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3. Changing course: Glucose starvation drives nuclear accumulation of Hexokinase 2 in S. cerevisiae.

Author

Lesko, Mitchell A., Chandrashekarappa, Dakshayini G., Jordahl, Eric M., Oppenheimer, Katherine G., Bowman II, Ray W., Shang, Chaowei, Durrant, Jacob D., Schmidt, Martin C., and O'Donnell, Allyson F.

Subjects
GLUCOKINASE, GLUCOSE, PROTEIN kinases, GENETIC transcription regulation, STARVATION, GLUCOSE-regulated proteins
Abstract

Glucose is the preferred carbon source for most eukaryotes, and the first step in its metabolism is phosphorylation to glucose-6-phosphate. This reaction is catalyzed by either hexokinases or glucokinases. The yeast Saccharomyces cerevisiae encodes three such enzymes, Hxk1, Hxk2, and Glk1. In yeast and mammals, some isoforms of this enzyme are found in the nucleus, suggesting a possible moonlighting function beyond glucose phosphorylation. In contrast to mammalian hexokinases, yeast Hxk2 has been proposed to shuttle into the nucleus in glucose-replete conditions, where it reportedly moonlights as part of a glucose-repressive transcriptional complex. To achieve its role in glucose repression, Hxk2 reportedly binds the Mig1 transcriptional repressor, is dephosphorylated at serine 15 and requires an N-terminal nuclear localization sequence (NLS). We used high-resolution, quantitative, fluorescent microscopy of live cells to determine the conditions, residues, and regulatory proteins required for Hxk2 nuclear localization. Countering previous yeast studies, we find that Hxk2 is largely excluded from the nucleus under glucose-replete conditions but is retained in the nucleus under glucose-limiting conditions. We find that the Hxk2 N-terminus does not contain an NLS but instead is necessary for nuclear exclusion and regulating multimerization. Amino acid substitutions of the phosphorylated residue, serine 15, disrupt Hxk2 dimerization but have no effect on its glucose-regulated nuclear localization. Alanine substation at nearby lysine 13 affects dimerization and maintenance of nuclear exclusion in glucose-replete conditions. Modeling and simulation provide insight into the molecular mechanisms of this regulation. In contrast to earlier studies, we find that the transcriptional repressor Mig1 and the protein kinase Snf1 have little effect on Hxk2 localization. Instead, the protein kinase Tda1 regulates Hxk2 localization. RNAseq analyses of the yeast transcriptome dispels the idea that Hxk2 moonlights as a transcriptional regulator of glucose repression, demonstrating that Hxk2 has a negligible role in transcriptional regulation in both glucose-replete and limiting conditions. Our studies define a new model of cis- and trans-acting regulators of Hxk2 dimerization and nuclear localization. Based on our data, the nuclear translocation of Hxk2 in yeast occurs in glucose starvation conditions, which aligns well with the nuclear regulation of mammalian orthologs. Our results lay the foundation for future studies of Hxk2 nuclear activity. Author summary: Glucose is converted to energy in most cells. To initiate this conversion, enzymes called hexokinases must modify glucose, making them critical metabolic regulators. Mutations that change hexokinase function are associated with disease, including cancers and metabolic disorders. In addition to modifying glucose, which happens in the cytosol, hexokinases can move into the nucleus where their function is not as well understood. We demonstrate that in yeast, hexokinase 2 moves into the nucleus when cells are starved for glucose and is nuclear excluded in rich glucose conditions. We define key regulators, both within hexokinase 2 itself and in hexokinase 2 interacting proteins, that control its nuclear localization. Finally, we demonstrate that hexokinase 2 does not directly control gene expression in response to changing glucose environments. Our work contradicts a long-standing view for hexokinase 2 nuclear regulation and function and presents a new model for how hexokinase 2 nuclear localization is contolled. [ABSTRACT FROM AUTHOR]

Published
2023
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4. HIRA protects telomeres against R-loop-induced instability in ALT cancer cells.

Author

Lynskey, Michelle Lee, Brown, Emily E., Bhargava, Ragini, Wondisford, Anne R., Ouriou, Jean-Baptiste, Freund, Oliver, Bowman II, Ray W., Smith, Baylee A., Lardo, Santana M., Schamus-Hayes, Sandra, Hainer, Sarah J., and O'Sullivan, Roderick J.

Abstract

Inactivating mutations in chromatin modifiers, like the α-thalassemia/mental retardation, X-linked (ATRX)-death domain-associated protein (DAXX) chromatin remodeling/histone H3.3 deposition complex, drive the cancer-specific alternative lengthening of telomeres (ALT) pathway. Prior studies revealed that HIRA, another histone H3.3 chaperone, compensates for ATRX-DAXX loss at telomeres to sustain ALT cancer cell survival. How HIRA rescues telomeres from the consequences of ATRX-DAXX deficiency remains unclear. Here, using an assay for transposase-accessible chromatin using sequencing (ATAC-seq) and cleavage under targets and release using nuclease (CUT&RUN), we establish that HIRA-mediated deposition of new H3.3 maintains telomeric chromatin accessibility to prevent the detrimental accumulation of nucleosome-free single-stranded DNA (ssDNA) in ATRX-DAXX-deficient ALT cells. We show that the HIRA-UBN1/UBN2 complex deposits new H3.3 to prevent TERRA R-loop buildup and transcription-replication conflicts (TRCs) at telomeres. Furthermore, HIRA-mediated H3.3 incorporation into telomeric chromatin links productive ALT to the phosphorylation of serine 31, an H3.3-specific amino acid, by Chk1. Therefore, we identify a critical role for HIRA-mediated H3.3 deposition that ensures the survival of ATRX-DAXX-deficient ALT cancer cells. [Display omitted] • HIRA establishes greater telomeric chromatin accessibility after ATRX-DAXX loss • Deposition of new H3.3 by HIRA-UBN restricts telomeric ssDNA and TERRA R-loops • Unresolved TERRA R-loops block new H3.3 deposition by HIRA-UBN • CHK1 phosphorylation of H3.3 is critical to prevent ssDNA and TERRA R-loop buildup Lynskey et al. report links between HIRA-mediated histone H3.3 deposition and R-loop homeostasis at ALT telomeres. In most ALT cancer cells, after ATRX-DAXX is inactivated, HIRA regulates telomeric chromatin assembly. HIRA limits ssDNA accumulation and mitigates out-of-control R-loop formation and transcription-replication conflicts at telomeres, threatening cancer cell survival. [ABSTRACT FROM AUTHOR]

Published
2024
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5. TORC1 Signaling Controls the Stability and Function of α-Arrestins Aly1 and Aly2.

Author

Bowman II, Ray W., Jordahl, Eric M., Davis, Sydnie, Hedayati, Stefanie, Barsouk, Hannah, Ozbaki-Yagan, Nejla, Chiang, Annette, Li, Yang, and O'Donnell, Allyson F.

Subjects
*ARRESTINS, *MEMBRANE proteins, *CARRIER proteins, *MEMBRANE transport proteins, *PHOSPHOPROTEIN phosphatases, *CELL communication, *ADAPTOR proteins
Abstract

Nutrient supply dictates cell signaling changes, which in turn regulate membrane protein trafficking. To better exploit nutrients, cells relocalize membrane transporters via selective protein trafficking. Key in this reshuffling are the α-arrestins, selective protein trafficking adaptors conserved from yeast to man. α-Arrestins bind membrane proteins, controlling the ubiquitination and endocytosis of many transporters. To prevent the spurious removal of membrane proteins, α-arrestin-mediated endocytosis is kept in check through phospho-inhibition. This phospho-regulation is complex, with up to 87 phospho-sites on a single α-arrestin and many kinases/phosphatases targeting α-arrestins. To better define the signaling pathways controlling paralogous α-arrestins, Aly1 and Aly2, we screened the kinase and phosphatase deletion (KinDel) library, which is an array of all non-essential kinase and phosphatase yeast deletion strains, for modifiers of Aly-mediated phenotypes. We identified many Aly regulators, but focused our studies on the TORC1 kinase, a master regulator of nutrient signaling across eukaryotes. We found that TORC1 and its signaling effectors, the Sit4 protein phosphatase and Npr1 kinase, regulate the phosphorylation and stability of Alys. When Sit4 is lost, Alys are hyperphosphorylated and destabilized in an Npr1-dependent manner. These findings add new dimensions to our understanding of TORC1 regulation of α-arrestins and have important ramifications for cellular metabolism. [ABSTRACT FROM AUTHOR]

Published
2022
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