Amino-acid substitutions at the domain interface affect substrate and allosteric inhibitor binding in α-isopropylmalate synthase from Mycobacterium tuberculosis.

α-Isopropylmalate synthase (α-IPMS) is a multi-domain protein catalysing the condensation of α-ketoisovalerate (α-KIV) and acetyl coenzyme A (AcCoA) to form α-isopropylmalate. This reaction is the first committed step in the leucine biosynthetic pathway in bacteria and plants, and α-IPMS is allosterically regulated by this amino acid. Existing crystal structures of α-IPMS from Mycobacterium tuberculosis (MtuIPMS) indicate that this enzyme has a strikingly different domain arrangement in each monomer of the homodimeric protein. This asymmetry results in two distinct interfaces between the N-terminal catalytic domains and the C-terminal regulatory domains in the dimer. In this study, residues Arg97 and Asp444 across one of these unequal domain interfaces were substituted to evaluate the importance of protein asymmetry and salt bridge formation between this pair of residues. Analysis of solution-phase structures of wild-type and variant MtuIPMS indicates that substitutions of these residues have little effect on overall protein conformation, a result also observed for addition of the feedback inhibitor leucine to the wild-type enzyme. All variants had increased catalytic efficiency relative to wild-type MtuIPMS, and those with an Asp444 substitution displayed increased affinity for the substrate AcCoA. All variants also showed reduced sensitivity to leucine and altered biphasic reaction kinetics when compared with those of the wild-type enzyme. It is proposed that substituting residues at the asymmetric domain interface increases flexibility in the protein, particularly affecting the AcCoA binding site and the response to leucine, without penalty on catalysis.

Removal of the C-terminal regulatory domain of α-isopropylmalate synthase disrupts functional substrate binding.

α-Isopropylmalate synthase (α-IPMS) catalyzes the metal-dependent aldol reaction between α-ketoisovalerate (α-KIV) and acetyl-coenzyme A (AcCoA) to give α-isopropylmalate (α-IPM). This reaction is the first committed step in the biosynthesis of leucine in bacteria. α-IPMS is homodimeric, with monomers consisting of (ß/α)(8) barrel catalytic domains fused to a C-terminal regulatory domain, responsible for binding leucine and providing feedback regulation for leucine biosynthesis. In these studies, we demonstrate that removal of the regulatory domain from the α-IPMS enzymes of both Neisseria meningitidis (NmeIPMS) and Mycobacterium tuberculosis (MtuIPMS) results in enzymes that are unable to catalyze the formation of α-IPM, although truncated NmeIPMS was still able to slowly hydrolyze AcCoA. The lack of catalytic activity of these truncation variants was confirmed by complementation studies with Escherichia coli cells lacking the α-IPMS gene, where transformation with the plasmids encoding the truncated α-IPMS enzymes was not able to rescue α-IPMS activity. X-ray crystal structures of both truncation variants reveal that both proteins are dimeric and that the catalytic sites of the proteins are intact, although the divalent metal ion that is thought to be responsible for activating substrate α-KIV is displaced slightly relative to its position in the substrate-bound, wild-type structure. Isothermal titration calorimetry and WaterLOGSY nuclear magnetic resonance experiments demonstrate that although these truncation variants are not able to catalyze the reaction between α-KIV and AcCoA, they are still able to bind the substrate α-KIV. It is proposed that the regulatory domain is crucial for ensuring protein dynamics necessary for competent catalysis.

The C-terminal regulatory domain is required for catalysis by Neisseria meningitidis alpha-isopropylmalate synthase.

alpha-Isopropylmalate synthase (alpha-IPMS) catalyses the first committed step in leucine biosynthesis in many pathogenic bacteria, including Neisseria meningitidis. This enzyme (NmeIPMS) has been purified, characterised, and compared to alpha-IPMS proteins from other bacteria. NmeIPMS is a homodimer which catalyses the condensation of alpha-ketoisovalerate (alpha-KIV) and acetyl coenzyme A (AcCoA), and is inhibited by leucine. NmeIPMS can use alternate alpha-ketoacids as substrates and, in contrast to alpha-IPMS from other sources, is activated by a range of metal ions including Cd(2+) and Zn(2+) that have previously been reported as inhibitory, since they suppress the dithiodipyridone assay system rather than the enzyme itself. Previous studies indicate that alpha-IPMS is a TIM barrel enzyme with an allosteric leucine-binding domain. To assess the importance of this domain, a truncated form of NmeIPMS was generated and characterised. Loss of the regulatory domain resulted in a loss of the ability to catalyse the aldol reaction, although the enzyme was still able to slowly hydrolyse AcCoA independently of alpha-KIV at a rate similar to that of the WT enzyme. This implies that the regulatory domain is not only required for control of enzymatic activity but may assist in the positioning of key residues in the catalytic TIM barrel. The importance of this domain to catalytic function may offer new strategies for inhibitor design.

Cloning and characterisation of dihydrodipicolinate synthase from the pathogen Neisseria meningitidis.

Neisseria meningitidis is an obligate commensal bacterium of humans, and also an important human pathogen. To facilitate future drug studies, we report here the biochemical and structural characterisation of a key enzyme in (S)-lysine biosynthesis, dihydrodipicolinate synthase (DHDPS), from N. meningitidis (NmeDHDPS). X-ray crystallography revealed only minor structural differences between NmeDHDPS and the enzyme from E. coli at the active and allosteric effector sites. The catalytic capabilities of NmeDHDPS are similar to those of the enzyme from E. coli, but intriguingly NmeDHDPS is subject to substrate inhibition by high concentrations of the second substrate, (S)-aspartate semialdehyde, and is also significantly more sensitive to feedback inhibition by (S)-lysine. This heightened sensitivity to inhibition at both active and allosteric sites suggests that it may be possible to target DHDPS from N. meningitidis for antibiotic development.