Apurinic/apyrmidinic endonuclease (APE1) is an unusual nuclear redox factor in which the redox-active cysteines identified to date, C65 and C93, are surface inaccessible residues whose activities may be influenced by partial unfolding of APE1. To assess the role of the remaining five cysteines in APE1’s redox activity, double cysteine mutants were analyzed excluding C65A, which is redox-inactive as a single mutant. C93A/C99A APE1 was found to be redox-inactive whereas other double cysteine mutants retained the same redox activity as that observed for C93A APE1. To determine whether these three cysteines, C65, C93, and C99, were sufficient for redox activity, all other cysteines were substituted with alanine, and this protein was shown to be fully redox active. Mutants with impaired redox activity failed to stimulate cell proliferation, establishing an important role for APE1’s redox activity in cell growth. Disulfide bond formation upon oxidation of APE1 was analyzed by proteolysis of the protein followed by mass spectrometry analysis. Within 5 min. of exposure to hydrogen peroxide, a single disulfide bond formed between C65 and C138 followed by the formation of three additional disulfide bonds within 15 min.; ten total disulfide bonds formed within one hour. A single mixed-disulfide bond involving C99 of APE1 was observed for the reaction of oxidized APE1 with TRX. Disulfide-bonded species of APE1 or APE1/TRX were further characterized by size exclusion chromatography and found to form large complexes. Taken together, our data suggest that APE1 is a unique redox factor with properties distinct from those of other redox factors.
Apurinic/apyrimidinic
endonuclease I (APE1) is an essential base
excision repair enzyme that catalyzes a Mg2+-dependent
reaction in which the phosphodiester backbone is cleaved 5′
of an abasic site in duplex DNA. This reaction has been proposed to
involve either one or two metal ions bound to the active site. In
the present study, we report crystal structures of Mg2+, Mn2+, and apo-APE1 determined at 1.4, 2.2, and 1.65
Å, respectively, representing two of the highest resolution structures
yet reported for APE1. In our structures, a single well-ordered Mn2+ ion was observed coordinated by D70 and E96; the Mg2+ site exhibited disorder modeled as two closely positioned
sites coordinated by D70 and E96 or E96 alone. Direct metal binding
analysis of wild-type, D70A, and E96A APE1, as assessed by differential
scanning fluorimetry, indicated a role for D70 and E96 in binding
of Mg2+ or Mn2+ to APE1. Consistent with the
disorder exhibited by Mg2+ bound to the active site, two
different conformations of E96 were observed coordinated to Mg2+. A third conformation for E96 in the apo structure is similar
to that observed in the APE1–DNA–Mg2+ complex
structure. Thus, binding of Mg2+ in three different positions
within the active site of APE1 in these crystal structures corresponds
directly with three different conformations of E96. Taken together,
our results are consistent with the initial capture of metal by D70
and E96 and repositioning of Mg2+ facilitated by the structural
plasticity of E96 in the active site.
Background: Metnase, a transposase-containing DNA repair protein, retains DNA cleavage activity with a DDN motif.Results: Substitution with the ancestral transposase DDD/DDE catalytic motif results in a decrease in ssDNA binding and ss-overhang cleavage activities.Conclusion: The DDN motif is required for Metnase DNA repair activities.Significance: Understanding the requirements for catalytic activity provides insights on how Metnase functions as a DNA repair protein.
The piggyBac DNA transposon is used widely in genome engineering applications. Unlike other transposons, its excision site can be precisely repaired without leaving footprints and it integrates specifically at TTAA tetranucleotides. We present cryo-EM structures of piggyBac transpososomes: a synaptic complex with hairpin DNA intermediates and a strand transfer complex capturing the integration step. The results show that the excised TTAA hairpin intermediate and the TTAA target adopt essentially identical conformations, providing a mechanistic link connecting the two unique properties of piggyBac. The transposase forms an asymmetric dimer in which the two central domains synapse the ends while two C-terminal domains form a separate dimer that contacts only one transposon end. In the strand transfer structure, target DNA is severely bent and the TTAA target is unpaired. In-cell data suggest that asymmetry promotes synaptic complex formation, and modifying ends with additional transposase binding sites stimulates activity.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.