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Cancer cells sometimes develop resistance to the cytotoxic drugs used in chemotherapy. Figuring out why the treatment isn't working and why it may even defeat its own purpose is therefore important to understand.

  
Kaisa Lehti, PhD. Ka... - Click to enlarge in new windowKaisa Lehti, PhD. Kaisa Lehti, PhD, Professor at the Norwegian University of Science and Technology's Department of Biomedical Laboratory Sciences, has lead the effort to understand more about why chemotherapy sometimes doesn't work.

"We haven't understood very much about how this resistance to chemotherapy develops and even less about how the microenvironment in cancer can affect the process," noted Kaisa Lehti, PhD, Professor at the Norwegian University of Science and Technology's (NTNU) Department of Biomedical Laboratory Science.

 

Lehti has led the work to understand more about how cancerous tissues develop resistance to a particular form of chemotherapy. The University of Helsinki, Karolinska Institutet, and NTNU have collaborated on the research (Nat Commun 2021; https://doi.org/10.1038/s41467-021-24009-8).

 

Standard Treatment May Fail

If ovarian cancer is detected early, almost all patients survive the first 5 years. But if it is discovered later, the chances of survival are much worse. Finding effective treatment is therefore very important.

 

One of the standard treatments for ovarian cancer is platinum chemotherapy. The cytotoxins are so named because they contain platinum compounds. They are often effective in treating various cancers. Unfortunately, cancer cells often develop resistance to this particular platinum chemotherapy treatment. The solution lies in how the cytotoxin itself can change the cancer cells and their environment.

 

Lehti sums up the process. "The cytotoxin can change the way the cancer cells send and perceive signals and can modify the microenvironment around the cells."

 

This change allows the cancer cells to withstand the damage caused by the cytotoxin-and can thus survive the chemotherapeutic attack. The researchers have found this key to the puzzle in a layer of tissue that often surrounds cancer cells.

 

"A fibrotic network of proteins, known as the extracellular matrix or ECM, surrounds the cancer cells, particularly the most aggressive ones," Lehti noted.

 

Fibrotic tissue is formed when the body tries to repair an injury. The fibrotic tissue, with the ECM network around the cancer cells, is mainly produced by normal connective tissue cells. But the cancer cells and connective tissue cells in the network can alter this tissue themselves.

 

"Previously, we haven't known how the communication between the cancer cells and the extracellular matrix is affected by, or even itself influences, the development of cancer and its response to chemotherapy," Lehti stated.

 

But the researchers know more about that now. Chemical and mechanical signals in the surrounding ECM tissue are already known to help cancer develop its ability to spread and resist treatment.

 

"Certain signals from the ECM can critically change the cancer cells' resistance to platinum-based cytotoxic drugs," she explained.

 

The cytotoxin can thus help change both the microenvironment around the cancer cells and the ability of the cancer cells to receive and sense signals in the environment that help them to resist the cytotoxin. This can cause the cytotoxin to eventually not work.

 

The increased knowledge about these mechanisms is helpful when choosing treatments for people with cancer.