Crystal structure of FadA2 thiolase from Mycobacterium tuberculosis and prediction of its substrate specificity and membrane-anchoring properties.

Tuberculosis (TB) is one of the leading causes of human death caused by Mycobacterium tuberculosis (Mtb). Mtb can enter into a long-lasting persistence where it can utilize fatty acids as the carbon source. Hence, fatty acid metabolism pathway enzymes are considered promising and pertinent mycobacterial drug targets. FadA2 (thiolase) is one of the enzymes involved in Mtb's fatty acid metabolism pathway. FadA2 deletion construct (ΔL136-S150) was designed to produce soluble protein. The crystal structure of FadA2 (ΔL136-S150) at 2.9 Å resolution was solved and analysed for membrane-anchoring region. The four catalytic residues of FadA2 are Cys99, His341, His390 and Cys427, and they belong to four loops with characteristic sequence motifs, i.e., CxT, HEAF, GHP and CxA. FadA2 is the only thiolase of Mtb which belongs to the CHH category containing the HEAF motif. Analysing the substrate-binding channel, it has been suggested that FadA2 is involved in the ß-oxidation pathway, i.e., the degradative pathway, as the long-chain fatty acid can be accommodated in the channel. The catalysed reaction is favoured by the presence of two oxyanion holes, i.e., OAH1 and OAH2. OAH1 formation is unique in FadA2, formed by the NE2 of His390 present in the GHP motif and NE2 of His341 present in the HEAF motif, whereas OAH2 formation is similar to CNH category thiolase. Sequence and structural comparison with the human trifunctional enzyme (HsTFE-ß) suggests the membrane-anchoring region in FadA2. Molecular dynamics simulations of FadA2 with a membrane containing POPE lipid were conducted to understand the role of a long insertion sequence of FadA2 in membrane anchoring.

The C-terminal end of mycobacterial HadBC regulates AcpM interaction during the FAS-II pathway: a structural perspective.

Comprehending the molecular strategies employed by Mycobacterium tuberculosis (Mtb) in FAS-II regulation is of paramount significance for curbing tuberculosis progression. Mtb employs two sets of dehydratases, namely HadAB and HadBC (ß-hydroxyacyl acyl carrier protein dehydratase), for the regulation of the fatty acid synthase (FAS-II) pathway. We utilized a sequence similarity network to discern the basis for the presence of two copies of the dehydratase gene in Mtb. This analysis groups HadC and HadA in different clusters, which could be attributed to the variability in their physiological role with respect to the acyl chain uptake. Our study reveals structural details pertaining to the crystal structure of the last remaining enzyme of the FAS-II pathway. It also provides insights into the highly flexible hot-dog helix and substrate regulatory loop. Additionally, mutational studies assisted in establishing the role of the C-terminal end in HadC of HadBC in the regulation of acyl carrier protein from Mtb-mediated interactions. Complemented with surface plasmon resonance and molecular dynamics simulation studies, the present study provides the first evidence of the molecular mechanisms involved in the differential binding affinity of the acyl carrier protein from Mtb towards both mtbHadAB and mtbHadBC.

Decrypting the oscillating nature of the 4'-phosphopantetheine arm in acyl carrier protein AcpM of Mycobacterium tuberculosis.

In Mycobacterium tuberculosis, acyl carrier protein (AcpM)-mediated fatty acid synthase type II is integral for the synthesis of mycolic acids. AcpM, designated as an atypical ACP, comprises of a putative 33 amino acid long C-terminal extension which is distinctive in nature. Here, we aimed at devising an 'easy-to-go' method for the generation of crypto-AcpM loaded with a solvatochromic probe 7-Nitrobenz-2-oxa-1,3-diazol-4-yl, which is linked to the 4'-phosphopantetheine (Ppant) prosthetic group of AcpM. The crypto-AcpM, coupled with fluorescence spectroscopy and molecular dynamics simulation studies, was employed to explore the elusive dynamics of Ppant arm in AcpM. This investigation establishes the role of the flexible C-terminal extension of AcpM in regulating the prosthetic group sequestration ability by modulating the 'Asp-Ser-Leu' motif.