Alison Kurimchak scite author profile

SUMMARY Small molecule BET bromodomain inhibitors (BETi) are actively being pursued in clinical trials for the treatment of a variety of cancers, however, the mechanisms of resistance to BETi remain poorly understood. Using a mass spectrometry approach that globally measures kinase signaling at the proteomic level, we evaluated the response of the kinome to targeted BETi treatment in a panel of BRD4-dependent ovarian carcinoma (OC) cell lines. Despite initial inhibitory effects of BETi, OC cells acquired resistance following sustained treatment with the BETi, JQ1. Through application of Multiplexed Inhibitor Beads (MIBs) and mass spectrometry, we demonstrate that BETi resistance is mediated by adaptive kinome reprogramming, where activation of compensatory pro-survival kinase networks overcomes BET protein inhibition. Furthermore, drug combinations blocking these kinases may prevent or delay the development of drug resistance and enhance the efficacy of BETi therapy.

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B55α PP2A Holoenzymes Modulate the Phosphorylation Status of the Retinoblastoma-related Protein p107 and Its Activation

Jayadeva

Kurimchak

Garriga

et al. 2010

Journal of Biological Chemistry

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. These phosphorylations are reversed by the action of two families of Ser/Thr phosphatases: PP1, which has been implicated in abrupt dephosphorylation of retinoblastoma protein (pRB) in mitosis, and PP2A, which plays a role in an equilibrium that counteracts cyclin-dependent kinase (CDK) action throughout the cell cycle. However, the identity of the trimeric PP2A holoenzyme(s) functioning in this process is unknown. Here we report the identification of a PP2A trimeric holoenzyme containing B55␣, which plays a major role in restricting the phosphorylation state of p107 and inducing its activation in human cells. Our data also suggest targeted selectivity in the interaction of pocket proteins with distinct PP2A holoenzymes, which is likely necessary for simultaneous pocket protein activation.The retinoblastoma family of growth suppressor proteins, designated pocket proteins, includes the product of the retinoblastoma susceptibility gene and the functionally and structurally related proteins p107 and p130 (reviewed in Ref. 1). Pocket proteins suppress the G 0 /G 1 cell cycle transition and passage through the restriction point by repressing E2F-dependent transcription via a direct interaction of the hypophosphorylated pocket protein with members of the E2F family of transcription factors. Mitogen-dependent activation of D-type cyclin-CDK 2 complexes cooperates with cyclin E-CDK2 complexes to hyperphosphorylate pocket proteins starting in midto late G 1 disrupting the pocket protein-E2F interaction and relieving repression of many genes whose products are required for cell cycle progression. Pocket proteins remain hyperphosphorylated through the S and G 2 phases and part of mitosis as they become targets of cyclin-CDK complexes that operate at these cell cycle stages (reviewed in Refs. 2-4).As cyclin-CDK complexes are inactivated during mitotic exit, the three pocket proteins become simultaneously hypophosphorylated. PP1 has been implicated in dephosphorylation of pRB from mitosis to a point in G 1 , where pRB becomes hyperphosphorylated by G 1 cyclin-CDKs (reviewed in Refs. 3 and 5). However, a second phosphatase plays a role in reversing the action of CDKs throughout the cell cycle and in quiescent cells (6). When the activity of cyclin-CDK complexes is pharmacologically inhibited, pocket proteins become rapidly dephosphorylated, and the severity of the hypophosphorylation depends on the subsets of CDKs that become inactivated. For instance, cycloheximide, an inhibitor of protein synthesis, causes rapid down-regulation of short lived cyclins such as D-type cyclins, resulting in potent dephosphorylation of p107, but only partial dephosphorylation of p130 and pRB, as CDK2 remains active for several hours. In contrast, treatment with the potent CDK inhibitor flavopiridol leads to rapid and complete dephosphorylation of pocket proteins as all CDKs become inactive (6).PP2A, a second Ser/Thr phosphatase, has been implicated in dephosphorylation of pocket proteins throughout the cell cycle by using selective pharmacolog...

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PP2A holoenzymes negatively and positively regulate cell cycle progression by dephosphorylating pocket proteins and multiple CDK substrates

Kurimchak¹,

Graña

2012

Gene

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Cell cycle progression is negatively regulated by the retinoblastoma family of pocket proteins and CDK inhibitors (CKIs). In contrast, CDKs promote progression through multiple phases of the cell cycle. One prominent way by which CDKs promote cell cycle progression is by inactivation of pocket proteins via hyperphosphorylation. Reactivation of pocket proteins to halt cell cycle progression requires dephosphorylation of multiple CDK-phosphorylated sites and is accomplished by PP2A and PP1 serine/threonine protein phosphatases. The same phosphatases are also implicated in dephosphorylation of multiple CDK substrates as cells exit mitosis and reenter the G1 phase of the cell cycle. This review is primarily focused on the role of PP2A and PP1 in the activation of pocket proteins during the cell cycle and in response to signaling cues that trigger cell cycle exit. Other functions of PP2A during the cell cycle will be discussed in brief, as comprehensive reviews on this topic have been published recently (De Wulf et al., 2009; Wurzenberger and Gerlich, 2011).

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Functional proteomics interrogation of the kinome identifies MRCKA as a therapeutic target in high-grade serous ovarian carcinoma

et al. 2020

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High-grade serous ovarian carcinoma (HGSOC) is the most lethal gynecological cancer with few effective, targeted therapies. HGSOC tumors exhibit genomic instability with frequent alterations in the protein kinome; however, only a small fraction of the kinome has been therapeutically targeted in HGSOC. Using multiplexed inhibitor beads and mass spectrometry, we mapped the kinome landscape of HGSOC tumors from patients and patient-derived xenograft models. The data revealed a prevalent signature consisting of established HGSOC driver kinases, as well as several kinases previously unexplored in HGSOC. Loss-of-function analysis of these kinases in HGSOC cells indicated MRCKA (also known as CDC42BPA) as a putative therapeutic target. Characterization of the effects of MRCKA knockdown in established HGSOC cell lines demonstrated that MRCKA was integral to signaling that regulated the cell cycle checkpoint, focal adhesion, and actin remodeling, as well as cell migration, proliferation, and survival. Moreover, inhibition of MRCKA using the small-molecule BDP9066 decreased cell proliferation and spheroid formation and induced apoptosis in HGSOC cells, suggesting that MRCKA may be a promising therapeutic target for the treatment of HGSOC.

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PP2A/B55α substrate recruitment as defined by the retinoblastoma-related protein p107

Fowle

Zhao

et al. 2021

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Protein phosphorylation is a reversible post-translation modification essential in cell signaling. This study addresses a long-standing question as to how the most abundant serine/threonine Protein Phosphatase 2 (PP2A) holoenzyme, PP2A/B55α, specifically recognizes substrates and presents them to the enzyme active site. Here, we show how the PP2A regulatory subunit B55α recruits p107, a pRB-related tumor suppressor and B55α substrate. Using molecular and cellular approaches, we identified a conserved region 1 (R1, residues 615-626) encompassing the strongest p107 binding site. This enabled us to identify an 'HxRVxxV619-625' short linear motif (SLiM) in p107 as necessary for B55α binding and dephosphorylation of the proximal pSer-615 in vitro and in cells. Numerous B55α/PP2A substrates, including TAU, contain a related SLiM C-terminal from a proximal phosphosite, 'p[ST]-P-x(4,10)-[RK]-V-x-x-[VI]-R'. Mutation of conserved SLiM residues in TAU dramatically inhibits dephosphorylation by PP2A/B55α, validating its generality. A data-guided computational model details the interaction of residues from the conserved p107 SLiM, the B55α groove, and phosphosite presentation. Altogether these data provide key insights into PP2A/B55α mechanisms of substrate recruitment and active site engagement, and also facilitate identification and validation of new substrates, a key step towards understanding PP2A/B55α role in multiple cellular processes.

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