Cascade testing for hereditary cancer in Singapore: how population genomics help guide clinical policy

Hereditary Cancer makes up around 5-10% of all cancers. It is important to diagnose hereditary cancer in a timely fashion, as not only do patients require long-term care from a young age, but their relatives also require management. The main approach to capture at-risk relatives is cascade testing. It involves genetic testing of relatives of the first detected carrier of a pathogenic variant in a family i.e. the proband. The current standard of care for cascade testing is a patient-mediated approach. Probands are then advised to inform and encourage family members to undergo genetic testing. In Singapore, cascade testing is inefficient, around 10-15%, lower than the 30% global average. Here, we describe the cascade testing process and its effort to increase testing in Singapore. Precision Health Research, Singapore (PRECISE), was set up to coordinate Singapore's National Precision Medicine strategy and has awarded five clinical implementation pilots, with one of them seeking to identify strategies for how cascade testing for hereditary cancer can be increased in a safe and cost-efficient manner. Achieving this will be done through addressing barriers such as cost, manpower shortages, exploring a digital channel for contacting at-risk relatives, and getting a deeper insight into why genetic testing gets declined. If successful, it will likely result in care pathways that are a cost-effective public health intervention for identifying individuals at risk. Surveillance and management of those unaffected at-risk individuals, if caught early, will result in improved patient outcomes, and further reduce the healthcare burden for the economy.

Functional Characterisation of the ATOH1 Molecular Subtype Indicates a Pro-Metastatic Role in Small Cell Lung Cancer

Molecular subtypes of Small Cell Lung Cancer (SCLC) have been described based on differential expression of transcription factors (TFs) ASCL1, NEUROD1, POU2F3 and immune-related genes. We previously reported an additional subtype based on expression of the neurogenic TF ATOH1 within our SCLC Circulating tumour cell-Derived eXplant (CDX) model biobank. Here we show that ATOH1 protein was detected in 7/81 preclinical models and 16/102 clinical samples of SCLC. In CDX models, ATOH1 directly regulated neurogenesis and differentiation programs consistent with roles in normal tissues. In ex vivo cultures of ATOH1-positive CDX, ATOH1 was required for cell survival. In vivo, ATOH1 depletion slowed tumour growth and suppressed liver metastasis. Our data validate ATOH1 as a bona fide oncogenic driver of SCLC with tumour cell survival and pro-metastatic functions. Further investigation to explore ATOH1 driven vulnerabilities for targeted treatment with predictive biomarkers is warranted.

Combination Therapy With MDM2 and MEK Inhibitors Is Effective in Patient-Derived Models of Lung Adenocarcinoma With Concurrent Oncogenic Drivers and MDM2 Amplification

INTRODUCTION

Although targeted therapies have revolutionized the therapeutic landscape of lung adenocarcinomas (LUADs), disease progression on single-agent targeted therapy against known oncogenic drivers is common, and therapeutic options after disease progression are limited. In patients with MDM2 amplification (MDM2amp) and a concurrent oncogenic driver alteration, we hypothesized that targeting of the tumor-suppressor pathway (by means of restoration of p53 using MDM2 inhibition) and simultaneous targeting of co-occurring MAPK oncogenic pathway might represent a more durably effective therapeutic strategy.

METHODS

We evaluated genomic next-generation sequencing data using the Memorial Sloan Kettering Cancer Center-Integrated Mutation Profiling of Actionable Cancer Targets platform to nominate potential targets for combination therapy in LUAD. We investigated the small molecule MDM2 inhibitor milademetan in cell lines and patient-derived xenografts of LUAD with a known driver alteration and MDM2amp.

RESULTS

Of 10,587 patient samples from 7121 patients with LUAD profiled by next-generation sequencing, 6% (410 of 7121) harbored MDM2amp. MDM2amp was significantly enriched among tumors with driver alterations in METex14 (36%, p < 0.001), EGFR (8%, p < 0.001), RET (12%, p < 0.01), and ALK (10%, p < 0.01). The combination of milademetan and the MEK inhibitor trametinib was synergistic in growth inhibition of ECLC5-GLx (TRIM33-RET/MDM2amp), LUAD12c (METex14/KRASG12S/MDM2amp), SW1573 (KRASG12C, TP53 wild type), and A549 (KRASG12S) cells and in increasing expression of proapoptotic proteins PUMA and BIM. Treatment of ECLC5-GLx and LUAD12c with single-agent milademetan increased ERK phosphorylation, consistent with previous data on ERK activation with MDM2 inhibition. This ERK activation was effectively suppressed by concomitant administration of trametinib. In contrast, ERK phosphorylation induced by milademetan was not suppressed by concurrent RET inhibition using selpercatinib (in ECLC5-GLx) or MET inhibition using capmatinib (in LUAD12c). In vivo, combination milademetan and trametinib was more effective than either agent alone in ECLC5-GLx, LX-285 (EGFRex19del/MDM2amp), L13BS1 (METex14/MDM2amp), and A549 (KRASG12S, TP53 wild type).

CONCLUSIONS

Combined MDM2/MEK inhibition was found to have efficacy across multiple patient-derived LUAD models harboring MDM2amp and concurrent oncogenic drivers. This combination, potentially applicable to LUADs with a wide variety of oncogenic driver mutations and kinase fusions activating the MAPK pathway, has evident clinical implications and will be investigated as part of a planned phase 1/2 clinical trial.

Cytokine receptor IL27RA is an NF-κB-responsive gene involved in CD38 upregulation in multiple myeloma

Multiple myeloma (MM) shows constitutive activation of canonical and noncanonical nuclear factor κB (NF-κB) signaling via genetic mutations or tumor microenvironment (TME) stimulations. A subset of MM cell lines showed dependency for cell growth and survival on the canonical NF-κB transcription factor RELA alone, suggesting a critical role for a RELA-mediated biological program in MM pathogenesis. Here, we determined the RELA-dependent transcriptional program in MM cell lines and found the expression of the cell surface molecules interleukin-27 receptor-α (IL-27Rα) and the adhesion molecule JAM2 to be responsive to RELA at the messenger RNA and protein levels. IL-27Rα and JAM2 were expressed on primary MM cells at higher levels than on healthy long-lived plasma cells (PCs) in the bone marrow. IL-27 activated STAT1, and to a lesser extent STAT3, in MM cell lines and in PCs generated from memory B cells in an IL-21-dependent in vitro PC differentiation assay. Concomitant activity of IL-21 and IL-27 enhanced differentiation into PCs and increased the cell-surface expression of the known STAT target gene CD38. In accordance, a subset of MM cell lines and primary MM cells cultured with IL-27 upregulated CD38 cell-surface expression, a finding with potential implications for enhancing the efficacy of CD38-directed monoclonal antibody therapies by increasing CD38 expression on tumor cells. The elevated expression of IL-27Rα and JAM2 on MM cells compared with that on healthy PCs may be exploited for the development of targeted therapeutic strategies that modulate the interaction of MM cells with the TME.

Abstract 6127: MDM2 inhibition in combination with MEK inhibition in pre-clinical models of lung adenocarcinomas with MDM2 amplification

The eventual development of resistance to single-agent targeted therapies in lung adenocarcinomas (LUAD) is inevitable, and new strategies are needed. We hypothesize that combination therapies aimed at a known driver and a distinct targetable alteration could prolong time on oral targeted therapy. In an analysis of 7636 patients with LUAD who underwent MSK-IMPACT large panel NGS testing, 5.5% (416/7636) harbored MDM2 amplification (MDM2amp), a known mechanism of TP53 inactivation. MDM2amp was over-represented among tumors with alterations in METex14 (34.4%, p&lt;0.001), EGFR (10%, p&lt;0.001), RET (11%, p&lt;0.05), and ALK (9.9%, p&lt;0.002). The small molecule MDM2 inhibitor milademetan (mila) caused growth inhibition as a single-agent in MDM2amp patient-derived cell lines with concurrent kinase alterations including ECLC5-GLx (MDM2amp/TRIM33::RET/TP53 wildtype (WT)) and LUAD12c (MDM2amp/METex14/KRASG12S/TP53 WT). Mila also caused growth inhibition in a cell line with KRASG12C and WT TP53 without MDM2amp (SW1573 (KRASG12C/TP53WT)), but not in cell lines with TP53 mutations (LUAD-002AS1 (KIF5B::RET/TP53P128fs, H1792 (KRASG12C/TP53 splice site mut)). Treatment of ECLC5-GLx and LUAD12c with mila resulted in restoration of ERK phosphorylation, confirming a previous report of ERK activation upon MDM2 inhibition. At 48 hours, ERK phosphorylation was suppressed by concurrent mila and MEK inhibition using trametinib (tram). In contrast, ERK phosphorylation was not suppressed by concurrent mila and KIF5B::RET inhibition using selpercatinib (in ECLC5-GLx) or MET inhibition using capmatinib (in LUAD12c). The combination of mila+tram was synergistic in slowing growth of ECLC5-GLx, LUAD12c, and SW1573 cells, and increased expression of pro-apoptotic proteins PUMA and BIM, beyond that achieved by either agent alone. In ECLC5-GLx, mila+tram also caused increased apoptotic cells measured by Annexin-V compared to either agent alone (combination p&lt;0.01 compared to mila, p&lt;0.001 compared to tram). In vivo, combination mila+tram was more effective than mila or tram alone in ECLC5-GLx (p&lt;0.0001 and p&lt;0.0001, respectively), LX-285 (EGFRex19del/MDM2amp) (p&lt;0.0001 and p&lt;0.0001, respectively), and L-13BS1 (model resistant to capmatinib) (METex14/MDM2amp) (p&lt;0.05 and p&lt;0.0001, respectively). These results suggest that combined MDM2/MEK inhibition is effective in patient-derived LUAD models harboring MDM2amp. This combination, potentially applicable to LUADs with a wide variety of oncogenic driver mutations and kinase fusions will be investigated as part of a phase 1/2 clinical trial.

Citation Format: Arielle Elkrief, Vladimir Markov, Álvaro Quintanal-Villalonga, Rebecca Caeser, Pawel Sobczuk, Emily Cheng, Alexander Drilon, Gregory J. Riely, William W. Lockwood, Elisa de Stanchina, Charles M. Rudin, Igor Odintsov, Romel Somwar. MDM2 inhibition in combination with MEK inhibition in pre-clinical models of lung adenocarcinomas with MDM2 amplification [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 6127.

cfDNA methylome profiling for detection and subtyping of small cell lung cancers

Small cell lung cancer (SCLC) is characterized by morphologic, epigenetic and transcriptomic heterogeneity. Subtypes based upon predominant transcription factor expression have been defined that, in mouse models and cell lines, exhibit potential differential therapeutic vulnerabilities, with epigenetically distinct SCLC subtypes also described. The clinical relevance of these subtypes is unclear, due in part to challenges in obtaining tumor biopsies for reliable profiling. Here we describe a robust workflow for genome-wide DNA methylation profiling applied to both patient-derived models and to patients' circulating cell-free DNA (cfDNA). Tumor-specific methylation patterns were readily detected in cfDNA samples from patients with SCLC and were correlated with survival outcomes. cfDNA methylation also discriminated between the transcription factor SCLC subtypes, a precedent for a liquid biopsy cfDNA-methylation approach to molecularly subtype SCLC. Our data reveal the potential clinical utility of cfDNA methylation profiling as a universally applicable liquid biopsy approach for the sensitive detection, monitoring and molecular subtyping of patients with SCLC.

Abstract 6238: Profiling of the circulating cell-free DNA methylome for detection and subtyping of small cell lung cancers

Introduction: Small-cell lung cancer (SCLC) is a high-grade neuroendocrine carcinoma characterised by high proliferation rate and early, rapid metastatic spread. Although SCLC is treated as a homogenous disease, recent studies revealed morphologic and transcriptomic heterogeneity with several molecular subtypes described based on predominant transcription factor expression (ASCL1, NEUROD1, ATOH1, POU2F3, YAP1) (Rudin et al., 2019; Simpson et al., 2020) which in preclinical studies exhibit differing vulnerabilities raising the potential of stratified therapy. DNA methylation is also thought be an important regulator of SCLC biology (Gazdar et al., 2017) and epigenetically distinct subtypes derived from SCLC primary tumour samples reported (Poirier et al., 2015). Here, we developed a robust workflow for genome-wide DNA methylation profiling to examine the potential use of cfDNA methylation profiling for detection and subtyping of SCLC.

Results: To evaluate SCLC genome-wide DNA methylation patterns we employed a bisulfite-free enrichment-based approach (T7-MBD-seq). We tested this approach on tissue samples from preclinical models and from normal lung (n=110) and on cfDNA samples from both patients with SCLC and from non-cancer controls (n=157). Methylation profiles from preclinical models (patient-derived xenografts (PDX) and CTC derived explant (CDX) models) were comparable to previously described methylation patterns from SCLC primary tumours and were recapitulated in patients’ cfDNA samples. A tumour/normal classifier, based on 4,061 genomic regions detected as being hypermethylated in SCLC preclinical models, correctly assigned 93% and 100% cfDNA samples from patients with limited and extensive stage SCLC respectively, with a statistically significant correlation of prediction scores with disease stage (P=0.0076). Finally, to determine whether cfDNA methylation profiling could subtype SCLC patients, we built a subtype classifier, based on methylation signatures derived from 59 established SCLC cell lines. We applied the classifier to cfDNA samples from 56 patients and 10/11 with known subtypes (identified from a donor matched CDX model) were correctly classified. Overall, 73% of cfDNA samples were classified as ASCL1, 13% were classified as NEUROD1 and 14% were classified as being double negative with the distribution of the subtypes correlating closely to previously published IHC data from SCLC tissue samples (Baine et al., 2020).

Conclusions: Our data reveal two potential clinical utilities of cfDNA methylation profiling; a universally applicable liquid biopsy approach for more sensitive detection and monitoring of SCLC and molecular subtyping to ease the path to future clinical trials of subtype stratified treatments for patients with SCLC.

Citation Format: Dominic G. Rothwell, Francesca Chemi, Simon Pearce, Alex Clipson, Steven Hill, Alicia Marie Conway, Sophie Richardson, Katarzyna Murat, Rebecca Caeser, Jacklynn Egger, John T. Poirier, Alastair Kerr, Fiona Blackhall, Charles M. Rudin, Caroline Dive. Profiling of the circulating cell-free DNA methylome for detection and subtyping of small cell lung cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 6238.

WEE1 inhibition enhances the antitumor immune response to PD-L1 blockade by the concomitant activation of STING and STAT1 pathways in SCLC

Small cell lung cancers (SCLCs) have high mutational burden but are relatively unresponsive to immune checkpoint blockade (ICB). Using SCLC models, we demonstrate that inhibition of WEE1, a G2/M checkpoint regulator induced by DNA damage, activates the STING-TBK1-IRF3 pathway, which increases type I interferons (IFN-α and IFN-β) and pro-inflammatory chemokines (CXCL10 and CCL5), facilitating an immune response via CD8⁺ cytotoxic T cell infiltration. We further show that WEE1 inhibition concomitantly activates the STAT1 pathway, increasing IFN-γ and PD-L1 expression. Consistent with these findings, combined WEE1 inhibition (AZD1775) and PD-L1 blockade causes remarkable tumor regression, activation of type I and II interferon pathways, and infiltration of cytotoxic T cells in multiple immunocompetent SCLC genetically engineered mouse models, including an aggressive model with stabilized MYC. Our study demonstrates cell-autonomous and immune-stimulating activity of WEE1 inhibition in SCLC models. Combined inhibition of WEE1 plus PD-L1 blockade represents a promising immunotherapeutic approach in SCLC.

Genomic and transcriptomic analysis of a library of small cell lung cancer patient-derived xenografts

Access to clinically relevant small cell lung cancer (SCLC) tissue is limited because surgical resection is rare in metastatic SCLC. Patient-derived xenografts (PDX) and circulating tumor cell-derived xenografts (CDX) have emerged as valuable tools to characterize SCLC. Here, we present a resource of 46 extensively annotated PDX/CDX models derived from 33 patients with SCLC. We perform multi-omic analyses, using targeted tumor next-generation sequencing, RNA-sequencing, and immunohistochemistry to deconvolute the mutational landscapes, global expression profiles, and molecular subtypes of these SCLC models. SCLC subtypes characterized by transcriptional regulators, ASCL1, NEUROD1 and POU2F3 are confirmed in this cohort. A subset of SCLC clinical specimens, including matched PDX/CDX and clinical specimen pairs, confirm that the primary features and genomic and proteomic landscapes of the tumors of origin are preserved in the derivative PDX models. This resource provides a powerful system to study SCLC biology.

Rlf-Mycl Gene Fusion Drives Tumorigenesis and Metastasis in a Mouse Model of Small Cell Lung Cancer

Small cell lung cancer (SCLC) has limited therapeutic options and an exceptionally poor prognosis. Understanding the oncogenic drivers of SCLC may help define novel therapeutic targets. Recurrent genomic rearrangements have been identified in SCLC, most notably an in-frame gene fusion between RLF and MYCL found in up to 7% of the predominant ASCL1-expressing subtype. To explore the role of this fusion in oncogenesis and tumor progression, we used CRISPR/Cas9 somatic editing to generate a Rlf-Mycl-driven mouse model of SCLC. RLF-MYCL fusion accelerated transformation and proliferation of murine SCLC and increased metastatic dissemination and the diversity of metastatic sites. Tumors from the RLF-MYCL genetically engineered mouse model displayed gene expression similarities with human RLF-MYCL SCLC. Together, our studies support RLF-MYCL as the first demonstrated fusion oncogenic driver in SCLC and provide a new preclinical mouse model for the study of this subtype of SCLC.

SIGNIFICANCE

The biological and therapeutic implications of gene fusions in SCLC, an aggressive metastatic lung cancer, are unknown. Our study investigates the functional significance of the in-frame RLF-MYCL gene fusion by developing a Rlf-Mycl-driven genetically engineered mouse model and defining the impact on tumor growth and metastasis. This article is highlighted in the In This Issue feature, p. 2945.

MAPK pathway activation selectively inhibits ASCL1-driven small cell lung cancer

Activation of mitogenic signaling pathways is a common oncogenic driver of many solid tumors including lung cancer. Although activating mutations in the mitogen-activated protein kinase (MAPK) pathway are prevalent in non-small cell lung cancers, MAPK pathway activity, counterintuitively, is relatively suppressed in the more aggressively proliferative small cell lung cancer (SCLC). Here, we elucidate the role of the MAPK pathway and how it interacts with other signaling pathways in SCLC. We find that the most common SCLC subtype, SCLC-A associated with high expression of ASCL1, is selectively sensitive to MAPK activation in vitro and in vivo through induction of cell-cycle arrest and senescence. We show strong upregulation of ERK negative feedback regulators and STAT signaling upon MAPK activation in SCLC-A lines. These findings provide insight into the complexity of signaling networks in SCLC and suggest subtype-specific mitogenic vulnerabilities.

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MAPK activation causes cell-cycle arrest and senescence selectively in SCLC-A subtype

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MAPK-induced growth inhibition is independent of NOTCH signaling

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MAPK activation increases ERK negative feedback and activates STAT3 signaling

Abstract LB186: MAPK pathway activation represents a therapeutic vulnerability in ASCL1-driven SCLC

Background Lung cancer is the leading cause of cancer death, killing more people than colon, breast, and prostate cancers combined (Siegel et al. 2013). Small cell lung cancer (SCLC) is a high grade neuroendocrine tumor accounting for ~15% of all lung cancers (Hann et al. 2019). Metastasis is often found at first diagnosis, making SCLC exceptionally lethal (2-year survival &lt5%) (Byers et al. 2015). Whilst MAPK mutations can be found in roughly 30% of human cancers (Schubbert et al. 2007) including non-small cell lung cancer (NSCLC), genomic and proteomic analyses have indicated suppression of MAPK pathway activity in SCLC (Cerami et al. 2012; Gao et al. 2013; Wagle et al. 2018). This striking difference is not well understood and previous attempts to determine whether this might be therapeutically important (Ravi et al, 1998; Cristea et al. 2020) have had conflicting conclusions. SCLC has recently been defined by the relative expression of four major transcriptional regulators (ASCL1, NeuroD1, POU2F3, YAP1) (Rudin et al., 2019). In this study we aimed to elucidate the effect of MAPK activation in these different SCLC subtypes and explore its therapeutic vulnerability.

Results We used a doxycycline-inducible vector for expression of MEKDDS217D/S221D (MEK1) in a cohort of ASCL1-, NEUROD1, and POU2F3- driven cell lines. Activation through MEK1 in ASCL1-driven SCLC cell lines resulted in a significant decrease in cell growth over 9 days. This was associated with a decrease in neuroendocrine markers ASCL1 and INSM1, a G2 cell cycle arrest and no significant increase in apoptotic cells. Expression of MEK1 in other SCLC subtypes and NSCLC failed to show any appreciable changes in cell growth. Remarkably, athymic mice injected with a MEK1 expressing ASCL1-driven cell line showed significantly slower tumor formation and longer survival than the ASCL1-driven cell line not expressing MEK1. Previous work established that hyperactivation of BRAFV600E, RAS and MYC can result in oncogene-induced senescence (Serrano et al. 1997) which is caused by upregulation of negative feedback such as SPRY2, DUSP6, ETV5 rather than MAPK pathway activation in some solid tumors and pre-B ALL (Courtois-Cox et al 2006; Shojaee et al. 2015). Similarly, we also observed strong upregulation of DUSP6, SPRY2, but not ETV5 upon MAPK activation. This was especially prominent in ASCL1-driven cell lines that changed from the normal phenotype of being in suspension to a more adherent morphology as a result of MAPK activation. Interestingly, phosphokinase array in the major subtype cell lines after MEK1 activation, demonstrated that, almost exclusively, the STAT pathways, in particular STAT3 through phosphorylation at S727 was strongly upregulated in the ASCL1-driven subtype. This prompted us to examine whether these cells were sensitive to STAT3 inhibition. Upon treatment with a STAT3 inhibitor, Stattic (1μM), ASCL1-driven SCLC cells reached their IC50 after 3-5 days in comparison to 9 days for other SCLC subtypes. NSCLC cells were resistant to STAT3 inhibition.

Summary These findings suggest that ASCL1-driven SCLC in vitro and in vivo is sensitive to activation of MAPK signaling in comparison to other SCLC subtypes. Whilst activation of the MAPK pathway might seem counterintuitive to current treatment strategies that aim to inhibit oncogenic signaling, we propose the use of a STAT3 inhibitor that has shown to be effective in vitro.

Citation Format: Rebecca Caeser, Christopher Hulton, Vidushi Durani, Emily Costa, Megan Little, Nisargbhai S. Shah, Elisa de Stanchina, John T. Poirier, Charles M. Rudin, Triparna Sen. MAPK pathway activation represents a therapeutic vulnerability in ASCL1-driven SCLC [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr LB186.

Genetic manipulation and immortalized culture of ex vivo primary human germinal center B cells

Next-generation sequencing has transformed our knowledge of the genetics of lymphoid malignancies. However, limited experimental systems are available to model the functional effects of these genetic changes and their implications for therapy. The majority of mature B-cell malignancies arise from the germinal center (GC) stage of B-cell differentiation. Here we describe a detailed protocol for the purification and ex vivo expansion of primary, nonmalignant human GC B cells. We present methodology for the high-efficiency transduction of these cells to enable combinatorial expression of putative oncogenes. We also describe alternative approaches for CRISPR-Cas9-mediated deletion of putative tumor suppressors. Mimicking genetic changes commonly found in lymphoid malignancies leads to immortalized growth in vitro, while engraftment into immunodeficient mice generates genetically customized, synthetic models of human lymphoma. The protocol is simple and inexpensive and can be implemented in any laboratory with access to standard cell culture and animal facilities. It can be easily scaled up to enable high-throughput screening and thus provides a versatile platform for the functional interrogation of lymphoma genomic data.

Should WEE(1) CHK(1) in on the FAM(122A)ily?

Li et al. (2020) elucidate the resistance mechanisms to small-molecule inhibitors targeting the G2/M cell cycle checkpoint kinase, CHK1, in a variety of non-small cell lung cancer cell lines using CRISPR-mediated genetic approaches and identify biomarkers of response.

Genetic modification of primary human B cells to model high-grade lymphoma

Sequencing studies of diffuse large B cell lymphoma (DLBCL) have identified hundreds of recurrently altered genes. However, it remains largely unknown whether and how these mutations may contribute to lymphomagenesis, either individually or in combination. Existing strategies to address this problem predominantly utilize cell lines, which are limited by their initial characteristics and subsequent adaptions to prolonged in vitro culture. Here, we describe a co-culture system that enables the ex vivo expansion and viral transduction of primary human germinal center B cells. Incorporation of CRISPR/Cas9 technology enables high-throughput functional interrogation of genes recurrently mutated in DLBCL. Using a backbone of BCL2 with either BCL6 or MYC, we identify co-operating genetic alterations that promote growth or even full transformation into synthetically engineered DLBCL models. The resulting tumors can be expanded and sequentially transplanted in vivo, providing a scalable platform to test putative cancer genes and to create mutation-directed, bespoke lymphoma models.

Abstract 5469: RAS and STAT5 pathway lesions are mutually exclusive in B-cell malignancies through mechanisms of biochemical cross-inhibition

Activation of STAT5- and RAS-signaling are segregated to early and later stages of normal B cell development, respectively. Studying B-lineage acute lymphoblastic leukemia (ALL; n=578), we found that STAT5 (e.g. BCR-ABL1, JAK2, cytokine receptors) and RAS (NRAS, KRAS, PTPN11, NF1) lesions were mutually exclusive, with only 9 cases (1.6%) carrying lesions in both pathways. Reverse phase protein array measurements revealed that phosphorylation of MEK and ERK1/2 were inversely correlated with STAT5-phosphorylation (MDACC, 1983-2007; P&lt;0.001). These findings prompted us to study mechanisms of cross-inhibition between RAS and STAT5 pathways. Inducible NRASG12D activated ERK at the expense of STAT5 phosphorylation. This was due to stabilization and increased activation of the STAT5-phosphatase PTPN6 (SHP1). Inducible ablation of Ptpn6 elevated phospho-STAT5 levels, while genetic inactivation of Stat5 strongly increased ERK activity. Constitutively active STAT5 suppressed phosphorylation of ERK. Interestingly, STAT5 negatively regulated BCL6, which marks the transition from cytokine receptor-dependent pro-B cells (Stat5+) to pre-BCR dependent stages of development (ERK+). While oncogenic RAS suppressed STAT5, we also found that induction of RAS induced BCL6 expression at both the mRNA and protein levels. Increases in BCL6 expression in response to NRASG12D were abrogated upon treatment with a MEK kinase inhibitor or activation of STAT5. Studying a matched patient-derived pre-B ALL sample at diagnosis and at relapse (acquired KRASG12V mutation) revealed activation of ERK in association with increased BCL6 and decreased STAT5 levels in the KRASG12V relapsed ALL sample. With engagement of BCL6 and the STAT5-inhibitory phosphatase PTPN6 downstream of RAS and ERK signaling, these findings suggest that occupancy of either RAS or STAT5-pathway represents a commitment step that renders cells non-permissive to the respective alternative pathway. To test this hypothesis, we induced B cell transformation with either RAS or STAT5-pathway oncogenes and then subsequently transduced with either empty vectors (EV) or vectors carrying the alternative oncogene. While EVs were easily transduced, RAS- and STAT5-transformed B cells did not tolerate the alternative oncogene. Reflecting early (STAT5) and later (RAS) stages of B cell development, oncogenic activation of these pathways occurs in a mutually exclusive way, owing to biochemical cross-inhibition between STAT5 and RAS.

Citation Format: Lai N. Chan, Seyedmehdi Shojaee, Christian Hurtz, Rebecca Caeser, Gang Xiao, Huimin Geng, Steven Kornblau, Markus Muschen. RAS and STAT5 pathway lesions are mutually exclusive in B-cell malignancies through mechanisms of biochemical cross-inhibition [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 5469.

Erk Negative Feedback Control Enables Pre-B Cell Transformation and Represents a Therapeutic Target in Acute Lymphoblastic Leukemia

Studying mechanisms of malignant transformation of human pre-B cells, we found that acute activation of oncogenes induced immediate cell death in the vast majority of cells. Few surviving pre-B cell clones had acquired permissiveness to oncogenic signaling by strong activation of negative feedback regulation of Erk signaling. Studying negative feedback regulation of Erk in genetic experiments at three different levels, we found that Spry2, Dusp6, and Etv5 were essential for oncogenic transformation in mouse models for pre-B acute lymphoblastic leukemia (ALL). Interestingly, a small molecule inhibitor of DUSP6 selectively induced cell death in patient-derived pre-B ALL cells and overcame conventional mechanisms of drug-resistance.