Base-Pair Opening Dynamics Study of Fluoride Riboswitch in the Bacillus cereus CrcB Gene.

Riboswitches are segments of noncoding RNA that bind with metabolites, resulting in a change in gene expression. To understand the molecular mechanism of gene regulation in a fluoride riboswitch, a base-pair opening dynamics study was performed with and without ligands using the Bacillus cereus fluoride riboswitch. We demonstrate that the structural stability of the fluoride riboswitch is caused by two steps depending on ligands. Upon binding of a magnesium ion, significant changes in a conformation of the riboswitch occur, resulting in the greatest increase in their stability and changes in dynamics by a fluoride ion. Examining hydrogen exchange dynamics through NMR spectroscopy, we reveal that the stabilization of the U45·A37 base-pair due to the binding of the fluoride ion, by changing the dynamics while maintaining the structure, results in transcription regulation. Our results demonstrate that the opening dynamics and stabilities of a fluoride riboswitch in different ion states are essential for the genetic switching mechanism.

Structural and biophysical properties of RIG-I bound to dsRNA with G-U wobble base pairs.

Retinoic acid-inducible gene I (RIG-I) is responsible for innate immunity via the recognition of short double-stranded RNAs in the cytosol. With the clue that G-U wobble base pairs in the influenza A virus's RNA promoter region are responsible for RIG-I activation, we determined the complex structure of RIG-I ΔCARD and a short hairpin RNA with G-U wobble base pairs by X-ray crystallography. Interestingly, the overall helical backbone trace was not affected by the presence of the wobble base pairs; however, the base pair inclination and helical axis angle changed upon RIG-I binding. NMR spectroscopy revealed that RIG-I binding renders the flexible base pair of the influenza A virus's RNA promoter region between the two G-U wobble base pairs even more flexible. Binding to RNA with wobble base pairs resulted in a more flexible RIG-I complex. This flexible complex formation correlates with the entropy-favoured binding of RIG-I and RNA, which results in tighter binding affinity and RIG-I activation. This study suggests that the structure and dynamics of RIG-I are tailored to the binding of specific RNA sequences with different flexibility.

Systematic editing of synthetic RIG-I ligands to produce effective antiviral and anti-tumor RNA immunotherapies.

Retinoic acid-inducible gene I (RIG-I) recognizes double-stranded viral RNAs (dsRNAs) containing two or three 5' phosphates. A few reports of 5'-PPP-independent RIG-I agonists have emerged, but little is known about the molecular principles underlying their recognition. We recently found that the bent duplex RNA from the influenza A panhandle promoter activates RIG-I even in the absence of a 5'-triphosphate moiety. Here, we report that non-canonical synthetic RNA oligonucleotides containing G-U wobble base pairs that form a bent helix can exert RIG-I-mediated antiviral and anti-tumor effects in a sequence- and site-dependent manner. We present synthetic RNAs that have been systematically modified to enhance their efficacy and we outline the basic principles for engineering RIG-I agonists applicable to immunotherapy.

Design, synthesis, and biological evaluation of C7-functionalized DMXAA derivatives as potential human-STING agonists.

STING, a central protein in the innate immune response to cytosolic DNA, has emerged as a hot target for the development of vaccine-adjuvants and anticancer drugs. The discovery of potent human-STING (hSTING) agonist is expected to revolutionize the current cancer immunotherapy. Inspired by the X-ray crystal structure of DMXAA (5,6-dimethylxanthenone-4-acetic acid) and hSTINGG230I complex, we designed various DMXAA derivatives that contain a hydrogen bonding donor/acceptor or a halide at the C7 position. While 7-bromo- and 7-hydroxyl-DMXAA showed notable binding to mouse-STING (mSTING), our newly synthesized C7-functionalized DMXAA derivatives did not bind to hSTING. Nevertheless, our newly developed synthetic protocol for the C7-functionalization of DMXAA would be applicable to access other C7-substituted DMXAA analogues as potential hSTING agonists.

Solution structure of the Z-DNA binding domain of PKR-like protein kinase from Carassius auratus and quantitative analyses of the intermediate complex during B-Z transition.

Z-DNA binding proteins (ZBPs) play important roles in RNA editing, innate immune response and viral infection. Structural and biophysical studies show that ZBPs initially form an intermediate complex with B-DNA for B-Z conversion. However, a comprehensive understanding of the mechanism of Z-DNA binding and B-Z transition is still lacking, due to the absence of structural information on the intermediate complex. Here, we report the solution structure of the Zα domain of the ZBP-containing protein kinase from Carassius auratus(caZαPKZ). We quantitatively determined the binding affinity of caZαPKZ for both B-DNA and Z-DNA and characterized its B-Z transition activity, which is modulated by varying the salt concentration. Our results suggest that the intermediate complex formed by caZαPKZ and B-DNA can be used as molecular ruler, to measure the degree to which DNA transitions to the Z isoform.

Structural features of influenza A virus panhandle RNA enabling the activation of RIG-I independently of 5'-triphosphate.

Retinoic acid-inducible gene I (RIG-I) recognizes specific molecular patterns of viral RNAs for inducing type I interferon. The C-terminal domain (CTD) of RIG-I binds to double-stranded RNA (dsRNA) with the 5'-triphosphate (5'-PPP), which induces a conformational change in RIG-I to an active form. It has been suggested that RIG-I detects infection of influenza A virus by recognizing the 5'-triphosphorylated panhandle structure of the viral RNA genome. Influenza panhandle RNA has a unique structure with a sharp helical bending. In spite of extensive studies of how viral RNAs activate RIG-I, whether the structural elements of the influenza panhandle RNA confer the ability to activate RIG-I signaling has been poorly explored. Here, we investigated the dynamics of the influenza panhandle RNA in complex with RIG-I CTD using NMR spectroscopy and showed that the bending structure of the panhandle RNA negates the requirement of a 5'-PPP moiety for RIG-I activation.

Structural Studies of Potassium Transport Protein KtrA Regulator of Conductance of K+ (RCK) C Domain in Complex with Cyclic Diadenosine Monophosphate (c-di-AMP).

Although it was only recently identified as a second messenger, c-di-AMP was found to have fundamental importance in numerous bacterial functions such as ion transport. The potassium transporter protein, KtrA, was identified as a c-di-AMP receptor. However, the co-crystallization of c-di-AMP with the protein has not been studied. Here, we determined the crystal structure of the KtrA RCK_C domain in complex with c-di-AMP. The c-di-AMP nucleotide, which adopts a U-shaped conformation, is bound at the dimer interface of RCK_C close to helices α3 and α4. c-di-AMP interacts with KtrA RCK_C mainly by forming hydrogen bonds and hydrophobic interactions. c-di-AMP binding induces the contraction of the dimer, bringing the two monomers of KtrA RCK_C into close proximity. The KtrA RCK_C was able to interact with only c-di-AMP, but not with c-di-GMP, 3',3-cGAMP, ATP, and ADP. The structure of the KtrA RCK_C domain and c-di-AMP complex would expand our understanding about the mechanism of inactivation in Ktr transporters governed by c-di-AMP.

The structural basis of lipopolysaccharide recognition by the TLR4-MD-2 complex.

The lipopolysaccharide (LPS) of Gram negative bacteria is a well-known inducer of the innate immune response. Toll-like receptor (TLR) 4 and myeloid differentiation factor 2 (MD-2) form a heterodimer that recognizes a common 'pattern' in structurally diverse LPS molecules. To understand the ligand specificity and receptor activation mechanism of the TLR4-MD-2-LPS complex we determined its crystal structure. LPS binding induced the formation of an m-shaped receptor multimer composed of two copies of the TLR4-MD-2-LPS complex arranged symmetrically. LPS interacts with a large hydrophobic pocket in MD-2 and directly bridges the two components of the multimer. Five of the six lipid chains of LPS are buried deep inside the pocket and the remaining chain is exposed to the surface of MD-2, forming a hydrophobic interaction with the conserved phenylalanines of TLR4. The F126 loop of MD-2 undergoes localized structural change and supports this core hydrophobic interface by making hydrophilic interactions with TLR4. Comparison with the structures of tetra-acylated antagonists bound to MD-2 indicates that two other lipid chains in LPS displace the phosphorylated glucosamine backbone by approximately 5 A towards the solvent area. This structural shift allows phosphate groups of LPS to contribute to receptor multimerization by forming ionic interactions with a cluster of positively charged residues in TLR4 and MD-2. The TLR4-MD-2-LPS structure illustrates the remarkable versatility of the ligand recognition mechanisms employed by the TLR family, which is essential for defence against diverse microbial infection.

Solution structure of the RecQ C-terminal domain of human Bloom syndrome protein.

RecQ C-terminal (RQC) domain is known as the main DNA binding module of RecQ helicases such as Bloom syndrome protein (BLM) and Werner syndrome protein (WRN) that recognizes various DNA structures. Even though BLM is able to resolve various DNA structures similarly to WRN, BLM has different binding preferences for DNA substrates from WRN. In this study, we determined the solution structure of the RQC domain of human BLM. The structure shares the common winged-helix motif with other RQC domains. However, half of the N-terminal has unstructured regions (α1-α2 loop and α3 region), and the aromatic side chain on the top of the ß-hairpin, which is important for DNA duplex strand separation in other RQC domains, is substituted with a negatively charged residue (D1165) followed by the polar residue (Q1166). The structurally distinctive features of the RQC domain of human BLM suggest that the DNA binding modes of the BLM RQC domain may be different from those of other RQC domains.

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 ß-hairpin.

The Zα domains of human ADAR1 (ZαADAR1) bind to Z-DNA via interaction mediated by the α3-core and ß-hairpin. Five residues in the α3 helix and four residues in the ß-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 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.

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 ß1-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.

Structure and function of the regulatory HRDC domain from human Bloom syndrome protein.

The helicase and RNaseD C-terminal (HRDC) domain, conserved among members of the RecQ helicase family, regulates helicase activity by virtue of variations in its surface residues. The HRDC domain of Bloom syndrome protein (BLM) is known as a critical determinant of the dissolution function of double Holliday junctions by the BLM-Topoisomerase IIIα complex. In this study, we determined the solution structure of the human BLM HRDC domain and characterized its DNA-binding activity. The BLM HRDC domain consists of five α-helices with a hydrophobic 3(10)-helical loop between helices 1 and 2 and an extended acidic surface comprising residues in helices 3-5. The BLM HRDC domain preferentially binds to ssDNA, though with a markedly low binding affinity (K(d) ∼100 µM). NMR chemical shift perturbation studies suggested that the critical DNA-binding residues of the BLM HRDC domain are located in the hydrophobic loop and the N-terminus of helix 2. Interestingly, the isolated BLM HRDC domain had quite different DNA-binding modes between ssDNA and Holliday junctions in electrophoretic mobility shift assay experiments. Based on its surface charge separation and DNA-binding properties, we suggest that the HRDC domain of BLM may be adapted for a unique function among RecQ helicases--that of bridging protein and DNA interactions.

The human Cdc34 carboxyl terminus contains a non-covalent ubiquitin binding activity that contributes to SCF-dependent ubiquitination.

Cdc34 is an E2 ubiquitin-conjugating enzyme that functions in conjunction with SCF (Skp1.Cullin 1.F-box) E3 ubiquitin ligase to catalyze covalent attachment of polyubiquitin chains to a target protein. Here we identified direct interactions between the human Cdc34 C terminus and ubiquitin using NMR chemical shift perturbation assays. The ubiquitin binding activity was mapped to two separate Cdc34 C-terminal motifs (UBS1 and UBS2) that comprise residues 206-215 and 216-225, respectively. UBS1 and UBS2 bind to ubiquitin in the proximity of ubiquitin Lys(48) and C-terminal tail, both of which are key sites for conjugation. When bound to ubiquitin in one orientation, the Cdc34 UBS1 aromatic residues (Phe(206), Tyr(207), Tyr(210), and Tyr(211)) are probably positioned in the vicinity of ubiquitin C-terminal residue Val(70). Replacement of UBS1 aromatic residues by glycine or of ubiquitin Val(70) by alanine decreased UBS1-ubiquitin affinity interactions. UBS1 appeared to support the function of Cdc34 in vivo because human Cdc34(1-215) but not Cdc34(1-200) was able to complement the growth defect by yeast Cdc34 mutant strain. Finally, reconstituted IkappaBalpha ubiquitination analysis revealed a role for each adjacent pair of UBS1 aromatic residues (Phe(206)/Tyr(207), Tyr(210)/Tyr(211)) in conjugation, with Tyr(210) exhibiting the most pronounced catalytic function. Intriguingly, Cdc34 Tyr(210) was required for the transfer of the donor ubiquitin to a receptor lysine on either IkappaBalpha or a ubiquitin in a manner that depended on the neddylated RING sub-complex of the SCF. Taken together, our results identified a new ubiquitin binding activity within the human Cdc34 C terminus that contributes to SCF-dependent ubiquitination.

Base pair opening kinetics and dynamics in the DNA duplexes that specifically recognized by very short patch repair protein (Vsr).

In Escherichia coli, the very short patch (VSP) repair system is a major pathway for removal of T.G mismatches in Dcm target sequences. In the VSP repair pathway, the very short patch repair (Vsr) endonuclease selectively recognizes a T.G mismatch in Dcm target sequences and hydrolyzes the 5'-phosphate group of the mismatched thymine. The hydrogen exchange NMR studies here revealed that the T5.G18 mismatch in the Dcm target sequence significantly stabilizes own base pair but destabilizes the two neighboring G4.C19 and A6.T17 base pairs compare to other T.G mismatches. These unusual patterns of base pair stability in the Dcm target sequence can explain how the Vsr endonuclease specifically recognizes the mismatched Dcm target sequence and intercalates into the DNA.

The interaction between ubiquitin and yeast polymerase η C terminus does not require the UBZ domain.

Polymerase η (Polη) is one of the Y-family polymerases that is recruited by monoubiquitinated proliferating cell nuclear antigen (Ub-PCNA) to DNA damage sites during translesion synthesis (TLS). This interaction is mediated by an ubiquitin-binding zinc-finger (UBZ) domain and a PCNA-interacting protein (PIP) box in Polη, which binds to ubiquitin and PCNA, respectively. Here, we show that without the UBZ domain, the PIP box of yeast Polη has a novel binding function with ubiquitin. Furthermore, the UBZ domain and the PIP box share the same binding surfaces for ubiquitin. The interaction with ubiquitin via the PIP box stabilizes the Ub-PCNA/Polη complex. Moreover, the PIP residues I624 and L625 contribute to Polη function in TLS in vivo.

NMR spectroscopic elucidation of the B-Z transition of a DNA double helix induced by the Z alpha domain of human ADAR1.

The human RNA editing enzyme ADAR1 (double-stranded RNA deaminase I) deaminates adenine in pre-mRNA to yield inosine, which codes as guanine. ADAR1 has two left-handed Z-DNA binding domains, Z alpha and Z beta, at its NH(2)-terminus and preferentially binds Z-DNA, rather than B-DNA, with high binding affinity. The cocrystal structure of Z alpha(ADAR1) complexed to Z-DNA showed that one monomeric Z alpha(ADAR1) domain binds to one strand of double-stranded DNA and a second Z alpha(ADAR1) monomer binds to the opposite strand with 2-fold symmetry with respect to DNA helical axis. It remains unclear how Z alpha(ADAR1) protein specifically recognizes Z-DNA sequence in a sea of B-DNA to produce the stable Z alpha(ADAR1)-Z-DNA complex during the B-Z transition induced by Z alpha(ADAR1). In order to characterize the molecular recognition of Z-DNA by Z alpha(ADAR1), we performed circular dichroism (CD) and NMR experiments with complexes of Zalpha(ADAR1) bound to d(CGCGCG)(2) (referred to as CG6) produced at a variety of protein-to-DNA molar ratios. From this study, we identified the intermediate states of the CG6-Z alpha(ADAR1) complex and calculated their relative populations as a function of the Z alpha(ADAR1) concentration. These findings support an active B-Z transition mechanism in which the Z alpha(ADAR1) protein first binds to B-DNA and then converts it to left-handed Z-DNA, a conformation that is then stabilized by the additional binding of a second Z alpha(ADAR1) molecule.

NMR Dynamics Study Reveals the Zα Domain of Human ADAR1 Associates with and Dissociates from Z-RNA More Slowly than Z-DNA.

Human RNA editing enzyme ADAR1 deaminates adenosine in pre-mRNA to yield inosine. The Zα domain of human ADAR1 (hZαADAR1) binds specifically to left-handed Z-RNA as well as Z-DNA and stabilizes the Z-conformation. To answer the question of how hZαADAR1 can induce both the B-Z transition of DNA and the A-Z transition of RNA, we investigated the structure and dynamics of hZαADAR1 in complex with 6-base-pair Z-DNA or Z-RNA. We performed chemical shift perturbation and relaxation dispersion experiments on hZαADAR1 upon binding to Z-DNA as well as Z-RNA. Our study demonstrates the unique dynamics of hZαADAR1 during the A-Z transition of RNA, in which the hZαADAR1 protein forms a thermodynamically stable complex with Z-RNA, similar to Z-DNA, but kinetically converts RNA to the Z-form more slowly than DNA. We also discovered some distinct structural features of hZαADAR1 in the Z-RNA binding conformation. Our results suggest that the A-Z transition of RNA facilitated by hZαADAR1 displays unique structural and dynamic features that may be involved in targeting ADAR1 for a role in recognition of RNA substrates.

Structural and dynamics study of DNA dodecamer duplexes that contain un-, hemi-, or fully methylated GATC sites.

Methylation of DNA plays a regulatory role in DNA metabolism. The Escherichia coli DNA adenine methyltransferase methylates the N6 positions of adenines in the sequence 5'-GATC-3', which exists in the fully methylated state during most of the cell cycle. Just after DNA replication, however, the GATC sites transiently become hemimethylated, a condition that is indispensable for various cellular processes, such as negative modulation of replication initiation at oriC by SeqA. The lack of structural and dynamic information on DNA duplexes that contain fully methylated GATC sites makes it difficult to explain how hemimethylated GATC sites are recognized in vivo by proteins in a sea of fully methylated ones. Here, we used NMR spectroscopy to characterize the solution structure of a dodecamer DNA duplex that contained a fully methylated GATC site and the dynamics of the unmethylated, hemimethylated, and fully methylated GATC duplexes. Only the hemimethylated GATC duplex displays a unique major groove conformation, which is optimized for entrance into the cleft structure of SeqA. The apparent equilibrium constants for base-pair opening of the three differentially methylated GATC duplexes revealed that N6-methylation of the adenine residue affects the thermodynamics and kinetics of its own and neighboring base pairs. The equilibrium constants for base-pair opening of three GATC duplexes were determined using proton exchange catalyzed by TRIS. The two G.C base pairs of the hemimethylated GATC duplex displayed a faster base-pair opening rate and required less energy for the base-pair opening reaction than did those of the fully methylated one.