Stage IV

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.

Despite high tumor response rates, patients treated with osimertinib inevitably develop disease progression. Mechanisms of both intrinsic, adaptive, and acquired drug resistance remain incompletely understood on a genomic and proteomic level. Our overall objective is to find new targeted treatments and drug combinations that can tackle cancer evolution and drug resistance.

We seek to:

1. Understand biological determinants of response prior to therapy (poor prognosis features)
2. Utilize correct combination therapies in the first line to enhance response, based on biological features of subpopulations present at the start
3. Reprogram cells toward a more drug-sensitive state through understanding network plasticity.

More specifically, our aims are:

1. To define the genomic and proteomic characteristics of drug-tolerant persister cells (DTPCs) under dynamic treatment with osimertinib. Our goal is to identify new vulnerabilities in EGFR-mutant tumors which, when therapeutically targeted, can maximize the depth and duration of benefit to first-line osimertinib therapy.
2. To decipher mechanisms of altered cell cycle progression and osimertinib-induced DNA damage that drive tumor progression.

We have assembled a collaborative, multi-disciplinary team of laboratory scientists and clinical investigators combined with cutting edge technologies to assess genetic and proteomic heterogeneity at the single cell level, access to a robust pipeline of patient samples, and strong preliminary data to support our studies. The proposed aims are expected to define the molecular determinants of tumor heterogeneity and to develop rational therapeutic strategies for delaying / overcoming resistance. These synergistic aims are highly relevant to the current landscape of EGFR-mutant lung cancer.

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.

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.

The majority of lung cancer patients present with advanced disease that is largely incurable. Efforts to improve the early detection of this disease are critical to decrease lung cancer-related mortality. Low-dose computed tomography (CT) screening in high risk patients has demonstrated reduction in lung cancer related mortality through diagnosis of earlier stage disease at the cost of high false-positive rates and the frequent need for invasive diagnostic testing when indeterminate lung nodules are identified. Detecting tumor specific somatic mutations and/or epigenetic signatures in circulating tumor DNA (ctDNA) represents an attractive non-invasive method for identifying early stage lung cancer. However, to realize this promise for lung cancer screening, where ctDNA from small tumors is miniscule, the development of sensitive, specific, and economical ctDNA based assays is critical. 
The bacterial innate immune system consisting of clustered regularly interspaced short palindromic repeats (CRISPR) and their associated endonucleases (CRISPR-Cas) are specifically adapted to recognize foreign nucleic acids. The recent identification and diagnostic adaptation of certain classes of CRISPR-Cas systems, such as CRISPR-Cas12a and -Cas13a, offer unique platforms on which to develop sensitive, specific, and economical assays for the detection of ctDNA. The goal of the current project is to develop CRISPR-Cas12a and -Cas13a based ctDNA assays that can sensitively detect somatic cancer mutations and aberrant promoter hypermethylation often found in lung cancer patients and to validate these assays in plasma samples of patients with early stage NSCLC and in discriminating between benign and malignant nodules identified by low-dose CT screening studies. 

This project describes a 3-year training program for a career as a physician-scientist with the long term goal of establishing a research program within the field of translational thoracic oncology. The applicant is currently an Instructor of Medicine in the Section of Interventional Pulmonology and Thoracic oncology conducting research in developing biomarkers for the treatment selection and monitoring of patients with lung cancer. The research focus of this proposal is to develop molecular markers to better identify the subgroup of patients that will respond to PD1/PDL1 therapies in order to avoid unnecessary toxicities, reduce costs, and enable more appropriate therapies to be delivered. This goal will be accomplished in two complementary specific aims. In Specific Aim 1, a novel approach to acquire fresh tissue samples for immunophenotyping will be utilized to prospectively determine the ability of deep T cell phenotyping and functional assays to predict response to anti-PD1/PDL1 therapy using multi-parametric flow cytometry. In Specific Aim 2, a newly developed technique that enables the quantitative measurement of circulating PDL1 exosomes will be utilized to determine the association of pretreatment and on-treatment exosomal PDL1 expression levels to predict clinical outcomes in non-small cell lung cancer patients receiving checkpoint blockade. The training component of this proposal includes formal coursework, participation in a rich environment of post-doctoral lectures in thoracic oncology/tumor immunology, acquisition of advanced laboratory techniques, and individual mentoring. This project will take place under the supervision of Dr. Steven Albelda who is the Director of the Thoracic Oncology Laboratory at the University of Pennsylvania and Co-Director of the Abramson Cancer Center’s Translational Center of Excellence for Lung Cancer Immunobiology, and Dr. Anil Vachani who is the Director of Clinical Research for the Section of Interventional Pulmonology and Thoracic Oncology at Penn. Dr. Albelda and Dr. Vachani have mentored over 100 trainees. In addition, an advisory committee of distinguished scientists will provide experimental assistance, intellectual guidance, and career advice throughout the duration of this award.

Immune checkpoint blockade (ICB) has demonstrated profound effects on the anti-tumor immune response and has revolutionized the treatment landscape of non-small cell lung cancer (NSCLC). While chemotherapy has traditionally been viewed as detrimental to the immune system, recent clinical trials have demonstrated an impressive survival benefit when combining checkpoint blockade with chemotherapy (ICB+chemo) relative to chemotherapy alone. Despite this, many NSCLC patients do not achieve clinical benefit from ICB, even when combined with chemotherapy. The role of tumor mutational burden, and specifically T cells targeting neoantigens derived from these mutations, has been demonstrated in several ICB studies, however these factors have yet to be fully explored in chemotherapy-containing ICB treatment regimens. There is thus an urgent need to understand the effects of ICB+chemo on the anti-tumor immune response and to specifically evaluate how chemotherapy perturbs the phenotype and function of anti-tumor T cells. It is of paramount importance that we understand how PD-1 blockade and chemotherapy synergize to promote anti-tumor immunity in order to better stratify patients most likely to benefit from these treatments. We propose herein to perform the first comprehensive evaluation of the phenotype and function of neoantigen-specific T cells and their dynamics before and after treatment with ICB+chemo relative to ICB alone. The findings from this study will provide a detailed atlas of the immune system dynamics following treatment and will result in the development of an immunometabolic signature that will be correlated with clinical outcome. Importantly, the results of the proposed work will deepen our understanding of the immune response to ICB+chemo and will unravel the mechanisms underlying clinical response in NSCLC patients.

Targeted therapies, such as ALK inhibitors, represent a major advance in the treatment of lung cancer patients with specific oncogenic drivers. However, these patients relapse due to acquired or intrinsic resistance to these agents. While targeting immnoevasive pathways, such as immune checkpoint inhibitors, have shown efficacy in a subset of lung cancer patients who have progressed on other therapies, the response rate in ALK-positive lung cancer to these agents is very low, underscoring the need to identify other potential regulators of the anti-tumor immune response. The complement pathway is a component of the innate immune response, which regulates the adaptive immune system. Complement activation, initiated through multiple pathways, leads to a series of proteolytic cascades that generate inflammatory mediators designated as anaphylatoxins (C3a, C5a).

Our laboratory has employed an immunocompetent orthotopic model of lung cancer progression, where lung cancer cells are implanted into the lungs of syngeneic mice. To study pathways regulating progression of ALK-positive lung cancer, we have developed a panel of murine lung cancer cell lines with the oncogenic driver EML4/ALK. Using both genetic and pharmacological approaches we have demonstrated that while these tumors are resistant to anti-PD-1/anti-PD-L1 therapy, they are strongly inhibited by blocking the complement pathway. This project will define the mechanisms of complement activation, and the cellular and molecular mechanisms whereby complement inhibition blocks ALK-positive tumor progression. Studies will test a panel of complement inhibitors targeting different steps in the complement cascade and validate complement activation in human ALK-positive lung tumors.