The effect of starvation on insulin secretion and glucose metabolism in mouse pancreatic islets

1. Crude extracts of seeds of Pinus radiata catalysed acetate-, propionate-, n-butyrate- and n-valerate-dependent PP(i)-ATP exchange in the presence of MgCl(2), which was apparently due to a single enzyme. Propionate was the preferred substrate. Crude extracts did not catalyse medium-chain or long-chain fatty acid-dependent exchange. 2. Ungerminated dry seeds contained short-chain fatty acyl-CoA synthetase activity. The activity per seed was approximately constant for 11 days after imbibition and then declined. The enzyme was located only in the female gametophyte tissue. 3. The synthetase was purified 70-fold. 4. Some properties of the enzyme were studied by [(32)P]PP(i)-ATP exchange. K(m) values for acetate, propionate, n-butyrate and n-valerate were 4.7, 0.21, 0.33 and 2.1mm respectively. Competition experiments between acetate and propionate demonstrated that only one enzyme was involved and confirmed that the affinity of the enzyme for propionate was greater than that for acetate. CoA inhibited fatty acid-dependent PP(i)-ATP exchange. The enzyme catalysed fatty acid-dependent [(32)P]PP(i)-dATP exchange. 5. The enzyme also catalysed the fatty acyl-AMP-dependent synthesis of [(32)P]ATP from [(32)P]PP(i). Apparent K(m) (acetyl-AMP) and apparent K(m) (propionyl-AMP) were 57mum and 7.5mum respectively. The reaction was inhibited by AMP and CoA. 6. Purified enzyme catalysed the synthesis of acetyl-CoA and propionyl-CoA. Apparent K(m) (acetate) and apparent K(m) (propionate) were 16mm and 7.5mm respectively. The rate of formation of acetyl-CoA was enhanced by pyrophosphatase. 7. It was concluded that fatty acyl adenylates are intermediates in the formation of the corresponding fatty acyl-CoA.     

Synthesis of P1,P4-di(adenosine 5'-) tetraphosphate by leucyl-tRNA synthetase, coupled with ATP regeneration

A simple and practical procedure for the synthesis of P1,P4-di(adenosine 5'-) tetraphosphate from ATP by the catalysis of leucyl-tRNA synthetase from Bacillus stearothermophilus is described. Km for leucine was 6.7 microM and for ATP was 3.3 mM. The reaction yielded not only diadenosine tetraphosphate, but various byproducts such as P1,P3-(diadenosine 5'-) triphosphate, ADP and AMP. By coupling the reaction with an ATP regeneration system by acetate kinase and adenylate kinase with acetylphosphate as a phosphate donor, diadenosine tetraphosphate was prepared as a sole product at a high yield (96%).     

Adenosine 5'-tetraphosphate is synthesized by the histidine alpha 142----asparagine mutant of Escherichia coli succinyl-CoA synthetase.

Recently, we described the properties of a mutant (H142N) of Escherichia coli succinyl coenzyme A (CoA) synthetase in which His-142 of the alpha-subunit was changed to Asn (Luo, G.-X., and Nishimura, J.S. (1991) J. Biol. Chem. 266, 20781-20785). The mutant enzyme was practically devoid of ability to catalyze the overall reaction but was able to catalyze half-reactions at significant rates. Thus, phosphorylation by ATP and dephosphorylation by ADP of the mutant enzyme occurred at rates that were at least 10 times greater than those with wild type enzyme, and dephosphorylation by succinate plus CoA (succinyl-CoA formation) proceeded with a Vmax of 10% that of wild type, with no change in Km for succinate and very little change in Km for CoA. In the present work, it has been shown that incubation of 32P-labeled H142N with ATP caused a rapid depletion of label from the enzyme and incorporation of radioactivity into a nucleotide species that was neither ATP nor ADP. This reaction was catalyzed at comparatively negligible rates by wild type enzyme. Analysis of the labeled product by high pressure liquid chromatography and 31P NMR revealed that it was adenosine 5'-tetraphosphate (AP4). Incubation of labeled H142N with the ATP analog beta,gamma-methylene adenosine triphosphate also gave a product that appeared to be the corresponding tetraphosphate. The reaction in which AP4 was formed was greatly stimulated by the addition of phosphoenolpyruvate plus pyruvate kinase and strongly inhibited by ADP and by CoA plus succinate. The results are consistent with binding of ATP to, and reaction with, phosphorylated succinyl-CoA synthetase to form AP4. In this reaction, it was determined that the Km for ATP and the turnover number of phosphorylated enzyme were 14.5 microM and 0.024 s-1, respectively.     

Isolation and characterization of acetyl-coenzyme A synthetase from Methanothrix soehngenii.

In Methanothrix soehngenii, acetate is activated to acetyl-coenzyme A (acetyl-CoA) by an acetyl-CoA synthetase. Cell extracts contained high activities of adenylate kinase and pyrophosphatase, but no activities of a pyrophosphate:AMP and pyrophosphate:ADP phosphotransferase, indicating that the activation of 1 acetate in Methanothrix requires 2 ATP. Acetyl-CoA synthetase was purified 22-fold in four steps to apparent homogeneity. The native molecular mass of the enzyme from M. soehngenii estimated by gel filtration was 148 kilodaltons (kDa). The enzyme was composed of two subunits with a molecular mass of 73 kDa in an alpha 2 oligomeric structure. The acetyl-CoA synthetase constituted up to 4% of the soluble cell protein. At the optimum pH of 8.5, the Vmax was 55 mumol of acetyl-CoA formed per min per mg of protein. Analysis of enzyme kinetic properties revealed a Km of 0.86 mM for acetate and 48 microM for coenzyme A. With varying amounts of ATP, weak sigmoidal kinetic was observed. The Hill plot gave a slope of 1.58 +/- 0.12, suggesting two interacting substrate sites for the ATP. The kinetic properties of the acetyl-CoA synthetase can explain the high affinity for acetate of Methanothrix soehngenii.     

Crystal structure of yeast acetyl-coenzyme A synthetase in complex with AMP

Acetyl-coenzyme A synthetase (ACS) belongs to the family of AMP-forming enzymes that also includes acyl-CoA synthetases, firefly luciferase, and nonribosomal peptide synthetases. ACS catalyzes the two-step activation of acetate to acetyl-CoA: formation of an acetyl-AMP intermediate from acetate and ATP and the transfer of the acetyl group to CoA. In mammals, the acetyl-CoA product is used for biosynthesis of long chain fatty acids as well as energy production. We have determined the crystal structure of yeast ACS in a binary complex with AMP at 2.3 A resolution. The structure contains a large, N-terminal domain and a small, C-terminal domain. AMP is bound at the interface between the two domains. This structure represents a new conformation for the ACS enzyme, which may be competent for catalyzing the first step of the reaction. A Lys residue that is critical for this step is located in the active site. A rotation of 140 degrees in the small domain is needed for the binding of CoA and the catalysis of the second step. In contrast to the monomeric bacterial enzyme, yeast ACS is a stable trimer.     

Characterization of the acetyl-CoA synthetase of Acetobacter aceti.

The acetate activating system of Acetobacter aceti has been studied. The enzyme responsible, acetyl-CoA synthetase, has been purified about 500-fold from crude cell extracts and was approximately 85% pure as judged by polyacrylamide gel electrophoresis in sodium dodecyl sulphate. The purified enzyme showed optimal activity at pH 7.6 in both Tris-HCL and potassium phosphate buffers. In its purest form, the enzyme was stable at 4 degrees-C but denatured upon freezing. The Km values for CoA, ATP and acetate were found to be 0.104 mM, 0.36 mM and 0.25 mM respectively; propionate and acrylate were also activated by the enzyme but not butyrate, isobutyrate or valerate. GTP, UTP, CTP and ADP could not replace ATP in the reaction, and cysteine or pantetheine failed to replace CoA. The cationic requirements were studied and of the divalent cations tested, only Mn2+ could significantly replace Mg2+ in the reaction; K+ and NH4+ stimulated enzyme activity but inhibited at high concentrations; Na+ was a poor activator, but did not inhibit at higher concentrations. The effect of a number of glucose and other metabolites on enzyme activity has been tested.     

Biochemical and Kinetic Characterization of the Recombinant ADP-Forming Acetyl Coenzyme A Synthetase from the Amitochondriate Protozoan Entamoeba histolytica

Entamoeba histolytica, an amitochondriate protozoan parasite that relies on glycolysis as a key pathway for ATP generation, has developed a unique extended PP_i-dependent glycolytic pathway in which ADP-forming acetyl-coenzyme A (CoA) synthetase (ACD; acetate:CoA ligase [ADP-forming]; EC 6.2.1.13) converts acetyl-CoA to acetate to produce additional ATP and recycle CoA. We characterized the recombinant E. histolytica ACD and found that the enzyme is bidirectional, allowing it to potentially play a role in ATP production or in utilization of acetate. In the acetate-forming direction, acetyl-CoA was the preferred substrate and propionyl-CoA was used with lower efficiency. In the acetyl-CoA-forming direction, acetate was the preferred substrate, with a lower efficiency observed with propionate. The enzyme can utilize both ADP/ATP and GDP/GTP in the respective directions of the reaction. ATP and PP_i were found to inhibit the acetate-forming direction of the reaction, with 50% inhibitory concentrations of 0.81 ± 0.17 mM (mean ± standard deviation) and 0.75 ± 0.20 mM, respectively, which are both in the range of their physiological concentrations. ATP and PP_i displayed mixed inhibition versus each of the three substrates, acetyl-CoA, ADP, and phosphate. This is the first example of regulation of ACD enzymatic activity, and possible roles for this regulation are discussed.     

Properties of 5-hydroxyvalerate CoA-transferase from Clostridium aminovalericum

5-Hydroxyvalerate CoA-transferase from Clostridium aminovalericum, strain T2-7, was purified approximately 100-fold to homogeneity. The molecular mass of the native enzyme was determined by three different methods to be 178 +/- 11 kDa; that of the subunit was 47 kDa, indicating a homotetrameric structure. The following CoA esters acted as substrates (decreasing specificity, V/Km): 5-hydroxyvaleryl-CoA greater than propionyl-CoA greater than acetyl-CoA greater than (Z)-5-hydroxy-2-pentenoyl-CoA greater than butyryl-CoA greater than valeryl-CoA. 4-Pentenoate and 3-pentenoate were also activated by acetyl-CoA to the corresponding CoA esters, whereas crotonate, (E)-5-hydroxy-2-pentenoate, (E)-2-pentenoate and 2,4-pentadienoate were not attacked. 5-Hydroxyvalerate CoA-transferase showed ping-pong kinetics and was inactivated by sodium boranate only in the presence of a CoA substrate. This indicated the formation of a thiolester between a specific carboxyl group of the enzyme and CoASH during the course of the reaction. The CoA-transferase was inhibited by ATP and CTP, slightly by ADP, GTP and UTP, but not by AMP. The inhibition by ATP was competitive towards CoA esters and noncompetitive towards acetate.     

Stringent response of Bacillus stearothermophilus: evidence for the existence of two distinct guanosine 3',5'-polyphosphate synthetases.

Bacillus stearothermophilus reacted to pseudomonic acid-induced inhibition of isoleucine-transfer ribonucleic acid (RNA) acylation and to energy downshift caused by alpha-methylglucoside addition with accumulation of guanosine 3',5'-polyphosphates [(p)ppGpp] and restriction of RNA synthesis. In vitro studies indicated that (p)ppGpp was synthesized by two different enzymes. One enzyme, (p)ppGpp synthetase I, was present in the ribosomal fraction, required the addition of a ribosome-messenger RNA-transfer RNA complex for activation, and was inhibited by tetracycline and thiostrepton. It is suggested that (p)ppGpp synthetase I is comparable to the relA gene product from Escherichia coli and is responsible for (p)ppGpp accumulation during amino acid starvation. The other enzyme, (p)ppGpp synthetase II, was found in the high-speed supernatant fraction (S100). It functioned independently of ribosomes, transfer RNA, and messenger RNA and was not inhibited by the above-mentioned antibiotics. (p)ppGpp synthetase II is thought to be responsible for (p)ppGpp accumulation during carbon source downshift. The two enzymes differ in their Km values for adenosine triphosphate (ATP):2mM ATP for synthetase I and 0.05 mM ATP for synthetase II. They also have different molecular weights: apparent Mr of 86,000 (+/- 5,000) for synthetase I and 74,000 (+/- 5,000) for synthetase II.     

Biosynthesis of acetyl-coenzyme A in the electric organ of Torpedo marmorata in relation to acetylcholine metabolism.

Formation of acetyl-CoA through acetyl-CoA synthetase (forward reaction) and through choline acyltransferase (backward reaction) was investigated in tissue extract from the electric organ of Torpedo marmorata. When the tissue extract was submitted to gel filtration on Sephadex G-25, the formation of acetyl-CoA by acetyl-CoA synthetase appeared fully dependent on ATP and CoA and partially dependent on acetate (an endogenous supply of acetate is discussed). Choline acetyltransferase was a potent source of acetyl-CoA, only requiring acetylcholine and CoA, and was much more efficient than acetyl-CoA synthetase for concentrations of acetylcholine likely to be present in nerve endings.     

A comparative study on acetyl-CoA synthesising enzymes in spinal cord from cows, horses and pigs

1. Comparative data are presented of the activities of pyruvate dehydrogenase complex and acetyl-CoA synthetase and of the acetate content in homogenates from ventral grey matter in spinal cord from cows and two non-ruminant species, pigs and horses. The methods used in the study are evaluated and discussed. 2. The total pyruvate dehydrogenase complex activity was 24.9-29.9 mU/mg protein and did not differ between the species. The part of the complex that was in active form at the sampling occasion was 60, 85 and 95% in cows, pigs and horses, respectively. 3. Acetyl-CoA synthetase activity differed significantly between the species and was 0.93, 1.28 and 2.61 mU/mg protein in pigs, cows and horses, respectively. The highest cytosolic activity was found in the horses. Acetate concentration at half maximal reaction velocity (at saturating CoA and ATP levels) was found to be 0.15-0.70 mM and did not differ between the species. 4. Acetate content was 63, 83 and 96 micrograms/g wet wt in cows, horses and pigs, respectively. 5. It is concluded that there seems to be no striking difference in acetyl-CoA synthesis in peripheral nerves between ruminants and non-ruminant species.     

Synthesis of diadenosine 5',5'-P1,P4-tetraphosphate (AppppA) from adenosine 5'-phosphosulfate and adenosine 5'-triphosphate catalyzed by yeast AppppA phosphorylase

A novel way of enzymatic synthesis of diadenosine 5',5"'-P1,P4-tetraphosphate (AppppA), which does not involve aminoacyl-tRNA synthetases, has been discovered. Yeast AppppA alpha, beta-phosphorylase catalyzes irreversible conversion of adenosine 5'-phosphosulfate (APS) and ATP into AppppA according to the equation APS + ATP----AppppA + sulfate. In this reaction, the enzyme exhibits a broad pH optimum (between 6 and 8) and requires Mn2+, Mg2+, or Ca2+ ions for activity, with Mn2+ being twice as effective as Mg2+ or Ca2+ at optimal concentration (0.5 mM). The Km values computed for APS and ATP are 80 microM and 700 microM, respectively. The rate constant for the AppppA synthesis is 3 s-1 (pH 8.0, 30 degrees C, 0.5 mM MgCl2). Some ATP analogues like ppppA, GTP, adenosine 5'-(alpha, beta-methylenetriphosphate), and adenosine 5'-(beta, gamma-methylenetriphosphate), but not dATP, UTP, or CTP, are also substrates for AppppA phosphorylase and accept adenylate from APS with the formation of AppppA, AppppG, Appp(CH2)pA, and App(CH2)ppA, respectively. Functional versatility of yeast AppppA phosphorylase may provide a link between metabolism of AppppA on one hand and metabolism of APS and phosphate on the other and raises the possibility of participation of AppppA in regulation of metabolism of APS and/or inorganic phosphate in yeast.     

The 1.75 A crystal structure of acetyl-CoA synthetase bound to adenosine-5'-propylphosphate and coenzyme A

Acetyl-coenzyme A synthetase catalyzes the two-step synthesis of acetyl-CoA from acetate, ATP, and CoA and belongs to a family of adenylate-forming enzymes that generate an acyl-AMP intermediate. This family includes other acyl- and aryl-CoA synthetases, firefly luciferase, and the adenylation domains of the modular nonribosomal peptide synthetases. We have determined the X-ray crystal structure of acetyl-CoA synthetase complexed with adenosine-5'-propylphosphate and CoA. The structure identifies the CoA binding pocket as well as a new conformation for members of this enzyme family in which the approximately 110-residue C-terminal domain exhibits a large rotation compared to structures of peptide synthetase adenylation domains. This domain movement presents a new set of residues to the active site and removes a conserved lysine residue that was previously shown to be important for catalysis of the adenylation half-reaction. Comparison of our structure with kinetic and structural data of closely related enzymes suggests that the members of the adenylate-forming family of enzymes may adopt two different orientations to catalyze the two half-reactions. Additionally, we provide a structural explanation for the recently shown control of enzyme activity by acetylation of an active site lysine.     

Acetyl Coenzyme A Synthetase (ADP Forming) from the Hyperthermophilic Archaeon Pyrococcus furiosus: Identification, Cloning, Separate Expression of the Encoding Genes, acdAI and acdBI, in Escherichia coli, and In Vitro Reconstitution of the Active Heterotetrameric Enzyme from Its Recombinant Subunits

Acetyl-coenzyme A (acetyl-CoA) synthetase (ADP forming) represents a novel enzyme in archaea of acetate formation and energy conservation (acetyl-CoA + ADP + P(i) --> acetate + ATP + CoA). Two isoforms of the enzyme have been purified from the hyperthermophile Pyrococcus furiosus. Isoform I is a heterotetramer (alpha(2)beta(2)) with an apparent molecular mass of 145 kDa, composed of two subunits, alpha and beta, with apparent molecular masses of 47 and 25 kDa, respectively. By using N-terminal amino acid sequences of both subunits, the encoding genes, designated acdAI and acdBI, were identified in the genome of P. furiosus. The genes were separately overexpressed in Escherichia coli, and the recombinant subunits were reconstituted in vitro to the active heterotetrameric enzyme. The purified recombinant enzyme showed molecular and catalytical properties very similar to those shown by acetyl-CoA synthetase (ADP forming) purified from P. furiosus.     

Regulation of phosphatidylcholine synthesis in rat liver endoplasmic reticulum.

The biosynthesis of phosphatidylcholine in rat liver microsomal preparations catalysed by CDP-choline-1,2-diacylglycerol cholinephosphotransferase (EC 2.7.8.2) was inhibited by a combination of ATP and CoA or ATP and pantetheine. ATP alone at high concentrations (20 mM) inhibits phosphatidylcholine formation to the extent of 70%. In the presence of 0.1 mM-CoA, ATP (2 mM) inhibits to the extent of 80% and in the presence of 1 mM-pantetheine to the extent of 90%. ADP and other nucleotide triphosphates in combination with either CoA or pantetheine are only 10-30% as effective in inhibiting phosphatidylcholine synthesis. AMP(CH2)PP [adenosine 5'-(alphabeta-methylene)triphosphate] together with CoA inhibits to the extent of 59% and with pantetheine by 48%. AMP-P(CH2)P [adenosine 5'-(betagamma-methylene)triphosphate] together with either CoA or pantetheine had no significant effect on phosphatidylcholine formation. Other closely related derivatives of pantothenic acid were without effect either alone or in the presence of ATP, as were thiol compounds such as cysteine, homocysteine, cysteamine, dithiothreitol and glutathione. Several mechanisms by which this inhibition might take place were ruled out and it is concluded that ATP together with either CoA or pantetheine interacts reversibly with phosphatidylcholine synthetase to cause temporarily the inhibition of phosphatidylcholine formation.     

Spinach leaf acetyl-coenzyme a synthetase: purification and characterization

Acetyl-coenzyme A (CoA) synthetase was purified 364-fold from leaves of spinach (Spinacia oleracea L.) using ammonium sulfate fractionation followed by ion exchange, dye-ligand, and gel permeation chromatography. The final specific activity was 2.77 units per milligram protein. The average M_r value of the native enzyme was about 73,000. The Michaelis constants determined for Mg-ATP, acetate, and coenzyme A were 150, 57, and 5 micromolar, respectively. The purified enzyme was sensitive to substrate inhibition by CoA with an apparent K_i for CoA of 700 micromolar. The enzyme was specific for acetate; other short and long chain fatty acids were ineffective as substrates. Several intermediates and end products of fatty acid synthesis were examined as potential inhibitors of acetyl-CoA synthetase activity, but none of the compounds tested significantly inhibited acetyl-CoA synthetase activity in vitro. The properties of the purified enzyme support the postulated role of acetyl-CoA synthetase as a primary source of chloroplast acetyl-CoA.     

Synthesis of acetyl coenzyme A by carbon monoxide dehydrogenase complex from acetate-grown Methanosarcina thermophila.

The carbon monoxide dehydrogenase (CODH) complex from Methanosarcina thermophila catalyzed the synthesis of acetyl coenzyme A (acetyl-CoA) from CH3I, CO, and coenzyme A (CoA) at a rate of 65 nmol/min/mg at 55 degrees C. The reaction ended after 5 min with the synthesis of 52 nmol of acetyl-CoA per nmol of CODH complex. The optimum temperature for acetyl-CoA synthesis in the assay was between 55 and 60 degrees C; the rate of synthesis at 55 degrees C was not significantly different between pHs 5.5 and 8.0. The rate of acetyl-CoA synthesis was independent of CoA concentrations between 20 microM and 1 mM; however, activity was inhibited 50% with 5 mM CoA. Methylcobalamin did not substitute for CH3I in acetyl-CoA synthesis; no acetyl-CoA or propionyl coenzyme A was detected when sodium acetate or CH3CH2I replaced CH3I in the assay mixture. CO could be replaced with CO2 and titanium(III) citrate. When CO2 and 14CO were present in the assay, the specific activity of the acetyl-CoA synthesized was 87% of the specific activity of 14CO, indicating that CO was preferentially incorporated into acetyl-CoA without prior oxidation to free CO2. Greater than 100 microM potassium cyanide was required to significantly inhibit acetyl-CoA synthesis, and 500 microM was required for 50% inhibition; in contrast, oxidation of CO by the CODH complex was inhibited 50% by approximately 10 microM potassium cyanide.     

Pathways of acetate and propionate production in adult Fasciola hepatica

In adult F. hepatica pyruvate is decarboxylated via pyruvate dehydrogenase to acetyl-CoA; acetyl-CoA is then cleaved to acetate via three possible mechanisms (1) carnitine dependent hydrolysis, (2) CoA transferase, (3) reversal of a GTP dependent acyl-CoA synthetase. Of these three systems, CoA transferase has by far the greatest activity. Propionate production by F. hepatica is similar to the mammalian system, succinate being metabolized via succinic thiokinase, methylmalonyl-CoA isomerase, methyl-malonyl-CoA racemase and propionyl-CoA carboxylase to propionyl-CoA. Propionyl-CoA is then cleaved to propionate by the same three pathways as acetyl-CoA. No ATP or GTP production could be demonstrated when acetyl- or propionyl-CoA were incubated with homogenates of F. hepatica. This indicates that carnitine dependent hydrolysis or CoA transferase are the major pathways of acetyl- or propionyl-CoA breakdown. The CoA transferase reaction would result in the conservation of the bond energy although there is no net ATP synthesis.     

Synthesis of dinucleoside polyphosphates catalyzed by firefly luciferase.

In the presence of ATP, luciferin (LH2), Mg2+ and pyrophosphatase, the firefly (Photinus pyralis) luciferase synthesizes diadenosine 5',5"'-P1,P4-tetraphosphate (Ap4A) through formation of the E-LH2-AMP complex and transfer of AMP to ATP. The maximum rate of the synthesis is observed at pH 5.7. The Km values for luciferin and ATP are 2-3 microM and 4 mM, respectively. The synthesis is strictly dependent upon luciferin and a divalent metal cation. Mg2+ can be substituted with Zn2+, Co2+ or Mn2+, which are about half as active as Mg2+, as well as with Ni2+, Cd2+ or Ca2+, which, at 5 mM concentration, are 12-20-fold less effective than Mg2+. ATP is the best substrate of the above reaction, but it can be substituted with adenosine 5'-tetraphosphate (p4A), dATP, and GTP, and thus the luciferase synthesizes the corresponding homo-dinucleoside polyphosphates:diadenosine 5',5"'-P1,P5-pentaphosphate (Ap5A), dideoxyadenosine 5',5"'-P1,P4-tetraphosphate (dAp4dA) and diguanosine 5',5"'-P1,P4-tetraphosphate (Gp4G). In standard reaction mixtures containing ATP and a different nucleotide (p4A, dATP, adenosine 5'-[alpha,beta-methylene]-triphosphate, (Ap[CH2]pp), (S')-adenosine-5'-[alpha-thio]triphosphate [Sp)ATP[alpha S]) and GTP], luciferase synthesizes, in addition to Ap4A, the corresponding hetero-dinucleoside polyphosphates, Ap5A, adenosine 5',5"'-P1,P4-tetraphosphodeoxyadenosine (Ap4dA), diadenosine 5',5"'-P1,P4-[alpha,beta-methylene] tetraphosphate (Ap[CH2]pppA), (Sp-diadenosine 5',5"'-P1,P4-[alpha-thio]tetraphosphate [Sp)Ap4A[alpha S]) and adenosine-5',5"'-P1,P4-tetraphosphoguanosine (Ap4G), respectively. Adenine nucleotides, with at least a 3-phosphate chain and with an intact alpha-phosphate, are the preferred substrates for the formation of the enzyme-nucleotidyl complex. Nucleotides best accepting AMP from the E-LH2-AMP complex are those which contain at least a 3-phosphate chain and an intact terminal pyrophosphate moiety. ADP or other NDP are poor adenylate acceptors as very little diadenosine 5',5"'-P1,P3-triphosphate (Ap3A) or adenosine-5',5"'-P1,P3-triphosphonucleosides (Ap3N) are formed. In the presence of NTP (excepting ATP), luciferase is able to split Ap4A, transferring the resulting adenylate to NTP, to form hetero-dinucleoside polyphosphates. In the presence of PPi, luciferase is also able to split Ap4A, yielding ATP. The cleavage of Ap4A in the presence of Pi or ADP takes place at a very low rate. The synthesis of dinucleoside polyphosphates, catalyzed by firefly luciferase, is compared with that catalyzed by aminoacyl-tRNA synthetases and Ap4A phosphorylase.