Adenosine 5'-phosphosulfate kinase from Penicillium chrysogenum. Purification and kinetic characterization

Adenosine 5'-phosphosulfate (APS) kinase, the second enzyme in the pathway of inorganic sulfate assimilation, was purified to near homogeneity from mycelium of the filamentous fungus, Penicillium chrysogenum. The enzyme has a native molecular weight of 59,000-60,000 and is composed of two 30,000-dalton subunits. At 30 degrees C, pH 8.0 (0.1 M Tris-chloride buffer), 5.5 microM APS, 5 mM MgATP, 5 mM excess MgCl2, and "high" salt (70-150 mM (NH4)2SO4), the most highly purified preparation has a specific activity of 24.7 units X mg of protein-1 in the physiological direction of adenosine 3'-phosphate 5'-phosphosulfate (PAPS) formation. This activity is nearly 100-fold higher than that of any previously purified preparation of APS kinase. APS kinase is subject to potent substrate inhibition by APS. In the absence of added salt, the initial velocity at 5 mM MgATP plus 5 mM Mg2+ is maximal at about 1 microM APS and half-maximal at 0.2 and 4.4 microM APS. In the presence of 200 mM NaCl or 70-150 mM (NH4)2SO4, the optimum APS concentration shifts to 4-6 microM APS; the half-maximal values shift to 1-1.3 and 21-27 microM APS. The steady state kinetics of the reaction were investigated using a continuous spectrophotometric assay. The families of reciprocal plots in the range 0.25-5 mM MgATP and 0.8-5.1 microM APS are linear and intersect on the horizontal axis. Appropriate replots yield KmMgATP = 1.5 mM, KmAPS = 1.4 microM, and Vmax, = 38.7 units X mg of protein-1. Excess APS is an uncompetitive inhibitor with respect to MgATP (K1APS = 23 microM). PAPS, the product of the forward reaction, is also uncompetitive with MgATP. PAPS is not competitive with APS. In the reverse direction, the plots have the characteristics of a rapid equilibrium ordered sequence with MgADP adding before PAPS. The kinetic constants are KmPAPS = 8 microM, KiMgADP = 560 microM, and Vmaxr = 0.16 units X mg of protein-1. Iso-PAPS (the 2'-phosphate isomer of PAPS) is competitive with PAPS and uncompetitive with respect to MgADP (Ki = 6 microM). APS kinase is inactivated by phenylglyoxal, suggesting the involvement of an essential argininyl residue. MgATP or MgADP at 10 Ki protect against inactivation. APS or PAPS at 600 and 80 Km, respectively, are ineffective alone, but provide nearly complete protection in the presence of 0.1 Ki of MgADP or MgATP.(ABSTRACT TRUNCATED AT 400 WORDS)     

Crystal structure of adenosine 5'-phosphosulfate kinase from Penicillium chrysogenum

Adenosine 5'-phosphosulfate (APS) kinase catalyzes the second reaction in the two-step conversion of inorganic sulfate to 3'-phosphoadenosine 5'-phosphosulfate (PAPS). This report presents the 2.0 A resolution crystal structure of ligand-free APS kinase from the filamentous fungus, Penicillium chrysogenum. The enzyme crystallized as a homodimer with each subunit folded into a classic kinase motif consisting of a twisted, parallel beta-sheet sandwiched between two alpha-helical bundles. The Walker A motif, (32)GLSASGKS(39), formed the predicted P-loop structure. Superposition of the APS kinase active site region onto several other P-loop-containing proteins revealed that the conserved aspartate residue that usually interacts with the Mg(2+) coordination sphere of MgATP is absent in APS kinase. However, upon MgATP binding, a different aspartate, Asp 61, could shift and bind to the Mg(2+). The sequence (156)KAREGVIKEFT(166), which has been suggested to be a (P)APS motif, is located in a highly protease-susceptible loop that is disordered in both subunits of the free enzyme. MgATP or MgADP protects against proteolysis; APS alone has no effect but augments the protection provided by MgADP. The results suggest that the loop lacks a fixed structure until MgATP or MgADP is bound. The subsequent conformational change together with the potential change promoted by the interaction of MgATP with Asp 61 may define the APS binding site. This model is consistent with the obligatory ordered substrate binding sequence (MgATP or MgADP before APS) as established from steady state kinetics and equilibrium binding studies.     

Adenosine-5'-phosphosulfate kinase from Penicillium chrysogenum: ligand binding properties and the mechanism of substrate inhibition.

[35S]Adenosine-5'-phosphosulfate (APS) binding to Penicillium chrysogenum APS kinase was measured by centrifugal ultrafiltration. APS did not bind to the free enzyme with a measurable affinity even at low ionic strength where substrate inhibition by APS is quite marked. However, APS bound with an apparent Kd of 0.54 microM in the presence of 5 mM MgADP. In the presence of 0.1 M (NH4)2SO4, Kd,app was increased to 2.1 +/- 0.7 microM. Bound [35S]APS was displaced by low concentrations of 3'-phosphoadenosine-5'-phosphosulfate (PAPS), or iso-(2') PAPS, or (less efficiently) by adenosine-3,5'-diphosphate (PAP) or adenosine-5'-monosulfate (AMS). The results support our conclusion that substrate inhibition of the fungal enzyme by APS results from the formation of a dead end E. MgADP.APS complex. That is, APS binds to the subsite vacated by PAPS in the compulsory (or predominately) ordered product release sequence (PAPS before MgADP). Radioligand displacement was used to verify the Kd for APS dissociation from E.MgADP.APS and to determine the Kd values for the dissociation of iso-PAPS (13 +/- 5 microM), PAP (4.8 mM), or AMS (5.2 mM) from their respective ternary enzyme.MgADP.ligand complexes. Incubation of the fungal enzyme with [gamma-32P]MgATP did not yield a phosphoenzyme that survives gel filtration or gel electrophoresis.     

Ligand-induced structural changes in adenosine 5'-phosphosulfate kinase from Penicillium chrysogenum

Adenosine 5'-phosphosulfate (APS) kinase catalyzes the second reaction in the two-step, ATP-dependent conversion of inorganic sulfate to 3'-phosphoadenosine 5'-phosphosulfate (PAPS). PAPS serves as the sulfuryl donor for the biosynthesis of all sulfate esters and also as a precursor of reduced sulfur biomolecules in many organisms. Previously, we determined the crystal structure of ligand-free APS kinase from the filamentous fungus, Penicillium chrysogenum [MacRae et al. (2000) Biochemistry 39, 1613-1621]. That structure contained a protease-susceptible disordered region ("mobile lid"; residues 145-170). Addition of MgADP and APS, which together promote the formation of a nonproductive "dead-end" ternary complex, protected the lid from trypsin. This report presents the 1.43 A resolution crystal structure of APS kinase with both ADP and APS bound at the active site and the 2.0 A resolution structure of the enzyme with ADP alone bound. The mobile lid is ordered in both complexes and is shown to provide part of the binding site for APS. That site is formed primarily by the highly conserved Arg 66, Arg 80, and Phe 75 from the protein core and Phe 165 from the mobile lid. The two Phe residues straddle the adenine ring of bound APS. Arg 148, a completely conserved residue, is the only residue in the mobile lid that interacts directly with bound ADP. Ser 34, located in the apex of the P-loop, hydrogen-bonds to the 3'-OH of APS, the phosphoryl transfer target. The structure of the binary E.ADP complex revealed further changes in the active site and N-terminal helix that occur upon the binding/release of (P)APS.     

Sulfate-activating enzymes of Penicillium chrysogenum. The ATP sulfurylase.adenosine 5'-phosphosulfate complex does not serve as a substrate for adenosine 5'-phosphosulfate kinase

At a noninhibitory steady state concentration of adenosine 5'-phosphosulfate (APS), increasing the concentration of Penicillium chrysogenum ATP sulfurylase drives the rate of the APS kinase-catalyzed reaction toward zero. The result indicates that the ATP sulfurylase.APS complex does not serve as a substrate for APS kinase, i.e. there is no "substrate channeling" of APS between the two sulfate-activating enzymes. APS kinase had no effect on the [S]0.5 values, nH values, or maximum isotope trapping in the single turnover of ATP sulfurylase-bound [35S]APS. Equimolar APS kinase (+/- MgATP or APS) also had no effect on the rate constants for the inactivation of ATP sulfurylase by phenylglyoxal, diethylpyrocarbonate, or N-ethylmaleimide. Similarly, ATP sulfurylase (+/- ligands) had no effect on the inactivation of equimolar APS kinase by trinitrobenzene sulfonate, diethylpyrocarbonate, or heat. (The last promotes the dissociation of dimeric APS kinase to inactive monomers.) ATP sulfurylase also had no effect on the reassociation of APS kinase subunits at low temperature. The cumulative results suggest that the two sulfate activating enzymes do not associate to form a "3'-phosphoadenosine 5'-phosphosulfate synthetase" complex.     

APS kinase from Penicillium chrysogenum. Dissociation and reassociation of subunits as the basis of the reversible heat inactivation

Adenosine-5'-phosphosulfate (APS) kinase from Penicillium chrysogenum, loses catalytic activity at temperatures greater than approximately 40 degrees C. When the heat-inactivated enzyme is cooled to 30 degrees C or lower, activity is regained in a time-dependent process. At an intermediary temperature (e.g. 36 degrees C) an equilibrium between active and inactive forms can be demonstrated. APS kinase from P. chrysogenum is a dimer (Mr = 57,000-60,000) composed of two apparently identical subunits. Three lines of evidence suggest that the reversible inactivation is a result of subunit dissociation and reassociation. (a) Inactivation is a first-order process. The half-time for inactivation at a given temperature is independent of the original enzyme concentration. Reactivation follows second-order kinetics. The half-time for reactivation is inversely proportional to the original enzyme concentration. (b) The equilibrium active/inactive ratio at 36 degrees C increases as the total initial enzyme concentration is increased. However, Keq,app at 5 mM MgATP and 36 degrees C calculated as [inactive sites]2/0.5 [active sites] is near-constant at about 1.7 X 10(-8) M over a 10-fold concentration range of enzyme. (c) At 46 degrees C, the inactive P. chrysogenum enzyme (assayed after reactivation) elutes from a calibrated gel filtration column at a position corresponding to Mr = 33,000. Substrates and products of the APS kinase reaction had no detectable effect on the rate of inactivation. However, MgATP and MgADP markedly stimulated the reactivation process (kapp = 3 X 10(5) M-1 X s-1 at 30 degrees C and 10 mM MgATP). The kapp for reactivation was a nearly linear function of MgATP up to about 20 mM suggesting that the monomer has a very low affinity for the nucleotide compared to that of the native dimer. Keq,app at 36 degrees C increases as the MgATP concentration is increased. The inactivation rate constant increased as the pH was decreased but no pK alpha could be determined. The reactivation rate constant increased as the pH was increased. An apparent pK alpha of 6.4 was estimated.     

Characterization of the phosphorylated enzyme intermediate formed in the adenosine 5'-phosphosulfate kinase reaction.

Adenosine 5'-phosphosulfate (APS) kinase (ATP:APS 3'-phosphotransferase) catalyzes the ultimate step in the biosynthesis of 3'-phosphoadenosine 5'-phosphosulfate (PAPS), the primary biological sulfuryl donor. APS kinase from Escherichia coli is phosphorylated upon incubation with ATP, yielding a protein that can complete the overall reaction through phosphorylation of APS. Rapid-quench kinetic experiments show that, in the absence of APS, ATP phosphorylates the enzyme with a rate constant of 46 s-1, which is equivalent to the Vmax for the overall APS kinase reaction. Similar pre-steady-state kinetic measurements show that the rate constant for transfer of the phosphoryl group from E-P to APS is 91 s-1. Thus, the phosphorylated enzyme is kinetically competent to be on the reaction path. In order to elucidate which amino acid residue is phosphorylated, and thus to define the active site region of APS kinase, we have determined the complete sequence of cysC, the structural gene for this enzyme in E. coli. The coding region contains 603 nucleotides and encodes a protein of 22,321 Da. Near the amino terminus is the sequence 35GLSGSGKS, which exemplifies a motif known to interact with the beta-phosphoryl group of purine nucleotides. The residue that is phosphorylated upon incubation with ATP has been identified as serine-109 on the basis of the amino acid composition of a radiolabeled peptide purified from a proteolytic digest of 32P-labeled enzyme. We have identified a sequence beginning at residue 147 which may reflect a PAPS binding site. This sequence was identified in the carboxy terminal region of 10 reported sequences of proteins of PAPS metabolism.     

UDPglucose pyrophosphorylase from Xanthomonas spp. Characterization of the enzyme kinetics, structure and inactivation related to oligomeric dissociation

The genes encoding for UDPglucose pyrophosphorylase in two Xanthomonas spp. were cloned and overexpressed in Escherichia coli. After purification to electrophoretic homogeneity, the recombinant proteins were characterized, and both exhibited similar structural and kinetic properties. They were identified as dimeric proteins of molecular mass 60kDa, exhibiting relatively high specific activity ( approximately 80Units/mg) for UDPglucose synthesis. Both enzymes utilized UTP or TTP as substrate with similar affinity. The purified Xanthomonas enzyme was inactivated after dilution into the assay medium. Studies of crosslinking with the bifunctional lysyl reagent bisuberate suggest that inactivation occurs by enzyme dissociation to monomers. UTP effectively protects the enzyme against inactivation, from which a dissociation constant of 15microM was calculated for the interaction substrate-enzyme. The UTP binding to the enzyme would induce conformational changes in the protein, favoring the subunits interaction to form an active dimer. This view was reinforced by protein modeling of the Xanthomonas enzyme on the basis of the prokaryotic UDPglucose pyrophosphorylase crystallographic structure. The in silico approach pointed out two main critical regions in the enzyme involved in subunit-subunit interaction: the region surrounding the catalytic-substrate binding site and the C-term.     

Adenosine triphosphate sulfurylase from Penicillium chrysogenum equilibrium binding, substrate hydrolysis, and isotope exchange studies.

ATP sulfurylase from Penicillium chrysogenum was purified to homogeneity. The enzyme binds 8 mol of free ATP (K_s = 0.53 mM) or AMP (K_s = 0.50 mM) per 440,000 g. The results are consistent with our earlier report that the enzyme is composed of eight identical subunits of M_r 55,000 (J. W. Tweedie and I. H. Segel, 1971, Prep. Biochem. 1, 91–117; J. Biol. Chem. 246, 2438–2446). In the absence of cosubstrates, the purified enzyme catalyzes the hydrolysis of MgATP (to AMP and MgPP_i) and adenosine 5′-phosphosulfate (APS) (to AMP and SO₄^2?). MgATP hydrolysis is inhibited by nonreactive sulfate analogs such as nitrate, chlorate, and formate (uncompetitive with MgATP). In spite of the hydrolytic reactions it is possible to observe the binding of MgATP and APS to the enzyme in a qualitative (nonequilibrium) manner. Neither inorganic sulfate (the cosubstrate of the forward reaction) nor formate or inorganic phosphate (inhibitors competitive with sulfate) will bind to the free enzyme in detectable amounts in the absence or in the presence of Mg²⁺, Ca²⁺, free ATP, or a nonreactive analog of MgATP such as Mg-α,β-methylene-ATP. Similarly, inorganic pyrophosphate (the cosubstrate of the reverse reaction) will not bind in the absence or in the presence of Mg²⁺ or Ca²⁺. The induced binding of ³²P_i (presumably to the sulfate site) can be observed in the presence of MgATP. The results are consistent with the obligately ordered binding sequence deduced from the steady-state kinetics (J. Farley et al., 1976, J. Biol. Chem. 251, 4389–4397) and suggest that the subsites for SO^2?₄ or MgPP_i appear only after nucleotide cleavage to form E~AMP · MgPP_i or E~AMP · SO₄ complexes. The suggestion is supported by the relative values of K_ia (ca. 1 mm for MgATP) and K_iq (ca. 1 αm for APS) and by the inconsistent value of k_?1 calculated from $\text{V}{}_{\mathrm{<mtext>f</mtext>}}\text{K}{}_{\mathrm{<mtext>i</mtext><mtext>a</mtext>}}\text{K}{}_{\mathrm{<mtext>m</mtext><mtext>A</mtext>}}$ (The value is considerably less than V_r) Purified ATP sulfurylase will also catalyze a Mg³²PP_i-MgATP exchange in the absence of SO₄^2?. A ³⁵SO₄^2?-APS exchange could not be demonstrated in the absence or presence of MgPP_i. This result was not unexpected: The rate of APS hydrolysis (or conversion to MgATP) is extremely rapid compared to the expected exchange rate. Also, the pool of APS at equilibrium is extremely small compared to the sulfate pool. The V values for molybdolysis, APS hydrolysis (in the absence of PP_i), ATP synthesis (from APS + MgPP_i), and Mg³²PP_i-MgATP exchange at saturating sulfate are all about equal (12–19 μmol × min^?1 × mg of enzyme^?1). The rates of Mg³²PP_i-MgATP exchange in the absence of sulfate, APS synthesis (from MgATP + sulfate), and MgATP hydrolysis (in the absence of sulfate) are considerably slower (0.10 – 0.35 μmol × min^?1 × mg of enzyme^?1). These results and the fact that k₄ calculated from $\text{V}{}_{\mathrm{<mtext>r</mtext>}}\text{K}{}_{\mathrm{<mtext>i</mtext><mtext>q</mtext>}}\text{K}{}_{\mathrm{<mtext>m</mtext><mtext>Q</mtext>}}$ is considerably larger than V_f suggest that the rate-limiting step in the overall forward reaction is the isomerization reaction E~AMP-SO^2?₄ → EAPS. In the reverse direction the rate-limiting step may be SO^2?₄ release or isomerization of the E~AMP · MgPP_i · SO₄^2? complex. (The reaction appears to be rapid equilibrium ordered.) Reactions involving the synthesis or cleavage of APS are specific for Mg²⁺. Reactions involving the synthesis or cleavage of ATP will proceed with Mg²⁺, with Mn²⁺, and, at a lower rate, with Co²⁺. The results suggest that the enzyme possesses a Mg²⁺-preferring divalent cation (activator) binding site that is involved in APS synthesis and cleavage and is distinct from the MeATP or MePP_i site. The equilibrium binding of about one atom of ⁴⁵Ca²⁺ per subunit (possibly to the activator site) could be demonstrated (K_s = 1.4 mM).     

Dynamics of phosphodiesterase-induced cAMP dissociation from protein kinase A: Capturing transient ternary complexes by HDXMS

cAMP signaling is a fundamental cellular process necessary for mediating responses to hormonal stimuli. In contrast to cAMP-dependent activation of protein kinase A (PKA), an important cellular target, far less is known on termination in cAMP signaling, specifically how phosphodiesterases (PDEs) facilitate dissociation and hydrolysis of bound cAMP. In this study, we have probed the dynamics of a ternary complex of PKA and a PDE–RegA with an excess of a PDE-nonhydrolyzable cAMP analog, Sp-cAMPS by amide hydrogen/deuterium exchange mass spectrometry (HDXMS). Our results highlight how HDXMS can be used to monitor reactions together with mapping conformational dynamics of transient signaling complexes. Our results confirm a two-state model for active RegA-mediated dissociation of bound cAMP. Further, our results reveal that Sp-cAMPS and RegA mediate mutually exclusive interactions with the same region of PKA and at specific concentrations of Sp-cAMPS, RegA is capable of blocking Sp-cAMPS reassociation to PKA. This provides a molecular basis for how PDEs modulate levels of intracellular cAMP so that PKA is better suited to responding to fluxes rather than constant levels of cAMP. This study underscores how HDXMS can be a powerful tool for monitoring reactions together with mapping conformational dynamics in signaling proteins. This article is part of a Special Issue entitled: Mass spectrometry in structural biology.     

Adenosine-5'-phosphosulfate kinase from Escherichia coli K12. Purification, characterization, and identification of a phosphorylated enzyme intermediate

Adenosine-5'-phosphosulfate kinase (ATP:adenylylsulfate 3'-phosphotransferase), the second enzyme in the pathway of sulfate activation, has been purified (approximately 300-fold) to homogeneity from an Escherichia coli K12 strain, which overproduces the enzyme activity (approximately 100-fold). The purified enzyme has a specific activity of 153 mumol of 3'-phosphoadenosine 5'-phosphosulfate (PAPS) formed/min/mg of protein at 25 degrees C. The enzyme is remarkably efficient with a Vmax/Km(APS) of greater than 10(8) M-1 s-1, indicating that at physiologically low substrate concentrations the reaction is essentially diffusion limited. Upon incubation with MgATP a phosphorylated enzyme is formed; the isolated phosphorylated enzyme can transfer its phosphoryl group to adenosine 5'-phosphosulfate (APS) to form PAPS or to ADP to form ATP. The phosphorylated enzyme exists as a dimer of identical 21-kilodalton subunits, while the dephosphorylated form primarily exists as a tetramer. Divalent cations are required for activity with Mg(II), Mn(II), Co(II), and Cd(II) activating. Studies of the divalent metal-dependent stereoselectivity for the alpha- and beta-phosphorothioate derivatives of ATP indicate metal coordination to at least the alpha-phosphoryl group of the nucleotide. Steady state kinetic studies of the reverse reaction indicate a sequential mechanism, with a rapid equilibrium ordered binding of MgADP before PAPS. In the forward direction APS is a potent substrate inhibitor, competitive with ATP, complicating kinetic studies. The primary kinetic mechanism in the forward direction is sequential. Product inhibition studies at high concentrations of APS suggest an ordered kinetic mechanism with MgATP binding before APS. At submicromolar concentrations of APS, product inhibition by both MgADP and PAPS is more complex and is not consistent with a solely ordered sequential mechanism. The formation of a phosphorylated enzyme capable of transferring its phosphoryl group to APS or to MgADP suggests that a ping-pong pathway in which the rate of MgADP dissociation is comparable to the rate of APS binding might contribute at very low concentrations of APS. The substrate inhibition by APS is consistent with APS binding to the enzyme, to form a dead-end E.APS complex.     

Structural mechanism for substrate inhibition of the adenosine 5'-phosphosulfate kinase domain of human 3'-phosphoadenosine 5'-phosphosulfate synthetase 1 and its ramifications for enzyme regulation

In mammals, the universal sulfuryl group donor molecule 3'-phosphoadenosine 5'-phosphosulfate (PAPS) is synthesized in two steps by a bifunctional enzyme called PAPS synthetase. The APS kinase domain of PAPS synthetase catalyzes the second step in which APS, the product of the ATP-sulfurylase domain, is phosphorylated on its 3'-hydroxyl group to yield PAPS. The substrate APS acts as a strong uncompetitive inhibitor of the APS kinase reaction. We generated truncated and point mutants of the APS kinase domain that are active but devoid of substrate inhibition. Structural analysis of these mutant enzymes reveals the intrasubunit rearrangements that occur upon substrate binding. We also observe intersubunit rearrangements in this dimeric enzyme that result in asymmetry between the two monomers. Our work elucidates the structural elements required for the ability of the substrate APS to inhibit the reaction at micromolar concentrations. Because the ATP-sulfurylase domain of PAPS synthetase influences these elements in the APS kinase domain, we propose that this could be a communication mechanism between the two domains of the bifunctional enzyme.     

Isolation and characterization of the acetyl-CoA synthetase from Penicillium chrysogenum. Involvement of this enzyme in the biosynthesis of penicillins.

Acetyl-CoA synthetase (ACS) of Penicillium chrysogenum was purified to homogeneity (745-fold) from fungal cultures grown in a chemically defined medium containing acetate as the main carbon source. The enzyme showed maximal rate of catalysis when incubated in 50 mM HCl-Tris buffer, pH 8.0, at 37 degrees C. Under these conditions, ACS showed hyperbolic behavior against acetate, CoA, and ATP; the Km values calculated for these substrates were 6.8, 0.18, and 17 mM, respectively. ACS recognized as substrates not only acetate but also several fatty acids ranging between C2 and C8 and some aromatic molecules (phenylacetic, 2-thiopheneacetic, and 3-thiopheneacetic acids). ATP can be replaced by ADP although, in this case, a lower activity was observed (37%). ACS in inhibited by some thiol reagents (5,5'-dithiobis(nitrobenzoic acid), N-ethylmaleimide, p-chloromercuribenzoate) and divalent cations (Zn2+, Cu2+, and Hg2+), whereas it was stimulated when the reaction mixtures contained 1 mM dithiothreitol, reduced glutathione, or 2-mercaptoethanol. The calculated molecular mass of ACS was 139 +/- 1 kDa, and the native enzyme is composed of two apparent identical subunits (70 kDa) in an alpha 2 oligomeric structure. ACS activity was regulated "in vivo" by carbon catabolite inactivation when glucose was taken up by cells in which the enzyme had been previously induced. This enzyme can be coupled "in vitro" to acyl-CoA:6-aminopenicillanic acid acyltransferase from P. chrysogenum, thus allowing the reconstitution of the functional enzymatic system which catalyzes the two latter reactions responsible for the biosynthesis of different penicillins. The ACS from Aspergillus nidulans can also be coupled to 6-aminopenicillanic acid acyltransferase to synthesize penicillins. These results strongly indicate that this enzyme can catalyze the activation (to their CoA thioesters) of some of the side-chain precursors required in these two fungi for the production of several penicillins. All these data are reported here for the first time.