Abstract
The analysis of whole genomes has revealed specific geographical distribution of Mycobacterium tuberculosis (Mtb) strains across the globe suggestive of unique niche dependent adaptive mechanisms. We provide an important correlation of a genome‐based mutation to a molecular phenotype across two predominant clinical Mtb lineages of the Indian subcontinent. We have identified a distinct lineage specific mutation‐G247C, translating into an alanine‐proline conversion in the papA2 gene of Indo‐oceanic lineage 1 (L1) Mtb strains, and restoration of cell wall sulfolipids by simple genetic complementation of papA2 from lineage 3 (L3) or from H37Rv (lineage 4‐L4) attributed the loss of this glycolipid to this specific mutation in Indo‐Oceanic L1 Mtb. The investigation of structure of Mtb PapA2 revealed a distinct nonribosomal peptide synthetase (NRPS) C domain conformation with an unconventional presence of a zinc binding motif. Surprisingly, the A83P mutation did not map to either the catalytic center in the N‐terminal subdomain or any of the substrate‐binding region of the protein. On the contrary, the inherent ability of mutant PapA2 to form insoluble aggregates and molecular simulations with the wild‐type/mutant (Wt/mut) PapA2 purports an important role for the surface associated 83rd residue in protein conformation. This study demonstrates the importance of a critical structural residue in the papA2 protein of Mtb and helps establish a link between observed genomic alteration and its molecular consequence in the successful human pathogen Mtb. Significance We demonstrate the effect of a unique SNP in PapA2 gene of Indo‐oceanic Mycobacterium tuberculosis (Mtb) strains leading to the loss of sulfolipid from these strains. By X‐ray crystallographic analysis and molecular dynamics (MD) simulations, we show the importance of this residue in the global PapA2 structure. The presence of a Zn atom has not been reported before for this class of proteins. Here, we provide an important link between genomic alteration and its molecular consequence in Mtb highlighting one of the many adaptive mechanisms that have contributed to its success as a human pathogen. A high degree of identity with PapA1, 3, or 4 would help in interpreting the structure of these PapA proteins and other acyl transferases of other biological systems.
Highlights
Mycobacterium tuberculosis (Mtb) has the dubious distinction of being one of the most successful human pathogens by virtue of its extreme adaptability and survivability in the face of stress
The present study demonstrates the importance of a critical structural residue in the papA2 protein of Mtb and helps establish a link between observed genomic alteration and its molecular consequence in the successful human pathogen Mtb
In order to test if the differences panned to the other predominant strain of the subcontinent – (L3) in Northern India, we investigated the total cell wall associated lipid content among these two Mtb lineages
Summary
Mycobacterium tuberculosis (Mtb) has the dubious distinction of being one of the most successful human pathogens by virtue of its extreme adaptability and survivability in the face of stress. The Mtb cell wall is recognized as a complex entity unique in its composition of complex polyketide lipids like TDM, SL, DAT-PAT, PDIM. This assembly requires a finely tuned array of metabolic functions involving the biosynthesis, maturation, transport and assembly of precursors from the cytoplasm to the exterior [2,3,4,5]. The ability of Mtb strains to alter their cell wall repertoire to effectively communicate with host cells, modulate immune signalling and play a pivotal role in intracellular fitness is well recognised [6,7,8,9,10]. Minor modifications like cylopropanation of mycolic acids leads to marked alterations in the host immune activation/
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