Inhibition of tryptophanyl-tRNA synthetase by modifying ATP analogs

The interaction between tryptophanyl-tRNA synthetase (EC 6.1.1.2) from beef pancreas and the ATP analogs containing alkylating or phosphorylating groups in the polyphosphate moiety of ATP was studied as an approach to investigate the structure of the enzyme active center. Some of the compounds under study were shown to irreversibly inhibit the enzyme activity; the presence of ATP in the most cases protects the enzyme against inactivation. The kinetic constants Ki and k2 of interaction of the irreversible inhibitors with the enzyme were determined. It was found that the Ki values for a number of irreversible competitive inhibitors are by 1-2 orders of magnitude less than the Km value for ATP; the k2 values were found equal to 0.02-0.04 min-1. this suggests that the compounds may be used as affinity reagents, the most efficient ones being adenosine 5'-(beta-chloroethyl phosphate) and mixed AMP-mesithylene carbonic acid anhydride. The absence of a protective effect of ATP in the case of adenosine 5'-(beta-bromoethane phosphonate) and non-competitive type of reversible inhibition inhibition of the enzyme by adenosine 5'-chloromethane phosphonate indicate that the molecule of tryptophanyl-tRNA synthetase contains sites interacting with adenine nucleotides, other than the ATP binding sites of the active center.     

32P-labeling of bovine tryptophanyl-tRNA synthetase with [32P]pyrophosphate

The covalent derivative of the tryptophanyl-tRNA synthetase obtained under the action of³²PP_i contains one mole of the covalently bound pyrophosphate (or 2 moles of orthophosphate) per mole of dimeric enzyme. Dephosphorylation with alkaline phosphatase causes practically no changes of enzymatic activity although the enzyme looses its ability to bind PP_i.Enzymes tryptophanyl-tRNA synthetase (EC 6.1.1.2), alkaline phosphatase (EC 3.1.3.1), inorganic pyrophosphatase (EC 3.6.1.1)     

Limited proteolysis of the tryptophanyl-tRNA synthetase.

Earlier studies have shown that native tryptophanyl-tRNA synthetase from beef pancreas is composed of two apparently identical subunits having a molecular weight of 60000 plus or minus 2000 each. Incubation of the pruified enzyme with trypsin under restrictive conditions results in splitting of each subunit to form an enzymatically inactive polypeptide chain of mol. wt 24500 plus or minus 1500. During proteolysis, two distinct intermediate forms of mol. wt 51000 plus or minus 2000 and 40000 plus or minus 2000 and fragments of mol. wt 14000 plus or minus 2500 are formed. The presence of substrates, viz. ATP, tryptophan or tryptophanyl adenylate, decreases the rate of proteolysis. However, a band pattern monitored by acrylamide gel electrophoresis is qualitatively indistinguishable from that obtained in the absence of substrates. Native and trypsin-modified subunits (the latter having a molecular weight of 24500) have been maleylated, reduced, carbosymethylated and subjected to exhaustive digestion by trypsin followed by peptide mapping. Comparison of the finger prints has shown that the trypsin-modified subunit represents a polypeptide with lowered content of dicarboxylic amino acids. That the number of peptides revealed after complete proteolysis of native and trypsin-modified subunits does not favour the presence of long repetitive sequences in each subunit, is at variance with some bacterial aminoacyl-tRNA synthetases. Study of the fluorescence polarisation of 1-anilino-8-napthalene sulphonate adsorbed on the dimeric tryptophanyl-tRNA synthetase, indicates that the molecule behaves as a complete entity in Brownian rotation. The trypsin-resistant end products, composed of two types of polypeptides (mol. wts 24500 and 14000), remain associated with each other. From the mol. wt of this associate it follows that each fragment is present in the associate in duplicate. When the purification procedure was carried out in the absence of a protease inhibitor, the active modified enzyme form was obtained. As judged from the molecular weight values, it is composed of two equal subunits corresponding to one of the products of limited proteolysis. The data presented are compatible with compact three-dimensional structure of tryptophanyl-tRNA synthetase having very limited regions exposed to exogenous or endogenous proteolysis.     

Effect of Mg2, ATP and some analogs on phosphorylase phosphatase from adrenal cortex.

The effect of Mg2, ATP and some of its analogs was studied on the spontaneously active and the ATP-Mg-dependent forms of phosphorylase phosphatase extracted from adrenal cortex. Inhibition of the spontaneously active form was observed with Mg2 (Ki - 9mM), ATP (Ki = 9micronM), 2'-doxy-ATP (Ki = 8 micronM), AtetraP (Ki = 9 micronM), AMP(CH2)PP (Ki = 11 micronM), ADP(CH2)P (Ki = 19 micronM), ADP(NH)P (Ki = 16micronM) and ADP (Ki = 25micronM). Activation of the ATP-Mg-dependent form was obtained with Mg2 (Ka = 0.55mM) (to a lower extent) and with ATP (Ka = 2micronM), 2'-deoxy-ATP (Ka = 6micronM) or AtetraP (Ka = 15micronM) in the presence of 0.5mM Mg2. Activation with AMP(CH2)PP was only observed in the presence of high concentrations (5mM) of Mg2 (Ka = 13micronM). No activation at all was observed with ADP(CH2)P or ADP(NH)P. Even though the activation of the ATP-Mg-dependent form does not seem to involve a kinase reaction, the stimulation by ATP or its analogs is rather specific, since it does not occur with analogs in which a methylene group or a nitrogen is substituted for the oxygen between the beta- and gamma-phosphates.     

The plant aminoacyl-tRNA synthetases. Purification and characterization of valyl-tRNA, tryptophanyl-tRNA and seryl-tRNA synthetases from yellow-lupin seeds.

Valyl-tRNA, tryptophanyl-tRNA, and seryl-tRNA synthetases from yellow lupin seeds Lupinus luteus were purified to homogeneity by ammonium sulfate fractionation, hydrophobic chromatography on aminohexyl-Sepharose column and affinity chromatography on tRNA-Sepharose column. Valyl-tRNA synthetase consists of one polypeptide chain of molecular weight 125000 as judged by Sephadex G-200 gel filtration and dodecylsulfate-polyacrylamide gel electrophoresis in the presence of reducing agent. Seryl-tRNA synthetase, Mr equals 110000, is composed of two 55000-Mr subunits. Tryptophanyl-tRNA synthetase exhibits molecular weight of 200000 on Sephadex G-200 and 37000 in dodecylsulfate-polyacrylamide gel electrophoresis. This indicates that tryptophanyl-tRNA synthetase consists of several subunits (probably four). Since the seryl-tRNA synthetase exhibits the same mobility on dodecylsulfate-polyacrylamide gels both in the presence and absence of reducing agent it is concluded that there is no covalent bond(s) between the subunits of the enzyme. There is also no covalent bond(s) between the subunits of tryptophanyl-tRNA synthetase. Effect of anti-sulfhydryl reagents, monovalent salts, pH and different buffers on activity of the three synthetases is described. Kinetic constants for the substrates of the synthetases are also given. dATP is a substrate for seryl-tRNA synthetase but not for valyl-tRNA and tryptophanyl-tRNA synthetases.     

Fluorescence based structural analysis of tryptophan analogue-AMP formation in single tryptophan mutants of Bacillus stearothermophilus tryptophanyl-tRNA synthetase

The symmetrical dimer structure of tryptophanyl-tRNA synthetase is similar to that of tyrosyl-tRNA synthetase whose binding behavior and structural details have been elucidated in detail. The structure of both subunits after forming the intermediate tryptophanyl-AMP has important implications for the binding of the cognate tRNA(Trp). Single tryptophan mutants of Bacillus stearothermophilus tryptophanyl-tRNA synthetase have been constructed and expressed and used to probe structural changes in different domains of the enzyme in both subunits. Substrate titrations using the Trp analogues 4-fluorotryptophan and 7-azatryptophan in the presence of ATP to form the corresponding aminoacyl-adenylate reveal significant structural changes occurring throughout the active subunit in regions not confined to the active site. Changes in environment around the specific Trp residues were monitored using UV absorbance and steady-state fluorescence measurements. When titrated with 4-fluorotryptophan, both Trp 91 and Trp 290 fluorescence is quenched (49 and 22%, respectively) when one subunit has formed Trp-AMP. The fluorescence of Trp 48 is enhanced 19%. No further change in signal was observed after a 1:1 dimer/L-4FW-AMP complex ratio had been established. Using an anion-exchange filter binding assay with radiolabeled l-Trp as a substrate, binding to only one subunit was observed under nonsaturating conditions. This agrees with the results of the assay using 7-azatryptophan as a substrate. The observed changes extend to the unfilled subunit where a similar structure is believed to form after one subunit has formed tryptophan-AMP. Movement in the regions of the enzyme containing Trp 290 and Trp 91 suggests a mechanism for cross-subunit communication involving the helical backbone and dimer interface containing these two residues.     

Properties of matrix-bound dimer and monomer derivatives of immobilized creatine kinase from rabbit skeletal muscle.

Dimeric creatine kinase (EC 2.7.3.2) from rabbit skeletal muscle can be immobilized via a single subunit to CNBr-activated Sepharose 4B and subsequently treated with guanidine hydrochloride followed by renaturation to yield a catalytically active matrix-bound subunit derivative. The importance of the intact dimeric structure in the activation of the enzyme by acetate was demonstrated. Immobilization did not appear to alter the pH optimum of the enzyme, and the kinetic parameters fot the matrix-bound derivatives were generally similar to those for the soluble enzyme, but the matrix-bound derivatives showed higher thermal stability and greater resistance to denaturation than did the soluble enzyme. The rates of reaction of thiol groups of the matrix-bound derivatives with iodoacetamide in the absence and in the presence of combinations of substrates were similar to those of the soluble enzyme. Studies with 5,5'-dithiobis-(2-nitrobenzoic acid) and with iodoacetamide revealed the presence of an additional reactive thiol group in the matrix-bound subunit derivative, which is presumably masked in the dimeric derivatives.     

Phosphagen kinase evolution. Expression in echinoderms

Arginine kinase and creatine kinase that catalyze the transfer of a phosphate group between ATP and arginine and creatine, respectively, play an important role in cellular energetics. In contrast to most animals which exhibit a single phosphagen kinase activity (creatine kinase in chordates and arginine kinase in protostomians), echinoderms exhibit both arginine kinase and creatine kinase activities, sometimes in the same tissue. In contrast to chordates in which creatine kinases are dimers (consisting of two subunits of 40 kDa) and protostomians in which arginine kinases are usually monomers (40 kDa), echinoids contain specific phosphagen kinases: a dimeric arginine kinase (consisting of two subunits of 42 kDa) in eggs and a monomeric creatine kinase (145 kDa) in sperm. We have examined echinoderms from the five existing classes (echinoids, asteroids, ophiuroids, holothurians and crinoids) for the expression of these specific phosphagen kinases in different tissues. Gel filtration was used to determine the molecular masses of the native enzymes. Antibodies specific for arginine kinase or for creatine kinase were used to characterize the subunit composition of arginine kinase and creatine kinase after SDS/PAGE and transfer. In all echinoderms analyzed, arginine kinase always occurred as an enzyme of about 81 kDa consisting of two subunits of 42 kDa and creatine kinase as a monomeric enzyme of 140-155 kDa. The occurrence in echinoderms of both phosphagen kinases with distinct specificities and specific molecular structures is discussed from both a developmental and evolutionary point of view.     

Interaction of brain-type creatine kinase with its transition state analog: kinetics of inhibition and conformational changes

The effects of components of the transition state analog (creatine, MgADP, planar anion) on the kinetics and conformation of creatine kinase isozyme BB from monkey brain was studied. From analysis of the reaction time course using the pH stat assay, it was shown that during accumulation of the reaction products (ADP and creatine phosphate), among several anions added, nitrate proved the most effective in inhibiting catalytic activity. Maximum inhibition (77%) was achieved with 50 mM nitrate. The Km for ATP was 0.48 mM and in the presence of 2.5 mM nitrate, 2.2 mM; for ATP in the presence of the dead-end complex, creatine and ADP, the apparent Km was 2.0 mM and the Ki was 0.16 mM; in the presence of the transition state analog, MgADP + NO3- + creatine, the Ki was estimated to be 0.04 mM. Ultraviolet difference spectra of creatine kinase revealed significant differences only in the presence of the complete mixture of the components of the transition state analog. Comparison of gel filtration elution profiles for creatine kinase in the absence and presence of the complete mixture of components of the transition state analog did not reveal any differences in elution volume. Addition of components of the transition state analog to creatine kinase resulted in only a marginal change in intrinsic fluorescence. The presence of the components of the transition state analog increased the rate of reactivity of the enzyme with trinitrobenzenesulfonic acid from k = 6.06 +/- 0.05 M-1 min-1 to 6.96 +/- 0.11 M-1 min-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Substrate specificity of CTP synthetase from Escherichia coli

The stoichiometry of the enzymatic reaction catalyzed by CTP synthetase from Escherichia coli was analyzed by high-performance liquid chromatography. The results revealed that for every mole of UTP transformed to CTP, one mole of ATP was converted to ADP. The substrate specificity of CTP synthetase from E. coli was investigated by means of UTP analogs. Chemical modification of UTP involved either the uracil, ribose or 5'-triphosphate part. None of the UTP analogs studied proved to be a substrate. The capacity of the UTP analogs to inhibit CTP synthetase was investigated. From the UTP derivatives employed only 2-thiouridine 5'-triphosphate was found to inhibit the enzyme competitively with reasonable affinity: Ki/Km(UTP) = 1. This study indicated that the three main structural elements of the UTP molecule: uracil, ribose and 5'-triphosphate moiety, contribute to substrate specificity. The behaviour of a limited number of CTP analogs as product-like inhibitors supported this view.     

Effect of oligomerization on the properties of essential SH-groups of mitochondrial creatine kinase

The properties of creatine kinase isolated from bovine heart mitochondria in dimeric (Mr = 84 +/- 6 kD) and octameric (Mr = 340 +/- 17 kD) forms were compared with those of the earlier described hexameric form of the enzyme (Mr = 240 +/- 12 kD). The kinetics of SH-group modification by DTNB, the inactivation kinetics as well as the number of modified SH-groups point to significant differences between the three oligomeric forms of the enzyme. Each subunit of creatine kinase was found to possess one "fast" essential cysteine residue whose modification by DTNB and iodoacetamide led to enzyme inactivation. The formation of an analog of the transition state complex (E--MgADP--NO3--creatine) was paralleled with partial protection of only the "fast" cysteine residue which manifested itself in the decrease of the rate of its interaction with DTNB in all the three oligomeric forms. Dimer association into a hexamer and octamer occurred in parallel with a decrease of the affinity of essential SH-groups of cysteine for DTNB in 50% of the oligomeric molecule subunits. Thus, in the dimer two essential SH-groups were rapidly modified by DTNB at the same rate: k1 = k2 = (23.9 +/- 5.6).10(4) M-1 min-1. Within the hexamer, the rate of modification of 3 out of 6 SH-groups was practically unchanged: k1 = (10.6 +/- 2.3).10(4) M-1 min-1. Another 3 SH-groups in the remaining 50% of the subunits were partly masked, which manifested itself in a 10-fold decrease of their modification rate: k2 = (1.12 +/- 0.28).10(4) M-1 min-1. Within the octamer, the SH-groups rapidly interacted with DTNB only on 4 subunits: k1 = (20.7 +/- 2.2).10(4) M-1 min-1, whereas in the remaining 4 octamer subunits a practically complete masking of essential SH-groups was observed, as a result of which these groups became inaccessible to DTNB. This manifested itself in a 1000-fold decrease of the rate of SH-group modification by DTNB which reached that of non-essential SH-group modification. In has been found that a complete loss of the octamer activity is due to the modification of only 4 SH-groups which interact with DTNB at a high rate. A model for subunit association into a dimer, hexamer and octamer has been proposed. Presumably, 50% of the active centers in the mitochondrial creatine kinase octamer are not involved in the catalytic act.     

Mapping the ATP-binding site in the catalytic subunit of adenosine-3':5'-monophosphate-dependent protein kinase. Spatial relationship with the ATP site of the undissociated enzyme.

A set of 24 ATP analogs modified at various positions of the ATP molecule was used for mapping the ATP-binding site in the free catalytic subunit (C) of cAMP-dependent protein kinase (type I). Ki values for these analogs (of which 23 were shown to be competitive with ATP) were measured and compared with Ki values previously obtained for the same set of analogs upon binding to the undissociated form of the enzyme (R2C2). It was found that modifications at the adenine part of ATP bring about a considerable reduction in affinity between C and the resulting analog. The other parts of the ATP molecule play a less important, though definite, role in the binding of this nucleotide to C. By measuring the effect of each given modification in ATP on its binding to C, and comparing the effect of this modification on the binding of the same analog to R2C2, it was possible to obtain 'specificity profiles' for both forms of the kinase. Using such profiles it is shown that the adenine-binding subsite in C may well coincide with the adenine-binding subsite in R2C2. Two plausible models describing the spatial relationship between the ATP sites in C and R2C2 are proposed.     

Octameric mitochondrial and dimeric cytoplasmic creatine kinase. The number of subunits, participating in catalysis

It was found that in the octameric form of mitochondrial creatine kinase (Mr = 340 kD), only 52% of active centers bind Mg-ADP into a E-Mg-ADP-creatine complex with the dissociation constant, K(Cr)ADP, of 0.105 mM, which is close to the Km value for the enzyme (0.072 mM). In the dimeric form of cytoplasmic creatine kinase (Mr = 82 kD), 100% of active centers bind Mg--ADP; the K(Cr)ADP value (0.11 mM) is close to the Km value for the given enzyme preparation (0.083 mM). All active centers of rabbit muscle cytoplasmic creatine kinase were shown to form an analog of the transition state complex (ATSC) - E-Mg-ADP-NO3- -creatine. The constant for Mg-ADP dissociation from ATSC is identical for all centers of cytoplasmic creatine kinase and equals to 6.0 microM. The curves for ATSC saturation with Mg-ADP in the presence of iodacetamide for mitochondrial creatine kinase were constructed and computer analyzed. It was shown that in the octameric form of the enzyme only 54 +/- 13% of subunits can form ATSC. The constant for Mg-ADP dissociation from ATSC, KATSCADP is equal to 1.9 +/- 0.8 microM. It was concluded that 50% of subunits of the octameric form of mitochondrial creatine kinase are not involved in the catalytic act due to masking of their active centres and their inability to form transition state complexes. A model of regulation of cell supply with high energy compounds, e.g., ATP, creatine phosphate, via association-dissociation of mitochondrial creatine kinase oligomers is proposed.     

Brain pyridoxal kinase dissociation of the dimeric structure and catalytic activity of the monomeric species

Reversible dissociation of the dimeric structure of brain pyridoxal kinase into subunits was attained by addition of guanidinium HCl (2 M). The molecular mass of the subunits (40 kDa) was determined by HPLC chromatography. Separation of the processes of refolding and association of the monomeric species was achieved by attaching the protein subunits to a rigid matrix (Affi-gel 15). The matrix-bound monomer is catalytically competent. The reaction of the crosslinking reagent 4,4'-dimaleimidestilbene 2,2'-disulfonate (DMDS), a derivatized stilbene, with the dimeric structure of pyridoxal kinase resulted in the formation of an oligomeric species of 80 kDa detectable by SDS-PAGE. The crosslinked subunits exhibit the same catalytic parameters as the native enzyme. The presence of two nucleotide-binding sites per dimer was determined by fluorimetric titrations using pyridoxyl-ATP, a strong competitive inhibitor with respect to ATP. The ATP analog binds with a Kd = 5 microM to each nucleotide site of the dimeric enzyme. The mode of binding pyridoxyl-ATP to the kinase is discussed in reference to a model which assumes the presence of two binding domains per subunit.     

Purification and characterization of the bifunctional thymidylate synthetase-dihydrofolate reductase from methotrexate-resistant Leishmania tropica

Thymidylate synthetase (TS) and dihydrofolate reductase (DHFR) in Leishmania tropica exist as a bifunctional protein. By use of a methotrexate-resistant strain, which overproduces the bifunctional enzyme, the protein was purified 80-fold to apparent homogeneity in two steps. The native protein has an apparent molecular weight of 110 000 and consists of two subunits with identical size and charge. Available data indicate that each of the subunits possesses TS and DHFR. The TS of the bifunctional protein forms a covalent 5-fluoro-2'-deoxyuridylate (FdUMP)-(+/-)-5,10-methylenetetrahydrofolate-enzyme complex in which 2 mol of FdUMP is bound per mole of enzyme. In contrast, titration of DHFR with methotrexate indicated that only 1 mol of the inhibitor is bound per mole of dimeric enzyme. Both TS and DHFR activities of the bifunctional enzyme were inactivated by the sulfhydryl reagent N-ethylmaleimide. Substrates of the individual enzymes afforded protection against inactivation, indicating that each enzyme requires at least one cysteine for catalytic activity. Kinetic evidence indicates that most, if not all, of the 7,8-dihydrofolate produced by TS is channeled to DHFR faster than it is released into the medium. Although the mechanism of channeling is unknown, the possibility that the two enzymes share a common folate binding site has been ruled out.     

Sensitive radioimmuno assay for 2',5'-oligoadenylates using a novel 125I-labeled derivative of 2',5'-triadenylate 5'-triphosphate

A novel 125I-labeled derivative of 2',5'-triadenylate 5'-triphosphate, pppA2'p5'A2'p5'A, with high specific radioactivity was synthesized by coupling of periodate-oxidized pA2'p5'A2'p5'A with beta-alanyltyrosine methyl ester followed by 5'-triphosphorylation and iodination with 125I. Antisera toward 2',5'-oligoadenylate 5'-triphosphate were produced in rabbits by immunization with the conjugate of pppA2'p5'A2'p5'A2'p5'A with bovine serum albumin, and an antiserum with high specificity and high sensitivity for 2',5'-oligoadenylates was selected and tested extensively. Radioimmuno assaying of 2',5'-oligoadenylates was carried out by a competitive double antibody method in which the amount of the antibody bound to the 125I-labeled probe was measured after precipitation with goat anti-rabbit IgG. The concentration of pppA2'p5'A2'p5'A required for 50% inhibition of the binding between the antiserum and the probe was 0.6 nM. The cross reactivity of the antiserum with the 3',5'-triadenylate was more than 10,000 times weaker compared to in the case of 2',5'-oligoadenylates. Very low or no cross reaction was observed with ATP, AMP, and adenosine. The radioimmuno assay using the 125I-labeled compound and the antiserum allows the direct analysis of 2',5'-oligoadenylates in the range of 4 fmol to 1 pmol (0.04-10 nM in a 100 microliter sample). This assay was applied to the measurement of the activity of 2',5'-oligoadenylate synthetase in cells stimulated by interferon. The properties of the 125I-labeled derivative of pppA2'p5'A2'p5'A are described.     

Characterization of the glutamine site of Escherichia coli guanosine 5'-monophosphate synthetase.

Alkylation of guanosine 5'-monophosphate (GMP) synthetase with the glutamine analogs L-2-amino-4-oxo-5-chloropentanoic acid (chloroketon) and 6-diazo-5-oxonorleucine (DON) inactivated glutamine- and NH3-dependent GMP synthetase. Inactivation exhibited second order kinetics. Complete inactivation was accompanied by covalent attachment of 0.4 to 0.5 equivalent of chloroketon/subunit. Alkylation of GMP synthetase with iodacetamide selectively inactivated glutamine-dependent activity. The NH3-dependent activity was relatively unaffected. Approximately 1 equivalent of carboxamidomethyl group was incorporated per subunit. Carboxymethylcysteine was the only modified amino acid hydrolysis. Prior treatment with chloroketone decreased the capacity for alkylation by iodacetamide, suggesting that both reagents alkylate the same residue. GMP synthetase exhibits glutaminase activity when ATP is replaced by adenosine plus PPi. Iodoacetamide inactivates glutaminase concomitant with glutamine-dependent GMP synthetase. Analysis of pH versus velocity and Km data indicates that the amide of glutamine remains enzyme bound and does not mix with exogenous NH3 in the synthesis of GMP.     

Covalent derivatives of aminoacyl-tRNA-synthetases with substrates

The possibility of participation of covalent enzyme substrate's derivatives in reactions catalyzed by aminoacyl-tRNA synthetases is discussed in connection with general principles of enzyme catalysis. Tryptophanylated and pyrophosphorylated forms of beef pancreas tryptophanyl-tRNA synthetase were identified, isolated and characterized and the expected role of these derivatives in the enzyme function is discussed.     

The arrangement and role of some of the amino acid residues in the beta-ketoacyl synthetase site of chicken liver fatty acid synthetase

The beta-ketoacyl synthetase site of eukaryotic fatty acid synthetases is comprised in part of a pantetheinyl residue on one subunit juxtapositioned with a cysteinyl residue on the adjacent subunit. The present study has confirmed this arrangement and has identified 2 additional residues in the site. The active site residues were identified as summarized below. Sodium borohydride reduction of the keto derivatives of the dibromopropanone cross-linked residues yielded the alcohol derivatives which were amenable to isolation in good yields. The active enzyme yielded primarily a cysteinecysteamine derivative of 2-propanol, demonstrating that a cystyl and the pantetheinyl residues were cross-linked by dibromopropanone. However, in the cold-inactivated enzyme, the primary product of the cross-linking reaction was the dicystyl derivative. In addition, cross-linking between the cystyl and pantetheinyl residues, but not the two cystyl residues, resulted in the cross-linking of the two subunits. Therefore, it is proposed that there are two cystyl residues on one subunit juxtapositioned with the pantetheinyl residue on the adjacent subunit. The cystyl residues are highly reactive toward alkylating agents at pH 6.5, suggesting the presence of a cationic residue interacting with the thiolate anion. This proposal was supported using the bifunctional reagent o-phthalaldehyde which was found to cross-link the epsilon-amino group of lysine with the pantetheinyl-SH or the cystyl-SH in the beta-ketoacyl synthetase site to form a thioisoindole ring. The dialdehyde inhibited the enzyme by inactivating the beta-ketoacyl synthetase activity, and the inhibition could be prevented by malonyl-CoA and to a lesser extent by acetyl-CoA. Blocking the reactive thiol groups with dibromopropanone or 5,5'-dithiobis(2-nitrobenzoic acid) reduced the formation of the fluorescent thioisoindole ring. The close arrangement of a cystyl-SH, the pantetheinyl-SH, and the epsilon-amino group of lysine led us to propose that the positive epsilon-amino group may serve as an electron sink in a general acid-catalyzed decarboxylation reaction.     

New ribose-modified fluorescent analogs of adenine and guanine nucleotides available as substrates for various enzymes

The synthesis of fluorescent derivatives of nucleosides and nucleotides, by reaction with isatoic anhydride in aqueous solution at mild pH and temperature, yielding their 3'-O-anthraniloyl derivatives, is here described. The N-methylanthraniloyl derivatives were also synthesized by reaction with N-methylisatoic anhydride. Upon excitation at 330-350 nm these derivatives exhibited maximum fluorescence emission at 430-445 nm in aqueous solution with quantum yields of 0.12-0.24. Their fluorescence was sensitive to the polarity of the solvent; in N,N-dimethylformamide the quantum yields were 0.83-0.93. The major differences between the two fluorophores were the longer wavelength of the emission maximum of the N-methylanthraniloyl group and its greater quantum yield in water. All anthraniloyl derivatives, as well as the N-methylanthraniloyl ones, had virtually identical fluorescent properties, regardless of their base structures. The ATP derivatives showed considerable substrate activity as a replacement of ATP with adenylate kinase, guanylate kinase, glutamine synthetase, myosin ATPase and sodium-potassium transport ATPase. The ADP derivatives were good substrates for creatine kinase and glutamine synthetase (gamma-glutamyl transfer activity). The GMP and adenosine derivatives were substrates for guanylate kinase and adenosine deaminase, respectively. All derivatives had only slightly altered Km values for these enzymes. While more fluorescent in water, the N-methylanthraniloyl derivatives were found to show relatively low substrate activities against some of these enzymes. The results indicate that these ribose-modified nucleosides and nucleotides can be versatile fluorescent substrate analogs for various enzymes.