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1. To Kill or to Be Killed: How Does the Battle between the UPS and Autophagy Maintain the Intracellular Homeostasis in Eukaryotes?

   https://doi.org/10.3390/ijms24032221  

   Yu, Peifeng; Hua, Zhihua (February 2023, International Journal of Molecular Sciences)

   The ubiquitin-26S proteasome system and autophagy are two major protein degradation machineries encoded in all eukaryotic organisms. While the UPS is responsible for the turnover of short-lived and/or soluble misfolded proteins under normal growth conditions, the autophagy-lysosomal/vacuolar protein degradation machinery is activated under stress conditions to remove long-lived proteins in the forms of aggregates, either soluble or insoluble, in the cytoplasm and damaged organelles. Recent discoveries suggested an integrative function of these two seemly independent systems for maintaining the proteome homeostasis. One such integration is represented by their reciprocal degradation, in which the small 76-amino acid peptide, ubiquitin, plays an important role as the central signaling hub. In this review, we summarized the current knowledge about the activity control of proteasome and autophagosome at their structural organization, biophysical states, and turnover levels from yeast and mammals to plants. Through comprehensive literature studies, we presented puzzling questions that are awaiting to be solved and proposed exciting new research directions that may shed light on the molecular mechanisms underlying the biological function of protein degradation. 

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2. DnaK refolds denatured proteins by actively pulling out their misfolded structural elements

   https://doi.org/10.1101/2025.09.22.677870  

   Marszalek, Piotr E (September 2025, bioRxiv)

   a) Abstract DnaK is a prokaryotic Hsp70 chaperone, with numerous functions in helping to fold nascent polypeptides and more generally in proteostasis. It also restores native structures to heat-shocked proteins in an ATP-hydrolysis-dependent manner. The structures of DnaK complexes with nucleotides, co-chaperones andsmallpeptides have already been resolved. However, there are no structures of DnaK complexes with larger, mostly folded substrates, such as firefly luciferase (Fluc, 61 kDa), which impedes the understanding of the mechanism through which DnaK refolds such large proteins. Here, we generated a model of a DnaK-firefly luciferase complex with Alphafold3, and examined its dynamics with all-atom molecular dynamics simulations. In this complex, Fluc is immobilized under the DnaK alpha-helical lid against the NBD, not the SBDβ, contrary to the data reported in the literature for model peptides. The DnaK lid is positioned strategically over Fluc’s helix 405-411, which we recently determined to be the first (and likely the only) helix melted in Fluc at 42 °C. We simulated the interaction between DnaK and the helix in its native and misfolded state and found that during the lid translocation toward the SBDβ, only the melted helix follows the lid and is actively pulled out from Fluc, while the native helix is not dislocated. These observations suggest a new model for the DnaK chaperone mechanism, where the alpha helical lid forms hydrogen bonds to the protein segment to be structurally tested. Lid pulls out only highly deformable misfolded helices, allowing them to refold into their native structures, and does not pull out those that are correctly folded because they are not deformable. Broader Audience Statementc) DnaK is a model chaperone, which can reactivate thermally denatured proteins. Even though a plethora of significant findings about DnaK structure, dynamics and interactions with its co-chaperone have been accumulated over 30 years, the exact molecular mechanism by which DnaK refolds misfolded proteins remains a mystery. This work exploited the ability of the Alphafold3 platform to generate an atomistic model for a complex between DnaK and Firefly luciferase and used molecular dynamics simulations to directly capture how DnaK may assist denatured proteins by mechanically pulling out their misfolded helices. This study provides a new insight into the DnaK mechanism. 

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3. Friends in need: How chaperonins recognize and remodel proteins that require folding assistance

   https://doi.org/10.3389/fmolb.2022.1071168  

   Stan, George; Lorimer, George H.; Thirumalai, D. (November 2022, Frontiers in Molecular Biosciences)

   Chaperonins are biological nanomachines that help newly translated proteins to fold by rescuing them from kinetically trapped misfolded states. Protein folding assistance by the chaperonin machinery is obligatory in vivo for a subset of proteins in the bacterial proteome. Chaperonins are large oligomeric complexes, with unusual seven fold symmetry (group I) or eight/nine fold symmetry (group II), that form double-ring constructs, enclosing a central cavity that serves as the folding chamber. Dramatic large-scale conformational changes, that take place during ATP-driven cycles, allow chaperonins to bind misfolded proteins, encapsulate them into the expanded cavity and release them back into the cellular environment, regardless of whether they are folded or not. The theory associated with the iterative annealing mechanism, which incorporated the conformational free energy landscape description of protein folding, quantitatively explains most, if not all, the available data. Misfolded conformations are associated with low energy minima in a rugged energy landscape. Random disruptions of these low energy conformations result in higher free energy, less folded, conformations that can stochastically partition into the native state. Two distinct mechanisms of annealing action have been described. Group I chaperonins (GroEL homologues in eubacteria and endosymbiotic organelles), recognize a large number of misfolded proteins non-specifically and operate through highly coordinated cooperative motions. By contrast, the less well understood group II chaperonins (CCT in Eukarya and thermosome/TF55 in Archaea), assist a selected set of substrate proteins. Sequential conformational changes within a CCT ring are observed, perhaps promoting domain-by-domain substrate folding. Chaperonins are implicated in bacterial infection, autoimmune disease, as well as protein aggregation and degradation diseases. Understanding the chaperonin mechanism and the specific proteins they rescue during the cell cycle is important not only for the fundamental aspect of protein folding in the cellular environment, but also for effective therapeutic strategies. 

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4. Distribution and solvent exposure of Hsp70 chaperone binding sites across the Escherichia coli proteome

   https://doi.org/10.1002/prot.26456  

   Chen, Xi; Hutchinson, Rachel B.; Cavagnero, Silvia (January 2023, Proteins: Structure, Function, and Bioinformatics)

   Abstract Many proteins must interact with molecular chaperones to achieve their native state in the cell. Yet, how chaperone binding‐site characteristics affect the folding process is poorly understood. The ubiquitous Hsp70 chaperone system prevents client‐protein aggregation by holding unfolded conformations and by unfolding misfolded states. Hsp70 binding sites of client proteins comprise a nonpolar core surrounded by positively charged residues. However, a detailed analysis of Hsp70 binding sites on a proteome‐wide scale is still lacking. Further, it is not known whether proteins undergo some degree of folding while chaperone bound. Here, we begin to address the above questions by identifying Hsp70 binding sites in 2258Escherichia coli(E. coli) proteins. We find that most proteins bear at least one Hsp70 binding site and that the number of Hsp70 binding sites is directly proportional to protein size. Aggregation propensity upon release from the ribosome correlates with number of Hsp70 binding sites only in the case of large proteins. Interestingly, Hsp70 binding sites are more solvent‐exposed than other nonpolar sites, in protein native states. Our findings show that the majority ofE. coliproteins are systematically enabled to interact with Hsp70 even if this interaction only takes place during a fraction of the protein lifetime. In addition, our data suggest that some conformational sampling may take place within Hsp70‐bound states, due to the solvent exposure of some chaperone binding sites in native proteins. In all, we propose that Hsp70‐chaperone‐binding traits have evolved to favor Hsp70‐assisted protein folding devoid of aggregation. 

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5. Plant peroxisome proteostasis—establishing, renovating, and dismantling the peroxisomal proteome

   https://doi.org/10.1042/EBC20210059  

   Muhammad, DurreShahwar; Smith, Kathryn A.; Bartel, Bonnie (May 2022, Essays in Biochemistry)

   Abstract Plant peroxisomes host critical metabolic reactions and insulate the rest of the cell from reactive byproducts. The specialization of peroxisomal reactions is rooted in how the organelle modulates its proteome to be suitable for the tissue, environment, and developmental stage of the organism. The story of plant peroxisomal proteostasis begins with transcriptional regulation of peroxisomal protein genes and the synthesis, trafficking, import, and folding of peroxisomal proteins. The saga continues with assembly and disaggregation by chaperones and degradation via proteases or the proteasome. The story concludes with organelle recycling via autophagy. Some of these processes as well as the proteins that facilitate them are peroxisome-specific, while others are shared among organelles. Our understanding of translational regulation of plant peroxisomal protein transcripts and proteins necessary for pexophagy remain based in findings from other models. Recent strides to elucidate transcriptional control, membrane dynamics, protein trafficking, and conditions that induce peroxisome turnover have expanded our knowledge of plant peroxisomal proteostasis. Here we review our current understanding of the processes and proteins necessary for plant peroxisome proteostasis—the emergence, maintenance, and clearance of the peroxisomal proteome. 

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