Science 1 June 1990: Vol. 248. no. 4959, pp. 1112 - 1115 DOI: 10.1126/science.2188365

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Articles

The Yeast AAA+ Chaperone Hsp104 Is Part of a Network That Links the Actin Cytoskeleton with the Inheritance of Damaged Proteins.

P. Tessarz, M. Schwarz, A. Mogk, and B. Bukau (2009)
Mol. Cell. Biol. 29, 3738-3745
 |  Abstract »  |  Full Text »  |  PDF »

A G-protein {gamma} subunit mimic is a general antagonist of prion propagation in Saccharomyces cerevisiae.

M. Ishiwata, H. Kurahashi, and Y. Nakamura (2009)
PNAS 106, 791-796
 |  Abstract »  |  Full Text »  |  PDF »

Ssd1 Is Required for Thermotolerance and Hsp104-Mediated Protein Disaggregation in Saccharomyces cerevisiae.

S. S. Mir, D. Fiedler, and A. G. Cashikar (2009)
Mol. Cell. Biol. 29, 187-200
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Specificity of the J-protein Sis1 in the propagation of 3 yeast prions.

T. Higurashi, J. K. Hines, C. Sahi, R. Aron, and E. A. Craig (2008)
PNAS 105, 16596-16601
 |  Abstract »  |  Full Text »  |  PDF »

Regulation of Thermotolerance by Stress-Induced Transcription Factors in Saccharomyces cerevisiae.

N. Yamamoto, Y. Maeda, A. Ikeda, and H. Sakurai (2008)
Eukaryot. Cell 7, 783-790
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The 2008 Genetics Society of America Medal.

N. Hopkins (2008)
Genetics 178, 1125-1128
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Analysis of the AAA+ chaperone clpB gene and stress-response expression in the halophilic methanogenic archaeon Methanohalophilus portucalensis.

C.-J. Shih and M.-C. Lai (2007)
Microbiology 153, 2572-2583
 |  Abstract »  |  Full Text »  |  PDF »

Inaugural Article: Collaboration between the ClpB AAA+ remodeling protein and the DnaK chaperone system.

S. M. Doyle, J. R. Hoskins, and S. Wickner (2007)
PNAS 104, 11138-11144
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Modulation of Ubc4p/Ubc5p-Mediated Stress Responses by the RING-Finger-Dependent Ubiquitin-Protein Ligase Not4p in Saccharomyces cerevisiae.

K. W. Mulder, A. Inagaki, E. Cameroni, F. Mousson, G. S. Winkler, C. De Virgilio, M. A. Collart, and H. Th. M. Timmers (2007)
Genetics 176, 181-192
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Effects of Ubiquitin System Alterations on the Formation and Loss of a Yeast Prion.

K. D. Allen, T. A. Chernova, E. P. Tennant, K. D. Wilkinson, and Y. O. Chernoff (2007)
J. Biol. Chem. 282, 3004-3013
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Structural and Functional Conversion of Molecular Chaperone ClpB from the Gram-Positive Halophilic Lactic Acid Bacterium Tetragenococcus halophilus Mediated by ATP and Stress.

S. Sugimoto, H. Yoshida, Y. Mizunoe, K. Tsuruno, J. Nakayama, and K. Sonomoto (2006)
J. Bacteriol. 188, 8070-8078
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Hsp70 Chaperone Machine Remodels Protein Aggregates at the Initial Step of Hsp70-Hsp100-dependent Disaggregation.

S. Zietkiewicz, A. Lewandowska, P. Stocki, and K. Liberek (2006)
J. Biol. Chem. 281, 7022-7029
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Cyanobacterial ClpC/HSP100 Protein Displays Intrinsic Chaperone Activity.

F. I. Andersson, R. Blakytny, J. Kirstein, K. Turgay, B. Bukau, A. Mogk, and A. K. Clarke (2006)
J. Biol. Chem. 281, 5468-5475
 |  Abstract »  |  Full Text »  |  PDF »

The [PSI+] Prion of Saccharomyces cerevisiae Can Be Propagated by an Hsp104 Orthologue from Candida albicans.

J. F. Zenthon, F. Ness, B. Cox, and M. F. Tuite (2006)
Eukaryot. Cell 5, 217-225
 |  Abstract »  |  Full Text »  |  PDF »

Loss of Hsp70 in Drosophila Is Pleiotropic, With Effects on Thermotolerance, Recovery From Heat Shock and Neurodegeneration.

W. J. Gong and K. G. Golic (2006)
Genetics 172, 275-286
 |  Abstract »  |  Full Text »  |  PDF »

Regulation and Recovery of Functions of Saccharomyces cerevisiae Chaperone BiP/Kar2p after Thermal Insult.

L. Seppa and M. Makarow (2005)
Eukaryot. Cell 4, 2008-2016
 |  Abstract »  |  Full Text »  |  PDF »

The Small Heat Shock Protein IbpA of Escherichia coli Cooperates with IbpB in Stabilization of Thermally Aggregated Proteins in a Disaggregation Competent State.

M. Matuszewska, D. Kuczynska-Wisnik, E. Laskowska, and K. Liberek (2005)
J. Biol. Chem. 280, 12292-12298
 |  Abstract »  |  Full Text »  |  PDF »

A Stromal Hsp100 Protein Is Required for Normal Chloroplast Development and Function in Arabidopsis.

D. Constan, J. E. Froehlich, S. Rangarajan, and K. Keegstra (2004)
Plant Physiology 136, 3605-3615
 |  Abstract »  |  Full Text »  |  PDF »

Successive and Synergistic Action of the Hsp70 and Hsp100 Chaperones in Protein Disaggregation.

S. Zietkiewicz, J. Krzewska, and K. Liberek (2004)
J. Biol. Chem. 279, 44376-44383
 |  Abstract »  |  Full Text »  |  PDF »

The role of pre-existing aggregates in Hsp104-dependent polyglutamine aggregate formation and epigenetic change of yeast prions.

Y. Kimura, S. Koitabashi, A. Kakizuka, and T. Fujita (2004)
Genes Cells 9, 685-696
 |  Abstract »  |  Full Text »  |  PDF »

Dominant Gain-of-Function Mutations in Hsp104p Reveal Crucial Roles for the Middle Region.

E. C. Schirmer, O. R. Homann, A. S. Kowal, and S. Lindquist (2004)
Mol. Biol. Cell 15, 2061-2072
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Trigonal DnaK-DnaJ Complex Versus Free DnaK and DnaJ: HEAT STRESS CONVERTS THE FORMER TO THE LATTER, AND ONLY THE LATTER CAN DO DISAGGREGATION IN COOPERATION WITH ClpB.

Y.-h. Watanabe and M. Yoshida (2004)
J. Biol. Chem. 279, 15723-15727
 |  Abstract »  |  Full Text »  |  PDF »

Lessons from the Genome Sequence of Neurospora crassa: Tracing the Path from Genomic Blueprint to Multicellular Organism.

K. A. Borkovich, L. A. Alex, O. Yarden, M. Freitag, G. E. Turner, N. D. Read, S. Seiler, D. Bell-Pedersen, J. Paietta, N. Plesofsky, et al. (2004)
Microbiol. Mol. Biol. Rev. 68, 1-108
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The Prion Curing Agent Guanidinium Chloride Specifically Inhibits ATP Hydrolysis by Hsp104.

V. Grimminger, K. Richter, A. Imhof, J. Buchner, and S. Walter (2004)
J. Biol. Chem. 279, 7378-7383
 |  Abstract »  |  Full Text »  |  PDF »

clpB, a Novel Member of the Listeria monocytogenes CtsR Regulon, Is Involved in Virulence but Not in General Stress Tolerance.

A. Chastanet, I. Derre, S. Nair, and T. Msadek (2004)
J. Bacteriol. 186, 1165-1174
 |  Abstract »  |  Full Text »  |  PDF »

Differential Gene Expression in Auristatin PHE-Treated Cryptococcus neoformans.

T. Woyke, M. E. Berens, D. B. Hoelzinger, G. R. Pettit, G. Winkelmann, and R. K. Pettit (2004)
Antimicrob. Agents Chemother. 48, 561-567
 |  Abstract »  |  Full Text »  |  PDF »

The S. cerevisiae HtrA-like protein Nma111p is a nuclear serine protease that mediates yeast apoptosis.

B. Fahrenkrog, U. Sauder, and U. Aebi (2004)
J. Cell Sci. 117, 115-126
 |  Abstract »  |  Full Text »  |  PDF »

Screening of inbred lines to develop a thermotolerant sunflower hybrid using the temperature induction response (TIR) technique: a novel approach by exploiting residual variability.

M. Senthil-Kumar, V. Srikanthbabu, B. Mohan Raju, Ganeshkumar, N. Shivaprakash, and M. Udayakumar (2003)
J. Exp. Bot. 54, 2569-2578
 |  Abstract »  |  Full Text »  |  PDF »

Gts1p Activates SNF1-dependent Derepression of HSP104 and TPS1 in the Stationary Phase of Yeast Growth.

S.-i. Yaguchi and K. Tsurugi (2003)
J. Biol. Chem. 278, 29760-29768
 |  Abstract »  |  Full Text »  |  PDF »

The ClpB Homolog Hsp78 Is Required for the Efficient Degradation of Proteins in the Mitochondrial Matrix.

K. Rottgers, N. Zufall, B. Guiard, and W. Voos (2002)
J. Biol. Chem. 277, 45829-45837
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ATP-dependent Hexameric Assembly of the Heat Shock Protein Hsp101 Involves Multiple Interaction Domains and a Functional C-proximal Nucleotide-binding Domain.

D. R. Gallie, D. Fortner, J. Peng, and D. Puthoff (2002)
J. Biol. Chem. 277, 39617-39626
 |  Abstract »  |  Full Text »  |  PDF »

Amino acid residue 184 of yeast Hsp104 chaperone is critical for prion-curing by guanidine, prion propagation, and thermotolerance.

G. Jung, G. Jones, and D. C. Masison (2002)
PNAS 99, 9936-9941
 |  Abstract »  |  Full Text »  |  PDF »

Maize HSP101 Plays Important Roles in Both Induced and Basal Thermotolerance and Primary Root Growth.

J. Nieto-Sotelo, L. M. Martinez, G. Ponce, G. I. Cassab, A. Alagon, R. B. Meeley, J.-M. Ribaut, and R. Yang (2002)
PLANT CELL 14, 1621-1633
 |  Abstract »  |  Full Text »  |  PDF »

Heat Shock Changes the Heterogeneity Distribution in Populations of Caenorhabditis elegans: Does It Tell Us Anything About the Biological Mechanism of Stress Response?.

A. I. Yashin, J. W. Cypser, T. E. Johnson, A. I. Michalski, S. I. Boyko, and V. N. Novoseltsev (2002)
J. Gerontol. A Biol. Sci. Med. Sci. 57, B83-92
 |  Abstract »  |  Full Text »  |  PDF »

Roles of the Two ATP Binding Sites of ClpB from Thermus thermophilus.

Y.-h. Watanabe, K. Motohashi, and M. Yoshida (2002)
J. Biol. Chem. 277, 5804-5809
 |  Abstract »  |  Full Text »  |  PDF »

Novel Form of ClpB/HSP100 Protein in the Cyanobacterium Synechococcus.

M.-J. Eriksson, J. Schelin, E. Miskiewicz, and A. K. Clarke (2001)
J. Bacteriol. 183, 7392-7396
 |  Abstract »  |  Full Text »  |  PDF »

Hsp104 Interacts with Hsp90 Cochaperones in Respiring Yeast.

T. Abbas-Terki, O. Donze, P.-A. Briand, and D. Picard (2001)
Mol. Cell. Biol. 21, 7569-7575
 |  Abstract »  |  Full Text »  |  PDF »

Developmental and Thermal Regulation of the Maize Heat Shock Protein, HSP101.

T. E. Young, J. Ling, C. J. Geisler-Lee, R. L. Tanguay, C. Caldwell, and D. R. Gallie (2001)
Plant Physiology 127, 777-791
 |  Abstract »  |  Full Text »  |  PDF »

Cytotoxic and Genotoxic Consequences of Heat Stress Are Dependent on the Presence of Oxygen in Saccharomyces cerevisiae.

J. F. Davidson and R. H. Schiestl (2001)
J. Bacteriol. 183, 4580-4587
 |  Abstract »  |  Full Text »  |  PDF »

The Truncated Form of the Bacterial Heat Shock Protein ClpB/HSP100 Contributes to Development of Thermotolerance in the Cyanobacterium Synechococcus sp. Strain PCC 7942.

A. K. Clarke and M.-J. Eriksson (2000)
J. Bacteriol. 182, 7092-7096
 |  Abstract »  |  Full Text »

Internal Trehalose Protects Endocytosis from Inhibition by Ethanol in Saccharomyces cerevisiae.

P. Lucero, E. Peñalver, E. Moreno, and R. Lagunas (2000)
Appl. Envir. Microbiol. 66, 4456-4461
 |  Abstract »  |  Full Text »

Heat Shock Protein HSP101 Binds to the Fed-1 Internal Light Regulator y Element and Mediates Its High Translational Activity.

J. Ling, D. R. Wells, R. L. Tanguay, L. F. Dickey, W. F. Thompson, and D. R. Gallie (2000)
PLANT CELL 12, 1213-1228
 |  Abstract »  |  Full Text »

Acquired Thermotolerance and Expression of the HSP100/ClpB Genes of Lima Bean.

S. J. Keeler, C. M. Boettger, J. G. Haynes, K. A. Kuches, M. M. Johnson, D. L. Thureen, C. L. Keeler Jr., and S. L. Kitto (2000)
Plant Physiology 123, 1121-1132
 |  Abstract »  |  Full Text »

Isolation of Arabidopsis Mutants Lacking Components of Acquired Thermotolerance.

J. J. Burke, P. J. O'Mahony, and M. J. Oliver (2000)
Plant Physiology 123, 575-588
 |  Abstract »  |  Full Text »

Mutants of Arabidopsis thaliana defective in the acquisition of tolerance to high temperature stress.

S.-W. Hong and E. Vierling (2000)
PNAS 97, 4392-4397
 |  Abstract »  |  Full Text »  |  PDF »

Mercury Induces Regional and Cell-Specific Stress Protein Expression in Rat Kidney.

P. L. Goering, B. R. Fisher, B. T. Noren, A. Papaconstantinou, J. L. Rojko, and R. J. Marler (2000)
Toxicol. Sci. 53, 447-457
 |  Abstract »  |  Full Text »  |  PDF »

Prions in Saccharomyces and Podospora spp.: Protein-Based Inheritance.

R. B. Wickner, K. L. Taylor, H. K. Edskes, M.-L. Maddelein, H. Moriyama, and B. T. Roberts (1999)
Microbiol. Mol. Biol. Rev. 63, 844-861
 |  Abstract »  |  Full Text »  |  PDF »

The Cytoplasmic Chaperone Hsp104 Is Required for Conformational Repair of Heat-denatured Proteins in the Yeast Endoplasmic Reticulum.

A.-L. Hänninen, M. Simola, N. Saris, and M. Makarow (1999)
Mol. Biol. Cell 10, 3623-3632
 |  Abstract »  |  Full Text »

Rpb4p Is Necessary for RNA Polymerase II Activity at High Temperature.

I. Maillet, J. M. Buhler, A. Sentenac, and J. Labarre (1999)
J. Biol. Chem. 274, 22586-22590
 |  Abstract »  |  Full Text »  |  PDF »

Heat-inactivated proteins are rescued by the DnaK·J-GrpE set and ClpB chaperones.

K. Motohashi, Y. Watanabe, M. Yohda, and M. Yoshida (1999)
PNAS 96, 7184-7189
 |  Abstract »  |  Full Text »  |  PDF »

Molecular Cloning and Characterization of a Mouse Homolog of Bacterial ClpX, a Novel Mammalian Class II Member of the Hsp100/Clp Chaperone Family.

S. Santagata, D. Bhattacharyya, F.-H. Wang, N. Singha, A. Hodtsev, and E. Spanopoulou (1999)
J. Biol. Chem. 274, 16311-16319
 |  Abstract »  |  Full Text »  |  PDF »

Heterologous Expression of a Plant Small Heat-Shock Protein Enhances Escherichia coli Viability under Heat and Cold Stress.

A. Soto, I. Allona, C. Collada, M.-A. Guevara, R. Casado, E. Rodriguez-Cerezo, C. Aragoncillo, and L. Gomez (1999)
Plant Physiology 120, 521-528
 |  Abstract »  |  Full Text »

Recognition, Targeting, and Hydrolysis of the lambda  O Replication Protein by the ClpP/ClpX Protease.

M. Gonciarz-Swiatek, A. Wawrzynow, S.-J. Um, B. A. Learn, R. McMacken, W. L. Kelley, C. Georgopoulos, O. Sliekers, and M. Zylicz (1999)
J. Biol. Chem. 274, 13999-14005
 |  Abstract »  |  Full Text »  |  PDF »

Antagonistic Interactions between Yeast Chaperones Hsp104 and Hsp70 in Prion Curing.

G. P. Newnam, R. D. Wegrzyn, S. L. Lindquist, and Y. O. Chernoff (1999)
Mol. Cell. Biol. 19, 1325-1333
 |  Abstract »  |  Full Text »  |  PDF »

Molecular Chaperones: Biology and Prospects for Pharmacological Intervention.

D. F. Smith, L. Whitesell, and E. Katsanis (1998)
Pharmacol. Rev. 50, 493-514
 |  Abstract »  |  Full Text »  |  PDF »

Folding in vivo of a newly translated yeast cytosolic enzyme is mediated by the SSA class of cytosolic yeast Hsp70 proteins.

S. Kim, B. Schilke, E. A. Craig, and A. L. Horwich (1998)
PNAS 95, 12860-12865
 |  Abstract »  |  Full Text »  |  PDF »

HSP101 functions as a specific translational regulatory protein whose activity is regulated by nutrient status.

D. R. Wells, R. L. Tanguay, H. Le, and D. R. Gallie (1998)
Genes & Dev. 12, 3236-3251
 |  Abstract »  |  Full Text »

Transcriptional Factor Mutations Reveal Regulatory Complexities of Heat Shock and Newly Identified Stress Genes in Saccharomyces cerevisiae.

J. M. Treger, A. P. Schmitt, J. R. Simon, and K. McEntee (1998)
J. Biol. Chem. 273, 26875-26879
 |  Abstract »  |  Full Text »  |  PDF »

ClpB in a Cyanobacterium: Predicted Structure, Phylogenetic Relationships, and Regulation by Light and Temperature.

M. Celerin, A. A. Gilpin, N. J. Schisler, A. G. Ivanov, E. Miskiewicz, M. Krol, and D. E. Laudenbach (1998)
J. Bacteriol. 180, 5173-5182
 |  Abstract »  |  Full Text »

Requirement for Hsp90 and a CyP-40-type Cyclophilin in Negative Regulation of the Heat Shock Response.

A. A. Duina, H. M. Kalton, and R. F. Gaber (1998)
J. Biol. Chem. 273, 18974-18978
 |  Abstract »  |  Full Text »  |  PDF »

The ATPase Activity of Hsp104, Effects of Environmental Conditions and Mutations.

E. C. Schirmer, C. Queitsch, A. S. Kowal, D. A. Parsell, and S. Lindquist (1998)
J. Biol. Chem. 273, 15546-15552
 |  Abstract »  |  Full Text »  |  PDF »

COVASIAM: an Image Analysis Method That Allows Detection of Confluent Microbial Colonies and Colonies of Various Sizes for Automated Counting.

G. Corkidi, R. Diaz-Uribe, J. L. Folch-Mallol, and J. Nieto-Sotelo (1998)
Appl. Envir. Microbiol. 64, 1400-1404
 |  Abstract »  |  Full Text »

Transient ER retention as stress response: conformational repair of heat-damaged proteins to secretion-competent structures.

N Saris and M Makarow (1998)
J. Cell Sci. 111, 1575-1582
 |  Abstract »  |  PDF »

Proteasome Inhibitors Cause Induction of Heat Shock Proteins and Trehalose, Which Together Confer Thermotolerance in Saccharomyces cerevisiae.

D. H. L. a. A. L. Goldberg (1998)
Mol. Cell. Biol. 18, 30-38
 |  Abstract »  |  Full Text »

Interactions of the chaperone Hsp104 with yeast Sup35 and mammalian PrP.

E. C. Schirmer and S. Lindquist (1997)
PNAS 94, 13932-13937
 |  Abstract »  |  Full Text »  |  PDF »

Expression of a gene encoding a 16.9-kDa heat-shock protein, Oshsp16.9, in Escherichia coli enhances thermotolerance.

C.-H. Yeh, P.-F. L. Chang, K.-W. Yeh, W.-C. Lin, Y.-M. Chen, and C.-Y. Lin (1997)
PNAS 94, 10967-10972
 |  Abstract »  |  Full Text »  |  PDF »

Structure-Function Studies on Small Heat Shock Protein Oligomeric Assembly and Interaction with Unfolded Polypeptides.

M. R. Leroux, R. Melki, B. Gordon, G. Batelier, and E. P. M. Candido (1997)
J. Biol. Chem. 272, 24646-24656
 |  Abstract »  |  Full Text »  |  PDF »

The Hsp70 Homologue Lhs1p Is Involved in a Novel Function of the Yeast Endoplasmic Reticulum, Refolding and Stabilization of Heat-denatured Protein Aggregates.

N. Saris, H. Holkeri, R. A. Craven, C. J. Stirling, and M. Makarow (1997)
J. Cell Biol. 137, 813-824
 |  Abstract »  |  Full Text »  |  PDF »

Kinetics of Induction and Protective Effect of Heat-Shock Proteins After Cardioplegic Arrest.

M. Amrani, J. Corbett, S. Y. Boateng, M. J. Dunn, and M. H. Yacoub (1996)
Ann. Thorac. Surg. 61, 1407-1411
 |  Abstract »  |  Full Text »

Heat-induced Chaperone Activity of HSP90.

M. Yonehara, Y. Minami, Y. Kawata, J. Nagai, and I. Yahara (1996)
J. Biol. Chem. 271, 2641-2645
 |  Abstract »  |  Full Text »  |  PDF »

Cloning and Expression of Murine High Molecular Mass Heat Shock Proteins, HSP105.

K. Yasuda, A. Nakai, T. Hatayama, and K. Nagata (1995)
J. Biol. Chem. 270, 29718-29723
 |  Abstract »  |  Full Text »  |  PDF »

Requirement of a small cytoplasmic RNA for the establishment of thermotolerance.

P. Fung, J Gaertig, M. Gorovsky, and R. Hallberg (1995)
Science 268, 1036-1039
 |  Abstract »  |  PDF »

Role of the chaperone protein Hsp104 in propagation of the yeast prion-like factor [psi+].

Y. Chernoff, S. Lindquist, B Ono, S. Inge-Vechtomov, and S. Liebman (1995)
Science 268, 880-884
 |  Abstract »  |  PDF »

The Role of Hsp104 in Stress Tolerance and [PSI+] Propagation in Saccharomyces cerevisiae.

S. Lindquist, M.M. Patino, Y.O. Chernoff, A.S. Kowal, M.A. Singer, S.W. Liebman, K.-H. Lee, and T. Blake (1995)
Cold Spring Harb Symp Quant Biol 60, 451-460
 |  Abstract »  |  PDF »

Thermotolerance in mammalian cells. Protein denaturation and aggregation, and stress proteins.

H. Kampinga (1993)
J. Cell Sci. 104, 11-17
 |  Abstract »  |  PDF »

Copper Activation of Superoxide Dismutase 1 (SOD1) in Vivo. ROLE FOR PROTEIN-PROTEIN INTERACTIONS WITH THE COPPER CHAPERONE FOR SOD1.

P. J. Schmidt, C. Kunst, and V. C. Culotta (2000)
J. Biol. Chem. 275, 33771-33776
 |  Abstract »  |  Full Text »  |  PDF »

Torsin A and Its Torsion Dystonia-associated Mutant Forms Are Lumenal Glycoproteins That Exhibit Distinct Subcellular Localizations.

K. Kustedjo, M. H. Bracey, and B. F. Cravatt (2000)
J. Biol. Chem. 275, 27933-27939
 |  Abstract »  |  Full Text »  |  PDF »

Subunit interactions influence the biochemical and biological properties of Hsp104.

E. C. Schirmer, D. M. Ware, C. Queitsch, A. S. Kowal, and S. L. Lindquist (2001)
PNAS 98, 914-919
 |  Abstract »  |  Full Text »  |  PDF »

Polyglutamine aggregates alter protein folding homeostasis in Caenorhabditis elegans.

S. H. Satyal, E. Schmidt, K. Kitagawa, N. Sondheimer, S. Lindquist, J. M. Kramer, and R. I. Morimoto (2000)
PNAS 97, 5750-5755
 |  Abstract »  |  Full Text »  |  PDF »

Analysis of the AAA sensor-2 motif in the C-terminal ATPase domain of Hsp104 with a site-specific fluorescent probe of nucleotide binding.

D. A. Hattendorf and S. L. Lindquist (2002)
PNAS 99, 2732-2737
 |  Abstract »  |  Full Text »  |  PDF »

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