Ae-Ree Lee

NMR study on the B-Z junction formation of DNA duplexes induced by Z-DNA binding domain of human ADAR1.

Z-DNA is produced in a long genomic DNA by Z-DNA binding proteins, through formation of two B-Z junctions with the extrusion of one base pair from each junction. To answer the question of how Z-DNA binding proteins induce B-Z transitions in CG-rich segments while maintaining the B-conformation of surrounding segments, we investigated the kinetics and thermodynamics of base-pair openings of a 13-bp DNA in complex with the Z-DNA binding protein, Zα(ADAR1). We also studied perturbations in the backbone of Zα(ADAR1) upon binding to DNA. Our study demonstrates the initial contact conformation as an intermediate structure during B-Z junction formation induced by Zα(ADAR1), in which the Zα(ADAR1) protein displays unique backbone conformational changes, but the 13-bp DNA duplex maintains the B-form helix. We also found the unique structural features of the 13-bp DNA duplex in the initial contact conformation: (i) instability of the AT-rich region II and (ii) longer lifetime for the opening state of the CG-rich region I. Our findings suggest a three-step mechanism of B-Z junction formation: (i) Zα(ADAR1) specifically interacts with a CG-rich DNA segment maintaining B-form helix via a unique conformation; (ii) the neighboring AT-rich region becomes very unstable, and the CG-rich DNA segment is easily converted to Z-DNA; and (iii) the AT-rich regions are base-paired again, and the B-Z junction structure is formed.

Comparison of backbone dynamics of the type III antifreeze protein and antifreeze-like domain of human sialic acid synthase

Antifreeze proteins (AFPs) are found in a variety of cold-adapted (psychrophilic) organisms to promote survival at subzero temperatures by binding to ice crystals and decreasing the freezing temperature of body fluids. The type III AFPs are small globular proteins that consist of one α-helix, three 310-helices, and two β-strands. Sialic acids play important roles in a variety of biological functions, such as development, recognition, and cell adhesion and are synthesized by conserved enzymatic pathways that include sialic acid synthase (SAS). SAS consists of an N-terminal catalytic domain and a C-terminal antifreeze-like (AFL) domain, which is similar to the type III AFPs. Despite having very similar structures, AFL and the type III AFPs exhibit very different temperature-dependent stability and activity. In this study, we have performed backbone dynamics analyses of a type III AFP (HPLC12 isoform) and the AFL domain of human SAS (hAFL) at various temperatures. We also characterized the structural/dynamic properties of the ice-binding surfaces by analyzing the temperature gradient of the amide proton chemical shift and its correlation with chemical shift deviation from random coil. The dynamic properties of the two proteins were very different from each other. While HPLC12 was mostly rigid with a few residues exhibiting slow motions, hAFL showed fast internal motions at low temperature. Our results provide insight into the molecular basis of thermostability and structural flexibility in homologous psychrophilic HPLC12 and mesophilic hAFL proteins.

NMR study of the Z-DNA binding mode and B–Z transition activity of the Zα domain of human ADAR1 when perturbed by mutation on the α3 helix and β-hairpin

The Zα domains of human ADAR1 (ZαADAR1) bind to Z-DNA via interaction mediated by the α3-core and β-hairpin. Five residues in the α3 helix and four residues in the β-hairpin play important roles in Zα function, forming direct or water-mediated hydrogen bonds with DNA backbone phosphates or interacting hydrophobically with DNA bases. To understand the roles of these residues during B-Z transition of duplex DNA, we performed NMR experiments on complexes of various ZαADAR1 mutants with a 6-bp DNA duplex at various protein-to-DNA molar ratios. Our study suggests that single mutations at residues K169, N173, or Y177 cause unusual conformational changes in the hydrophobic faces of helices α1, α2, and α3, which dramatically decrease the Z-DNA binding affinity. 1D imino proton spectra and chemical shift perturbation showed that single mutations at residues K170, R174, T191, P192, P193, or W195 slightly affected the Z-DNA binding affinity. A hydrogen exchange study proved that the K170A- and R174A-ZαADAR1 proteins could efficiently change B-DNA to left-handed Z-DNA via an active B-Z transition pathway, whereas the G2·C5 base pair was significantly destabilized compared to wild-type ZαADAR1.

NMR dynamics study of the Z-DNA binding domain of human ADAR1 bound to various DNA duplexes.

The Z-DNA binding domain of human ADAR1 (Zα(ADAR1)) preferentially binds Z-DNA rather than B-DNA with high binding affinity. Here, we have carried out chemical shift perturbation and backbone dynamics studies of Zα(ADAR1) in the free form and in complex with three DNA duplexes, d(CGCGCG)(2), d(CACGTG)(2), and d(CGTACG)(2). This study reveals that Zα(ADAR1) initially binds to d(CGCGCG)(2) through the distinct conformation, especially in the unusually flexible β1-loop-α2 region, from the d(CGCGCG)(2)-(Zα(ADAR1))(2) complex. This study also suggests that Zα(ADAR1) exhibits a distinct conformational change during the B-Z transition of non-CG-repeat DNA duplexes with low binding affinities compared to the CG-repeat DNA duplex.

NMR study of the antifreeze activities of active and inactive isoforms of a type III antifreeze protein

The quaternary‐amino‐ethyl 1 (QAE1) isoforms of type III antifreeze proteins (AFPs) prevent the growth of ice crystals within organisms living in polar regions. We determined the antifreeze activity of wild‐type and mutant constructs of the Japanese notched‐fin eelpout (Zoarces elongates Kner) AFP8 (nfeAFP8) and characterized the structural and dynamics properties of their ice‐binding surface using NMR. We found that the three constructs containing the V20G mutation were incapable of stopping the growth of ice crystals and exhibited structural changes, as well as increased conformational flexibility, in the first 310 helix (residues 18–22) of the sequence. Our results suggest that the inactive nfeAFP8s are incapable of anchoring water molecules due to the unusual and flexible backbone conformation of their primary prism plane‐binding surface.

NMR investigation on the DNA binding and B-Z transition pathway of the Zα domain of human ADAR1.

Human ADAR1, which has two left-handed Z-DNA binding domains, preferentially binds Z-DNA rather than B-DNA with a high binding affinity. Z-DNA can be induced in long genomic DNA by Z-DNA binding proteins through the formation of two B-Z junctions with the extrusion of one base pair from each junction. We performed NMR experiments on complexes of Zα(ADAR1) with three DNA duplexes at a variety of protein-to-DNA molar ratios. This study confirmed that the Zα(ADAR1) first binds to an 8-bp CG-rich DNA segment via a unique conformation during B-Z transition and the neighboring AT-rich region becomes destabilized. We also found that, when DNA duplexes have only 6-bp CG-rich segment, the interaction with Zα(ADAR1) did not affect the thermal stabilities of the 6-bp CG-rich segment as well as the neighboring two A·T base pairs. These results indicate that four Zα(ADAR1) proteins interact with the 8-bp DNA sequence containing a 6-bp CG-repeat segment as well as a dinucleotide step, even though the dinucleotid step contains A∙T base pairs. Thus this study suggests that the length of the CG-rich region is more important than the specific DNA sequence for determining which base-pair is extruded from the B-Z junction structure. This study also found that the Zα(ADAR1) in complex with a 11-bp DNA duplex exhibits a Z-DNA-bound conformation distinct from that of free Zα(ADAR1) and the initial contact conformations of Zα(ADAR1) complexed with 13-bp DNA duplexes.

Unveiling the pathway to Z-DNA in the protein-induced B–Z transition

Abstract Left-handed Z-DNA is an extraordinary conformation of DNA, which can form by special sequences under specific biological, chemical or physical conditions. Human ADAR1, prototypic Z-DNA binding protein (ZBP), binds to Z-DNA with high affinity. Utilizing single-molecule FRET assays for Z-DNA forming sequences embedded in a long inactive DNA, we measure thermodynamic populations of ADAR1-bound DNA conformations in both GC and TG repeat sequences. Based on a statistical physics model, we determined quantitatively the affinities of ADAR1 to both Z-form and B-form of these sequences. We also reported what pathways it takes to induce the B–Z transition in those sequences. Due to the high junction energy, an intermediate B* state has to accumulate prior to the B–Z transition. Our study showing the stable B* state supports the active picture for the protein-induced B–Z transition that occurs under a physiological setting.

Expression and Purification of the Helicase-like Subdomains, H1 and H23, of Reverse Gyrase from A. fulgidus for Heteronuclear NMR study

Reverse gyrase is a hyperthermophile specific protein which introduces positive supercoils into DNA molecules. Reverse gyrase consists of an N-terminal helicase-like domain and a C-terminal topoisomerase domain. The helicase-like domain shares the three-dimensional structure with two tandem RecA-folds (H1 and H2), in which the subdomain H2 is interrupted by the latch domain (H3). To understand the physical property of the hyperthermophile-specific protein, two subdomains af_H1 and af_H23 have been cloned into E. coli expression vector, pET28a. The N-labeled af_H1 and af_H23 proteins were expressed and purified for heteronuclear NMR study. The af_H1 protein exhibits the well-dispersion of amide signals in its H/N-HSQC spectra and thus further NMR study continues to be progressed.

Thermodynamic Model for B-Z Transition of DNA Induced by Z-DNA Binding Proteins

Z-DNA is stabilized by various Z-DNA binding proteins (ZBPs) that play important roles in RNA editing, innate immune response, and viral infection. In this review, the structural and dynamics of various ZBPs complexed with Z-DNA are summarized to better understand the mechanisms by which ZBPs selectively recognize d(CG)-repeat DNA sequences in genomic DNA and efficiently convert them to left-handed Z-DNA to achieve their biological function. The intermolecular interaction of ZBPs with Z-DNA strands is mediated through a single continuous recognition surface which consists of an α3 helix and a β-hairpin. In the ZBP-Z-DNA complexes, three identical, conserved residues (N173, Y177, and W195 in the Zα domain of human ADAR1) play central roles in the interaction with Z-DNA. ZBPs convert a 6-base DNA pair to a Z-form helix via the B-Z transition mechanism in which the ZBP first binds to B-DNA and then shifts the equilibrium from B-DNA to Z-DNA, a conformation that is then selectively stabilized by the additional binding of a second ZBP molecule. During B-Z transition, ZBPs selectively recognize the alternating d(CG)n sequence and convert it to a Z-form helix in long genomic DNA through multiple sequence discrimination steps. In addition, the intermediate complex formed by ZBPs and B-DNA, which is modulated by varying conditions, determines the degree of B-Z transition.

NMR Study on the Preferential Binding of the Zα Domain of Human ADAR1 to CG-repeat DNA Duplex

The Z-DNA domain of human ADAR1 (ZαADAR1) produces B-Z junction DNA through preferential binding to the CG-repeat segment and destabilizing the neighboring AT-rich region. However, this study could not answer the question of how many base-pairs in AT-rich region are destabilized by binding of ZαADAR1. Thus, we have performed NMR experiments of ZαADAR1 to the longer DNA duplex containing an 8-base-paired (8-bp) CG-repeat segment and a 12-bp AT-rich region. This study revealed that ZαADAR1 preferentially binds to the CG-repeat segment rather than AT-rich region in a long DNA and then destabilizes at least 6 base-pairs in the neighboring AT-rich region for efficient B-Z transition of the CG-repeat segment.