Peptide pulsed autologous Dendritic cell(Universidad Nacional de Colombia)

Due to their genetic instability, breast tumors that do not express receptors for Estrogens, Progestagens or amplify the Her2 / neu oncogene [called triple-negative breast cancer (TNBC)] and other tumors such as melanoma, non-small cell lung cancer, accumulate numerous mutations that make them highly resistant to different regimens of chemo- or radiotherapy, thereby generating high morbidity and mortality. However, immunology can turn the genetic instability of tumors into the Achilles' tendon. Evidence of this has been revealed in Phase I clinical studies in patients with melanoma and lung cancer in an advanced stage of metastasis treated with Ipilimumab (anti-CTLA4) to decrease immunosuppression, in whom peptides containing mutations presented in Major Complex molecules Histocompatibility of Class I (MHC I) of the tumor itself results in their recognition as "foreign" neo-antigens leading to the efficient destruction of the tumor by anti-tumor CD8 + T lymphocytes that are amplified when they are vaccinated with these peptides.
For this reason, the identification of non-synonymous mutations of single amino acid and vaccination with 25 amino acid peptides that incorporate these mutations (synthetic vaccines) is emerging today as an alternative for immunotherapy of cancers responsible for high mortality in humans. In an approach that takes 16 weeks, today, it is possible to go from the analysis of the tumor's transcriptome (which allows identifying the universe of tumor mutations) to the patient's vaccination with a personalized vaccine that contains neo-antigens of his tumor.
TNBC is the most aggressive breast tumor, representing around 15% of breast cancers in our environment. While generally, at least 30% of women with other types of metastatic breast cancer survive 5 years after diagnosis, most patients diagnosed with metastatic TNBC die within this time. The lack of selective therapies and the poor prognosis of patients with TNBC make their therapeutic management difficult, so the implementation of new therapies for this type of tumor is the main focus of researchers who seek more effective and selective treatments to improve the life expectancy of patients without compromising their quality of life. The genetic instability and high rate of mutations of the TNBC most likely favor the generation of neo-epitopes. Still, due to the immunosuppressive environment of the tumor, it escapes the immunosurveillance of the immune system. Despite the high mortality induced by this tumor, a percentage of patients treated with neoadjuvant chemotherapy with agents such as Doxorubicin and Cyclophosphamide (AC) + Taxanes respond to this chemotherapy regimen. In particular, the anti-tumor effect of AC is attributed to two things: (i) the direct cytotoxic effect on the tumor cell, (ii) the immunostimulation of T lymphocytes promoted by Immunogenic Cell Death (ICD) selectively induced by these drugs. Therefore, in this project, we propose to carry out the first clinical study in Colombia of vaccination of patients with TNBC with synthetic peptides that contain mutations of their own tumor to evaluate the immunogenicity and safety of this type of personalized vaccine as a therapeutic alternative for this tumor. Achieving the specific objectives set out in this project would mean that we have been validated in Colombia the experimental design necessary to identify unique epitopes in tumors and demonstrate the safety and immunogenicity of these vaccines. We consider that having achieved the above; we will have taken an important step towards the implementation in our country of the use of this type of vaccine for immunotherapy not only of TNBC but of other tumors such as glioblastoma, gastric, esophagus, and pancreas, highly fatal due to its high mutation rate.