Abstract
Isocitrate lyase (ICL), a potential anti-tubercular drug target, catalyzes the first step of the glyoxylate shunt. In the present investigation, we studied the conformational flexibility of MtbICL to better understand its stability and catalytic activity. Our biochemical results showed that a point mutation at Phe345, which is topologically distant (>10 Å) to the active site signature sequence (189KKCGH193), completely abolishes the activity of the enzyme. In depth computational analyses were carried out for understanding the structural alterations using molecular dynamics, time-dependent secondary structure and principal component analysis. The results showed that the mutated residue increased the structural flexibility and induced conformational changes near the active site (residues 170–210) and in the C-terminal lid region (residues 411–428). Both these regions are involved in the catalytic activity of MtbICL. Upon mutation, the residual mobility of the enzyme increased, resulting in a decrease in the stability, which was confirmed by the lower free energy of stabilization in the mutant enzyme suggesting the destabilization in the structure. Our results have both biological importance and chemical novelty. It reveals internal dynamics of the enzyme structure and also suggests that regions other than the active site should be exploited for targeting MtbICL inhibition and development of novel anti-tuberculosis compounds.
Highlights
Proteins are intrinsically dynamic systems whose motions cover large ranges in both magnitude and timescale[1]
The Isocitrate lyase (ICL) expression is upregulated in Mycobacterium during the infection of macrophages and the disruption of MtbICL inhibits the persistence of M. tuberculosis in the macrophage in mice[10,11,12]
We suggest that targeting regions other than the active site shall be considered for the strategy to develop structure based inhibitor against MtbICL
Summary
Proteins are intrinsically dynamic systems whose motions cover large ranges in both magnitude and timescale[1]. The resulting principal components (PCs) are sorted according to their contribution to the total fluctuation along the ensemble of conformations This data can be used to study global, correlated motions in atomic simulations of proteins. Isocitrate lyase (ICL), one of the key enzymes of glyoxylate shunt, catalyzes the transformation of isocitrate to succinate and glyoxylate It is important for carbon anaplerosis in the TCA cycle amid growth on C2 substrates such as fatty acids[6, 7]. We investigated the role of a topologically distant Phe[345] in the structure-activity regulation of MtbICL. To achieve this goal, biochemical experiments and multi-dimensional computational studies were performed on MtbICL and MtbICLF345A (hereafter referred as native and mutant protein respectively).
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