Since the beginning of the project, we have focused on uncovering the metabolic weaknesses of cancer by studying the tumor microenvironment (TME). To achieve this, we developed innovative tools like Dual Ribosome Profiling (DualRP) and diricore, which allow us to explore the metabolic interactions between cancer cells and the surrounding stromal cells. These tools help us understand how cancer cells depend on specific amino acids to grow and survive. DualRP, in particular, enables us to analyze the gene activity of two interacting cell populations within the TME at the same time, giving us valuable insights into how cancer adapts to its environment.
One of our significant findings was that cancer cells and fibroblasts, which support the tumor, experience shortages of key amino acids, such as alanine and glycine, under low glucose conditions. However, when these cells are co-cultured, they manage to overcome this shortage by activating a specific signaling pathway, allowing them to produce the nutrients they need to make proteins. Additionally, we developed mouse models that let us examine different cell types' interactions and metabolic activities in a more natural, living environment. This has been crucial in discovering how amino acid restrictions can affect immune cells, particularly T-cells, during cancer treatment with checkpoint inhibitors. Our research showed that when T-cells lack certain amino acids, their ability to respond to cancer therapies weakens.
Our findings are being shared through scientific publications and conferences, contributing to the broader understanding of cancer metabolism. Moving forward, we aim to develop new therapies that target these metabolic weaknesses, with the hope of improving cancer treatments and overcoming drug resistance. This research sets the stage for future innovations in cancer therapy by shedding light on the complex metabolic interactions within the TME.
Overall, the project has advanced our understanding of the TME's metabolic complexities, setting the stage for future therapeutic innovations in cancer treatment.