Ali E. Yesilkanal scite author profile

• Stromal OPN anchors leukemia cells in prodormancy BM niches.• Inhibiting this interaction leads dormant cells to proliferate, sensitizing them to chemotherapy.Malignant cells may evade death from cytotoxic agents if they are in a dormant state. The host microenvironment plays important roles in cancer progression, but how niches might control cancer cell dormancy is little understood. Here we show that osteopontin (OPN), an extracellular matrix molecule secreted by osteoblasts, can function to anchor leukemic blasts in anatomic locations supporting tumor dormancy. We demonstrate that acute lymphoblastic leukemia (ALL) cells specifically adhere to OPN in vitro and secrete OPN when localized to the endosteal niche in vivo. Using intravital microscopy to perform imaging studies of the calvarial bone marrow (BM) of xenografted mice, we show that OPN is highly expressed adjacent to dormant tumor cells within the marrow. Inhibition of the OPN-signaling axis significantly increases the leukemic cell Ki-67 proliferative index and leads to a twofold increase in tumor burden in treated mice. Moreover, using cell-cycle-dependent Ara-C chemotherapy to produce minimal residual disease (MRD) in leukemic mice, we show that OPN neutralization synergizes with Ara-C to reduce detectable BM MRD. Taken together, these data suggest that ALL interacts with extracellular OPN within the malignant BM, and that this interaction induces cell cycle exit in leukemic blasts, protecting them from cytotoxic chemotherapy. (Blood. 2013;121(24):4821-4831) IntroductionAcute lymphoblastic leukemia (ALL) in adults initially responds well to induction chemotherapy, with greater than 80% of patients attaining a complete remission (CR). Unfortunately, most initial CRs are short lived, and overall survival rate is only 30% to 40% for adults who are diagnosed before age 60 years.1 Although outcomes in the pediatric population are better, a significant number of patients still experience relapsed or refractory disease.2 Relapses in both populations are believed to be the outgrowth of minimal residual disease (MRD) that is not completely eliminated by chemotherapy. Indeed, it has been demonstrated that patients with the lowest levels of detectable MRD at CR have the best prognosis and least likelihood of relapse.2 Strategies to overcome resistance and reduce MRD may therefore have the potential to increase overall survival duration.Antiapoptotic signals from the host tissue microenvironment are increasingly recognized as important mechanisms of malignant cell survival against chemotherapy. Our previous work using the Nalm-6 model of ALL has shown that the bone marrow (BM) microenvironment plays a critical role in disease spread and in the dysregulation of normal hematopoiesis that occurs during leukemic growth. 3,4 To metastasize and outcompete native BM cells, leukemic cells co-opt normal signaling mechanisms within hematopoietic stem cell (HSC) niches. At least 2 distinct HSC niches, one perivascular and one endosteal (or bony), exist in the BM. 5 In t...

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TET1-Mediated Hydroxymethylation Facilitates Hypoxic Gene Induction in Neuroblastoma

Mariani

et al. 2014

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SUMMARY The ten-eleven-translocation 5-methylcytosine dioxygenase (TET) family of enzymes catalyzes the conversion of 5-methylcytosine (5-mC) to 5-hydroxyme-thylcytosine (5-hmC), a modified cytosine base that facilitates gene expression. Cells respond to hypoxia by inducing a transcriptional program regulated in part by oxygen-dependent dioxygenases that require Fe(II) and α-ketoglutarate. Given that the TET enzymes also require these cofactors, we hypothesized that the TETs regulate the hypoxia-induced transcriptional program. Here, we demonstrate that hypoxia increases global 5-hmC levels, with accumulation of 5-hmC density at canonical hypoxia response genes. A subset of 5-hmC gains colocalize with hypoxia response elements facilitating DNA demethylation and HIF binding. Hypoxia results in transcriptional activation of TET1, and full induction of hypoxia-responsive genes and global 5-hmC increases require TET1. Finally, we show that 5-hmC increases and TET1 upregulation in hypoxia are HIF-1 dependent. These findings establish TET1-mediated 5-hmC changes as an important epigenetic component of the hypoxic response.

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Targeting Raf Kinase Inhibitory Protein Regulation and Function

Yesilkanal

Rosner

2018

Cancers

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Raf Kinase Inhibitory Protein (RKIP) is a highly conserved kinase inhibitor that functions as a metastasis suppressor in a variety of cancers. Since RKIP can reprogram tumor cells to a non-metastatic state by rewiring kinase networks, elucidating the mechanism by which RKIP acts not only reveals molecular mechanisms that regulate metastasis, but also represents an opportunity to target these signaling networks therapeutically. Although RKIP is often lost during metastatic progression, the mechanism by which this occurs in tumor cells is complex and not well understood. In this review, we summarize our current understanding of RKIP regulation in tumors and consider experimental and computational strategies for recovering or mimicking its function by targeting mediators of metastasis.

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Raf Kinase Inhibitory Protein (RKIP) as a Metastasis Suppressor: Regulation of Signaling Networks in Cancer

Yesilkanal

Rosner

2014

Crit Rev Oncog

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Cancer is one of the deadliest diseases worldwide, accounting for about 8 million deaths a year. For solid tumors, cancer patients die as a result of the metastatic spread of the tumor to the rest of the body. Therefore, there is a clinical need for understanding the molecular and cellular basis of metastasis, identifying patients whose tumors are more likely to metastasize, and developing effective therapies against metastatic progression. Over the years, Raf kinase inhibitory protein (RKIP) has emerged as a natural suppressor of the metastatic process, constituting a tool for studying metastasis and its clinical outcomes. Here, we review RKIP’s role as a metastasis suppressor and the signaling networks and genes regulated by RKIP in metastatic, triple-negative breast cancer. We also highlight the clinical implications and power of building gene signatures based on RKIP-regulated signaling modules in identifying cancer patients that are at higher risk for metastases. Finally, we highlight the potential of RKIP as a tool for developing new therapeutic strategies in cancer treatment.

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Ali E. Yesilkanal

Effective breast cancer combination therapy targeting BACH1 and mitochondrial metabolism

Adhesion to osteopontin in the bone marrow niche regulates lymphoblastic leukemia cell dormancy

TET1-Mediated Hydroxymethylation Facilitates Hypoxic Gene Induction in Neuroblastoma

Targeting Raf Kinase Inhibitory Protein Regulation and Function

Raf Kinase Inhibitory Protein (RKIP) as a Metastasis Suppressor: Regulation of Signaling Networks in Cancer

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