Its substrate specificity characterizes the DnaJ co-chaperone as a scanning factor for the DnaK chaperone

Stefan Rüdiger; Jens Schneider-Mergener; Bernd Bukau

doi:10.1093/emboj/20.5.1042

Its substrate specificity characterizes the DnaJ co-chaperone as a scanning factor for the DnaK chaperone

Stefan Rüdiger, Jens Schneider-Mergener, Bernd Bukau

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The evolutionarily conserved DnaJ proteins are essential components of Hsp70 chaperone systems. The DnaJ homologue of Escherichia coli associates with chaperone substrates and mediates their ATP hydrolysis-dependent locking into the binding cavity of its Hsp70 partner, DnaK. To determine the substrate specificity of DnaJ proteins, we screened 1633 peptides derived from 14 protein sequences for binding to E.coli DnaJ. The binding motif of DnaJ consists of a hydrophobic core of approximately eight residues enriched for aromatic and large aliphatic hydrophobic residues and arginine. The hydrophobicity of this motif explains why DnaJ itself can prevent protein aggregation. Although this motif shows differences from DnaK's binding motif, DnaJ and DnaK share the majority of binding peptides. In contrast to DnaK, DnaJ binds peptides consisting of L- and D-amino acids, and therefore is not restricted by backbone contacts. These features allow DnaJ to scan hydrophobic protein surfaces and initiate the functional cycle of the DnaK system by associating with hydrophobic exposed patches and subsequent targeting of DnaK to these or to hydrophobic patches in spatial neighbourhood.

Original language	English
Pages (from-to)	1042-1050
Number of pages	9
Journal	EMBO Journal
Volume	20
Issue number	5
DOIs	https://doi.org/10.1093/emboj/20.5.1042
Publication status	Published - 1 Mar 2001
Externally published	Yes

Keywords

Heat shock proteins
Hsp40
Hsp70
Protein folding
Spot synthesis
amino acid
arginine
binding protein
chaperone
heat shock protein 40
heat shock protein 70
peptide derivative
protein DnaJ
protein DnaK
amino acid sequence
article
controlled study
enzyme specificity
enzyme substrate
Escherichia coli
hydrophobicity
nonhuman
priority journal
protein aggregation
protein analysis
protein binding
protein folding

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10.1093/emboj/20.5.1042

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title = "Its substrate specificity characterizes the DnaJ co-chaperone as a scanning factor for the DnaK chaperone",

abstract = "The evolutionarily conserved DnaJ proteins are essential components of Hsp70 chaperone systems. The DnaJ homologue of Escherichia coli associates with chaperone substrates and mediates their ATP hydrolysis-dependent locking into the binding cavity of its Hsp70 partner, DnaK. To determine the substrate specificity of DnaJ proteins, we screened 1633 peptides derived from 14 protein sequences for binding to E.coli DnaJ. The binding motif of DnaJ consists of a hydrophobic core of approximately eight residues enriched for aromatic and large aliphatic hydrophobic residues and arginine. The hydrophobicity of this motif explains why DnaJ itself can prevent protein aggregation. Although this motif shows differences from DnaK's binding motif, DnaJ and DnaK share the majority of binding peptides. In contrast to DnaK, DnaJ binds peptides consisting of L- and D-amino acids, and therefore is not restricted by backbone contacts. These features allow DnaJ to scan hydrophobic protein surfaces and initiate the functional cycle of the DnaK system by associating with hydrophobic exposed patches and subsequent targeting of DnaK to these or to hydrophobic patches in spatial neighbourhood.",

keywords = "Heat shock proteins, Hsp40, Hsp70, Protein folding, Spot synthesis, amino acid, arginine, binding protein, chaperone, heat shock protein 40, heat shock protein 70, peptide derivative, protein DnaJ, protein DnaK, amino acid sequence, article, controlled study, enzyme specificity, enzyme substrate, Escherichia coli, hydrophobicity, nonhuman, priority journal, protein aggregation, protein analysis, protein binding, protein folding",

author = "Stefan R{\"u}diger and Jens Schneider-Mergener and Bernd Bukau",

year = "2001",

month = mar,

day = "1",

doi = "10.1093/emboj/20.5.1042",

language = "English",

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TY - JOUR

T1 - Its substrate specificity characterizes the DnaJ co-chaperone as a scanning factor for the DnaK chaperone

AU - Rüdiger, Stefan

AU - Schneider-Mergener, Jens

AU - Bukau, Bernd

PY - 2001/3/1

Y1 - 2001/3/1

N2 - The evolutionarily conserved DnaJ proteins are essential components of Hsp70 chaperone systems. The DnaJ homologue of Escherichia coli associates with chaperone substrates and mediates their ATP hydrolysis-dependent locking into the binding cavity of its Hsp70 partner, DnaK. To determine the substrate specificity of DnaJ proteins, we screened 1633 peptides derived from 14 protein sequences for binding to E.coli DnaJ. The binding motif of DnaJ consists of a hydrophobic core of approximately eight residues enriched for aromatic and large aliphatic hydrophobic residues and arginine. The hydrophobicity of this motif explains why DnaJ itself can prevent protein aggregation. Although this motif shows differences from DnaK's binding motif, DnaJ and DnaK share the majority of binding peptides. In contrast to DnaK, DnaJ binds peptides consisting of L- and D-amino acids, and therefore is not restricted by backbone contacts. These features allow DnaJ to scan hydrophobic protein surfaces and initiate the functional cycle of the DnaK system by associating with hydrophobic exposed patches and subsequent targeting of DnaK to these or to hydrophobic patches in spatial neighbourhood.

AB - The evolutionarily conserved DnaJ proteins are essential components of Hsp70 chaperone systems. The DnaJ homologue of Escherichia coli associates with chaperone substrates and mediates their ATP hydrolysis-dependent locking into the binding cavity of its Hsp70 partner, DnaK. To determine the substrate specificity of DnaJ proteins, we screened 1633 peptides derived from 14 protein sequences for binding to E.coli DnaJ. The binding motif of DnaJ consists of a hydrophobic core of approximately eight residues enriched for aromatic and large aliphatic hydrophobic residues and arginine. The hydrophobicity of this motif explains why DnaJ itself can prevent protein aggregation. Although this motif shows differences from DnaK's binding motif, DnaJ and DnaK share the majority of binding peptides. In contrast to DnaK, DnaJ binds peptides consisting of L- and D-amino acids, and therefore is not restricted by backbone contacts. These features allow DnaJ to scan hydrophobic protein surfaces and initiate the functional cycle of the DnaK system by associating with hydrophobic exposed patches and subsequent targeting of DnaK to these or to hydrophobic patches in spatial neighbourhood.

KW - Heat shock proteins

KW - Hsp40

KW - Hsp70

KW - Protein folding

KW - Spot synthesis

KW - amino acid

KW - arginine

KW - binding protein

KW - chaperone

KW - heat shock protein 40

KW - heat shock protein 70

KW - peptide derivative

KW - protein DnaJ

KW - protein DnaK

KW - amino acid sequence

KW - article

KW - controlled study

KW - enzyme specificity

KW - enzyme substrate

KW - Escherichia coli

KW - hydrophobicity

KW - nonhuman

KW - priority journal

KW - protein aggregation

KW - protein analysis

KW - protein binding

KW - protein folding

U2 - 10.1093/emboj/20.5.1042

DO - 10.1093/emboj/20.5.1042

M3 - Article

SN - 0261-4189

VL - 20

SP - 1042

EP - 1050

JO - EMBO Journal

JF - EMBO Journal

IS - 5

ER -

Its substrate specificity characterizes the DnaJ co-chaperone as a scanning factor for the DnaK chaperone

Abstract

Keywords

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