Activation and control of p53 tetramerization in individual living cells

Gaglia, Giorgio; Guan, Yalin; Shah, Jagesh V.; Lahav, Galit

doi:10.1073/pnas.1311126110

Cited by 115 publications

(123 citation statements)

References 27 publications

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“…Brightness values (Fig. 1B) are consistent with the dimer-to-tetramer transition recently reported in vivo (19), demonstrating the capability of the technique to discriminate between these oligomerization states. However, concerns regarding a possible artifact of the technique at the array need to be addressed.…”

Section: Significancesupporting

confidence: 87%

DNA binding triggers tetramerization of the glucocorticoid receptor in live cells

Presman

Ganguly

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

116

190

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Transcription factors dynamically bind to chromatin and are essential for the regulation of genes. Although a large percentage of these proteins appear to self-associate to form dimers or higher order oligomers, the stoichiometry of DNA-bound transcription factors has been poorly characterized in vivo. The glucocorticoid receptor (GR) is a ligandregulated transcription factor widely believed to act as a dimer or a monomer. Using a unique set of imaging techniques coupled with a cell line containing an array of DNA binding elements, we show that GR is predominantly a tetramer when bound to its target DNA. We find that DNA binding triggers an interdomain allosteric regulation within the GR, leading to tetramerization. We therefore propose that dynamic changes in GR stoichiometry represent a previously unidentified level of regulation in steroid receptor activation. Quaternary structure analysis of other members of the steroid receptor family (estrogen, androgen, and progesterone receptors) reveals variation in oligomerization states among this family of transcription factors. Because GR's oligomerization state has been implicated in therapy outcome, our findings open new doors to the rational design of novel GR ligands and redefine the quaternary structure of steroid receptors. Steroid receptors are transcription factors regulated by physiological stimuli that dynamically bind to chromatin and control complex biological pathways (1). In particular, the glucocorticoid receptor (GR) is essential for life and is one of the most targeted proteins in the pharmacological industry due to its powerful antiinflammatory and immunosuppressive activities (2). Current pharmaceutical approaches are based on a recently challenged (3) binary model wherein direct binding of GR dimers and indirect binding of GR monomers via other proteins determine the transcriptional output (4).Upon hormone activation, GR associates to a subset of glucocorticoid response elements (GREs) across the genome, depending on the accessibility of the chromatin landscape (5). GR is a modular protein organized into three structural and functional domains; the N-terminal ligand-independent activation function-1 domain (NTD), the central DNA-binding domain (DBD), and the C-terminal ligand-binding domain (LBD) (6). GR, and all steroid receptors, are widely believed to bind DNA directly as homodimers (7). However, this paradigm has been established exclusively from in vitro studies, working mostly with the DBD fragment (8-10), only using the whole GR protein in rare cases (11,12). The small number of experiments performed in live cells only addresses the entire nuclear population, lacking specific information regarding the GR fraction bound to chromatin (13-16). Furthermore, these studies were unable to discriminate between dimers or higher oligomeric states.For the present study, we combine an experimental model where GR-DNA interaction can be observed in real time with techniques that allow the quantification of the oligomeric state of proteins inside living...

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Section: Significancesupporting

confidence: 87%

DNA binding triggers tetramerization of the glucocorticoid receptor in live cells

Presman

Ganguly

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

116

190

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“…These findings suggested to us that a dynamic intracellular population of metastable αS multimers and monomers coexists normally, and others have proposed similar models of dynamic/metastable tetramers (12), multimers (15), or "conformers" that may represent multimers (16). Analogous dynamic equilibria have been proposed for well-known tetrameric proteins such as hemoglobin (17) and p53 (18). An older study, from when αS was assumed to be solely monomeric, showed crosslinked low-n αS multimers in intact cells, and the authors discussed the possibility that synuclein normally exists in cells as low molecular mass oligomers, primarily dimers and trimers, that are in equilibrium with monomeric synuclein and are stabilized by experimentally induced covalent association (19).…”

supporting

confidence: 57%

KTKEGV repeat motifs are key mediators of normal α-synuclein tetramerization: Their mutation causes excess monomers and neurotoxicity

Dettmer

Newman

Saucken

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

149

184

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α-Synuclein (αS) is a highly abundant neuronal protein that aggregates into β-sheet-rich inclusions in Parkinson's disease (PD). αS was long thought to occur as a natively unfolded monomer, but recent work suggests it also occurs normally in α-helix-rich tetramers and related multimers. To elucidate the fundamental relationship between αS multimers and monomers in living neurons, we performed systematic mutagenesis to abolish self-interactions and learn which structural determinants underlie native multimerization. Unexpectedly, tetramers/multimers still formed in cells expressing each of 14 sequential 10-residue deletions across the 140-residue polypeptide. We postulated compensatory effects among the six highly conserved and one to three additional αS repeat motifs (consensus: KTKEGV), consistent with αS and its homologs β-and γ-synuclein all forming tetramers while sharing only the repeats. Upon inserting in-register missense mutations into six or more αS repeats, certain mutations abolished tetramer formation, shown by intact-cell cross-linking and independently by fluorescentprotein complementation. For example, altered repeat motifs KLKEGV, KTKKGV, KTKEIV, or KTKEGW did not support tetramerization, indicating the importance of charged or small residues. When we expressed numerous different in-register repeat mutants in human neural cells, all multimer-abolishing but no multimer-neutral mutants caused frank neurotoxicity akin to the proapoptotic protein Bax. The multimer-abolishing variants became enriched in bufferinsoluble cell fractions and formed round cytoplasmic inclusions in primary cortical neurons. We conclude that the αS repeat motifs mediate physiological tetramerization, and perturbing them causes PD-like neurotoxicity. Moreover, the mutants we describe are valuable tools for studying normal and pathological properties of αS and screening for tetramer-stabilizing therapeutics.alpha-synuclein | multimer | tetramer | Parkinson's disease | neurotoxicity

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“…2) on DNA, such as histone 2AX, and on checkpoint 2 protein kinase (Chk2), which, in turn, rapidly phosphorylates and activates p53 (42,43). Although phosphorylation of human p53 at Ser 20 by Chk2 is important for its transactivation of p21 CDKN1A (which encodes the cyclin-dependent kinase inhibitor 1A) and other stress response targets (44), p53 tetramerization is also essential for its activation (45,46).…”

Section: Stresses Trigger Autophagy Mtorc1 Has a Central Role In The mentioning

confidence: 99%

Retrograde signaling from autophagy modulates stress responses

et al. 2017

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Macroautophagy is a process in which cytoplasmic components, including whole organelles, are degraded within lysosomes. Basally, this process is essential for homeostasis and is constitutively functional in most cells, but it can also be implemented as part of stress responses. We discuss findings showing that autophagy proteins can modulate and amplify the activities of transcription factors involved in stress responses, such as those in the p53, FOXO, MiT/TFE, Nrf2, and NFkB/Rel families. Thus, transcription factors not only amplify stress responses and autophagy but are also subject to retrograde regulation by autophagy-related proteins. Physical interactions with autophagy-related proteins, competition for activating intermediates, and "signalphagy," which is the role autophagy plays in the degradation of specific signaling proteins, together provide powerful tools for implementing negative feedback or positive feed-forward loops on the transcription factors that regulate autophagy. We present examples illustrating how this network interacts to regulate metabolic and physiologic responses.

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Activation and control of p53 tetramerization in individual living cells

Cited by 115 publications

References 27 publications

DNA binding triggers tetramerization of the glucocorticoid receptor in live cells

DNA binding triggers tetramerization of the glucocorticoid receptor in live cells

KTKEGV repeat motifs are key mediators of normal α-synuclein tetramerization: Their mutation causes excess monomers and neurotoxicity

Retrograde signaling from autophagy modulates stress responses

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