Kavya Rakhra

Supramolecular Stacking of Doxorubicin on Carbon Nanotubes for In Vivo Cancer Therapy

Doxorubicin (DOX) is a member of the anthracycline class of chemotherapeutic agents that are used for the treatment of many common human cancers, including aggressive non-Hodgkin’s lymphoma.[1,2] However, DOX is highly toxic in humans and can result in severe suppression of hematopoiesis, gastrointestinal toxicity,[3] and cardiac toxicity.[4] To date, several approaches, including delivery using liposomes (DOXIL),[5] have been developed to reduce the toxicity and enhance the clinical utility of this highly active antineoplastic agent.

CD4+ T Cells Contribute to the Remodeling of the Microenvironment Required for Sustained Tumor Regression upon Oncogene Inactivation

Oncogene addiction is thought to occur cell autonomously. Immune effectors are implicated in the initiation and restraint of tumorigenesis, but their role in oncogene inactivation-mediated tumor regression is unclear. Here, we show that an intact immune system, specifically CD4(+) T cells, is required for the induction of cellular senescence, shutdown of angiogenesis, and chemokine expression resulting in sustained tumor regression upon inactivation of the MYC or BCR-ABL oncogenes in mouse models of T cell acute lymphoblastic lymphoma and pro-B cell leukemia, respectively. Moreover, immune effectors knocked out for thrombospondins failed to induce sustained tumor regression. Hence, CD4(+) T cells are required for the remodeling of the tumor microenvironment through the expression of chemokines, such as thrombospondins, in order to elicit oncogene addiction.

Synthetic Nanoparticles for Vaccines and Immunotherapy

National Institutes of Health (U.S.) (Grants AI111860, CA174795, CA172164, AI091693, and AI095109)

Eradication of large established tumors in mice by combination immunotherapy that engages innate and adaptive immune responses

Checkpoint blockade with antibodies specific for cytotoxic T lymphocyte–associated protein (CTLA)-4 or programmed cell death 1 (PDCD1; also known as PD-1) elicits durable tumor regression in metastatic cancer, but these dramatic responses are confined to a minority of patients. This suboptimal outcome is probably due in part to the complex network of immunosuppressive pathways present in advanced tumors, which are unlikely to be overcome by intervention at a single signaling checkpoint. Here we describe a combination immunotherapy that recruits a variety of innate and adaptive immune cells to eliminate large tumor burdens in syngeneic tumor models and a genetically engineered mouse model of melanoma; to our knowledge tumors of this size have not previously been curable by treatments relying on endogenous immunity. Maximal antitumor efficacy required four components: a tumor-antigen-targeting antibody, a recombinant interleukin-2 with an extended half-life, anti-PD-1 and a powerful T cell vaccine. Depletion experiments revealed that CD8+ T cells, cross-presenting dendritic cells and several other innate immune cell subsets were required for tumor regression. Effective treatment induced infiltration of immune cells and production of inflammatory cytokines in the tumor, enhanced antibody-mediated tumor antigen uptake and promoted antigen spreading. These results demonstrate the capacity of an elicited endogenous immune response to destroy large, established tumors and elucidate essential characteristics of combination immunotherapies that are capable of curing a majority of tumors in experimental settings typically viewed as intractable.

Lymphomas that recur after MYC suppression continue to exhibit oncogene addiction

The suppression of oncogenic levels of MYC is sufficient to induce sustained tumor regression associated with proliferative arrest, differentiation, cellular senescence, and/or apoptosis, a phenomenon known as oncogene addiction. However, after prolonged inactivation of MYC in a conditional transgenic mouse model of Eμ-tTA/tetO-MYC T-cell acute lymphoblastic leukemia, some of the tumors recur, recapitulating what is frequently observed in human tumors in response to targeted therapies. Here we report that these recurring lymphomas express either transgenic or endogenous Myc, albeit in many cases at levels below those in the original tumor, suggesting that tumors continue to be addicted to MYC. Many of the recurring lymphomas (76%) harbored mutations in the tetracycline transactivator, resulting in expression of the MYC transgene even in the presence of doxycycline. Some of the remaining recurring tumors expressed high levels of endogenous Myc, which was associated with a genomic rearrangement of the endogenous Myc locus or activation of Notch1. By gene expression profiling, we confirmed that the primary and recurring tumors have highly similar transcriptomes. Importantly, shRNA-mediated suppression of the high levels of MYC in recurring tumors elicited both suppression of proliferation and increased apoptosis, confirming that these tumors remain oncogene addicted. These results suggest that tumors induced by MYC remain addicted to overexpression of this oncogene.

Immunology in the clinic review series; focus on cancer: multiple roles for the immune system in oncogene addiction

OTHER THEMES PUBLISHED IN THIS IMMUNOLOGY IN THE CLINIC REVIEW SERIES

High-throughput quantitation of inorganic nanoparticle biodistribution at the single-cell level using mass cytometry

Inorganic nanoparticles (NPs) are studied as drug carriers, radiosensitizers and imaging agents, and characterizing nanoparticle biodistribution is essential for evaluating their efficacy and safety. Tracking NPs at the single-cell level with current technologies is complicated by the lack of reliable methods to stably label particles over extended durations in vivo. Here we demonstrate that mass cytometry by time-of-flight provides a label-free approach for inorganic nanoparticle quantitation in cells. Furthermore, mass cytometry can enumerate AuNPs with a lower detection limit of ∼10 AuNPs (3 nm core size) in a single cell with tandem multiparameter cellular phenotyping. Using the cellular distribution insights, we selected an amphiphilic surface ligand-coated AuNP that targeted myeloid dendritic cells in lymph nodes as a peptide antigen carrier, substantially increasing the efficacy of a model vaccine in a B16-OVA melanoma mouse model. This technology provides a powerful new level of insight into nanoparticle fate in vivo.

A tumor-immune mathematical model of CD4+ T helper cell dependent tumor regression by oncogene inactivation

Understanding the complex dynamics between the tumor cells and the host immune system will be key to improved therapeutic strategies against cancer. We propose an ODE-based mathematical model of both the tumor and immune system and how they respond to inactivation of the driving oncogene. Our model supports experimental results showing that cellular senescence of tumor cells is dependent on CD4+ T helper cells, leading to relapse of tumors in immunocompromised hosts.

Abstract A42: Combination immunotherapy of an autochthonous murine lung cancer model expressing human CEA as a tumor-associated self-antigen

While cancer immunotherapies like checkpoint inhibitors have resulted in unprecedented clinical success, they only benefit a subset of patients. To improve therapeutic outcomes for greater numbers of patients, one strategy is to rationally combine different immunotherapy modalities. We recently demonstrated that attaching albumin-binding lipophilic tails to peptide antigens or molecular adjuvants (creating amphiphile vaccines) results in enhanced T-cell responses. Additionally, we observed significant tumor regression upon combining tumor-antigen targeting antibodies with extended half-life IL-2 (exPK-IL-2) in mouse models of melanoma and prostate cancer. In the present work, we combined both approaches to treat a spontaneous model of lung adenocarcinoma expressing carcinoembryonic antigen (CEA), an oncofetal protein expressed in some human lung cancers. KrasLSL-G12D/+;;p53fl/fl mice were crossed with transgenic mice expressing human-CEA to generate a CEA-tolerant background. Lung tumors were induced by infection with a lentivirus expressing Cre recombinase and human CEA. Due to the extended latency of tumor initiation in this model, we also generated a CEA-expressing cell line from these mice to test the efficacy of different combination immunotherapy regimens. We discovered that weekly treatments combining a CEA-targeting amphiphile-vaccine, exPK-IL-2, and an anti-CEA antibody with checkpoint inhibitors (anti-PD-1 and -CTLA4) resulted in sustained tumor regression in 50% of mice bearing established tumors. We are currently testing this combination immunotherapy on autochthonous lung tumors. Our results suggest that breaking tolerance to a tumor-associated self-antigen (CEA) and combining immunotherapies to recruit both innate and adaptive immune effectors can have a potent therapeutic effect in intractable tumors like lung cancer. Citation Format: Kavya Rakhra, Eric F. Zhu, Wuhbet Abraham, Kelly D. Moynihan, Naveen Mehta, Karl D. Wittrup, Darrell J. Irvine. Combination immunotherapy of an autochthonous murine lung cancer model expressing human CEA as a tumor-associated self-antigen. [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2016 Oct 20-23; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2017;5(3 Suppl):Abstract nr A42.

Abstract A52: Eradication of large established tumors with combination immunotherapy engaging innate and adaptive immunity

Checkpoint blockade against CTLA-4 or PD-1 has demonstrated that an endogenous immune response can be stimulated to elicit durable regressions in advanced cancer, but these dramatic responses are currently confined to a minority of patients. This outcome is probably due in part to the complex network of immunosuppressive pathways present in advanced tumors, which are unlikely to be overcome by intervention at a single signaling checkpoint, requiring a counter-directed network of pro-immunity signals. Here we demonstrate a combination immunotherapy that recruits a diverse set of innate and adaptive immune effectors, enabling robust elimination of tumor burdens that to our knowledge have not previously been curable by treatments relying on endogenous immunity. Maximal anti-tumor efficacy required four components: a tumor antigen targeting antibody, an extended half-life IL-2, anti-PD-1, and a powerful T-cell vaccine. This combination elicited durable cures in a majority of animals, formed immunological memory in multiple transplanted tumor models, and induced sustained tumor regression in an autochthonous BRrafV600E/Pten-/- melanoma model. Multiple innate immune cell subsets, CD8+ T-cells, and cross-presenting dendritic cells were critical to successful therapy. Treatment induced high levels of intratumoral inflammatory cytokines and immune cell infiltration, enhanced antibody-mediated tumor antigen uptake, and promoted antigen spreading. These results demonstrate the capacity of an elicited endogenous immune response to destroy large, established tumors and elucidate essential characteristics of combination immunotherapies capable of curing a majority of tumors in experimental settings typically viewed as intractable. Citation Format: Kelly Dare Moynihan, Cary Opel, Gregory Szeto, Alice Tzeng, Zhu Eric, Jesse Engreitz, Williams Robert, Kavya Rakhra, Michael Zhang, Adrienne Rothschilds, Sudha Kumari, Ryan L. Kelly, Byron Kwan, Wuhbet Abraham, Kevin Hu, Naveen Mehta, Monique Kauke, Heikyung Suh, Douglas A. Lauffenburger, K. Dane Wittrup, Darrell J. Irvine. Eradication of large established tumors with combination immunotherapy engaging innate and adaptive immunity. [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2016 Oct 20-23; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2017;5(3 Suppl):Abstract nr A52.