Low amounts of heavy water increase the phase separation propensity of a fragment of the androgen receptor activation domain

Bielskutė, Stasė; Garcia‐Cabau, Carla; Frigolé-Vivas, Marta; Szulc, Elzbieta; Mol, Eva De; Pesarrodona, Mireia; García, Jesús; Salvatella, Xavier

doi:10.1002/pro.4110

Cited by 18 publications

(22 citation statements)

References 48 publications

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“…Within this context, recent discoveries regarding phase separation of AR are of high interest. It has been demonstrated that the intrinsically disordered N-terminal domain of AR forms liquid-like droplets in vitro at ∼100 μM ( 17 ), and the isolated Tau 5 region within this NTD at ∼500 μM ( 18 ). Moreover, the isolated DBD was shown to undergo phase separation in presence of RNA (poly U) ( 19 ).…”

Section: Introductionmentioning

confidence: 99%

Dynamic phase separation of the androgen receptor and its coactivators key to regulate gene expression

Zhang

Biswas

Massah

et al. 2022

Nucleic Acids Research

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Numerous cancers, including prostate cancer (PCa), are addicted to transcription programs driven by specific genomic regions known as super-enhancers (SEs). The robust transcription of genes at such SEs is enabled by the formation of phase-separated condensates by transcription factors and coactivators with intrinsically disordered regions. The androgen receptor (AR), the main oncogenic driver in PCa, contains large disordered regions and is co-recruited with the transcriptional coactivator mediator complex subunit 1 (MED1) to SEs in androgen-dependent PCa cells, thereby promoting oncogenic transcriptional programs. In this work, we reveal that full-length AR forms foci with liquid-like properties in different PCa models. We demonstrate that foci formation correlates with AR transcriptional activity, as this activity can be modulated by changing cellular foci content chemically or by silencing MED1. AR ability to phase separate was also validated in vitro by using recombinant full-length AR protein. We also demonstrate that AR antagonists, which suppress transcriptional activity by targeting key regions for homotypic or heterotypic interactions of this receptor, hinder foci formation in PCa cells and phase separation in vitro. Our results suggest that enhanced compartmentalization of AR and coactivators may play an important role in the activation of oncogenic transcription programs in androgen-dependent PCa.

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Section: Introductionmentioning

confidence: 99%

Dynamic phase separation of the androgen receptor and its coactivators key to regulate gene expression

Zhang

Biswas

Massah

et al. 2022

Nucleic Acids Research

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“…Some important steps have been taken including insights from single‐molecule fluorescence resonance energy transfer (smFRET), electron paramagnetic resonance (EPR), and nuclear magnetic resonance (NMR) 13 . However, none have been applied successfully to resolve the structure of the full‐length AR‐NTD due to technical difficulties 14–16 …”

Section: Introductionmentioning

confidence: 99%

“…13 However, none have been applied successfully to resolve the structure of the fulllength AR-NTD due to technical difficulties. [14][15][16] The intrinsic disorder poses a challenge not only for experimental analysis of the conformation but also for computational modeling of the chain due to the size of the conformation space and lack of stable folds. For example, the state-of-the art artificial intelligence-based prediction approaches fail to identify the conformation of AR-NTD.…”

Section: Introductionmentioning

confidence: 99%

Topological dynamics of an intrinsically disordered N‐terminal domain of the human androgen receptor

Sheikhhassani

Scalvini

et al. 2022

Protein Science

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Human androgen receptor contains a large N-terminal domain (AR-NTD) that is highly dynamic and this poses a major challenge for experimental and computational analysis to decipher its conformation. Misfolding of the AR-NTD is implicated in prostate cancer and Kennedy's disease, yet our knowledge of its structure is limited to primary sequence information of the chain and a few functionally important secondary structure motifs. Here, we employed an innovative combination of molecular dynamics simulations and circuit topology (CT) analysis to identify the tertiary structure of AR-NTD. We found that the AR-NTD adopts highly dynamic loopy conformations with two identifiable regions with distinct topological make-up and dynamics. This consists of a N-terminal region (NR, residues 1-224) and a C-terminal region (CR, residues 225-538), which carries a dense core. Topological mapping of the dynamics reveals a traceable time-scale dependent topological evolution. NR adopts different positioning with respect to the CR and forms a cleft that can partly enclose the hormone-bound ligand-binding domain (LBD) of the androgen receptor. Furthermore, our data suggest a model in which dynamic NR and CR compete for binding to the DNA-binding domain of the receptor, thereby regulating the accessibility of its DNA-binding site. Our approach allowed for the identification of a previously unknown regulatory binding site within the CR core, revealing the structural mechanisms of action of AR inhibitor EPI-001, and paving the way for other drug discovery applications. K E Y W O R D Sandrogen receptor, circuit topology, conformational dynamics, intrachain contacts, nuclear hormone receptors Vahid Sheikhhassani and Barbara Scalvini contributed equally to this study.

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“…Another fluorinated molecule (TFT) in a coaxial insert acts as an external reference 39 , and enables observation of magnetic field inhomogeneity emerging as a result of macroscopic layer separation, without the complication of the reference solution itself participating in LLPS. The coaxial insert is also crucial for housing deuterated solvent for field-frequency lock required by the NMR spectrometer, thereby avoiding the addition of 2 H 2 O directly to the protein solution, which is known to alter the LLPS propensity of proteins 33 , 40 , 41 . Despite the presence of two distinct phases emerging during the initial microscopic phase separation, magnetic field homogeneity, as judged by TFT signal lineshape, is initially remarkably unperturbed.…”

Section: Discussionmentioning

confidence: 99%

Temporal and spatial characterisation of protein liquid-liquid phase separation using NMR spectroscopy

Bramham

Golovanov

2022

Nat Commun

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Liquid-liquid phase separation (LLPS) of protein solutions is increasingly recognised as an important phenomenon in cell biology and biotechnology. However, opalescence and concentration fluctuations render LLPS difficult to study, particularly when characterising the kinetics of the phase transition and layer separation. Here, we demonstrate the use of a probe molecule trifluoroethanol (TFE) to characterise the kinetics of protein LLPS by NMR spectroscopy. The chemical shift and linewidth of the probe molecule are sensitive to local protein concentration, with this sensitivity resulting in different characteristic signals arising from the dense and lean phases. Monitoring of these probe signals by conventional bulk-detection 19F NMR reports on the formation and evolution of both phases throughout the sample, including their concentrations and volumes. Meanwhile, spatially-selective 19F NMR, in which spectra are recorded from smaller slices of the sample, was used to track the distribution of the different phases during layer separation. This experimental strategy enables comprehensive characterisation of the process and kinetics of LLPS, and may be useful to study phase separation in protein systems as a function of their environment.

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Low amounts of heavy water increase the phase separation propensity of a fragment of the androgen receptor activation domain

Cited by 18 publications

References 48 publications

Dynamic phase separation of the androgen receptor and its coactivators key to regulate gene expression

Dynamic phase separation of the androgen receptor and its coactivators key to regulate gene expression

Topological dynamics of an intrinsically disordered N‐terminal domain of the human androgen receptor

Temporal and spatial characterisation of protein liquid-liquid phase separation using NMR spectroscopy

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