T cells are often called “assassins” or “killers” because they can orchestrate and carry out missions to hunt down bacteria, viruses, and cancer cells throughout the body.
Mighty as they may be, recent research has shown that once T cells infiltrate the environment of a solid tumour, they lose the energy needed to combat the cancer.
A research team led by Jessica Thaxton, PhD, MsCR, associate professor of cell biology and physiology and co-leader of the Cancer Cell Biology Program at the UNC Lineberger Comprehensive Cancer Center, aimed to understand why T cells do not sustain energy in tumours.
Using their expertise in tumour immunity and metabolism, the Thaxton Lab, led by the Katie Hurst, MPH, and 4th year graduate student Ellie Hunt, found that a metabolic enzyme called Acetyl-CoA Carboxylase (ACC) causes T cells to store fat rather than burning fat for energy.
“Our discovery fills a long-standing gap in knowledge regarding why T cells in solid tumours don't appropriately generate energy,” said Thaxton.
“We inhibited the expression of ACC in mouse cancer models, and we observed that T cells were able to persist much better in solid tumours.”
The new findings and immunotherapeutic strategies, which were published in Cell Metabolism, could be used to make multiple types of T-cell therapies more effective for patients, possibly encompassing both checkpoint and chimeric antigen receptor (CAR) T-cell therapies.
In the field of cancer immunotherapy, it has long been known that T cells are not able to create their cellular energy, called adenosine triphosphate or ATP, when they are inside of a solid tumour.
In 2019, Thaxton’s lab studied a T cell with optimal antitumor function. In a publication in Cancer Immunology Research, Hurst and Thaxton used a proteomics screen to identify enzymes associated with the optimal antitumor metabolism of these T cells.
Through this screen, the two discovered that ACC expression may limit the ability of T cells to make ATP in tumours. ACC, a key molecule that is involved in many metabolic pathways, blocks cells from breaking down fat and using it as fuel for energy in mitochondria.
“Acetyl-CoA carboxylase can drive the balance between storing lipids versus breaking down those lipids and feeding them into the citric acid cycle for energy,” said Thaxton.
“If ACC is flipped ‘on’, cells generally store lipid. If ACC is ‘off’, cells tend to use the lipid in their mitochondria to make ATP.”
Using Hunt’s expertise in confocal imaging, the research team was able to observe lipid stores in T cells isolated from multiple types of cancers.
The observation, as well as other experiments, confirmed the team’s hypothesis that T cells were storing lipids instead of breaking them down.
Thaxton’s team then used CRISPR Cas9-mediated gene deletion to see what would happen if they “deleted” ACC from the picture.
There was a rapid reduction in the amount of lipid storage in T cells, and the team was able to visualise fat relocating to the mitochondria to be used to generate energy.
Thaxton now hypothesises that T cells may need a “delicate balance” of lipids to persist in solid tumours with a certain amount of lipid dedicated to cancer cell assassination and low levels of fats being maintained in stores.
The latest findings could prove to be useful in enhancing chimeric antigen receptor (CAR) T-cell therapies.
This cutting-edge technology takes T cells out of cancer patients, modifies them in the lab to hunt down tumour cells, and then re-infuses the cells to fight the patient's cancer.
Preliminary data from Thaxton's lab demonstrates that even the manufactured T cells contain excess lipid stores.
The lab is starting to look in patient samples to understand how researchers can possibly flip the ACC metabolic switch directly in patient tumours, negating the need to take out and reinfuse cells back into the body.
But researchers must first determine how this could affect other immune cell populations in the body, such as macrophages.
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