News — New research in colorectal cancers directed by investigators at the suggests that expression of transcription factors — proteins that help turn specific genes on or off by binding to nearby DNA — may play a central role in the degree of DNA methylation across the genome, contributing to the development of different subtypes of these cancers. Methylation is a process in which certain chemical groups attach to areas of DNA that guide genes’ on/off switches. Studying the expression of these transcription factors in patients with colorectal cancers could reveal biomarkers to help determine overall survival in people with a subgroup of colorectal cancers who generally have better survival rates and, importantly, respond better to immune checkpoint therapy — a type of immunotherapy that releases restraints that cancer cells place on the immune response — and other treatments. Similar patterns of transcription factor expression could be seen by the researchers even in precancerous polyps, and could potentially be used by physicians to determine which patients need closer follow-up to prevent cancer development.
A description of the work was published online July 24 in the journal .
Aberrant DNA methylation is a well-known phenomenon occurring in cancers, explains senior study author , an associate professor of oncology at the Johns Hopkins Kimmel Cancer Center, but the degree of DNA methylation varies in cancers of the same tissue type. Some colon and other cancers have a very high degree of DNA methylation gains while others have much lower frequency of DNA methylation gains, he says. Traditionally, these have been described in an area of the genome known as a promoter region, which helps launch the transcription process. The exact mechanisms underlying these changes have not been clear.
In a series of laboratory studies of genetic material taken from tubular adenomas (precancerous polyps in the colon) and colon tumors, the researchers linked cancer-specific transcription factor expression alterations to methylation alterations in colorectal cancers and their premalignant precursor lesions, which provided insights into the origins and evolution of different molecular subtypes of colorectal cancers.
Specifically, researchers observed that some regions of the genome undergoing increased methylation tend to have binding sites for transcription factors that are downregulated, or have low expression. In some types of colon cancer, based on the types of genetic alterations associated with the cancer, transcription factors are upregulated or have higher expression.
The findings suggest that cancer-specific methylation differences potentially evolve due to perturbation in the activity or expression of transcription factors. Similar changes in DNA methylation patterns were observed in precancerous polyps.
“These studies highlight that the transcription factor expression changes and corresponding DNA methylation changes are early events during tumor development,” says lead study author Yuba Bhandari, Ph.D., a research associate at the Johns Hopkins Kimmel Cancer Center. “As polyps do not carry all of the key genetic changes typically found in full-blown cancer cells, the transcription factor changes may represent the earliest molecular regulators of precancerous cells, with profound impact on the genome-wide DNA methylation changes.”
The specific set of transcription factors identified in the study may help in stratifying colorectal cancer prognosis, Easwaran adds.
“This is particularly important, because multiple studies have shown that a certain subtype of colorectal cancers responds best to immune checkpoint blockade therapies, while others may not fare as well,” he says. “Expression profiling of relevant transcription factors may help develop better therapeutic strategies across subtypes of colorectal cancers.”
Additional study co-authors included Rachael Powers, Sehej Parmar, Sara-Jayne Thursby, Ekta Gupta, Ozlem Kulak, Kurtis Bachman and Stephen Baylin of Johns Hopkins. Additional investigators from Janssen Research and Development in Pennsylvania and in Belgium contributed.
The work was supported by the National Institutes of Health grants R01CA230995 and R01CA229240; National Institute of Environmental Health Sciences grant R01ES011858; National Cancer Institute grant R21CA212495; Sam Waxman Research Foundation and National Institute on Aging grant U01AG066101; Janssen Initiative; Commonwealth Grant; and Grollman Glick Scholarship.
Baylin consults for MDxHealth. Methylation-specific PCR is licensed to MDxHealth in agreement with The Johns Hopkins University. Baylin and JHU are entitled to royalty shares received from sales. These arrangements have been reviewed and approved by The Johns Hopkins University in accordance with its conflict-of-interest policies.