New Genetic Links Could be a Biomarker for Brain Cancer Cell Growth
Highlights
- Genetic differences have been identified that help distinguish between healthy brain cells and brain cancer cells.
- In aggressive neurofibromatosis Type 1, the genetic mutations caused the loss of both the protein product of ATRX and also alternative lengthening of telomeres.
- In pediatric low-grade gliomas, a microRNA called miR-487b, was consistently underexpressed in tumor tissue compared to healthy cells.
Two genetic differences that differentiate brain cancer cells from normal tissue cells have been identified by scientists from Johns Hopkins Institute.
This might offer clues to the behavior of the tumors and offer potential new targets for therapy.
‘A thorough understanding of the fine genetic differences between cancers and healthy tissues will help in developing reliable prognostic strategies and better therapeutic agents.’
Study 1- On Neurofibromatosis Type 1 (NF1)
The first study was published online on September 20th in Acta Neuropathologica. The study was led by Fausto J. Rodriguez, M.D., associate professor of pathology at the Johns Hopkins University School of Medicine and member of the Johns Hopkins Kimmel Cancer Center.
A protein known as ATRX was identified in human brain tumors that arise as part of a genetically inherited condition known as neurofibromatosis type 1 (NF1).
NF1 initially causes benign tumors on nerves which later develops into brain cancer. Most NF1-related malignancies are non-aggressive. But a fraction are "high-grade" and difficult to treat.
The aim of the study was to find out what makes the more aggressive NF1-related tumors genetically different from low grade tumors and normal, healthy cells.
Tumors that affect the nervous system usually have mutations in the ATRX gene. These mutations lead to the production of proteins that maintains the length of telomeres. By maintaining the length of the telomeres, ATRX mutations give cells the ability to endlessly divide which is the hallmark of cancer.
Telomeres are repetitive segments of DNA on the ends of chromosome. In normal cells, their length shorten each time a cell divides. Telomere shortening prevents the excess cell division.
In healthy cells, a protein called telomerase helps to maintain telomere length.
Alternative Lengthening of Telomeres
The role of ATRX mutations in NF1 related brain cancers were studied using samples of high-grade and low-grade gliomas from 27 patients suffering from NF1.
Researchers tested the samples for longer telomeres that were not the product of telomerase. This nontelomerase-associated telomere lengthening is known as alternative lengthening of telomeres or ALT. They also tested for loss of the protein product of ATRX caused by mutations in this gene.
About a third of the 27 samples had ALT and loss of the ATRX protein.
Of the 12 patients with high grade tumors only seven samples showed presence of both ALT and ATRX protein. And of the 14 patients with low-grade tumors, only 2 samples showed the presence of both.
By confirming the role of the mutation through further research, new anti-cancer agents that target cells with ATRX mutations or ALT to limit telomere length, can be developed.
Study 2- On Low-Grade Pediatric Gliomas
The second study was published online on October 14th in Modern Pathology.
According to Fausto J. Rodriguez, unlike many other types of cancerous tumors, low-grade pediatric gliomas appear to have few genetic mutations, leaving the biology of these cancers a mystery.
Researchers studied how the cancer cells regulated the expression of genes or whether they make their constituent proteins.
One way to control expression is through microRNA. These are small pieces of noncoding genetic material that control whether a gene's protein is generated from the DNA blueprints inside cell nuclei.
When researchers analyzed 800 different microRNAs in nine different types of low-grade gliomas or related cancers, a microRNA called miR-487b, which was consistently underexpressed in tumor tissue compared to healthy cells, was identified.
Eventually, physicians might be able to look at the levels of miR-487b and other microRNAs in blood or cerebrospinal fluid to test for the presence of cancer.
Targeting microRNAs directly by altering their levels can also prevent cancer cells from forming tumors.
A thorough understanding of the fine genetic differences between cancers and healthy tissues will help in developing reliable prognostic strategies and better therapeutic agents.
References
- Fausto J. Rodriguez et al. Frequent alternative lengthening of telomeres and ATRX loss in adult NF1-associated diffuse and high-grade astrocytomas. Acta Neuropathologica; (2016) DOI: 10.1007/S00401-016-1619-0
- Fausto J. Rodriguez et al. MicroRNA profiling of low-grade glial and glioneuronal tumors shows an independent role for cluster 14q32.31 member miR-487b.Modern Pathology; (2016) doi: 10.1038
Source: Medindia
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APA
Dr. Meenakshy Varier. (2016, December 03). New Genetic Links Could be a Biomarker for Brain Cancer Cell Growth. Medindia. Retrieved on Sep 19, 2024 from https://www.medindia.net/news/healthwatch/new-genetic-links-could-be-a-biomaker-for-brain-cancer-cell-growth-165830-1.htm.
MLA
Dr. Meenakshy Varier. "New Genetic Links Could be a Biomarker for Brain Cancer Cell Growth". Medindia. Sep 19, 2024. <https://www.medindia.net/news/healthwatch/new-genetic-links-could-be-a-biomaker-for-brain-cancer-cell-growth-165830-1.htm>.
Chicago
Dr. Meenakshy Varier. "New Genetic Links Could be a Biomarker for Brain Cancer Cell Growth". Medindia. https://www.medindia.net/news/healthwatch/new-genetic-links-could-be-a-biomaker-for-brain-cancer-cell-growth-165830-1.htm. (accessed Sep 19, 2024).
Harvard
Dr. Meenakshy Varier. 2016. New Genetic Links Could be a Biomarker for Brain Cancer Cell Growth. Medindia, viewed Sep 19, 2024, https://www.medindia.net/news/healthwatch/new-genetic-links-could-be-a-biomaker-for-brain-cancer-cell-growth-165830-1.htm.