PDBsum entry 1bdt

Gene regulation/DNA

PDB id

1bdt

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Contents

			Protein chains

					52 a.a.

			DNA/RNA

			Waters ×83

PDB id:

1bdt

Links

Name:

Gene regulation/DNA

Title:

Wild type gene-regulating protein arc/DNA complex

Structure:

DNA (5'- d( Tp Ap Tp Ap Gp Tp Ap Gp Ap Gp Tp Gp Cp Tp Tp Cp Tp Ap Tp Cp Ap T)- 3'). Chain: e. Engineered: yes. DNA (5'- d( Ap Ap Tp Gp Ap Tp Ap Gp Ap Ap Gp Cp Ap Cp Tp Cp Tp Ap Cp Tp Ap T)- 3'). Chain: f.

Source:

Synthetic: yes. Enterobacteria phage p22. Organism_taxid: 10754. Expressed in: escherichia coli. Expression_system_taxid: 562. Other_details: synthetic gene

Biol. unit:

Dimer (from PDB file)

Resolution:

2.50Å

R-factor:

0.236

R-free:

0.282

Authors:

J.F.Schilbach,A.W.Karzai,B.E.Raumann,R.T.Sauer

Key ref:

J.F.Schildbach et al. (1999). Origins of DNA-binding specificity: role of protein contacts with the DNA backbone. Proc Natl Acad Sci U S A, 96, 811-817. PubMed id: 9927650 DOI: 10.1073/pnas.96.3.811

Date:

11-May-98

Release date:

16-Feb-99

PROCHECK

	Headers

	References

Protein chains

P03050 (RARC_BPP22) - Transcriptional repressor arc from Salmonella phage P22

Seq: Struc:					53 a.a. 52 a.a.

Key:

PfamA domain

Secondary structure

CATH domain

DNA/RNA chains

		T-A-T-A-G-T-A-G-A-G-T-G-C-T-T-C-T-A-T-C-A-T 22 bases
		A-A-T-G-A-T-A-G-A-A-G-C-A-C-T-C-T-A-C-T-A-T 22 bases

DOI no: 10.1073/pnas.96.3.811	Proc Natl Acad Sci U S A 96:811-817 (1999)
PubMed id: 9927650

Origins of DNA-binding specificity: role of protein contacts with the DNA backbone.
J.F.Schildbach, A.W.Karzai, B.E.Raumann, R.T.Sauer.

ABSTRACT

A central question in protein-DNA recognition is the origin of the specificity that permits binding to the correct site in the presence of excess, nonspecific DNA. In the P22 Arc repressor, the Phe-10 side chain is part of the hydrophobic core of the free protein but rotates out to pack against the sugar-phosphate backbone of the DNA in the repressor-operator complex. Characterization of a library of position 10 variants reveals that Phe is the only residue that results in fully active Arc. One class of mutants folds stably but binds operator with reduced affinity; another class is unstable. FV10, one member of the first class, binds operator DNA and nonoperator DNA almost equally well. The affinity differences between FV10 and wild type indicate that each Phe-10 side chain contributes 1.5-2.0 kcal to operator binding but less than 0.5 kcal/mol to nonoperator binding, demonstrating that contacts between Phe-10 and the operator DNA backbone contribute to binding specificity. This appears to be a direct contribution as the crystal structure of the FV10 dimer is similar to wild type and the Phe-10-DNA backbone interactions are the only contacts perturbed in the cocrystal structure of the FV10-operator complex.

Selected figure(s)



	Figure 4. Fig. 4. Superimposition of the protein and DNA backbones from the protein-DNA cocrystal structures of wild-type Arc (yellow) and the FV10 mutant (orange). The wild-type Phe-10 side chains and mutant Val-10 side chains are shown in ball-and-stick representation.		Figure 5. Fig. 5. The base-contact residues, Gln-9 and Asn-11, have similar conformations in the wild-type Arc (Right) and FV10 (Left) cocrystal structures. Residues from the Arc B subunit are shown, and the electron density (1 ) is from simulated-annealing omit maps.

Figures were selected by an automated process.

Literature references that cite this PDB file's key reference

PubMed id

Reference

20010837

A.Sabogal, A.Y.Lyubimov, J.E.Corn, J.M.Berger, and D.C.Rio (2010).
THAP proteins target specific DNA sites through bipartite recognition of adjacent major and minor grooves.

Nat Struct Mol Biol, 17, 117-123.

PDB code:

3kde

20144952

S.Campagne, O.Saurel, V.Gervais, and A.Milon (2010).
Structural determinants of specific DNA-recognition by the THAP zinc finger.

Nucleic Acids Res, 38, 3466-3476.

PDB code:

2ko0

19535331

F.Guillière, N.Peixeiro, A.Kessler, B.Raynal, N.Desnoues, J.Keller, M.Delepierre, D.Prangishvili, G.Sezonov, and J.I.Guijarro (2009).
Structure, function, and targets of the transcriptional regulator SvtR from the hyperthermophilic archaeal virus SIRV1.

J Biol Chem, 284, 22222-22237.

PDB code:

2kel

19720035

J.Vertrees, J.O.Wrabl, and V.J.Hilser (2009).
An energetic representation of protein architecture that is independent of primary and secondary structure.

Biophys J, 97, 1461-1470.

18478582

P.Poulain, A.Saladin, B.Hartmann, and C.Prévost (2008).
Insights on protein-DNA recognition by coarse grain modelling.

J Comput Chem, 29, 2582-2592.

17001030

J.D.Larson, J.L.Jenkins, J.P.Schuermann, Y.Zhou, D.F.Becker, and J.J.Tanner (2006).
Crystal structures of the DNA-binding domain of Escherichia coli proline utilization A flavoprotein and analysis of the role of Lys9 in DNA recognition.

Protein Sci, 15, 2630-2641.

PDB codes:

2ay0 2gpe

16484205

M.J.Wilson, and I.L.Lamont (2006).
Mutational analysis of an extracytoplasmic-function sigma factor to investigate its interactions with RNA polymerase and DNA.

J Bacteriol, 188, 1935-1942.

16820531

M.van Dijk, A.D.van Dijk, V.Hsu, R.Boelens, and A.M.Bonvin (2006).
Information-driven protein-DNA docking using HADDOCK: it is a matter of flexibility.

Nucleic Acids Res, 34, 3317-3325.

16698786

S.L.Moors, M.Hellings, M.De Maeyer, Y.Engelborghs, and A.Ceulemans (2006).
Tryptophan rotamers as evidenced by X-ray, fluorescence lifetimes, and molecular dynamics modeling.

Biophys J, 91, 816-823.

16224104

A.Maiti, and S.Roy (2005).
Switching DNA-binding specificity by unnatural amino acid substitution.

Nucleic Acids Res, 33, 5896-5903.

15723352

A.Popescu, A.Karpay, D.A.Israel, R.M.Peek, and A.M.Krezel (2005).
Helicobacter pylori protein HP0222 belongs to Arc/MetJ family of transcriptional regulators.

Proteins, 59, 303-311.

PDB code:

1x93

16164413

K.Welfle, F.Pratto, R.Misselwitz, J.Behlke, J.C.Alonso, and H.Welfle (2005).
Role of the N-terminal region and of beta-sheet residue Thr29 on the activity of the omega2 global regulator from the broad-host range Streptococcus pyogenes plasmid pSM19035.

Biol Chem, 386, 881-894.

15190131

A.B.de la Hoz, F.Pratto, R.Misselwitz, C.Speck, W.Weihofen, K.Welfle, W.Saenger, H.Welfle, and J.C.Alonso (2004).
Recognition of DNA by omega protein from the broad-host range Streptococcus pyogenes plasmid pSM19035: analysis of binding to operator DNA with one to four heptad repeats.

Nucleic Acids Res, 32, 3136-3147.

15070749

M.Bakkali, T.Y.Chen, H.C.Lee, and R.J.Redfield (2004).
Evolutionary stability of DNA uptake signal sequences in the Pasteurellaceae.

Proc Natl Acad Sci U S A, 101, 4513-4518.

14995651

R.Murugan (2004).
DNA-protein interactions under random jump conditions.

Phys Rev E Stat Nonlin Soft Matter Phys, 69, 011911.

14622405

A.P.Golovanov, D.Barillà, M.Golovanova, F.Hayes, and L.Y.Lian (2003).
ParG, a protein required for active partition of bacterial plasmids, has a dimeric ribbon-helix-helix structure.

Mol Microbiol, 50, 1141-1153.

PDB code:

1p94

11867477

D.C.Daniel, M.Thompson, and N.W.Woodbury (2002).
DNA-binding interactions and conformational fluctuations of Tc3 transposase DNA binding domain examined with single molecule fluorescence spectroscopy.

Biophys J, 82, 1654-1666.

10698941

A.Ramos, S.Grünert, J.Adams, D.R.Micklem, M.R.Proctor, S.Freund, M.Bycroft, D.St Johnston, and G.Varani (2000).
RNA recognition by a Staufen double-stranded RNA-binding domain.

EMBO J, 19, 997.

PDB code:

1ekz

10886361

M.Oda, and H.Nakamura (2000).
Thermodynamic and kinetic analyses for understanding sequence-specific DNA recognition.

Genes Cells, 5, 319-326.

10322039

M.N.Alekshun, and S.B.Levy (1999).
Characterization of MarR superrepressor mutants.

J Bacteriol, 181, 3303-3306.

The most recent references are shown first. Citation data come partly from CiteXplore and partly from an automated harvesting procedure. Note that this is likely to be only a partial list as not all journals are covered by either method. However, we are continually building up the citation data so more and more references will be included with time. Where a reference describes a PDB structure, the PDB code is shown on the right.