Researchers have found links between an individual's genetics and their response to treatment with chemotherapy. The findings, by researchers at the National Cancer Institute (NCI), part of the National Institutes of Health, and colleagues, show how a genetic variant, located in the SOD2 gene, may affect how a person responds to the chemotherapy drug cyclophosphamide. Cyclophosphamide is used in the treatment of breast and other cancers.
The SOD2 gene produces a key protein that protects cells from damage by molecules known as reactive oxygen species, or free radicals. Reactive oxygen species are produced by normal cellular processes and the action of some chemotherapy drugs. The findings represent the first preliminary evidence pointing toward a mechanism and a potential biomarker for cyclophosphamide resistance in breast cancer patients. The study appeared online in Clinical Cancer Research.
"This study shows how, with the progress of individualized medicine, a diagnostic test may be developed that determines whether a patient has certain genetic variations that may modify the effect of certain chemotherapies," said study author Sharon Glynn, of NCI's Center for Cancer Research.
"In the future, such tests may be used to guide the treatment of patients with the SOD2 variation, ensuring that they receive a therapy that is more effective than cyclophosphamide-based therapies," added senior author Stefan Ambs, also of the Center for Cancer Research.
Most genes in human cells are present in two copies-one inherited from the mother and the other inherited from the father. These gene copies can vary from one another. Some variations in genes play an important role in how a gene is expressed or how its protein product functions.
The variant identified by the researchers in the SOD2 gene affects both the structure and the function of the encoded protein, an enzyme known as manganese superoxide dismutase (MnSOD) and affects the ability of MnSOD to reach its proper location in the cell and its activity level. MnSOD normally functions inside cellular compartments known as mitochondria and helps protect cells from damage caused by reactive oxygen species formed during cellular metabolism. Excessive levels of reactive oxygen species can be toxic to cells. Indeed, some anticancer drugs depend on increased production of reactive oxygen species to kill cancer cells. Furthermore, some studies have indicated that, because MnSOD neutralizes reactive oxygen species, it can modify the effects of chemotherapy drugs. For example, in laboratory and animal models, increased activity of MnSOD protects cells against the toxic effects of doxorubicin, which is a widely used anticancer drug.
In the new study, the research team investigated whether the variation affected survival in two separate groups of women with breast cancer: 248 women in the United States and 340 women in Norway. Some of the women received chemotherapy, and some did not receive chemotherapy. The team first analyzed DNA from the women to determine their genotype, meaning which types of the SOD2 gene they had. The researchers found that, among patients who received chemotherapy, those who had one form had decreased survival and those with another form had the poorest survival. In contrast, the genotype of SOD2 did not affect survival among those who did not receive chemotherapy.
Next, the team looked at the relationship between SOD2 genotype and the type of chemotherapy the women received. The data were analyzed according to which of three types of commonly used chemotherapy drugs were administered: doxorubicin, 5-fluorouracil, or cyclophosphamide. Both doxorubicin and cyclophosphamide generate reactive oxygen species in cancer cells during treatment. The researchers determined that the presence of a particular variant was associated with decreased survival of patients treated with chemotherapy regimens that contained any of the three drugs. However, the most significant effects were found with the drug cyclophosphamide. Women with a distinct variant form of SOD2 and who received cyclophosphamide-containing chemotherapy had the poorest survival.
The research team says more work is necessary to confirm these findings and to examine the precise mechanism by which a genotype influences the response of cancer cells to cyclophosphamide. The team plans to examine the influence of several variations on the resistance to other chemotherapies.
NCI leads the National Cancer Programme and the NIH effort to dramatically reduce the burden of cancer and improve the lives of cancer patients and their families, through research into prevention and cancer biology, the development of new interventions, and the training and mentoring of new researchers.