Your search keyword '"Kaye N. Truscott"' showing total 13 results

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

Author

David A. Dougan, Kaye N. Truscott, and Janine Kirstein

Subjects

Hsp70, AAA+ proteins, JDP, ATP-dependent unfolding, proteostasis, protein remodelling, Biology (General), QH301-705.5

Published

2023

2. Insight into the RssB-Mediated Recognition and Delivery of σs to the AAA+ Protease, ClpXP

Author

Dimce Micevski, Kornelius Zeth, Terrence D. Mulhern, Verena J. Schuenemann, Jessica E. Zammit, Kaye N. Truscott, and David A. Dougan

Subjects

RssB, SigmaS, AAA+ protease, ClpX, X-ray structure, adaptor protein, Microbiology, QR1-502

Abstract

In Escherichia coli, SigmaS (σS) is the master regulator of the general stress response. The cellular levels of σS are controlled by transcription, translation and protein stability. The turnover of σS, 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 σS recognition and delivery by RssB is only poorly understood. Here we describe the crystal structures of both RssB domains (RssBN and RssBC) and the SAXS analysis of full-length RssB (both free and in complex with σS). Together with our biochemical analysis we propose a model for the recognition and delivery of σS by this essential adaptor protein. Similar to most bacterial RRs, the N-terminal domain of RssB (RssBN) comprises a typical mixed (βα)5-fold. Although phosphorylation of RssBN (at Asp58) is essential for high affinity binding of σS, much of the direct binding to σS occurs via the C-terminal effector domain of RssB (RssBC). 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 σS interaction, as σS binding to the R117A mutant can be restored by phosphorylation. Likewise, R117A retains the ability to interact with and activate ClpX for degradation of σS, 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 σS at a distal site.

Published

2020

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

Author

David A. Dougan and Kaye N. Truscott

Published

2023

4. Novel modification by L/F-tRNA-protein transferase (LFTR) generates a Leu/N-degron ligand in Escherichia coli

Author

Robert. Ninnis, David A. Dougan, Kaye N. Truscott, and Ralf D. Ottofuelling

Subjects

chemistry.chemical_classification, Protease, Chemistry, medicine.medical_treatment, Peptide, medicine.disease_cause, Residue (chemistry), Enzyme, Biochemistry, Transfer RNA, medicine, Transferase, Degron, Escherichia coli

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 Escherchia coli the principal N-degron pathway is known as the Leu/N-degron pathway of which an Nt Leu is a key feature of the degron. Although the physiological role of the Leu/N-degron pathway is currently unclear, many of the components of the pathway are well defined. Proteins degraded by this pathway contain an Nt degradation signal (N-degron) composed of an Nt primary destabilizing (Nd1) residue (Leu, Phe, Trp or Tyr) and an unstructured region which generally contains a hydrophobic element. Most N-degrons are generated from a pro-N-degron, either by endoproteolytic cleavage, or by enzymatic attachment of a Nd1 residue (Leu or Phe) to the N-terminus of a protein (or protein fragment) by the enzyme Leu/Phe tRNA protein transferase (LFTR) in a non-ribosomal manner. Regardless of the mode of generation, all Leu/N-degrons are recognized by ClpS and delivered to the ClpAP protease for degradation. To date, only two physiological Leu/N-degron bearing substrates have been verified, one of which (PATase) is modified by LFTR. In this study, we have examined the substrate proteome of LFTR during stationary phase. From this analysis, we have identified several additional physiological Leu/N-degron ligands, including AldB, which is modified by a previously undescribed activity of LFTR. Importantly, the novel specificity of LFTR was confirmed in vitro, using a range of model proteins. Our data shows that processing of the Nt-Met of AldB generates a novel substrate for LFTR. Importantly, the LFTR-dependent modification of T2-AldB is essential for its turnover by ClpAPS, in vitro. To further examine the acceptor specificity of LFTR, we performed a systematic analysis using a series of peptide arrays. These data reveal that the identity of the second residue modulates substrate conjugation with positively charged residues being favored and negatively charged and aromatic residues being disfavored. Collectively, these findings extend our understanding of LFTR specificity and the Leu/N-degron pathway in E. coli.

Published

2021

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

Author

David A. Dougan, Liz J. Valente, Hanmiao Zhan, Kornelius Zeth, Lauren M. Angley, Kaye N. Truscott, Erica J. Brodie, Matthew A. Perugini, Tamanna Saiyed, Philip R. Strack, Verena J. Schuenemann, Bradley R. Lowth, and University of Zurich

Subjects

0301 basic medicine, DNA repair, medicine.medical_treatment, Medicine (miscellaneous), 610 Medicine & health, 2700 General Medicine, Mitochondrion, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, 0302 clinical medicine, medicine, Humans, lcsh:QH301-705.5, Polymerase, Uncategorized, X-ray crystallography, Membrane potential, Protease, biology, Chemistry, Signal transducing adaptor protein, Nuclear Proteins, Mitochondrial proteins, Endopeptidase Clp, Recombinant Proteins, Cell biology, Protein quality control, Mitochondria, 030104 developmental biology, lcsh:Biology (General), Gene Expression Regulation, Docking (molecular), 11294 Institute of Evolutionary Medicine, Proteolysis, biology.protein, General Agricultural and Biological Sciences, Linker, 030217 neurology & neurosurgery, HeLa Cells

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., Strack et al find that Polymerase δ interacting protein 38 (PDIP38) is targeted to the mitochondrial matrix where it colocalises with the mitochondrial AAA + protein CLPXP. PDIP38 modulates the specificity of CLPXP in vitro and alters the stability of CLPX in vitro and in cells. The PDIP38 structure leads the authors to speculate that PDIP38 is a CLPXP adaptor.

Published

2020

6. PDIP38 is a novel adaptor-like modulator of the mitochondrial AAA+ protease CLPXP

Author

Verena J. Schuenemann, David A. Dougan, Kornelius Zeth, Tamanna Saiyed, Philip R. Strack, Liz J. Valente, Hanmiao Zhan, Erica J. Brodie, and Kaye N. Truscott

Subjects

Protease, biology, Chemistry, medicine.medical_treatment, Two-hybrid screening, Signal transducing adaptor protein, DNA polymerase delta, Cell biology, Docking (molecular), medicine, biology.protein, Target protein, Nuclear protein, Polymerase

Abstract

SummaryPolymerase δ interacting protein of 38 kDa (PDIP38) was originally identified in a yeast two hybrid screen as an interacting protein of DNA polymerase delta, more than a decade ago. Since this time several subcellular locations have been reported and hence its function remains controversial. Our current understanding of PDIP38 function has also been hampered by a lack of detailed biochemical or structural analysis of this protein. Here we show, that human PDIP38 is directed to the mitochondrion, where it resides in the matrix compartment, together with its partner protein CLPX. PDIP38 is a bifunctional protein, composed of two conserved domains separated by an α-helical hinge region (or middle domain). 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 (ZBD) of CLPX. In contrast, the C-terminal (DUF525) domain forms an Immunoglobin-like β-sandwich fold, which contains a highly conserved hydrophobic groove. Based on the physicochemical properties of this groove, we propose that PDIP38 is required for the recognition (and delivery to CLPXP) of proteins bearing specific hydrophobic degrons, potentially located at the termini of the target protein. Significantly, interaction with PDIP38 stabilizes the steady state levels of CLPX in vivo. Consistent with these data, PDIP38 inhibits the LONM-mediated turnover of CLPX in vitro. Collectively, our findings shed new light on the mechanistic and functional significance of PDIP38, indicating that in contrast to its initial identification as a nuclear protein, PIDP38 is a bona fide mitochondrial adaptor protein for the CLPXP protease.

Published

2020

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

Author

Megan J. Maher, David A. Dougan, Anuradha S. Herath, Kaye N. Truscott, and Saumya R. Udagedara

Subjects

Models, Molecular, 0301 basic medicine, Protein Conformation, Respiratory chain, SDHA, Flavoprotein, Dehydrogenase, Crystallography, X-Ray, Quinone oxidoreductase, 03 medical and health sciences, Bacterial Proteins, Protein Domains, Escherichia coli, Multidisciplinary, Flavoproteins, biology, Chemistry, Electron Transport Complex II, Escherichia coli Proteins, Succinate dehydrogenase, Biological Sciences, Fumarate reductase, Strobilurins, 030104 developmental biology, Biochemistry, biology.protein, Crystallization, Protein Binding

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-A 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 A 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.

Published

2018

8. Pupylation of PafA or Pup inhibits components of the Pup‐Proteasome System

Author

Adnan Ali H. Alhuwaider, Kaye N. Truscott, and David A. Dougan

Subjects

0301 basic medicine, Proteasome Endopeptidase Complex, Mycobacterium smegmatis, Biophysics, Protein degradation, Biochemistry, Substrate Specificity, 03 medical and health sciences, Bacterial Proteins, Ubiquitin, Structural Biology, Genetics, Molecular Biology, Adenosine Triphosphatases, chemistry.chemical_classification, DNA ligase, biology, Chemistry, Lysine, Ubiquitin-Protein Ligase Complexes, Cell Biology, biology.organism_classification, Recombinant Proteins, Enzyme assay, Cell biology, Nutrient starvation, 030104 developmental biology, Amino Acid Substitution, Pupylation, Proteasome, Proteolysis, Mutagenesis, Site-Directed, biology.protein, Protein Processing, Post-Translational

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.

Published

2017

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

Author

Erica J. Brodie, Tamanna Saiyed, Kaye N. Truscott, David A. Dougan, and Hanmiao Zhan

Subjects

Models, Molecular, 0301 basic medicine, Protein Conformation, Hearing Loss, Sensorineural, medicine.medical_treatment, Mutant, lcsh:Medicine, Peptide, Article, 03 medical and health sciences, Protein structure, medicine, Humans, Genetic Predisposition to Disease, lcsh:Science, Genetic Association Studies, chemistry.chemical_classification, Multidisciplinary, Protease, biology, lcsh:R, Genetic Variation, Active site, Endopeptidase Clp, Gonadal Dysgenesis, 46,XX, Mitochondria, Cell biology, 030104 developmental biology, Proteostasis, chemistry, Docking (molecular), Mutation, biology.protein, lcsh:Q, Homeostasis

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

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

Author

Linda A. Ward, Kaye N. Truscott, David A. Dougan, and Ju Lin Tan

Subjects

0301 basic medicine, Plasmodium, Biophysics, Protozoan Proteins, N-end rule, Protein degradation, Biology, Biochemistry, Substrate Specificity, 03 medical and health sciences, Residue (chemistry), Protein Domains, Structural Biology, Genetics, Tyrosine, Isoleucine, Molecular Biology, Apicoplast, Signal transducing adaptor protein, Cell Biology, Endopeptidase Clp, Neoplasm Proteins, 030104 developmental biology, Proteolysis, Leucine

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.

Published

2016

11. The structural biology of mitochondrial respiratory complex assembly

Author

David A. Dougan, Shadi Maghool, Michael T. Ryan, Megan J. Maher, Kaye N. Truscott, Saumya R. Udagedara, David A. Stroud, and A. Herath

Subjects

Inorganic Chemistry, Structural biology, Structural Biology, General Materials Science, Computational biology, Physical and Theoretical Chemistry, Respiratory system, Biology, Condensed Matter Physics, Biochemistry

Published

2018

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

Author

Ayenachew Bezawork-Geleta, David A. Dougan, Kaye N. Truscott, and Erica J. Brodie

Subjects

Proteases, Multidisciplinary, Protease La, biology, Endopeptidase Clp, Mitochondrion, Protein aggregation, Article, Cell biology, Mitochondria, Rats, Mitochondrial Proteins, Protein Aggregates, Proteostasis, Biochemistry, Chaperone (protein), Mitochondrial unfolded protein response, Proteolysis, biology.protein, Unfolded protein response, Unfolded Protein Response, Animals, Humans, Protein folding, HeLa Cells

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

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

Author

David A. Dougan, Kaye N. Truscott, Jessica E. Zammit, and Dimce Micevski

Subjects

Conformational change, AAA+, medicine.medical_treatment, Proteolysis, Bioinformatics, Biochemistry, Genetics and Molecular Biology (miscellaneous), Biochemistry, medicine, Regulated degradation, Anti-adaptors, Molecular Biosciences, lcsh:QH301-705.5, Molecular Biology, Original Research, degradation, RssB, Protease, anti-adaptor, medicine.diagnostic_test, Chemistry, Protein turnover, Signal transducing adaptor protein, regulation, Cell biology, Response regulator, lcsh:Biology (General), Docking (molecular), general stress response, AAA+ protease, rpoS

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