NMR study of hydrogen exchange during the B-Z transition of a DNA duplex induced by the Zα domains of yatapoxvirus E3L

The Yaba-like disease viruses (YLDV) are members of the Yatapoxvirus family and have double-stranded DNA genomes. The E3L protein, which is essential for pathogenesis in the vaccinia virus, consists of two domains: an N-terminal Z-DNA binding domain and a C-terminal RNA binding domain. The crystal structure of the E3L orthologue of YLDV (yabZα_E3L) bound to Z-DNA revealed that the overall structure of yabZα_E3L and its interaction with Z-DNA are very similar to those of hZα_ADAR1. Here we have performed NMR hydrogen exchange experiments on the complexes between yabZα_E3L and d(CGCGCG)₂ with a variety of protein-to-DNA molar ratios. This study revealed that yabZα_E3L could efficiently change the B-form helix of the d(CGCGCG)₂ to left-handed Z-DNA via the active-mono B-Z transition pathway like hZα_ADAR1.     

The Zβ domain of human DAI binds to Z-DNA via a novel B-Z transition pathway

The human DNA-dependent activator of IFN-regulatory factor (DAI) protein, which activates the innate immune response in response to DNA, contains two tandem Z-DNA binding domains (Zα and Zβ) at the NH(2) terminus. The hZβ(DAI) structure is similar to other Z-DNA binding proteins, although it demonstrates an unusual Z-DNA recognition. We performed NMR experiments on complexes of hZβ(DAI) with DNA duplex, d(CGCGCG)(2), at a variety of protein-to-DNA molar ratios. The results suggest that hZβ(DAI) binds to Z-DNA via an active-di B-Z transition mechanism, where two hZβ(DAI) proteins bind to B-DNA to form the hZβ(DAI)-B-DNA complex; the B-DNA is subsequently converted to left-handed Z-DNA. This novel mechanism of DNA binding and B-Z conversion is distinct from Z-DNA binding of the human ADAR1 protein.     

Interaction of the Zalpha domain of human ADAR1 with a negatively supercoiled plasmid visualized by atomic force microscopy

Interest to the left-handed DNA conformation has been recently boosted by the findings that a number of proteins contain the Zα domain, which has been shown to specifically recognize Z-DNA. The biological function of Zα is presently unknown, but it has been suggested that it may specifically direct protein regions of Z-DNA induced by negative supercoiling in actively transcribing genes. Many studies, including a crystal structure in complex with Z-DNA, have focused on the human ADAR1 Zα domain in isolation. We have hypothesized that the recognition of a Z-DNA sequence by the Zα_ADAR1 domain is context specific, occurring under energetic conditions, which favor Z-DNA formation. To test this hypothesis, we have applied atomic force microscopy to image Zα_ADAR1 complexed with supercoiled plasmid DNAs. We have demonstrated that the Zα_ADAR1 binds specifically to Z-DNA and preferentially to d(CG)_n inserts, which require less energy for Z-DNA induction compared to other sequences. A notable finding is that site-specific Zα binding to d(GC)₁₃ or d(GC)₂C(GC)₁₀ inserts is observed when DNA supercoiling is insufficient to induce Z-DNA formation. These results indicate that Zα_ADAR1 binding facilities the B-to-Z transition and provides additional support to the model that Z-DNA binding proteins may regulate biological processes through structure-specific recognition.     

Sequence discrimination of the Zα domain of human ADAR1 during B-Z transition of DNA duplexes

The Zα domain of human ADAR1 (Zα_ADAR1) preferentially binds Z-DNA rather than B-DNA with high binding affinity. Zα_ADAR1 binds to the Z-conformation of both non-CG-repeat DNA duplexes and a d(CGCGCG)₂ duplex similarly. We performed NMR experiments on complexes between the Zα_ADAR1 and non-CG-repeat DNA duplexes, d(CACGTG)₂ or d(CGTACG)₂, with a variety of protein-DNA molar ratios. Comparison of these results with those from the analysis of d(CGCGCG)₂ in the previous study suggests that Zα_ADAR1 exhibits the sequence preference of d(CGCGCG)₂ ? d(CACGTG)₂ > d(CGTACG)₂ through multiple sequence discrimination steps during the B-Z transition.     

Structure of the DLM-1-Z-DNA complex reveals a conserved family of Z-DNA-binding proteins

The first crystal structure of a protein, the Z alpha high affinity binding domain of the RNA editing enzyme ADAR1, bound to left-handed Z-DNA was recently described. The essential set of residues determined from this structure to be critical for Z-DNA recognition was used to search the database for other proteins with the potential for Z-DNA binding. We found that the tumor-associated protein DLM-1 contains a domain with remarkable sequence similarities to Z alpha(ADAR). Here we report the crystal structure of this DLM-1 domain bound to left-handed Z-DNA at 1.85 A resolution. Comparison of Z-DNA binding by DLM-1 and ADAR1 reveals a common structure-specific recognition core within the binding domain. However, the domains differ in certain residues peripheral to the protein-DNA interface. These structures reveal a general mechanism of Z-DNA recognition, suggesting the existence of a family of winged-helix proteins sharing a common Z-DNA binding motif.     

The Zα domain of PKZ from Carassius auratus can bind to d(GC)n in negative supercoils

PKZ was the most recently discovered member of eIF2α kinase family in fish. CaPKZ, the first identified fish PKZ, possessed a conserved eIF2α kinase catalytic domain in C-terminal and two Z-DNA binding domains (Zα) in N-terminal. The Zα of CaPKZ closely resembled that of other Z-DNA binding proteins: ADAR1, DLM-1, and E3L. In order to understand more about the function of CaPKZ, we expressed and purified three constructed peptides of CaPKZ (P_Zα): P_Zα1Zα2, P_Zα1Zα1 and P_Zα2Zα2. Moreover, most of the plasmids containing d(GC)_n inserts were maintained in the Z-conformation, as confirmed by using inhibition of methylation experiments and anti-Z-DNA antibody. Gel mobility shift assays were then used to examine the affinity of these P_Zα to the recombinant plasmids. Meanwhile, a competition experiment using P_Zα1Zα2 and anti-Z-DNA antibody was performed. The results revealed that P_Zα1Zα2 and P_Zα1Zα1 were able to bind to the recombinant plasmids with high affinity, whereas P_Zα2Zα2 could not bind to it. In addition, dimerization of P_Zα1Zα2 indicated the function unit of Zα of CaPKZ would be a dimer.     

Dual conformational recognition by Z-DNA binding protein is important for the B–Z transition process

Left-handed Z-DNA is radically different from the most common right-handed B-DNA and can be stabilized by interactions with the Zα domain, which is found in a group of proteins, such as human ADAR1 and viral E3L proteins. It is well-known that most Zα domains bind to Z-DNA in a conformation-specific manner and induce rapid B–Z transition in physiological conditions. Although many structural and biochemical studies have identified the detailed interactions between the Zα domain and Z-DNA, little is known about the molecular basis of the B–Z transition process. In this study, we successfully converted the B–Z transition-defective Zα domain, vvZα_E3L, into a B–Z converter by improving B-DNA binding ability, suggesting that B-DNA binding is involved in the B–Z transition. In addition, we engineered the canonical B-DNA binding protein GH5 into a Zα-like protein having both Z-DNA binding and B–Z transition activities by introducing Z-DNA interacting residues. Crystal structures of these mutants of vvZα_E3L and GH5 complexed with Z-DNA confirmed the significance of conserved Z-DNA binding interactions. Altogether, our results provide molecular insight into how Zα domains obtain unusual conformational specificity and induce the B–Z transition.     

The flanking sequence contributes to the immobilisation of spermine at the G-quadruplex in the NHE (nuclease hypersensitivity element) III1 of the c-Myc promoter

Defining the molecular basis of the DNA sequence selectivity of polyamine binding is central to understanding polyamine-dependent gene expression. We have studied, by selective NMR experiments, the variation of spermine mobility and conformation in the presence of G-quadruplexes formed by sequences of the purine-rich strand of the c-Myc promoter, nuclease hypersensitivity element III₁ (NHE III₁). All the NHE quadruplexes restrict spermine mobility and induce a spermine conformational change but the most effective immobilisation occurs when all five G-tracts of the NHE III₁ are present. This suggests structure within the nucleotides flanking the G-quadruplex has a role in immobilising spermine.     

The SEP domain of p47 acts as a reversible competitive inhibitor of cathepsin L

The solution structure of the human p47 SEP domain in a construct comprising residues G1-S2-p47(171-270) was determined by NMR spectroscopy. A structure-derived hypothesis about the domains' function was formulated and pursued in binding experiments with cysteine proteases. The SEP domain was found to be a reversible competitive inhibitor of cathepsin L with a K_i of 1.5 μM. The binding of G1-S2-p47(171-270) to cathepsin L was mapped by biochemical assays and the binding interface was investigated by NMR chemical shift perturbation experiments.     

Modulation of ADAR1 editing activity by Z-RNA in vitro

RNA editing by A-to-I modification has been recognized as an important molecular mechanism for generating RNA and protein diversity. In mammals, it is mediated by a family of adenosine deaminases that act on RNAs (ADARs). The large version of the editing enzyme ADAR1 (ADAR1-L), expressed from an interferon-responsible promoter, has a Z-DNA/Z-RNA binding domain at its N-terminus. We have tested the in vitro ability of the enzyme to act on a 50 bp segment of dsRNA with or without a Z-RNA forming nucleotide sequence. A-to-I editing efficiency is markedly enhanced in presence of the sequence favoring Z-RNA. In addition, an alteration in the pattern of modification along the RNA duplex becomes evident as reaction times decrease. These results suggest that the local conformation of dsRNA molecules might be an important feature for target selectivity by ADAR1 and other proteins with Z-RNA binding domains.     

Identifying the regulatory element for human angiotensin-converting enzyme 2 (ACE2) expression in human cardiofibroblasts

Angiotensin-converting enzyme 2 (ACE2) has been proposed as a potential target for cardioprotection in regulating cardiovascular functions, owing to its key role in the formation of the vasoprotective peptides angiotensin-(1-7) from angiotensin II (Ang II). The regulatory mechanism of ace2 expression, however, remains to be explored. In this study, we investigated the regulatory element within the upstream of ace2. The human ace2 promoter region, from position −2069 to +20, was cloned and a series of upstream deletion mutants were constructed and cloned into a luciferase reporter vector. The reporter luciferase activity was analyzed by transient transfection of the constructs into human cardiofibroblasts (HCFs) and an activating domain was identified in the −516/−481 region. Deletion or reversal of this domain within ace2 resulted in a significant decrease in promoter activity. The nuclear proteins isolated from the HCFs formed a DNA-protein complex with double stranded oligonucleotides of the −516/−481 domain, as detected by electrophoretic mobility shift assay. Site-directed mutagenesis of this region identified a putative protein binding domain and a potential binding site, ATTTGGA, homologous to that of an Ikaros binding domain. This regulatory element was responsible for Ang II stimulation via the Ang II-Ang II type-1 receptor (AT1R) signaling pathway, but was not responsible for pro-inflammatory cytokines TGF-β1 and TNF-α. Our results suggest that the nucleotide sequences −516/−481 of human ace2 may be a binding domain for an as yet unidentified regulatory factor(s) that regulates ace2 expression and is associated with Ang II stimulation.