Phosphonate and α-fluorophosphonate analogs of d-glucose 6-phosphate as active-site probes of 1l-myo-inositol 1-phosphate synthase.

Phosphate ester analogs in which the bridging oxygen is replaced with a methylene or fluoromethylene group are well known non-hydrolyzable mimics of use as inhibitors and substrate analogs for reactions involving phosphate esters. Properties of the replaced oxygen are often best mimicked by a mono-fluoromethylene group, but such groups are challenging to synthesize and can exist as two stereoisomers. Here, we describe the protocol for our method of synthesizing the α-fluoromethylene analogs of d-glucose 6-phosphate (G6P), as well as the methylene and difluoromethylene analogs, and their application in the study of 1l-myo-inositol-1-phosphate synthase (mIPS). mIPS catalyzes the synthesis of 1l-myo-inositol 1-phosphate (mI1P) from G6P, in an NAD-dependent aldol cyclization. Its key role in myo-inositol metabolism makes it a putative target for the treatment of several health disorders. The design of these inhibitors allowed for the possibility of substrate-like behavior, reversible inhibition, or mechanism-based inactivation. In this chapter, the synthesis of these compounds, expression and purification of recombinant hexahistidine-tagged mIPS, the mIPS kinetic assay and methods for determining the behavior of the phosphate analogs in the presence of mIPS, and a docking approach to rationalizing the observed behavior are described.

Substrate Substitution in Kanosamine Biosynthesis Using Phosphonates and Phosphite Rescue.

Kanosamine is an antibiotic and antifungal compound synthesized from glucose 6-phosphate (G6P) in Bacillus subtilis by the action of three enzymes: NtdC, which catalyzes NAD-dependent oxidation of the C3-hydroxyl; NtdA, a PLP-dependent aminotransferase; and NtdB, a phosphatase. We previously demonstrated that NtdC can also oxidize substrates such as glucose and xylose, though at much lower rates, suggesting that the phosphoryloxymethylene moiety of the substrate is critical for effective catalysis. To probe this, we synthesized two phosphonate analogues of G6P in which the bridging oxygen is replaced by methylene and difluoromethylene groups. These analogues are substrates for NtdC, with second-order rate constants an order of magnitude lower than those for G6P. NtdA converts the resulting 3-keto products to the corresponding kanosamine 6-phosphonate analogues. We compared the rates to the rate of NtdC oxidation of glucose and xylose and showed that the low reactivity of xylose could be rescued 4-fold by the presence of phosphite, mimicking G6P in two pieces. These results allow the evaluation of the individual energetic contributions to catalysis of the bridging oxygen, the bridging C6 methylene, the phosphodianion, and the entropic gain of one substrate versus two substrate pieces. Phosphite also rescued the reversible formation 3-amino-3-deoxy-d-xylose by NtdA, demonstrating that truncated and nonhydrolyzable analogues of kanosamine 6-phosphate can be generated enzymatically.

Carbocyclic Substrate Analogues Reveal Kanosamine Biosynthesis Begins with the α-Anomer of Glucose 6-Phosphate.

NtdC is an NAD-dependent dehydrogenase that catalyzes the conversion of glucose 6-phosphate (G6P) to 3-oxo-glucose 6-phosphate (3oG6P), the first step in kanosamine biosynthesis in Bacillus subtilis and other closely-related bacteria. The NtdC-catalyzed reaction is unusual because 3oG6P undergoes rapid ring opening, resulting in a 1,3-dicarbonyl compound that is inherently unstable due to enolate formation. We have reported the steady-state kinetic behavior of NtdC, but many questions remain about the nature of this reaction, including whether it is the α-anomer, ß-anomer, or open-chain form that is the substrate for the enzyme. Here, we report the synthesis of carbocyclic G6P analogues by two routes, one based upon the Ferrier II rearrangement to generate the carbocycle and one based upon a Claisen rearrangement. We were able to synthesize both pseudo-anomers of carbaglucose 6-phosphate (C6P) using the Ferrier approach, and activity assays revealed that the pseudo-α-anomer is a good substrate for NtdC, while the pseudo-ß-anomer and the open-chain analogue, sorbitol 6-phosphate (S6P), are not substrates. A more efficient synthesis of α-C6P was achieved using the Claisen rearrangement approach, which allowed for a thorough evaluation of the NtdC-catalyzed oxidation of α-C6P. The requirement for the α-anomer indicates that NtdC and NtdA, the subsequent enzyme in the pathway, have co-evolved to recognize the α-anomer in order to avoid mutarotation between enzymatic steps.

Simultaneous Measurement of Glucose-6-phosphate 3-Dehydrogenase (NtdC) Catalysis and the Nonenzymatic Reaction of Its Product: Kinetics and Isotope Effects on the First Step in Kanosamine Biosynthesis.

Glucose-6-phosphate 3-dehydrogenase (NtdC) is an NAD-dependent oxidoreductase encoded in the NTD operon of Bacillus subtilis. The oxidation of glucose 6-phosphate by NtdC is the first step in kanosamine biosynthesis. The product, 3-oxo-d-glucose 6-phosphate (3oG6P), has never been synthesized or isolated. The NtdC-catalyzed reaction is very slow at low and neutral pH, and its rate increases to a maximum near pH 9.5. However, under alkaline conditions, the product is not stable because of ring opening followed by deprotonation of the 1,3-dicarbonyl compound. The absorbance band due to this enolate at 310 nm overlaps with that of the other enzymatic product, NADH, complicating kinetic measurements. We report the deconvolution of the resulting spectra of the reaction to determine the rate constants and likely kinetic mechanism. In doing so, we were able to determine the extinction coefficient of the enolate of 3oG6P (23000 M-1 cm-1), which allowed the measurement of the first-order rate constant (5.51 × 10-3 s-1) and activation energy (93 kJ mol-1) of nonenzymatic enolate formation. Using deuterium-labeled substrates, we show that hydride transfer from carbon 3 is partially rate-limiting in the enzymatic reaction, and deuterium substitution on carbon 2 has no significant effect on the enzymatic reaction but lowers the rate of deprotonation of 3oG6P 4-fold. These experiments clearly establish the regiochemistry of the reactions. Coupling of the NtdC reaction with the subsequent step in the pathway, NtdA-catalyzed glutamate-dependent amino transfer, has a small but significant effect on the rate of NAD reduction, consistent with these enzymes working together to process the unstable metabolite.

A previously unrecognized kanosamine biosynthesis pathway in Bacillus subtilis.

The ntd operon in Bacillus subtilis is essential for biosynthesis of 3,3'-neotrehalosadiamine (NTD), an unusual nonreducing disaccharide reported to have antibiotic properties. It has been proposed that the three enzymes encoded within this operon, NtdA, NtdB, and NtdC, constitute a complete set of enzymes required for NTD synthesis, although their functions have never been demonstrated in vitro. We now report that these enzymes catalyze the biosynthesis of kanosamine from glucose-6-phosphate: NtdC is a glucose-6-phosphate 3-dehydrogenase, NtdA is a pyridoxal phosphate-dependent 3-oxo-glucose-6-phosphate:glutamate aminotransferase, and NtdB is a kanosamine-6-phosphate phosphatase. None of these enzymatic reactions have been reported before. This pathway represents an alternate route to the previously reported pathway from Amycolatopsis mediterranei which derives kanosamine from UDP-glucose.

Homoisocitrate dehydrogenase from Candida albicans: properties, inhibition, and targeting by an antifungal pro-drug.

The LYS12 gene from Candida albicans, coding for homoisocitrate dehydrogenase was cloned and expressed as a His-tagged protein in Escherichia coli. The purified gene product catalyzes the Mg(2+)- and K(+)-dependent oxidative decarboxylation of homoisocitrate to α-ketoadipate. The recombinant enzyme demonstrates strict specificity for homoisocitrate. SDS-PAGE of CaHIcDH revealed its molecular mass of 42.6 ± 1 kDa, whereas in size-exclusion chromatography, the enzyme eluted in a single peak corresponding to a molecular mass of 158 ± 3 kDa. Native electrophoresis showed that CaHIcDH may exist as a monomer and as a tetramer and the latter form is favored by homoisocitrate binding. CaHIcDH is an hysteretic enzyme. The K(M) values of the purified His-tagged enzyme for NAD(+) and homoisocitrate were 1.09 mM and 73.7 µM, respectively, and k(cat) was 0.38 s(-1). Kinetic parameters determined for the wild-type CaHIcDH were very similar. The enzyme activity was inhibited by (2R,3S)-3-(p-carboxybenzyl)malate (CBMA), with IC(50) = 3.78 mM. CBMA demonstrated some moderate antifungal activity in minimal media that could be enhanced upon conversion of the enzyme inhibitor into its trimethyl ester derivative (TMCBMA). TMCBMA is the first reported antifungal for which an enzyme of the AAP was identified as a molecular target.