Dual Targeting of Oncogenic Activation and Inflammatory Signaling Increases Therapeutic Efficacy in Myeloproliferative Neoplasms

Kleppe, Maria; Koche, Richard P.; Zou, Lihua; Galen, Peter van; Hill, Corinne E.; Dong, Lauren; Groote, Sofie De; Papalexi, Efthymia; Somasundara, Amritha Varshini Hanasoge; Cordner, Keith B.; Keller, Matthew D.; Farnoud, Noushin; Medina, Juan; McGovern, Erin; Reyes, Jaime M.; Roberts, Justin M.; Witkin, Matthew D.; Rapaport, Franck; Teruya‐Feldstein, Julie; Qi, Jun; Rampal, Raajit K.; Bernstein, B; Bradner, James E.; Levine, Ross L.

doi:10.1016/j.ccell.2017.11.009

Cited by 213 publications

(164 citation statements)

References 69 publications

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“…Corroborating with these findings are the promising early clinical activity of SMAC mimetic LCL-161 in MF (Pemmaraju et al, 2018) and pre-clinical data demonstrating TNF-induced apoptotic activity of birinapant (a bivalent IAP inhibitor) in MF cell lines at concentrations that selectively block cIAP, but not XIAP (Heaton et al, 2018). Elevated cIAP and downregulation of the pro-apoptotic MAPK8 through the aberrantly activated TNF-TNFR2 autocrine loop promotes NF-kB activation, which favours survival and promotes further inflammatory cytokine production (Hoesel & Schmid, 2013;Kleppe et al, 2018). The exact mechanism underlying the aberrant modulation of TNF-TNFR2 signalling in JAK2 V617F is an area of active investigation.…”

Section: Role Of Iaps and Tumour Necrosis Factor (Tnfa) In Myelofibrosismentioning

confidence: 82%

SMAC mimetics as potential cancer therapeutics in myeloid malignancies

et al. 2019

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Summary Evasion of apoptosis has been identified as one of the essential hallmarks of cancer. Inhibitor of apoptosis proteins (IAPs) are implicated in a host of myeloid malignancies, providing the rationale for strategies aimed at neutralizing IAPs to lower the cancer cell apoptosis threshold. Modes of IAP antagonism may include down‐regulating IAP expression, up‐regulating endogenous pro‐apoptotic proteins, such as tumour necrosis factor‐α or Fas ligand, or directly antagonizing IAP activity against caspases. Direct targeting of IAPs using mimetics of the second mitochondria‐derived activator of caspase (SMAC) protein has shown therapeutic promise by sensitizing the effect of chemotherapy on malignant cells. In pre‐clinical studies, SMAC mimetics have demonstrated broad synergistic activity with a wide range of therapeutics, including cytotoxic chemotherapy, receptor tyrosine kinase inhibitors, agents targeting death receptors and alternative mechanisms of cell death, such as necroptosis or autophagy and immune check point blockade. SMAC mimetics represent a novel approach for further investigation in patients with high‐risk, chemo‐refractory blood cancers, as single agents or in thoughtfully selected combinations. In this review, we discuss the development and therapeutic rationale of small molecule SMAC mimetics, with an emphasis on agents in clinical development for myeloid malignancies.

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Section: Role Of Iaps and Tumour Necrosis Factor (Tnfa) In Myelofibrosismentioning

confidence: 82%

SMAC mimetics as potential cancer therapeutics in myeloid malignancies

et al. 2019

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“…Inflammation plays a role in all MPN subgroups, most pronounced in MF patients. It has been shown that inhibiting specific cytokines like IL-1β or the NfkB pathway can either decrease hematopoietic cell growth ex vivo ( 61 ) or even diminish fibrosis in vivo ( 62 ). Targeting soluble mediators in MF patients serves predominantly to ameliorate constitutional symptoms and reduce frequent comorbidities like MF -associated anemia.…”

Section: Therapeutic Targeting Of Soluble Mediators the Malignant Bomentioning

confidence: 99%

“…The NfκB pathway has been shown to be activated in JAK2 mutated MPN. Recently, a potential combinatorial therapeutic approach for MPN patients has been proposed, by targeting inflammation through reduction of NfκB activity using BET inhibition in combination with JAK inhibition ( 62 ). Using MPN mouse models, Kleppe et al showed that increased NfκB activity in MPN is partly cell-extrinsic, highlighting the importance of targeting the BM microenvironment.…”

Section: Therapeutic Targeting Of Soluble Mediators the Malignant Bomentioning

confidence: 99%

“…Using MPN mouse models, Kleppe et al showed that increased NfκB activity in MPN is partly cell-extrinsic, highlighting the importance of targeting the BM microenvironment. The BET inhibitor, JQ1 showed potent anti-fibrotic effects and cooperated with Jak inhibition to ameliorate inflammation ( 62 ). Moreover, the NFKB pathway has also been shown to be upregulated in CALR mutated MPN HSPCs ( 24 ), suggesting that BET inhibition might also be effective in CALR -mutant MPN patients.…”

Section: Therapeutic Targeting Of Soluble Mediators the Malignant Bomentioning

confidence: 99%

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Remodeling the Bone Marrow Microenvironment – A Proposal for Targeting Pro-inflammatory Contributors in MPN

Jutzi

Mullally

2020

Front. Immunol.

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Philadelphia-negative myeloproliferative neoplasms (MPN) are malignant bone marrow (BM) disorders, typically arising from a single somatically mutated hematopoietic stem cell. The most commonly mutated genes, JAK2 , CALR , and MPL lead to constitutively active JAK-STAT signaling. Common clinical features include myeloproliferation, splenomegaly and constitutional symptoms. This review covers the contributions of cellular components of MPN pathology (e.g., monocytes, megakaryocytes, and mesenchymal stromal cells) as well as cytokines and soluble mediators to the development of myelofibrosis (MF) and highlights recent therapeutic advances. These findings outline the importance of malignant and non-malignant BM constituents to the pathogenesis and treatment of MF.

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“…All MPNs are characterized by chronic inflammatory state (reviewed in [7][8][9]). Thus, oncogenic and inflammatory signaling, both known to fuel genotoxic stress and tumorigenesis in the hematopoietic system in a cell-autonomous and non-cell-autonomous manner, converge in disease evolution of MPNs [10][11][12][13][14]. Therefore, CML and PV provide an excellent model of inflammation-associated neoplasia for investigating mechanisms of DNA damage accumulation and DNA damage response (DDR) activation throughout early pre-cancerous ontogeny.…”

Section: Introductionmentioning

confidence: 99%

Role of DNA Damage Response in Suppressing Malignant Progression of Chronic Myeloid Leukemia and Polycythemia Vera: Impact of Different Oncogenes

Stetka

Gurský

Velasquez

et al. 2020

Cancers

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Inflammatory and oncogenic signaling, both known to challenge genome stability, are key drivers of BCR-ABL-positive chronic myeloid leukemia (CML) and JAK2 V617F-positive chronic myeloproliferative neoplasms (MPNs). Despite similarities in chronic inflammation and oncogene signaling, major differences in disease course exist. Although BCR-ABL has robust transformation potential, JAK2 V617F-positive polycythemia vera (PV) is characterized by a long and stable latent phase. These differences reflect increased genomic instability of BCR-ABL-positive CML, compared to genome-stable PV with rare cytogenetic abnormalities. Recent studies have implicated BCR-ABL in the development of a "mutator" phenotype fueled by high oxidative damage, deficiencies of DNA repair, and defective ATR-Chk1-dependent genome surveillance, providing a fertile ground for variants compromising the ATM-Chk2-p53 axis protecting chronic phase CML from blast crisis. Conversely, PV cells possess multiple JAK2 V617F-dependent protective mechanisms, which ameliorate replication stress, inflammation-mediated oxidative stress and stress-activated protein kinase signaling, all through up-regulation of RECQL5 helicase, reactive oxygen species buffering system, and DUSP1 actions. These attenuators of genome instability then protect myeloproliferative progenitors from DNA damage and create a barrier preventing cellular stress-associated myelofibrosis. Therefore, a better understanding of BCR-ABL and JAK2 V617F roles in the DNA damage response and disease pathophysiology can help to identify potential dependencies exploitable for therapeutic interventions.CML is characterized by an indolent, chronic phase (CP) preceding an acute transformation to BC. Failure of DNA damage repair and loss or malfunction of DDR components accompanied by accumulation of DNA damage and genomic instability has been considered in CML evolution [38,39]. It was proposed that BCR-ABL-expressing cells feature reduced activation of the ATR-Chk1-mediated DDR signaling, with ensuing accumulation of substantial genomic instability due to replication stress and oxidative damage. Mechanistically, such disruption of ATR-dependent signaling was attributed to nuclear import of BCR-ABL after DNA damage and its binding to ATR [40]. However, contrasting data were also reported, showing that BCR-ABL does activate ATR-Chk1 signaling, reflecting responsiveness of BCR-ABL-positive myeloid cells to DNA damage following genotoxic treatment [41]. Some studies also addressed functionality of the ATM-Chk2 signaling axis in CML. Thus, c-Abl is a nuclear tyrosine kinase activated by DNA damage in an ATM-dependent manner [42,43]. Even though the BCR-ABL is predominantly localized to the cytoplasm [44], the aforementioned ability of BCR-ABL translocation to the nucleus after DNA damage led to a proposal that BCR-ABL and c-Abl share multiple protein interactions including that with ATM [40]. As a consequence, ATM-mediated activatory phosphorylation of Chk2 was detected in BCR-ABL-expressing cellular models and...

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Dual Targeting of Oncogenic Activation and Inflammatory Signaling Increases Therapeutic Efficacy in Myeloproliferative Neoplasms

Cited by 213 publications

References 69 publications

SMAC mimetics as potential cancer therapeutics in myeloid malignancies

SMAC mimetics as potential cancer therapeutics in myeloid malignancies

Remodeling the Bone Marrow Microenvironment – A Proposal for Targeting Pro-inflammatory Contributors in MPN

Role of DNA Damage Response in Suppressing Malignant Progression of Chronic Myeloid Leukemia and Polycythemia Vera: Impact of Different Oncogenes

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