The goals of this proposal are to carry out structural studies on Hspl 00 to uncover the mechanisms by which it functions as a molecular chaperone. E. coli Hspl 00 ClpB was recently identified to act as a molecular chaperone by disaggregating non-native polypeptides. To investigate the mechanisms for HsplOO CIpB to disaggregate non-native polypeptides, we propose to determine ClpB N-terminal domain structure. The CIpB N-terminal domain has been shown to interact directly with non-native polypeptides and play essential roles in CIpB chaperone functions. We have crystallized the N-terminal domain of ClpB and the crystals diffracted X-ray to I .95A. In the structure of CIpB N-terminal domain, we may identify a peptide-binding groove. Therefore, we could predict the minimal length of peptides bound by Hspl 00 CIpB. The high affinity peptide substrates of CIpB will be identified by genetic and biophysical approaches. We will crystallize the complex of CIpB N-terminal domain with its peptide substrate. The crystal structure of the complex will provide fundamental insights on how HsplOO CIpB recognizes and binds the non-native polypeptides. To reveal the mechanisms for CIpB to carry out its ATPase activities, we propose to determine the crystal structure of CIpB nucleotide-binding domain 2 with the C-terminal fragment (D2C). CIpB contains two nucleotide-binding domains NBDI and NBD2. We have solved the crystal structure of CIpB NBDI and have crystallized CIpB D2C complexed with ATP or ADP. To test the models for the mechanisms for HsplOO CIpB chaperone functions, we will construct two sets of structure-based CIpB mutants. One is to mutate residues within ClpB N-terminal domain that are critically involved in binding peptides. These mutants will be tested for loss of functions by peptide binding assays and protein folding assays. The other set of mutants is to support the proposed """"""""See-Saw"""""""" model for CIpB ATPase activity. We will mutate residues to disable the conformational changes of the CIpB C-terminal fragment. The mutants will be tested for functions by nucleotide binding assays, ATPase activity assays and protein folding assays. Collectively, this proposal covers a comprehensive study that reveals the mechanisms by which ClpB interacts with non-native polypeptides and perform ATP hydrolysis to function as a molecular chaperone.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM065959-02
Application #
6615749
Study Section
Molecular and Cellular Biophysics Study Section (BBCA)
Program Officer
Wehrle, Janna P
Project Start
2002-08-01
Project End
2006-07-31
Budget Start
2003-08-01
Budget End
2004-07-31
Support Year
2
Fiscal Year
2003
Total Cost
$253,750
Indirect Cost
Name
University of Alabama Birmingham
Department
Anatomy/Cell Biology
Type
Schools of Medicine
DUNS #
063690705
City
Birmingham
State
AL
Country
United States
Zip Code
35294
Cui, Wenjun; Li, Jingzhi; Ron, David et al. (2011) The structure of the PERK kinase domain suggests the mechanism for its activation. Acta Crystallogr D Biol Crystallogr 67:423-8
Yan, Ming; Li, Jingzhi; Sha, Bingdong (2011) Structural analysis of the Sil1-Bip complex reveals the mechanism for Sil1 to function as a nucleotide-exchange factor. Biochem J 438:447-55
Zheng, Ying; Qin, Hongwei; Frank, Stuart J et al. (2011) A CK2-dependent mechanism for activation of the JAK-STAT signaling pathway. Blood 118:156-66
Qian, Xinguo; Gebert, Michael; Hopker, Jan et al. (2011) Structural basis for the function of Tim50 in the mitochondrial presequence translocase. J Mol Biol 411:513-9
Hu, Junbin; Li, Jingzhi; Qian, Xinguo et al. (2009) The crystal structures of yeast Get3 suggest a mechanism for tail-anchored protein membrane insertion. PLoS One 4:e8061
Li, Jingzhi; Qian, Xinguo; Hu, Junbin et al. (2009) Molecular chaperone Hsp70/Hsp90 prepares the mitochondrial outer membrane translocon receptor Tom71 for preprotein loading. J Biol Chem 284:23852-9
Hu, Junbin; Wu, Yunkun; Li, Jingzhi et al. (2008) The crystal structure of the putative peptide-binding fragment from the human Hsp40 protein Hdj1. BMC Struct Biol 8:3
Li, Jingzhi; Wu, Yunkun; Qian, Xinguo et al. (2006) Crystal structure of yeast Sis1 peptide-binding fragment and Hsp70 Ssa1 C-terminal complex. Biochem J 398:353-60
Wu, Yunkun; McCombs, Debbie; Nagy, Lisa et al. (2006) Preliminary X-ray crystallographic studies of yeast mitochondrial protein Tom70p. Acta Crystallogr Sect F Struct Biol Cryst Commun 62:265-7
Josyula, Ratnakar; Jin, Zhongmin; Fu, Zhengqing et al. (2006) Crystal structure of yeast mitochondrial peripheral membrane protein Tim44p C-terminal domain. J Mol Biol 359:798-804

Showing the most recent 10 out of 16 publications