Your search keyword '"Dougan DA"' showing total 50 results

1. LON is the master protease that protects against protein aggregation in human mitochondria through direct degradation of misfolded proteins

Author

Bezawork-Geleta, A, Brodie, EJ, Dougan, DA, Truscott, KN, Bezawork-Geleta, A, Brodie, EJ, Dougan, DA, and Truscott, KN

Abstract

Maintenance of mitochondrial protein homeostasis is critical for proper cellular function. Under normal conditions resident molecular chaperones and proteases maintain protein homeostasis within the organelle. Under conditions of stress however, misfolded proteins accumulate leading to the activation of the mitochondrial unfolded protein response (UPRmt). While molecular chaperone assisted refolding of proteins in mammalian mitochondria has been well documented, the contribution of AAA+ proteases to the maintenance of protein homeostasis in this organelle remains unclear. To address this gap in knowledge we examined the contribution of human mitochondrial matrix proteases, LONM and CLPXP, to the turnover of OTC-∆, a folding incompetent mutant of ornithine transcarbamylase, known to activate UPRmt. Contrary to a model whereby CLPXP is believed to degrade misfolded proteins, we found that LONM, and not CLPXP is responsible for the turnover of OTC-∆ in human mitochondria. To analyse the conformational state of proteins that are recognised by LONM, we examined the turnover of unfolded and aggregated forms of malate dehydrogenase (MDH) and OTC. This analysis revealed that LONM specifically recognises and degrades unfolded, but not aggregated proteins. Since LONM is not upregulated by UPRmt, this pathway may preferentially act to promote chaperone mediated refolding of proteins.

Published

2015

2. Effects of substitutions in the binding surface of an antibody on antigen affinity.

Author

Dougan, DA, Malby, RL, Gruen, LC, Kortt, AA, and Hudson, PJ

Published

1998

3. Editorial: Guardians of protein homeostasis (proteostasis) in health, disease and aging.

Author

Dougan DA, Truscott KN, and Kirstein J

Abstract

Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Published

2023

4. Affinity isolation and biochemical characterization of N-degron ligands using the N-recognin, ClpS.

Author

Dougan DA and Truscott KN

Subjects

Ligands, Protein Binding, Proteolysis, Peptide Hydrolases metabolism, Substrate Specificity, Escherichia coli genetics, Escherichia coli metabolism, Peptides chemistry

Abstract

The N-degron pathways are a set of proteolytic systems that relate the half-life of a protein to its N-terminal (Nt) residue. In Escherichia coli the principal N-degron pathway is known as the Leu/N-degron pathway. Proteins degraded by this pathway contain an Nt degradation signal (N-degron) composed of an Nt primary destabilizing (N d1 ) residue (Leu, Phe, Trp or Tyr). All Leu/N-degron substrates are recognized by the adaptor protein, ClpS and delivered to the ClpAP protease for degradation. Although many components of the pathway are well defined, the physiological role of this pathway remains poorly understood. To address this gap in knowledge we developed a biospecific affinity chromatography technique to isolate physiological substrates of the Leu/N-degron pathway. In this chapter we describe the use of peptide arrays to determine the binding specificity of ClpS. We demonstrate how the information obtained from the peptide array, when coupled with ClpS affinity chromatography, can be used to specifically elute physiological Leu/N-degron ligands from a bacterial lysate. These techniques are illustrated using E. coli ClpS (EcClpS), but both are broadly suitable for application to related N-recognins and systems, not only for the determination of N-recognin specificity, but also for the identification of natural Leu/N-degron ligands from various bacterial and plant species that contain ClpS homologs., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

5. ClpXP-mediated Degradation of the TAC Antitoxin is Neutralized by the SecB-like Chaperone in Mycobacterium tuberculosis.

Author

Texier P, Bordes P, Nagpal J, Sala AJ, Mansour M, Cirinesi AM, Xu X, Dougan DA, and Genevaux P

Subjects

ATPases Associated with Diverse Cellular Activities metabolism, Bacterial Proteins metabolism, Cloning, Molecular, Endopeptidase Clp metabolism, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Gene Expression, Genetic Vectors chemistry, Genetic Vectors metabolism, Genome, Bacterial, Molecular Chaperones metabolism, Mycobacterium tuberculosis metabolism, Protein Isoforms genetics, Protein Isoforms metabolism, Proteolysis, Recombinant Proteins genetics, Recombinant Proteins metabolism, ATPases Associated with Diverse Cellular Activities genetics, Bacterial Proteins genetics, Endopeptidase Clp genetics, Escherichia coli Proteins genetics, Gene Expression Regulation, Bacterial, Molecular Chaperones genetics, Mycobacterium tuberculosis genetics, Toxin-Antitoxin Systems genetics

Abstract

Bacterial toxin-antitoxin (TA) systems are composed of a deleterious toxin and its antagonistic antitoxin. They are widespread in bacterial genomes and mobile genetic elements, and their functions remain largely unknown. Some TA systems, known as TAC modules, include a cognate SecB-like chaperone that assists the antitoxin in toxin inhibition. Here, we have investigated the involvement of proteases in the activation cycle of the TAC system of the human pathogen Mycobacterium tuberculosis. We show that the deletion of endogenous AAA + proteases significantly bypasses the need for a dedicated chaperone and identify the mycobacterial ClpXP1P2 complex as the main protease involved in TAC antitoxin degradation. In addition, we show that the ClpXP1P2 degron is located at the extreme C-terminal end of the chaperone addiction (ChAD) region of the antitoxin, demonstrating that ChAD functions as a hub for both chaperone binding and recognition by proteases., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

6. Exploring a potential Achilles heel of Mycobacterium tuberculosis: defining the ClpC1 interactome.

Author

Dougan DA, Alver R, and Turgay K

Subjects

Bacterial Proteins genetics, Heat-Shock Proteins, Humans, Peptide Hydrolases, Mycobacterium tuberculosis genetics, Toxin-Antitoxin Systems

Abstract

Protein degradation plays a vital role in the correct maintenance of a cell, not only under normal physiological conditions but also in response to stress. In the human pathogen Mtb, this crucial cellular task is performed by several ATPase associated with diverse cellular activities proteases including ClpC1P. Ziemski et al. performed a bacterial adenylate cyclase two-hybrid screen to identify ClpC1 substrates and showed the Type II TA systems represent a major group of ClpC1-interacting proteins. Comment on: https://doi.org/10.1111/febs.15335., (© 2020 The Authors. The FEBS Journal published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.)

Published

2021

7. Polymerase delta-interacting protein 38 (PDIP38) modulates the stability and activity of the mitochondrial AAA+ protease CLPXP.

Author

Strack PR, Brodie EJ, Zhan H, Schuenemann VJ, Valente LJ, Saiyed T, Lowth BR, Angley LM, Perugini MA, Zeth K, Truscott KN, and Dougan DA

Subjects

Endopeptidase Clp genetics, Gene Expression Regulation, HeLa Cells, Humans, Nuclear Proteins genetics, Recombinant Proteins, Endopeptidase Clp metabolism, Mitochondria metabolism, Nuclear Proteins metabolism

Abstract

Over a decade ago Polymerase δ interacting protein of 38 kDa (PDIP38) was proposed to play a role in DNA repair. Since this time, both the physiological function and subcellular location of PDIP38 has remained ambiguous and our present understanding of PDIP38 function has been hampered by a lack of detailed biochemical and structural studies. Here we show, that human PDIP38 is directed to the mitochondrion in a membrane potential dependent manner, where it resides in the matrix compartment, together with its partner protein CLPX. Our structural analysis revealed that PDIP38 is composed of two conserved domains separated by an α/β linker region. The N-terminal (YccV-like) domain of PDIP38 forms an SH3-like β-barrel, which interacts specifically with CLPX, via the adaptor docking loop within the N-terminal Zinc binding domain of CLPX. In contrast, the C-terminal (DUF525) domain forms an immunoglobin-like β-sandwich fold, which contains a highly conserved putative substrate binding pocket. Importantly, PDIP38 modulates the substrate specificity of CLPX and protects CLPX from LONM-mediated degradation, which stabilises the cellular levels of CLPX. Collectively, our findings shed new light on the mechanism and function of mitochondrial PDIP38, demonstrating that PDIP38 is a bona fide adaptor protein for the mitochondrial protease, CLPXP.

Published

2020

8. Insight into the RssB-Mediated Recognition and Delivery of σ s to the AAA+ Protease, ClpXP.

Author

Micevski D, Zeth K, Mulhern TD, Schuenemann VJ, Zammit JE, Truscott KN, and Dougan DA

Subjects

ATPases Associated with Diverse Cellular Activities chemistry, DNA-Binding Proteins chemistry, Endopeptidase Clp chemistry, Escherichia coli Proteins chemistry, Models, Molecular, Molecular Chaperones chemistry, Mutation genetics, Phosphorylation, Protein Binding, Protein Domains, Scattering, Small Angle, Sigma Factor chemistry, Sigma Factor metabolism, Transcription Factors chemistry, X-Ray Diffraction, ATPases Associated with Diverse Cellular Activities metabolism, DNA-Binding Proteins metabolism, Endopeptidase Clp metabolism, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Molecular Chaperones metabolism, Transcription Factors metabolism

Abstract

In Escherichia coli , SigmaS (σ S ) is the master regulator of the general stress response. The cellular levels of σ S are controlled by transcription, translation and protein stability. The turnover of σ S , by the AAA+ protease (ClpXP), is tightly regulated by a dedicated adaptor protein, termed RssB (Regulator of Sigma S protein B)-which is an atypical member of the response regulator (RR) family. Currently however, the molecular mechanism of σ S recognition and delivery by RssB is only poorly understood. Here we describe the crystal structures of both RssB domains (RssB N and RssB C ) and the SAXS analysis of full-length RssB (both free and in complex with σ S ). Together with our biochemical analysis we propose a model for the recognition and delivery of σ S by this essential adaptor protein. Similar to most bacterial RRs, the N-terminal domain of RssB (RssB N ) comprises a typical mixed (βα) 5 -fold. Although phosphorylation of RssB N (at Asp58) is essential for high affinity binding of σ S , much of the direct binding to σ S occurs via the C-terminal effector domain of RssB (RssB C ). In contrast to most RRs the effector domain of RssB forms a β-sandwich fold composed of two sheets surrounded by α-helical protrusions and as such, shares structural homology with serine/threonine phosphatases that exhibit a PPM/PP2C fold. Our biochemical data demonstrate that this domain plays a key role in both substrate interaction and docking to the zinc binding domain (ZBD) of ClpX. We propose that RssB docking to the ZBD of ClpX overlaps with the docking site of another regulator of RssB, the anti-adaptor IraD. Hence, we speculate that docking to ClpX may trigger release of its substrate through activation of a "closed" state (as seen in the RssB-IraD complex), thereby coupling adaptor docking (to ClpX) with substrate release. This competitive docking to RssB would prevent futile interaction of ClpX with the IraD-RssB complex (which lacks a substrate). Finally, substrate recognition by RssB appears to be regulated by a key residue (Arg117) within the α5 helix of the N-terminal domain. Importantly, this residue is not directly involved in σ S interaction, as σ S binding to the R117A mutant can be restored by phosphorylation. Likewise, R117A retains the ability to interact with and activate ClpX for degradation of σ S , both in the presence and absence of acetyl phosphate. Therefore, we propose that this region of RssB (the α5 helix) plays a critical role in driving interaction with σ S at a distal site.

Published

2020

9. Molecular and structural insights into an asymmetric proteolytic complex (ClpP1P2) from Mycobacterium smegmatis.

Author

Nagpal J, Paxman JJ, Zammit JE, Thomas AA, Truscott KN, Heras B, and Dougan DA

Subjects

Adenosine Triphosphatases metabolism, Adenosine Triphosphatases ultrastructure, Bacterial Proteins metabolism, Crystallography, X-Ray, Endopeptidase Clp metabolism, Molecular Docking Simulation, Protein Structure, Quaternary, Proteolysis, Bacterial Proteins ultrastructure, Endopeptidase Clp ultrastructure, Mycobacterium smegmatis metabolism, Protein Multimerization, Protein Subunits metabolism

Abstract

The ClpP protease is found in all kingdoms of life, from bacteria to humans. In general, this protease forms a homo-oligomeric complex composed of 14 identical subunits, which associates with its cognate ATPase in a symmetrical manner. Here we show that, in contrast to this general architecture, the Clp protease from Mycobacterium smegmatis (Msm) forms an asymmetric hetero-oligomeric complex ClpP1P2, which only associates with its cognate ATPase through the ClpP2 ring. Our structural and functional characterisation of this complex demonstrates that asymmetric docking of the ATPase component is controlled by both the composition of the ClpP1 hydrophobic pocket (Hp) and the presence of a unique C-terminal extension in ClpP1 that guards this Hp. Our structural analysis of Msm ClpP1 also revealed openings in the side-walls of the inactive tetradecamer, which may represent sites for product egress.

Published

2019

10. The Direct Molecular Target for Imipridone ONC201 Is Finally Established.

Author

Wang S and Dougan DA

Subjects

Cell Line, Tumor, Heterocyclic Compounds, 4 or More Rings, Imidazoles, Proteolysis, Pyridines, Pyrimidines, Antineoplastic Agents

Abstract

In this issue of Cancer Cell, Ishizawa et al. describe the hyperactivation of ClpP as a strategy in cancer therapy. They discovered ONC201, a clinical-stage compound, as a potent activator of ClpP and established that ClpP activation is responsible for the antitumor activity of imipridone ONC201., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

11. N-degron specificity of chloroplast ClpS1 in plants.

Author

Montandon C, Dougan DA, and van Wijk KJ

Subjects

Amino Acid Sequence, Hydrophobic and Hydrophilic Interactions, Models, Molecular, Protein Conformation, Adaptor Proteins, Signal Transducing chemistry, Adaptor Proteins, Signal Transducing metabolism, Arabidopsis Proteins chemistry, Arabidopsis Proteins metabolism, Chloroplasts metabolism, Proteolysis

Abstract

The prokaryotic N-degron pathway depends on the Clp chaperone-protease system and the ClpS adaptor for recognition of N-degron bearing substrates. Plant chloroplasts contain a diversified Clp protease, including the ClpS homolog ClpS1. Several candidate ClpS1 substrates have been identified, but the N-degron specificity is unclear. Here, we employed in vitro ClpS1 affinity assays using eight N-degron green fluorescence protein reporters containing either F, Y, L, W, I, or R in the N-terminal position. This demonstrated that ClpS1 has a restricted N-degron specificity, recognizing proteins bearing an N-terminal F or W, only weakly recognizing L, but not recognizing Y or I. This affinity is dependent on two conserved residues in the ClpS1 binding pocket and is sensitive to FR dipeptide competition, suggesting a unique chloroplast N-degron pathway., (© 2019 Federation of European Biochemical Societies.)

Published

2019

12. Perrault syndrome type 3 caused by diverse molecular defects in CLPP.

Author

Brodie EJ, Zhan H, Saiyed T, Truscott KN, and Dougan DA

Subjects

Endopeptidase Clp chemistry, Endopeptidase Clp metabolism, Gonadal Dysgenesis, 46,XX metabolism, Hearing Loss, Sensorineural metabolism, Humans, Mitochondria genetics, Mitochondria metabolism, Models, Molecular, Mutation, Protein Conformation, Endopeptidase Clp genetics, Genetic Association Studies, Genetic Predisposition to Disease, Genetic Variation, Gonadal Dysgenesis, 46,XX diagnosis, Gonadal Dysgenesis, 46,XX genetics, Hearing Loss, Sensorineural diagnosis, Hearing Loss, Sensorineural genetics

Abstract

The maintenance of mitochondrial protein homeostasis (proteostasis) is crucial for correct cellular function. Recently, several mutations in the mitochondrial protease CLPP have been identified in patients with Perrault syndrome 3 (PRLTS3). These mutations can be arranged into two groups, those that cluster near the docking site (hydrophobic pocket, Hp) for the cognate unfoldase CLPX (i.e. T145P and C147S) and those that are adjacent to the active site of the peptidase (i.e. Y229D). Here we report the biochemical consequence of mutations in both regions. The Y229D mutant not only inhibited CLPP-peptidase activity, but unexpectedly also prevented CLPX-docking, thereby blocking the turnover of both peptide and protein substrates. In contrast, Hp mutations cause a range of biochemical defects in CLPP, from no observable change to CLPP activity for the C147S mutant, to dramatic disruption of most activities for the "gain-of-function" mutant T145P - including loss of oligomeric assembly and enhanced peptidase activity.

Published

2018

13. Dysregulating ClpP: From Antibiotics to Anticancer?

Author

Dougan DA, Hantke I, and Turgay K

Subjects

Caseins, Cell Death, Humans, Mitochondria, Anti-Bacterial Agents, Endopeptidase Clp

Abstract

In this issue of Cell Chemical Biology, Wong et al. (2018) identify several dysregulators of a key mitochondrial protease: casein lytic protease P (ClpP). These dysregulators were found to trigger programmed cell death and may offer fresh avenues for the development of novel cancer therapeutics., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

14. Understanding the Pro/N-end rule pathway.

Author

Dougan DA and Varshavsky A

Subjects

Proteolysis, Signal Transduction

Published

2018

15. Crystal structure of bacterial succinate:quinone oxidoreductase flavoprotein SdhA in complex with its assembly factor SdhE.

Author

Maher MJ, Herath AS, Udagedara SR, Dougan DA, and Truscott KN

Subjects

Bacterial Proteins, Crystallization, Crystallography, X-Ray, Electron Transport Complex II genetics, Escherichia coli, Escherichia coli Proteins ultrastructure, Flavoproteins ultrastructure, Models, Molecular, Protein Binding, Protein Conformation, Protein Domains, Strobilurins, Electron Transport Complex II metabolism, Escherichia coli Proteins chemistry, Flavoproteins chemistry

Abstract

Succinate:quinone oxidoreductase (SQR) functions in energy metabolism, coupling the tricarboxylic acid cycle and electron transport chain in bacteria and mitochondria. The biogenesis of flavinylated SdhA, the catalytic subunit of SQR, is assisted by a highly conserved assembly factor termed SdhE in bacteria via an unknown mechanism. By using X-ray crystallography, we have solved the structure of Escherichia coli SdhE in complex with SdhA to 2.15-Å resolution. Our structure shows that SdhE makes a direct interaction with the flavin adenine dinucleotide-linked residue His45 in SdhA and maintains the capping domain of SdhA in an "open" conformation. This displaces the catalytic residues of the succinate dehydrogenase active site by as much as 9.0 Å compared with SdhA in the assembled SQR complex. These data suggest that bacterial SdhE proteins, and their mitochondrial homologs, are assembly chaperones that constrain the conformation of SdhA to facilitate efficient flavinylation while regulating succinate dehydrogenase activity for productive biogenesis of SQR., Competing Interests: The authors declare no conflict of interest.

Published

2018

16. Pupylation of PafA or Pup inhibits components of the Pup-Proteasome System.

Author

Thomas AA, Truscott KN, and Dougan DA

Subjects

Adenosine Triphosphatases metabolism, Amino Acid Substitution, Bacterial Proteins chemistry, Bacterial Proteins genetics, Lysine chemistry, Mutagenesis, Site-Directed, Mycobacterium smegmatis genetics, Protein Processing, Post-Translational, Proteolysis, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Substrate Specificity, Ubiquitin-Protein Ligase Complexes chemistry, Ubiquitin-Protein Ligase Complexes genetics, Ubiquitin-Protein Ligase Complexes metabolism, Bacterial Proteins metabolism, Mycobacterium smegmatis metabolism, Proteasome Endopeptidase Complex metabolism

Abstract

The pupylation of cellular proteins plays a crucial role in the degradation cascade via the Pup-Proteasome system (PPS). It is essential for the survival of Mycobacterium smegmatis under nutrient starvation and, as such, the activity of many components of the pathway is tightly regulated. Here, we show that Pup, like ubiquitin, can form polyPup chains primarily through K61 and that this form of Pup inhibits the ATPase-mediated turnover of pupylated substrates by the 20S proteasome. Similarly, the autopupylation of PafA (the sole Pup ligase found in mycobacteria) inhibits its own enzyme activity; hence, pupylation of PafA may act as a negative feedback mechanism to prevent substrate pupylation under specific cellular conditions., (© 2017 Federation of European Biochemical Societies.)

Published

2018

17. AAA+ Machines of Protein Destruction in Mycobacteria.

Author

Alhuwaider AAH and Dougan DA

Abstract

The bacterial cytosol is a complex mixture of macromolecules (proteins, DNA, and RNA), which collectively are responsible for an enormous array of cellular tasks. Proteins are central to most, if not all, of these tasks and as such their maintenance (commonly referred to as protein homeostasis or proteostasis) is vital for cell survival during normal and stressful conditions. The two key aspects of protein homeostasis are, (i) the correct folding and assembly of proteins (coupled with their delivery to the correct cellular location) and (ii) the timely removal of unwanted or damaged proteins from the cell, which are performed by molecular chaperones and proteases, respectively. A major class of proteins that contribute to both of these tasks are the AAA+ (ATPases associated with a variety of cellular activities) protein superfamily. Although much is known about the structure of these machines and how they function in the model Gram-negative bacterium Escherichia coli , we are only just beginning to discover the molecular details of these machines and how they function in mycobacteria. Here we review the different AAA+ machines, that contribute to proteostasis in mycobacteria. Primarily we will focus on the recent advances in the structure and function of AAA+ proteases, the substrates they recognize and the cellular pathways they control. Finally, we will discuss the recent developments related to these machines as novel drug targets.

Published

2017

18. Pro(moting) the Turnover of Gluconeogenic Enzymes by a New Branch of the N-end Rule Pathway.

Author

Dougan DA

Subjects

Animals, Humans, Gluconeogenesis, Glucose biosynthesis, Ligases metabolism

Abstract

The N-end rule pathway is a set of protein degradation systems that link the in vivo stability of a protein to its N-terminal residue. A recent paper from Alexander Varshavsky's laboratory [1] identifies a new branch of the N-end rule pathway that specifically recognizes the N-terminal Pro residue of key gluconeogenesis enzymes., (Crown Copyright © 2017. Published by Elsevier Ltd. All rights reserved.)

Published

2017

19. The N-end rule adaptor protein ClpS from Plasmodium falciparum exhibits broad substrate specificity.

Author

Tan JL, Ward L, Truscott KN, and Dougan DA

Subjects

Endopeptidase Clp chemistry, Isoleucine metabolism, Neoplasm Proteins chemistry, Protein Domains, Proteolysis, Protozoan Proteins chemistry, Substrate Specificity, Endopeptidase Clp metabolism, Neoplasm Proteins metabolism, Plasmodium enzymology, Protozoan Proteins metabolism

Abstract

The N-end rule is a conserved protein degradation pathway that relates the metabolic stability of a protein to the identity of its N-terminal residue. Proteins bearing a destabilising N-terminal residue (N-degron) are recognised by specialised components of the pathway (N-recognins) and degraded by cellular proteases. In bacteria, the N-recognin ClpS is responsible for the specific recognition of proteins bearing an N-terminal destabilising residue such as leucine, phenylalanine, tyrosine or tryptophan. In this study, we show that the putative apicoplast N-recognin from Plasmodium falciparum (PfClpS), in contrast to its bacterial homologues, exhibits an expanded substrate specificity that includes recognition of the branched chain amino acid isoleucine., (© 2016 Federation of European Biochemical Societies.)

Published

2016

20. LON is the master protease that protects against protein aggregation in human mitochondria through direct degradation of misfolded proteins.

Author

Bezawork-Geleta A, Brodie EJ, Dougan DA, and Truscott KN

Subjects

Animals, Endopeptidase Clp genetics, Endopeptidase Clp metabolism, HeLa Cells, Humans, Mitochondria genetics, Mitochondrial Proteins genetics, Protease La genetics, Rats, Mitochondria metabolism, Mitochondrial Proteins metabolism, Protease La metabolism, Protein Aggregates, Proteolysis, Unfolded Protein Response

Abstract

Maintenance of mitochondrial protein homeostasis is critical for proper cellular function. Under normal conditions resident molecular chaperones and proteases maintain protein homeostasis within the organelle. Under conditions of stress however, misfolded proteins accumulate leading to the activation of the mitochondrial unfolded protein response (UPR(mt)). While molecular chaperone assisted refolding of proteins in mammalian mitochondria has been well documented, the contribution of AAA+ proteases to the maintenance of protein homeostasis in this organelle remains unclear. To address this gap in knowledge we examined the contribution of human mitochondrial matrix proteases, LONM and CLPXP, to the turnover of OTC-∆, a folding incompetent mutant of ornithine transcarbamylase, known to activate UPR(mt). Contrary to a model whereby CLPXP is believed to degrade misfolded proteins, we found that LONM, and not CLPXP is responsible for the turnover of OTC-∆ in human mitochondria. To analyse the conformational state of proteins that are recognised by LONM, we examined the turnover of unfolded and aggregated forms of malate dehydrogenase (MDH) and OTC. This analysis revealed that LONM specifically recognises and degrades unfolded, but not aggregated proteins. Since LONM is not upregulated by UPR(mt), this pathway may preferentially act to promote chaperone mediated refolding of proteins.

Published

2015

21. Anti-adaptors use distinct modes of binding to inhibit the RssB-dependent turnover of RpoS (σ(S)) by ClpXP.

Author

Micevski D, Zammit JE, Truscott KN, and Dougan DA

Abstract

In Escherichia coli, σ(S) is the master regulator of the general stress response. The level of σ(S) changes in response to multiple stress conditions and it is regulated at many levels including protein turnover. In the absence of stress, σ(S) is rapidly degraded by the AAA+ protease, ClpXP in a regulated manner that depends on the adaptor protein RssB. This two-component response regulator mediates the recognition of σ(S) and its delivery to ClpXP. The turnover of σ(S) however, can be inhibited in a stress specific manner, by one of three anti-adaptor proteins. Each anti-adaptor binds to RssB and inhibits its activity, but how this is achieved is not fully understood at a molecular level. Here, we describe details of the interaction between each anti-adaptor and RssB that leads to the stabilization of σ(S). By defining the domains of RssB using partial proteolysis we demonstrate that each anti-adaptor uses a distinct mode of binding to inhibit RssB activity. IraD docks specifically to the N-terminal domain of RssB, IraP interacts primarily with the C-terminal domain, while IraM interacts with both domains. Despite these differences in binding, we propose that docking of each anti-adaptor induces a conformational change in RssB, which resembles the inactive dimer of RssB. This dimer-like state of RssB not only prevents substrate binding but also triggers substrate release from a pre-bound complex.

Published

2015

22. Mitochondrial matrix proteostasis is linked to hereditary paraganglioma: LON-mediated turnover of the human flavinylation factor SDH5 is regulated by its interaction with SDHA.

Author

Bezawork-Geleta A, Saiyed T, Dougan DA, and Truscott KN

Subjects

Electron Transport Complex II genetics, Enzyme Stability genetics, Flavin-Adenine Dinucleotide metabolism, HeLa Cells, Humans, Immunoblotting, Mitochondrial Proteins genetics, Paraganglioma genetics, Protease La genetics, Protein Binding, Protein Subunits genetics, Protein Subunits metabolism, Proteostasis Deficiencies genetics, Substrate Specificity, Electron Transport Complex II metabolism, Mitochondria metabolism, Mitochondrial Proteins metabolism, Paraganglioma metabolism, Protease La metabolism, Proteostasis Deficiencies metabolism

Abstract

Mutations in succinate dehydrogenase (SDH) subunits and assembly factors cause a range of clinical conditions. One such condition, hereditary paraganglioma 2 (PGL2), is caused by a G78R mutation in the assembly factor SDH5. Although SDH5(G78R) is deficient in its ability to promote SDHA flavinylation, it has remained unclear whether impairment to its import, structure, or stability contributes to its loss of function. Using import-chase analysis in human mitochondria isolated from HeLa cells, we found that the import and maturation of human SDH5(G78R) was normal, while its stability was reduced significantly, with ~25% of the protein remaining after 180 min compared to ~85% for the wild-type protein. Notably, the metabolic stability of SDH5(G78R) was restored to wild-type levels by depleting mitochondrial LON (LONM). Degradation of SDH5(G78R) by LONM was confirmed in vitro; however, in contrast to the in organello analysis, wild-type SDH5 was also rapidly degraded by LONM. SDH5 instability was confirmed in SDHA-depleted mitochondria. Blue native PAGE showed that imported SDH5(G78R) formed a transient complex with SDHA; however, this complex was stabilized in LONM depleted mitochondria. These data demonstrate that SDH5 is protected from LONM-mediated degradation in mitochondria by its stable interaction with SDHA, a state that is dysregulated in PGL2.

Published

2014

23. Control of protein function through regulated protein degradation: biotechnological and biomedical applications.

Author

Nagpal J, Tan JL, Truscott KN, Heras B, and Dougan DA

Subjects

Biomedical Technology methods, Biotechnology methods, Bacteria metabolism, Bacterial Proteins metabolism, Endopeptidase Clp metabolism, Gene Expression Regulation, Bacterial, Proteolysis

Abstract

Targeted protein degradation is crucial for the correct function and maintenance of a cell. In bacteria, this process is largely performed by a handful of ATP-dependent machines, which generally consist of two components - an unfoldase and a peptidase. In some cases, however, substrate recognition by the protease may be regulated by specialized delivery factors (known as adaptor proteins). Our detailed understanding of how these machines are regulated to prevent uncontrolled degradation within a cell has permitted the identification of novel antimicrobials that dysregulate these machines, as well as the development of tunable degradation systems that have applications in biotechnology. Here, we focus on the physiological role of the ClpP peptidase in bacteria, its role as a novel antibiotic target and the use of protein degradation as a biotechnological approach to artificially control the expression levels of a protein of interest., (Copyright © 2013 S. Karger AG, Basel.)

Published

2013

24. Preface.

Author

Dougan DA

Subjects

Adenosine Triphosphate metabolism, Bacteria enzymology, Bacterial Proteins metabolism, Molecular Chaperones metabolism, Peptide Hydrolases metabolism, Proteolysis

Published

2013

25. Proteolytic regulation of stress response pathways in Escherichia coli.

Author

Micevski D and Dougan DA

Subjects

Signal Transduction, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Proteolysis, Sigma Factor metabolism, Stress, Physiological

Abstract

Maintaining correct cellular function is a fundamental biological process for all forms of life. A critical aspect of this process is the maintenance of protein homeostasis (proteostasis) in the cell, which is largely performed by a group of proteins, referred to as the protein quality control (PQC) network. This network of proteins, comprised of chaperones and proteases, is critical for maintaining proteostasis not only during favourable growth conditions, but also in response to stress. Indeed proteases play a crucial role in the clearance of unwanted proteins that accumulate during stress, but more importantly, in the activation of various different stress response pathways. In bacteria, the cells response to stress is usually orchestrated by a specific transcription factor (sigma factor). In Escherichia coli there are seven different sigma factors, each of which responds to a particular stress, resulting in the rapid expression of a specific set of genes. The cellular concentration of each transcription factor is tightly controlled, at the level of transcription, translation and protein stability. Here we will focus on the proteolytic regulation of two sigma factors (σ(32) and σ(S)), which control the heat and general stress response pathways, respectively. This review will also briefly discuss the role proteolytic systems play in the clearance of unwanted proteins that accumulate during stress.

Published

2013

26. Machines of destruction - AAA+ proteases and the adaptors that control them.

Author

Gur E, Ottofueling R, and Dougan DA

Subjects

Adenosine Triphosphate metabolism, Bacteria enzymology, Bacterial Proteins metabolism, Molecular Chaperones metabolism, Peptide Hydrolases metabolism, Proteolysis

Abstract

Bacteria are frequently exposed to changes in environmental conditions, such as fluctuations in temperature, pH or the availability of nutrients. These assaults can be detrimental to cell as they often result in a proteotoxic stress, which can cause the accumulation of unfolded proteins. In order to restore a productive folding environment in the cell, bacteria have evolved a network of proteins, known as the protein quality control (PQC) network, which is composed of both chaperones and AAA+ proteases. These AAA+ proteases form a major part of this PQC network, as they are responsible for the removal of unwanted and damaged proteins. They also play an important role in the turnover of specific regulatory or tagged proteins. In this review, we describe the general features of an AAA+ protease, and using two of the best-characterised AAA+ proteases in Escherichia coli (ClpAP and ClpXP) as a model for all AAA+ proteases, we provide a detailed mechanistic description of how these machines work. Specifically, the review examines the physiological role of these machines, as well as the substrates and the adaptor proteins that modulate their substrate specificity.

Published

2013

27. Substrate recognition and processing by a Walker B mutant of the human mitochondrial AAA+ protein CLPX.

Author

Lowth BR, Kirstein-Miles J, Saiyed T, Brötz-Oesterhelt H, Morimoto RI, Truscott KN, and Dougan DA

Subjects

Animals, Endopeptidase Clp genetics, Humans, Mutation, Protein Binding, Substrate Specificity, Endopeptidase Clp metabolism

Abstract

The mitochondrial matrix of mammalian cells contains several different ATP-dependent proteases, including CLPXP, some of which contribute to protein maturation and quality control. Currently however, the substrates and the physiological roles of mitochondrial CLPXP in humans, has remained elusive. Similarly, the mechanism by which these ATP-dependent proteases recognize their substrates currently remains unclear. Here we report the characterization of a Walker B mutation in human CLPX, in which the highly conserved glutamate was replaced with alanine. This mutant protein exhibits improved interaction with the model unfolded substrate casein and several putative physiological substrates in vitro. Although this mutant lacks ATPase activity, it retains the ability to mediate casein degradation by hCLPP, in a fashion similar to the small molecule ClpP-activator, ADEP. Our functional dissection of hCLPX structure, also identified that most model substrates are recognized by the N-terminal domain, although some substrates bypass this step and dock, directly to the pore-1 motif. Collectively these data reveal, that despite the difference between bacterial and human CLPXP complexes, human CLPXP exhibits a similar mode of substrate recognition and is deregulated by ADEPs., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

28. The N-end rule pathway: from recognition by N-recognins, to destruction by AAA+proteases.

Author

Dougan DA, Micevski D, and Truscott KN

Subjects

Amino Acid Motifs, Amino Acid Sequence, Animals, Conserved Sequence, Humans, Metabolic Networks and Pathways, Molecular Sequence Data, Proteasome Endopeptidase Complex chemistry, Protein Binding, Protein Interaction Domains and Motifs, Ubiquitin-Protein Ligase Complexes chemistry, ATP-Dependent Proteases chemistry, Proteolysis

Abstract

Intracellular proteolysis is a tightly regulated process responsible for the targeted removal of unwanted or damaged proteins. The non-lysosomal removal of these proteins is performed by processive enzymes, which belong to the AAA+superfamily, such as the 26S proteasome and Clp proteases. One important protein degradation pathway, that is common to both prokaryotes and eukaryotes, is the N-end rule. In this pathway, proteins bearing a destabilizing amino acid residue at their N-terminus are degraded either by the ClpAP protease in bacteria, such as Escherichia coli or by the ubiquitin proteasome system in the eukaryotic cytoplasm. A suite of enzymes and other molecular components are also required for the successful generation, recognition and delivery of N-end rule substrates to their cognate proteases. In this review we examine the similarities and differences in the N-end rule pathway of bacterial and eukaryotic systems, focusing on the molecular determinants of this pathway., (Crown Copyright © 2011. Published by Elsevier B.V. All rights reserved.)

Published

2012

29. Unfolded protein responses in bacteria and mitochondria: a central role for the ClpXP machine.

Author

Truscott KN, Bezawork-Geleta A, and Dougan DA

Subjects

Animals, Cell Wall metabolism, Escherichia coli enzymology, Humans, Mitochondria enzymology, Proteolysis, Signal Transduction, Stress, Physiological, Endopeptidase Clp metabolism, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Mitochondria metabolism, Unfolded Protein Response

Abstract

In the crowded environment of a cell, the protein quality control machinery, such as molecular chaperones and proteases, maintains a population of folded and hence functional proteins. The accumulation of unfolded proteins in a cell is particularly harmful as it not only reduces the concentration of active proteins but also overburdens the protein quality control machinery, which in turn, can lead to a significant increase in nonproductive folding and protein aggregation. To circumvent this problem, cells use heat shock and unfolded protein stress response pathways, which essentially sense the change to protein homeostasis upregulating protein quality control factors that act to restore the balance. Interestingly, several stress response pathways are proteolytically controlled. In this review, we provide a brief summary of targeted protein degradation by AAA+ proteases and focus on the role of ClpXP proteases, particularly in the signaling pathway of the Escherichia coli extracellular stress response and the mitochondrial unfolded protein response., (Copyright © 2011 Wiley Periodicals, Inc.)

Published

2011

30. Chemical activators of ClpP: turning Jekyll into Hyde.

Author

Dougan DA

Published

2011

31. The bacterial N-end rule pathway: expect the unexpected.

Author

Dougan DA, Truscott KN, and Zeth K

Subjects

Amino Acid Motifs, Bacteria chemistry, Bacteria genetics, Bacterial Proteins genetics, Protein Biosynthesis, Protein Stability, Bacteria metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism

Abstract

The N-end rule pathway is a highly conserved process that operates in many different organisms. It relates the metabolic stability of a protein to its N-terminal amino acid. Consequently, amino acids are described as either 'stabilizing' or 'destabilizing'. Destabilizing residues are organized into three hierarchical levels: primary, secondary, and in eukaryotes - tertiary. Secondary and tertiary destabilizing residues act as signals for the post-translational modification of the target protein, ultimately resulting in the attachment of a primary destabilizing residue to the N-terminus of the protein. Regardless of their origin, proteins containing N-terminal primary destabilizing residues are recognized by a key component of the pathway. In prokaryotes, the recognition component is a specialized adaptor protein, known as ClpS, which delivers target proteins directly to the ClpAP protease for degradation. In contrast, eukaryotes use a family of E3 ligases, known as UBRs, to recognize and ubiquitylate their substrates resulting in their turnover by the 26S proteasome. While the physiological role of the N-end rule pathway is largely understood in eukaryotes, progress on the bacterial pathway has been slow. However, new interest in this area of research has invigorated several recent advances, unlocking some of the secrets of this unique proteolytic pathway in prokaryotes.

Published

2010

32. Diverse functions of mitochondrial AAA+ proteins: protein activation, disaggregation, and degradation.

Author

Truscott KN, Lowth BR, Strack PR, and Dougan DA

Subjects

Adenosine Triphosphatases genetics, Humans, Hydrolysis, Mitochondria genetics, Mitochondrial Proteins genetics, Molecular Chaperones genetics, Molecular Chaperones metabolism, Protein Structure, Secondary, Protein Structure, Tertiary, Adenosine Triphosphatases chemistry, Adenosine Triphosphatases metabolism, Mitochondria metabolism, Mitochondrial Proteins metabolism

Abstract

In eukaryotes, mitochondria are required for the proper function of the cell and as such the maintenance of proteins within this organelle is crucial. One class of proteins, collectively known as the AAA+ (ATPases associated with various cellular activities) superfamily, make a number of important contributions to mitochondrial protein homeostasis. In this organelle, they contribute to the maturation and activation of proteins, general protein quality control, respiratory chain complex assembly, and mitochondrial DNA maintenance and integrity. To achieve such diverse functions this group of ATP-dependent unfoldases utilize the energy from ATP hydrolysis to modulate the structure of proteins via unique domains and (or) associated functional components. In this review, we describe the current status of knowledge regarding the known mitochondrial AAA+ proteins and their role in this organelle.

Published

2010

33. Adapting the machine: adaptor proteins for Hsp100/Clp and AAA+ proteases.

Author

Kirstein J, Molière N, Dougan DA, and Turgay K

Subjects

Transcription Factors metabolism, Adenosine Triphosphatases metabolism, Bacteria metabolism, Bacterial Proteins metabolism, Endopeptidase Clp metabolism, Heat-Shock Proteins metabolism, Metalloendopeptidases metabolism

Abstract

Members of the AAA+ protein superfamily contribute to many diverse aspects of protein homeostasis in prokaryotic cells. As a fundamental component of numerous proteolytic machines in bacteria, AAA+ proteins play a crucial part not only in general protein quality control but also in the regulation of developmental programmes, through the controlled turnover of key proteins such as transcription factors. To manage these many, varied tasks, Hsp100/Clp and AAA+ proteases use specific adaptor proteins to enhance or expand the substrate recognition abilities of their cognate protease. Here, we review our current knowledge of the modulation of bacterial AAA+ proteases by these cellular arbitrators.

Published

2009

34. Modification of PATase by L/F-transferase generates a ClpS-dependent N-end rule substrate in Escherichia coli.

Author

Ninnis RL, Spall SK, Talbo GH, Truscott KN, and Dougan DA

Subjects

Amino Acid Motifs, Amino Acid Sequence, Bacterial Outer Membrane Proteins metabolism, Carrier Proteins chemistry, Chromatography, Affinity, Dipeptides metabolism, Endopeptidase Clp chemistry, Endopeptidase Clp metabolism, Escherichia coli Proteins chemistry, Hydrophobic and Hydrophilic Interactions, Ligands, Models, Biological, Molecular Sequence Data, Mutant Proteins metabolism, Protein Binding, Substrate Specificity, Aminoacyltransferases metabolism, Carrier Proteins metabolism, Escherichia coli enzymology, Escherichia coli Proteins metabolism, Metabolic Networks and Pathways, Protein Processing, Post-Translational, Transaminases metabolism

Abstract

The N-end rule pathway is conserved from bacteria to man and determines the half-life of a protein based on its N-terminal amino acid. In Escherichia coli, model substrates bearing an N-degron are recognised by ClpS and degraded by ClpAP in an ATP-dependent manner. Here, we report the isolation of 23 ClpS-interacting proteins from E. coli. Our data show that at least one of these interacting proteins--putrescine aminotransferase (PATase)--is post-translationally modified to generate a primary N-degron. Remarkably, the N-terminal modification of PATase is generated by a new specificity of leucyl/phenylalanyl-tRNA-protein transferase (LFTR), in which various combinations of primary destabilising residues (Leu and Phe) are attached to the N-terminal Met. This modification (of PATase), by LFTR, is essential not only for its recognition by ClpS, but also determines the stability of the protein in vivo. Thus, the N-end rule pathway, through the ClpAPS-mediated turnover of PATase may have an important function in putrescine homeostasis. In addition, we have identified a new element within the N-degron, which is required for substrate delivery to ClpA.

Published

2009

35. Structural basis of N-end rule substrate recognition in Escherichia coli by the ClpAP adaptor protein ClpS.

Author

Schuenemann VJ, Kralik SM, Albrecht R, Spall SK, Truscott KN, Dougan DA, and Zeth K

Subjects

Amino Acid Sequence, Leucine chemistry, Models, Biological, Molecular Sequence Data, Phenylalanine chemistry, Protein Binding, Protein Structure, Quaternary, Protein Structure, Tertiary, Tryptophan chemistry, Carrier Proteins chemistry, Carrier Proteins metabolism, Endopeptidase Clp metabolism, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Peptides chemistry, Peptides metabolism

Abstract

In Escherichia coli, the ClpAP protease, together with the adaptor protein ClpS, is responsible for the degradation of proteins bearing an amino-terminal destabilizing amino acid (N-degron). Here, we determined the three-dimensional structures of ClpS in complex with three peptides, each having a different destabilizing residue--Leu, Phe or Trp--at its N terminus. All peptides, regardless of the identity of their N-terminal residue, are bound in a surface pocket on ClpS in a stereo-specific manner. Several highly conserved residues in this binding pocket interact directly with the backbone of the N-degron peptide and hence are crucial for the binding of all N-degrons. By contrast, two hydrophobic residues define the volume of the binding pocket and influence the specificity of ClpS. Taken together, our data suggest that ClpS has been optimized for the binding and delivery of N-degrons containing an N-terminal Phe or Leu.

Published

2009

36. Conserved residues in the N-domain of the AAA+ chaperone ClpA regulate substrate recognition and unfolding.

Author

Erbse AH, Wagner JN, Truscott KN, Spall SK, Kirstein J, Zeth K, Turgay K, Mogk A, Bukau B, and Dougan DA

Subjects

Amino Acid Motifs genetics, Amino Acid Sequence, Amino Acid Substitution genetics, Arginine genetics, Conserved Sequence, Endopeptidase Clp genetics, Escherichia coli enzymology, Escherichia coli genetics, Escherichia coli Proteins genetics, Heat-Shock Proteins genetics, Molecular Chaperones genetics, Molecular Sequence Data, Mutation, Protein Denaturation genetics, Protein Structure, Tertiary genetics, Substrate Specificity genetics, Endopeptidase Clp chemistry, Endopeptidase Clp physiology, Escherichia coli Proteins chemistry, Escherichia coli Proteins physiology, Molecular Chaperones physiology, Protein Folding

Abstract

Protein degradation in the cytosol of Escherichia coli is carried out by a variety of different proteolytic machines, including ClpAP. The ClpA component is a hexameric AAA+ (ATPase associated with various cellular activities) chaperone that utilizes the energy of ATP to control substrate recognition and unfolding. The precise role of the N-domains of ClpA in this process, however, remains elusive. Here, we have analysed the role of five highly conserved basic residues in the N-domain of ClpA by monitoring the binding, unfolding and degradation of several different substrates, including short unstructured peptides, tagged and untagged proteins. Interestingly, mutation of three of these basic residues within the N-domain of ClpA (H94, R86 and R100) did not alter substrate degradation. In contrast mutation of two conserved arginine residues (R90 and R131), flanking a putative peptide-binding groove within the N-domain of ClpA, specifically compromised the ability of ClpA to unfold and degrade selected substrates but did not prevent substrate recognition, ClpS-mediated substrate delivery or ClpP binding. In contrast, a highly conserved tyrosine residue lining the central pore of the ClpA hexamer was essential for the degradation of all substrate types analysed, including both folded and unstructured proteins. Taken together, these data suggest that ClpA utilizes two structural elements, one in the N-domain and the other in the pore of the hexamer, both of which are required for efficient unfolding of some protein substrates.

Published

2008

37. The tyrosine kinase McsB is a regulated adaptor protein for ClpCP.

Author

Kirstein J, Dougan DA, Gerth U, Hecker M, and Turgay K

Subjects

Bacillus subtilis physiology, Bacterial Proteins genetics, DNA Primers, Heat-Shock Proteins genetics, Mutagenesis, Site-Directed, Phosphorylation, Bacillus subtilis enzymology, Bacterial Proteins metabolism, Gene Expression Regulation, Enzymologic, Heat-Shock Proteins metabolism, Heat-Shock Response physiology, Protein Kinases metabolism, Repressor Proteins metabolism

Abstract

Cells of the soil bacterium Bacillus subtilis have to adapt to fast environmental changes in their natural habitat. Here, we characterized a novel system in which cells respond to heat shock by regulatory proteolysis of a transcriptional repressor CtsR. In B. subtilis, CtsR controls the synthesis of itself, the tyrosine kinase McsB, its activator McsA and the Hsp100/Clp proteins ClpC, ClpE and their cognate peptidase ClpP. The AAA+ protein family members ClpC and ClpE can form an ATP-dependent protease complex with ClpP and are part of the B. subtilis protein quality control system. The regulatory response is mediated by a proteolytic switch, which is formed by these proteins under heat-shock conditions, where the tyrosine kinase McsB acts as a regulated adaptor protein, which in its phosphorylated form activates the Hsp100/Clp protein ClpC and targets the repressor CtsR for degradation by the general protease ClpCP.

Published

2007

38. Adaptor protein controlled oligomerization activates the AAA+ protein ClpC.

Author

Kirstein J, Schlothauer T, Dougan DA, Lilie H, Tischendorf G, Mogk A, Bukau B, and Turgay K

Subjects

Adenosine Diphosphate chemistry, Adenosine Triphosphate chemistry, Bacillus subtilis, Biopolymers chemistry, Protein Binding, Protein Structure, Tertiary, Adaptor Proteins, Signal Transducing chemistry, Bacterial Proteins chemistry, Heat-Shock Proteins chemistry

Abstract

The AAA+ protein ClpC is not only involved in the removal of misfolded and aggregated proteins but also controls, through regulated proteolysis, key steps of several developmental processes in the Gram-positive bacterium Bacillus subtilis. In contrast to other AAA+ proteins, ClpC is unable to mediate these processes without an adaptor protein like MecA. Here, we demonstrate that the general activation of ClpC is based upon the ability of MecA to participate in the assembly of an active and substrate-recognizing higher oligomer consisting of ClpC and the adaptor protein, which is a prerequisite for all activities of this AAA+ protein. Using hybrid proteins of ClpA and ClpC, we identified the N-terminal and the Linker domain of the first AAA+ domain of ClpC as the essential MecA interaction sites. This new adaptor-mediated mechanism adds another layer of control to the regulation of the biological activity of AAA+ proteins.

Published

2006

39. ClpS is an essential component of the N-end rule pathway in Escherichia coli.

Author

Erbse A, Schmidt R, Bornemann T, Schneider-Mergener J, Mogk A, Zahn R, Dougan DA, and Bukau B

Subjects

Amino Acid Sequence, Binding Sites, Escherichia coli genetics, Molecular Sequence Data, Peptide Library, Peptides chemistry, Peptides metabolism, Substrate Specificity, Carrier Proteins metabolism, Endopeptidase Clp metabolism, Escherichia coli metabolism, Escherichia coli Proteins metabolism

Abstract

The N-end rule states that the half-life of a protein is determined by the nature of its amino-terminal residue. Eukaryotes and prokaryotes use N-terminal destabilizing residues as a signal to target proteins for degradation by the N-end rule pathway. In eukaryotes an E3 ligase, N-recognin, recognizes N-end rule substrates and mediates their ubiquitination and degradation by the proteasome. In Escherichia coli, N-end rule substrates are degraded by the AAA + chaperone ClpA in complex with the ClpP peptidase (ClpAP). Little is known of the molecular mechanism by which N-end rule substrates are initially selected for proteolysis. Here we report that the ClpAP-specific adaptor, ClpS, is essential for degradation of N-end rule substrates by ClpAP in bacteria. ClpS binds directly to N-terminal destabilizing residues through its substrate-binding site distal to the ClpS-ClpA interface, and targets these substrates to ClpAP for degradation. Degradation by the N-end rule pathway is more complex than anticipated and several other features are involved, including a net positive charge near the N terminus and an unstructured region between the N-terminal signal and the folded protein substrate. Through interaction with this signal, ClpS converts the ClpAP machine into a protease with exquisitely defined specificity, ideally suited to regulatory proteolysis.

Published

2006

40. Thermotolerance requires refolding of aggregated proteins by substrate translocation through the central pore of ClpB.

Author

Weibezahn J, Tessarz P, Schlieker C, Zahn R, Maglica Z, Lee S, Zentgraf H, Weber-Ban EU, Dougan DA, Tsai FT, Mogk A, and Bukau B

Subjects

Cell Survival genetics, Endopeptidase Clp, Escherichia coli genetics, Escherichia coli Proteins genetics, Escherichia coli Proteins isolation & purification, HSP70 Heat-Shock Proteins genetics, Heat-Shock Proteins genetics, Heat-Shock Proteins isolation & purification, Molecular Motor Proteins, Molecular Sequence Data, Multiprotein Complexes genetics, Multiprotein Complexes metabolism, Protein Engineering, Protein Transport physiology, Sequence Homology, Amino Acid, Sequence Homology, Nucleic Acid, Escherichia coli metabolism, Escherichia coli Proteins metabolism, HSP70 Heat-Shock Proteins metabolism, Heat-Shock Proteins metabolism, Heat-Shock Response genetics, Molecular Chaperones genetics, Molecular Chaperones metabolism, Protein Folding

Abstract

Cell survival under severe thermal stress requires the activity of the ClpB (Hsp104) AAA+ chaperone that solubilizes and reactivates aggregated proteins in concert with the DnaK (Hsp70) chaperone system. How protein disaggregation is achieved and whether survival is solely dependent on ClpB-mediated elimination of aggregates or also on reactivation of aggregated proteins has been unclear. We engineered a ClpB variant, BAP, which associates with the ClpP peptidase and thereby is converted into a degrading disaggregase. BAP translocates substrates through its central pore directly into ClpP for degradation. ClpB-dependent translocation is demonstrated to be an integral part of the disaggregation mechanism. Protein disaggregation by the BAP/ClpP complex remains dependent on DnaK, defining a role for DnaK at early stages of the disaggregation reaction. The activity switch of BAP to a degrading disaggregase does not support thermotolerance development, demonstrating that cell survival during severe thermal stress requires reactivation of aggregated proteins.

Published

2004

41. Targeted delivery of an ssrA-tagged substrate by the adaptor protein SspB to its cognate AAA+ protein ClpX.

Author

Dougan DA, Weber-Ban E, and Bukau B

Subjects

ATPases Associated with Diverse Cellular Activities, Adaptor Proteins, Vesicular Transport metabolism, Adenosine Triphosphate metabolism, Adhesins, Bacterial metabolism, Amino Acid Motifs, Amino Acid Sequence, Bacterial Physiological Phenomena, Bacterial Proteins chemistry, Endopeptidase Clp, Escherichia coli Proteins, Green Fluorescent Proteins, Luminescent Proteins metabolism, Models, Biological, Molecular Chaperones, Molecular Sequence Data, Multigene Family, Peptides chemistry, Plasmids metabolism, Protein Binding, Protein Structure, Secondary, Protein Structure, Tertiary, RNA, Bacterial chemistry, Sequence Homology, Amino Acid, Spectrophotometry, Time Factors, Adenosine Triphosphatases metabolism, Adhesins, Bacterial physiology, RNA, Bacterial metabolism

Abstract

In the bacterial cytosol, degradation of ssrA-tagged proteins is primarily carried out by the proteolytic machine ClpXP in a process which is stimulated by a ClpX-specific adaptor protein, SspB. Here we elucidate the steps required for binding and transfer of ssrA-tagged substrates from SspB to ClpX. The N-terminal region of SspB is essential for its interaction with ssrA-tagged substrates, while a short conserved region at the C terminus of SspB interacts specifically with the N domain of ClpX. A single point mutation within the conserved C-terminal region of SspB is sufficient to abolish the SspB-mediated degradation of ssrA-tagged proteins by ClpXP. We propose that this region represents a common motif for the recognition of ClpX as the C-terminal region of SspB shares considerable homology with the other ClpX-specific adaptor protein, RssB. Through docking of SspB to the N-terminal domain of ClpX, the substrate is delivered to the substrate binding site in ClpX.

Published

2003

42. MecA, an adaptor protein necessary for ClpC chaperone activity.

Author

Schlothauer T, Mogk A, Dougan DA, Bukau B, and Turgay K

Subjects

Adenosine Triphosphatases metabolism, Adenosine Triphosphate pharmacology, Bacterial Proteins metabolism, Caseins metabolism, Heat-Shock Proteins metabolism, Luciferases metabolism, Malate Dehydrogenase metabolism, Molecular Chaperones metabolism, Protein Binding, Protein Folding, Temperature, Time Factors, Bacillus subtilis metabolism, Bacterial Proteins physiology, Heat-Shock Proteins physiology

Abstract

ClpC of Bacillus subtilis is an ATP-dependent HSP100Clp protein involved in general stress survival. A complex of ClpC with the protease ClpP and the adaptor protein MecA also controls competence development by regulated proteolysis of the transcription factor ComK. We investigated the in vitro chaperone activity of ClpC and found that the presence of MecA was crucial for the major chaperone activities of ClpC. In particular, MecA enabled ClpC to solubilize and refold aggregated proteins. Finally, in the presence of ClpP, MecA allowed the ClpC-dependent degradation of unfolded or heat-aggregated proteins. This study demonstrates that adaptor proteins like MecA through interaction with their cognate ClpC proteins can have a dual role in the protein quality-control network by rescuing, or together with ClpP, by degrading, aggregated proteins. MecA can thereby coordinate substrate targeting with ClpC activation, adding another layer to the regulation of HSP100/Clp protein activity.

Published

2003

43. A folding machine for many but a master of none.

Author

Erbse A, Dougan DA, and Bukau B

Subjects

Adenosine Triphosphate metabolism, Chaperonin 10 genetics, Chaperonin 60 genetics, Genetic Variation, Green Fluorescent Proteins, Luminescent Proteins chemistry, Luminescent Proteins metabolism, Models, Biological, Protein Folding, Chaperonin 10 metabolism, Chaperonin 60 metabolism

Published

2003

44. Structural analysis of the adaptor protein ClpS in complex with the N-terminal domain of ClpA.

Author

Zeth K, Ravelli RB, Paal K, Cusack S, Bukau B, and Dougan DA

Subjects

Amino Acid Sequence, Binding Sites, Carrier Proteins physiology, Crystallography, X-Ray, Endopeptidase Clp, Escherichia coli Proteins physiology, Macromolecular Substances, Protein Structure, Tertiary, Sequence Alignment, Substrate Specificity, Adenosine Triphosphatases chemistry, Adenosine Triphosphatases metabolism, Carrier Proteins chemistry, Carrier Proteins metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Models, Molecular, Serine Endopeptidases chemistry, Serine Endopeptidases metabolism

Abstract

In Escherichia coli, protein degradation is performed by several proteolytic machines, including ClpAP. Generally, the substrate specificity of these machines is determined by chaperone components, such as ClpA. In some cases, however, the specificity is modified by adaptor proteins, such as ClpS. Here we report the 2.5 A resolution crystal structure of ClpS in complex with the N-terminal domain of ClpA. Using mutagenesis, we demonstrate that two contact residues (Glu79 and Lys 84) are essential not only for ClpAS complex formation but also for ClpAPS-mediated substrate degradation. The corresponding residues are absent in the chaperone ClpB, providing a structural rationale for the unique specificity shown by ClpS despite the high overall similarity between ClpA and ClpB. To determine the location of ClpS within the ClpA hexamer, we modeled the N-terminal domain of ClpA onto a structurally defined, homologous AAA+ protein. From this model, we proposed a molecular mechanism to explain the ClpS-mediated switch in ClpA substrate specificity.

Published

2002

45. Insertion and assembly of human tom7 into the preprotein translocase complex of the outer mitochondrial membrane.

Author

Johnston AJ, Hoogenraad J, Dougan DA, Truscott KN, Yano M, Mori M, Hoogenraad NJ, and Ryan MT

Subjects

Amino Acid Sequence, Animals, COS Cells, HeLa Cells, Humans, Mitochondrial Membrane Transport Proteins, Mitochondrial Precursor Protein Import Complex Proteins, Molecular Sequence Data, Molecular Weight, Membrane Proteins chemistry, Membrane Proteins physiology, Membrane Transport Proteins, Mitochondrial Proteins chemistry, Protein Precursors chemistry, Receptors, Cell Surface

Abstract

Tom7 is a component of the translocase of the outer mitochondrial membrane (TOM) and assembles into a general import pore complex that translocates preproteins into mitochondria. We have identified the human Tom7 homolog and characterized its import and assembly into the mammalian TOM complex. Tom7 is imported into mitochondria in a nucleotide-independent manner and is anchored to the outer membrane with its C terminus facing the intermembrane space. Unlike studies in fungi, we found that human Tom7 assembles into an approximately 120-kDa import intermediate in HeLa cell mitochondria. To detect subunits within this complex, we employed a novel supershift analysis whereby mitochondria containing newly imported Tom7 were incubated with antibodies specific for individual TOM components prior to separation by blue native electrophoresis. We found that the 120-kDa complex contains Tom40 and lacks receptor components. This intermediate can be chased to the stable approximately 380-kDa mammalian TOM complex that additionally contains Tom22. Overexpression of Tom22 in HeLa cells results in the rapid assembly of Tom7 into the 380-kDa complex indicating that Tom22 is rate-limiting for TOM complex formation. These results indicate that the levels of Tom22 within mitochondria dictate the assembly of TOM complexes and hence may regulate its biogenesis.

Published

2002

46. AAA+ proteins and substrate recognition, it all depends on their partner in crime.

Author

Dougan DA, Mogk A, Zeth K, Turgay K, and Bukau B

Subjects

ATP-Dependent Proteases, ATPases Associated with Diverse Cellular Activities, Bacillus subtilis metabolism, Endopeptidase Clp, Eukaryotic Cells metabolism, Membrane Proteins chemistry, Membrane Proteins metabolism, Molecular Chaperones, Serine Endopeptidases chemistry, Serine Endopeptidases metabolism, Substrate Specificity, Adenosine Triphosphatases chemistry, Adenosine Triphosphatases metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Endopeptidases chemistry, Endopeptidases metabolism, Escherichia coli Proteins metabolism, Heat-Shock Proteins chemistry, Heat-Shock Proteins metabolism

Abstract

Members of the AAA+ superfamily have been identified in all organisms studied to date. They are involved in a wide range of cellular events. In bacteria, representatives of this superfamily are involved in functions as diverse as transcription and protein degradation and play an important role in the protein quality control network. Often they employ a common mechanism to mediate an ATP-dependent unfolding/disassembly of protein-protein or DNA-protein complexes. In an increasing number of examples it appears that the activities of these AAA+ proteins may be modulated by a group of otherwise unrelated proteins, called adaptor proteins. These usually small proteins specifically modify the substrate recognition of their AAA+ partner protein. The occurrence of such adaptor proteins are widespread; representatives have been identified not only in Escherichia coli but also in Bacillus subtilis, not to mention yeast and other eukaryotic organisms. Interestingly, from the currently known examples, it appears that the N domain of AAA+ proteins (the most divergent region of the protein within the family) provides a common platform for the recognition of these diverse adaptor proteins. Finally, the use of adaptor proteins to modulate AAA+ activity is, in some cases, an elegant way to redirect the activity of an AAA+ protein towards a particular substrate without necessarily affecting other activities of that AAA+ protein while, in other cases, the adaptor protein triggers a complete switch in AAA+ activity.

Published

2002

47. Protein folding and degradation in bacteria: to degrade or not to degrade? That is the question.

Author

Dougan DA, Mogk A, and Bukau B

Subjects

Endopeptidase Clp, Escherichia coli Proteins metabolism, HSP70 Heat-Shock Proteins metabolism, Heat-Shock Proteins metabolism, Models, Molecular, Protein Conformation, Bacteria metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Molecular Chaperones metabolism, Protein Folding

Abstract

In Escherichia coli protein quality control is carried out by a protein network, comprising chaperones and proteases. Central to this network are two protein families, the AAA+ and the Hsp70 family. The major Hsp70 chaperone. DnaK, efficiently prevents protein aggregation and supports the refolding of damaged proteins. In a special case, DnaK, together with the assistance of the AAA+ protein ClpB, can also refold aggregated proteins. Other Hsp70 systems have more specialized functions in the cell, for instance HscA appears to be involved in the assembly of Fe/S proteins. In contrast to ClpB, many AAA+ proteins associate with a peptidase to form proteolytic machines which remove irreversibly damaged proteins from the cellular pool. The AAA+ component of these proteolytic machines drives protein degradation. They are required not only for recognition of the substrate but also for substrate unfolding and translocation into the proteolytic chamber. In many cases, specific adaptor proteins modify the substrate binding properties of AAA+ proteins. While chaperones and proteases do not appear to directly cooperate with each other, both systems appear to be necessary for proper functioning of the cell and can, at least in part, substitute for one another.

Published

2002

48. Crystallization and preliminary X-ray analysis of the Escherichia coli adaptor protein ClpS, free and in complex with the N-terminal domain of ClpA.

Author

Zeth K, Dougan DA, Cusack S, Bukau B, and Ravelli RB

Subjects

Endopeptidase Clp, Escherichia coli metabolism, Protein Binding, Protein Structure, Tertiary, Adenosine Triphosphatases chemistry, Carrier Proteins chemistry, Crystallography, X-Ray methods, Escherichia coli Proteins chemistry, Serine Endopeptidases chemistry

Abstract

Protein degradation in Escherichia coli is accomplished by a handful of large oligomeric complexes. In most cases, these proteolytic machines are comprised of a chaperone (e.g. ClpA) that is required to prepare the substrate for degradation by the peptidase (e.g. ClpP). Recently, it was shown that the substrate recognition of the chaperone ClpA could be modified by the adaptor protein ClpS. To investigate the structural implications of this change in substrate specificity, ClpS was crystallized alone and in complex with the N-terminal domain of ClpA (ClpA(N)). Crystals of ClpS diffract to 2.9 A resolution and belong to space group P2(1)2(1)2(1), with unit-cell parameters a = 82.63, b = 145.67, c = 152.31 A. Two different crystal forms of the ClpA(N)-ClpS complex were characterized. Crystal form I (CFI) belongs to the orthorhombic space group P2(1)2(1)2, with unit-cell parameters a = 91.63, b = 112.47, c = 38.47 A; data to 1.92 A resolution were collected. Crystals of form II (CFII) belong to space group P4(1/3)2(1)2, with unit-cell parameters a = b = 93.57, c = 78.77 A, and diffract to 1.85 A resolution. Data sets collected from heavy-atom derivatives of CFI indicated the incorporation of Pt and Hg atoms. Structure solution using MIR and MAD methods is currently under way.

Published

2002

49. ClpS, a substrate modulator of the ClpAP machine.

Author

Dougan DA, Reid BG, Horwich AL, and Bukau B

Subjects

Adenosine Triphosphatases genetics, Amino Acid Sequence, Carrier Proteins genetics, Endopeptidase Clp, Escherichia coli genetics, Escherichia coli Proteins chemistry, Escherichia coli Proteins genetics, Hot Temperature, Luciferases metabolism, Malate Dehydrogenase metabolism, Molecular Sequence Data, Protein Binding, RNA, Bacterial metabolism, Sequence Alignment, Serine Endopeptidases genetics, Substrate Specificity, Adenosine Triphosphatases metabolism, Carrier Proteins metabolism, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Operon genetics, Serine Endopeptidases metabolism

Abstract

In the bacterial cytosol, ATP-dependent protein degradation is performed by several different chaperone-protease pairs, including ClpAP. The mechanism by which these machines specifically recognize substrates remains unclear. Here, we report the identification of a ClpA cofactor from Escherichia coli, ClpS, which directly influences the ClpAP machine by binding to the N-terminal domain of the chaperone ClpA. The degradation of ClpAP substrates, both SsrA-tagged proteins and ClpA itself, is specifically inhibited by ClpS. In contrast, ClpS enhanced ClpA recognition of two heat-aggregated proteins in vitro and, consequently, the ClpAP-mediated disaggregation and degradation of these substrates. We conclude that ClpS modifies ClpA substrate specificity, potentially redirecting degradation by ClpAP toward aggregated proteins.

Published

2002

50. Single-chain Fv of anti-idiotype 11-1G10 antibody interacts with antibody NC41 single-chain Fv with a higher affinity than the affinity for the interaction of the parent Fab fragments.

Author

Iliades P, Dougan DA, Oddie GW, Metzger DW, Hudson PJ, and Kortt AA

Subjects

Amino Acid Sequence, Antibodies, Anti-Idiotypic genetics, Antibodies, Anti-Idiotypic immunology, Antigen-Antibody Complex, Base Sequence, Escherichia coli genetics, Immunoglobulin Fab Fragments chemistry, Immunoglobulin Fab Fragments immunology, Immunoglobulin Fragments chemistry, Immunoglobulin Fragments immunology, Immunoglobulin Fragments isolation & purification, Molecular Sequence Data, Recombinant Proteins immunology, Recombinant Proteins isolation & purification, Antibodies, Anti-Idiotypic chemistry, Antibody Affinity, Immunoglobulin Fragments genetics

Abstract

A single-chain Fv (scFv) fragment of anti-idiotype antibody 11-1G10, which recognizes an idiotope of anti-neuraminidase antibody NC41, was constructed by joining VH and VL domains with a (Gly4Ser)3 linker, with a pelB leader sequence, and two C-terminal FLAG tag sequences, and expressed in E. coli (10 mg/L). The 11-1G10 scFv was isolated by affinity chromatography on an anti-FLAG M2 antibody column as a 2:1 mixture of monomer and dimer forms which were separated by Superdex 75 chromatography; monomer (at 100 microg/ml) was stable for 7 days at 21 degrees C and 30 days at 4 degrees C, whereas the dimer slowly dissociated to monomer to yield a 2:1 monomerdimer equilibrium mixture after 30 days at 4 degrees C. The dimer was bivalent, with each combining site binding an NC41 Fab to yield a stable complex of Mr approximately 156,000. Binding affinities, determined in solution using a BIAcore biosensor, showed that the affinity for the interaction of 11-IG10 scFv monomer with NC41 scFv monomer was five- to six-fold higher than the interaction of the parent Fab pair. This is the first example of an scFv derived from a monoclonal antibody with a higher affinity than its parent Fab.

Published

1998