Mutational and structural analyses of UdgX: insights into the active site pocket architecture and its evolution.

UdgX excises uracil from uracil-containing DNA to concurrently form a covalent bond with the resulting AP-DNA. Structurally, UdgX is highly similar to family-4 UDGs (F4-UDGs). However, UdgX is unique in possessing a flexible R-loop (105KRRIH109). Among the class-defining motifs, while its motif A (51GEQPG55) diverged to possess Q53 in place of A53/G53 in F4-UDGs, motif B [178HPS(S/A)(L/V)(L/V)R184] has remained unchanged. Previously, we proposed an SN1 mechanism resulting in a covalent bond between H109 and AP-DNA. In this study, we investigated several single/double mutants of UdgX. The H109A, H109S, H109G, H109Q, H109C and H109K mutants gain conventional UDG activity to varying levels. The crystal structures of UdgX mutants show topological changes in their active sites, rationalizing their UDG activities. The E52Q, E52N and E52A mutants reveal that E52 forms a catalytic dyad with H109 to enhance its nucleophilicity. The Q53A mutant supports that UdgX specific evolution of Q53 occurred essentially to stabilize the R-loop conformation. The R184A mutation (motif B) supports the role of R184 in substrate-binding. Taken together, the structural, bioinformatics, and mutational studies suggest that UdgX diverged from F4-UDGs, and the emergence of the characteristic R-loop in UdgX is functionally assisted by A53/G53 to Q53 changes in motif A.

Nudix hydrolases with Coenzyme A (CoA) and acyl-CoA pyrophosphatase activities confer growth advantage to Mycobacterium smegmatis.

Nudix hydrolase family proteins hydrolyse toxic by-products of cellular metabolism such as mutagenic nucleoside triphosphates, sugar nucleotides and signalling molecules. We studied the substrate specificities of Nudix hydrolases encoded by rv3672c and rv3040c from Mycobacterium tuberculosis and their respective homologues, msmeg_6185 and msmeg_2327 from M. smegmatis. The rv3672c- and msmeg_6185-encoded proteins (Rv3672 and MSMEG_6185, respectively) showed CoA pyrophosphatase (CoAse) activity that converted acyl-CoA to adenosine-3',5'-diphosphate (3', 5'-ADP) and 4-acyl phosphopantetheine. The efficiencies of Rv3672 and MSMEG_6185 in hydrolysing CoA derivatives were found to be higher than those of the Rv3040 and MSMEG_2327 (encoded by rv3040c and msmeg_2327, respectively). Further, amongst the substrates tested, Rv3672 and MSMEG_6185 used CoA and oxidized CoA as the most preferred substrates. Use of the M. smegmatis model showed that the expression of msmeg_6185 occurs in the log and stationary phases but declines during the late stationary phase and becomes undetectable during hypoxia. The co-culture competition experiments performed between the wild-type and Δmsmeg_6185 strains of M. smegmatis in different carbon sources revealed that the presence of msmeg_6185 provided growth fitness advantage to M. smegmatis, irrespective of the carbon source, implicating its function in regulation for the optimal physiological levels of acyl-CoAs in the cell.

Development of mCherry tagged UdgX as a highly sensitive molecular probe for specific detection of uracils in DNA.

Uracil is not always a mistakenly occurring base in DNA. Uracils in DNA genomes are known to be important in the life cycles of Bacillus subtilis phages (PBS1/2) and the malarial parasite, Plasmodium falciparum; and have been implicated in the development of fruit fly and antibody maturation in B-lymphocytes. Availability of a sensitive, specific and robust technique for the detection uracils in genes/genomes is essential to understand its varied biological roles. Mycobacterium smegmatis UdgX (MsmUdgX), identified and characterised in our laboratory, forms covalent complexes with the uracil sites in DNA in a specific manner. MsmUdgX cleaves the glycosidic bond between uracil and the deoxyribose sugar in DNA to produce uracilate and oxocarbenium ions. The oxocarbenium ion is then captured into a covalent complex by the nucleophilic attack of a histidine side chain of MsmUdgX. Here, we describe the use of a fusion protein, mCherry tagged MsmUdgX (mChUdgX), which combines the property of MsmUdgX to covalently and specifically bind the uracil sites in the genome, with the sensitivity of fluorescent detection of mCherry as a reporter. We show that both the purified mChUdgX and the Escherichia coli cell-extracts overexpressing mChUdgX provide high sensitivity and specificity of detecting uracils in DNA.

Covalent binding of uracil DNA glycosylase UdgX to abasic DNA upon uracil excision.

Uracil DNA glycosylases (UDGs) are important DNA repair enzymes that excise uracil from DNA, yielding an abasic site. Recently, UdgX, an unconventional UDG with extremely tight binding to DNA containing uracil, was discovered. The structure of UdgX from Mycobacterium smegmatis in complex with DNA shows an overall similarity to that of family 4 UDGs except for a protruding loop at the entrance of the uracil-binding pocket. Surprisingly, H109 in the loop was found to make a covalent bond to the abasic site to form a stable intermediate, while the excised uracil remained in the pocket of the active site. H109 functions as a nucleophile to attack the oxocarbenium ion, substituting for the catalytic water molecule found in other UDGs. To our knowledge, this change from a catalytic water attack to a direct nucleophilic attack by the histidine residue is unprecedented. UdgX utilizes a unique mechanism of protecting cytotoxic abasic sites from exposure to the cellular environment.