Jump Main Menu. Go directly to the main content

Sección de idiomas

EN

Fin de la sección de idiomas

Access / Registration

Sección de utilidades

Fin de la sección de utilidades

MENU
Secondary menu End of secondary menu

Research projects

Start of main content

Identification at single-cell level of molecular and metabolomic mechanisms governing antitumoral response of CAR T therapies in MM patients (M4CART)

21st national competition for scientific and technical research

Personalized therapy, immunotherapy and cancer

Senior Researcher : Idoia Ochoa Álvarez

Research Centre or Institution : Universidad de Navarra. Pamplona.

Abstract

Therapeutic strategies based on chimeric antigen receptor T lymphocytes (CAR T cells) have become a real option for patients with certain hematologic diseases. Despite significant responses, patients with Multiple Myeloma (MM) treated with CAR T therapies have shown significant relapses associated with lack of persistence of CAR T and additional mechanism of resistance. However, the molecular and metabolomic mechanisms governing CAR T cell function and persistence are not yet fully understood, and there is a lack of studies especially after CAR T cell infusion into patients.

Thanks to the advances in single-cell sequencing, it is now possible to acquire gene-expression data for each individual cell in samples containing thousands of cells. These cells can be further grouped into different states, which are characterized by similar, but distinct enough, regulatory and metabolomic mechanisms. However, current regulatory inference methods fail to capture these regulatory dynamics, that are ultimately linked to heterogeneity of cells. Similarly, current methods based on the concept of synthetic lethality for the inference of metabolomic dependencies and vulnerabilities on tumor cells are not tailored to single-cell data.

The hypothesis of this work is that the efficiency of CAR T therapies depends on complex Gene Regulatory Networks (GRN) and metabolomic mechanisms affecting cell viability. Thus, the overarching goal of this project is to dissect the regulatory and metabolomic mechanisms governing antitumoral response of CAR T therapies in MM after cell infusion to the patients. We will use single cell information coupled with novel machine learning methods to identify the key regulatory elements that instruct and govern CAR T cells during CAR T therapies. Further, we will deepen our understanding on how these mechanisms are subverted in those patients who are refractory or present therapeutic failure. Together this work will provide a broad picture of the mechanisms controlling CAR T function and may lead to the identification of factors with prognostic value or could be modulated to improve the therapeutic efficacy of CAR T therapies in MM patients.  

  • Activities related
  • Projects related
  • News related
  • Publications related

see all

End of main content