Structure-based prediction of DNA target sites by regulatory proteins

Kono, Hidetoshi; Sarai, Akinori

doi:10.1002/(sici)1097-0134(19990401)35:1<114::aid-prot11>3.0.co;2-t

Cited by 166 publications

(133 citation statements)

References 64 publications

(99 reference statements)

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“…phate moiety of DNA but also via recognition of a DNA base, especially a guanine (39,40). In this context, it should be noted that the IB-responsive element (5Ј-YCCC-3Ј) of the Lcn2 promoter is abundant in the Lys/Arg-recognizing base guanine in the antisense strand.…”

Section: Discussionmentioning

confidence: 99%

“…Promoter and Not via p50 -It should be noted that the basic residues lysine and arginine are both capable of not only forming a salt bridge with a phosphate group of DNA but also of directly interacting with a base of DNA, especially guanine (39,40). Furthermore, we have shown recently that a cytosine-rich region downstream of the B site is involved in formation of the active three-species complex IBp50-DNA (23), suggesting that the extra-B site makes a direct contact with p50, IB, or both.…”

Section: Lys-717 and Lys-719 In Ank7 Of Ib Participate In Complex Formentioning

confidence: 97%

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The Nuclear Protein IκBζ Forms a Transcriptionally Active Complex with Nuclear Factor-κB (NF-κB) p50 and the Lcn2 Promoter via the N- and C-terminal Ankyrin Repeat Motifs

Kohda

Yamazaki

Sumimoto

2016

Journal of Biological Chemistry

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The nuclear protein IB, comprising the N-terminal transactivation domain and the C-terminal ankyrin repeat (ANK) domain composed of seven ANK motifs, activates transcription of a subset of nuclear factor-B (NF-B)-dependent innate immune genes such as Lcn2 encoding the antibacterial protein lipocalin-2. Lcn2 activation requires formation of a complex containing IB and NF-B p50, a transcription factor that harbors the DNA-binding Rel homology region but lacks a transactivation domain, on the promoter with the canonical NF-Bbinding site (B site) and its downstream cytosine-rich element. Here we show that IB productively interacts with p50 via Asp-451 in the N terminus of ANK1, a residue that is evolutionarily conserved among IB and the related nuclear IB proteins Bcl-3 and IB NS . Threonine substitution for Asp-451 abrogates direct association with the B-site-binding protein p50, complex formation with the Lcn2 promoter DNA, and activation of Lcn2 transcription. The basic residues Lys-717 and Lys-719 in the C-terminal region of ANK7 contribute to IB binding to the Lcn2 promoter, probably via interaction with the cytosinerich element required for Lcn2 activation; glutamate substitution for both lysines results in a loss of transcriptionally active complex formation without affecting direct contact of IB with p50. Both termini of the ANK domain in Bcl-3 and IB NS function in a manner similar to that of IB to interact with promoter DNA, indicating a common mechanism in which the nuclear IBs form a regulatory complex with NF-B and promoter DNA via the invariant aspartate in ANK1 and the conserved basic residues in ANK7. Nuclear factor-B (NF-B)2 plays central roles in host defense and inflammation as a homo-or heterodimer of NF-B/Rel family proteins by controlling the expression of genes for pro-inflammatory cytokines, chemokines, and antibacterial proteins (1-4). The mammalian NF-B family is composed of five structurally related polypeptides: p50, p52, p105 (the precursor of p50), p100 (the precursor of p52), p65 (also known as RelA), RelB, and c-Rel. They share the Rel homology region, which mediates dimerization, nuclear translocation, binding to specific DNA sequences known as NF-B-binding elements (B sites), and association with one of the IB family proteins (1-4). Among the members of the family, p65, RelB, and c-Rel have an ability to activate transcription by themselves via the C-terminal trans-activation domain, which is absent in the smaller p50 and p52 proteins. In resting cells, NF-B dimers are retained in the cytoplasm by associating with a member of the prototypical/cytoplasmic IB proteins including IB␣, IB␤, and IB⑀ (1-4). Cell activation with appropriate stimuli such as bacterial LPS leads to phosphorylation-induced degradation of cytoplasmic IBs and resultant liberation of NF-B dimers (1, 5, 6). The released NF-B dimers subsequently translocate to the nucleus and thus induce the expression of primary response genes via binding to B sites on their promoter/enhancer regions (1-4).The primarily induced gen...

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Section: Discussionmentioning

confidence: 99%

Section: Lys-717 and Lys-719 In Ank7 Of Ib Participate In Complex Formentioning

confidence: 97%

The Nuclear Protein IκBζ Forms a Transcriptionally Active Complex with Nuclear Factor-κB (NF-κB) p50 and the Lcn2 Promoter via the N- and C-terminal Ankyrin Repeat Motifs

Kohda

Yamazaki

Sumimoto

2016

Journal of Biological Chemistry

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“…This result surprised us, as classical models of protein binding to specific sequences in double-stranded DNA highlight hydrogen-bonding interactions between amino acid side chains and the DNA base pairs as determinants of sequence specificity (32,33). Fig.…”

Section: Position-specific Abasic Interference With Dna Religation-mentioning

confidence: 99%

Individual Nucleotide Bases, Not Base Pairs, Are Critical for Triggering Site-specific DNA Cleavage by Vaccinia Topoisomerase

Tian

Sayer

Jerina

et al. 2004

Journal of Biological Chemistry

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Vaccinia DNA topoisomerase forms a covalent DNA-(3-phosphotyrosyl)-enzyme intermediate at a specific target site 5-C ؉5 C ؉4 C ؉3 T ؉2 T ؉1 p2N ؊1 in duplex DNA. Here we study the effects of abasic lesions at individual positions of the scissile and nonscissile strands on the rate of single-turnover DNA transesterification and the cleavage-religation equilibrium. The rate of DNA incision was reduced by factors of 350, 250, 60, and 10 when abasic sites replaced the ؊1N, ؉1T, ؉2T, and ؉4C bases of the scissile strand, but abasic lesions at ؉5C and ؉3C had little or no effect. Abasic lesions in the nonscissile strand in lieu of ؉4G, ؉3G, ؉2A, and ؉1A reduced the rate of cleavage by factors of 130, 150, 10, and 5, whereas abasic lesions at ؉5G and ؊1N had no effect. The striking positional asymmetry of abasic interference on the scissile and nonscissile strands highlights the importance of individual bases, not base pairs, in promoting DNA cleavage. The rate of single-turnover DNA religation by the covalent topoisomerase-DNA complex was insensitive to abasic sites within the CCCTT sequence of the scissile strand, but an abasic lesion at the 5-OH nucleoside (؊1N) of the attacking DNA strand slowed the rate of religation by a factor of 600. Nonscissile strand abasic lesions at ؉1A and ؊1N slowed the rate of religation by factors of ϳ140 and 20, respectively, and strongly skewed the cleavage-religation equilibrium toward the covalent complex. Thus, abasic lesions immediately flanking the cleavage site act as topoisomerase poisons.Poxvirus topoisomerases are exemplary type IB topoisomerase family members; they cleave and rejoin one strand of the DNA duplex through a transient DNA-(3Ј-phosphotyrosyl)-enzyme intermediate. Vaccinia topoisomerase cleaves duplex DNA at a pentapyrimidine target sequence, 5Ј-(T/C)CCTTp2 (1). (The Tp2 nucleotide is defined as the ϩ1 nucleotide.) Topoisomerases encoded by other genera of poxviruses recognize the same DNA target sequence (2-6), despite the large variations in overall G/C contents of the genomes of the different poxvirus genera. Available structural and biochemical studies suggest that the assembly of a catalytically competent topoisomerase active site is triggered by recognition of the 5Ј-CCCTT/3Ј-GGGAA target sequence (7,8).Early studies using nuclease footprinting, modification interference, modification protection, analog substitution, and UV cross-linking techniques suggested that vaccinia topoisomerase makes contact with several nucleotide bases and the sugar-phosphate backbone of DNA within and immediately flanking the CCCTT element (9 -15). Recent studies have focused on delineating the features of the DNA interface that affect the kinetics of transesterification. For example, positionspecific covalent polycyclic aromatic hydrocarbon diol epoxide-DNA adducts have been exploited to probe the minor groove interface (16) and the effects of intercalation at all of the dinucleotides steps spanning the target site (17, 18). The aromatic hydrocarbon adduct studies delineated the ...

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“…The nucleotide sequence specificity of DNA-binding proteins can not be deduced directly from amino acid sequence because the packing, hydrogen-bonding and electrostatic interactions responsible for nucleotide-specific recognition are dependent on the threedimensional structure of the protein-DNA complex 11,12 . While a number of canonical amino acid-nucleotide interaction motifs are observed in protein-DNA interfaces 13 , they are…”

Section: Introductionmentioning

confidence: 99%

Computational redesign of endonuclease DNA binding and cleavage specificity

Ashworth

Havranek

Duarte

et al. 2006

Nature

303

263

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The reprogramming of DNA-binding specificity is an important challenge for computational protein design that tests current understanding of protein-DNA recognition, and has considerable practical relevance for biotechnology and medicine [1][2][3][4][5][6] . Here we describe the computational redesign of the cleavage specificity of the intron-encoded homing endonuclease I-MsoI 7 using a physically realistic atomic-level forcefield 8,9 . Using an in silico screen, we identified single basepair substitutions predicted to disrupt binding by the wild-type enzyme, and then optimized the identities and conformations of clusters of amino acids around each of these unfavourable substitutions using Monte Carlo sampling 10 . A redesigned enzyme that was predicted to display altered target site specificity, while maintaining wild-type binding affinity, was experimentally characterized. The redesigned enzyme binds and cleaves the redesigned recognition site ~10,000 times more effectively than does the wild-type enzyme, with a level of target discrimination comparable to the original endonuclease. Determination of the structure of the redesigned nuclease-recognition site complex by X-ray crystallography confirms the accuracy of the computationally predicted interface. These results suggest that computational protein design methods can have an important role in the creation of novel highly specific endonucleases for gene therapy and other applications.The nucleotide sequence specificity of DNA-binding proteins can not be deduced directly from amino acid sequence because the packing, hydrogen-bonding and electrostatic interactions responsible for nucleotide-specific recognition are dependent on the threedimensional structure of the protein-DNA complex 11,12 . While a number of canonical amino acid-nucleotide interaction motifs are observed in protein-DNA interfaces 13 , they areCorrespondence and requests for materials should be addressed to J.A. (ashwortj@u.washington.edu) or D.B. (dabaker@u.washington.edu). Supplementary Information is linked to the online version of the paper at www.nature.com/nature. Author Contributions J.J.H. and C.M.D. developed the original protein-DNA interface design methods and code. J.A. made further code and method developments, generated and assessed the computational predictions, and performed mutagenesis, biochemical characterization, and crystallization. D.S. collected and processed the crystallographic data, and aided in protein purification and structure refinement. I-MsoI, which belongs to the LAGLIDADG family of homing endonucleases, is a 170-residue homodimeric enzyme that cleaves long target sites (20-24 base pairs (bp)) with considerable specificity 7,15,16 . The homing endonucleases provide an excellent model system for understanding protein-DNA interaction specificity, as well as starting points for engineering of novel specificities for targeted genomics applications, including gene therapy 4,5 . Crystal structures of the enzymes bound to their recognition sites reveal a rich ...

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Structure-based prediction of DNA target sites by regulatory proteins

Cited by 166 publications

References 64 publications

The Nuclear Protein IκBζ Forms a Transcriptionally Active Complex with Nuclear Factor-κB (NF-κB) p50 and the Lcn2 Promoter via the N- and C-terminal Ankyrin Repeat Motifs

The Nuclear Protein IκBζ Forms a Transcriptionally Active Complex with Nuclear Factor-κB (NF-κB) p50 and the Lcn2 Promoter via the N- and C-terminal Ankyrin Repeat Motifs

Individual Nucleotide Bases, Not Base Pairs, Are Critical for Triggering Site-specific DNA Cleavage by Vaccinia Topoisomerase

Computational redesign of endonuclease DNA binding and cleavage specificity

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