A novel interaction linking the FAS-II and phthiocerol dimycocerosate (PDIM) biosynthetic pathways.

The fatty acid biosynthesis (FAS-II) pathway in Mycobacterium tuberculosis generates long chain fatty acids that serve as the precursors to mycolic acids, essential components of the mycobacterial cell wall. Enzymes in the FAS-II pathway are thought to form one or more noncovalent multi-enzyme complexes within the cell, and a bacterial two-hybrid screen was used to search for missing components of the pathway and to furnish additional data on interactions involving these enzymes in vivo. Using the FAS-II beta-ketoacyl synthase, KasA, as bait, an extensive bacterial two-hybrid screen of a M. tuberculosis genome fragment library unexpectedly revealed a novel interaction between KasA and PpsB as well as PpsD, two polyketide modules involved in the biosynthesis of the virulence lipid phthiocerol dimycocerosate (PDIM). Sequence analysis revealed that KasA interacts with PpsB and PpsD in the region of the acyl carrier domain of each protein, raising the possibility that lipids could be transferred between the FAS-II and PDIM biosynthetic pathways. Subsequent studies utilizing purified proteins and radiolabeled lipids revealed that fatty acids loaded onto PpsB were transferred to KasA and also incorporated into long chain fatty acids synthesized using a Mycobacterium smegmatis lysate. These data suggest that in addition to producing PDIMs, the growing phthiocerol product can also be shuttled into the FAS-II pathway via KasA as an entry point for further elongation. Interactions between these biosynthetic pathways may exist as a simple means to increase mycobacterial lipid diversity, enhancing functionality and the overall complexity of the cell wall.

Probing mechanisms of resistance to the tuberculosis drug isoniazid: Conformational changes caused by inhibition of InhA, the enoyl reductase from Mycobacterium tuberculosis.

The frontline tuberculosis drug isoniazid (INH) inhibits InhA, the NADH-dependent fatty acid biosynthesis (FAS-II) enoyl reductase from Mycobacterium tuberculosis (MTB), via formation of a covalent adduct with NAD(+) (the INH-NAD adduct). Resistance to INH can be correlated with many mutations in MTB, some of which are localized in the InhA cofactor binding site. While the InhA mutations cause a substantial decrease in the affinity of InhA for NADH, surprisingly the same mutations result in only a small impact on binding of the INH-NAD adduct. Based on the knowledge that InhA interacts in vivo with other components of the FAS-II pathway, we have initiated experiments to determine whether enzyme inhibition results in structural changes that could affect protein-protein interactions involving InhA and how these ligand-induced conformational changes are modulated in the InhA mutants. Significantly, while NADH binding to wild-type InhA is hyperbolic, the InhA mutants bind the cofactor with positive cooperativity, suggesting that the mutations permit access to a second conformational state of the protein. While cross-linking studies indicate that enzyme inhibition causes dissociation of the InhA tetramer into dimers, analytical ultracentrifugation and size exclusion chromatography reveal that ligand binding causes a conformational change in the protein that prevents cross-linking across one of the dimer-dimer interfaces in the InhA tetramer. Interestingly, a similar ligand-induced conformational change is also observed for the InhA mutants, indicating that the mutations modulate communication between the subunits without affecting the two conformational states of the protein that are present.

Assembling amyloid fibrils from designed structures containing a significant amyloid beta-peptide fragment.

The amyloid plaque, consisting of amyloid beta-peptide (Abeta) fibrils surrounded by dystrophic neurites, is an invariable feature of Alzheimer's disease. The determination of the molecular structure of Abeta fibrils is a significant goal that may lead to the structure-based design of effective therapeutics for Alzheimer's disease. Technical challenges have thus far rendered this goal impossible. In the present study, we develop an alternative methodology. Rather than determining the structure directly, we design conformationally constrained peptides and demonstrate that only certain 'bricks' can aggregate into fibrils morphologically identical to Abeta fibrils. The designed peptides include variants of a decapeptide fragment of Abeta, previously shown to be one of the smallest peptides that (1) includes a pentapeptide sequence necessary for Abeta-Abeta binding and aggregation and (2) can form fibrils indistinguishable from those formed by full-length Abeta. The secondary structure of these bricks is monitored by CD spectroscopy, and electron microscopy is used to study the morphology of the aggregates formed. We then made various residue deletions and substitutions to determine which structural features are essential for fibril formation. From the constraints, statistical analysis of side-chain pair correlations in beta-sheets and experimental data, we deduce a detailed model of the peptide strand alignment in fibrils formed by these bricks. Our results show that the constrained decapeptide dimers rapidly form an intramolecular, antiparallel beta-sheet and polymerize into amyloid fibrils at low concentrations. We suggest that the formation of an exposed beta-sheet (e.g. an Abeta dimer formed by interaction in the decapeptide region) could be a rate-limiting step in fibril formation. A theoretical framework that explains the results is presented in parallel with the data.