Proteasome accessory factor A (PafA) transferase activity makes sense in the light of its homology with glutamine synthetase

The Pup-proteasome system (PPS) is a prokaryotic tagging and degradation system analogous in function to the ubiquitin-proteasome system (UPS). Like ubiquitin, Pup is conjugated to proteins, tagging them for proteasomal degradation. However, in the PPS, a single Pup-ligase, PafA, conjugates Pup to a wide variety of proteins. PafA couples ATP hydrolysis to formation of an isopeptide bond between Pup and a protein lysine via a mechanism similar to that used by glutamine synthetase (GS) to generate glutamine from ammonia and glutamate. GS can also transfer the glutamyl moiety from glutamine to a hydroxyl amine in an ATP-independent manner. Recently, the ability of PafA to transfer Pup from one protein to another was demonstrated. Here, we report that such PafA activity mechanistically resembles the transferase activity of GS. Both PafA and GS transferase activities are ATP-independent and proceed in two catalytic steps. In the first step catalyzed by PafA, an inorganic phosphate is used by the enzyme to depupylate a Pup donor, while forming an acyl phosphate Pup intermediate. The second step consists of Pup conjugation to the new protein, alongside the release of an inorganic phosphate. Detailed experimental analysis, combined with kinetic modeling of PafA transferase activity, allowed us to correctly predict the kinetics and magnitude of Pup transfer between two targets, and analyze the effects of their affinity to PafA on the efficiency of transfer. By deciphering the mechanism of the PafA transferase reaction in kinetic detail, this work provides in-depth mechanistic understanding of PafA, a key PPS enzyme.     

Reconstitution of the Mycobacterium tuberculosis pupylation pathway in Escherichia coli

Prokaryotic ubiquitin-like protein (Pup) is a post-translational modifier that attaches to more than 50 proteins in Mycobacteria. Proteasome accessory factor A (PafA) is responsible for Pup conjugation to substrates, but the manner in which proteins are selected for pupylation is unknown. To address this issue, we reconstituted the pupylation of model Mycobacterium proteasome substrates in Escherichia coli, which does not encode Pup or PafA. Surprisingly, Pup and PafA were sufficient to pupylate at least 51 E. coli proteins in addition to the mycobacterial proteins. These data suggest that pupylation signals are intrinsic to targeted proteins and might not require Mycobacterium-specific cofactors for substrate recognition by PafA in vivo.     

The Mechanism of Mycobacterium smegmatis PafA Self-Pupylation

PafA, the prokaryotic ubiquitin-like protein (Pup) ligase, catalyzes the Pup modification of bacterial proteins and targets the substrates for proteasomal degradation. It has been reported that that M. smegmatis PafA can be poly-pupylated. In this study, the mechanism of PafA self-pupylation is explored. We found that K320 is the major target residue for the pupylation of PafA. During the self-pupylation of PafA, the attachment of the first Pup to PafA is catalyzed by the other PafA molecule through an intermolecular reaction, while the formation of the polymeric Pup chain is carried out in an intramolecular manner through the internal ligase activity of the already pupylated PafA. Among the three lysine residues, K7, K31 and K61, in M. smegmatis Pup, K7 and K31 are involved in the formation of the poly-Pup chain in PafA poly-pupylation. Poly-pupylation of PafA can be reversibly regulated by depupylase Dop. The polymeric Pup chain formed through K7/K31 linkage is much more sensitive to Dop than the mono-Pup directly attached to PafA. Moreover, self-pupylation of PafA is involved in the regulation of its stability in vivo in a proteasome-dependent manner, suggesting that PafA self-pupylation functions as a mechanism in the auto-regulation of the Pup-proteasome system.     

Activity of the mycobacterial proteasomal ATPase Mpa is reversibly regulated by pupylation

Pupylation is a bacterial post-translational modification of target proteins on lysine residues with prokaryotic ubiquitin-like protein Pup. Pup-tagged substrates are recognized by a proteasome-interacting ATPase termed Mpa in Mycobacterium tuberculosis. Mpa unfolds pupylated substrates and threads them into the proteasome core particle for degradation. Interestingly, Mpa itself is also a pupylation target. Here, we show that the Pup ligase PafA predominantly produces monopupylated Mpa modified homogeneously on a single lysine residue within its C-terminal region. We demonstrate that this modification renders Mpa functionally inactive. Pupylated Mpa can no longer support Pup-mediated proteasomal degradation due to its inability to associate with the proteasome core. Mpa is further inactivated by rapid Pup- and ATPase-driven deoligomerization of the hexameric Mpa ring. We show that pupylation of Mpa is chemically and functionally reversible. Mpa regains its enzymatic activity upon depupylation by the depupylase Dop, affording a rapid and reversible activity control over Mpa function.     

Unraveling the biochemistry and provenance of pupylation: a prokaryotic analog of ubiquitination

   

Recently Mycobacterium tuberculosis was shown to possess a novel protein modification, in which a small protein Pup is conjugated to the epsilon-amino groups of lysines in target proteins. Analogous to ubiquitin modification in eukaryotes, this remarkable modification recruits proteins for degradation via archaeal-type proteasomes found in mycobacteria and allied actinobacteria. While a mycobacterial protein named PafA was found to be required for this conjugation reaction, its biochemical mechanism has not been elucidated. Using sensitive sequence profile comparison methods we establish that the PafA family proteins are related to the γ-glutamyl-cysteine synthetase and glutamine synthetase. Hence, we predict that PafA is the Pup ligase, which catalyzes the ATP-dependent ligation of the terminal γ-carboxylate of glutamate to lysines, similar to the above enzymes. We further discovered that an ortholog of the eukaryotic PAC2 (e.g. cg2106) is often present in the vicinity of the actinobacterial Pup-proteasome gene neighborhoods and is likely to represent the ancestral proteasomal chaperone. Pup-conjugation is sporadically present outside the actinobacteria in certain lineages, such as verrucomicrobia, nitrospirae, deltaproteobacteria and planctomycetes, and in the latter two lineages it might modify membrane proteins.     

Prokaryotic ubiquitin-like protein remains intrinsically disordered when covalently attached to proteasomal target proteins

Background

The post-translational modification pathway referred to as pupylation marks proteins for proteasomal degradation in Mycobacterium tuberculosis and other actinobacteria by covalently attaching the small protein Pup (prokaryotic ubiquitin-like protein) to target lysine residues. In contrast to the functionally analogous eukaryotic ubiquitin, Pup is intrinsically disordered in its free form. Its unfolded state allows Pup to adopt different structures upon interaction with different binding partners like the Pup ligase PafA and the proteasomal ATPase Mpa. While the disordered behavior of free Pup has been well characterized, it remained unknown whether Pup adopts a distinct structure when attached to a substrate.

Results

Using a combination of NMR experiments and biochemical analysis we demonstrate that Pup remains unstructured when ligated to two well-established pupylation substrates targeted for proteasomal degradation in Mycobacterium tuberculosis, malonyl transacylase (FabD) and ketopantoyl hydroxylmethyltransferase (PanB). Isotopically labeled Pup was linked to FabD and PanB by in vitro pupylation to generate homogeneously pupylated substrates suitable for NMR analysis. The single target lysine of PanB was identified by a combination of mass spectroscopy and mutational analysis. Chemical shift comparison between Pup in its free form and ligated to substrate reveals intrinsic disorder of Pup in the conjugate.

Conclusion

When linked to the proteasomal substrates FabD and PanB, Pup is unstructured and retains the ability to interact with its different binding partners. This suggests that it is not the conformation of Pup attached to these two substrates which determines their delivery to the proteasome, but the availability of the degradation complex and the depupylase.

     

Dop functions as a depupylase in the prokaryotic ubiquitin‐like modification pathway

Post‐translational modification of proteins with prokaryotic ubiquitin‐like protein (Pup) is the bacterial equivalent of ubiquitination in eukaryotes. Mycobacterial pupylation is a two‐step process in which the carboxy‐terminal glutamine of Pup is first deamidated by Dop (deamidase of Pup) before ligation of the generated γ‐carboxylate to substrate lysines by the Pup ligase PafA. In this study, we identify a new feature of the pupylation system by demonstrating that Dop also acts as a depupylase in the Pup proteasome system in vivo and in vitro. Dop removes Pup from substrates by specific cleavage of the isopeptide bond. Depupylation can be enhanced by the unfolding activity of the mycobacterial proteasomal ATPase Mpa.     

Kinetic studies of adenosine kinase from L1210 cells: a model enzyme with a two-site ping-pong mechanism

Purified adenosine kinase from L1210 cells displayed substrate inhibition by high concentrations of adenosine (Ado), ATP, and MgCl2. When incubated with ATP and MgCl2, the enzyme was phosphorylated, and the phosphorylated kinase transferred phosphate to adenosine in the absence of ATP and MgCl2. Substrate binding, isotope exchange, and kinetic studies suggested that the enzyme catalyzes the reaction by means of a two-site ping-pong mechanism with the phosphorylated enzyme as an obligatory intermediate. Among many possible pathways within this mechanism probably a random-bi ordered-bi route is the preferred sequence in which the two substrates, adenosine and MgATP, bind in a random order to form the ternary complex MgATP . E . Ado followed by the sequential dissociation of MgADP and AMP. Dissociation constants of various enzyme-substrate and enzyme-product complexes and the first-order rate constant of the rate-limiting step were estimated.     

Molecular analysis of the prokaryotic ubiquitin‐like protein (Pup) conjugation pathway in Mycobacterium tuberculosis

Proteins targeted for degradation by the Mycobacterium proteasome are post‐translationally tagged with prokaryotic ubiquitin‐like protein (Pup), an intrinsically disordered protein of 64 residues. In a process termed ‘pupylation’, Pup is synthesized with a terminal glutamine, which is deamidated to glutamate by Dop (deamidase of Pup) prior to attachment to substrate lysines by proteasome accessory factor A (PafA). Importantly, PafA was previously shown to be essential to cause lethal infections by Mycobacterium tuberculosis (Mtb) in mice. In this study we show that Dop, like PafA, is required for the full virulence of Mtb. Additionally, we show that Dop is not only involved in the deamidation of Pup, but also needed to maintain wild‐type steady state levels of pupylated proteins in Mtb. Finally, using structural models and site‐directed mutagenesis our data suggest that Dop and PafA are members of the glutamine synthetase fold family of proteins.     

Active site of lysyl-tRNA synthetase: structural studies of the adenylation reaction

Aminoacyl-tRNA synthetases play a key role in protein biosynthesis by catalyzing the specific aminoacylation of tRNA. The energy required for the formation of the ester bond between the amino acid carboxylate group and the tRNA acceptor stem is supplied by coupling the reaction to the hydrolysis of ATP. Lysyl-tRNA synthetase from Escherichia coli belongs to the family of class II synthetases and carries out a two-step reaction, in which lysine is activated by being attached to the alpha-phosphate of AMP before being transferred to the cognate tRNA. Crystals of the thermo-inducible E. coli lysyl-tRNA synthetase LysU which diffract to 2.1 A resolution have been used to determine crystal structures of the enzyme in the presence of lysine, the lysyl-adenylate intermediate, and the nonhydrolyzable ATP analogue AMP-PCP. Additional data have been obtained from crystals soaked in a solution containing ATP and Mn(2+). The refined crystal structures give "snapshots" of the active site corresponding to key steps in the aminoacylation reaction and provide the structural framework for understanding the mechanism of lysine activation. The active site of LysU is shaped to position the substrates for the nucleophilic attack of the lysine carboxylate on the ATP alpha-phosphate. No residues are directly involved in catalysis, but a number of highly conserved amino acids and three metal ions coordinate the substrates and stabilize the pentavalent transition state. A loop close to the catalytic pocket, disordered in the lysine-bound structure, becomes ordered upon adenine binding.     

Mechanism of substrate dephosphorylation in low Mr protein tyrosine phosphatase.

Substrate dephosphorylation by the low molecular weight protein tyrosine phosphatases proceeds via nucleophilic substitution at the phosphorous atom yielding a cysteinyl phosphate intermediate. However, several questions regarding the exact reaction mechanism remain unanswered. Starting from the crystal structure of the enzyme we study the energetics of this reaction, using the empirical valence bond method in combination with molecular dynamics and free energy perturbation simulations. The free energy profiles of two mechanisms corresponding to different protonation states of the reacting groups are examined along stepwise and concerted pathways. The activation barriers calculated relative to the enzyme-substrate complex are very similar for both monoanionic and dianionic substrates, but taking the substrate binding step into account shows that hydrolysis of monoanionic substrates is strongly favored by the enzyme, because a dianionic substrate will not bind when the reacting cysteine is ionized. The calculated activation barrier for dephosphorylation of monoanionic phenyl phosphate according to this novel mechanism is 14 kcal mol(-1), which is in good agreement with experimental data. Proteins 1999;36:370-379.     

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.     

Substrate inhibition in a human variant of hypoxanthine-guanine phosphoribosyltransferase

Hypoxanthine-guanine phosphoribosyltransferase from a young man with purine overproduction and decreased purine salvage in fibroblast cultures was found to have low activity at concentrations of purine substrates at which the enzyme from normal individuals showed near maximal activity. The low enzyme activity was not associated with changes in the values of the Km(app) and Vmax(app) for any of the enzyme substrates. However, the enzyme activity was susceptible to substrate inhibition by hypoxanthine and guanine. The values obtained for the true Km, true Vmax, and true Ki for hypoxanthine were 26 +/- 10 microM, 1761 +/- 382 microunits/mg of protein, and 80 +/- 20 microM, respectively. The pattern of the substrate inhibition, as seen on a plot of 1/v versus hypoxanthine concentration, was characteristic of that associated with the formation of a dead-end complex between the inhibitory substrate and an enzyme form with which it normally does not react. The nature of this enzyme form and that of the dead-end complex was determined from double inhibition experiments, which indicated that hypoxanthine interacted with an enzyme-PPi intermediate to form an enzyme-hypoxanthine-PPi dead-end complex. The trapping of the enzyme in this inactive form explains the low activity at high purine base concentrations. Further information as to the nature of the reaction mechanism was obtained from plots of the reciprocal of enzyme activity versus the reciprocal of PP-ribose-P concentration at different fixed hypoxanthine concentrations. A pattern characteristic of uncompetitive substrate inhibition was obtained. This is indicative of an ordered sequential binding of substrates on the enzyme; PP-ribose-P binding before hypoxanthine. Thus, the variant enzyme showed an ordered sequential reaction mechanism, with the inhibitory substrate forming a dead-end complex with an enzyme-PPi intermediate.     

Studies on a possible phosphoryl-enzyme intermediate in the catalytic reaction of yeast phosphoglycerate kinase

A phosphoryl-enzyme intermediate as part of the mechanism of phosphoglycerate kinase has been suggested for the rabbit muscle enzyme (6) and the yeast enzyme (7,8). ATP in the binary enzyme-substrate complexes appeared to phosphorylate these enzymes and ADP-ATP exchange activities were observed (6,7,8). The present report shows, however, that highly purified yeast enzyme cannot be phosphorylated by ATP. On the other hand ADP-ATP exchange activity was obtained but this was proportional to trace amounts of adenylate kinase activity, which was found to contaminate the enzyme preparations. Thus a Ping Pong mechanism as an alternative to a mechanism including a ternary complex between the enzyme and its two substrates appears very improbable. Whether the enzyme or the phosphoryl-group-accepting substrate is responsible for the primary nucleophilic attack occurring in the ternary complex is still an open question, however. Yeast phosphoglycerate kinase appears to have no ATPase activity.     

Mechanistic studies of Escherichia coli adenosine-5'-phosphosulfate kinase

Adenosine-5'-phosphosulfate kinase (APS kinase) catalyzes the formation of 3'-phosphoadenosine 5'-phosphosulfate (PAPS), the major form of activated sulfate in biological systems. The enzyme from Escherichia coli has complex kinetic behavior, including substrate inhibition by APS and formation of a phosphorylated enzyme (E-P) as a reaction intermediate. The presence of a phosphorylated enzyme potentially enables the steady-state kinetic mechanism to change from sequential to ping-pong as the APS concentration decreases. Kinetic and equilibrium binding measurements have been used to evaluate the proposed mechanism. Equilibrium binding studies show that APS, PAPS, ADP, and the ATP analog AMPPNP each bind at a single site per subunit; thus, substrates can bind in either order. When ATPgammaS replaces ATP as substrate the V(max) is reduced 535-fold, the kinetic mechanism is sequential at each APS concentration, and substrate inhibition is not observed. The results indicate that substrate inhibition arises from a kinetic phenomenon in which product formation from ATP binding to the E. APS complex is much slower than paths in which product formation results from APS binding either to the E. ATP complex or to E-P. APS kinase requires divalent cations such as Mg(2+) or Mn(2+) for activity. APS kinase binds one Mn(2+) ion per subunit in the absence of substrates, consistent with the requirement for a divalent cation in the phosphorylation of APS by E-P. The affinity for Mn(2+) increases 23-fold when the enzyme is phosphorylated. Two Mn(2+) ions bind per subunit when both APS and the ATP analog AMPPNP are present, indicating a potential dual metal ion catalytic mechanism.     

Kinetic analysis of the mechanism for subtilisin in essentially anhydrous organic solvents

Steady-state kinetic analysis has been used to confirm the catalytic mechanism of lyophilized subtilisin suspended in a variety of organic solvents. Specifically, this article demonstrates that partial reactions can occur between subtilisin and ester substrates in organic solvents. Partitioning of common intermediates between competing acceptors at a constant ratio of products has also been described. The decomposition of a common intermediate formed from different substrates at the same rate is also further evidence of an acyl-enzyme mechanism for subtilisin suspended in anhydrous solvents. Partitioning of a common intermediate to give two products at a constant total rate, and saturation kinetics at varying substrate concentrations, complete a kinetic investigation of the enzyme mechanism. All the data generated support the formation of a stable acyl enzyme during the transesterification reaction catalzyed by subtilisin in the solvents used.     

Mechanism of the addition half of the O-acetylserine sulfhydrylase-A reaction

O-Acetylserine sulfhydrylase (OASS) catalyzes the last step in the cysteine biosynthetic pathway in enteric bacteria and plants, substitution of the beta-acetoxy group of O-acetyl-l-serine (OAS) with inorganic bisulfide. The first half of the sulfhydrylase reaction, formation of the alpha-aminoacrylate intermediate, limits the overall reaction rate, while in the second half-reaction, with bisulfide as the substrate, chemistry is thought to be diffusion-limited. In order to characterize the second half-reaction, the pH dependence of the pseudo-first-order rate constant for disappearance of the alpha-aminoacrylate intermediate was measured over the pH range 6.0-9.5 using the natural substrate bisulfide, and a number of nucleophilic analogues. The rate is pH-dependent for substrates with a pK(a) > 7, while the rate constant is pH-independent for substrates with a pK(a) < 7 suggesting that the pK(a)s of the substrate and an enzyme group are important in this half of the reaction. In D(2)O, at low pD values, the amino acid external Schiff base is trapped, while in H(2)O the reaction proceeds through release of the amino acid product, which is likely rate-limiting for all nucleophilic reactants. A number of new beta-substituted amino acids were produced and characterized by (1)H NMR spectroscopy.     

Kinetic competence of enzymic intermediates: fact or fiction?

A number of enzymatic reactions involve intermediates that are not normally released during the reaction. Whether such an intermediate when added to the enzyme reacts as fast or faster than the normal substrates, and thus is "kinetically competent", depends on the degree to which the equilibrium constant for forming the intermediate from the substrates is different on the enzyme surface and in solution, as well as on the relative affinities of the enzyme for substrate and intermediate. Similar values for these equilibrium constants require that the intermediate react slowly, while a far more favorable value for intermediate formation on the enzyme allows the intermediate to react at up to the diffusion-limiting rate. When one intermediate is formed from two substrates, it may react much more rapidly than when two intermediates are formed from two substrates, or one from one. Comparison of the kinetics of the putative intermediate(s) and the substrate(s) can reveal a great deal about the mechanism of the catalytic reaction and the kinetic barrier that normally keeps the intermediate(s) on the enzyme.     

Dihydrofolate reductase from Escherichia coli: the kinetic mechanism with NADPH and reduced acetylpyridine adenine dinucleotide phosphate as substrates

Kinetic studies on the reaction catalyzed by dihydrofolate reductase from Escherichia coli have been undertaken with the aim of characterizing further the kinetic mechanism of the reaction. For this purpose, the kinetic properties of substrates were determined by measurement of (a) initial velocities over a wide range of substrate concentrations and (b) the stickiness of substrates in ternary enzyme complexes. Stickiness is defined as the rate at which a substrate reacts to give products relative to the rate at which that substrate dissociates. Stickiness was determined by varying the viscosity of reaction mixtures and the concentration of one substrate in the presence of a saturating concentration of the other substrate. The results indicate that NADPH is sticky in the enzyme-NADPH-dihydrofolate complex, while dihydrofolate is much less sticky in this complex. At higher concentrations, NADPH functions as an activator through the formation of an enzyme-NADPH-tetrahydrofolate from which tetrahydrofolate is released more rapidly than from an enzyme-tetrahydrofolate complex. Higher concentrations of dihydrofolate also cause enzyme activation, and it appears that this effect is due to the ability of dihydrofolate to displace tetrahydrofolate from a binary enzyme complex through the formation of a transitory enzyme-tetrahydrofolate-dihydrofolate complex. As NADPH and dihydrofolate function as activators and as NADPH behaves as a sticky substrate, the kinetic mechanism of the dihydrofolate reductase reaction with the natural substrates is steady-state random. By contrast with NADPH, reduced 3-acetylpyridine adenine dinucleotide phosphate exhibits only slight stickiness and does not function as an activator.(ABSTRACT TRUNCATED AT 250 WORDS)