Modified Cell Immune Response Key to Defeating Lymphoma, Leukemia: Research

Scientifically-altered T cells, which produce the body's immune response, may be a key to defeating leukemia, lymphoma, and multiple myeloma, say authors of a new study.

T cells are white blood cells that permanently patrol human tissues and blood vessels, hunting down foreign invaders such as bacteria and viruses.

These cytotoxic or killer cells can be taken from the cancer patient's blood and then fortified with added artificial, chimeric antigen receptors as a last-ditch treatment for the above cancers.

Colorized scanning electron micrograph of T lymphocyte
Picture shows colorized scanning electron micrograph of a T lymphocyte. Scientifically-altered T cells, which produce the body’s immune response, may be a key to defeating leukemia, lymphoma, and multiple myeloma, say authors of a new study. NIAID/Zenger

Modified with chimeric receptors, T cells can also detect specific structures on the surface of cancer cells.

In theory, when these modified or CAR T cells are returned via infusion to a patient, they go into action against cancer and multiply and continue living in the body as a living drug that can destroy specific tumors.

However, patients still have relapses of cancer because tumor cells outwit CAR T cells by producing more of the EBAG9 protein in genes, which stimulates the T cells to do the same.

In T cells, EBAG9 inhibits the release of cytotoxic enzymes, which slows the immune response.

Shutting down the EBAG9 gene in mice had already been shown to cause a sustained increase in the immune response to cancer, as well as stimulating T memory cells that allow a better immune response to a cancer antigen.

In the paper titled "EBAG9 silencing exerts an immune checkpoint function without aggravating adverse effects" published July 11 in the journal Molecular Therapy, researchers have shown similar findings in human CAR T cells in vitro.

Chemotherapy treatments for lung cancer patients
Chemotherapy treatments for lung cancer patients are mixed in the pharmacy at the Kimmel Comprehensive Cancer Center at Johns Hopkins on August 15, 2005, in Baltimore, Maryland. Scientifically-altered T cells, which produce the body’s immune response, may be a key to defeating leukemia, lymphoma, and multiple myeloma, say authors of a new study. Win McNamee/Getty Images

"Shutting down EBAG9 allows the body to eradicate tumor cells earlier and more radically. As well as achieving longer-lasting therapeutic success, this could also create a real chance of cure," said co-author Armin Rehm.

For years, researchers knew that the EBAG9 gene plays an important yet unidentified role in cancer.

Researchers at Germany's Max Delbrück Center for Molecular Medicine in the Helmholtz Association found that lab mice without that gene dealt with bacterial and viral infections much better than mice with the gene.

The mice also formed more T memory cells, which are of particular interest in tumor biology.

The study's lead author, Anthea Wirges, managed to curb the synthesis of the EBAG9 protein using microRNA.

In the new study, Wirges used microRNA to cultivate "EBAG9-silenced" CAR T cells with different human leukemia or lymphoma cells.

This showed in human cells, as in the mouse model, the silencing of EBAG9 reduced tumor growth much more. Relapses also only developed much later.

"Releasing the EBAG9 brake allows the genetically engineered T cells to release more cytotoxic substances. However, they don't cause the strong cytokine storm that is typically a side effect of CAR therapy," said Wirges.

The risk of side effects, say the study's authors, is minimized because fewer cells are used.

"Switching off the immune brake works across the board. We can do it with every CAR T cell that we produce – regardless of which type of blood cancer it targets," Rehm said.

For now, clinicians will have to rely on chemotherapy combined with conventional antibody therapy.

Researcher Ute Hopken said, "CAR therapy only comes into play if the cancer returns. It's very expensive because it's an individual cellular product for a single person."

But a single treatment with that product can save a life, claim the authors.The team is now looking for clinicians and financing to conduct clinical studies.

In November, they plan to present their findings to Germany's Paul Ehrlich Institute, which approves such therapies.

This story was provided to Newsweek by Zenger News.