Transcriptional repressor CopR: Structure model-based localization of the deoxyribonucleic acid binding motif

Steinmetzer, Katrin; Hillisch, Alexander; Behlke, Joachim; Brantl, Sabine

doi:10.1002/(sici)1097-0134(20000301)38:4<393::aid-prot5>3.0.co;2-h

Cited by 17 publications

(19 citation statements)

References 41 publications

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“…The steps involved in the prediction of protein structure by homology modeling. Structure modeling of the bacterial transcriptional repressor CopR is shown [28]. Although the model is based on a low-sequence identity of only 13.8% between CopR and the P22 c2 repressor, several experimental methods support this homology model.…”

Section: Experimental Protein Structure Information and The Sequence-mentioning

confidence: 96%

“…Typically, the amino acids that are to be modified in these studies are selected on the basis of sequence alignments by focusing on conserved residues. However, if at least some structure information is available, the selection of the amino acids that are to be mutated can be much more precise and successful [28]. This approach is even more powerful when applied in conjunction with pharmacologically active compounds.…”

Section: Structure-guided Design Of Mutagenesis Experimentsmentioning

confidence: 99%

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Utility of homology models in the drug discovery process

Hillisch

Pineda

Hilgenfeld

2004

Drug Discovery Today

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276

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Advances in bioinformatics and protein modeling algorithms, in addition to the enormous increase in experimental protein structure information, have aided in the generation of databases that comprise homology models of a significant portion of known genomic protein sequences. Currently, 3D structure information can be generated for up to 56% of all known proteins. However, there is considerable controversy concerning the real value of homology models for drug design. This review provides an overview of the latest developments in this area and includes selected examples of successful applications of the homology modeling technique to pharmaceutically relevant questions. In addition, the strengths and limitations of the application of homology models during all phases of the drug discovery process are discussed.

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Section: Experimental Protein Structure Information and The Sequence-mentioning

confidence: 96%

Section: Structure-guided Design Of Mutagenesis Experimentsmentioning

confidence: 99%

Utility of homology models in the drug discovery process

Hillisch

Pineda

Hilgenfeld

2004

Drug Discovery Today

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276

176

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“…2), termed KS9, had been analyzed previously (28) and was found to be bound at least as efficiently as the wild-type sequence. Our three-dimensional model of the N-terminal 63 amino acids of CopR (30) predicts that this nucleotide position in binding site I is contacted by R34 of the recognition helix (Fig. 2) and that the contact would be stronger with a C instead of a T.…”

Section: Resultsmentioning

confidence: 97%

“…Furthermore, it was found that CopR binds exclusively as a dimer, and the equilibrium dissociation constants for the CopR dimers and the CopR-DNA complex were calculated to be 0.4 nM and 1.4 M, respectively (29). A three-dimensional model of the Nterminal 63 amino acids of CopR was built and was used to identify amino acids involved in DNA binding and dimerization (30,31,32). By this means, it was found that amino acids R29 and R34, located in the recognition helix (helix III) of the helix-turn-helix motif, make specific contacts to the DNA at G240 (binding site I) and G254 (binding site II) or G242/T243 (site I) and G251 (site II), respectively.…”

mentioning

confidence: 99%

“…Water-mediated contacts were suggested for E35 interacting with the outermost C residues in both binding sites. Unspecific DNA contacts via the sugar-phosphate backbone were proposed for K10 in ␣-helix I and S28 in the recognition helix (30). Furthermore, it was established that the structured acidic C terminus of CopR that forms a ␤-strand is necessary for stabilization of the protein (22,23).…”

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confidence: 99%

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Transcriptional Repressor CopR: Use of SELEX To Study the copR Operator Indicates that Evolution Was Directed at Maximal Binding Affinity

Freede

Brantl

2004

J Bacteriol

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CopR is one of the two copy number control elements of the streptococcal plasmid pIP501. It represses transcription of the repR mRNA encoding the essential replication initiator protein about 10-to 20-fold by binding to its operator region upstream of the repR promoter pII. CopR binds at two consecutive sites in the major groove of the DNA that share the consensus motif 5-CGTG. Previously, the minimal operator was narrowed down to 17 bp, and equilibrium dissociation constants for DNA binding and dimerization were determined to be 0.4 nM and 1.4 M, respectively. In this work, we used a SELEX procedure to study copR operator sequences of different lengths in combination with electrophoretic mobility shift assays of mutated copR operators as well as copy number determinations to assess the sequence requirements for CopR binding. The results suggest that in vivo evolution was directed at maximal binding affinity. Three simultaneous nucleotide exchanges outside the bases directly contacted by CopR only slightly affected CopR binding in vitro or copy numbers in vivo. Furthermore, the optimal spacer sequence was found to comprise 7 bp, to be AT rich, and to need an A/T and a T at the 3 positions, whereas broad variations in the sequences flanking the minimal 17-bp operator were well tolerated.Replication of the streptococcal plasmid pIP501 is regulated by two components that act in concert: the transcriptional repressor CopR (10.6 kDa) and the antisense RNA RNAIII (136 nucleotides [nt]) (5). Whereas RNAIII exerts its inhibitory effect by premature termination (attenuation) of the essential repR mRNA (6, 8), CopR has a dual function. On the one hand, it represses transcription from the essential repR promoter pII about 10-to 20-fold (7); on the other hand, it prevents convergent transcription from pII and pIII (antisense promoter), thereby indirectly increasing transcription initiation at pIII (9). Previously, it was found that CopR contacts the DNA asymmetrically at two consecutive major grooves that share the consensus motif 5Ј-CGTG (28). Thus, the outermost G residues were found to be most important for CopR binding, whereas exchanges of nucleotides adjacent (3Ј) to the CGTG motif only slightly altered DNA binding. The operator sequence was narrowed down to 17 bp. Furthermore, it was found that CopR binds exclusively as a dimer, and the equilibrium dissociation constants for the CopR dimers and the CopR-DNA complex were calculated to be 0.4 nM and 1.4 M, respectively (29). A three-dimensional model of the Nterminal 63 amino acids of CopR was built and was used to identify amino acids involved in DNA binding and dimerization (30,31,32). By this means, it was found that amino acids R29 and R34, located in the recognition helix (helix III) of the helix-turn-helix motif, make specific contacts to the DNA at G240 (binding site I) and G254 (binding site II) or G242/T243 (site I) and G251 (site II), respectively. Water-mediated contacts were suggested for E35 interacting with the outermost C residues in both binding sites. ...

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Transcriptional repressor CopR: Amino acids involved in forming the dimeric interface

Steinmetzer

Hillisch²,

Behlke

et al. 2000

Proteins

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Plasmid pIP501 encoded transcriptional repressor CopR is one of the two regulators of plasmid copy number. It acts as a transcriptional repressor at the essential repR promoter. Furthermore, CopR prevents convergent transcription from the repR and the antisense promoter, thereby indirectly increasing the amount of antisense-RNA, the second regulatory component. CopR binds as a dimer to a nearly palindromic operator with the consensus sequence 5'CGTG. Previously, a CopR structural model was built and used to identify amino acids involved in DNA binding. These data showed that CopR is a HTH protein belonging to the lambda repressor superfamily and allowed the identification of two amino acids involved in specific DNA recognition. Here, we describe site-directed mutagenesis in combination with EMSA, dimerization studies using sedimentation equilibrium, and CD measurements to verify the model predictions concerning amino acids involved in dimerization. With this approach, the dimeric interface could be located between amino acids I44 and L62. F5 located at the N-terminus is additionally required for proper folding, and could, therefore, not be unequivocally assigned to the dimeric interface. CD measurements at protein concentrations well below K(Dimer) revealed that the monomer of CopR is folded.

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Transcriptional repressor CopR: Structure model-based localization of the deoxyribonucleic acid binding motif

Cited by 17 publications

References 41 publications

Utility of homology models in the drug discovery process

Utility of homology models in the drug discovery process

Transcriptional Repressor CopR: Use of SELEX To Study the copR Operator Indicates that Evolution Was Directed at Maximal Binding Affinity

Transcriptional repressor CopR: Amino acids involved in forming the dimeric interface

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