Your search keyword '"Franz-Ulrich Hartl"' showing total 107 results

1. Calmodulin Regulates Protease Versus Co-Chaperone Activity of a Metacaspase

Author

Anna anon, Frederik Eisele, Sandra M. Hill, Xinxin Hao, Kara L. Schneider, Rahmi Imamoglu, David Balchin, Beidong Liu, Franz-Ulrich Hartl, Peter Bozhkov, and Thomas Nyström

Published

2023

2. Editor's evaluation: A native chemical chaperone in the human eye lens

Author

Franz-Ulrich Hartl

Published

2022

3. Mechanisms of Stop Codon Readthrough Mitigation Reveal Principles of GCN1 Mediated Translational Quality Control

Author

Martin B. D. Müller, Prasad Kasturi, Gopal Jayaraj, and Franz-Ulrich Hartl

Published

2022

4. Editor's evaluation: Conserved structural elements specialize ATAD1 as a membrane protein extraction machine

Author

Franz-Ulrich Hartl

Published

2021

5. Gel-like inclusions of C-terminal fragments of TDP-43 sequester and inhibit proteasomes in neurons

Author

Frédéric Frottin, Franz-Ulrich Hartl, Rubén Fernández-Busnadiego, Dieter Edbauer, Qiang Guo, Felix Meissner, Wolfgang Baumeister, Mark S. Hipp, H. Riemenschneider, Christian Haass, Matthias Mann, Jakob M. Bader, Daniel Farny, and Gernot Kleinberger

Subjects

0303 health sciences, Chemistry, Neurodegeneration, nutritional and metabolic diseases, medicine.disease, Proteomics, nervous system diseases, Cell biology, 03 medical and health sciences, 0302 clinical medicine, Proteostasis, Proteasome, mental disorders, medicine, Amyotrophic lateral sclerosis, 030217 neurology & neurosurgery, 030304 developmental biology, Frontotemporal dementia

Abstract

TDP-43 inclusions enriched in C-terminal fragments of ~25kDa (“TDP-25”) are associated with neurodegeneration in amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Here, we analyzed gain-of-function mechanisms of TDP-25 combining cryo-electron tomography, proteomics and functional assays. TDP-25 inclusions are amorphous with gel-like biophysical properties and sequester proteasomes adopting exclusively substrate-processing conformations. This leads to proteostasis impairment, further enhanced by pathogenic mutations. These findings bolster the importance of proteasome dysfunction in ALS/FTD.

Published

2021

6. Rubisco condensate formation by CcmM in β-carboxysome biogenesis

Author

Manajit Hayer-Hartl, N.D. Nguyen, Benedict M. Long, Andreas Bracher, Graeme Price, H. Aigner, H. Wang, Franz-Ulrich Hartl, X. Yan, and W.Y. Hee

Subjects

0106 biological sciences, Cyanobacteria, 0303 health sciences, Multidisciplinary, biology, Chemistry, RuBisCO, Carbon fixation, biology.organism_classification, Photosynthesis, 01 natural sciences, Pyrenoid, 03 medical and health sciences, Carboxysome, Carbonic anhydrase, biology.protein, Biophysics, Biogenesis, 030304 developmental biology, 010606 plant biology & botany

Abstract

Cells use compartmentalization of enzymes as a strategy to regulate metabolic pathways and increase their efficiency1. The α- and β-carboxysomes of cyanobacteria contain ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco)—a complex of eight large (RbcL) and eight small (RbcS) subunits—and carbonic anhydrase2–4. As HCO3− can diffuse through the proteinaceous carboxysome shell but CO2 cannot5, carbonic anhydrase generates high concentrations of CO2 for carbon fixation by Rubisco6. The shell also prevents access to reducing agents, generating an oxidizing environment7–9. The formation of β-carboxysomes involves the aggregation of Rubisco by the protein CcmM10, which exists in two forms: full-length CcmM (M58 in Synechococcus elongatus PCC7942), which contains a carbonic anhydrase-like domain8 followed by three Rubisco small subunit-like (SSUL) modules connected by flexible linkers; and M35, which lacks the carbonic anhydrase-like domain11. It has long been speculated that the SSUL modules interact with Rubisco by replacing RbcS2–4. Here we have reconstituted the Rubisco–CcmM complex and solved its structure. Contrary to expectation, the SSUL modules do not replace RbcS, but bind close to the equatorial region of Rubisco between RbcL dimers, linking Rubisco molecules and inducing phase separation into a liquid-like matrix. Disulfide bond formation in SSUL increases the network flexibility and is required for carboxysome function in vivo. Notably, the formation of the liquid-like condensate of Rubisco is mediated by dynamic interactions with the SSUL domains, rather than by low-complexity sequences, which typically mediate liquid–liquid phase separation in eukaryotes12,13. Indeed, within the pyrenoids of eukaryotic algae, the functional homologues of carboxysomes, Rubisco adopts a liquid-like state by interacting with the intrinsically disordered protein EPYC114. Understanding carboxysome biogenesis will be important for efforts to engineer CO2-concentrating mechanisms in plants15–19. The structure of a Rubisco–CcmM complex sheds light on the formation of carboxysomes in cyanobacteria.

Published

2019

7. Biogenesis and Metabolic Maintenance of Rubisco

Author

Andreas Bracher, Franz-Ulrich Hartl, Spencer M. Whitney, and Manajit Hayer-Hartl

Subjects

inorganic chemicals, 0301 basic medicine, Protein Folding, Oxygenase, Chaperonins, Physiology, Ribulose-Bisphosphate Carboxylase, Plant Science, Protein Engineering, Photosynthesis, Chaperonin, 03 medical and health sciences, Light-independent reactions, Molecular Biology, chemistry.chemical_classification, Sugar phosphates, biology, fungi, RuBisCO, food and beverages, Cell Biology, Carbon Dioxide, Plants, Pyruvate carboxylase, 030104 developmental biology, chemistry, Biochemistry, biology.protein, Biogenesis, Molecular Chaperones

Abstract

Ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) mediates the fixation of atmospheric CO2 in photosynthesis by catalyzing the carboxylation of the 5-carbon sugar ribulose-1,5-bisphosphate (RuBP). Rubisco is a remarkably inefficient enzyme, fixing only 2–10 CO2 molecules per second. Efforts to increase crop yields by bioengineering Rubisco remain unsuccessful, owing in part to the complex cellular machinery required for Rubisco biogenesis and metabolic maintenance. The large subunit of Rubisco requires the chaperonin system for folding, and recent studies have shown that assembly of hexadecameric Rubisco is mediated by specific assembly chaperones. Moreover, Rubisco function can be inhibited by a range of sugar-phosphate ligands, including RuBP. Metabolic repair depends on remodeling of Rubisco by the ATP-dependent Rubisco activase and hydrolysis of inhibitory sugar phosphates by specific phosphatases. Here, we review our present understanding of the structure and function of these auxiliary factors and their utilization in efforts to engineer more catalytically efficient Rubisco enzymes.

Published

2017

8. The nucleolus functions as a phase-separated protein quality control compartment

Author

Frédéric Frottin, Ralf Jungmann, Rajat Gupta, Mark S. Hipp, Thomas Schlichthaerle, Florian Schueder, Franz-Ulrich Hartl, Shivani Tiwary, Roman Körner, and Jürgen Cox

Subjects

Protein Folding, NPM1, Proteome, Nucleolus, Phase Transition, Tissue Culture Techniques, 03 medical and health sciences, 0302 clinical medicine, Humans, HSP70 Heat-Shock Proteins, Granular component, Nuclear protein, 030304 developmental biology, 0303 health sciences, Multidisciplinary, Chemistry, HEK 293 cells, Nuclear Proteins, Cell biology, HEK293 Cells, Protein folding, Nucleophosmin, Protein quality, Cell Nucleolus, 030217 neurology & neurosurgery

Abstract

Phasing-in quality control in the nucleus The fundamental process of protein quality control in the nucleus is not well understood. The nucleus contains several non–membrane-bound subcompartments forming liquid-like condensates. The largest of these is the nucleolus, the site of ribosome biogenesis. Frottin et al. found that metastable nuclear proteins that misfold upon heat stress enter the nucleolus. In the nucleolus, they avoid irreversible aggregation and remain competent for heat shock protein 70–dependent refolding upon recovery from stress. Prolonged stress or the uptake of proteins associated with neurodegenerative diseases prevented this reversibility. Thus, the properties of a phase-separated compartment can assist in protein quality control. Science , this issue p. 342

Published

2019

9. Improved recombinant expression and purification of functional plant Rubisco

Author

Gabriel Thieulin-Pardo, Robert H. Wilson, Manajit Hayer-Hartl, and Franz-Ulrich Hartl

Subjects

Models, Molecular, folding, Protein Folding, Oxygenase, Rubisco, Arabidopsis, Gene Expression, Plant Biology, Biochemistry, Protein Structure, Secondary, Chaperonin, Structural Biology, Protein Isoforms, Cloning, Molecular, Photosynthesis, 0303 health sciences, biology, Chemistry, Communication, molecular chaperones, 030302 biochemistry & molecular biology, food and beverages, Pyruvate carboxylase, Chloroplast, Oligopeptides, assembly, inorganic chemicals, Rubisco activase, Recombinant Fusion Proteins, Ribulose-Bisphosphate Carboxylase, Genetic Vectors, Biophysics, 03 medical and health sciences, Escherichia coli, Genetics, Histidine, protein expression, Molecular Biology, 030304 developmental biology, Arabidopsis Proteins, RuBisCO, fungi, Cell Biology, Protein engineering, Carbon Dioxide, Phosphate-Binding Proteins, Group I Chaperonins, Kinetics, Protein Subunits, Chaperone (protein), biology.protein

Abstract

Improving the performance of the key photosynthetic enzyme Ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) by protein engineering is a critical strategy for increasing crop yields. The extensive chaperone requirement of plant Rubisco for folding and assembly has long been an impediment to this goal. Production of plant Rubisco in Escherichia coli requires the coexpression of the chloroplast chaperonin and four assembly factors. Here, we demonstrate that simultaneous expression of Rubisco and chaperones from a T7 promotor produces high levels of functional enzyme. Expressing the small subunit of Rubisco with a C-terminal hexahistidine-tag further improved assembly, resulting in a similar to 12-fold higher yield than the previously published procedure. The expression system described here provides a platform for the efficient production and engineering of plant Rubisco.

Published

2019

10. Protein Folding in Vivo

Author

Franz-Ulrich Hartl and Florian Georgescauld

Subjects

Folding (chemistry), Proteostasis, biology, Chemistry, biology.protein, Translation (biology), Protein folding, Protein aggregation, Macromolecular crowding, Hsp90, Chaperonin, Cell biology

Abstract

Proteins are composed of linear chains of amino acids. Upon synthesis in the cell, most proteins must rapidly acquire a specific three-dimensional structure, a process known as folding, before they can perform their various biological functions. Productive folding is often competed by aggregation, owing to the high macromolecular crowding of the cellular environment. Moreover, the process of translation increases the danger of misfolding, as incomplete nascent polypeptides are not yet able to fold into stable structures in many cases. To avoid these off-pathway reactions, a class of proteins called molecular chaperones has evolved in all organisms. They interact with nascent or stress-denatured polypeptides, prevent their aggregation and assist in folding and assembly processes, often in an ATP-regulated manner. These functions are especially important in conditions of cell stress, and their failure is linked with the manifestation of numerous age-dependent degenerative diseases. Key Concepts Molecular chaperones are proteins that mediate folding and assembly of other proteins, without being components of the final folded or assembled structures. Molecular chaperones prevent the potentially toxic aggregation of newly synthesised polypeptides during translation and when mature proteins unfold during stress conditions or ageing. Hsp70 chaperones act as a hub in the proteostasis network by assisting protein folding and conformational maintenance and by distributing client proteins to other chaperones for correct folding. The chaperonins mediate the folding of proteins with complex topologies and kinetically frustrated folding pathways. Keywords: protein folding; molecular chaperones; chaperonins; Hsp70; Hsp90; protein aggregation

Published

2015

11. Plant RuBisCo assembly in E. coli with five chloroplast chaperones including BSD2

Author

L. Calisse, Robert H. Wilson, Manajit Hayer-Hartl, Andreas Bracher, Franz-Ulrich Hartl, J.Y. Bhat, and H. Aigner

Subjects

0301 basic medicine, inorganic chemicals, Multidisciplinary, biology, Chemistry, RuBisCO, Mutagenesis, fungi, food and beverages, Photosynthesis, medicine.disease_cause, biology.organism_classification, Chaperonin, Chloroplast, 03 medical and health sciences, 030104 developmental biology, Biochemistry, biology.protein, medicine, Arabidopsis thaliana, Protein folding, Escherichia coli

Abstract

A biotech tour de force RuBisCo, the key enzyme of photosynthesis, is a complex of eight large and eight small subunits. It mediates the fixation of atmospheric CO 2 in the Calvin-Benson-Bassham cycle. In addition to being enzymatically inefficient, RuBisCo has a problem with distinguishing between CO 2 and O 2 . The fixation of O 2 results in the energetically wasteful reaction of photorespiration. Thus, there is a strong incentive to improve RuBisCo's catalytic properties by engineering. However, for decades, it has been impossible to express the enzyme from plants in an easily manipulatable bacterial host. Aigner et al. succeeded in functionally expressing plant RuBisCo in Escherichia coli (see the Perspective by Yeates and Wheatley). This should allow for the systematic mutational analysis of RuBisCo and selection of favorable variants for improved crop yields. Science , this issue p. 1272 ; see also p. 1253

Published

2017

12. Folding of large multidomain proteins by partial encapsulation in the chaperonin TRiC/CCT

Author

Andreas Bracher, Leonie Mönkemeyer, Florian Rüßmann, Franz-Ulrich Hartl, Stephanie A. Etchells, and Markus Stemp

Subjects

Protein Folding, Effective size, Recombinant Fusion Proteins, Green Fluorescent Proteins, Protein domain, macromolecular substances, Biology, Models, Biological, Substrate Specificity, Chaperonin, Protein stability, Chaperonin Containing TCP-1, Humans, Ribonucleoprotein, U5 Small Nuclear, Actin, Multidisciplinary, Protein Stability, Biological Sciences, Actins, Protein Structure, Tertiary, Crystallography, Proteome, Biophysics, Protein folding, sense organs

Abstract

The eukaryotic chaperonin, TRiC/CCT (TRiC, TCP-1 ring complex; CCT, chaperonin containing TCP-1), uses a built-in lid to mediate protein folding in an enclosed central cavity. Recent structural data suggest an effective size limit for the TRiC folding chamber of ∼70 kDa, but numerous chaperonin substrates are substantially larger. Using artificial fusion constructs with actin, an obligate chaperonin substrate, we show that TRiC can mediate folding of large proteins by segmental or domain-wise encapsulation. Single or multiple protein domains up to ∼70 kDa are stably enclosed by stabilizing the ATP-hydrolysis transition state of TRiC. Additional domains, connected by flexible linkers that pass through the central opening of the folding chamber, are excluded and remain accessible to externally added protease. Experiments with the physiological TRiC substrate hSnu114, a 109-kDa multidomain protein, suggest that TRiC has the ability to recognize domain boundaries in partially folded intermediates. In the case of hSnu114, this allows the selective encapsulation of the C-terminal ∼45-kDa domain and segments thereof, presumably reflecting a stepwise folding mechanism. The capacity of the eukaryotic chaperonin to overcome the size limitation of the folding chamber may have facilitated the explosive expansion of the multidomain proteome in eukaryotes.

Published

2012

13. Structural Probing of a Protein Phosphatase 2A Network by Chemical Cross-Linking and Mass Spectrometry

Author

Alexander Leitner, Lars Malmström, Raymond H. Mak, Ruedi Aebersold, Daniel Boehringer, Thomas Walzthoeni, Martin Beck, Franz Herzog, Abdullah Kahraman, Nenad Ban, Andreas Bracher, and Franz-Ulrich Hartl

Subjects

Chaperonins, Molecular model, Protein Conformation, Protein subunit, Biology, Crystallography, X-Ray, Bioinformatics, Mass Spectrometry, Chaperonin, 03 medical and health sciences, Protein structure, Protein Interaction Mapping, Humans, Protein Phosphatase 2, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Multidisciplinary, 030302 biochemistry & molecular biology, Signal transducing adaptor protein, Protein phosphatase 2, Amino acid, Cross-Linking Reagents, Structural biology, chemistry, Biophysics, Metabolic Networks and Pathways

Abstract

Dynamic Assembly Structural characterization of protein complexes has yielded significant insight into biological function; however, most structural techniques require stable, homogenous samples. This presents a challenge in characterizing transient signaling complexes. Herzog et al. (p. 1348 ) used chemical cross-linking and mass spectroscopy (XL-MS) to characterize the modular and dynamic interaction network involving phosphatase 2A (PP2A), which interacts with tens of regulatory and adaptor proteins in diverse signaling pathways. They found 176 interprotein and 569 intraprotein distance restraints that delineated the topology of the network. The study establishes the importance of XL-MS in the suite of structural methods used to characterize dynamic assemblies.

Published

2012

14. Structure of green-type Rubisco activase from tobacco

Author

Petra Wendler, Andreas Bracher, Oliver Mueller-Cajar, Mathias Stotz, Susanne Ciniawsky, Manajit Hayer-Hartl, and Franz-Ulrich Hartl

Subjects

Models, Molecular, Ribulose-Bisphosphate Carboxylase, Nicotiana tabacum, Molecular Sequence Data, Mutant, Random hexamer, Crystallography, X-Ray, Photosynthesis, Protein structure, Structural Biology, Tobacco, Botany, Amino Acid Sequence, Molecular Biology, Plant Proteins, chemistry.chemical_classification, Sugar phosphates, biology, Chemistry, fungi, RuBisCO, food and beverages, biology.organism_classification, Protein Structure, Tertiary, Enzyme, Tissue Plasminogen Activator, biology.protein, Biophysics, Sequence Alignment

Abstract

Rubisco, the enzyme that catalyzes the fixation of atmospheric CO(2) in photosynthesis, is subject to inactivation by inhibitory sugar phosphates. Here we report the 2.95-Å crystal structure of Nicotiana tabacum Rubisco activase (Rca), the enzyme that facilitates the removal of these inhibitors. Rca from tobacco has a classical AAA(+)-protein domain architecture. Although Rca populates a range of oligomeric states when in solution, it forms a helical arrangement with six subunits per turn when in the crystal. However, negative-stain electron microscopy of the active mutant R294V suggests that Rca functions as a hexamer. The residues determining species specificity for Rubisco are located in a helical insertion of the C-terminal domain and probably function in conjunction with the N-domain in Rubisco recognition. Loop segments exposed toward the central pore of the hexamer are required for the ATP-dependent remodeling of Rubisco, resulting in the release of inhibitory sugar.

Published

2011

15. Distinct binding sites for the ATPase and substrate-binding domain of human Hsp70 on the cell surface of antigen presenting cells

Author

Petra Diestelkötter-Bachert, Alice Hellwig, Sandra Zitzler, Franz-Ulrich Hartl, and Felix T. Wieland

Subjects

Endosome, Immunology, Antigen presentation, Antigen-Presenting Cells, Biology, Cell Line, Mice, Animals, Humans, Cytotoxic T cell, HSP70 Heat-Shock Proteins, Binding site, Receptor, Antigen-presenting cell, Molecular Biology, Fluorescent Dyes, Adenosine Triphosphatases, Antigen Presentation, Binding Sites, Macrophages, Cell Membrane, Cross-presentation, Protein Structure, Tertiary, Cell biology, Cytokine secretion, Protein Binding

Abstract

Hsp70 has high potential as an immune-adjuvant molecule: it mediates cytokine expression and maturation of antigen presenting cells (APCs) and also elicits a cytotoxic T-lymphocyte (CTL) response to antigenic peptides. How Hsp70 interacts with APCs is only poorly understood. Various surface proteins have been implicated in binding Hsp70 but their role in antigen presentation has remained controversial. The specific aim of this work was to determine the binding and uptake of human full-length Hsp70 as well as its separate ATPase (N70) and substrate-binding domains (C70) by APCs. Using laser scanning microscopy and FACS analysis, we established the existence of at least two distinct receptors for Hsp70, which are localized to distinct microdomains of the APC membrane. These receptors interact with the N70 and C70 domains of Hsp70, respectively. This observation was supported by the finding of a substantial portion of Hsp70 and C70, but not N70, in a detergent resistant membrane fraction. Accordingly, C70 and N70 did not compete with each other for binding. The bound proteins were rapidly internalized, with N70 and C70 localizing to separate endosomal compartments. Similarly, internalized free and peptide-loaded Hsp70 segregated rapidly within the cell. Efficient cross presentation of antigenic peptide bound to Hsp70 or C70 was demonstrated with the B3Z read out system. Consequently, the interaction of C70 with its putative receptor seems to be responsible for Hsp70-mediated cross presentation. Future studies should make use of C70 in identifying the uptake receptor of Hsp70-peptide complexes. In addition we could observe a stimulation of uptake of free peptide by preincubation with Hsp70 and N70, but not C70, whereas an Hsp-dependent cytokine secretion could not be detected. Consequently, by employing the individual domains it may be possible to distinguish between the different outcomes of Hsp70 treatment, like immune stimulation, DC maturation and antigen-specific responses.

Published

2008

16. Fes1p acts as a nucleotide exchange factor for the ribosome-associated molecular chaperone Ssb1p

Author

Z. Dragovic, Nikolay Tzvetkov, Y. Shomura, Franz-Ulrich Hartl, and Andreas Bracher

Subjects

chemistry.chemical_classification, Saccharomyces cerevisiae Proteins, Sequence Homology, Amino Acid, ATPase, Point mutation, Molecular Sequence Data, Clinical Biochemistry, Saccharomyces cerevisiae, Intracellular Signaling Peptides and Proteins, Surface Plasmon Resonance, Biology, biology.organism_classification, Biochemistry, Ribosome, Nucleotide exchange factor, Cytosol, chemistry, biology.protein, HSP70 Heat-Shock Proteins, Protein folding, Nucleotide, Amino Acid Sequence, Ribosomes, Molecular Biology

Abstract

The HspBP1 homolog Fes1p was recently identified as a nucleotide exchange factor (NEF) of Ssa1p, a canonical Hsp70 molecular chaperone in the cytosol of Saccharomyces cerevisiae. Besides the Ssa-type Hsp70s, the yeast cytosol contains three additional classes of Hsp70, termed Ssb, Sse and Ssz. Here, we show that Fes1p also functions as NEF for the ribosome-bound Ssb Hsp70s. Sequence analysis indicated that residues important for interaction with Fes1p are highly conserved in Ssa1p and Ssb1p, but not in Sse1p and Ssz1p. Indeed, Fes1p interacts with Ssa1p and Ssb1p with similar affinity, but does not form a complex with Sse1p. Functional analysis showed that Fes1p accelerates the release of the nucleotide analog MABA-ADP from Ssb1p by a factor of 35. In contrast to the interaction between mammalian HspBP1 and Hsp70, however, addition of ATP only moderately decreases the affinity of Fes1p for Ssb1p. Point mutations in Fes1p abolishing complex formation with Ssa1p also prevent the interaction with Ssb1p. The ATPase activity of Ssb1p is stimulated by the ribosome-associated complex of Zuotin and Ssz1p (RAC). Interestingly, Fes1p inhibits the stimulation of Ssb1p ATPase by RAC, suggesting a complex regulatory role of Fes1p in modulating the function of Ssb Hsp70s in co-translational protein folding.

Published

2006

17. Regulation of Hsp70 Function by HspBP1

Author

Z. Dragovic, Hung-Chun Chang, Jason C. Young, Y. Shomura, Jeffrey L. Brodsky, Franz-Ulrich Hartl, Nikolay Tzvetkov, Andreas Bracher, and V. Guerriero

Subjects

chemistry.chemical_classification, Conformational change, biology, ATPase, Cell Biology, Protein structure, chemistry, Biochemistry, Chaperone (protein), biology.protein, Biophysics, Nucleotide, Protein folding, Binding site, Molecular Biology, Peptide sequence

Abstract

HspBP1 belongs to a family of eukaryotic proteins recently identified as nucleotide exchange factors for Hsp70. We show that the S. cerevisiae ortholog of HspBP1, Fes1p, is required for efficient protein folding in the cytosol at 37°C. The crystal structure of HspBP1, alone and complexed with part of the Hsp70 ATPase domain, reveals a mechanism for its function distinct from that of BAG-1 or GrpE, previously characterized nucleotide exchange factors of Hsp70. HspBP1 has a curved, all α-helical fold containing four armadillo-like repeats unlike the other nucleotide exchange factors. The concave face of HspBP1 embraces lobe II of the ATPase domain, and a steric conflict displaces lobe I, reducing the affinity for nucleotide. In contrast, BAG-1 and GrpE trigger a conserved conformational change in lobe II of the ATPase domain. Thus, nucleotide exchange on eukaryotic Hsp70 occurs through two distinct mechanisms.

Published

2005

18. Structural Characterization of Mutant Huntingtin Inclusion Bodies by Cryo-Electron Tomography

Author

Bäuerlein Fjb, Saha, Archana Mishra, Franz-Ulrich Hartl, Rubén Fernández-Busnadiego, Irina Dudanova, Wolfgang Baumeister, Mark S. Hipp, and Ruediger Klein

Subjects

0301 basic medicine, 03 medical and health sciences, 030104 developmental biology, Materials science, Huntingtin, Mutant, Biophysics, Cryo-electron tomography, Instrumentation, Inclusion bodies, Characterization (materials science)

Published

2016

19. Detection and selective dissociation of intact ribosomes in a mass spectrometer

Author

Knud H. Nierhaus, Franz-Ulrich Hartl, Adam A. Rostom, Paola Fucini, Carol V. Robinson, R Juenemann, D R Benjamin, and Christopher M. Dobson

Subjects

Ribosomal Proteins, Multidisciplinary, Protein mass spectrometry, Chemistry, Analytical chemistry, Biological Sciences, Top-down proteomics, Mass spectrometry, Ribosome, Mass Spectrometry, Dissociation (chemistry), Molecular Weight, Cross-Linking Reagents, RNA, Ribosomal, Ribosomal protein, Escherichia coli, Magnesium, 30S, Ribosomes, 50S

Abstract

Intact Escherichia coli ribosomes have been projected into the gas phase of a mass spectrometer by means of nanoflow electrospray techniques. Species with mass/charge ratios in excess of 20,000 were detected at the level of individual ions by using time-of-flight analysis. Once in the gas phase the stability of intact ribosomes was investigated and found to increase as a result of cross-linking ribosomal proteins to the rRNA. By lowering the Mg 2+ concentration in solutions containing ribosomes the particles were found to dissociate into 30S and 50S subunits. The resolution of the charge states in the spectrum of the 30S subunit enabled its mass to be determined as 852,187 ± 3,918 Da, a value within 0.6% of that calculated from the individual proteins and the 16S RNA. Further dissociation into smaller macromolecular complexes and then individual proteins could be induced by subjecting the particles to increasingly energetic gas phase collisions. The ease with which proteins dissociated from the intact species was found to be related to their known interactions in the ribosome particle. The results show that emerging mass spectrometric techniques can be used to characterize a fully functional biological assembly as well as its isolated components.

Published

2000

20. Identification of in vivo substrates of the chaperonin GroEL

Author

Franz-Ulrich Hartl, F. Lottspeich, Eckerskorn C, Dmitrij Frishman, and Walid A. Houry

Subjects

Multidisciplinary, Chaperonin 60, macromolecular substances, Biology, medicine.disease_cause, GroEL, Protein Structure, Secondary, Substrate Specificity, Chaperonin, enzymes and coenzymes (carbohydrates), Cytosol, Biochemistry, Chaperone (protein), biological sciences, Foldase, Escherichia coli, medicine, biology.protein, bacteria, Protein folding, HSP60

Abstract

The chaperonin GroEL has an essential role in mediating protein folding in the cytosol of Escherichia coli. Here we show that GroEL interacts strongly with a well-defined set of approximately 300 newly translated polypeptides, including essential components of the transcription/translation machinery and metabolic enzymes. About one third of these proteins are structurally unstable and repeatedly return to GroEL for conformational maintenance. GroEL substrates consist preferentially of two or more domains with alphabeta-folds, which contain alpha-helices and buried beta-sheets with extensive hydrophobic surfaces. These proteins are expected to fold slowly and be prone to aggregation. The hydrophobic binding regions of GroEL may be well adapted to interact with the non-native states of alphabeta-domain proteins.

Published

1999

21. Polypeptide Flux through Bacterial Hsp70

Author

S. A. Teter, D. Ang, P. Blum, G. Fischer, Franz-Ulrich Hartl, D. Rockabrand, Walid A. Houry, T. Tradler, and Costa Georgopoulos

Subjects

biology, 'de novo' protein folding, Trigger factor, Biochemistry, Genetics and Molecular Biology(all), genetic processes, General Biochemistry, Genetics and Molecular Biology, Hsp70, Biochemistry, Chaperone (protein), biological sciences, biology.protein, Normal growth, bacteria, Gene

Abstract

A role for DnaK, the major E. coli Hsp70, in chaperoning de novo protein folding has remained elusive. Here we show that under nonstress conditions DnaK transiently associates with a wide variety of nascent and newly synthesized polypeptides, with a preference for chains larger than 30 kDa. Deletion of the nonessential gene encoding trigger factor, a ribosome-associated chaperone, results in a doubling of the fraction of nascent polypeptides interacting with DnaK. Combined deletion of the trigger factor and DnaK genes is lethal under normal growth conditions. These findings indicate important, partially overlapping functions of DnaK and trigger factor in de novo protein folding and explain why the loss of either chaperone can be tolerated by E. coli.

Published

1999

22. Mass spectrometry of ribosomes and ribosomal subunits

Author

J P Hendrick, Franz-Ulrich Hartl, D R Benjamin, Christopher M. Dobson, and Carol V. Robinson

Subjects

Ribosomal Proteins, Multidisciplinary, Protein mass spectrometry, Protein Conformation, Chemistry, Electrospray ionization, Analytical chemistry, Biological Sciences, Ribosomal RNA, Mass spectrometry, Ribosome, Mass Spectrometry, Molecular Weight, RNA, Bacterial, Ribosomal protein, Protein Biosynthesis, Escherichia coli, Mass spectrum, Biophysics, Eukaryotic Ribosome, Ribosomes, Protein Binding

Abstract

Nanoflow electrospray ionization has been used to introduce intact Escherichia coli ribosomes into the ion source of a mass spectrometer. Mass spectra of remarkable quality result from a partial, but selective, dissociation of the particles within the mass spectrometer. Peaks in the spectra have been assigned to individual ribosomal proteins and to noncovalent complexes of up to five component proteins. The pattern of dissociation correlates strongly with predicted features of ribosomal protein–protein and protein–RNA interactions. The spectra allow the dynamics and state of folding of specific proteins to be investigated in the context of the intact ribosome. This study demonstrates a potentially general strategy to probe interactions within complex biological assemblies.

Published

1998

23. The effect of macromolecular crowding on chaperonin-mediated protein folding

Author

Franz-Ulrich Hartl and Justin W. Martin

Subjects

Protein Folding, macromolecular substances, Plasma protein binding, Biology, Models, Biological, Chaperonin, Cytosol, Chaperonin 10, Ficoll, Multidisciplinary, Dextrans, Chaperonin 60, GroES, Biological Sciences, GroEL, Thiosulfate Sulfurtransferase, enzymes and coenzymes (carbohydrates), Biochemistry, Chaperone (protein), biological sciences, Foldase, biology.protein, Biophysics, bacteria, Protein folding, Macromolecular crowding, Protein Binding

Abstract

The cylindrical chaperonin GroEL and its cofactor GroES mediate ATP-dependent protein folding in Escherichia coli . Recent studies in vitro demonstrated that GroES binding to GroEL causes the displacement of unfolded polypeptide into the central volume of the GroEL cavity for folding in a sequestrated environment. Resulting native protein leaves GroEL upon GroES release, whereas incompletely folded polypeptide can be recaptured for structural rearrangement followed by another folding trial. Additionally, each cycle of GroES binding and dissociation is associated with the release of nonnative polypeptide into the bulk solution. Here we show that this loss of substrate from GroEL is prevented when the folding reaction is carried out in the presence of macromolecular crowding agents, such as Ficoll and dextran, or in a dense cytosolic solution. Thus, the release of nonnative polypeptide is not an essential feature of the productive chaperonin mechanism. Our results argue that conditions of excluded volume, thought to prevail in the bacterial cytosol, increase the capacity of the chaperonin to retain nonnative polypeptide throughout successive reaction cycles. We propose that the leakiness of the chaperonin system under physiological conditions is adjusted such that E. coli proteins are likely to complete folding without partitioning between different GroEL complexes. Polypeptides that are unable to fold on GroEL eventually will be transferred to other chaperones or the degradation machinery.

Published

1997

24. Molecular Chaperones in Cellular Protein Folding: Mechanisms and Pathways

Author

Franz-Ulrich Hartl

Subjects

Co-chaperone, biology, Chemistry, Chaperone (protein), Genetics, biology.protein, Chemical chaperone, Molecular Biology, Biochemistry, Biotechnology, Cellular protein, Cell biology

Published

2013

25. Pharmacologic shifting of a balance between protein refolding and degradation mediated by Hsp90

Author

E Nimmesgern, Franz-Ulrich Hartl, Ouathek Ouerfelli, Laura Sepp-Lorenzino, C Schneider, Neal Rosen, and Samuel J. Danishefsky

Subjects

Protein Folding, Multidisciplinary, medicine.diagnostic_test, Kinase, Proteolysis, Biological Sciences, Biology, Hsp90, Hsp70, Cell biology, Biochemistry, polycyclic compounds, medicine, biology.protein, Animals, Humans, Protein folding, Luciferase, HSP90 Heat-Shock Proteins, Signal transduction, Luciferases, Signal Transduction, Ansamycins

Abstract

The role of the abundant stress protein Hsp90 in protecting cells against stress-induced damage is not well understood. The recent discovery that a class of ansamycin antibiotics bind specifically to Hsp90 allowed us to address this problem from a new angle. We find that mammalian Hsp90, in cooperation with Hsp70, p60, and other factors, mediates the ATP-dependent refolding of heat-denatured proteins, such as firefly luciferase. Failure to refold results in proteolysis. The ansamycins inhibit refolding, both in vivo and in a cell extract, by preventing normal dissociation of Hsp90 from luciferase, causing its enhanced degradation. This mechanism also explains the ansamycin-induced proteolysis of several protooncogenic protein kinases, such as Raf-1, which interact with Hsp90. We propose that Hsp90 is part of a quality control system that facilitates protein refolding or degradation during recovery from stress. This function is used by a limited set of signal transduction molecules for their folding and regulation under nonstress conditions. The ansamycins shift the mode of Hsp90 from refolding to degradation, and this effect is probably amplified for specific Hsp90 substrates.

Published

1996

26. Mechanism of chaperonin action: GroES binding and release can drive GroEL-mediated protein folding in the absence of ATP hydrolysis

Author

F Weber, Franz-Ulrich Hartl, and Manajit Hayer-Hartl

Subjects

General Immunology and Microbiology, biology, General Neuroscience, macromolecular substances, GroES, GroEL, General Biochemistry, Genetics and Molecular Biology, Chaperonin, enzymes and coenzymes (carbohydrates), Protein structure, Biochemistry, ATP hydrolysis, Chaperone (protein), biological sciences, Foldase, health occupations, biology.protein, Biophysics, bacteria, Protein folding, Molecular Biology

Abstract

As a basic principle, assisted protein folding by GroEL has been proposed to involve the disruption of misfolded protein structures through ATP hydrolysis and interaction with the cofactor GroES. Here, we describe chaperonin subreactions that prompt a re-examination of this view. We find that GroEL-bound substrate polypeptide can induce GroES cycling on and off GroEL in the presence of ADP. This mechanism promotes efficient folding of the model protein rhodanese, although at a slower rate than in the presence of ATP. Folding occurs when GroES displaces the bound protein into the sequestered volume of the GroEL cavity. Resulting native protein leaves GroEL upon GroES release. A single-ring variant of GroEL is also fully functional in supporting this reaction cycle. We conclude that neither the energy of ATP hydrolysis nor the allosteric coupling of the two GroEL rings is directly required for GroEL/GroES-mediated protein folding. The minimal mechanism of the reaction is the binding and release of GroES to a polypeptide-containing ring of GroEL, thereby closing and opening the GroEL folding cage. The role of ATP hydrolysis is mainly to induce conformational changes in GroEL that result in GroES cycling at a physiologically relevant rate.

Published

1996

27. A zinc finger-like domain of the molecular chaperone DnaJ is involved in binding to denatured protein substrates

Author

Franz-Ulrich Hartl, R Korszun, A Szabo, and J Flanagan

Subjects

Zinc finger, chemistry.chemical_classification, endocrine system, General Immunology and Microbiology, General Neuroscience, Plasma protein binding, Biology, DNAJ Protein, General Biochemistry, Genetics and Molecular Biology, Amino acid, Biochemistry, chemistry, Consensus sequence, Protein folding, Binding site, Molecular Biology, Peptide sequence

Abstract

The Escherichia coli heat-shock protein DnaJ cooperates with the Hsp70 homolog DnaK in protein folding in vitro and in vivo. Little is known about the structural features of DnaJ that mediate its interaction with DnaK and unfolded polypeptide. DnaJ contains at least four blocks of sequence representing potential functional domains which have been conserved throughout evolution. In order to understand the role of each of these regions, we have analyzed DnaJ fragments in reactions corresponding to known functions of the intact protein. Both the N-terminal 70 amino acid 'J-domain' and a 35 amino acid glycine-phenylalanine region following it are required for interactions with DnaK. However, only complete DnaJ can cooperate with DnaK and a third protein, GrpE, in refolding denatured firefly luciferase. As demonstrated by atomic absorption and extended X-ray absorption fine structure spectroscopy (EXAFS), the 90 amino acid cysteine-rich region of DnaJ contains two Zn atoms tetrahedrally coordinated to four cysteine residues, resembling their arrangement in the C4 Zn binding domains of certain DNA binding proteins. Interestingly, binding experiments and cross-linking studies indicate that this Zn finger-like domain is required for the DnaJ molecular chaperone to specifically recognize and bind to proteins in their denatured state.

Published

1996

28. Protein folding in the cell: competing models of chaperonin function

Author

Franz-Ulrich Hartl and R J Ellis

Subjects

Protein Folding, Chaperonins, Chemistry, Cell, Chaperonin 60, GroES, medicine.disease_cause, Models, Biological, Biochemistry, GroEL, In vitro, Chaperonin, medicine.anatomical_structure, Chaperonin 10, Genetics, medicine, Biophysics, bacteria, Protein folding, Molecular Biology, Escherichia coli, Intracellular, Biotechnology

Abstract

The long-standing view that polypeptide chains newly synthesized inside cells fold spontaneously to their functional conformations in an energy-independent fashion derives from the observation that many pure denatured proteins will refold spontaneously in vitro when the denaturant is removed. This view is being challenged by the alternative proposal that in vivo many chains need to be helped to fold correctly by preexisting proteins acting as molecular chaperones, some of which hydrolyse ATP. The need for molecular chaperones arises because of the high concentrations of transiently interacting protein surfaces inside cells permit the formation of incorrect nonfunctional structures. The best-studied family of molecular chaperones are called the chaperonins, the archetypal examples being the GroEL and GroES proteins of Escherichia coli. The chaperonins increase the yield of correctly refolded polypeptide chains, both by decreasing their propensity to aggregate with one another and by allowing polypeptides kinetically trapped in incorrect conformations to make fresh attempts to refold into the functional conformations. The mechanisms by which the chaperonins achieve these remarkable results are currently under debate. This review surveys competing models for chaperonin action, and emphasizes the importance when evaluating these models of considering the intracellular environment in which the chaperonins have evolved to function.

Published

1996

29. The role of molecular chaperones in protein folding

Author

J P Hendrick and Franz-Ulrich Hartl

Subjects

Protein Folding, Protein Conformation, Biochemistry, Ribosome, Chaperonin, Structure-Activity Relationship, Protein structure, Genetics, Animals, HSP70 Heat-Shock Proteins, Molecular Biology, biology, Cell Membrane, Chaperonin 60, GroEL, Cell biology, Co-chaperone, Eukaryotic Cells, Prokaryotic Cells, Protein Biosynthesis, Chaperone (protein), biology.protein, Protein folding, Chemical chaperone, Molecular Chaperones, Protein Binding, Biotechnology

Abstract

Folding of newly synthesized polypeptides in the crowded cellular environment requires the assistance of so-called molecular chaperone proteins. Chaperones of the Hsp70 class and their partner proteins interact with nascent polypeptide chains on ribosomes and prevent their premature (mis)folding at least until a domain capable of forming a stable structure is synthesized. For many proteins, completion of folding requires the subsequent interaction with one of the large oligomeric ring-shaped proteins of the chaperonin family, which is composed of the GroEL-like proteins in eubacteria, mitochondria, and chloroplasts, and the TRiC family in eukaryotic cytosol and archaea. These proteins bind partially folded polypeptide in their central cavity and promote folding by ATP-dependent cycles of release and rebinding. In these reactions, molecular chaperones interact predominantly with the hydrophobic surfaces exposed by nonnative polypeptides, thereby preventing incorrect folding and aggregation.

Published

1995

30. Asymmetrical Interaction of GroEL and GroES in the ATPase Cycle of Assisted Protein Folding

Author

Franz-Ulrich Hartl, J Martin, and Manajit Hayer-Hartl

Subjects

Protein Folding, macromolecular substances, Chaperonin, chemistry.chemical_compound, Adenosine Triphosphate, ATP hydrolysis, Chaperonin 10, Magnesium, Adenosine Triphosphatases, Multidisciplinary, biology, Hydrolysis, Serine Endopeptidases, Chaperonin 60, GroES, Hydrogen-Ion Concentration, GroEL, Adenosine Diphosphate, Kinetics, enzymes and coenzymes (carbohydrates), Biochemistry, chemistry, Chaperone (protein), biological sciences, Foldase, health occupations, biology.protein, Biophysics, bacteria, Protein folding, Endopeptidase K, Adenosine triphosphate

Abstract

The chaperonins GroEL and GroES of Escherichia coli facilitate protein folding in an adenosine triphosphate (ATP)-dependent reaction cycle. The kinetic parameters for the formation and dissociation of GroEL-GroES complexes were analyzed by surface plasmon resonance. Association of GroES and subsequent ATP hydrolysis in the interacting GroEL toroid resulted in the formation of a stable GroEL:ADP:GroES complex. The complex dissociated as a result of ATP hydrolysis in the opposite GroEL toroid, without formation of a symmetrical GroEL:(GroES)2 intermediate. Dissociation was accelerated by the addition of unfolded polypeptide. Thus, the functional chaperonin unit is an asymmetrical GroEL:GroES complex, and substrate protein plays an active role in modulating the chaperonin reaction cycle.

Published

1995

31. Functional Significance of Symmetrical Versus Asymmetrical GroEL-GroES Chaperonin Complexes

Author

Günter Pfeifer, Shirley A. Müller, Franz-Ulrich Hartl, A. Da Silva, Manajit Hayer-Hartl, Wolfgang Baumeister, R Hegerl, Kenneth N. Goldie, and Andreas Engel

Subjects

Microscopy, Electron, Scanning Transmission, Protein Folding, Adenylyl Imidodiphosphate, macromolecular substances, Plasma protein binding, medicine.disease_cause, Chaperonin, Adenosine Triphosphate, Chaperonin 10, medicine, Magnesium, Escherichia coli, Multidisciplinary, biology, Chaperonin 60, GroES, Hydrogen-Ion Concentration, GroEL, enzymes and coenzymes (carbohydrates), Crystallography, Chaperone (protein), biological sciences, Foldase, health occupations, Biophysics, biology.protein, bacteria, Protein folding

Abstract

The Escherichia coli chaperonin GroEL and its regulator GroES are thought to mediate adenosine triphosphate-dependent protein folding as an asymmetrical complex, with substrate protein bound within the GroEL cylinder. In contrast, a symmetrical complex formed between one GroEL and two GroES oligomers, with substrate protein binding to the outer surface of GroEL, was recently proposed to be the functional chaperonin unit. Electron microscopic and biochemical analyses have now shown that unphysiologically high magnesium concentrations and increased pH are required to assemble symmetrical complexes, the formation of which precludes the association of unfolded polypeptide. Thus, the functional significance of GroEL:(GroES)2 particles remains to be demonstrated.

Published

1995

32. The Thermosome of Thermoplasma acidophilum and Its Relationship to the Eukaryotic Chaperonin TRiC

Author

Günter Pfeifer, J. Kellermann, Shirley A. Müller, Elmar Nimmesgern, Andreas Engel, Michael Nitsch, Wolfgang Baumeister, Franz-Ulrich Hartl, Thomas Waldmann, and Jürgen Peters

Subjects

Male, Protein Denaturation, Chaperonins, Thermoplasma, Ubiquitin-Protein Ligases, Molecular Sequence Data, ved/biology.organism_classification_rank.species, In Vitro Techniques, Biochemistry, Thermosome, T-Complex Genome Region, Chaperonin, Bacterial Proteins, Animals, Amino Acid Sequence, t-Complex Genome Region, Adenosine Triphosphatases, Sulfolobus shibatae, Sequence Homology, Amino Acid, biology, Molecular mass, ved/biology, Intracellular Signaling Peptides and Proteins, Nuclear Proteins, Thermoplasma acidophilum, biology.organism_classification, GroEL, Molecular Weight, Microscopy, Electron, Testicular Hormones, Crystallography, Biophysics, Cattle, Electrophoresis, Polyacrylamide Gel, Microtubule-Associated Proteins

Abstract

A high molecular-mass protein complex from the archaebacterium Thermoplasma acidophilum, referred to here as the 'thermosome', is built from two subunits (M(r) 58 and 60). The thermosome has been purified to homogeneity. The molecular mass of the native complex was determined to be 1061 +/- 30 Da by scanning transmission electron microscopy. It shows a weak ATPase activity and is able to bind denatured polypeptides. Averages obtained from electron micrographs of negatively stained molecules in the end-on and side-on orientations, respectively, were compared with those of the t-complex polypeptide 1 ring complex (TRiC), isolated from bovine testes. Both molecules consist of two stacked pseudo eightfold symmetric rings which build up a cylindrical particle with a large cavity in the center. Sequence alignments of peptides generated from both subunits of the thermosome and different subunits of TRiC reveal a high partial similarity to each other and to the archaebacterial chaperonin thermophilic factor 55 from Sulfolobus shibatae as well as to eukaryotic TCP1 proteins. These striking structural similarities confirm the proposition that all these molecules belong to a single protein family which is structurally and functionally related to the GroEL class of molecular chaperones.

Published

1995

33. Conformation of GroEL-bound α-lactalbumin probed by mass spectrometry

Author

S J Eyles, Michael Gross, Christopher M. Dobson, Mark Mayhew, Franz-Ulrich Hartl, Sheena E. Radford, Carol V. Robinson, and Jonathan J. Ewbank

Subjects

Multidisciplinary, biology, Protein Conformation, Chemistry, Electrospray ionization, Analytical chemistry, Chaperonin 60, Mass spectrometry, GroEL, Mass Spectrometry, Molten globule, Kinetics, Crystallography, Protein structure, Chaperone (protein), Escherichia coli, Lactalbumin, biology.protein, Animals, Cattle, Disulfides, Protein secondary structure, Hydrogen, Protein Binding, GroEL Protein

Abstract

The conformation of a three-disulphide derivative of bovine alpha-lactalbumin bound to the molecular chaperone GroEL has been investigated by monitoring directly its hydrogen exchange kinetics using electrospray ionization mass spectrometry. The bound protein is weakly protected from exchange to an extent closely similar to that of an uncomplexed molten globule state of the three-disulphide protein. Binding to GroEL in this system appears to involve relatively disordered partly folded states resembling intermediates formed in the very early stages of kinetic folding of many proteins in vitro.

Published

1994

34. Conformational specificity of the chaperonin GroEL for the compact folding intermediates of alpha-lactalbumin

Author

Manajit Hayer-Hartl, Franz-Ulrich Hartl, T.E. Creighton, and J.J. Ewbank

Subjects

Models, Molecular, Protein Folding, Protein Conformation, Stereochemistry, Biology, General Biochemistry, Genetics and Molecular Biology, Chaperonin, Iodoacetamide, Protein structure, Bacterial Proteins, Animals, Disulfides, Molecular Biology, Protein secondary structure, Heat-Shock Proteins, General Immunology and Microbiology, General Neuroscience, Chaperonin 60, GroEL, Peptide Fragments, Molten globule, Protein tertiary structure, Folding (chemistry), Biochemistry, biological sciences, Lactalbumin, Cattle, Salts, Protein folding, Protein Binding, Research Article

Abstract

The chaperonin GroEL binds unfolded polypeptides, preventing aggregation, and then mediates their folding in an ATP-dependent process. To understand the structural features in non-native polypeptides recognized by GroEL, we have used alpha-lactalbumin (alpha LA) as a model substrate. alpha LA (14.2 kDa) is stabilized by four disulfide bonds and a bound Ca2+ ion, offering the possibility of trapping partially folded disulfide intermediates between the native and the fully unfolded state. The conformers of alpha LA with high affinity for GroEL are compact, containing up to three disulfide bonds, and have significant secondary structure, but lack stable tertiary structure and expose hydrophobic surfaces. Complex formation requires almost the complete alpha LA sequence and is strongly dependent on salts that stabilize hydrophobic interactions. Unfolding of alpha LA to an extended state as well as the burial of hydrophobic surface upon formation of ordered tertiary structure prevent the binding to GroEL. Interestingly, GroEL interacts only with a specific subset of the many partially folded disulfide intermediates of alpha LA and thus may influence in vitro the kinetics of the folding pathways that lead to disulfide bonds with native combinations. We conclude that the chaperonin interacts with the hydrophobic surfaces exposed by proteins in a flexible compact intermediate or molten globule state.

Published

1994

35. Tcp20, a subunit of the eukaryotic TRiC chaperonin from humans and yeast

Author

L M Richard, W Z Li, Marshall A. Lichtman, Thomas S. Cardillo, P Lin, Franz-Ulrich Hartl, Fred Sherman, Judith Frydman, D Toth, and T R Boal

Subjects

Protein subunit, Saccharomyces cerevisiae, Protein primary structure, macromolecular substances, Cell Biology, Biology, biology.organism_classification, Biochemistry, GroEL, Molecular biology, Chaperonin, Essential gene, HSP60, sense organs, Molecular Biology, Peptide sequence

Abstract

Members of the Hsp60 chaperonin family, such as Escherichia coli GroEL/S and the eukaryotic cytosolic chaperonin complex, TRiC (TCP ring complex), are double toroid complexes capable of assisting the folding of proteins in vitro in an ATP-dependent fashion. TRiC differs from the GroEL chaperonin in that it has a hetero rather than homo-oligomeric subunit composition and lacks a GroES-like regulatory cofactor. We have established greater than 57% identity between a protein encoded by the TCP20 gene from a human cDNA library and the newly identified protein encoded by the TCP20 gene located on the right arm of chromosome IV of the yeast Saccharomyces cerevisiae. These Tcp20 proteins showed approximately 30% identity to Tcp1, a known subunit of TRiC. Gel filtration, followed by Western analysis of purified bovine testis TRiC with a Tcp20-specific antibody, indicated that Tcp20 is a subunit of the hetero-oligomeric TRiC. Gene disruption experiments showed that TCP20, like TCP1, is an essential gene in yeast, consistent with the view that TRiC is required for folding of key proteins. The amino acid sequence similarities and the derived evolutionary relationships established that the human and yeast Tcp20 proteins represent members of a new family of subunits of TRiC chaperonins.

Published

1994

36. Role of the chaperonin cofactor Hsp10 in protein folding and sorting in yeast mitochondria

Author

Franz-Ulrich Hartl and J Höhfeld

Subjects

Protein Folding, Chaperonins, Recombinant Fusion Proteins, Genes, Fungal, Molecular Sequence Data, Saccharomyces cerevisiae, Biology, Chaperonin, Fungal Proteins, Gene Expression Regulation, Fungal, Chaperonin 10, Amino Acid Sequence, Cloning, Molecular, Protein Precursors, Heat-Shock Proteins, Fungal protein, Base Sequence, Temperature, Proteins, Cell Biology, GroES, Articles, Chaperonin 60, Sequence Analysis, DNA, GroEL, Mitochondria, enzymes and coenzymes (carbohydrates), Biochemistry, Chaperone (protein), Mutation, biology.protein, Protein folding, HSP60, Intermembrane space, Sequence Alignment, Protein Binding

Abstract

Protein folding in mitochondria is mediated by the chaperonin Hsp60, the homologue of E. coli GroEL. Mitochondria also contain a homologue of the cochaperonin GroES, called Hsp10, which is a functional regulator of the chaperonin. To define the in vivo role of the co-chaperonin, we have used the genetic and biochemical potential of the yeast S. cerevisiae. The HSP10 gene was cloned and sequenced and temperature-sensitive lethal hsp10 mutants were generated. Our results identify Hsp10 as an essential component of the mitochondrial protein folding apparatus, participating in various aspects of Hsp60 function. Hsp10 is required for the folding and assembly of proteins imported into the matrix compartment, and is involved in the sorting of certain proteins, such as the Rieske Fe/S protein, passing through the matrix en route to the intermembrane space. The folding of the precursor of cytosolic dihydrofolate reductase (DHFR), imported into mitochondria as a fusion protein, is apparently independent of Hsp10 function consistent with observations made for the chaperonin-mediated folding of DHFR in vitro. The temperature-sensitive mutations in Hsp10 map to a domain (residues 25-40) that corresponds to a previously identified mobile loop region of bacterial GroES and result in a reduced binding affinity of hsp10 for the chaperonin at the non-permissive temperature.

Published

1994

37. Molecular chaperones in protein folding: the art of avoiding sticky situations

Author

Roman Hlodan, Franz-Ulrich Hartl, and Thomas Langer

Subjects

Protein Folding, Chaperonins, Proteins, Biology, Biochemistry, Chaperonin, Cell biology, Fungal Proteins, Co-chaperone, Bacterial Proteins, Chaperone (protein), Foldase, Native state, biology.protein, Animals, Humans, HSP60, Protein folding, Chemical chaperone, Molecular Biology, Heat-Shock Proteins

Abstract

Molecular chaperones are a class of proteins that interact with the non-native conformations of other proteins. The major role of chaperones of the Hsp70 and Hsp60 families is to prevent aggregation of newly synthesized polypeptides and then to mediate their folding to the native state. As a result of functional studies of these proteins, there has been a revision of the long-held view that protein folding in the cell is a spontaneous process.

Published

1994

38. Identification of nucleotide-binding regions in the chaperonin proteins GroEL and GroES

Author

Jörg Martin, Scott J. Geromanos, Paul Tempst, and Franz-Ulrich Hartl

Subjects

chemistry.chemical_classification, Multidisciplinary, macromolecular substances, GroES, Biology, GroEL, Cofactor, Chaperonin, Biochemistry, chemistry, biological sciences, Foldase, biology.protein, bacteria, Protein folding, Nucleotide, Binding site

Abstract

THE chaperonin GroEL, a tetradecameric cylinder consisting of subunits of Mr∼60,000 (60K), and its cofactor GroES, a heptameric ring of 10K subunits, mediate protein folding in the cytosol of Escherichia coll1–3. In the presence of nucleotide, GroES forms a 1:1 complex with GroEL which binds unfolded protein in its central cavity and releases it to allow folding upon ATP hydrolysis4–7. Using labelling with azido-ATP, we have identified a protease-stable nucleotide-binding domain of Mr 40K in the GroEL subunits (residues 153-531). Azido-ATP is crosslinked to the highly conserved Tyr 477, indicating that this residue is close to the purine ring of the bound nucleotide. Surprisingly, GroES also binds ATP cooperatively and with an affinity comparable to that of GroEL. Azido-nucleotide labelling of GroES subunits occurs at the conserved Tyr 71 in a protease-stable 6.5K domain (starting at residue 33). Proteinase K cleavage at residue 32 is prevented when GroES is bound to GroEL. ATP binding to GroES may be important in charging the seven subunits of the interacting GroEL ring with ATP to facilitate cooperative ATP binding and hydrolysis for substrate protein release.

Published

1993

39. MOLECULAR CHAPERONE FUNCTIONS OF HEAT-SHOCK PROTEINS

Author

Franz-Ulrich Hartl and Joseph P. Hendrick

Subjects

Protein Folding, biology, Protein metabolism, Proteins, Chaperonin 60, Metabolism, Protein degradation, Biochemistry, Hsp70, chemistry.chemical_compound, Bacterial Proteins, chemistry, Chaperone (protein), Heat shock protein, Chaperonin 10, biology.protein, Animals, Humans, Protein folding, Protein Precursors, Heat-Shock Proteins, DNA

Abstract

3. HSP70 PROTEINS: CHAPERONES WITH DIVERSE ROLES IN PROTEIN METABOLISM . . .. . . . . . . . . .. . . . . .. . . ... . . . .... . . . . 357 Structure and Function of Hsp70 Chaperones . . . . . . . . . . . . . . . . . . . . . . . 357 Maintenance of the Translocation-Competent State of Precursor Proteins . . . . . . 359 The Hsp70 DnaK and Dna! are a Chaperone Team . . . . . . . . . . . . . . . . . . . 360 Organellar Hsp70s in Membrane Translocation and Folding .. . . . .. . . . . . . 361 Hsp70 in Cells Under Metabolic Stress . . . . . . . . . . . . . . . . . . . . . . . . . . . 362 Hsp70 and Protein Degradation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 363

Published

1993

40. Affinity purification of molecular chaperones of the yeast Hansenula polymorpha using immobilized denatured alcohol oxidase

Author

Bettina Huhse, Melchior E. Evers, Marten Veenhuis, Wolf H. Kunau, Vladimir I. Titorenko, Willem Harder, Franz-Ulrich Hartl, and Groningen Biomolecular Sciences and Biotechnology

Subjects

Protein Denaturation, Chaperonins, PEROXISOME, COMPLEX FORMATION, PROTEINS, Molecular Sequence Data, Saccharomyces cerevisiae, Biophysics, Biochemistry, Chromatography, Affinity, Pichia, Chaperonin, Hansenula polymorpha, Fungal Proteins, SACCHAROMYCES-CEREVISIAE, Bacterial Proteins, Affinity chromatography, Structural Biology, Genetics, HSP, Amino Acid Sequence, ALCOHOL OXIDASE, Molecular Biology, Heat-Shock Proteins, CHAPERONE, Gel electrophoresis, biology, Chaperonin 60, Cell Biology, Enzymes, Immobilized, biology.organism_classification, GroEL, Molecular biology, Yeast, Alcohol oxidase, Alcohol Oxidoreductases, Chaperone (protein), biology.protein, HANSENULA-POLYMORPHA

Abstract

We used peroxisomal alcohol oxidase (AO) for the affinity purification of molecular chaperones from yeasts. Methodical studies showed that up to 0.8 mg of purified bacterial GroEL was able to bind per ml of immobilized denatured AO column material. Using crude extracts of Hansenula polymorpha or Saccharomyces cerevisiae, several proteins were specifically eluted with Mg-ATP which were recognized by antibodies against hsp60 or hsp70. One H. polymorpha 70 kDa protein was strongly induced during growth at elevated temperatures, whereas a second 70 kDa protein as well as a 60 kDa protein showed strong protein sequence homology to mitochondrial SSCI and hsp60, respectively, from S. cerevisiae.

Published

1993

41. A signal recognition particle in Escherichia coli?

Author

Franz-Ulrich Hartl and Martin Wiedmann

Subjects

Signal recognition particle, Biochemistry, medicine, Biology, General Agricultural and Biological Sciences, medicine.disease_cause, Escherichia coli, General Biochemistry, Genetics and Molecular Biology

Published

1993

42. Two related genes encoding extremely hydrophobic proteins suppress a lethal mutation in the yeast mitochondrial processing enhancing protein

Author

Walter Neupert, Jörg Martin, Franz-Ulrich Hartl, Ann H. West, Deborah J. Clark, and Arthur L. Horwich

Subjects

Signal peptide, Mutation, biology, Sequence analysis, Saccharomyces cerevisiae, Cell Biology, Mitochondrion, Membrane transport, biology.organism_classification, medicine.disease_cause, Biochemistry, Plasmid, medicine, Inner mitochondrial membrane, Molecular Biology

Abstract

The processing enhancing protein of mitochondria (PEP) is an essential component that has been shown to participate in proteolytic removal of NH2-terminal signal peptides from precursor proteins imported into the mitochondrial matrix. Using a yeast strain bearing a PEP mutation that renders it temperature-sensitive, an approach of genetic suppression was taken in order to identify additional components that could be involved with protein import: high copy plasmids comprising a yeast genomic library were tested for ability to suppress the 37 degrees C growth defect. Two plasmids were isolated, pSMF1 and pSMF2, which suppressed the growth defect nearly as well as the cloned PEP gene itself. Sequence analysis of the rescuing genes predicted extremely hydrophobic proteins with sizes of 63 and 60 kDa, respectively. Remarkably, the predicted SMF1 and SMF2 products are 49% identical to each other overall. To test the requirement for SMF1 and SMF2, the chromosomal genes were disrupted. Individual disruption was without effect, but cells in which both genes were disrupted grew poorly. When mitochondria were prepared from the double disruption strain grown in a nonfermentable carbon source, they were morphologically normal but defective for translocation of radiolabeled precursor proteins. SMF1 protein was provisionally localized to the mitochondrial membranes using epitope tagging. We suggest that SMF1 and SMF2 are mitochondrial membrane proteins that influence PEP-dependent protein import, possibly at the step of protein translocation.

Published

1992

43. Chaperonin-mediated protein folding: GroES binds to one end of the GroEL cylinder, which accommodates the protein substrate within its central cavity

Author

Thomas Langer, Franz-Ulrich Hartl, Günter Pfeifer, Wolfgang Baumeister, and Jörg Martin

Subjects

Protein Folding, GroES Protein, macromolecular substances, General Biochemistry, Genetics and Molecular Biology, Chaperonin, Bacterial Proteins, Chaperonin 10, Escherichia coli, Image Processing, Computer-Assisted, Molecular Biology, Heat-Shock Proteins, GroEL Protein, General Immunology and Microbiology, biology, General Neuroscience, Chaperonin 60, GroES, GroEL, Microscopy, Electron, enzymes and coenzymes (carbohydrates), Biochemistry, Chaperone (protein), biological sciences, Foldase, Chromatography, Gel, health occupations, biology.protein, Biophysics, bacteria, Electrophoresis, Polyacrylamide Gel, Protein folding, Research Article

Abstract

The mechanism of GroEL (chaperonin)-mediated protein folding is only partially understood. We have analysed structural and functional properties of the interaction between GroEL and the co-chaperonin GroES. The stoichiometry of the GroEL 14mer and the GroES 7mer in the functional holo-chaperonin is 1:1. GroES protects half of the GroEL subunits from proteolytic truncation of the approximately 50 C-terminal residues. Removal of this region results in an inhibition of the GroEL ATPase, mimicking the effect of GroES on full-length GroEL. Image analysis of electron micrographs revealed that GroES binding triggers conspicuous conformational changes both in the GroES adjacent end and at the opposite end of the GroEL cylinder. This apparently prohibits the association of a second GroES oligomer. Addition of denatured polypeptide leads to the appearance of irregularly shaped, stain-excluding masses within the GroEL double-ring, which are larger with bound alcohol oxidase (75 kDa) than with rhodanese (35 kDa). We conclude that the functional complex of GroEL and GroES is characterized by asymmetrical binding of GroES to one end of the GroEL cylinder and suggest that binding of the substrate protein occurs within the central cavity of GroEL.

Published

1992

44. Function in protein folding of TRiC, a cytosolic ring complex containing TCP-1 and structurally related subunits

Author

Judith Frydman, Hediye Erdjument-Bromage, Franz-Ulrich Hartl, E Nimmesgern, J S Wall, and Paul Tempst

Subjects

Male, Microscopy, Electron, Scanning Transmission, Protein Folding, Chaperonins, Ubiquitin-Protein Ligases, Molecular Sequence Data, macromolecular substances, Thermosome, T-Complex Genome Region, General Biochemistry, Genetics and Molecular Biology, Chaperonin, Adenosine Triphosphate, Bacterial Proteins, Tubulin, Animals, Amino Acid Sequence, Luciferases, Molecular Biology, Heat-Shock Proteins, t-Complex Genome Region, Adenosine Triphosphatases, Sequence Homology, Amino Acid, General Immunology and Microbiology, biology, General Neuroscience, Intracellular Signaling Peptides and Proteins, Nuclear Proteins, Proteins, Chaperonin 60, GroES, GroEL, Coleoptera, Enzyme Activation, enzymes and coenzymes (carbohydrates), Biochemistry, Chaperone (protein), biological sciences, biology.protein, Biophysics, bacteria, Cattle, Electrophoresis, Polyacrylamide Gel, Protein folding, HSP60, sense organs, Microtubule-Associated Proteins, Protein Binding, Research Article

Abstract

T-complex polypeptide 1 (TCP-1) was analyzed as a potential chaperonin (GroEL/Hsp60) equivalent of the eukaryotic cytosol. We found TCP-1 to be part of a hetero-oligomeric 970 kDa complex containing several structurally related subunits of 52-65 kDa. These members of a new protein family are assembled into a TCP-1 ring complex (TRiC) which resembles the GroEL double ring. The main function of TRiC appears to be in chaperoning monomeric protein folding: TRiC binds unfolded polypeptides, thereby preventing their aggregation, and mediates the ATP-dependent renaturation of unfolded firefly luciferase and tubulin. At least in vitro, TRiC appears to function independently of a small co-chaperonin protein such as GroES. Folding of luciferase is mediated by TRiC but not by GroEL/ES. This suggests that the range of substrate proteins interacting productively with TRiC may differ from that of GroEL. We propose that TRiC mediates the folding of cytosolic proteins by a mechanism distinct from that of the chaperonins in specific aspects.

Published

1992

45. Prevention of Protein Denaturation Under Heat Stress by the Chaperonin Hsp60

Author

Franz-Ulrich Hartl, J Martin, and Arthur L. Horwich

Subjects

Protein Denaturation, Protein Folding, Hot Temperature, Saccharomyces cerevisiae, Chaperonin, HSPA4, Adenosine Triphosphate, Bacterial Proteins, Heat shock protein, Dihydrofolate reductase, Chaperonin 10, Heat-Shock Proteins, Multidisciplinary, Neurospora crassa, biology, Caseins, Chaperonin 60, Mitochondria, Hsp70, Tetrahydrofolate Dehydrogenase, Biochemistry, Chaperone (protein), biology.protein, Biophysics, Thermodynamics, Electrophoresis, Polyacrylamide Gel, Protein folding, HSP60

Abstract

The increased synthesis of heat shock proteins is a ubiquitous physiological response of cells to environmental stress. How these proteins function in protecting cellular structures is not yet understood. The mitochondrial heat shock protein 60 (Hsp60) has now been shown to form complexes with a variety of polypeptides in organelles exposed to heat stress. The Hsp60 was required to prevent the thermal inactivation in vivo of native dihydrofolate reductase (DHFR) imported into mitochondria. In vitro, Hsp60 bound to DHFR in the course of thermal denaturation, preventing its aggregation, and mediated its adenosine triphosphate-dependent refolding at increased temperatures. These results suggest a general mechanism by which heat shock proteins of the Hsp60 family stabilize preexisting proteins under stress conditions.

Published

1992

46. A molecular chaperone from a thermophilic archaebacterium is related to the eukaryotic protein t-complex polypeptide-1

Author

J D Trent, E Nimmesgern, Joseph S. Wall, Arthur L. Horwich, and Franz-Ulrich Hartl

Subjects

Archaeal Proteins, Ubiquitin-Protein Ligases, Molecular Sequence Data, Saccharomyces cerevisiae, ved/biology.organism_classification_rank.species, T-Complex Genome Region, Sulfolobus, Chaperonin, Mice, Bacterial Proteins, Sequence Homology, Nucleic Acid, Group I Chaperonins, Animals, Amino Acid Sequence, Heat-Shock Proteins, t-Complex Genome Region, Adenosine Triphosphatases, Sulfolobus shibatae, Multidisciplinary, Base Sequence, biology, ved/biology, Intracellular Signaling Peptides and Proteins, Temperature, Nuclear Proteins, biology.organism_classification, GroEL, DNA-Binding Proteins, Biochemistry, Chaperone (protein), biology.protein, Microtubule-Associated Proteins, Molecular Chaperones

Abstract

There is evidence to suggest that components of archaebacteria are evolutionarily related to cognates in the eukaryotic cytosol. We postulated that the major heat-shock protein of the thermophilic archaebacterium, Sulfolobus shibatae, is a molecular chaperone and that it is related to an as-yet unidentified chaperone component in the eukaryotic cytosol. Acquired thermotolerance in S. shibatae correlates with the predominant synthesis of this already abundant protein, referred to as thermophilic factor 55 (TF55). TF55 is a homo-oligomeric complex of two stacked 9-membered rings, closely resembling the 7-membered-ring complexes of the chaperonins, groEL, hsp60 and Rubisco-binding protein. The TF55 complex binds unfolded polypeptides in vitro and has ATPase activity-features consistent with its being a molecular chaperone. The primary structure of TF55, however, is not significantly related to the chaperonins. On the other hand, it is highly homologous (36-40% identity) to a ubiquitous eukaryotic protein, t-complex polypeptide-1 (TCP1). In Saccharomyces cerevisiae, TCP1 is an essential protein that may play a part in mitotic spindle formation. We suggest that TF55 in archaebacteria and TCP1 in the eukaryotic cytosol are members of a new class of molecular chaperones.

Published

1991

47. THE ENZYMOLOGY OF PROTEIN TRANSLOCATION ACROSS THE Escherichia coli PLASMA MEMBRANE

Author

William Wickner, Arnold J. M. Driessen, and Franz-Ulrich Hartl

Subjects

SIGNAL RECOGNITION PARTICLE, Signal peptide, MALTOSE-BINDING-PROTEIN, TRANSLOCASE, PROTONMOTIVE FORCE, Biological Transport, Active, TRANSLOCATION ATPASE, Protein Sorting Signals, Biochemistry, MITOCHONDRIAL PRECURSOR PROTEINS, ENDOPLASMIC-RETICULUM MEMBRANE, Maltose-binding protein, LEADER PEPTIDE, Bacterial Proteins, PROTON MOTIVE FORCE, Escherichia coli, NASCENT PERIPLASMIC PROTEINS, Translocase, Integral membrane protein, Preprotein binding, Adenosine Triphosphatases, SecA Proteins, biology, AMINO-ACID RESIDUES, Membrane transport protein, Escherichia coli Proteins, POSITIVELY CHARGED RESIDUES, Cell Membrane, BACTERIAL LEADER PEPTIDASE, Membrane Transport Proteins, Translocase of the inner membrane, CYTOPLASMIC MEMBRANE, biology.protein, SECRETION, SEC Translocation Channels

Abstract

Converging physiological, genetic, and biochemical studies have established the salient features of preprotein translocation across the plasma membrane of Escherichia coli. Translocation is catalyzed by two proteins, a soluble chaperone and a membrane-bound translocase. SecB, the major chaperone for export, forms a complex with preproteins. Complex formation inhibits side-reactions such as aggregation and misfolding and aids preprotein binding to the membrane surface. Translocase consists of functionally linked peripheral and integral membrane protein domains. SecA protein, the peripheral membrane domain of translocase, is the primary receptor for the SecB/preprotein complex. SecA hydrolyzes ATP, promoting cycles of translocation, preprotein release, Δµ~H+-dependent translocation, and rebinding of the preprotein. The membrane-embedded domain of translocase is the SecY/E protein. It has, as subunits, the SeeY and SecE polypeptides. The SecY/E protein stabilizes and activates SecA and participates in binding it to the membrane. SecA recognizes the leader domain of preproteins, whereas both SecA and SecB recognize the mature domain. Many proteins translocate without requiring SecB, and some proteins do not need translocase to assemble into the plasma membrane. Translocation is usually followed by endoproteolytic cleavage by leader peptidase. The availability of virtually every pure protein and cloned gene involved in the translocation process makes E. coli the premier organism for the study of translocation mechanisms.

Published

1991

48. ΔµH+ and ATP Function at Different Steps of the Catalytic Cycle of Preprotein Translocase

Author

William Wickner, Elmar Schiebel, Arnold J. M. Driessen, and Franz-Ulrich Hartl

Subjects

ATPase, Biology, Models, Biological, environment and public health, General Biochemistry, Genetics and Molecular Biology, Adenosine Triphosphate, Bacterial Proteins, ATP hydrolysis, Escherichia coli, Translocase, Protein Precursors, Adenosine Triphosphatases, SecYEG Translocon, SecA Proteins, Escherichia coli Proteins, Membrane Transport Proteins, Hydrogen-Ion Concentration, Membrane transport, Transmembrane protein, Kinetics, Catalytic cycle, Biochemistry, biology.protein, Biophysics, bacteria, Oxidation-Reduction, Protein Processing, Post-Translational, SEC Translocation Channels, Bacterial Outer Membrane Proteins, Protein Binding

Abstract

Preprotein translocation in E. coli requires ATP, the membrane electrochemical potential Δμ H +, and translocase, an enzyme with an ATPase domain (SecA) and the membrane-embedded SecYE. Studies of translocase and proOmpA reveal a five-step catalytic cycle: First, proOmpA binds to the SecA domain. Second, SecA binds ATP. Third, ATP-binding energy permits translocation of ∼20 residues of proOmpA. Fourth, ATP hydrolysis releases proOmpA. ProOmpA may then rebind to SecA and reenter this cycle, allowing progress through a series of transmembrane intermediates. In the absence of Δμ H + or association with SecA, proOmpA passes backward through the membrane, but moves forward when either ATP and SecA or a membrane electrochemical potential is supplied. However, in the presence of Δμ H + (fifth step), proOmpA rapidly completes translocation. Δμ H + — driven translocation is blocked by SecA plus nonhydrolyzable ATP analogs, indicating that Δμ H + drives translocation when ATP and proOmpA are not bound to SecA.

Published

1991

49. N-terminal polyglutamine-containing fragments inhibit androgen receptor transactivation function

Author

J. Ceraline, Sarah A. Broadley, Franz-Ulrich Hartl, and N. W. Schiffer

Subjects

Transcriptional Activation, Immunoprecipitation, Clinical Biochemistry, Saccharomyces cerevisiae, Blotting, Western, Bulbo-Spinal Atrophy, X-Linked, Biochemistry, Transactivation, medicine, Humans, Trichloroacetic Acid, Receptor, Luciferases, Molecular Biology, biology, Models, Genetic, RNF4, Chemistry, biology.organism_classification, medicine.disease, Molecular biology, Peptide Fragments, Androgen receptor, Microscopy, Fluorescence, Receptors, Androgen, Chromatography, Gel, Androgen insensitivity syndrome, Electrophoresis, Polyacrylamide Gel, Indicators and Reagents, Peptides, Binding domain, Plasmids, Subcellular Fractions

Abstract

Several neurodegenerative diseases, including Kennedy's disease (KD), are associated with misfolding and aggregation of polyglutamine (polyQ)-expansion proteins. KD is caused by a polyQ-expansion in the androgen receptor (AR), a key player in male sexual differentiation. Interestingly, KD patients often show signs of mild-to-moderate androgen insensitivity syndrome (AIS) resulting from AR dysfunction. Here, we used the yeast Saccharomyces cerevisiae to investigate the molecular mechanism behind AIS in KD. Upon expression in yeast, polyQ-expanded N-terminal fragments of AR lacking the hormone binding domain caused a polyQ length-dependent growth defect. Interestingly, while AR fragments with 67 Q formed large, SDS-resistant inclusions, the most pronounced toxicity was observed upon expression of 102 Q fragments which accumulated exclusively as soluble oligomers in the 100–600 kDa range. Analysis using a hormone-dependent luciferase reporter revealed that full-length polyQ-expanded AR is fully functional in transactivation, but becomes inactivated in the presence of the corresponding polyQ-expanded N-terminal fragment. Furthermore, the greatest impairment of AR activity was observed upon interaction of full-length AR with soluble AR fragments. Taken together, our results suggest that soluble polyQ-containing fragments bind to full-length AR and inactivate it, thus providing insight into the mechanism behind AIS in KD and possibly other polyglutamine diseases, such as Huntington's disease.

Published

2008

50. Protein-catalysed protein folding

Author

Franz-Ulrich Hartl, Arthur L. Horwich, and Walter Neupert

Subjects

Chaperonins, Protein Conformation, Chemistry, Catalytic function, Proteins, Bioengineering, Biological activity, Chaperonin 60, macromolecular substances, Chaperonin, Folding (chemistry), enzymes and coenzymes (carbohydrates), Mechanism of action, Biochemistry, biological sciences, medicine, bacteria, Protein folding, medicine.symptom, Heat-Shock Proteins, Biotechnology

Abstract

A number of proteins, termed chaperonins, have been identified as part of the mechanism of folding other proteins into their biologically active forms. The role of chaperonins appears to be twofold — to prevent illegitimate interactions with other proteins and to facilitate folding, possibly through an energy-dependent, catalytic function. Controlled overexpression of chaperonins may be of therapeutic value in manipulating human immune response and rescuing certain inherited human mutations.

Published

1990