PDBsum entry 1um8

Chaperone

PDB id

1um8

Loading ...

Contents

			Protein chain

					327 a.a. *

			Ligands

					ADP

			Waters ×85

* Residue conservation analysis

PDB id:

1um8

Links
- PDBe
- RCSB
- MMDB
- JenaLib
- Proteopedia
- CATH
- SCOP
- PDBSWS
- PDBePISA
- CSA
- ProSAT

Name:

Chaperone

Title:

Crystal structure of helicobacter pylori clpx

Structure:

Atp-dependent clp protease atp-binding subunit clpx. Chain: a. Fragment: residues 71-446. Engineered: yes

Source:

Helicobacter pylori. Organism_taxid: 85962. Strain: 26695. Gene: clpx. Expressed in: escherichia coli. Expression_system_taxid: 562.

Resolution:

2.60Å

R-factor:

0.219

R-free:

0.258

Authors:

D.Y.Kim,K.K.Kim

Key ref:

D.Y.Kim and K.K.Kim (2003). Crystal structure of ClpX molecular chaperone from Helicobacter pylori. J Biol Chem, 278, 50664-50670. PubMed id: 14514695 DOI: 10.1074/jbc.M305882200

Date:

25-Sep-03

Release date:

23-Dec-03

PROCHECK

	Headers

	References

Protein chain

O25926 (CLPX_HELPY) - ATP-dependent Clp protease ATP-binding subunit ClpX from Helicobacter pylori (strain ATCC 700392 / 26695)

Seq: Struc:					446 a.a. 327 a.a.

Key:

PfamA domain

Secondary structure

CATH domain



		Enzyme reactions

Enzyme class:

E.C.?

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

DOI no: 10.1074/jbc.M305882200	J Biol Chem 278:50664-50670 (2003)
PubMed id: 14514695

Crystal structure of ClpX molecular chaperone from Helicobacter pylori.
D.Y.Kim, K.K.Kim.

ABSTRACT

ClpX, a heat shock protein 100 chaperone, which acts as the regulatory subunit of the ATP-dependent ClpXP protease, is responsible for intracellular protein remodeling and degradation. To provide a structural basis for a better understanding of the function of the Clp ATPase family, the crystal structures of Helicobacter pylori ClpX, lacking an N-terminal Cys cluster region complexed with ADP, was determined. The overall structure of ClpX is similar to that of heat shock locus U (HslU), consisting of two subdomains, with ADP bound at the subdomain interface. The crystal structure of ClpX reveals that a conserved tripeptide (LGF) is located on the tip of ClpP binding loop extending from the N-terminal subdomain. A hexameric model of ClpX suggests that six tripeptides make hydrophobic contacts with the hydrophobic clefts of the ClpP heptmer asymmetrically. In addition, the nucleotide binding environment provides the structural explanation for the hexameric assembly and the modulation of ATPase activity.

Selected figure(s)



	Figure 1. FIG. 1. The structures of Hp ClpX-ASD, E. coli HslU, and E. coli ClpA D2. A, the overall structure of Hp ClpX-ASD is presented as a ribbon diagram. The ATPase core domain, SSD domain, and LGF tripeptide are colored magenta, green, and red, respectively. The ATP molecule is shown in orange as a ball-and-stick model. Each secondary structure and the N and C termini are labeled. The protease interface and substrate interface are indicated in the figure to display the relative orientation of Hp ClpX. E. coli HslU (B) and E. coli ClpA D2 (C), positioned in the same orientation with Hp ClpX-ASD, are displayed as ribbon diagrams, with the same color codes. D, the sequences of Hp ClpX, E. coli ClpX, and E. coli HslU were aligned by the CLUSTALW program (28), following the manual adjustment based on a structural comparison. The secondary structures of Hp ClpX-ASD are indicated by a cylinder for the -helix and an arrow for the -strand. The amino acids in the LGF peptide are boxed in blue. In the alignment, identical residues are boxed in red, with homologous residues boxed in yellow.		Figure 2. FIG. 2. The hexamer model of Hp ClpX-ASD and E. coli ClpP heptamer. The ribbon diagrams of the hexamer model of Hp ClpX-ASD viewed along the 6-fold axis from the protease interface (A) and from the side (B) are shown. The same color schemes as described in the legend to Fig. 1A are used. However, each subunit is colored with a different brightness. The N and C termini of one subunit are labeled. The surface charge distribution of Hp ClpX-ASD (C) and E. coli ClpP (D) is shown. The protease interface of Hp ClpX and the ATPase interface of ClpP are drawn to show the possible ClpX-ClpP interface. The red and blue areas represent the negatively and positively charged surfaces, respectively. The white region represents the hydrophobic surface. The LGF peptide of ClpX (residues 297, 298, and 299), and the conserved hydrophobic cleft of ClpP (residues 60, 62, 82, 90, 92, 112, 114, and 189), are colored in yellow.

Figures were selected by the author.

Literature references that cite this PDB file's key reference

PubMed id

Reference

22562135

S.E.Glynn, A.R.Nager, T.A.Baker, and R.T.Sauer (2012).
Dynamic and static components power unfolding in topologically closed rings of a AAA+ proteolytic machine.

Nat Struct Mol Biol, 19, 616-622.

21266546

A.Kravats, M.Jayasinghe, and G.Stan (2011).
Unfolding and translocation pathway of substrate protein controlled by structure in repetitive allosteric cycles of the ClpY ATPase.

Proc Natl Acad Sci U S A, 108, 2234-2239.

22056769

M.Stotz, O.Mueller-Cajar, S.Ciniawsky, P.Wendler, F.U.Hartl, A.Bracher, and M.Hayer-Hartl (2011).
Structure of green-type Rubisco activase from tobacco.

Nat Struct Mol Biol, 18, 1366-1370.

PDB codes:

3t15 3zw6

20305655

B.G.Lee, E.Y.Park, K.E.Lee, H.Jeon, K.H.Sung, H.Paulsen, H.Rübsamen-Schaeff, H.Brötz-Oesterhelt, and H.K.Song (2010).
Structures of ClpP in complex with acyldepsipeptide antibiotics reveal its activation mechanism.

Nat Struct Mol Biol, 17, 471-478.

PDB codes:

3ktg 3kth 3kti 3ktj 3ktk

20851345

D.H.Li, Y.S.Chung, M.Gloyd, E.Joseph, R.Ghirlando, G.D.Wright, Y.Q.Cheng, M.R.Maurizi, A.Guarné, and J.Ortega (2010).
Acyldepsipeptide antibiotics induce the formation of a structured axial channel in ClpP: A model for the ClpX/ClpA-bound state of ClpP.

Chem Biol, 17, 959-969.

PDB code:

3mt6

20462489

G.Effantin, T.Ishikawa, G.M.De Donatis, M.R.Maurizi, and A.C.Steven (2010).
Local and global mobility in the ClpA AAA+ chaperone detected by cryo-electron microscopy: functional connotations.

Structure, 18, 553-562.

20162627

O.Doppelt-Azeroual, F.Delfaud, F.Moriaud, and A.G.de Brevern (2010).
Fast and automated functional classification with MED-SuMo: an application on purine-binding proteins.

Protein Sci, 19, 847-867.

19136627

A.Duerig, S.Abel, M.Folcher, M.Nicollier, T.Schwede, N.Amiot, B.Giese, and U.Jenal (2009).
Second messenger-mediated spatiotemporal control of protein degradation regulates bacterial cell cycle progression.

Genes Dev, 23, 93.

19136590

D.P.Haeusser, A.H.Lee, R.B.Weart, and P.A.Levin (2009).
ClpX inhibits FtsZ assembly in a manner that does not require its ATP hydrolysis-dependent chaperone activity.

J Bacteriol, 191, 1986-1991.

19395483

H.Y.Lien, R.S.Shy, S.S.Peng, Y.L.Wu, Y.T.Weng, H.H.Chen, P.C.Su, W.F.Ng, Y.C.Chen, P.Y.Chang, and W.F.Wu (2009).
Characterization of the Escherichia coli ClpY (HslU) substrate recognition site in the ClpYQ (HslUV) protease using the yeast two-hybrid system.

J Bacteriol, 191, 4218-4231.

19914167

S.E.Glynn, A.Martin, A.R.Nager, T.A.Baker, and R.T.Sauer (2009).
Structures of asymmetric ClpX hexamers reveal nucleotide-dependent motions in a AAA+ protein-unfolding machine.

Cell, 139, 744-756.

PDB codes:

3hte 3hws

19892734

Y.Shin, J.H.Davis, R.R.Brau, A.Martin, J.A.Kenniston, T.A.Baker, R.T.Sauer, and M.J.Lang (2009).
Single-molecule denaturation and degradation of proteins by the AAA+ ClpXP protease.

Proc Natl Acad Sci U S A, 106, 19340-19345.

18313382

A.Martin, T.A.Baker, and R.T.Sauer (2008).
Diverse pore loops of the AAA+ ClpX machine mediate unassisted and adaptor-dependent recognition of ssrA-tagged substrates.

Mol Cell, 29, 441-450.

18421150

E.Y.Park, and H.K.Song (2008).
A degradation signal recognition in prokaryotes.

J Synchrotron Radiat, 15, 246-249.

18582897

J.A.Yakamavich, T.A.Baker, and R.T.Sauer (2008).
Asymmetric nucleotide transactions of the HslUV protease.

J Mol Biol, 380, 946-957.

18816064

L.D.Jennings, J.Bohon, M.R.Chance, and S.Licht (2008).
The ClpP N-terminus coordinates substrate access with protease active site reactivity.

Biochemistry, 47, 11031-11040.

18550799

L.Zhu, J.O.Wrabl, A.P.Hayashi, L.S.Rose, and P.J.Thomas (2008).
The torsin-family AAA+ protein OOC-5 contains a critical disulfide adjacent to Sensor-II that couples redox state to nucleotide binding.

Mol Biol Cell, 19, 3599-3612.

18929572

M.D.Gonciarz, F.G.Whitby, D.M.Eckert, C.Kieffer, A.Heroux, W.I.Sundquist, and C.P.Hill (2008).
Biochemical and structural studies of yeast Vps4 oligomerization.

J Mol Biol, 384, 878-895.

PDB codes:

3eie 3eih

18755692

R.Lum, M.Niggemann, and J.R.Glover (2008).
Peptide and protein binding in the axial channel of Hsp104. Insights into the mechanism of protein unfolding.

J Biol Chem, 283, 30139-30150.

17612489

A.Martin, T.A.Baker, and R.T.Sauer (2007).
Distinct static and dynamic interactions control ATPase-peptidase communication in a AAA+ protease.

Mol Cell, 27, 41-52.

17218279

C.M.Farrell, T.A.Baker, and R.T.Sauer (2007).
Altered specificity of a AAA+ protease.

Mol Cell, 25, 161-166.

17545305

S.M.Doyle, J.R.Hoskins, and S.Wickner (2007).
Collaboration between the ClpB AAA+ remodeling protein and the DnaK chaperone system.

Proc Natl Acad Sci U S A, 104, 11138-11144.

16810315

G.Thibault, Y.Tsitrin, T.Davidson, A.Gribun, and W.A.Houry (2006).
Large nucleotide-dependent movement of the N-terminal domain of the ClpX chaperone.

EMBO J, 25, 3367-3376.

16834776

T.Cavalier-Smith (2006).
Rooting the tree of life by transition analyses.

Biol Direct, 1, 19.

16877706

T.V.Rotanova, I.Botos, E.E.Melnikov, F.Rasulova, A.Gustchina, M.R.Maurizi, and A.Wlodawer (2006).
Slicing a protease: structural features of the ATP-dependent Lon proteases gleaned from investigations of isolated domains.

Protein Sci, 15, 1815-1828.

16237435

A.Martin, T.A.Baker, and R.T.Sauer (2005).
Rebuilt AAA + motors reveal operating principles for ATP-fuelled machines.

Nature, 437, 1115-1120.

16046622

B.M.Burton, and T.A.Baker (2005).
Remodeling protein complexes: insights from the AAA+ unfoldase ClpX and Mu transposase.

Protein Sci, 14, 1945-1954.

15989952

G.L.Hersch, R.E.Burton, D.N.Bolon, T.A.Baker, and R.T.Sauer (2005).
Asymmetric interactions of ATP with the AAA+ ClpX6 unfoldase: allosteric control of a protein machine.

Cell, 121, 1017-1027.

15880122

I.Levchenko, R.A.Grant, J.M.Flynn, R.T.Sauer, and T.A.Baker (2005).
Versatile modes of peptide recognition by the AAA+ adaptor protein SspB.

Nat Struct Mol Biol, 12, 520-525.

PDB code:

1yfn

15989953

J.Hinnerwisch, W.A.Fenton, K.J.Furtak, G.W.Farr, and A.L.Horwich (2005).
Loops in the central channel of ClpA chaperone mediate protein binding, unfolding, and translocation.

Cell, 121, 1029-1041.

15948963

R.B.Weart, S.Nakano, B.E.Lane, P.Zuber, and P.A.Levin (2005).
The ClpX chaperone modulates assembly of the tubulin-like protein FtsZ.

Mol Microbiol, 57, 238-249.

16263929

R.Sprangers, A.Gribun, P.M.Hwang, W.A.Houry, and L.E.Kay (2005).
Quantitative NMR spectroscopy of supramolecular complexes: dynamic side pores in ClpP are important for product release.

Proc Natl Acad Sci U S A, 102, 16678-16683.

15371343

J.M.Flynn, I.Levchenko, R.T.Sauer, and T.A.Baker (2004).
Modulating substrate choice: the SspB adaptor delivers a regulator of the extracytoplasmic-stress response to the AAA+ protease ClpXP for degradation.

Genes Dev, 18, 2292-2301.

14962378

M.R.Maurizi, and D.Xia (2004).
Protein binding and disruption by Clp/Hsp100 chaperones.

Structure, 12, 175-183.

15064753

S.A.Joshi, G.L.Hersch, T.A.Baker, and R.T.Sauer (2004).
Communication between ClpX and ClpP during substrate processing and degradation.

Nat Struct Mol Biol, 11, 404-411.

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 codes are shown on the right.