SMUG2 DNA glycosylase from Pedobacter heparinus as a new subfamily of the UDG superfamily

Structural and functional coupling in cross-linking uracil-DNA glycosylase UDGX

Enzymes in uracil-DNA glycosylase (UDG) superfamily are involved in removal of deaminated nucleobases such as uracil, methylcytosine derivatives such as formylcytosine and carboxylcytosine, and other base damage in DNA repair. UDGX is the latest addition of a new class to the UDG superfamily with a sporadic distribution in bacteria. UDGX type enzymes have a distinct biochemical property of cross-linking itself to the resulting AP site after uracil removal. Built on previous biochemical and structural analyses, this work comprehensively investigated the kinetic and enzymatic properties of Mycobacterium smegmatis UDGX. Kinetics and mutational analyses, coupled with structural information, defined the roles of E52, D56, D59, F65 of motif 1, H178 of motif 2 and N91, K94, R107 and H109 of motif 3 play in uracil excision and cross-linking. More importantly, a series of quantitative analyses underscored the structural coupling through inter-motif and intra-motif interactions and subsequent functional coupling of the uracil excision and cross-linking reactions. A catalytic model is proposed, which underlies this catalytic feature unique to UDGX type enzymes. This study offers new insight on the catalytic mechanism of UDGX and provides a unique example of enzyme evolution.

Screening of glycosylase activity on oxidative derivatives of methylcytosine: Pedobacter heparinus SMUG2 as a formylcytosine- and carboxylcytosine-DNA glycosylase

5-Methylcytosine (mC) is an epigenetic mark that impacts transcription, development, diseases including cancer and aging. The demethylation process involves Tet-mediated stepwise oxidation of mC to hmC, fC, or caC, excision of fC or caC by thymine-DNA glycosylase (TDG), and subsequent base excision repair. Thymine-DNA glycosylase (TDG) belongs to uracil-DNA glycosylase (UDG) superfamily, which is a group of enzymes that are initially found to be responsible for excising the deaminated bases from DNA and generating apurinic/apyrimidinic (AP) sites. mC oxidative derivatives may also be generated from Fenton chemistry and γ-irradiation. In screening DNA glycosylase activity in UDG superfamily, we identified new activity on fC- and caC-containing DNA in family 2 MUG/TDG and family 6 HDG enzymes. Surprisingly, we found a glycosylase SMUG2 from bacterium Pedobacter heparinus (Phe), a subfamily of family 3 SMUG1 DNA glycosylase, displayed catalytic activity towards not only DNA containing uracil, but also fC and caC. Given the sequence and structural differences between the family 3 and other family enzymes, we investigated the catalytic mechanism using mutational, enzyme kinetics and molecular modeling approaches. Mutational analysis and kinetics measurements identified I62, N63 and F76 of motif 1, and H205 of motif 2 in Phe SMUG2 as important catalytic residues, of which H205 of motif 2 played a critical role in catalyzing the removal of fC and caC. A catalytic model underlying the roles of these residues was proposed. The structural and catalytic differences between Phe SMUG2 and human TDG were compared by molecular modeling and molecular dynamics simulations. This study expands our understanding of DNA glycosylase capacity in UDG superfamily and provides insights into the molecular mechanism of fC and caC excision in Phe SMUG2.

Evolutionary Origins of DNA Repair Pathways: Role of Oxygen Catastrophe in the Emergence of DNA Glycosylases

It was proposed that the last universal common ancestor (LUCA) evolved under high temperatures in an oxygen-free environment, similar to those found in deep-sea vents and on volcanic slopes. Therefore, spontaneous DNA decay, such as base loss and cytosine deamination, was the major factor affecting LUCA’s genome integrity. Cosmic radiation due to Earth’s weak magnetic field and alkylating metabolic radicals added to these threats. Here, we propose that ancient forms of life had only two distinct repair mechanisms: versatile apurinic/apyrimidinic (AP) endonucleases to cope with both AP sites and deaminated residues, and enzymes catalyzing the direct reversal of UV and alkylation damage. The absence of uracil–DNA N-glycosylases in some Archaea, together with the presence of an AP endonuclease, which can cleave uracil-containing DNA, suggests that the AP endonuclease-initiated nucleotide incision repair (NIR) pathway evolved independently from DNA glycosylase-mediated base excision repair. NIR may be a relic that appeared in an early thermophilic ancestor to counteract spontaneous DNA damage. We hypothesize that a rise in the oxygen level in the Earth’s atmosphere ~2 Ga triggered the narrow specialization of AP endonucleases and DNA glycosylases to cope efficiently with a widened array of oxidative base damage and complex DNA lesions.

Role of endonuclease III enzymes in uracil repair

Endonuclease III is a DNA glycosylase previously known for its repair activity on oxidative pyrimidine damage. Uracil is a deamination product derived from cytosine. Uracil DNA N-glycosylase (UNG) and mismatch-specific uracil DNA glycosylase (MUG) are two known repair enzymes with enzymatic activity on uracil in E. coli. Here we report a G/U specific uracil DNA glycosylase activity in E. coli endonuclease III (endo III, Nth), which is comparable to MUG but significantly lower than its thymine glycol DNA glycosylase activity. The possibility that the novel activity is due to contamination is ruled out by expressing the wild type nth gene and an active site mutant in a uracil-repair-deficient genetic background. Consistent with the biochemical analysis, analyses of lac⁺ reversion and mutation frequencies in the presence of human AID induced cytosine deamination indicate the endo III can play a role in repair of cytosine deamination. In addition to E. coli, UDG activity is found in endo III homologs from other organisms. E. coli nucleoside diphosphate kinase (Ndk) was also tested for UDG activity because it was previously reported as an uracil repair enzyme. Under the assay conditions, very limited UDG activity was detected in single-stranded uracil-containing DNA from E. coli Ndk and no UDG activity was detected in human Ndk homologs. This study provides definitive clarification on uracil repair by endo III and reveals that endonuclease III is a G/U-specific UDG that can be viewed as a prototype for the human MBD4 uracil DNA glycosylase.

An unconventional family 1 uracil DNA glycosylase in Nitratifractor salsuginis

The uracil DNA glycosylase superfamily consists of at least six families with a diverse specificity toward DNA base damage. Family 1 uracil N-glycosylase (UNG) exhibits exclusive specificity on uracil-containing DNA. Here, we report a family 1 UNG homolog from Nitratifractor salsuginis with distinct biochemical features that differentiate it from conventional family 1 UNGs. Globally, the crystal structure of N. salsuginisUNG shows a few additional secondary structural elements. Biochemical and enzyme kinetic analysis, coupled with structural determination, molecular modeling, and molecular dynamics simulations, shows that N. salsuginisUNG contains a salt bridge network that plays an important role in DNA backbone interactions. Disruption of the amino acid residues involved in the salt bridges greatly impedes the enzymatic activity. A tyrosine residue in motif 1 (GQDPY) is one of the distinct sequence features setting family 1 UNG apart from other families. The crystal structure of Y81G mutant indicates that several subtle changes may account for its inactivity. Unlike the conventional family 1 UNG enzymes, N. salsuginisUNG is not inhibited by Ugi, a potent inhibitor specific for family 1 UNG. This study underscores the diversity of paths that a uracil DNA glycosylase may take to acquire its unique structural and biochemical properties during evolution.

DATABASE

Structure data are available in the PDB under accession numbers 5X3G and 5X3H.

Identification of a prototypical single-stranded uracil DNA glycosylase from Listeria innocua

A recent phylogenetic study on UDG superfamily estimated a new clade of family 3 enzymes (SMUG1-like), which shares a lower homology with canonic SMUG1 enzymes. The enzymatic properties of the newly found putative DNA glycosylase are unknown. To test the potential UDG activity and evaluate phylogenetic classification, we isolated one SMUG1-like glycosylase representative from Listeria innocua (Lin). A biochemical screening of DNA glycosylase activity in vitro indicates that Lin SMUG1-like glycosylase is a single-strand selective uracil DNA glycosylase. The UDG activity on DNA bubble structures provides clue to its physiological significance in vivo. Mutagenesis and molecular modeling analyses reveal that Lin SMUG1-like glycosylase has similar functional motifs with SMUG1 enzymes; however, it contains a distinct catalytic doublet S67-S68 in motif 1 that is not found in any families in the UDG superfamily. Experimental investigation shows that the S67M-S68N double mutant is catalytically more active than either S67M or S68N single mutant. Coupled with mutual information analysis, the results indicate a high degree of correlation in the evolution of SMUG1-like enzymes. This study underscores the functional and catalytic diversity in the evolution of enzymes in UDG superfamily.