Your search keyword '"Nüske E"' showing total 9 results

1. Filament formation by metabolic enzymes is a specific adaptation to an advanced state of cellular starvation

Author

Petrovska, I., Nüske, E., Munder, M. C., Kulasegaran, G., Malinovska, L., Kroschwald, S., Richter, D., Fahmy, K., Gibson, K., Verbavatz, J.-M., Alberti, S., Petrovska, I., Nüske, E., Munder, M. C., Kulasegaran, G., Malinovska, L., Kroschwald, S., Richter, D., Fahmy, K., Gibson, K., Verbavatz, J.-M., and Alberti, S.

Abstract

One of the key questions in biology is how the metabolism of a cell responds to changes in the environment. In budding yeast, starvation causes a drop in intracellular pH, but the functional role of this pH change is not well understood. Here, we show that the enzyme glutamine synthetase (Gln1) forms filaments at low pH and that filament formation leads to enzyme inactivation. Filament formation by Gln1 is a highly cooperative process, strongly dependent on macromolecular crowding, and involves back-to-back stacking of cylindrical homo-decamers into filaments that associate laterally to form higher order fibrils. Other metabolic enzymes also assemble into filaments at low pH. Hence, we propose that filament formation is a general mechanism to inactivate and store key metabolic enzymes during a state of advanced cellular starvation. These findings have broad implications for understanding the interplay between nutritional stress, the metabolism and the physical organization of a cell.

Published

2014

2. Significant life events and social connectedness in Australian women’s gambling experiences

Author

Nuske Elaine Mary, Holdsworth Louise, and Breen Helen

Subjects

women, gambling, gender analysis, social capital theory, Social pathology. Social and public welfare. Criminology, HV1-9960, Social history and conditions. Social problems. Social reform, HN1-995

Abstract

AIM - The aim is to examine significant life events and social connections that encourage some women to gamble. Specifically, how do these events and connections described as important for women who develop gambling-related problems differ for women who remain recreational gamblers? DESIGN - 20 women who were electronic gaming machine (EGMs, poker machines, slots) players were interviewed using a brief interview guide. They also completed the nine question Problem Gambling Severity Index (PGSI) from the Canadian Problem Gambling Index CPGI). 11 women self-identified as recreational gamblers (RG) while 9 had sought and received help for their gambling problems (PG). Using a feminist, qualitative design and an adaptive grounded theory method to analyze their histories, a number of themes emerged indicating a progression to problem gambling for some and the ability to recognise when control over gambling was needed by others. RESULTS - Although both groups (RG and PG) reported common gambling motivations differences appeared in the strength of their social support networks and ways of coping with stress, especially stress associated with a significant life event. CONCLUSIONS - The human need for social connectedness and personal bonds with others emphasised the usefulness of using social capital theories in gambling research with women.

Published

2016

3. Filament formation by the translation factor eIF2B regulates protein synthesis in starved cells.

Author

Nüske E, Marini G, Richter D, Leng W, Bogdanova A, Franzmann TM, Pigino G, and Alberti S

Subjects

Cytosol metabolism, Hydrogen-Ion Concentration, Microbial Viability, Models, Biological, Phosphorylation, Yeasts physiology, Cytoskeleton metabolism, Energy Metabolism, Eukaryotic Initiation Factor-2B metabolism, Gene Expression Regulation, Protein Biosynthesis, Stress, Physiological

Abstract

Cells exposed to starvation have to adjust their metabolism to conserve energy and protect themselves. Protein synthesis is one of the major energy-consuming processes and as such has to be tightly controlled. Many mechanistic details about how starved cells regulate the process of protein synthesis are still unknown. Here, we report that the essential translation initiation factor eIF2B forms filaments in starved budding yeast cells. We demonstrate that filamentation is triggered by starvation-induced acidification of the cytosol, which is caused by an influx of protons from the extracellular environment. We show that filament assembly by eIF2B is necessary for rapid and efficient downregulation of translation. Importantly, this mechanism does not require the kinase Gcn2. Furthermore, analysis of site-specific variants suggests that eIF2B assembly results in enzymatically inactive filaments that promote stress survival and fast recovery of cells from starvation. We propose that translation regulation through filament assembly is an efficient mechanism that allows yeast cells to adapt to fluctuating environments., Competing Interests: Competing interestsSimon Alberti is an advisor on the scientific advisory board of Dewpoint Therapeutics., (© 2020. Published by The Company of Biologists Ltd.)

Published

2020

4. Reorganization of budding yeast cytoplasm upon energy depletion.

Author

Marini G, Nüske E, Leng W, Alberti S, and Pigino G

Subjects

Adenosine Triphosphate metabolism, Cytoplasm metabolism, Electron Microscope Tomography methods, Eukaryotic Initiation Factor-2B metabolism, Eukaryotic Initiation Factor-2B physiology, Organelles metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Cytoplasm physiology, Energy Metabolism physiology, Stress, Physiological physiology

Abstract

Yeast cells, when exposed to stress, can enter a protective state in which cell division, growth, and metabolism are down-regulated. They remain viable in this state until nutrients become available again. How cells enter this protective survival state and what happens at a cellular and subcellular level are largely unknown. In this study, we used electron tomography to investigate stress-induced ultrastructural changes in the cytoplasm of yeast cells. After ATP depletion, we observed significant cytosolic compaction and extensive cytoplasmic reorganization, as well as the emergence of distinct membrane-bound and membraneless organelles. Using correlative light and electron microscopy, we further demonstrated that one of these membraneless organelles was generated by the reversible polymerization of eukaryotic translation initiation factor 2B, an essential enzyme in the initiation of protein synthesis, into large bundles of filaments. The changes we observe are part of a stress-induced survival strategy, allowing yeast cells to save energy, protect proteins from degradation, and inhibit protein functionality by forming assemblies of proteins.

Published

2020

5. A method of predicting the in vitro fibril formation propensity of Aβ40 mutants based on their inclusion body levels in E. coli.

Author

Sanagavarapu K, Nüske E, Nasir I, Meisl G, Immink JN, Sormanni P, Vendruscolo M, Knowles TPJ, Malmendal A, Cabaleiro-Lago C, and Linse S

Subjects

Alzheimer Disease metabolism, Amyloid genetics, Electrophoresis, Polyacrylamide Gel, Escherichia coli genetics, Humans, Kinetics, Microscopy, Confocal, Recombinant Proteins genetics, Recombinant Proteins metabolism, Amyloid metabolism, Amyloid beta-Peptides genetics, Amyloid beta-Peptides metabolism, Escherichia coli cytology, Inclusion Bodies metabolism, Mutation, Peptide Fragments genetics, Peptide Fragments metabolism

Abstract

Overexpression of recombinant proteins in bacteria may lead to their aggregation and deposition in inclusion bodies. Since the conformational properties of proteins in inclusion bodies exhibit many of the characteristics typical of amyloid fibrils. Based on these findings, we hypothesize that the rate at which proteins form amyloid fibrils may be predicted from their propensity to form inclusion bodies. To establish a method based on this concept, we first measured by SDS-PAGE and confocal microscopy the level of inclusion bodies in E. coli cells overexpressing the 40-residue amyloid-beta peptide, Aβ40, wild-type and 24 charge mutants. We then compared these results with a number of existing computational aggregation propensity predictors as well as the rates of aggregation measured in vitro for selected mutants. Our results show a strong correlation between the level of inclusion body formation and aggregation propensity, thus demonstrating the power of this approach and its value in identifying factors modulating aggregation kinetics.

Published

2019

6. Phase separation of a yeast prion protein promotes cellular fitness.

Author

Franzmann TM, Jahnel M, Pozniakovsky A, Mahamid J, Holehouse AS, Nüske E, Richter D, Baumeister W, Grill SW, Pappu RV, Hyman AA, and Alberti S

Subjects

Catalytic Domain, Hydrogen-Ion Concentration, Peptide Termination Factors chemistry, Phase Transition, Prion Proteins chemistry, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae Proteins chemistry, Peptide Termination Factors metabolism, Prion Proteins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Stress, Physiological

Abstract

Despite the important role of prion domains in neurodegenerative disease, their physiological function has remained enigmatic. Previous work with yeast prions has defined prion domains as sequences that form self-propagating aggregates. Here, we uncovered an unexpected function of the canonical yeast prion protein Sup35. In stressed conditions, Sup35 formed protective gels via pH-regulated liquid-like phase separation followed by gelation. Phase separation was mediated by the N-terminal prion domain and regulated by the adjacent pH sensor domain. Phase separation promoted yeast cell survival by rescuing the essential Sup35 translation factor from stress-induced damage. Thus, prion-like domains represent conserved environmental stress sensors that facilitate rapid adaptation in unstable environments by modifying protein phase behavior., (Copyright © 2018, American Association for the Advancement of Science.)

Published

2018

7. A pH-driven transition of the cytoplasm from a fluid- to a solid-like state promotes entry into dormancy.

Author

Munder MC, Midtvedt D, Franzmann T, Nüske E, Otto O, Herbig M, Ulbricht E, Müller P, Taubenberger A, Maharana S, Malinovska L, Richter D, Guck J, Zaburdaev V, and Alberti S

Subjects

Cell Survival, Hydrogen-Ion Concentration, Stress, Physiological, Cytoplasm chemistry, Cytoplasm drug effects, Dictyostelium physiology, Phase Transition drug effects, Saccharomyces cerevisiae physiology

Abstract

Cells can enter into a dormant state when faced with unfavorable conditions. However, how cells enter into and recover from this state is still poorly understood. Here, we study dormancy in different eukaryotic organisms and find it to be associated with a significant decrease in the mobility of organelles and foreign tracer particles. We show that this reduced mobility is caused by an influx of protons and a marked acidification of the cytoplasm, which leads to widespread macromolecular assembly of proteins and triggers a transition of the cytoplasm to a solid-like state with increased mechanical stability. We further demonstrate that this transition is required for cellular survival under conditions of starvation. Our findings have broad implications for understanding alternative physiological states, such as quiescence and dormancy, and create a new view of the cytoplasm as an adaptable fluid that can reversibly transition into a protective solid-like state.

Published

2016

8. Promiscuous interactions and protein disaggregases determine the material state of stress-inducible RNP granules.

Author

Kroschwald S, Maharana S, Mateju D, Malinovska L, Nüske E, Poser I, Richter D, and Alberti S

Subjects

Protein Binding, Protein Interaction Mapping, Saccharomycetales physiology, Stress, Physiological, Cytoplasmic Granules metabolism, Protein Multimerization, Ribonucleoproteins metabolism, Saccharomycetales metabolism

Abstract

RNA-protein (RNP) granules have been proposed to assemble by forming solid RNA/protein aggregates or through phase separation into a liquid RNA/protein phase. Which model describes RNP granules in living cells is still unclear. In this study, we analyze P bodies in budding yeast and find that they have liquid-like properties. Surprisingly, yeast stress granules adopt a different material state, which is reminiscent of solid protein aggregates and controlled by protein disaggregases. By using an assay to ectopically nucleate RNP granules, we further establish that RNP granule formation does not depend on amyloid-like aggregation but rather involves many promiscuous interactions. Finally, we show that stress granules have different properties in mammalian cells, where they show liquid-like behavior. Thus, we propose that the material state of RNP granules is flexible and that the solid state of yeast stress granules is an adaptation to extreme environments, made possible by the presence of a powerful disaggregation machine.

Published

2015

9. Filament formation by metabolic enzymes is a specific adaptation to an advanced state of cellular starvation.

Author

Petrovska I, Nüske E, Munder MC, Kulasegaran G, Malinovska L, Kroschwald S, Richter D, Fahmy K, Gibson K, Verbavatz JM, and Alberti S

Abstract

One of the key questions in biology is how the metabolism of a cell responds to changes in the environment. In budding yeast, starvation causes a drop in intracellular pH, but the functional role of this pH change is not well understood. Here, we show that the enzyme glutamine synthetase (Gln1) forms filaments at low pH and that filament formation leads to enzymatic inactivation. Filament formation by Gln1 is a highly cooperative process, strongly dependent on macromolecular crowding, and involves back-to-back stacking of cylindrical homo-decamers into filaments that associate laterally to form higher order fibrils. Other metabolic enzymes also assemble into filaments at low pH. Hence, we propose that filament formation is a general mechanism to inactivate and store key metabolic enzymes during a state of advanced cellular starvation. These findings have broad implications for understanding the interplay between nutritional stress, the metabolism and the physical organization of a cell.

Published

2014