PDBsum entry 1tlh

Transcription

PDB id

1tlh

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Contents

			Protein chains

					89 a.a. *


					68 a.a. *

* Residue conservation analysis

PDB id:

1tlh

Links

Name:

Transcription

Title:

T4 asia bound to sigma70 region 4

Structure:

10 kda anti-sigma factor. Chain: a. Synonym: audrey stevens' inhibitor, 10 kda RNA polymerase-associated protein. Engineered: yes. RNA polymerase sigma factor rpod. Chain: b. Synonym: sigma-70. Engineered: yes

Source:

Enterobacteria phage t4. Organism_taxid: 10665. Gene: asia. Expressed in: escherichia coli. Expression_system_taxid: 562. Escherichia coli. Organism_taxid: 562. Gene: rpod, alt, b3067. Expressed in: escherichia coli bl21(de3).

NMR struc:

20 models

Authors:

L.J.Lambert,Y.Wei,V.Schirf,B.Demeler,M.H.Werner

Key ref:

L.J.Lambert et al. (2004). T4 AsiA blocks DNA recognition by remodeling sigma70 region 4. EMBO J, 23, 2952-2962. PubMed id: 15257291 DOI: 10.1038/sj.emboj.7600312

Date:

09-Jun-04

Release date:

23-Nov-04

PROCHECK

	Headers

	References

Protein chain

P32267 (ASIA_BPT4) - 10 kDa anti-sigma factor from Enterobacteria phage T4

Seq: Struc:					90 a.a. 89 a.a.

Protein chain

P00579 (RPOD_ECOLI) - RNA polymerase sigma factor RpoD from Escherichia coli (strain K12)

Seq: Struc:

Seq: Struc:					613 a.a. 68 a.a.

Key:

PfamA domain

Secondary structure

CATH domain



		Enzyme reactions

Enzyme class:

Chains A, B: E.C.?

[IntEnz] [ExPASy] [KEGG] [BRENDA]

DOI no: 10.1038/sj.emboj.7600312	EMBO J 23:2952-2962 (2004)
PubMed id: 15257291

T4 AsiA blocks DNA recognition by remodeling sigma70 region 4.
L.J.Lambert, Y.Wei, V.Schirf, B.Demeler, M.H.Werner.

ABSTRACT

Bacteriophage T4 AsiA is a versatile transcription factor capable of inhibiting host gene expression as an 'anti-sigma' factor while simultaneously promoting gene-specific expression of T4 middle genes in conjunction with T4 MotA. To accomplish this task, AsiA engages conserved region 4 of Eschericia coli sigma70, blocking recognition of most host promoters by sequestering the DNA-binding surface at the AsiA/sigma70 interface. The three-dimensional structure of an AsiA/region 4 complex reveals that the C-terminal alpha helix of region 4 is unstructured, while four other helices adopt a completely different conformation relative to the canonical structure of unbound region 4. That AsiA induces, rather than merely stabilizes, this rearrangement can be realized by comparison to the homologous structures of region 4 solved in a variety of contexts, including the structure of Thermotoga maritima sigmaA region 4 described herein. AsiA simultaneously occupies the surface of region 4 that ordinarily contacts core RNA polymerase (RNAP), suggesting that an AsiA-bound sigma70 may also undergo conformational changes in the context of the RNAP holoenzyme.

Selected figure(s)



	Figure 2. Figure 2 Three-dimensional structure of T. maritima A SR4. (A) Superposition of the NMR structure family. Chemical shifts for residues 379 -383 (the loop between S4 and S5) were not identified and this segment is relatively disordered in the family. (B) Helix arrangement in TmSR4. Helix S1 (residues 322 -329), helix S2 (residues 334 -342), helix S3 (residues 353 -361), helix S4 (residues 364 -377) and helix S5 (residues 385 -393) were identified from secondary 13C[ / ]shifts, d[NN] (i, i+1) NOEs and 3J[NH ]coupling constants. (C) Hydrophobic core of TmSR4 formed from nonpolar residues found in all the five helices. (D) Superposition of TmSR4 (blue), the T. aquaticus A SR4 in its DNA-bound conformation (red) (Campbell et al, 2002) and the T. thermophilus A SR4 in its holoenzyme conformation (green) (Vassylyev et al, 2002).		Figure 6. Figure 6 AsiA remodels the conformation of SR4. The structure of TmSR4 (blue) is compared to the structure of AsiA-bound EcSR4 (green) in two views. The C-termini of helices S1 -S4 are colored red. Helix S5 seen in TmSR4 is unfolded in EcSR4 and the unfolded segment has been excluded from the views of EcSR4 for clarity. (A) Lateral view along helix S4 and (B) top view rotated 90� about the horizontal axis relative to (A). Apparent in both views, helix S2 in the complex is inverted N-to-C-terminus and helix S1 is repositioned by approximately 180� in the AsiA-bound conformation relative to the conformation in TmSR4. The DNA-binding HTH element (helices S3 and S4) is unfolded from its canonical orientation in TmSR4 and forms a pseudo-continuous helix in the AsiA-bound state.

Figures were selected by the author.

Literature references that cite this PDB file's key reference

PubMed id

Reference

21029433

D.M.Hinton (2010).
Transcriptional control in the prereplicative phase of T4 development.

Virol J, 7, 289.

20184899

K.G.Thakur, T.Praveena, and B.Gopal (2010).
Structural and biochemical bases for the redox sensitivity of Mycobacterium tuberculosis RslA.

J Mol Biol, 397, 1199-1208.

PDB code:

3hug

19366670

A.H.Yuan, B.E.Nickels, and A.Hochschild (2009).
The bacteriophage T4 AsiA protein contacts the beta-flap domain of RNA polymerase.

Proc Natl Acad Sci U S A, 106, 6597-6602.

19691505

B.Roucourt, and R.Lavigne (2009).
The role of interactions between phage and bacterial proteins within the infected cell: a diverse and puzzling interactome.

Environ Microbiol, 11, 2789-2805.

19538446

K.B.Decker, and D.M.Hinton (2009).
The secret to 6S: regulating RNA polymerase by ribo-sequestration.

Mol Microbiol, 73, 137-140.

19376864

M.Dehbi, G.Moeck, F.F.Arhin, P.Bauda, D.Bergeron, T.Kwan, J.Liu, J.McCarty, M.Dubow, and J.Pelletier (2009).
Inhibition of transcription in Staphylococcus aureus by a primary sigma factor-binding polypeptide from phage G1.

J Bacteriol, 191, 3763-3771.

19651989

X.Rao, P.Deighan, Z.Hua, X.Hu, J.Wang, M.Luo, J.Wang, Y.Liang, G.Zhong, A.Hochschild, and L.Shen (2009).
A regulator from Chlamydia trachomatis modulates the activity of RNA polymerase through direct interaction with the beta subunit and the primary sigma subunit.

Genes Dev, 23, 1818-1829.

18375176

E.A.Campbell, L.F.Westblade, and S.A.Darst (2008).
Regulation of bacterial RNA polymerase sigma factor activity: a structural perspective.

Curr Opin Microbiol, 11, 121-127.

18485078

R.P.Bonocora, G.Caignan, C.Woodrell, M.H.Werner, and D.M.Hinton (2008).
A basic/hydrophobic cleft of the T4 activator MotA interacts with the C-terminus of E.coli sigma70 to activate middle gene transcription.

Mol Microbiol, 69, 331-343.

18521075

S.P.Haugen, W.Ross, and R.L.Gourse (2008).
Advances in bacterial promoter recognition and its control by factors that do not bind DNA.

Nat Rev Microbiol, 6, 507-519.

18359804

U.K.Sharma, and D.Chatterji (2008).
Differential mechanisms of binding of anti-sigma factors Escherichia coli Rsd and bacteriophage T4 AsiA to E. coli RNA polymerase lead to diverse physiological consequences.

J Bacteriol, 190, 3434-3443.

17803943

E.A.Campbell, R.Greenwell, J.R.Anthony, S.Wang, L.Lim, K.Das, H.J.Sofia, T.J.Donohue, and S.A.Darst (2007).
A conserved structural module regulates transcriptional responses to diverse stress signals in bacteria.

Mol Cell, 27, 793-805.

PDB codes:

2q1z 2z2s

17681541

G.A.Patikoglou, L.F.Westblade, E.A.Campbell, V.Lamour, W.J.Lane, and S.A.Darst (2007).
Crystal structure of the Escherichia coli regulator of sigma70, Rsd, in complex with sigma70 domain 4.

J Mol Biol, 372, 649-659.

PDB code:

2p7v

17371501

G.Stoskiene, L.Truncaite, A.Zajanckauskaite, and R.Nivinskas (2007).
Middle promoters constitute the most abundant and diverse class of promoters in bacteriophage T4.

Mol Microbiol, 64, 421-434.

17997097

L.L.Beck, T.G.Smith, and T.R.Hoover (2007).
Look, no hands! Unconventional transcriptional activators in bacteria.

Trends Microbiol, 15, 530-537.

16420370

A.Typas, and R.Hengge (2006).
Role of the spacer between the -35 and -10 regions in sigmas promoter selectivity in Escherichia coli.

Mol Microbiol, 59, 1037-1051.

16452409

D.M.Hinton, S.Vuthoori, and R.Mulamba (2006).
The bacteriophage T4 inhibitor and coactivator AsiA inhibits Escherichia coli RNA Polymerase more rapidly in the absence of sigma70 region 1.1: evidence that region 1.1 stabilizes the interaction between sigma70 and core.

J Bacteriol, 188, 1279-1285.

16996538

K.Baxter, J.Lee, L.Minakhin, K.Severinov, and D.M.Hinton (2006).
Mutational analysis of sigma70 region 4 needed for appropriation by the bacteriophage T4 transcription factors AsiA and MotA.

J Mol Biol, 363, 931-944.

16601684

S.Nechaev, and E.P.Geiduschek (2006).
The role of an upstream promoter interaction in initiation of bacterial transcription.

EMBO J, 25, 1700-1709.

16791737

Y.Wei, and M.H.Werner (2006).
iDC: A comprehensive toolkit for the analysis of residual dipolar couplings for macromolecular structure determination.

J Biomol NMR, 35, 17-25.

15882415

B.D.Gregory, B.E.Nickels, S.A.Darst, and A.Hochschild (2005).
An altered-specificity DNA-binding mutant of Escherichia coli sigma70 facilitates the analysis of sigma70 function in vivo.

Mol Microbiol, 56, 1208-1219.

15817381

D.M.Hinton (2005).
Molecular gymnastics: distortion of an RNA polymerase sigma factor.

Trends Microbiol, 13, 140-143.

15574501

S.Nechaev, M.Kamali-Moghaddam, E.André, J.P.Léonetti, and E.P.Geiduschek (2004).
The bacteriophage T4 late-transcription coactivator gp33 binds the flap domain of Escherichia coli RNA polymerase.

Proc Natl Acad Sci U S A, 101, 17365-17370.

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.