Neoantigen-Targeted Vaccines in Combination with Immune Checkpoint Inhibitors for Pancreatic Cancer
Johns Hopkins University, Baltimore MD
Investigators
Linked publications & trials
Abstract
PROJECT SUMMARY Immune checkpoint inhibitors (ICIs) provide durable clinical responses in about 20% of cancer patients, but have minimal effects in cancers lacking intraâtumoral T cells. Approaches that turn Tâcellâdeplete cancers into ones that attract highâquality T cells are needed to sensitize these unresponsive cancers to ICIs. Tumors contain somatic mutations that encode for mutant proteins that are tumorâspecific and not expressed on normal cells (termed neoantigens). Cancers, such as melanoma, with the highest mutational burdens are more likely to respond to single agent ICIs. However, most cancers, including pancreatic ductal adenocarcinoma (PDAC), have lower mutational loads, resulting in lower antigenicity, weaker endogenous T cell repertoires, and fewer T cells infiltrating the tumor. PDACs also have an immunosuppressive tumor microenvironment (TME) consisting of monocytes, B cells and T cells that express T cell inhibitory signals. Preclinical studies show that a mutated KRAS (mKRAS) vaccine given with ICIs to geneticallyâengineered mice overexpressing mKRASG12D (KPC mice) inhibits premalignant lesions from progressing to PDAC (PMID: 24607504). My work with Panc02 cells showed that a neoantigenâtargeted vaccine, PancVAX, a mixture of twelve 20âmer neoantigen peptides, when paired with IC modulators cleared tumors in Panc02âbearing mice with a survival benefit (PMID: 30333318). In this proposal we will test the hypothesis that peptide vaccines targeting âsharedâ mKRAS neoantigens, or âpersonalizedâ patientâtumorâspecific neoantigens will trigger highâquality neoantigenâspecific effector and effector memory T cells, which will then become available for further activation by ICIs and result in tumor rejection. We will thus conduct two early clinical trials to test vaccines targeting mKRAS (Specific Aim 1) or patientâtumorâspecific neoantigens (Specific Aim 2) in combination with the ICIs ipilimumab and nivolumab in patients with resected and metastatic PDAC, respectively. In both instances, we will assess safety of the triple combinations, perform inâdepth immune phenotyping of peripheral blood to include T cell number, quality and repertoire, and study the cellular architecture of the TME. A complement of stateâofâtheâart technologies including single cell RNAâSeq and TCRâSeq, and multispectral immunofluorescence will be utilized. In the long term, these studies should inform future combination immunotherapy approaches in PDAC patients, and, in the short term, will provide me with vital new skillsets in bioinformatics, human immunology, and early clinical trial design. The outstanding mentorship of my Advisory Team, the rich scientific environment at Johns Hopkins, and the vast array of available resources should poise me to achieve my goal of becoming a funded, independent investigator in translational oncology by the end of this grant period.
View original record on NIH RePORTER →