Genetic drivers of oncogenic pathways in molecular subgroups of peripheral T-cell lymphoma

Heavican, Tayla B.; Bouska, Alyssa; Yu, Jiayu; Lone, Waseem; Amador, Catalina; Gong, Qiang; Zhang, Weiwei; Li, Yuping; Davé, Bhavana J.; Nairismägi, Maarja Liisa; Greiner, Timothy C.; Vose, Julie M.; Weisenburger, Dennis D.; Lachel, Cynthia M.; Wang, Chao; Fu, Kai; Stevens, Jadd M.; Lim, Soon Thye; Ong, Choon Kiat; Gascoyne, Randy D.; Missiaglia, Edoardo; Lemonnier, François; Haı̈oun, Corinne; Hartmann, Sven; Pedersen, Martin Bjerregård; Laginestra, Maria Antonella; Wilcox, Ryan A.; Teh, Bin Tean; Yoshida, Noriaki; Ohshima, Koichi; Seto, Masao; Rosenwald, Andreas; Ott, German; Campo, Elı́as; Rimsza, Lisa M.; Jaffe, Elaine S.; Braziel, Rita M.; d’Amore, Francesco; Inghirami, Giorgio; Bertoni, Francesco; Leval, Laurence de; Gaulard, Philippe; Staudt, Louis M.; McKeithan, Timothy W.; Pileri, Stefano; Chan, Wing C.; Iqbal, Javeed

doi:10.1182/blood-2018-09-872549

Cited by 216 publications

(285 citation statements)

References 61 publications

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“…For example, genomic losses (usually heterozygous) that include relevant tumor suppressor genes, including p53, PTEN, and CDKN2A/B, are observed in~40-50% of GATA-3 PTCL, while genomic losses generally were infrequently observed in T-bet PTCL. 50 Genomic gains involving c-myc were observed in ≈40% of GATA-3 PTCL, and are concordant with the enriched expression of c-myc target genes previously observed in this subset. 19 The loss of relevant tumor suppressor genes, including p53, and amplification of c-myc, may further contribute to the high rate of primary refractory disease observed in GATA-3 PTCL.…”

Section: Ptcl Nos: Molecular Pathogenesis and The Emergent Role Ofsupporting

confidence: 80%

“…In contrast to the mutational landscape in these epigenetic regulators, significant differences in clinically relevant chromosomal copy number alternations have been observed between GATA‐3 and T‐bet PTCL. For example, genomic losses (usually heterozygous) that include relevant tumor suppressor genes, including p53, PTEN, and CDKN2A/B, are observed in ~40–50% of GATA‐3 PTCL, while genomic losses generally were infrequently observed in T‐bet PTCL . Genomic gains involving c‐myc were observed in ≈40% of GATA‐3 PTCL, and are concordant with the enriched expression of c‐myc target genes previously observed in this subset .…”

Section: Ptcl Nos: Molecular Pathogenesis and The Emergent Role Of Gsupporting

confidence: 73%

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GATA‐3 in T‐cell lymphoproliferative disorders

Murga‐Zamalloa

Wilcox

2019

IUBMB Life

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Section: Ptcl Nos: Molecular Pathogenesis and The Emergent Role Ofsupporting

confidence: 80%

Section: Ptcl Nos: Molecular Pathogenesis and The Emergent Role Of Gsupporting

confidence: 73%

GATA‐3 in T‐cell lymphoproliferative disorders

Murga‐Zamalloa

Wilcox

2019

IUBMB Life

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“…Another mechanism of STAT3 activation is possible through the deregulation of suppressors of the JAK/STAT pathway such as SOCS3 [40] leading to constitutive STAT activation and oncogenesis. In addition, further studies are needed to combine any association with JAK-STAT pathway activation and expression of essential transcription factors such as GATA3 and Tbet, which define new subclasses of PTCL-NOS with prognostic consequences, where GATA3 signatures are associated with worse prognosis [41,42].…”

Section: Discussionmentioning

confidence: 99%

STAT3 Mutation Is Associated with STAT3 Activation in CD30+ ALK− ALCL

Andersson

Brück

Braun

et al. 2020

Cancers

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Peripheral T-cell lymphomas (PTCL) are a heterogeneous, and often aggressive group of non-Hodgkin lymphomas. Recent advances in the molecular and genetic characterization of PTCLs have helped to delineate differences and similarities between the various subtypes, and the JAK/STAT pathway has been found to play an important oncogenic role. Here, we aimed to characterize the JAK/STAT pathway in PTCL subtypes and investigate whether the activation of the pathway correlates with the frequency of STAT gene mutations. Patient samples from AITL (n = 30), ALCL (n = 21) and PTCL-NOS (n = 12) cases were sequenced for STAT3, STAT5B, JAK1, JAK3, and RHOA mutations using amplicon sequencing and stained immunohistochemically for pSTAT3, pMAPK, and pAKT. We discovered STAT3 mutations in 13% of AITL, 13% of ALK + ALCL, 38% of ALK − ALCL and 17% of PTCL-NOS cases. However, no STAT5B mutations were found and JAK mutations were only present in ALK -ALCL (15%). Concurrent mutations were found in all subgroups except ALK + ALCL where STAT3 mutations were always seen alone. High pY-STAT3 expression was observed especially in AITL and ALCL samples. When studying JAK-STAT pathway mutations, pY-STAT3 expression was highest in PTCLs harboring either JAK1 or STAT3 mutations and CD30 + phenotype representing primarily ALK − ALCLs. Further investigation is needed to elucidate the molecular mechanisms of JAK-STAT pathway activation in PTCL.Cancers 2020, 12, 702 2 of 17 diagnoses [1]. The most prevalent PTLCs are PTCL not otherwise specified (NOS), angioimmunoblastic T-cell lymphoma (AITL), anaplastic lymphoma kinase-negative (ALK − ALCL), and anaplastic lymphoma kinase-positive anaplastic large cell lymphoma (ALK + ALCL) [2,3].Despite generally favorable response rates to chemotherapy, remissions are often not durable, and as such the natural history of PTCL is characterized by relapses and refractory disease. For this reason, upfront hematopoietic stem cell transplantation (HSCT) is often recommended in first remission for patients who are fit and have chemo-sensitive disease [4]. For patients who are not suitable for transplantation, chances of long-term disease control are very limited, with an average progression-free survival (PFS) of 5.5 months [5]. In this setting, optimal therapeutic approaches remain undefined representing an unmet clinical need.Recent advances in the molecular and genetic characterization of PTCL have helped to delineate differences and similarities between the various subtypes [6]. Several recurrent mutations have been identified in small subsets of patients potentially enabling more accurate disease classification and guide treatment decisions. In AITL, the three most commonly identified genetic lesions occur in the Tet methylcytosine dioxygenase 2 gene (TET2), the Ras homolog gene family, member A (RHOA), and the isocitrate dehydrogenase 2 gene (IDH2). Besides AITL, TET2 mutations can be seen with a high frequency also in PTCL-NOS with a T follicular helper cell phenotype [7]. RHOA, a small GTPase participating i...

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“…42 Genomic imbalances are frequent as well; gains of chromosomes 5 and 21 are frequent, especially in IDH2-mutated cases, and copy number losses in genes regulating the PI3K-AKT-mTOR pathway are enriched in IDH2-wild type cases. 43 RNA fusions involving CD28 and ICOS, or rarely CD28 and CTLA4, are detected in a small subset of the patients and are mutually exclusive with CD28 mutations. 44…”

Section: Pathological Features Of Nodal-based Ptclsmentioning

confidence: 98%

Approach to nodal-based T-cell lymphomas

Leval

2020

Pathology

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Peripheral T-cell lymphomas (PTCLs) represent a heterogeneous group of uncommon malignancies derived from mature T cells and usually characterised by an aggressive clinical course. Their clinical presentation, localisation and pattern of dissemination are highly variable, but the majority of cases present as nodal diseases. The recently revised classification of lymphomas has incorporated many new molecular genetic data derived from gene expression profiling and next generation sequencing studies, which refine the definition and diagnostic criteria of several entities. Nevertheless, the distinction of PTCL from various reactive conditions, and the diagnosis of PTCL subtypes remains notably challenging. Here, an updated summary of the clinicopathological and molecular features of the most common nodal-based PTCLs (angioimmunoblastic T-cell lymphoma and other nodal lymphomas derived from follicular T helper cells, anaplastic large cell lymphomas and peripheral T-cell lymphoma, not otherwise specified) is presented. Practical recommendations in the diagnostic approach to nodal T-cell lymphoproliferations are presented, including indications for the appropriate use and interpretation of ancillary studies. Finally, we discuss commonly encountered diagnostic problems, including pitfalls and mimics in the differential diagnosis with various reactive conditions, and the criteria that allow proper identification of distinct PTCL entities.

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Genetic drivers of oncogenic pathways in molecular subgroups of peripheral T-cell lymphoma

Cited by 216 publications

References 61 publications

GATA‐3 in T‐cell lymphoproliferative disorders

GATA‐3 in T‐cell lymphoproliferative disorders

STAT3 Mutation Is Associated with STAT3 Activation in CD30+ ALK− ALCL

Approach to nodal-based T-cell lymphomas

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