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1. Yeast poly(A)-binding protein (Pab1) controls translation initiation in vivo primarily by blocking mRNA decapping and decay

   https://doi.org/10.1093/nar/gkaf143  

   Poonia, Poonam; Valabhoju, Vishalini; Li, Tianwei; Iben, James; Niu, Xiao; Lin, Zhenguo; Hinnebusch, Alan G (February 2025, Nucleic Acids Research)

   Abstract Poly(A)-binding protein (Pab1 in yeast) is involved in mRNA decay and translation initiation, but its molecular functions are incompletely understood. We found that auxin-induced degradation of Pab1 reduced bulk mRNA and polysome abundance in WT but not in a mutant lacking the catalytic subunit of decapping enzyme (Dcp2), suggesting that enhanced decapping/degradation is a major driver of reduced translation at limiting Pab1. An increased median poly(A) tail length conferred by Pab1 depletion was likewise not observed in the dcp2Δ mutant, suggesting that mRNA isoforms with shorter tails are preferentially decapped/degraded at limiting Pab1. In contrast to findings on mammalian cells, the translational efficiencies (TEs) of many mRNAs were altered by Pab1 depletion; however, these changes were diminished in dcp2Δ cells, suggesting that reduced mRNA abundance is also a major driver of translational reprogramming at limiting Pab1. Thus, assembly of the closed-loop mRNP via PABP–eIF4G interaction appears to be dispensable for wild-type translation of most transcripts at normal mRNA levels. Interestingly, histone mRNAs and proteins were preferentially diminished on Pab1 depletion in DCP2 but not dcp2Δ cells, accompanied by activation of internal cryptic promoters in the manner expected for reduced nucleosome occupancies, implicating Pab1 in post-transcriptional control of histone gene expression. 

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2. 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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3. An adaptive biomolecular condensation response is conserved across environmentally divergent species

   https://doi.org/10.1038/s41467-024-47355-9  

   Keyport_Kik, Samantha; Christopher, Dana; Glauninger, Hendrik; Hickernell, Caitlin_Wong; Bard, Jared_A_M; Lin, Kyle_M; Squires, Allison_H; Ford, Michael; Sosnick, Tobin_R; Drummond, D_Allan (April 2024, Nature Communications)

   Abstract Cells must sense and respond to sudden maladaptive environmental changes—stresses—to survive and thrive. Across eukaryotes, stresses such as heat shock trigger conserved responses: growth arrest, a specific transcriptional response, and biomolecular condensation of protein and mRNA into structures known as stress granules under severe stress. The composition, formation mechanism, adaptive significance, and even evolutionary conservation of these condensed structures remain enigmatic. Here we provide a remarkable view into stress-triggered condensation, its evolutionary conservation and tuning, and its integration into other well-studied aspects of the stress response. Using three morphologically near-identical budding yeast species adapted to different thermal environments and diverged by up to 100 million years, we show that proteome-scale biomolecular condensation is tuned to species-specific thermal niches, closely tracking corresponding growth and transcriptional responses. In each species, poly(A)-binding protein—a core marker of stress granules—condenses in isolation at species-specific temperatures, with conserved molecular features and conformational changes modulating condensation. From the ecological to the molecular scale, our results reveal previously unappreciated levels of evolutionary selection in the eukaryotic stress response, while establishing a rich, tractable system for further inquiry. 

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4. Proteome-wide determinants of co-translational chaperone binding in bacteria

   https://doi.org/10.1038/s41467-025-59067-9  

   Galmozzi, Carla Verónica; Tippmann, Frank; Wruck, Florian; Auburger, Josef Johannes; Kats, Ilia; Guennigmann, Manuel; Till, Katharina; O´Brien, Edward P; Tans, Sander J; Kramer, Günter; et al (December 2025, Nature Communications)

   Abstract Chaperones are essential to the co-translational folding of most proteins. However, the principles of co-translational chaperone interaction throughout the proteome are poorly understood, as current methods are restricted to few substrates and cannot capture nascent protein folding or chaperone binding sites, precluding a comprehensive understanding of productive and erroneous protein biosynthesis. Here, by integrating genome-wide selective ribosome profiling, single-molecule tools, and computational predictions using AlphaFold we show that the binding of the mainE. colichaperones involved in co-translational folding, Trigger Factor (TF) and DnaK correlates with “unsatisfied residues” exposed on nascent partial folds – residues that have begun to form tertiary structure but cannot yet form all native contacts due to ongoing translation. This general principle allows us to predict their co-translational binding across the proteome based on sequence only, which we verify experimentally. The results show that TF and DnaK stably bind partially folded rather than unfolded conformers. They also indicate a synergistic action of TF guiding intra-domain folding and DnaK preventing premature inter-domain contacts, and reveal robustness in the larger chaperone network (TF, DnaK, GroEL). Given the complexity of translation, folding, and chaperone functions, our predictions based on general chaperone binding rules indicate an unexpected underlying simplicity. 

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5. The landscape of transcriptional and 1translational changes over 22 years of bacterial adaptation

   https://doi.org/10.7554/eLife.81979  

   Favate, John S; Liang, Shun; Cope, Alexander L; Yadavalli, Srujana Samhita; Shah, Premal (October 2022, eLife)

   Organisms can adapt to an environment by taking multiple mutational paths. This redundancy at the genetic level, where many mutations have similar phenotypic and fitness effects, can make untangling the molecular mechanisms of complex adaptations difficult. Here we use the E. coli long-term evolution experiment (LTEE) as a model to address this challenge. To understand how different genomic changes could lead to parallel fitness gains, we characterize the landscape of transcriptional and translational changes across 12 replicate populations evolving in parallel for 50,000 generations. By quantifying absolute changes in mRNA abundances, we show that not only do all evolved lines have more mRNAs but that this increase in mRNA abundance scales with cell size. We also find that despite few shared mutations at the genetic level, clones from replicate populations in the LTEE are remarkably similar in their gene expression patterns at both the transcriptional and translational levels. Furthermore, we show that the majority of the expression changes are due to changes at the transcriptional level with very few translational changes. Finally, we show how mutations in transcriptional regulators lead to consistent and parallel changes in the expression levels of downstream genes. These results deepen our understanding of the molecular mechanisms underlying complex adaptations and provide insights into the repeatability of evolution. 

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