Structural Characterization of a Viral NEIL1 Ortholog Unliganded and Bound to Abasic Site-containing DNA

Endonuclease VIII (Nei) is a DNA glycosylase of the base excision repair pathway that recognizes and excises oxidized pyrimidines. We determined the crystal structures of a NEIL1 ortholog from the giant Mimivirus (MvNei1) unliganded and bound to DNA containing tetrahydrofuran (THF), which is the first structure of any Nei with an abasic site analog. The MvNei1 structures exhibit the same overall architecture as other enzymes of the Fpg/Nei family, which consists of two globular domains joined by a linker region. MvNei1 harbors a zincless finger, first described in human NEIL1, rather than the signature zinc finger generally found in the Fpg/Nei family. In contrast to Escherichia coli Nei, where a dramatic conformational change was observed upon binding DNA, the structure of MvNei1 bound to DNA does not reveal any substantial movement compared with the unliganded enzyme. A protein segment encompassing residues 217–245 in MvNei1 corresponds to the “missing loop” in E. coli Nei and the “αF–β10 loop” in E. coli Fpg, which has been reported to be involved in lesion recognition. Interestingly, the corresponding loop in MvNei1 is ordered in both the unliganded and furan-bound structures, unlike other Fpg/Nei enzymes where the loop is generally ordered in the unliganded enzyme or in complexes with a lesion, and disordered otherwise. In the MvNei1·tetrahydrofuran complex a tyrosine located at the tip of the putative lesion recognition loop stacks against the furan ring; the tyrosine is predicted to adopt a different conformation to accommodate a modified base.All organisms must cope with the generation of potentially lethal or mutagenic oxidative DNA base damage produced by endogenous free radicals. The enzymes that recognize and initiate the repair of these lesions are the DNA glycosylases, which are found ubiquitously in all three kingdoms of life (for reviews see Refs. 1–4). Some of these enzymes are bifunctional, i.e. they catalyze the hydrolysis of the N-glycosyl bond linking a base to a deoxyribose (glycosylase activity) and subsequently cleave the DNA 3′ to the apurinic/apyrimidinic site (lyase activity), whereas others are monofunctional and only carry out the glycosylase reaction, generating abasic sites as products. Structural studies indicate that the DNA glycosylases that recognize oxidative DNA damages fall into two family groups: the helix-hairpin-helix superfamily and the Fpg/Nei family (for reviews see Refs. 1, 5, 6). The helix-hairpin-helix superfamily includes a diverse group of enzymes with varying substrate specificities which nonetheless share a helix-hairpin-helix motif that consists of two α-helices connected by a hairpin loop, followed by a Gly/Pro-rich loop and a conserved catalytic aspartate residue (7). Glycosylase members of the second family, the Fpg/Nei family, share a two-domain architecture: The N-terminal domain consists of a two-layered β-sandwich with two α-helices, whereas the C-terminal domain contains four α-helices, of which two are involved in a conserved helix-two-turn-helix (H2TH)³ motif, and two β-strands that make up the zinc finger motif (2, 6). Both these motifs are involved in DNA binding. Escherichia coli formamidopyrimidine DNA glycosylase (Fpg) was the first identified member of this family and was characterized by its ability to recognize and remove formamidopyrimidines (8); however, the principal biological substrate for Fpg is 8-oxoguanine (8-oxoG) (9, 10).More than a decade ago a second DNA glycosylase, which recognizes oxidized pyrimidines, Nei (endonuclease VIII), was identified in E. coli and found to be similar in sequence to Fpg (11, 12). In contrast to Fpg, Nei is only sparsely distributed among prokaryotes (2). Several years ago homologs of this enzyme were identified and characterized in vertebrates, the so-called Nei-like or Neil proteins (13–17). The evolutionary origin of the Neil proteins in vertebrates is unclear (2), and this issue was further confounded several years ago when two Nei-like proteins were identified in the giant Mimivirus (mimicking microbe) (18). This is the largest virus characterized to date with a genomic size of 1.2 Mb, larger than many bacteria (19) and with more than 900 protein coding genes (20). The host for Mimivirus is Acanthamoeba polyphaga, a soil and freshwater protozoan (18).We have recently cloned and characterized the two Nei glycosylases from Mimivirus, MvNei1 (L315) and MvNei2 (L720) (21). Sequence analysis suggests that Mimivirus Nei1 possesses a zincless finger β-hairpin motif first described in human NEIL1, rather than the signature zinc finger (22–24) characteristic of the Fpg/Nei family. Furthermore, we have shown that MvNei1 and MvNei2 have enzymatic properties very similar to their human homologs, NEIL1 and NEIL2 (21). MvNei1 and NEIL1 share substrate preferences for oxidized pyrimidines in duplex DNA. Although MvNei1 and NEIL1 do not recognize 8-oxoguanine, both enzymes cleave its further oxidation products (25, 26), guanidinohydantoin (Gh) and spiroiminodihydantoin, when paired with C (21, 27). Single stranded DNA with the same base lesions, as well as bubble structures, are also substrates for both enzymes (15, 21, 28).Here we report the crystal structures of MvNei1 unliganded and in complex with DNA containing tetrahydrofuran (THF), a structural analog of the cyclic hemiacetal form of an abasic site. Human NEIL1 and MvNei1 bind DNA containing THF but do not cleave the DNA backbone. The MvNei1·THF complex is the first structure of an Nei with an abasic site analog. MvNei1 shares significant structural similarity with human NEIL1 (29). In contrast to E. coli Nei where a dramatic conformational change was observed upon binding DNA (30), the structure of MvNei1 bound to furan containing DNA does not reveal any substantial conformational change compared with the unliganded protein. The MvNei1 loop corresponding to the αF-β9/10 lesion recognition loop of Fpg is ordered in both the unliganded and furan-bound structures, unlike what was reported for other Fpg/Nei enzymes where the loop is generally ordered when the enzyme is unliganded or bound to a lesion, and disordered otherwise. In the MvNei1·THF complex a tyrosine located at the tip of the putative lesion recognition loop stacks against the furan ring; the tyrosine and/or the tip of the loop are predicted to adopt a different conformation in the presence of a modified base.