Characterization of the PLP-dependent transaminase initiating azasugar biosynthesis

2018 ◽  
Vol 475 (13) ◽  
pp. 2241-2256
Author(s):  
Jeffrey M. Arciola ◽  
Nicole A. Horenstein
Keyword(s):  
Steady State ◽  
Specific Activity ◽  
Paenibacillus Polymyxa ◽  
Binding Pocket ◽  
Kinetic Mechanism ◽  
Steady State Kinetics ◽  
Ping Pong ◽  
Amino Donor ◽  
Event Based

Biosynthesis of the azasugar 1-deoxynojirimycin (DNJ) critically involves a transamination in the first committed step. Here, we identify the azasugar biosynthetic cluster signature in Paenibacillus polymyxa SC2 (Ppo), homologous to that reported in Bacillus amyloliquefaciens FZB42 (Bam), and report the characterization of the aminotransferase GabT1 (named from Bam). GabT1 from Ppo exhibits a specific activity of 4.9 nmol/min/mg at 30°C (pH 7.5), a somewhat promiscuous amino donor selectivity, and curvilinear steady-state kinetics that do not reflect the predicted ping-pong behavior typical of aminotransferases. Analysis of the first half reaction with l-glutamate in the absence of the acceptor fructose 6-phosphate revealed that it was capable of catalyzing multiple turnovers of glutamate. Kinetic modeling of steady-state initial velocity data was consistent with a novel hybrid branching kinetic mechanism which included dissociation of PMP after the first half reaction to generate the apoenzyme which could bind PLP for another catalytic deamination event. Based on comparative sequence analyses, we identified an uncommon His-Val dyad in the PLP-binding pocket which we hypothesized was responsible for the unusual kinetics. Restoration of the conserved PLP-binding site motif via the mutant H119F restored classic ping-pong kinetic behavior.

Steady-State Kinetics and Spectroscopic Characterization of Enzyme–tRNA Interactions for the Non-Heme Diiron tRNA-Monooxygenase, MiaE

Biochemistry ◽  
2014 ◽  
Vol 54 (2) ◽  
pp. 363-376 ◽  
Author(s):  
Bishnu P. Subedi ◽  
Andra L. Corder ◽  
Siai Zhang ◽  
Frank W. Foss ◽  
Brad S. Pierce
Keyword(s):  
Steady State ◽  
Spectroscopic Characterization ◽  
Steady State Kinetics

Characterization of recombinant human acetyl-CoA carboxylase-2 steady-state kinetics

2009 ◽  
Vol 1794 (6) ◽  
pp. 961-967 ◽  
Author(s):  
Virendar K. Kaushik ◽  
Michael Kavana ◽  
Jessica M. Volz ◽  
Stephen C. Weldon ◽  
Susan Hanrahan ◽  
...  
Keyword(s):  
Steady State ◽  
Acetyl Coa Carboxylase ◽  
Acetyl Coa ◽  
Steady State Kinetics

scholarly journals Steady-state kinetics of malonyl-CoA synthetase from Bradyrhizobium japonicum and evidence for malonyl-AMP formation in the reaction

1994 ◽  
Vol 297 (2) ◽  
pp. 327-333 ◽  
Author(s):  
Y S Kim ◽  
S W Kang
Keyword(s):  
Steady State ◽  
Bradyrhizobium Japonicum ◽  
Initial Velocity ◽  
Catalytic Mechanism ◽  
Kinetic Mechanism ◽  
Product Inhibition ◽  
Steady State Kinetics ◽  
Malonyl Coa ◽  
Michaelis Constants ◽  
Inhibition Studies

Malonyl-CoA synthetase catalyses the formation of malonyl-CoA directly from malonate and CoA with hydrolysis of ATP into AMP and PP1. The catalytic mechanism of malonyl-CoA synthetase from Bradyrhizobium japonicum was investigated by steady-state kinetics. Initial-velocity studies and the product-inhibition studies with AMP and PPi strongly suggested ordered Bi Uni Uni Bi Ping Pong Ter Ter system as the most probable steady-state kinetic mechanism of malonyl-CoA synthetase. Michaelis constants were 61 microM, 260 microM and 42 microM for ATP, malonate and CoA respectively, and the value for Vmax, was 11.2 microM/min. The t.l.c. analysis of the 32P-labelled products in a reaction mixture containing [gamma-32P]ATP in the absence of CoA showed that PPi was produced after the sequential addition of ATP and malonate. Formation of malonyl-AMP, suggested as an intermediate in the kinetically deduced mechanism, was confirmed by the analysis of 31P-n.m.r. spectra of an AMP product isolated from the 18O-transfer experiment using [18O]malonate. The 31P-n.m.r. signal of the AMP product appeared at 0.024 p.p.m. apart from that of [16O4]AMP, indicating that one atom of 18O transferred from [18O]malonate to AMP through the formation of malonyl-AMP. Formation of malonyl-AMP was also confirmed through the t.l.c. analysis of reaction mixture containing [alpha-32P]ATP. These results strongly support the ordered Bi Uni Uni Bi Pin Pong Ter Ter mechanism deduced from initial-velocity and product-inhibition studies.

scholarly journals Reactivity of Toluate Dioxygenase with Substituted Benzoates and Dioxygen

2002 ◽  
Vol 184 (15) ◽  
pp. 4096-4103 ◽  
Author(s):  
Yong Ge ◽  
Frédéric H. Vaillancourt ◽  
Nathalie Y. R. Agar ◽  
Lindsay D. Eltis
Keyword(s):  
Steady State ◽  
Pseudomonas Putida ◽  
Sodium Phosphate ◽  
Ternary Complex ◽  
Specific Activity ◽  
Complex Mechanism ◽  
Aromatic Substrate ◽  
Steady State Kinetics ◽  
Full Complement

ABSTRACT Toluate dioxygenase (TADO) of Pseudomonas putida mt-2 catalyzes the dihydroxylation of a broad range of substituted benzoates. The two components of this enzyme were hyperexpressed and anaerobically purified. Reconstituted TADO had a specific activity of 3.8 U/mg with m-toluate, and each component had a full complement of their respective Fe2S2 centers. Steady-state kinetics data obtained by using an oxygraph assay and by varying the toluate and dioxygen concentrations were analyzed by a compulsory order ternary complex mechanism. TADO had greatest specificity for m-toluate, displaying apparent parameters of KmA = 9 ± 1 μM, k cat = 3.9 ± 0.2 s−1, and K m O2 = 16 ± 2 μM (100 mM sodium phosphate, pH 7.0; 25°C), where K m O2 represents the K m for O2 and KmA represents the K m for the aromatic substrate. The enzyme utilized benzoates in the following order of specificity: m-toluate > benzoate ≃ 3-chlorobenzoate > p-toluate ≃ 4-chlorobenzoate ≫ o-toluate ≃ 2-chlorobenzoate. The transformation of each of the first five compounds was well coupled to O2 utilization and yielded the corresponding 1,2-cis-dihydrodiol. In contrast, the transformation of ortho-substituted benzoates was poorly coupled to O2 utilization, with >10 times more O2 being consumed than benzoate. However, the apparent K m of TADO for these benzoates was >100 μM, indicating that they do not effectively inhibit the turnover of good substrates.

Nitrogen and Sulfur Transferases

2007 ◽  
Author(s):  
Perry A. Frey ◽  
Adrian D. Hegeman
Keyword(s):  
Steady State ◽  
Reaction Mechanism ◽  
Active Site ◽  
Reaction Mechanisms ◽  
Radical Reaction ◽  
Amino Group ◽  
Steady State Kinetics ◽  
Ping Pong ◽  
Polar Reaction

Unlike other group transfer reactions in biochemistry, the actions of nitrogen transferring enzymes do not follow a single unifying chemical principle. Nitrogen-transferring enzymes catalyze aminotransfer, amidotransfer, and amidinotransfer. An aminotransferase catalyzes the transfer of the NH2 group from a primary amine to a ketone or aldehyde. An amidotransferase catalyzes the transfer of the anide-NH2 group from glutamine to another group. These reactions proceed by polar reaction mechanisms. Aminomutases catalyze 1,2-intramolecular aminotransfer, in which an amino group is inserted into an adjacent C—H bond. The action of lysine 2,3-aminomutase, described in chapter 7, is an example of an aminomutase that functions by a radical reaction mechanism. Tyrosine 2,3-aminomutase also catalyzes the 2,3-amino migration, but it does so by a polar reaction mechanism. In this chapter, we consider NH2-transferring enzymes that function by polar reaction mechanisms. Transaminases or aminotransferases are the most extensively studied pyridoxal-5'-phosphate (PLP)–dependent enzymes, and many aminotransferases catalyze essential steps in catabolic and anabolic metabolism. In the classic transaminase reaction, aspartate aminotransferase (AAT) catalyzes the fully reversible reaction of L-aspartate with α-ketoglutarate according to fig. 13-1 to form oxaloacetate and L-glutamate. Like all aminotransferases, AAT is PLP dependent, and PLP functions in its classic role of providing a reactive carbonyl group to function in facilitating the cleavage of the α-H of aspartate and the departure of the α-amino group of aspartate for transfer to α-ketoglutarate (Snell, 1962). PLP in the holoenzyme functions in essence to stabilize the α-carbanions of L-aspartate or L-glutamate, the major biological role of PLP discussed in chapter 3. The functional groups of the enzyme catalyze steps in the mechanism, such as the 1,3-prototropic shift of the α-proton to C4' of pyridoxamine 5'-phosphate (PMP). The steady-state kinetics corresponds to the ping pong bi bi mechanism shown at the bottom of fig. 13-1. This mechanism allows L-aspartate to react with the internal aldimine, E=PLP in fig. 13-1, to produce an equivalent of oxaloacetate, with conversion of PLP to PMP at the active site (E.PMP), the free, covalently modified enzyme in the ping pong mechanism.

scholarly journals Steady-State Kinetic Analysis of Phosphotransacetylase from Methanosarcina thermophila

2006 ◽  
Vol 188 (3) ◽  
pp. 1155-1158 ◽  
Author(s):  
Sarah H. Lawrence ◽  
James G. Ferry
Keyword(s):  
Steady State ◽  
Kinetic Analysis ◽  
Random Order ◽  
Kinetic Mechanism ◽  
Methanosarcina Thermophila ◽  
Steady State Kinetic ◽  
Ping Pong ◽  
Acetyl Group ◽  
State Kinetic ◽  
Reversible Transfer

ABSTRACT Phosphotransacetylase (EC 2.3.1.8) catalyzes the reversible transfer of the acetyl group from acetyl phosphate to coenzyme A (CoA), forming acetyl-CoA and inorganic phosphate. A steady-state kinetic analysis of the phosphotransacetylase from Methanosarcina thermophila indicated that there is a ternary complex kinetic mechanism rather than a ping-pong kinetic mechanism. Additionally, inhibition patterns of products and a nonreactive substrate analog suggested that the substrates bind to the enzyme in a random order. Dynamic light scattering revealed that the enzyme is dimeric in solution.

scholarly journals Catalysis of potato epoxide hydrolase, StEH1

2005 ◽  
Vol 390 (2) ◽  
pp. 633-640 ◽  
Author(s):  
Lisa T. Elfström ◽  
Mikael Widersten
Keyword(s):  
Steady State ◽  
Epoxide Hydrolase ◽  
Ph Dependence ◽  
Functional Characterization ◽  
Kinetic Mechanism ◽  
Kinetic Measurements ◽  
Steady State Kinetics ◽  
Substrate Conversion ◽  
Km Value ◽  
The Individual

The kinetic mechanism of epoxide hydrolase (EC 3.3.2.3) from potato, StEH1 (Solanum tuberosum epoxide hydrolase 1), was studied by presteady-state and steady-state kinetics as well as by pH dependence of activity. The specific activities towards the different enantiomers of TSO (trans-stilbene oxide) as substrate were 43 and 3 μmol·min−1·mg−1 with the R,R- or S,S-isomers respectively. The enzyme was, however, enantioselective in favour of the S,S enantiomer due to a lower Km value. The pH dependences of kcat with R,R or S,S-TSO were also distinct and supposedly reflecting the pH dependences of the individual kinetic rates during substrate conversion. The rate-limiting step for TSO and cis- and trans-epoxystearate was shown by rapid kinetic measurements to be the hydrolysis of the alkylenzyme intermediate. Functional characterization of point mutants verified residues Asp105, Tyr154, Tyr235 and His300 as crucial for catalytic activity. All mutants displayed drastically decreased enzymatic activities during steady state. Presteady-state measurements revealed the base-deficient H300N (His300→Asn) mutant to possess greatly reduced efficiencies in catalysis of both chemical steps (alkylation and hydrolysis).

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