Secondary literature sources for Zalpha
The following references were automatically generated.
- Schwartz T, Behlke J, Lowenhaupt K, Heinemann U, Rich A
- Structure of the DLM-1-Z-DNA complex reveals a conserved family of Z-DNA-binding proteins.
- Nat Struct Biol. 2001; 8: 761-5
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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.
- Ford H Jr et al.
- Adenosine deaminase prefers a distinct sugar ring conformation for binding and catalysis: kinetic and structural studies.
- Biochemistry. 2000; 39: 2581-92
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Several recent X-ray crystal structures of adenosine deaminase (ADA) in complex with various adenosine surrogates have illustrated the preferred mode of substrate binding for this enzyme. To define more specific structural details of substrate preferences for binding and catalysis, we have studied the ADA binding efficiencies and deamination kinetics of several synthetic adenosine analogues in which the furanosyl ring is biased toward a particular conformation. NMR solution studies and pseudorotational analyses were used to ascertain the preferred furanose ring puckers (P, nu(MAX)) and rotamer distributions (chi and gamma) of the nucleoside analogues. It was shown that derivatives which are biased toward a "Northern" (3'-endo, N) sugar ring pucker were deaminated up to 65-fold faster and bound more tightly to the enzyme than those that preferred a "Southern" (2'-endo, S) conformation. This behavior, however, could be modulated by other structural factors. Similarly, purine riboside inhibitors of ADA that prefer the N hemisphere were more potent inhibitors than S analogues. These binding propensities were corroborated by detailed molecular modeling studies. Docking of both N- and S-type analogues into the ADA crystal structure coordinates showed that N-type substrates formed a stable complex with ADA, whereas for S-type substrates, it was necessary for the sugar pucker to adjust to a 3'-endo (N-type) conformation to remain in the ADA substrate binding site. These data outline the intricate structural details for optimum binding in the catalytic cleft of ADA.
- Hakoshima T
- [Crystal structure of Z-DNA binding domain bound to left-handed Z-DNA: outstanding achievement of Alexander Rich]
- Tanpakushitsu Kakusan Koso. 2000; 45: 595-9
- Liu W, Vu HM, Geiduschek EP, Kearns DR
- Solution structure of a mutant of transcription factor 1: implications for enhanced DNA binding.
- J Mol Biol. 2000; 302: 821-30
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An NMR solution structure of a mutant of the homodimer protein transcription factor 1, TF1-G15/I32 (22 kDa), has been solved to atomic resolution, with 23 final structures that converge to an r.m. s.d. of 0.78 A. The overall shape of TF1-G15/I32 remains similar to that of the wild-type protein and other type II DNA-binding proteins. Each monomer has two N-terminal alpha-helices separated by a short loop, followed by a three-stranded beta-sheet, whose extension between the second and third beta-strands forms an antiparallel beta-ribbon arm, leading to a C-terminal third alpha-helix that is severely kinked in the middle. Close examination of the structure of TF1-G15/I32 reveals why it is more stable and binds DNA more tightly than does its wild-type counterpart. The dimeric core, consisting of the N-terminal helices and the beta-sheets, is more tightly packed, and this might be responsible for its increased thermal stability. The DNA-binding domain, composed of the top face of the beta-sheet, the beta-ribbon arms and the C-terminal helices, is little changed from wild-type TF1. Rather, the enhancement in DNA affinity must be due almost exclusively to the creation of an additional DNA-binding site at the side of the dimer by changes affecting helices 1 and 2: helix 2 of TF1-G15/I32 is one residue longer than helix 2 of the wild-type protein, bends inward, and is both translationally and rotationally displaced relative to helix 1. This rearrangement creates a longer, narrower fissure between the V-shaped N-terminal helices and exposes additional positively charged surface at each side of the dimer.
- Chen CS, White A, Love J, Murphy JR, Ringe D
- Methyl groups of thymine bases are important for nucleic acid recognition by DtxR.
- Biochemistry. 2000; 39: 10397-407
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The expression of diphtheria toxin is controlled by the diphtheria toxin repressor (DtxR). Under conditions of high iron concentration, DtxR binds the tox operator to inhibit transcription. To study how DNA binding specificity is achieved by this repressor, we solved the crystal structure of the nickel(II) activated DtxR(C102D) mutant complexed with a 43mer DNA duplex containing the DtxR consensus binding sequence. Structural analysis of this complex and comparison with a previously determined DtxR(C102D)-Ni(II)-tox operator ternary complex revealed unusual van der Waals interactions between Ser37/Pro39 of the repressor helix-turn-helix (HTH) motif and the methyl groups of specific thymine bases in the consensus binding sequence. Gel mobility shift assays utilizing deoxyuridine modified duplex DNA probes proved the importance of these interactions: the four methyl groups shown to interact with Ser37/Pro39 in the crystal structure contribute a total of 3.4 kcal/mol to binding energy. Thus, in addition to making base-specific hydrogen-bonding interactions to the DNA through its Gln43 residue, DtxR also recognizes methyl groups at certain positions in the DNA sequence with its Ser37 and Pro39 side chains, to achieve binding specificity toward its cognate operator sequences.
- Kim YG, Lowenhaupt K, Maas S, Herbert A, Schwartz T, Rich A
- The zab domain of the human RNA editing enzyme ADAR1 recognizes Z-DNA when surrounded by B-DNA.
- J Biol Chem. 2000; 275: 26828-33
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The Zab domain of the editing enzyme ADAR1 binds tightly and specifically to Z-DNA stabilized by bromination or supercoiling. A stoichiometric amount of protein has been shown to convert a substrate of suitable sequence to the Z form, as demonstrated by a characteristic change in the CD spectrum of the DNA. Now we show that Zab can bind not only to isolated Z-forming d(CG)(n) sequences but also to d(CG)(n) embedded in B-DNA. The binding of Zab to such sequences results in a complex including Z-DNA, B-DNA, and two B-Z junctions. In this complex, the d(CG)(n) sequence, but not the flanking region, is in the Z conformation. The presence of Z-DNA was detected by cleavage with a Z-DNA specific nuclease, by undermethylation using Z-DNA sensitive SssI methylase, and by circular dichroism. It is possible that Zab binds to B-DNA with low affinity and flips any favorable sequence into Z-DNA, resulting in a high affinity complex. Alternatively, Zab may capture Z-DNA that exists transiently in solution. The binding of Zab to potential as well as established Z-DNA segments suggests that the range of biological substrates might be wider than previously thought.
- Perez-Alvarado GC, Munnerlyn A, Dyson HJ, Grosschedl R, Wright PE
- Identification of the regions involved in DNA binding by the mouse PEBP2alpha protein.
- FEBS Lett. 2000; 470: 125-30
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The polyomavirus enhancer binding protein 2alpha (PEBP2alpha) is a DNA binding transcriptional regulatory protein that binds conserved sites in the polyomavirus enhancer, mammalian type C retroviral enhancers and T-cell receptor gene enhancers. Binding of PEBP2alpha and homologous proteins to the consensus DNA sequence TGPyGGTPy is mediated through a protein domain known as the runt domain. Although recent NMR studies of DNA-bound forms of the runt domain have shown an immunoglobulin-like (Ig) fold, the identification of residues of the protein that are involved in DNA binding has been obscured by the low solubility of the runt domain. Constructs of the mouse PEBP2alphaA1 gene were generated with N- and C-terminal extensions beyond the runt homology region. The construct containing residues Asp90 to Lys225 of the sequence (PEBP2alpha90-225) yielded soluble protein. The residues that participate in DNA binding were determined by comparing the NMR spectra of free and DNA-bound PEBP2alpha90-225. Analysis of the changes in the NMR spectra of the two forms of the protein by chemical shift deviation mapping allowed the unambiguous determination of the regions that are responsible for specific DNA recognition by PEBP2alpha. Five regions in PEBP2alpha90-225 that are localized at one end of the beta-barrel were found to interact with DNA, similar to the DNA binding interactions of other Ig fold proteins.
- Tang YY et al.
- Biophysical characterization of interactions between the core binding factor alpha and beta subunits and DNA.
- FEBS Lett. 2000; 470: 167-72
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Core binding factors (CBFs) play key roles in several developmental pathways and in human disease. CBFs consist of a DNA binding CBFalpha subunit and a non-DNA binding CBFbeta subunit that increases the affinity of CBFalpha for DNA. We performed sedimentation equilibrium analyses to unequivocally establish the stoichiometry of the CBFalpha:beta:DNA complex. Dissociation constants for all four equilibria involving the CBFalpha Runt domain, CBFbeta, and DNA were defined. Conformational changes associated with interactions between CBFalpha, CBFbeta, and DNA were monitored by nuclear magnetic resonance and circular dichroism spectroscopy. The data suggest that CBFbeta 'locks in' a high affinity DNA binding conformation of the CBFalpha Runt domain.
- Muthuswami R, Truman PA, Mesner LD, Hockensmith JW
- A eukaryotic SWI2/SNF2 domain, an exquisite detector of double-stranded to single-stranded DNA transition elements.
- J Biol Chem. 2000; 275: 7648-55
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Many members of the SWI2/SNF2 family of adenosine triphosphatases participate in the assembly/disassembly of multiprotein complexes involved in the DNA metabolic processes of transcription, recombination, repair, and chromatin remodeling. The DNA molecule serves as an essential effector or catalyst for most of the members of this particular class of proteins, and the structure of the DNA may be more important than the nucleotide sequence. Inspection of the DNA structure at sites where multiprotein complexes are assembled/disassembled for these various DNA metabolic processes reveals the presence of a common element: a double-stranded to single-stranded transition region. We now show that this DNA element is crucial for the ATP hydrolytic function of an SWI2/SNF2 family member: DNA-dependent ATPase A. We further demonstrate that a domain containing the seven helicase-related motifs that are common to the SWI2/SNF2 family of proteins mediates the interaction with the DNA, yielding specific DNA structural recognition. This study forms a primary step toward understanding the physico-biochemical nature of the interaction between a particular class of DNA-dependent ATPase and their DNA effectors. Furthermore, this study provides a foundation for development of mechanisms to specifically target this class of DNA-dependent ATPases.
- Brown BA 2nd, Lowenhaupt K, Wilbert CM, Hanlon EB, Rich A
- The zalpha domain of the editing enzyme dsRNA adenosine deaminase binds left-handed Z-RNA as well as Z-DNA.
- Proc Natl Acad Sci U S A. 2000; 97: 13532-6
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The Zalpha domain of human double-stranded RNA adenosine deaminase 1 binds specifically to left-handed Z-DNA and stabilizes the Z-conformation. Here we report spectroscopic and analytical results that demonstrate that Zalpha can also stabilize the left-handed Z-conformation in double-stranded RNA. Zalpha induces a slow transition from the right-handed A-conformation to the Z-form in duplex r(CG)(6), with an activation energy of 38 kcal mol(-1). We conclude that Z-RNA as well as Z-DNA can be accommodated in the tailored binding site of Zalpha. The specific binding of Z-RNA by Zalpha may be involved in targeting double-stranded RNA adenosine deaminase 1 for a role in hypermutation of RNA viruses.
- Herbert A, Rich A
- Left-handed Z-DNA: structure and function.
- Genetica. 1999; 106: 37-47
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Z-DNA is a high energy conformer of B-DNA that forms in vivo during transcription as a result of torsional strain generated by a moving polymerase. An understanding of the biological role of Z-DNA has advanced with the discovery that the RNA editing enzyme double-stranded RNA adenosine deaminase type I (ADAR1) has motifs specific for the Z-DNA conformation. Editing by ADAR1 requires a double-stranded RNA substrate. In the cases known, the substrate is formed by folding an intron back onto the exon that is targeted for modification. The use of introns to direct processing of exons requires that editing occurs before splicing. Recognition of Z-DNA by ADAR1 may allow editing of nascent transcripts to be initiated immediately after transcription, ensuring that editing and splicing are performed in the correct sequence. Structural characterization of the Z-DNA binding domain indicates that it belongs to the winged helix-turn-helix class of proteins and is similar to the globular domain of histone-H5.
- Bianchi A, de Lange T
- Ku binds telomeric DNA in vitro.
- J Biol Chem. 1999; 274: 21223-7
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Ku is a heterodimeric protein with high binding affinity for ends, nicks, and gaps in double-stranded DNA. Both in mammalian cells and in budding yeast, Ku plays a role in nonhomologous end joining in the double strand break repair pathway. However, Ku has a more significant role in DNA repair in mammalian cells compared with yeast, in which a homology-dependent pathway is the predominant one. Recently Ku has been shown to be a likely component of the telomeric complex in yeast, suggesting the possibility of a similar role for Ku at mammalian telomeres. However, long single-stranded G-rich overhangs are continuously present at mammalian but not at yeast telomeres. These overhangs have the potential to fold in vitro into G-G base-paired conformations, such as G-quartets, that might prevent Ku from recognizing telomeric ends and thus offer a mechanism to sequester the telomere from the prevalent double strand break repair pathway in mammals. We show here that Ku binds to mammalian telomeric DNA ends in vitro and that G-quartet conformations are unable to prevent Ku from binding with high affinity to the DNA. Our results indicate that the DNA binding characteristics of Ku are consistent with its direct interaction with telomeric DNA in mammalian cells and its proposed role as a telomere end factor.
- Schwartz T et al.
- Proteolytic dissection of Zab, the Z-DNA-binding domain of human ADAR1.
- J Biol Chem. 1999; 274: 2899-906
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Zalpha is a peptide motif that binds to Z-DNA with high affinity. This motif binds to alternating dC-dG sequences stabilized in the Z-conformation by means of bromination or supercoiling, but not to B-DNA. Zalpha is part of the N-terminal region of double-stranded RNA adenosine deaminase (ADAR1), a candidate enzyme for nuclear pre-mRNA editing in mammals. Zalpha is conserved in ADAR1 from many species; in each case, there is a second similar motif, Zbeta, separated from Zalpha by a more divergent linker. To investigate the structure-function relationship of Zalpha, its domain structure was studied by limited proteolysis. Proteolytic profiles indicated that Zalpha is part of a domain, Zab, of 229 amino acids (residues 133-361 in human ADAR1). This domain contains both Zalpha and Zbeta as well as a tandem repeat of a 49-amino acid linker module. Prolonged proteolysis revealed a minimal core domain of 77 amino acids (positions 133-209), containing only Zalpha, which is sufficient to bind left-handed Z-DNA; however, the substrate binding is strikingly different from that of Zab. The second motif, Zbeta, retains its structural integrity only in the context of Zab and does not bind Z-DNA as a separate entity. These results suggest that Zalpha and Zbeta act as a single bipartite domain. In the presence of substrate DNA, Zab becomes more resistant to proteases, suggesting that it adopts a more rigid structure when bound to its substrate, possibly with conformational changes in parts of the protein.
- Provvedi R, Dubnau D
- ComEA is a DNA receptor for transformation of competent Bacillus subtilis.
- Mol Microbiol. 1999; 31: 271-80
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Competent cells of Bacillus subtilis efficiently bind and internalize DNA. ComEA and the seven proteins encoded by the comG operon are required in vivo for the binding step. We show here that ComEA, a bitopic membrane protein, is itself capable of high-affinity DNA binding. A domain necessary for DNA binding is located at the C-terminus of ComEA. Proteins with similar 60-80 amino acid residue domains are widespread among bacteria and higher organisms. ComEA shows a marked preference for double-stranded DNA and can bind to oligomers as small as 22 bp in length. DNA binding by ComEA exhibits no apparent base sequence specificity. Using a membrane vesicle DNA-binding assay system we show that in the absence of cell wall, ComEA is still required for DNA binding, whereas the requirement for the ComG proteins is bypassed. We conclude that the ComG proteins are needed in vivo to provide access of the binding domain of ComEA to exogenous DNA. Possible specific roles for the ComG proteins are discussed.
- Gruschus JM, Tsao DH, Wang LH, Nirenberg M, Ferretti JA
- The three-dimensional structure of the vnd/NK-2 homeodomain-DNA complex by NMR spectroscopy.
- J Mol Biol. 1999; 289: 529-45
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The three-dimensional solution structure obtained by NMR of the complex formed between the uniformly singly15N and doubly13C/15N-labeled vnd/NK-2 homeodomain and its consensus 16 base-pair DNA binding sequence was determined. This work was carried out using the accepted repertoire of experiments augmented with a novel implementation of the water flipback technique to enhance signals from exchangeable amide protons. The results using this new technique confirm the existence of hydrogen bonding between the invariant Asn51 and the second adenine of the DNA binding sequence, as seen in crystal structures of other homeodomain-DNA complexes, but never before detected by NMR. Hydrogen bonding by Arg5 and Lys3 in the minor groove of the DNA appears to be responsible for two unusually upfield-shifted ribose H1' resonances. The DNA duplex is nearly straight and its structure is primarily that of B -DNA. A detailed comparison is presented for all available homeodomain-DNA structures including the vnd/NK-2 DNA complex, which demonstrates that homology is maintained in the protein structure, whereas for the orientation of the homeodomain relative to DNA, small but significant variations are observed. Interactions are described involving certain residues in specific positions of the homeodomain, namely Leu7, Thr41, and Gln50 of vnd/NK-2, where single amino acid residue mutations lead to dramatic developmental alterations. The availability of our previously determined three- dimensional structure of the vnd/NK-2 homeodomain in the absence of DNA allows us to assess structural changes in the homeodomain induced by DNA binding.
- Connolly KM, Wojciak JM, Clubb RT
- Resonance assignments of the Tn916 integrase DNA-binding domain and the integrase:DNA complex.
- J Biomol NMR. 1999; 14: 95-6
- Schade M, Turner CJ, Lowenhaupt K, Rich A, Herbert A
- Structure-function analysis of the Z-DNA-binding domain Zalpha of dsRNA adenosine deaminase type I reveals similarity to the (alpha + beta) family of helix-turn-helix proteins.
- EMBO J. 1999; 18: 470-9
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RNA editing alters pre-mRNA through site-selective adenosine deamination, which results in codon changes that lead to the production of novel proteins. An enzyme that catalyzes this reaction, double-stranded RNA adenosine deaminase (ADAR1), contains two N-terminal Z-DNA-binding motifs, Zalpha and Zbeta, the function of which is as yet unknown. In this study, multidimensional NMR spectroscopy was used to show that the topology of Zalpha is alpha1beta1alpha2alpha3beta2beta3. Long-range NOEs indicate that beta1 and beta3 interact with each other. Site-directed mutagenesis was used to identify residues in alpha3, beta3 and the loop connecting beta2 to beta3 that affect Z-DNA binding. Also identified were 11 hydrophobic residues that are essential for protein stability. Comparison with known structures reveals some similarity between Zalpha and (alpha + beta) helix-turn-helix proteins, such as histone 5 and the family of hepatocyte nuclear factor-3 winged-helix-turn-helix transcription factors. Taken together, the structural and functional data suggest that recognition of Z-DNA by Zalpha involves residues in both the alpha3 helix and the C-terminal beta-sheet.
- Schade M, Behlke J, Lowenhaupt K, Herbert A, Rich A, Oschkinat H
- A 6 bp Z-DNA hairpin binds two Z alpha domains from the human RNA editing enzyme ADAR1.
- FEBS Lett. 1999; 458: 27-31
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The Z alpha domain of the human RNA editing enzyme double-stranded RNA deaminase I (ADAR1) binds to left-handed Z-DNA with high affinity. We found by analytical ultracentrifugation and CD spectroscopy that two Z alpha domains bind to one d(CG)3T4(CG)3 hairpin which contains a stem of six base pairs in the Z-DNA conformation. Both wild-type Z alpha and a C125S mutant show a mean dissociation constant of 30 nM as measured by surface plasmon resonance and analytical ultracentrifugation. Our data suggest that short (> or = 6 bp) segments of Z-DNA within a gene are able to recruit two ADAR1 enzymes to that particular site.
- Huang X, Pieczko ME, Long EC
- Combinatorial optimization of the DNA cleaving Ni(II) x Xaa-Xaa-His metallotripeptide domain.
- Biochemistry. 1999; 38: 2160-6
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A positional-scanning combinatorial protocol was employed to optimize the deoxyribose-based cleavage of B-form DNA by Ni(II) x Xaa-Xaa-His metallopeptides. This procedure employed 18 naturally occurring amino acids (excluding Cys and Trp) to generate two libraries in which the first and second positions of the peptide ligand were varied. Increased direct DNA cleavage relative to Ni(II) x Gly-Gly-His was observed when (1) the amino-terminal peptide position contained Pro, Met, Arg, or Lys (with Pro exhibiting the greatest activity) and (2) the second peptide position contained Lys, Arg, Met, Ser, or Thr (with Lys exhibiting the greatest activity); the optimized metallopeptide, Ni(II) x Pro-Lys-His, was found to cleave DNA an order of magnitude better than Ni(II) x Gly-Gly-His. While metal complexation and the A/T-rich site selectivity of the optimized metallopeptides were not altered, DNA binding affinity was slightly increased relative to Ni(II) x Gly-Gly-His, however, not to an extent necessary to account for the observed increase in reactivity. Examination of molecular models of Ni(II) x Pro-Lys-His bound to the minor groove of DNA via hydrogen bonding of the His N3 imidazole hydrogen to the N3 of adenine or O2 of thymine suggests that the Pro residue can make hydrophobic contacts with the sugars lining the walls of the groove while the Lys residue is able to form a salt bridge with a proximal phosphate; with these interactions, the metal center is poised to abstract the C4'-H of an adjacent nucleotide suggesting that noncovalent interactions result in a positioning which contributes to increased DNA cleavage activity.
- Eriksson MA, Nilsson L
- Structural and dynamic differences of the estrogen receptor DNA-binding domain, binding as a dimer and as a monomer to DNA: molecular dynamics simulation studies.
- Eur Biophys J. 1999; 28: 102-11
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Molecular dynamics (MD) simulations of the estrogen receptor DNA-binding domain (ERDBD) as a dimer in complex with its DNA response element (ERE) show a significant difference in both structure and dynamics, compared to a MD simulation of monomeric ERDBD bound to its half-site response element (EREH). The C-terminal zinc binding domain (ZnII), including a region (helix II) which is in a helical conformation in ERE-(ERDBD)2, is considerably more flexible in EREH-ERDBD than in the dimeric complex. In EREH-ERDBD, all helical hydrogen bonds in helix II are broken and the entire ZnII region is detached from a hydrogen bonding network that in ERE-(ERDBD)2 connects to other parts of the protein as well as to the DNA. The regions that become flexible in EREH-ERDBD are identical to the regions where the NMR solution structure of free ERDBD is poorly ordered. This strongly suggests that dimerisation of ERDBD is required for ordering of the ZnII region and that monomeric binding to DNA is not sufficient for the ordering. This contrasts to the glucocorticoid receptor DNA-binding domain (GRDBD) which has essentially the same mobility (uniform and limited), regardless of whether it is free as a monomer in solution, bound as a monomer to its half-site response element or in a dimeric complex with the full response element. The hydrogen bonding network that connects ZnII with other parts of the protein and to DNA is almost identical in ERDBD and GRDBD. However, in GRDBD there is also a serine (in the N-terminal zinc coordinating region) with a central role in this network, connecting to the ZnII region. This serine is replaced by a glycine in ERDBD and we suggest that this substitution is sufficient for destabilisation of the network, thus leading to a more flexible ZnII region, which becomes ordered first upon forming a complex with another ERDBD and DNA.
- Liu Y, Emeson RB, Samuel CE
- Serotonin-2C receptor pre-mRNA editing in rat brain and in vitro by splice site variants of the interferon-inducible double-stranded RNA-specific adenosine deaminase ADAR1.
- J Biol Chem. 1999; 274: 18351-8
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The interferon-inducible RNA-specific adenosine deaminase (ADAR1) is an RNA editing enzyme implicated in the site-selective deamination of adenosine to inosine in cellular pre-mRNAs. The pre-mRNA for the rat serotonin-2C receptor (5-HT2CR) possesses four editing sites (A, B, C, and D), which undergo A-to-I nucleotide conversions that alter the signaling function of the encoded G-protein-coupled receptor. Measurements of 5-HT2CR pre-mRNA editing in vitro revealed site-specific deamination catalyzed by ADAR1. Three splice site variants, ADAR1-a, -b, and -c, all efficiently edited the A site of 5-HT2CR pre-mRNA, but the D site did not serve as an efficient substrate for any of the ADAR1 variants. Mutational analysis of the three double-stranded (ds) RNA binding motifs present in ADAR1 revealed a different relative importance of the individual dsRNA binding motifs for deamination of the A site of 5-HT2CR and synthetic dsRNA substrates. Quantitative reverse transcription-polymerase chain reaction analyses demonstrated that the 5-HT2CR pre-mRNA was most highly expressed in the choroid plexus of rat brain. However, ADAR1 and the related deaminase ADAR2 showed significant expression in all regions of the brain examined, including cortex, hippocampus, olfactory bulb, and striatum, where the 5-HT2CR pre-mRNA was extensively edited.
- Jin C, Marsden I, Chen X, Liao X
- Dynamic DNA contacts observed in the NMR structure of winged helix protein-DNA complex.
- J Mol Biol. 1999; 289: 683-90
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Genesis is an HNF-3/fkh homologous protein. By using multi-dimensional NMR techniques, we have obtained the solution structure and backbone dynamics of Genesis complexed with a 17 base-pair DNA. Our results indicate that both the local folding and dynamic properties of Genesis are perturbed when it binds to the DNA site. Our data show that a conserved flexible amino acid sequence (wing 1) makes dynamic contacts to DNA in the complex and a short helix is induced by Genesis-DNA interactions. Our data indicate that, unlike the HNF-3gamma/DNA complex, a magnesium ion is not required in forming the stable Genesis-DNA complex.
- Jones S, van Heyningen P, Berman HM, Thornton JM
- Protein-DNA interactions: A structural analysis.
- J Mol Biol. 1999; 287: 877-96
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A detailed analysis of the DNA-binding sites of 26 proteins is presented using data from the Nucleic Acid Database (NDB) and the Protein Data Bank (PDB). Chemical and physical properties of the protein-DNA interface, such as polarity, size, shape, and packing, were analysed. The DNA-binding sites shared common features, comprising many discontinuous sequence segments forming hydrophilic surfaces capable of direct and water-mediated hydrogen bonds. These interface sites were compared to those of protein-protein binding sites, revealing them to be more polar, with many more intermolecular hydrogen bonds and buried water molecules than the protein-protein interface sites. By looking at the number and positioning of protein residue-DNA base interactions in a series of interaction footprints, three modes of DNA binding were identified (single-headed, double-headed and enveloping). Six of the eight enzymes in the data set bound in the enveloping mode, with the protein presenting a large interface area effectively wrapped around the DNA.A comparison of structural parameters of the DNA revealed that some values for the bound DNA (including twist, slide and roll) were intermediate of those observed for the unbound B-DNA and A-DNA. The distortion of bound DNA was evaluated by calculating a root-mean-square deviation on fitting to a canonical B-DNA structure. Major distortions were commonly caused by specific kinks in the DNA sequence, some resulting in the overall bending of the helix. The helix bending affected the dimensions of the grooves in the DNA, allowing the binding of protein elements that would otherwise be unable to make contact. From this structural analysis a preliminary set of rules that govern the bending of the DNA in protein-DNA complexes, are proposed.
- Xu HE, Rould MA, Xu W, Epstein JA, Maas RL, Pabo CO
- Crystal structure of the human Pax6 paired domain-DNA complex reveals specific roles for the linker region and carboxy-terminal subdomain in DNA binding.
- Genes Dev. 1999; 13: 1263-75
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Pax6, a transcription factor containing the bipartite paired DNA-binding domain, has critical roles in development of the eye, nose, pancreas, and central nervous system. The 2.5 A structure of the human Pax6 paired domain with its optimal 26-bp site reveals extensive DNA contacts from the amino-terminal subdomain, the linker region, and the carboxy-terminal subdomain. The Pax6 structure not only confirms the docking arrangement of the amino-terminal subdomain as seen in cocrystals of the Drosophila Prd Pax protein, but also reveals some interesting differences in this region and helps explain the sequence specificity of paired domain-DNA recognition. In addition, this structure gives the first detailed information about how the paired linker region and carboxy-terminal subdomain contact DNA. The extended linker makes minor groove contacts over an 8-bp region, and the carboxy-terminal helix-turn-helix unit makes base contacts in the major groove. The structure and docking arrangement of the carboxy-terminal subdomain of Pax6 is remarkably similar to that of the amino-terminal subdomain, and there is an approximate twofold symmetry axis relating the polypeptide backbones of these two helix-turn-helix units. Our structure of the Pax6 paired domain-DNA complex provides a framework for understanding paired domain-DNA interactions, for analyzing mutations that map in the linker and carboxy-terminal regions of the paired domain, and for modeling protein-protein interactions of the Pax family proteins.
- Lu J et al.
- The structure and dynamics of rat apo-cellular retinol-binding protein II in solution: comparison with the X-ray structure.
- J Mol Biol. 1999; 286: 1179-95
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The structure and dynamics of rat apo-cellular retinol binding protein II (apo-CRBP II) in solution has been determined by multidimensional NMR analysis of uniformly enriched recombinant rat 13C, 15N-apo-CRBP II and 15N-apo-CRBP II. The final ensemble of 24 NMR structures has been calculated from 3274 conformational restraints or 24.4 restraints/residue. The average root-mean-square deviation of the backbone atoms for the final 24 structures relative to their mean structure is 1.06 A. Although the average solution structure is very similar to the crystal structure, it differs at the putative entrance to the binding cavity, which is formed by the helix-turn-helix motif, the betaC-betaD turn and the betaE-betaF turn. The mean coordinates of the main-chain atoms of amino acid residues 28-38 are displaced in the solution structure relative to the crystal structure. The side-chain of F58, located on the betaC-betaD turn, is reoriented such that it interacts with L37 and no longer blocks entry into the ligand-binding pocket. Residues 28-35, which form the second helix of the helix-turn-helix motif in the crystal structure, do not exhibit a helical conformation in the solution structure. The solution structure of apo-CRBP II exhibits discrete regions of backbone disorder which are most pronounced at residues 28-32, 37-38 and 73-76 in the betaE-betaF turn as evaluated by the consensus chemical shift index, the root-mean-square deviation, amide 1H exchange rates and 15N relaxation studies. These studies indicate that fluctuations in protein conformation occur on the microseconds to ms time-scale in these regions of the protein. Some of these exchange processes can be directly observed in the three-dimensional 15N-resolved NOESY spectrum. These results suggest that in solution, apo-CRBP II undergoes conformational changes on the microseconds to ms time-scale which result in increased access to the binding cavity.
- Esposito D, Craigie R
- HIV integrase structure and function.
- Adv Virus Res. 1999; 52: 319-33
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HIV integrase consists of three domains, the structures of which have been individually determined by X-ray crystallography or NMR spectroscopy. The core domain, spanning residues 50-212, is responsible for the catalytic activity of the enzyme. The crystal structure of a dimer of this domain shows similarity to other proteins that carry out polynucleotidyl transfer, including MuA transposase and RNase H. The small N-terminal domain folds into a dimeric helix-turn-helix structure, which is stabilized by the coordination of zinc with conserved His and Cys residues. The function of this domain is unclear; however, it is required for integration activity and enhances tetramerization in the context of the full-length integrase. The C-terminal domain, which has an SH3-like fold, is involved in DNA binding. The structure of this domain reveals a large saddle-shaped cleft that is formed by dimerization. This cleft contains a number of positively charged residues, and its dimensions are appropriate for accommodating a double-stranded DNA helix. Although the C-terminal domain was originally believed to be involved in target DNA binding, more recent evidence suggests that it may bind to both the ends of the viral DNA and to the target DNA. Although the individual domain structures provide some insights into the function of the protein, a more detailed understanding of the complete mechanism by which integrase binds, cleaves, and transfers DNA requires a greater knowledge of how these domains are arranged in the active multimer.
- Pohl E, Holmes RK, Hol WG
- Crystal structure of a cobalt-activated diphtheria toxin repressor-DNA complex reveals a metal-binding SH3-like domain.
- J Mol Biol. 1999; 292: 653-67
- Display abstract
The diphtheria toxin repressor (DtxR) is the prototype of a family of iron-dependent regulator (IdeR) proteins, which are activated by divalent iron and bind DNA to prevent the transcription of downstream genes. In Corynebacterium diphtheriae, DtxR regulates not only the expression of diphtheria toxin encoded by a corynebacteriophage, but also of components of the siderophore-mediated iron-transport system. Here we report the crystal structure of wild-type DtxR, a 226 residue three-domain dimeric protein, activated by cobalt and bound to a 21 bp DNA duplex based on the consensus operator sequence. Two DtxR dimers surround the DNA duplex which is distorted compared to canonical B -DNA. The SH3-like third domain interacts with the metal at site 1 via the side-chains of Glu170 and Gln173, revealing for the first time a metal-binding function for this class of domains. The SH3-like domain is also in contact with the DNA-binding first domain and with the second, or dimerization, domain. The DNA-binding helices in the first domain are shifted by 3 to 5 A when compared to the apo-repressor, and fit into the major groove of the duplex bound. These shifts are due to a hinge-binding motion of the DNA-binding domain with respect to the dimerization domains of DtxR. The third domain might play a role in regulating this hinge motion.
- Jin C, Liao X
- Backbone dynamics of a winged helix protein and its DNA complex at different temperatures: changes of internal motions in genesis upon binding to DNA.
- J Mol Biol. 1999; 292: 641-51
- Display abstract
The dynamic properties of a winged helix protein, Genesis, and its DNA complex at different temperatures were studied. Due to the complexity of motions, the commonly used model-free formalism could not be used to reflect the dynamic properties. The reduced spectral density function mapping approach was proven to be a useful tool to describe the overall and internal motion of molecules on the picosecond to nanosecond time-scale, and conformational exchanges on the microsecond to millisecond time-scale. The local motions in DNA-free Genesis showed strong temperature dependence and the backbone dynamics of each secondary structural element responds to the temperature change differently, while the Genesis-DNA complex showed more stability with changing the temperatures. Furthermore, each DNA contact sequence of Genesis showed distinct dynamic perturbation after Genesis binds to DNA.
- Namgoong SY, Sankaralingam S, Harshey RM
- Altering the DNA-binding specificity of Mu transposase in vitro.
- Nucleic Acids Res. 1998; 26: 3521-7
- Display abstract
We describe the isolation of a variant of Mu transposase (MuA protein) which can recognize altered att sites at the ends of Mu DNA. No prior knowledge of the structure of the DNA binding domain or its mode of interaction with att DNA was necessary to obtain this variant. Protein secondary structure programs initially helped target mutations to predicted helical regions within a subdomain of MuA demonstrated to harbor att DNA binding activity. Of the 54 mutant positions examined, only two showed decreased affinity for att DNA, while eight others affected assembly of the Mu transpososome. A variant impaired in DNA binding [MuA(R146V)], and predicted to be in the recognition helix of an HTH motif, was challenged with altered att sites created from degenerate oligonucleotides to select for novel DNA binding specificity. DNA sequences bound to MuA(R146V) were detected by gel-retardation, and following several steps of PCR amplification/enrichment, were identified by cloning and sequencing. The strategy allowed recovery of an altered att site for which MuA(R146V) showed higher affinity than for the wild-type site, although this site was bound by wild-type MuA as well. The altered association between MuA(R146V) and an altered att site target was competent in transposition. We discuss the strengths and limitations of this methodology, which has applications in dissecting the functional role of specific protein-DNA associations.
- Liu Y, Herbert A, Rich A, Samuel CE
- Double-stranded RNA-specific adenosine deaminase: nucleic acid binding properties.
- Methods. 1998; 15: 199-205
- Display abstract
The RNA-specific adenosine deaminase (ADAR1, herein referred to as ADAR) is an interferon-inducible RNA-editing enzyme. ADAR catalyzes the C-6 deamination of adenosine in double-stranded (ds) structures present in viral RNAs and cellular pre-mRNAs as well as synthetic dsRNA substrates. ADAR possesses three functionally distinct copies of the highly conserved double-stranded RNA binding R motif (RI, RII, RIII) implicated in the recognition of dsRNA structures within the substrate RNAs. ADAR is also a Z-DNA-binding protein. Two Z-DNA binding motifs (Zalpha and Zbeta) present in ADAR correspond to repeated regions homologous to the N-terminal region of the vaccinia virus E3L protein. Here we describe assay methods for measurement of ADAR enzymatic activity, dsRNA binding activity, and Z-DNA binding activity.
- Dempsey LA, Hanakahi LA, Maizels N
- A specific isoform of hnRNP D interacts with DNA in the LR1 heterodimer: canonical RNA binding motifs in a sequence-specific duplex DNA binding protein.
- J Biol Chem. 1998; 273: 29224-9
- Display abstract
The B cell-specific, sequence-specific duplex DNA-binding protein LR1 is a transcriptional activator and may also function in heavy chain class switch recombination. LR1 is composed of two polypeptides, a 106-kDa subunit that is nucleolin, and a 45-kDa subunit that we now show to be a specific isoform of hnRNP D. hnRNP D and nucleolin both contain canonical RNA binding domains (RBDs also called RRMs) and Arg-Gly-Gly (RGG) motifs. Although these motifs are not commonly associated with sequence-specific recognition of duplex DNA, nonetheless LR1 binds duplex DNA with high affinity (KD = 1.8 nM) and clear sequence specificity. Two RBD-RGG proteins can therefore combine to produce a sequence-specific duplex DNA-binding protein.
- Gao YG et al.
- The crystal structure of the hyperthermophile chromosomal protein Sso7d bound to DNA.
- Nat Struct Biol. 1998; 5: 782-6
- Display abstract
Sso7d and Sac7d are two small (approximately 7,000 Mr), but abundant, chromosomal proteins from the hyperthermophilic archaeabacteria Sulfolobus solfataricus and S. acidocaldarius respectively. These proteins have high thermal, acid and chemical stability. They bind DNA without marked sequence preference and increase the Tm of DNA by approximately 40 degrees C. Sso7d in complex with GTAATTAC and GCGT(iU)CGC + GCGAACGC was crystallized in different crystal lattices and the crystal structures were solved at high resolution. Sso7d binds in the minor groove of DNA and causes a single-step sharp kink in DNA (approximately 60 degrees) by the intercalation of the hydrophobic side chains of Val 26 and Met 29. The intercalation sites are different in the two complexes. Observations of this novel DNA binding mode in three independent crystal lattices indicate that it is not a function of crystal packing.
- Cai M et al.
- Solution structure of the cellular factor BAF responsible for protecting retroviral DNA from autointegration.
- Nat Struct Biol. 1998; 5: 903-9
- Display abstract
The solution structure of the human barrier-to-autointegration factor, BAF, a 21,000 Mr dimer, has been solved by NMR, including extensive use of dipolar couplings which provide a priori long range structural information. BAF is a highly evolutionarily conserved DNA binding protein that is responsible for inhibiting autointegration of retroviral DNA, thereby promoting integration of retroviral DNA into the host chromosome. BAF is largely helical, and each subunit is composed of five helices. The dimer is elongated in shape and the dimer interface comprises principally hydrophobic contacts supplemented by a single salt bridge. Despite the absence of any sequence similarity to any other known protein family, the topology of helices 3-5 is similar to that of a number of DNA binding proteins, with helices 4 and 5 constituting a helix-turn-helix motif. A model for the interaction of BAF with DNA that is consistent with structural and mutagenesis data is proposed.
- Connolly KM, Wojciak JM, Clubb RT
- Site-specific DNA binding using a variation of the double stranded RNA binding motif.
- Nat Struct Biol. 1998; 5: 546-50
- Display abstract
The integrase family of site-specific recombinases catalyze a diverse array of DNA rearrangements in archaebacteria, eubacteria and yeast. The solution structure of the DNA binding domain of the integrase protein from the conjugative transposon Tn916 has been determined using NMR spectroscopy. The structure provides the first insights into distal site DNA binding by a site-specific integrase and reveals that the N-terminal domain is structurally similar to the double stranded RNA binding domain (dsRBD). The results of chemical shift mapping experiments suggest that the integrase protein interacts with DNA using residues located on the face of its three stranded beta-sheet. This surface differs from the proposed RNA binding surface in dsRBDs, suggesting that different surfaces on the same protein fold can be used to bind DNA and RNA.
- Hosmane RS, Hong M
- How important is the N-3 sugar moiety in the tight-binding interaction of coformycin with adenosine deaminase?
- Biochem Biophys Res Commun. 1997; 236: 88-93
- Display abstract
Preliminary findings on the possible important role of the N-3 sugar moiety of coformycin in its tight-binding interaction with adenosine deaminase (ADA) are reported. The compound 3-beta-D-Ribofuranosyl-5,6,7,8-tetrahydro-4H-imidazo[4,5-d][1,3]diaze pin-5-one-8-ol (1), its 3-benzyl analogue (6), and the aglycon (7) served as probes. The first two were both found to be competitive inhibitors of ADA with Ki's in the range of 10(-5) M, while the last one was inactive.
- Groziak MP, Huan ZW, Ding H, Meng Z, Stevens WC, Robinson PD
- Effect of a chemical modification on the hydrated adenosine intermediate produced by adenosine deaminase and a model reaction for a potential mechanism of action of 5-aminoimidazole ribonucleotide carboxylase.
- J Med Chem. 1997; 40: 3336-45
- Display abstract
Using the hydrated adenosine intermediate (6R)-6-amino-1, 6-dihydro-6-hydroxy-9-(beta-D-ribofuranosyl)purine (2) produced by adenosine deaminase (ADA, EC 3.5.4.4) as a starting point, the active site probe and inhibitor platform 5-(formylamino)imidazole riboside (FAIRs, 4) was designed by removal of the-C6(OH)(NH2)-molecular fragment of 2 generated by the early events of the enzyme-catalyzed hydrolysis. FAIRs was synthesized directly from the sodium salt of 5-amino-1-(beta-D-ribofuranosyl)imidazole-4-carboxylic acid (CAIR) along a reaction sequence involving a tandem N-formylation/decarboxylation that may have a mechanistic connection to the Escherichia coli purE-catalyzed constitutional isomerization of N5-CAIR to CAIR. The physical and spectral properties of FAIRs were elucidated, its X-ray crystal and NMR solution structures were determined, and its interaction with ADA was investigated. Crystalline FAIRs exists solely as the Z-formamide rotamer and exhibits many of the same intramolecular hydrogen bonding events known to contribute to the association of Ado to ADA. In water and various organic solvents, however, FAIRs exists as NMR-distinct, slowly interconverting Z and E rotamers. This truncated enzymatic tetrahedral intermediate analog was determined to be a competitive inhibitor of ADA with an apparent Ki binding constant of 40 microM, a value quite close to that (33 microM) of the natural substrate's K(m). The actual species selected for binding by ADA, though, is likely the minor hydroxyimino prototropic form of Z-FAIRs possessing a far lower true Ki value. As the structural features of FAIRs appear well-suited to support its use as a template for constructing active site probes of both ADA and AIR carboxylases, a variety of carbohydrate-protected versions of FAIRs suitable for facile aglycon elaborations were synthesized. The N3-alkylation, N3-borane complexation, and C4-iodination of some of these were investigated in order to assess physicochemical properties that may assist in the elucidation of mechanisms for the AIR carboxylases. The survey of these properties taken together with a reasonable mechanism for the model CAIRs-->FAIRs synthetic transformation is interpreted to support a mechanism for the purE-catalyzed N5-CAIR-->CAIR biosynthetic one that involves a carboxylative sp3-rehybridization of the imidazole C4 atom rather than one possessing a dipole-stabilized C4 sp2 carbanionic intermediate.
- Sunnerhagen M, Nilges M, Otting G, Carey J
- Solution structure of the DNA-binding domain and model for the complex of multifunctional hexameric arginine repressor with DNA.
- Nat Struct Biol. 1997; 4: 819-26
- Display abstract
The structure of the monomeric DNA-binding domain of the Escherichia coli arginine repressor, ArgR, determined by NMR spectroscopy, shows structural homology to the winged helix-turn-helix (wHTH) family, a motif found in a diverse class of proteins including both gene regulators and gene organizers from prokaryotes and eukaryotes. Biochemical data on DNA binding by intact ArgR are used as constraints to position the domain on its DNA target and to derive a model for the hexamer-DNA complex using the known structure of the L-arginine-binding domain. The structural independence of the wHTH fold may be important for multimeric DNA-binding proteins that contact extended DNA regions with imperfect match to consensus sequences, a feature of many wHTH-domain proteins.
- Kim YG, Kim PS, Herbert A, Rich A
- Construction of a Z-DNA-specific restriction endonuclease.
- Proc Natl Acad Sci U S A. 1997; 94: 12875-9
- Display abstract
Novel restriction enzymes can be created by fusing the nuclease domain of FokI endonuclease with defined DNA binding domains. Recently, we have characterized a domain (Z alpha) from the N-terminal region of human double-stranded RNA adenosine deaminase (hADAR1), which binds the Z-conformation with high specificity. Here we report creation of a conformation-specific endonuclease, Z alpha nuclease, which is a chimera of Z alpha and FokI nuclease. Purified Z alpha nuclease cleaves negatively supercoiled plasmids only when they contain a Z-DNA forming insert, such as (dC-dG)13. The precise location of the cleavage sites was determined by primer extension. Cutting has been mapped to the edge of the B-Z junction, suggesting that Z alpha nuclease binds within the Z-DNA insert, but cleaves in the nearby B-DNA, by using a mechanism similar to type IIs restriction enzymes. These data show that Z alpha binds Z-DNA in an environment similar to that in a cell. Z alpha nuclease, a structure-specific restriction enzyme, may be a useful tool for further study of the biological role of Z-DNA.
- Cooper BF et al.
- The role of divalent cations in structure and function of murine adenosine deaminase.
- Protein Sci. 1997; 6: 1031-7
- Display abstract
For murine adenosine deaminase, we have determined that a single zinc or cobalt cofactor bound in a high affinity site is required for catalytic function while metal ions bound at an additional site(s) inhibit the enzyme. A catalytically inactive apoenzyme of murine adenosine deaminase was produced by dialysis in the presence of specific zinc chelators in an acidic buffer. This represents the first production of the apoenzyme and demonstrates a rigorous method for removing the occult cofactor. Restoration to the holoenzyme is achieved with stoichiometric amounts of either Zn2+ or Co2+ yielding at least 95% of initial activity. Far UV CD and fluorescence spectra are the same for both the apo- and holoenzyme, providing evidence that removal of the cofactor does not alter secondary or tertiary structure. The substrate binding site remains functional as determined by similar quenching measured by tryptophan fluorescence of apo- or holoenzyme upon mixing with the transition state analog, deoxycoformycin. Excess levels of adenosine or N6- methyladenosine incubated with the apoenzyme prior to the addition of metal prevent restoration, suggesting that the cofactor adds through the substrate binding cleft. The cations Ca2+, Cd2+, Cr2+, Cu+, Cu2+, Mn2+, Fe2+, Fe3+, Pb2+, or Mg2+ did not restore adenosine deaminase activity to the apoenzyme. Mn2+, Cu2+, and Zn2+ were found to be competitive inhibitors of the holoenzyme with respect to substrate and Cd2+ and Co2+ were noncompetitive inhibitors. Weak inhibition (Ki > or = 1000 microM) was noted for Ca2+, Fe2+, and Fe3+.
- Kim Jm, DasSarma S
- Isolation and chromosomal distribution of natural Z-DNA-forming sequences in Halobacterium halobium.
- J Biol Chem. 1996; 271: 19724-31
- Display abstract
Conditions favoring left-handed Z-DNA such as high salinity (> 4 ), high negative DNA supercoiling, and GC-rich DNA [statistically favoring d(CG)n repeat sequences], are all found in the extremely halophilic archaeum (archaebacterium) Halobacterium halobium. In order to identify and study Z-DNA regions of the H. halobium genome, an affinity chromatography method with high Z-DNA selection efficiency was developed. Supercoiled plasmids were incubated with a Z-DNA-specific antibody (Z22) and passed over a protein A-agarose column, and the bound plasmids were eluted using an ethidium bromide gradient. In control experiments using mixtures of pUC12 (Z-negative) and a d(CG)5-containing (Z-positive) pUC12 derivative, up to 4,000-fold enrichment of the Z-DNA-containing plasmid was demonstrated per cycle of the Z-DNA selection procedure. The selection efficiency was determined by transformation of Escherichia coli DH5alpha with eluted plasmids and blue-white screening on X-gal plates. Twenty recombinant plasmids containing Z-DNA-forming sequences of H. halobium were isolated from a genomic library using affinity chromatography. Z-DNA-forming sequences in selected plasmids were identified by bandshift and antibody footprinting assays using Z22 monoclonal antibody. Alternating purine-pyrimidine sequences ranging from 8 base pairs (bp) to 13 bp with at least a 6-bp alternating d(GC) stretch were found in the Z22 antibody binding regions of isolated plasmids. The distribution of Z-DNA-forming sequences in the Halobacterium salinarum GRB chromosome was analyzed by dot-blot hybridization of an ordered cosmid library using the cloned H. halobium Z-DNA segments as probe. Among the 11 Z-DNA segments tested, five were found to be clustered in a 100-kilobase pair region of the genome, whereas six others were distributed throughout the rest of the genome.
- Herbert A, Rich A
- The biology of left-handed Z-DNA.
- J Biol Chem. 1996; 271: 11595-8
- Pervushin K, Billeter M, Siegal G, Wuthrich K
- Structural role of a buried salt bridge in the 434 repressor DNA-binding domain.
- J Mol Biol. 1996; 264: 1002-12
- Display abstract
The independently folding 63-residue N-terminal DNA-binding domain of the 434 repressor, 434(1-63), contains a buried Arg10-Glu35 salt bridge. A corresponding salt bridge is found in a variety of prokaryotic and eukaryotic DNA-binding proteins with helix-turn-helix motifs. Here, the NMR solution structures of 434(1-63) and the mutant protein 434[R10M](1-63) were determined to investigate the structural role of this salt bridge. Both proteins contain the same type of global fold, with five alpha-helices and a helix-turn-helix motif formed by the helices II and III. The primary structural difference caused by the Arg10 --> Met mutation is a translation of helix I along its axis relative to the helix II-turn-helix III motif. This limited conformational change is paralleled by a 9 kJ M(-1) decrease of the stability of the folded mutant protein in aqueous solution at pH 4.8. It affects the pKa value of Glu19 as well as the population of a hydrogen bond between the backbone amide proton of Asn16 and the side-chain carboxylate group of Glu19. Using the crystal structure of the 434 repressor dimer complexed with the operator DNA as a basis, model building of the DNA complex with the NMR structure of 434[R10M](1-63) shows that Asn16, which is located on the protein surface, makes direct contact with the DNA and indicates that the point mutation Arg10 --> Met should also lead to modifications of the protein-protein contacts in the complex.
- Sideraki V, Wilson DK, Kurz LC, Quiocho FA, Rudolph FB
- Site-directed mutagenesis of histidine 238 in mouse adenosine deaminase: substitution of histidine 238 does not impede hydroxylate formation.
- Biochemistry. 1996; 35: 15019-28
- Display abstract
His 238, a conserved amino acid located in hydrogen-bonding distance from C-6 of the substrate in the active site of murine adenosine deaminase (mADA) and postulated to play an important role in catalysis, was altered into an alanine, a glutamate, and an arginine using site-directed mutagenesis. The Ala and Glu substitutions did not result in changes of the secondary or tertiary structure, while the Arg mutation caused local perturbations in tertiary structure and quenched the emission of one or more enzyme tryptophans. Neither the Glu or Arg mutations affected substrate binding affinity. By contrast, the Ala mutation enhanced substrate and inhibitor binding by 20-fold. The most inactive of the mutants, Glu 238, had a kcat/K(m) 4 x 10(-6) lower than the wild-type value, suggesting that a positive charge on His 238 is important for proper catalytic function. The Ala 238 mutant was the most active ADA, with a kcat/K(m) 2 x 10(-3) lower than the wild-type value. NMR spectroscopy and crystallography revealed that this mutant is able to catalyze hydration of purine riboside, a ground-state analog of the reaction. These results collectively show that His 238 is not required for formation of the hydroxylate used in the deamination and may instead have an important electrostatic role.
- Shih P, Wolfenden R
- Enzyme-substrate complexes of adenosine and cytidine deaminases: absence of accumulation of water adducts.
- Biochemistry. 1996; 35: 4697-703
- Display abstract
Adenosine deaminase has been reported to bind the product inosine (the substrate for the reverse reaction) as inosine 1,6-hydrate considered similar in structure to the transition state for adenosine deamination (Wilson & Quiocho, 1994) Accumulation on the enzyme of inosine 1,6-hydrate would be surprising, because this compound is an actual intermediate, probably approaching the transition state, in oxygen exchange between water and the C==O group of inosine, a reaction previously shown to be catalyzed by adenosine deaminase (Wolfenden & Kirsch, 1968). The equilibrium constant for conversion of ES to ES*, in the oxygen exchange reaction, is less than 10-12. To investigate the structure of enzyme-bound inosine in a different way, we labeled deoxyinosine with 13C, excepting an upfield shift of 70-110 ppm if significant rehybridization to sp3 had occurred at the carbonyl group. Instead, the results show a very small shift (1.3 ppm), indicating that C-6 of 2'-deoxyinosine retains its sp2 hybridization after binding by calf intestinal adenosine deaminase. In a separate series of experiments, [4,5-13C]-2'-deoxyuridine was synthesized and found to retain its sp2 hybridization at C-4, after binding by Escherichia coli cytidine deaminase, an enzyme that catalyzes 18O exchange from water into uridine. These findings are consistent with the general expectation, based on the unfavorable equilibrium of activation of enzyme-bound substrates, that enzymes should not accumulate appreciable concentrations of intermediates whose free energies approach that of the transition state in substrate transformation.
- Marrone TJ, Straatsma TP, Briggs JM, Wilson DK, Quiocho FA, McCammon JA
- Theoretical study of inhibition of adenosine deaminase by (8R)-coformycin and (8R)-deoxycoformycin.
- J Med Chem. 1996; 39: 277-84
- Display abstract
Molecular dynamics and free energy simulations were performed to examine the binding of (8R)-deoxycoformycin and (8R)-coformycin to adenosine deaminase. The two inhibitors differ only at the 2' position of the sugar ring; the sugar moiety of conformycin is ribose, while it is deoxyribose for deoxycoformycin. The 100 ps molecular dynamics trajectories reveal that Asp 19 and His 17 interact strongly with the 5' hydroxyl group of the sugar moiety of both inhibitors and appear to play an important role in binding the sugar. The 2' and 3' groups of the sugars are near the protein-water interface and can be stabilized by either protein residues or water. The flexibility of the residues at the opening of the active site helps to explain the modest difference in binding of the two inhibitors and how substrates/inhibitors can enter an otherwise inaccessible binding site.
- Howell ML, Schroth GP, Ho PS
- Sequence-dependent effects of spermine on the thermodynamics of the B-DNA to Z-DNA transition.
- Biochemistry. 1996; 35: 15373-82
- Display abstract
Spermine has been shown to bind to and stabilize a number of altered DNA conformations, including left-handed Z-DNA. Here, we have quantitatively studied the effects of spermine on the negative supercoil-induced transition from B- to Z-DNA. We have determined the intrinsic association constants for and the effective number of ligands that bind to both B- and Z-DNA. The intrinsic affinity of spermine for Z-DNA is approximately 10 times higher for d(CA/TG) (KZP = 1.2 x 10(8) M-1) than for d(CG) dinucleotides (KZP = 1.5 x 10(7) M-1), and both are greater than that for B-DNA (KBP = 1.4 x 10(5) M-1). This accounts for the stabilization of Z-DNA by spermine. The number of spermine accommodated by Z-DNA (nZ) is sequence-dependent [nZ = 0.6 spermine per 18 d(CA/TG) dinucleotides and 2.3 for 12 d(CG) dinucleotides]. The value of nZ of < 1 was interpreted as evidence for negative cooperativity in spermine binding to d(CA/TG) dinucleotides. Thus, although d(CA/TG) sequences saturate at lower spermine concentrations, the ligand has an overall greater effect on the stability of d(CG) dinucleotides as Z-DNA. B-DNA accommodates more spermines per base pair than either sequence as Z-DNA. At higher concentrations (> 10 microM), spermine destabilizes Z-DNA. Using these parameters in a model for competitive spermine binding to B-DNA and Z-DNA, we can make predictions for how potential Z-DNA sequences found in the human genome are affected by cellular levels of superhelical density and spermine.
- Carter CW Jr
- The nucleoside deaminases for cytidine and adenosine: structure, transition state stabilization, mechanism, and evolution.
- Biochimie. 1995; 77: 92-8
- Display abstract
Enzymatic deamination of cytidine and adenosine bases in RNA have recently been shown to be mechanisms for changing the coding specificity of messenger and transfer RNAs. The structures of the enzymes that carry out deamination of the corresponding nucleosides have been analyzed by X-ray crystallography. They are quite different from one another in most respects, including quaternary and tertiary structure, but they have similar chemical groups in their active sites. Both enzymes envelope their nucleoside substrates completely, perhaps accounting for the fact that they are inactive on RNA substrates. Much has been learned about catalytic mechanisms from the structures of the enzymes and their complexes with transition state analog inhibitors. Catalysis proceeds with the activation by zinc of a bound water molecule, presumably to hydroxide ion, which attacks the appropriate carbon to generate a tetrahedral intermediate. The detailed stereochemistry of the two resulting chiral centers is diastereoisomeric. Details of the ensuing proton transfer steps necessary to generate and release the products are also apparently different in the two enzymes. Thus, the active site similarities are probably the result of convergent evolution.
- Herbert AG, Rich A
- A method to identify and characterize Z-DNA binding proteins using a linear oligodeoxynucleotide.
- Nucleic Acids Res. 1993; 21: 2669-72
- Display abstract
An oligodeoxynucleotide that readily flips to the Z-DNA conformation in 10mM MgCl2 was produced by using Klenow enzyme to incorporate 5-bromodeoxycytosine and deoxyguanosine into a (dC-dG)22 template. During synthesis the oligomer can be labeled with 32P to high specific activity. The labeled oligodeoxynucleotide can be used in bandshift experiment to detect proteins that bind Z-DNA. This allows the binding specificity of such proteins to be determined with high reliability using unlabeled linear and supercoiled DNA competitors. In addition, because the radioactive oligodeoxynucleotide contains bromine atoms, DNA-protein complexes can be readily crosslinked using UV light. This allows an estimate to be made of the molecular weight of the proteins that bind to the radioactive probe. Both techniques are demonstrated using a goat polyclonal anti-Z-DNA antiserum.
- Dzingeleski GD, Wolfenden R
- Hypersensitivity of an enzyme reaction to solvent water.
- Biochemistry. 1993; 32: 9143-7
- Display abstract
The hydrolytic activity of calf intestinal adenosine deaminase is reduced sharply, but reversibly, in the presence of added methanol, ethanol, acetonitrile, or dioxane. This decrease in kcat/Km appears to be related to diminished water content in the presence of each of these cosolvents. No agreement between cosolvents is observed if enzyme activity is plotted as a function of viscosity or dielectric constant; nor do these cosolvents act as conventional reversible inhibitors. The Km value of adenosine and the Ki values of a substrate analogue (6-dimethylaminopurine ribonucleoside) and a powerful competitive inhibitor (6-hydroxy-1,6-dihydropurine ribonucleoside) increase with decreasing solvent water content, but kcat is unaffected. Values of 1/Km and 1/Ki increase with roughly the 9th power of the concentration of water and show no sign of approaching a maximum value as the concentration of water approaches 55 M. These results are consistent with an equilibrium between an abundant, inactive, relatively dehydrated form of the enzyme and a rare, relatively hydrated form of the enzyme. Only the hydrated form of the enzyme, containing at least nine more water molecules than the dehydrated form, appears to be capable of binding substrates or competitive inhibitors. Possible physiological consequences of this behavior, in a tissue in which water is transported in large quantities, are considered.
- Herbert AG, Spitzner JR, Lowenhaupt K, Rich A
- Z-DNA binding protein from chicken blood nuclei.
- Proc Natl Acad Sci U S A. 1993; 90: 3339-42
- Display abstract
A protein (Z alpha) that appears to be highly specific for the left-handed Z-DNA conformer has been identified in chicken blood nuclear extracts. Z alpha activity is measured in a band-shift assay by using a radioactive probe consisting of a (dC-dG)35 oligomer that has 50% of the deoxycytosines replaced with 5-bromodeoxycytosine. In the presence of 10 mM Mg2+, the probe converts to the Z-DNA conformation and is bound by Z alpha. The binding of Z alpha to the radioactive probe is specifically blocked by competition with linear poly(dC-dG) stabilized in the Z-DNA form by chemical bromination but not by B-form poly(dC-dG) or boiled salmon-sperm DNA. In addition, the binding activity of Z alpha is competitively blocked by supercoiled plasmids containing a Z-DNA insert but not by either the linearized plasmid or by an equivalent amount of the parental supercoiled plasmid without the Z-DNA-forming insert. Z alpha can be crosslinked to the 32P-labeled brominated probe with UV light, allowing us to estimate that the minimal molecular mass of Z alpha is 39 kDa.
- Friedman AE, Kumar CV, Turro NJ, Barton JK
- Luminescence of ruthenium(II) polypyridyls: evidence for intercalative binding to Z-DNA.
- Nucleic Acids Res. 1991; 19: 2595-602
- Display abstract
Photophysical studies have been undertaken to characterize the binding interactions of enantiomers of Ru(phen)3(2+), Ru(DIP)3(2+), and racemic Ru(bpy)2dppz2+ (where phen = 1,10-phenanthroline, DIP = 4,7-diphenylphenanthroline, and dppz = dipyridophenazine) with Z-form poly d(GC). Parallel enhancements in steady state luminescent intensity and a lengthening of luminescent lifetimes are seen for ruthenium enantiomers with Z-DNA as for B-DNA but with enantioselectivities reversed. Greater enhancements are seen for delta-isomers with the right-handed helix but for lambda-isomers with the left-handed helix. Ru(bpy)2dppz2+, an avid intercalator in B-DNA, displays no luminescence free in aqueous solution, but luminesces brightly bound to either B- or Z-poly d(GC). Stern-Volmer quenching studies also support the enantioselective preference in binding to B-DNA by delta-isomers and a reversal with binding to Z-DNA preferentially by the lambda-isomers. Steady state polarization studies indicate a rigid association of the complexes with both B- and Z-DNA on the time-scale of their emission and again with symmetrical enantioselectivities for the left and right-handed helices. Given the well characterized intercalative association of the complexes with B-DNA, the parallel results seen here with Z-DNA point strongly to a comparable intercalative association with the Z-form helix. That molecules may interact with Z-DNA through intercalation has not been demonstrated previously and now requires consideration in describing the range of interactions of small molecules and proteins with Z-DNA.
- Geierstanger BH, Kagawa TF, Chen SL, Quigley GJ, Ho PS
- Base-specific binding of copper(II) to Z-DNA. The 1.3-A single crystal structure of d(m5CGUAm5CG) in the presence of CuCl2.
- J Biol Chem. 1991; 266: 20185-91
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The single crystal structure of d(m5CGUAm5CG) soaked with copper(II) chloride was solved to atomic (1.3 A) resolution to study the base specificity of copper binding to double-stranded DNA. In the present copper(II) chloride-soaked structure, four crystallographically unique copper(II) complexes were observed bound to five of the six purine bases in the hexamer duplex. Covalent copper(II) binding occurred at N-7 of all four guanine bases and at one of the two adenine bases in the DNA duplex. Copper binding was not observed at the position (Ade4) located in an open solvent channel, whereas the second adenine site (Ade10) shared a complex with a guanine residue (Gua12) of a neighboring symmetry-related hexamer. The coordination geometries and distribution of these copper(II) complexes at the guanine bases in the crystal were comparable to the analogous sites in the isomorphous copper(II) chloride-soaked d(CGCGCG) crystal (Kagawa, T., Geierstanger, B. H., Wang, A. H.-J., and Ho, P.S. (1991) J. Biol. Chem. 266, 20175-20184). Thus, the decreased copper(II) binding affinity for Ade4 was not an artifact of crystal packing, but is intrinsic to the chemical properties of this purine base in duplex DNA. This suggests that the adenine bases in dilute solutions of Z-DNA and more generally other duplex DNA conformations are not susceptible to copper(II) modification. Thus, preferential copper(II) binding at guanine bases over adenine bases in double-stranded DNA may explain the observed specificity of copper(II)-induced oxidative DNA damage near guanine residues (Yamamoto, K., and Kawanishi, S. (1989) J. Biol. Chem. 264, 15435-15440; Sagripanti, J.-L., and Kraemer, K. H. (1989) J. Biol. Chem. 264, 1729-1734). The sharing of a single copper(II) complex by Ade10 and Gua12 of an adjacent hexamer suggests that additional and perhaps specific DNA-DNA interactions, as may be found in the densely packed environment of the nuclear matrix in the cell, may render N-7 of adenine bases prone to copper(II) modification.
- Kagawa TF, Geierstanger BH, Wang AH, Ho PS
- Covalent modification of guanine bases in double-stranded DNA. The 1.2-A Z-DNA structure of d(CGCGCG) in the presence of CuCl2.
- J Biol Chem. 1991; 266: 20175-84
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We have solved the single crystal structure to 1.2-A resolution of the Z-DNA sequence d(CGCGCG) soaked with copper(II) chloride. This structure allows us to elucidate the structural properties of copper in a model that mimics a physiologically relevant environment. A copper(II) cation was observed to form a covalent coordinate bond to N-7 of each guanine base along the hexamer duplex. The occurrence of copper bound at each site was dependent on the exposure of the bases and the packing of the hexamers in the crystal. The copper at the highest occupied site was observed to form a regular octahedral complex, with four water ligands in the equatorial plane and a fifth water along with N-7 of the purine base at the axial positions. All other copper complexes appear to be variations of this structure. By using the octahedral complex as the prototype for copper(II) binding to guanine bases in the Z-DNA crystal, model structures were built showing that duplex B-DNA can accommodate octahedral copper(II) complexes at the guanine bases as well as copper complexes bridged at adjacent guanine residues by a reactive dioxygen species. The increased susceptibility to oxidative DNA cleavage induced by copper(II) ions in solution of the bases located 5' to one or more adjacent guanine residues can thus be explained in terms of the cation and DNA structures described by these models.
- Krishna P, Kennedy BP, van de Sande JH, McGhee JD
- Yolk proteins from nematodes, chickens, and frogs bind strongly and preferentially to left-handed Z-DNA.
- J Biol Chem. 1988; 263: 19066-70
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Yolk proteins purified from the nematode Caenorhabditis elegans, from the frog Xenopus laevis, and from chicken eggs all have the unexpected property of binding strongly and preferentially to a left-handed Z-DNA probe, brominated poly(dG-dC). We estimate that the nematode proteins bind to Z-DNA with an association constant of at least 10(4) (M-1) and that this association constant is at least 40-50-fold higher than the association constant to B-DNA. Thus, yolk proteins have a higher Z-DNA specificity than most of the Z-DNA binding proteins previously isolated from other sources. Although yolk protein binding to Z-DNA is poorly competed by a wide variety of nucleic acids, the interaction is strongly competed by the phospholipids cardiolipin and phosphatidic acid (500-1000-fold better than by the same mass of B-DNA). We suggest that Z-DNA interacts with the yolk protein phospholipid binding site. In general, our results emphasize the danger of using physical properties to infer biological function. In particular, our results should raise serious questions about the biological relevance of previously isolated Z-DNA binding proteins.
- Basu HS, Feuerstein BG, Zarling DA, Shafer RH, Marton LJ
- Recognition of Z-RNA and Z-DNA determinants by polyamines in solution: experimental and theoretical studies.
- J Biomol Struct Dyn. 1988; 6: 299-309
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Protonated polyamines are among the most efficient cations that induce the left-handed Z-form in certain polynucleotides. It is not known, however, whether these cations bind to specific sites on Z-sequences in solution. We have studied potential polyamine binding sites by measuring the effects of polyamines on the binding of purified immunoglobulins (IgGs) to different regions of the Z-helix and by molecular mechanics modeling. The specific binding of anti-Z-DNA and anti-Z-RNA IgGs to Z-helices was studied as a function of spermidine or spermine concentration. The effect of polyamines on the antibody-nucleic acid interaction was different for IgGs with different specificities for various determinants on the Z-helix. Polyamines inhibit the binding of certain anti-Z IgGs directed against specific sites probably at or near the interface between the major convex surface and the phosphate backbone, most likely by competing with the antibody binding site(s). In contrast, polyamines have no effect on other anti-Z IgGs directed against sites determined by the phosphate backbone. Furthermore, these cations can enhance the binding of anti-Z IgG directed against bulky groups at the C-5 position on the major convex surface of the helix; the enhancement may be related to charge neutralization. Under these conditions, no direct binding of antibodies with polyamines was observed. These data suggest the existence of a specific binding site(s) for polyamines on both Z-DNA and Z-RNA in solution. These binding sites have some similarity to those observed in oligonucleotide crystals by Quigley (in "Molecular Structure and Biological Activity," J.F. Griffin and W.L. Duax, eds., Elsevier, Amsterdam (1982), pp. 317-331). The experimental evidence for specific spermine binding sites on the helical surface was supported by molecular mechanics modeling of the interaction of spermine with the major groove of (dG-dC)5.(dG-dC)5 in both the Z- and B-forms. The crystal coordinates of spermine-containing oligonucleotides in both the B- and Z-forms were used as the starting points for modeling studies. The potential energy of spermine bound to the major convex surface of the Z-form was much less favorable than that of spermine bound to the major groove of the B-form. In the presence of sodium ions, however, the Z-form-spermine complexes were favored over the B-form. Thus, both theoretical and experimental studies indicate that polyamines can specifically recognize Z-helical determinants in solution as well as in crystals.
- Leith IR, Hay RT, Russell WC
- Detection of Z DNA binding proteins in tissue culture cells.
- Nucleic Acids Res. 1988; 16: 8277-89
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A gel electrophoresis DNA binding assay to detect Z DNA binding proteins has been developed utilising [32P] labelled poly [d(G-C)] which was converted to the Z form by incubation in 100 microM Co(NH3)6Cl3. The parameters of the assay were established using a Z DNA antibody as a model system and then applied to extracts of Hela and BHK21 cells. Using an anti-Z DNA antibody conditions were established which allowed resolution of antibody-DNA complexes and free DNA in the presence of 100 microM Co(NH3)6Cl3. The inclusion of unlabelled complementary homopolymers eliminated non-specific binding to the labelled Z-DNA probe. Competition experiments demonstrated that the assay was highly specific for double stranded non-B DNA. Application of the technique to extracts of mammalian cells demonstrated that human and hamster cells contain Z-DNA binding proteins; further characterisation by a blotting technique indicated that a 56,000 molecular weight cell protein preferentially binds Z-DNA.
- Lafer EM, Sousa R, Rosen B, Hsu A, Rich A
- Isolation and characterization of Z-DNA binding proteins from wheat germ.
- Biochemistry. 1985; 24: 5070-6
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The preparation of a heterogeneous non-histone protein extract from wheat germ utilizing Br-poly(dG-dC).poly(dG-dC) (Z-DNA) affinity chromatography is described. The binding characteristics of antibodies against Z-DNA are used as a model system to define important criteria that the DNA binding behavior of a Z-DNA binding protein should display. We show that the wheat germ extract contains DNA binding proteins specific for left-handed Z-DNA by these criteria. The affinity of the proteins measured by competition experiments was approximately 10(5) greater for Br-poly(dG-dC).poly(dG-dC) (Z-DNA) than for poly(dG-dC).poly(dG-dC) (B-DNA). The affinity of the proteins for plasmid DNA increases with increasing negative superhelicity which is known to stabilize Z-DNA. The proteins are shown to compete with Z-DNA antibodies for binding to supercoiled plasmids. Finally, the affinity for two plasmids at a given superhelical density is greater for the plasmid containing an insert known to form Z-DNA than for a plasmid without the insert. The proteins exhibit a 2-3-fold greater affinity for stretches of (dC-dA)n.(dT-dG)n over stretches of (dG-dC)n.(dG-dC)n when both sequences are induced to form Z-DNA by supercoiling.
- Nordheim A, Tesser P, Azorin F, Kwon YH, Moller A, Rich A
- Isolation of Drosophila proteins that bind selectively to left-handed Z-DNA.
- Proc Natl Acad Sci U S A. 1982; 79: 7729-33
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An affinity column for isolating Z-DNA binding proteins was made by attaching brominated poly(dG-dC) to Sephadex. Proteins from Drosophila nuclei were prepared and those that could bind to Escherichia coli B-DNA were removed from the solution. The remaining proteins were passed over the Z-DNA affinity column and then eluted with NaCl. Using both direct and competitive filter binding assays, we found that the eluted proteins bind to brominated poly(dG-dC) (Z-DNA) and poly(dG-m5dC) but not to poly(dG-dC) (B-DNA), native or denatured E. coli or calf thymus DNA, or brominated oligonucleotides. The proteins also bind to negatively supercoiled plasmids carrying Z-DNA sequences but not to relaxed or linearized plasmids in which the Z-DNA conformation is no longer present. Gel analysis reveals a mixture of several large proteins up to approximately 150,000 daltons.
- Mitra CK, Sarma MH, Sarma RH
- Left-handed deoxyribonucleic acid double helix in solution.
- Biochemistry. 1981; 20: 2036-41
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Magnetic shielding constants were calculated for the synthetic deoxyribonucleic acid (DNA) double helix poly(dG-dC).poly(dG-dC) from the x, y, and z coordinates of Z-DNA of Rich and co-workers [Wang, A. H-J., Quigley, G. J., Kolpak, F. J., Crawford, J. L., van Boom, J. H., van der Marel, G., & Rich, A. (1979) Nature (London) 282, 680-686)] and B-DNA of Arnott & Hukins [Arnott, S., & Hukins, D. W. L. (1972) Biochem. Biophys. Res. Commun. 47, 1504-1509], taking into account the contribution to shielding from ring current effects and effects from the diamagnetic and paramagnetic components of the atomic magnetic anisotropy. Comparison of the calculated shielding values with the experimentally observed nuclear magnetic resonance shift data for poly(dG-dC).poly(dG-dC) in high salt solution shows striking agreement for Z-DNA and considerable deviation for B-DNA, indicating that this synthetic DNA double helix is high salt solution can assume the spatial configuration of the left-handed Z-DNA double helix known to occur in crystals.