Three-dimensional DNA crystals with pH-responsive noncanonical junctions.

Three-dimensional (3D) DNA crystals have been envisioned as programmable biomaterial scaffolds for creating ordered arrays of biological and nonbiological molecules. Despite having excellent programmable properties, the linearity of the Watson-Crick B-form duplex imposes limitations on 3D crystal design. Predictable noncanonical base pairing motifs have the potential to serve as junctions to connect linear DNA segments into complex 3D lattices. Here, we designed crystals based on a template structure with parallel-stranded noncanonical base pairs. Depending on pH, the structures we determined contained all but one or two of the designed secondary structure interactions. Surprisingly, a conformational change of the designed Watson-Crick duplex region resulted in crystal packing differences between the predicted and observed structures. However, the designed noncanonical motif was virtually identical to the template when crystals were grown at pH 5.5, highlighting the motif's predictability. At pH 7.0 we observed a structurally similar variation on this motif that contains a previously unobserved C-G•G-C quadruple base pair. We demonstrate that these two variants can interconvert in crystallo in response to pH perturbations. This study spotlights several important considerations in DNA crystal design, describes the first 3D DNA lattice composed of A-DNA helical sheets, and reveals a noncanonical DNA motif that has adaptive features that may be useful for designing dynamic crystals or biomaterial assemblies.

Point mutations in Escherichia coli DNA pol V that confer resistance to non-cognate DNA damage also alter protein-protein interactions.

Y-family DNA polymerases are important for conferring cellular resistance to DNA damaging agents in part due to their specialized ability to copy damaged DNA. The Escherichia coli Y-family DNA polymerases are encoded by the umuDC and dinB genes. UmuC and the cleaved form of UmuD, UmuD', form UmuD'2C (pol V), which is able to bypass UV photoproducts such as cyclobutane pyrimidine dimers and 6-4 thymine-thymine dimers, whereas DinB is specialized to copy N(2)-dG adducts, such as N(2)-furfuryl-dG. To better understand this inherent specificity, we used hydroxylamine to generate a random library of UmuC variants from which we then selected those with the ability to confer survival to nitrofurazone (NFZ), which is believed to cause N(2)-furfuryl-dG lesions. We tested the ability of three of the selected UmuC variants, A9V, H282P, and T412I, to bypass N(2)-furfuryl-dG in vitro, and discovered that pol V containing UmuC A9V has overall modestly better primer extension activity than WT pol V, whereas the UmuC T412I and UmuC H282P mutations result in much lower primer extension efficiency. Upon further characterization, we found that the ability of the UmuC variant A9V to render cells UV-mutable is dependent on the proper length of the arm of UmuD'. Cells harboring UmuC variants T412I and H282P show enhanced cleavage of UmuD to form UmuD', which, together with our other observations, suggests that this may be due to a disruption of a direct interaction between UmuC and UmuD. Thus, we find that protein interactions as well as protein conformation appear to be crucial for resistance to specific types of DNA damage.