Biomarker or biomarker testing

EGFR-mutant lung cancers (LC) serve as the prototype oncogene-driven cancer and mechanisms of resistance to EGFR therapy are well-established. Selective pressure of EGFR inhibitors can induce lineage plasticity to escape oncogene-dependence. While we have shown EGFR/TP53/RB1-mutations are necessary but insufficient to induce small cell transformation, no other genomic signatures and transcriptomic/epigenomic effectors that induce transformation have been identified.

Using parallel exome sequencing, bulk RNA sequencing, and bisulfite sequencing, we will characterize the biomarkers of transformation in EGFR/TP53/RB1-mutant LC and mixed adenocarcinoma/squamous cell tumors. We will also utilize single-cell RNA sequencing to identify the transcriptional changes associated with transformation and to identify distinct cell types within a heterogenous tumor. We will reconstruct a phenotypic landscape to identify subclones in a transitional state between histologies. The information obtained from these studies will nominate novel biomarkers of lineage plasticity that will be validated and proposed for study in clinical trials.

The current standard of care for ALK rearranged non-small cell lung cancer (NSCLC) is targeted therapy with ALK tyrosine kinase inhibitors (TKIs) which bind within the kinase domain of ALK. Due to the development of ALK resistance mutations or bypass activation of parallel or downstream signal pathways, patients inevitably relapse. Even with the introduction of second or third generation TKIs, median overall survival has been estimated to be 6.8 years . Recent advances in immunotherapy have demonstrated progress in lung cancer treatment. However, a majority of ALK positive NSCLC patients have yet to realize the benefits from checkpoint inhibitors or CAR-T cell therapies due to primary resistance or toxicity. Therefore, the development of new treatments for ALK-rearranged NSCLC is an area of critical need. We believe that an effective assault on ALK-driven tumors requires the implementation of creative strategies that allow us to expand our arsenal of drugs to target ALK beyond its kinase domain. To meet this challenge, we have developed and employed cysteine druggability mapping (CDM), a method to define the landscape of inhibitor-protein interactions in a cancer cell. CDM identifies cysteines that can bind to covalent drug-like molecules which serve as early prototypes on which to base cancer drug development programs.
Cysteine-reactive covalent inhibitors have already emerged as an effective approach to targeting protein kinases. Osimertinib, a third-generation epidermal growth factor receptor (EGFR) TKI covalent inhibitor, overcomes EGFR T790M resistance mutations following treatment with EGFR TKI, demonstrating significant improvements over standard EGFR TKIs when used as first line therapy. Importantly, targeting cysteines with covalent inhibitors massively expands the number of proteins which are targetable with small molecule inhibitors, including many targets previously considered undruggable.

We will use ALK fusion positive cancer cell lines, together with tumor tissues from patients who developed resistance mechanisms, to generate druggable cysteine profiles by CDM. Druggable proteins specific to ALK fusion positive samples, including EML4-ALK itself, will be prioritized in our screening for protein degraders from a library of over 2,500 advanced cysteine reactive compounds. After screening, we will assess the specificity of the compound hits and validate their anti-tumor activity using ALK fusion positive cell lines and patient derived ALK TKI-resistant cell lines. We consider the use of the novel, cutting-edge cysteine targeting technology to screen for potent therapeutic compounds as a valuable proposition to improve management of patients with ALK positive lung cancer, with the goal of transforming this cancer into a chronic condition.

With the development of increasingly potent and selective ALK tyrosine kinase inhibitors (TKIs), resistance is commonly mediated by ALK-independent mechanisms, such as bypass pathway activation. As bypass signaling dependencies vary across ALK-rearranged (ALK+) lung cancers, a multipronged approach is needed to broadly suppress potential bypass signals. We have identified MET activation in 20% of ALK+ tumors that are resistant to next-generation ALK TKIs. In preclinical studies, dual ALK/MET blockade re-sensitized MET-amplified ALK+ tumors to lorlatinib. MEK and SHP2 have recently been identified as important effector proteins downstream of several bypass signaling pathways. In ALK+ models harboring diverse bypass signals, pairing an ALK TKI with either a MEK or SHP2 inhibitor demonstrated broad anti-proliferative activity. Based on these findings, we will conduct a clinical trial to evaluate lorlatinib in combination with a MET, MEK, or SHP2 inhibitor for patients with ALK+ lung cancers with ALK-independent resistance. Serial tumor biopsies will be analyzed to characterize molecular determinants of response to combination therapy and identify expression changes induced by treatment. This innovative multi-arm trial will also assess whether dynamics of genetic alterations in plasma can be used to guide intensification of treatment from monotherapy to early combination therapy for patients who have not yet developed resistance to ALK-directed therapy. Collectively, the studies in this grant strive to develop diverse strategies for overcoming ALK-independent resistance, a heterogeneous molecular entity that undermines efficacy of current ALK therapeutics.

Several tyrosine kinase inhibitors (TKIs) are available for the treatment of ALK+ NSCLC, but resistance to all ALK TKIs (including alectinib, brigatinib, lorlatinib) has been reported and occurs through a variety of mechanisms. Once patients develop resistance to available ALK inhibitors, they are typically treated with cytotoxic chemotherapy rather than immunotherapy since response rates to PD-1 pathway inhibitors in this population are very low. However, our work in mouse models of ALK+ NSCLC has demonstrated that a vaccine generated against the rearranged portion of ALK can both prevent the development of ALK+ tumors and also more effectively treat them once they arise. We have also recently found evidence for anti-ALK immune responses in patients, as a subset of them generate spontaneous ALK autoantibodies.

We aim to translate our preclinical findings to a first-in-human clinical trial. Aim 1 will test the safety and efficacy of a novel ALK vaccine + an amphiphilic CpG toll-like receptor 9 agonist adjuvant, administered in combination with an ALK TKI or PD-1 inhibitor in patients with TKI-resistant ALK-positive NSCLC. In Aim 2, using liquid chromatography data-independent acquisition mass spectrometry, we will directly identify antigenic ALK peptides presented by MHC molecules on the surface of cancer cells from tumor biopsies obtained on trial participants. In Aim 3, we will study pre- and post-vaccination anti-ALK T-cell responses among trial participants by analyzing peripheral leukocytes and intratumoral immune cells. The overarching goal is to develop a vaccine that stimulates patients’ immune cells to recognize and eliminate ALK+ tumors.

Small cell lung cancer (SCLC) is an aggressive, neuroendocrine malignancy that accounts for approximately 15% of lung cancers. Despite recent advances, including the approval of immunotherapy combined with chemotherapy for frontline treatment, the median overall survival for patients with extensive-stage SCLC remains approximately one year. These dismal outcomes are attributable, in part, to the lack of approved biomarkers for SCLC, which, in turn, is due to the dearth of available tissue for molecular analysis. Using transcriptomic data, we have developed a gene signature that defines four distinct molecular subtypes of SCLC – each with unique biology and therapeutic vulnerabilities. These subtypes are driven by the presence (or absence) of three transcription factors (ASCL1 – SCLC-A; NEUROD1 – SCLC-N; POU2F3 – SCLC-P; and a fourth triple-negative subtype “Inflamed” – SCLC-I) that are largely mutually exclusive. Our preliminary data suggests that inter- and intra-tumoral heterogeneity among these subtypes drives response and resistance to standard and novel therapies for SCLC, including classes such as PARP inhibitors (PARPi) and immunotherapy. We propose applying bulk and single-cell molecular approaches to assign and longitudinally monitor subtype among our established cohort of patient-derived xenograft models treated with PARPi, as well as patient tumor biopsies from an investigator-initiated trial assessing a PARPi/immunotherapy combination. Based on our preliminary data, we hypothesize that SCLC-P and SCLC-I will preferentially benefit from PARP inhibitors and immunotherapy, respectively, and that subtype shifts detectable at the single-cell level along with accompanying shifts in the composition of the immune microenvironment, will govern response and resistance.

KRAS mutations are the most common activating mutation in lung cancer and are identified in 25-30% of cases of lung adenocarcinoma. The clinical activity of molecularly targeted therapy in KRAS mutant lung cancer has been limited, as most prior approaches focused on downstream targets of the MAPK pathway, an approach which was largely ineffective. KRAS G12C is the most common subtype of activating KRAS mutation in NSCLC. Identification of a binding pocket of KRAS G12C enabled the development of covalent inhibitors (Ostrem et al. Nature, 2013), which selectively bind to the mutant cysteine and spare wild type or other mutant KRAS proteins (hereafter referred to as G12Ci). These drugs bind only to GDP-bound (i.e. inactive) KRAS G12C and trap the oncoprotein in its inactive state by preventing nucleotide exchange (Lito et al. Science, 2016). Of this new class of agents, two drugs (MRTX849 and AMG510) have demonstrated efficacy in early phase clinical trials, representing a remarkable breakthrough in the management of KRAS G12C mutant lung cancer. Acknowledging the limited number of patients treated thus far, response rates of 40-50% have been reported, demonstrating clinical activity far superior to prior molecularly targeted approaches for the management of KRAS mutant lung cancer. Despite this major advance it is clear that resistance to therapy, both primary and acquired, will remain a challenge and may in part be due to upstream receptor tyrosine kinase (RTK) signaling. Understanding the mechanisms of resistance to this new class of therapy is of paramount importance to improve the efficacy and durability of response, and for identifying rational combinatorial therapies for future clinical trials.