine, respectively, all inhibited NH(3)- and Gln-dependent CTP formation (often in a cooperative manner) to a similar extent (IC(50) approximately 0.2-0.5 mM). This inhibition appeared to be due solely to the purine base and was relatively insensitive to the identity of the purine with the exception of inosine, ITP, and adenosine (IC(50) approximately 4-12 mM). 8-Oxoguanosine was the best inhibitor identified (IC(50) = 80 microM). Our findings suggest that modifying 2-aminopurine or 2-aminopurine riboside may serve as an effective strategy for developing cytidine 5'-triphosphate synthase inhibitors.     

Distinct interactions of GTP,UTP, and CTP with G(s) proteins

Early studies showed that in addition to GTP, the pyrimidine nucleotides UTP and CTP support activation of the adenylyl cyclase (AC)-stimulating G(s) protein. The aim of this study was to elucidate the mechanism by which UTP and CTP support G(s) activation. As models, we used S49 wild-type lymphoma cells, representing a physiologically relevant system in which the beta(2)-adrenoreceptor (beta(2)AR) couples to G(s), and Sf9 insect cell membranes expressing beta(2)AR-Galpha(s) fusion proteins. Fusion proteins provide a higher sensitivity for the analysis of beta(2)AR-G(s) coupling than native systems. Nucleoside 5'-triphosphates (NTPs) supported agonist-stimulated AC activity in the two systems and basal AC activity in membranes from cholera toxin-treated S49 cells in the order of efficacy GTP > or = UTP > CTP > ATP (ineffective). NTPs disrupted high affinity agonist binding in beta(2)AR-Galpha(s) in the order of efficacy GTP > UTP > CTP > ATP (ineffective). In contrast, the order of efficacy of NTPs as substrates for nucleoside diphosphokinase, catalyzing the formation of GTP from GDP and NTP was ATP > or = UTP > or = CTP > or = GTP. NTPs inhibited beta(2)AR-Galpha(s)-catalyzed [gamma-(32)P]GTP hydrolysis in the order of potency GTP > UTP > CTP. Molecular dynamics simulations revealed that UTP is accommodated more easily within the binding pocket of Galpha(s) than CTP. Collectively, our data indicate that GTP, UTP, and CTP interact differentially with G(s) proteins and that transphosphorylation of GDP to GTP is not involved in this G protein activation. In certain cell systems, intracellular UTP and CTP concentrations reach approximately 10 nmol/mg of protein and are higher than intracellular GTP concentrations, indicating that G protein activation by UTP and CTP can occur physiologically. G protein activation by UTP and CTP could be of particular importance in pathological conditions such as cholera and Lesch-Nyhan syndrome.     

Investigation of the mechanism of CTP synthetase using rapid quench and isotope partitioning methods

The UTP-dependent ATPase reaction and the glutamine-dependent overall reaction of Escherichia coli CTP synthetase have been studied by rapid quench and isotope partitioning kinetics. The effect of GTP, an allosteric effector, on the pre-steady-state kinetics of both reactions has also been examined. The time courses of the UTP-dependent ATPase reaction in the presence and absence of GTP are both characterized by a burst of acid-labile phosphate equivalent to 0.93 and 0.43 subunits, respectively. The time course of the glutamine-dependent reaction in the absence of GTP is also characterized by a burst of acid-labile phosphate corresponding to 0.8 subunit; however, in the presence of GTP, no burst was observed. These results along with positional isotope exchange experiments [von der Saal, W., Anderson, P. M., & Villafranca, J. J. (1985) J. Biol. Chem. 260, 14997] provide evidence that the mechanism of CTP formation involves phosphorylation of UTP followed by attack of NH3, and finally release of phosphate, producing CTP, ADP, and Pi. A kinetic model for the first stages of the enzymatic reaction was developed from the rapid quench data, and the internal equilibrium constant for the formation of the phosphorylated UTP intermediate was determined. The internal equilibrium constants for the UTP-dependent reaction in the presence and absence of GTP were found to be 1.1 and 18, respectively. By contrast, the internal equilibrium constant for the reaction in the presence of glutamine was 50. Thus, the presence of glutamine shifts the internal equilibrium constant to favor formation of the phosphorylated UTP intermediate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Limited proteolysis of Escherichia coli cytidine 5'-triphosphate synthase. Identification of residues required for CTP formation and GTP-dependent activation of glutamine hydrolysis.

Cytidine 5'-triphosphate synthase catalyses the ATP-dependent formation of CTP from UTP using either ammonia or l-glutamine as the source of nitrogen. When glutamine is the substrate, GTP is required as an allosteric effector to promote catalysis. Limited trypsin-catalysed proteolysis, Edman degradation, and site-directed mutagenesis were used to identify peptide bonds C-terminal to three basic residues (Lys187, Arg429, and Lys432) of Escherichia coli CTP synthase that were highly susceptible to proteolysis. Lys187 is located at the CTP/UTP-binding site within the synthase domain, and cleavage at this site destroyed all synthase activity. Nucleotides protected the enzyme against proteolysis at Lys187 (CTP > ATP > UTP > GTP). The K187A mutant was resistant to proteolysis at this site, could not catalyse CTP formation, and exhibited low glutaminase activity that was enhanced slightly by GTP. K187A was able to form tetramers in the presence of UTP and ATP. Arg429 and Lys432 appear to reside in an exposed loop in the glutamine amide transfer (GAT) domain. Trypsin-catalyzed proteolysis occurred at Arg429 and Lys432 with a ratio of 2.6 : 1, and nucleotides did not protect these sites from cleavage. The R429A and R429A/K432A mutants exhibited reduced rates of trypsin-catalyzed proteolysis in the GAT domain and wild-type ability to catalyse NH3-dependent CTP formation. For these mutants, the values of kcat/Km and kcat for glutamine-dependent CTP formation were reduced approximately 20-fold and approximately 10-fold, respectively, relative to wild-type enzyme; however, the value of Km for glutamine was not significantly altered. Activation of the glutaminase activity of R429A by GTP was reduced 6-fold at saturating concentrations of GTP and the GTP binding affinity was reduced 10-fold. This suggests that Arg429 plays a role in both GTP-dependent activation and GTP binding.     

Characterization and compartmentation,in green leaves,of hexokinases with different specificities for glucose,fructose, and mannose and for nucleoside triphosphates

When green leaves of spinach (Spinacia oleracea L.) were surveyed for the presence of hexokinases which utilize glucose, fructose and-or mannose as a substrate, four kinases could be distinguished by their order of elution during chromatography on diethylaminoethyl (DEAE)-cellulose: (i) a hexokinase I with a specificity for fructose, glucose, and mannose, (ii) a fructokinase I with a specificity for fructose, (iii) a hexokinase II with a specificity for glucose, fructose and mannose, and (iv) a fructokinase II with a specificity for fructose. Hexokinases I and II had high apparent K_m values for fructose (8 and 15 mM, respectively) and medium or low apparent K_m values for glucose (150 and 18 μM, respectively) and mannose (18 and 15 μM, respectively). Maximal velocities were highest with fructose, medium with glucose and lowest with mannose. That hexokinases I and II used several sugars as substrate was concluded (i) from their identical elution profiles during enzyme separation and (ii) because their activities with two or three sugars at a time was always lower than the sum of activities with one substrate, indicating competition of the sugars for the reaction with the enzymes. Fructokinases I and II were very specific for fructose (85 and 140 μM, respectively) and had only little, if any, activity with glucose or mannose. All kinases showed varying degrees of activity with nucleoside triphosphates other than ATP. In the presence of all three sugars, hexokinases I and II were considerably more active with ATP than with uridine-, cytidine-, and guanosine 5'-triphosphate (UTP, CTP, GTP) except that, in the presence of glucose, hexokinase I was almost as active with UTP as with ATP. In the presence of fructose, fructokinase I exhibited highest activity with GTP and a gradually decreasing level of activity with CTP, UTP, and ATP. The activities in the presence of the other two sugars were highest with ATP. Fructokinase II was most active with ATP and fructose and progressively less active with GTP, UTP, and CTP. Cell fractionation by isopycnic density-gradient centrifugation or differential centrifugation indicated that fructokinase II was associated with chloroplasts, hexokinase II with mitochondria, and the other two kinases with the non-particulate cell fraction. In green leaves of pea (Pisum sativum L.), only a hexokinase (II) and fructokinase (II) were present. Corn (Zea mays L.) leaves exhibited only very low hexokinase activity. Dedicated to Prof. Dr. Hans Mohr on the occasion of his 60th birthday     

Detection of the conformational change in the catalytic site of adenosine triphosphatase from beef liver mitochondria by affinity labeling with the dialdehyde derivative of ethenoadenosine triphosphate

Beef liver mitochondrial F1ATPase was inactivated by the 2',3'-dialdehyde derivative of ethenoATP (epsilon ATP) in a pseudo-first order reaction. The kinetics of protection of the enzyme against inactivation by various nucleoside triphosphates (NTPs) revealed that the dial-epsilon ATP was bound to the catalytic site as an affinity label. Certain anions (sulfate or bicarbonate) were ineffective for protection. In the early phase of the reaction, inactivation was due to the binding of 1 mol dial-epsilon ATP per mol enzyme. In this phase, dial-epsilon ATP bound exclusively to the subunit beta of the enzyme, indicating that the catalytic site is in this subunit. The fluorescence of the ethenoadenosine moiety, bound exclusively to the subunit beta of the enzyme, was measured as a conformational probe of the catalytic site region. Addition of ATP or CTP to the labeled enzyme resulted in a decrease in the fluorescence intensity. GTP and other NTPs were less effective than ATP or CTP. The anions (sulfate of bicarbonate) suppressed the ability of ATP to decrease the fluorescence in a competitive manner. Quantitative analysis of these fluorescence changes suggested that they might originate from the binding of the NTP to the regulatory site of the enzyme. These findings are in good agreement with the two-site model proposed by us (Wakagi, T. & Ohta, T. (1981) J. Biochem. 89, 1205) which was deduced from the steady state kinetics of the NTPase reactions catalyzed by the F1ATPase.     

Specific enzymatic determination of adenosine triphosphate

The well-known soluble kinases are not specific for ATP (1). All these enzymes convert ATP as well as GTP, ITP, CTP, and UTP, although at different rates. The only exception is adenylate kinase (1). However, with this enzyme, a direct determination of ATP in tissue extracts which contain both the di- and mononucleotides is not possible.Phosphoglycerate kinase from various sources is specific for ATP, GTP, and ITP and does not react with the pyrimidine nucleotides (2), Now, however, it was found that phosphoglycerate kinase from the blue alga Spirulina platensis does not convert GTP and ITP. With this enzyme, therefore, it is possible to specifically determine ATP in tissue extracts or in mixtures of nucleotides. In the same test, GTP and ITP can be determined by adding phosphoglycerate kinase from yeast or from other sources (2).     

Competition between ammonia derived from internal glutamine hydrolysis and hydroxylamine present in the solution for incorporation into UTP as catalysed by Lactococcus lactis CTP synthase

CTP synthase catalyses the reaction: glutamine+UTP+ATP --> glutamate+CTP+ADP+P(i). The reaction is greatly stimulated by the allosteric binding of GTP. In addition to glutamine that is hydrolysed by the enzyme to ammonia and glutamate, CTP synthase will also utilise external sources of amino donors such as NH(4)Cl. This reaction is no longer dependent on allosteric activation by GTP. Hydroxylamine is also a substrate for Lactococcus lactis CTP synthase and results in the formation of N4-OH CTP. This product has the feature that it absorbs at 300nm where CTP absorption was shown to be greatly reduced and enabled the determination of N4-OH CTP formation in the presence of CTP synthesis derived from glutamine hydrolysis. Differences in initial rates determined for the hydroxylamine dependent reaction at 291nm in the presence and absence of glutamine and GTP were ascribed to simultaneous CTP and N4-OH CTP synthesis in the presence of these compounds. A characterisation of the apparent inhibition by GTP and glutamine of N4-OH CTP synthesis determined at 300nm showed that glutamine dependent CTP synthesis occurs at a rate of about 60% of that in the absence of hydroxylamine. GTP dependent inhibition of the ammonium chloride dependent reaction of L. lactis CTP synthase by the glutamine analog glutamate gamma-semialdehyde showed a partial inhibition with a maximum inhibition of about 60%. These results are interpreted in terms of a "half of the sites" mechanism for glutamine hydrolysis on CTP synthase.     

Unidirectional inhibition of phosphoenolpyruvate carboxykinase from Rhodospirillum rubrum by ATP

The kinetic and regulatory properties of partially purified phosphoenolpyruvate (PEP) carboxykinase (EC 4.1.1.32) from Rhodospirillum rubrum were studied. The enzyme was active with guanosine-and inosinephosphates and must thus be classified as GTP (ITP): oxaloacetate carboxylyase (transphosphorylating). In the direction of oxaloacetate-formation, the enzyme was strongly inhibited by ATP (K_i=0.03 mM). ITP, UTP, CTP and GTP were less inhibitory. The inhibition was competitive with respect to GDP or IDP, but not with respect to PEP. In the direction of PEP-synthesis, the enzyme was not inhibited, but rather activated by ATP.     

Cardiac sarcolemmal and sarcoplasmic reticulum membrane vesicles exhibit distinctive (Ca-Mg)-ATPase substrate specificities

The nucleoside 5'-triphosphate (NTP) substrate specificities for Ca-stimulated ATPase and ATP-dependent Ca2+ uptake activities have been examined in cardiac sarcolemma (SL) and sarcoplasmic (SR) membrane vesicles. The results indicate that SL membrane vesicles exhibit a much narrower range of NTP substrate specificities than SR membranes. In SR membrane vesicles, the Ca-stimulated Mg-dependent hydrolysis of ATP and dATP occurred at nearly equivalent rates, whereas the rates of hydrolysis of GTP, ITP, CTP, and UTP ranged from 16-33% of that for ATP. All of the above nucleotides also supported Ca2+ transport into SR vesicles; dATP was somewhat more effective than ATP while GTP, ITP, CTP, and UTP ranged from 28-30% of the activity for ATP. In the presence of oxalate, the initial rate of Ca accumulation with dATP was 4-fold higher than for ATP, whereas the activity for GTP, ITP, CTP, and UTP ranged from 35-45% of that for ATP. For the SL membranes, Ca-activated dATP hydrolysis occurred at 60% of the rate for ATP; GTP, ITP, CTP, and UTP were hydrolyzed by the SL preparations at only 7-9% of the rate for ATP. NTP-dependent Ca2+ uptake in SL membranes was supported only by ATP and dATP, with dATP 60% as effective as ATP. GTP, ITP, CTP, and UTP did not support the transport of Ca2+ by SL vesicles. The results indicate that the SL and SR membranes contain distinctly different ATP-dependent Ca2+ transport systems.     

Biochemistry of terminal deoxynucleotidyltransferase: mechanism of inhibition by adenosine 5'-triphosphate

The polymerization of deoxyribunucleoside triphosphate catalyzed by terminal deoxyribonucleotidyltransferase (TdT, EC 2.7.7.31) is severely inhibited by the addition of ribonucleoside triphosphates, ATP being the most potent inhibitor. Examination of the inhibitory effect of ATP using oligo(dA)12-18 as well as activated DNA as primers revealed that (a) ATP inhibition is not due to its addition onto a 3'-OH primer terminus ad judged by the lack of incorporation of labeled ATP, although under similar conditions incorporation of GTP can be demonstrated, (b) a consistent degree of inhibition was noted independent of primer or enzyme concentration; (c) addition of ATP to an ongoing reaction promptly reduces the rate of polymerization; (d) kinetic studies indicate a competitive (with respect to substrate deoxy triphosphate) pattern of inhibition; (e) addition of excess deoxyribotriphosphate promptly relieves the inhibition. Unlike ATP, other ribotriphosphates yield a mixed pattern of inhibition partly mediated by competitive mechanisms. GTP and CTP and to a minor extent UTP are incorporated into DNA in the presence or absence of deoxy triphosphate. Furthermore, addition of ATP also inhibits incorporation of GTP and CTP.     

Binding of ATP to eukaryotic initiation factor 2. Differential modulation of mRNA-binding activity and GTP-dependent binding of methionyl-tRNAMetf

Eukaryotic initiation factor 2 (eIF-2) is shown to bind ATP with high affinity. Binding of ATP to eIF-2 induces loss of the ability to form a ternary complex with Met-tRNAf and GTP, while still allowing, and even stimulating, the binding of mRNA. Ternary complex formation between eIF-2, GTP, and Met-tRNAf is inhibited effectively by ATP, but not by CTP or UTP. Hydrolysis of ATP is not required for inhibition, for adenyl-5'-yl imidodiphosphate (AMP-PNP), a nonhydrolyzable analogue of ATP, is as active an inhibitor; adenosine 5'-O-(thiotriphosphate) (ATP gamma S) inhibits far more weakly. Ternary complex formation is inhibited effectively by ATP, dATP, or ADP, but not by AMP and adenosine. Hence, the gamma-phosphate of ATP and its 3'-OH group are not required for inhibition, but the beta-phosphate is indispensible. Specific complex formation between ATP and eIF-2 is shown 1) by effective retention of Met-tRNAf- and mRNA-binding activities on ATP-agarose and by the ability of free ATP, but not GTP, CTP, or UTP, to effect elution of eIF-2 from this substrate; 2) by eIF-2-dependent retention of [alpha-32P]ATP or dATP on nitrocellulose filters and its inhibition by excess ATP, but not by GTP, CTP, or UTP. Upon elution from ATP-agarose by high salt concentrations, eIF-2 recovers its ability to form a ternary complex with Met-tRNAf and GTP. ATP-induced inhibition of ternary complex formation is relieved by excess Met-tRNAf, but not by excess GTP or guanyl-5'-yl imidodiphosphate (GMP-PNP). Thus, ATP does not act by inhibiting binding of GTP to eIF-2. Instead, ATP causes Met-tRNAf in ternary complex to dissociate from eIF-2. Conversely, affinity of eIF-2 for ATP is high in the absence of GTP and Met-tRNAf (Kd less than or equal to 10(-12) M), but decreases greatly in conditions of ternary complex formation. These results support the concept that eIF-2 assumes distinct conformations for ternary complex formation and for binding of mRNA, and that these are affected differently by ATP. Interaction of ATP with an eIF-2 molecule in ternary complex with Met-tRNAf and GTP promotes displacement of Met-tRNAf from eIF-2, inducing a state favorable for binding of mRNA. ATP may thus regulate the dual binding activities of eIF-2 during initiation of translation.     

Inhibition of 5′-nucleotidase from Ehrlich ascites-tumour cells by nucleoside triphosphates

1. 5'-Nucleotidase activity was obtained in a soluble form after treatment of a particulate fraction from Ehrlich ascites-tumour cells with deoxycholate. The relative rates of hydrolysis of 6-thioinosine 5'-phosphate, UMP, AMP, CMP, GMP, IMP, xanthosine monophosphate, thymidine monophosphate and 2',3'-AMP were 180, 129, 100, 93, 83, 79, 46, 41 and 3 respectively. 2. Values found for the Michaelis constant were: AMP, 67+/-12mum; IMP, 111+/-8mum; GMP, 93mum. 3. ATP and thymidine triphosphate were competitive inhibitors of AMP hydrolysis (inhibitor constants 0.4 and 4.8mum respectively); UTP, GTP and CTP were mixed competitive and non-competitive inhibitors. Thymidine triphosphate was a competitive inhibitor of IMP hydrolysis (inhibitor constant 14.4mum) and ATP, UTP and GTP showed mixed competitive and non-competitive inhibition. 4. ATP, thymidine triphosphate, UTP, GTP and CTP did not completely inhibit hydrolysis of AMP, IMP and UMP; the concentrations of ATP required to inhibit AMP and IMP hydrolysis by 50% were 12 and 230mum respectively. 5. Non-hyperbolic curves relating activity to UMP concentration were obtained in the presence and absence of triphosphates. 6. After fractionation on Sephadex G-200 columns a single peak of 5'-nucleotidase activity (particle weight 120000-125000) was obtained with AMP, IMP and GMP as substrates. UMP hydrolysis was catalysed by enzyme in this peak and in two slower peaks corresponding to apparent particle weights of 32000 and 16000; a single component (particle weight 120000), reacting with UMP and insensitive to UTP inhibition, was obtained when the column was eluted with buffer containing 1mm-UMP. 7. The possible significance of the results in the regulation of tumour-cell 5'-nucleotidase is discussed.     

Nucleotide requirements for anaphase chromosome movements in permeabilized mitotic cells: anaphase B but not anaphase A requires ATP

Permeabilized PtK1 cells continue to undergo anaphase chromosome movements provided MgATP is included in the lysis medium. However, chromosome-to-pole movement (anaphase A) and spindle elongation (anaphase B) differ with respect to nucleotide requirements. The rate of anaphase B depends on the concentration of ATP in the lysis medium; two-thirds the maximal rate is observed in 0.2 mM ATP. However, other nucleotides, such as ITP, CTP and GTP, cannot substitute for ATP. Spindle elongation is blocked by the addition of nonhydrolyzable ATP analogs. ADP, AMP and inhibitors such as vanadate, the magnesium chelator EDTA and sulfhydryl reagents. Anaphase does no require exogenous ATP and is unaffected by these inhibitors. These results are consistent with "dynein-like" ATPase involvement during spindle elongation, and rule out the possibility of tubulin-dynein and actomyosin mechanochemistry during anaphase A. I suggest that chromosome-to-pole movement involves the collapse of an elastic component in the spindle. Force generation could be provided by microtubule depolymerization or by the contraction of a nonmicrotubule microtrabecular lattice.     

The obligate intracellular bacterium Chlamydia trachomatis is auxotrophic for three of the four ribonucleoside triphosphates

Using we11-characterized mutant host cell lines, deficient in specific enzymes of energy and nucleotide metabolism, we addressed numerous questions regarding nucleotide metabolism in the obligate intracellular bacterium Chlamydia trachomatis. The results presented indicate that C. trachomatis: (i) does not absolutely depend on mitochondrial generated ATP for survival; (ii) does have a significant draw on host-cell NTP pools but does not have a detrimental effect on the ability of the host cell to maintain its energy charge; (iii) lacks the ability to synthesize purine and pyrimidine nucleotides de novo; (iv) is not capable of interconverting purine nucleotides; and (v) possesses the pyrimidine metabolic-pathway enzymes CTP synthetase and deoxycytidine nucleotide deaminase. In total our results indicate that C. trachomatis is auxotrophic for host-cell ATP, GTP and UTP. In contrast, CTP can be obtained from the host cell or it can be synthesized from UTP by the parasite.     

CTP-dependent endogenous ADP-ribosylation of a 38 kDa protein in HL-60 cell membranes

Incubation of membranes of human promyelocytic leukemia HL-60 cells with [32P]NAD led to ADP-ribosylation of several proteins including a 38 kDa protein by endogenous ADP-ribosyltransferases. The ADP-ribosylation of the 38 kDa protein was distinctly different from others on the basis of pH dependency and heat stability at 50 degrees C, suggesting that there are at least two endogenous ADP-ribosyltransferases. It was enhanced by CTP, but not affected by ATP, GTP and UTP, whereas it was inhibited by GTP gamma S. [alpha-32P]CTP bound to the 38 kDa protein immobilized on a nitrocellulose sheet, indicating that the 38 kDa protein which bound CTP is strongly ADP-ribosylated by an endogenous ADP-ribosyltransferase.