SUMMARY
Composed of up to 1000 phospho-anhydride bond-linked phosphate monomers, inorganic polyphosphate (polyP) is one of the most ancient, conserved, and enigmatic molecules in biology. Here we demonstrate that polyP functions as a hitherto unrecognized chaperone. We show that polyP stabilizes proteins in vivo, diminishes the need for other chaperone systems to survive proteotoxic stress conditions, and protects a wide variety of proteins against stress-induced unfolding and aggregation. In vitro studies reveal that polyP has protein-like chaperone qualities, binds to unfolding proteins with high affinity in an ATP-independent manner, and supports their productive refolding once non-stress conditions are restored. Our results uncover a universally important function for polyP and suggest that these long chains of inorganic phosphate may have served as one of nature’s first chaperones, a role that continues to the present day.
The process of ribosomal recoding is generally regulated by an autonomous mRNA signal downstream of stop-codons. While structural studies have provided mechanistic insights into viral systems, no such studies exist in mammalian systems. Here we define a novel structural mechanism for the VEGF-A readthrough system and show that regulation is multifaceted and complex, requiring a multipartite set of RNA elements located at long distances that interact with each other and with hnRNP A2/B1 to synergistically enhance readthrough levels. The Ax-element downstream of the stop codon adopts a unique multistem (SL-Ax1-3) architecture: SL-Ax1 interacts with hnRNP A2/B1, while SL-Ax2 interacts with an RNA element (SL-Au1) located ~500 nt upstream at the start of the coding sequence. SL-Au1 also independently binds to hnRNP A2/B1, which manipulates an equilibrium between alternate structures— from a sequestered bulge towards one that allows for the long-range interaction with SL-Ax2. Overall, our study not only highlights the significance of structural organization of elements within the coding sequence of mRNA, but also provides a functional relevance of the closed-loop mRNA organization in non-canonical translation and suggests complex mechanisms allow for finer integration of many signals for a required output.
The present work addresses the topic of die clamping at the forging hammer in the context of the definition of a current requirement profile as well as the evaluation of individual influencing variables on the clamping process. In addition to the presentation of survey results for the requirements profile, the first part focus on the sensible minimization of influencing variables to be investigated and on the verification of a possible evaluation method. Based on this, in the second part exemplary influencing variables on the clamping condition are investigated by means of FEM. Thereby it can be shown by way of example, that the heat flow of the forging process and the friction conditions between the clamping elements have a noteworthy influence on the clamping condition of the dies and that deviations in the clamping force can lead to significant damage.
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