Breaking Barriers: New Discovery on How Ovarian Cancer Blocks Immune Cells’ Energy Supply

By | November 3, 2024

A new breakthrough in ovarian cancer research has unveiled how ovarian tumors manage to starve immune cells of essential energy, significantly weakening their ability to fight back. Researchers at Weill Cornell Medicine have identified a mechanism in ovarian cancer that prevents T cells, an essential component of the immune system, from accessing the lipid-based energy they need to attack tumors. This discovery, published in Nature on October 23, 2024, opens the door to innovative immunotherapy approaches for treating aggressive cancers.

How Ovarian Tumors Block T-Cell Energy Supply
T cells rely on lipids, or fats, to fuel their fight against pathogens and tumors. However, ovarian cancer disrupts this process, trapping a key protein called FABP5 inside the T cells, which blocks lipid uptake. Here’s how this mechanism works:

  • FABP5 Protein: In healthy T cells, FABP5 moves to the cell surface, allowing the uptake of lipids for energy. But in ovarian cancer, FABP5 becomes trapped within the cytoplasm, stopping lipid uptake and energy production.
  • Transgelin 2: Researchers found that a protein named Transgelin 2 helps transport FABP5 to the cell surface. Without Transgelin 2, FABP5 is immobilized inside the cell, blocking energy intake.
  • XBP1 Factor: Tumor environments activate a transcription factor known as XBP1. This suppresses Transgelin 2 production, leading to the trapping of FABP5 in the cytoplasm and leaving T cells with no energy source to fight the tumor.

According to Dr. Juan Cubillos-Ruiz, senior author of the study, “The lack of Transgelin 2 essentially cuts off the energy supply for T cells, weakening their ability to respond to ovarian tumors.”

Study Insights on T Cell Starvation and Lipid Metabolism
Using patient-derived samples and mouse models of ovarian cancer, the study revealed the following:

  • Lipids Abundant in Tumors: Although lipids are plentiful in the tumor microenvironment, T cells cannot access these molecules.
  • Role of Transgelin 2: In the absence of Transgelin 2, T cells cannot move FABP5 to the surface, making it impossible to utilize lipids as fuel.
  • Impact on CAR T Cells: Even engineered CAR T cells, currently under clinical trials, are affected. Without lipid uptake, these modified T cells struggle against solid tumors like ovarian cancer.
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Towards New Immunotherapy Strategies
To counter this immune suppression, researchers experimented with a modified Transgelin 2 gene. Here’s how their approach could reshape immunotherapy for ovarian cancer:

  1. Modified CAR T Cells: The team added a version of Transgelin 2 that is immune to suppression by stress factors in the tumor.
  2. Energy Supply Restored: With this modification, FABP5 successfully moved to the T cell surface, allowing lipid intake and energizing the T cells.
  3. Improved Tumor Attack: Modified CAR T cells with Transgelin 2 were significantly more effective in attacking ovarian tumors compared to standard CAR T cells.

Dr. Cubillos-Ruiz and his team believe that this discovery could lead to a new generation of T cell therapies that are better suited for aggressive cancers like ovarian cancer, which are traditionally difficult to treat with immunotherapy alone.

Implications for Future Cancer Treatments
This research highlights several important implications for cancer treatment beyond ovarian cancer:

  • Potential for Solid Tumors: Traditional CAR T cell therapies work well for blood cancers but struggle with solid tumors. Reprogramming T cells to handle lipid metabolism barriers could extend CAR T cell success to a broader range of cancers.
  • Broader Cancer Therapy: Researchers suggest that targeting immune suppression mechanisms within tumor microenvironments could be a game-changer for many types of solid tumors.
  • Supporting Personalized Cancer Care: Understanding how ovarian cancer and other tumors evade the immune system at a molecular level can help personalize treatment approaches for individual patients.

Conclusion
This groundbreaking study unveils a critical barrier to immunotherapy in treating ovarian cancer, marking a significant step toward more effective treatment options. The novel strategy of reprogramming T cells to overcome energy blockades within tumor environments is promising for not only ovarian cancer patients but potentially for others battling hard-to-treat solid tumors. Future research and clinical trials are anticipated to validate and expand these findings, possibly transforming the treatment landscape for aggressive cancers.

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References

  • “Transgelin 2 guards T cell lipid metabolism and antitumour function” by Sung-Min Hwang et al., Nature, October 23, 2024, DOI: 10.1038/s41586-024-08071-y
  • Funding support provided by the National Institutes of Health, Department of Defense, and the American Association for Cancer Research