BRCA mutation

genetics
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mutation
BRCA1
BRCA2
Top Questions

What are BRCA mutations?

Who discovered BRCA1 and BRCA2?

How do BRCA mutations affect cancer risk?

What is the prevalence of BRCA mutations?

What are some ethical concerns related to BRCA mutations?

BRCA mutation, alteration in one of the BRCA (breast cancer) genesBRCA1 or BRCA2—that hinders the ability of cells to repair DNA damage, leading to an increased risk of certain cancers. BRCA1 and BRCA2 normally act as tumor suppressor genes, having a critical role in DNA repair and in maintaining the integrity of a cell’s genetic material. Mutations in BRCA1 and BRCA2 are especially common in breast cancer, ovarian cancer, and prostate cancer and occur at increased prevalence in individuals who have a family history of these cancers.

Discovery of BRCA1 and BRCA2

A genetic link to breast cancer was first demonstrated in 1990, by American geneticist Mary-Claire King. Her work led to the discovery in 1994 of BRCA1, which became the first gene associated with a hereditary form of breast cancer. Shortly thereafter, in 1995, BRCA2 was discovered by a team of scientists led by geneticist Michael Stratton at the Institute of Cancer Research in the United Kingdom. By the following year, tests to detect alterations in the two genes had become available for breast cancer screening, opening the way to personalized risk assessment and targeted prevention strategies for high-risk individuals, such as those with a family history of breast cancer.

Prevalence

The prevalence of BRCA mutation varies according to several factors, ethnicity in particular. Specific variants in the genes occur as a result of the so-called founder effect, whereby certain mutations recur in geographically isolated or culturally distinct populations in which the mutation was carried by an ancestor. In the general population, mutations in the genes occur in roughly 1 in 400 individuals (0.25 percent of populations) worldwide. By comparison, founder mutations that have been documented in individuals of Ashkenazi Jewish descent are significantly more frequent: within this ethnic group about 1 in 40 individuals (2.5 percent of the population) carry a mutation in one of the two genes. Founder mutations have been identified in other historically isolated populations, including in ethnic groups in the Netherlands, Norway, and Sweden and in certain Spanish-descended populations, especially among persons with Sephardic Jewish ancestry.

Impact on cancer risk

Breast cancer is the most common cancer affecting women worldwide, though the risk of developing it varies substantially, depending on environmental and hereditary factors. For example, among American women in the general population, about 12 to 13 percent will develop breast cancer in their lifetime. However, for women who inherit mutations in BRCA1, some 55 to 65 percent will have developed breast cancer by age 70; among women with a BRCA2 mutation, roughly 45 percent will develop breast cancer. In addition, 30 to 40 percent of inherited BRCA1 mutation carriers and 25 percent of BRCA2 mutation carriers who survive breast cancer will develop the disease contralaterally (in the opposite breast) within two decades of their initial cancer diagnosis. This likelihood is significantly higher than the risk of contralateral malignancy among breast cancer survivors without BRCA mutation.

BRCA mutation also greatly increases the risk of other cancer types. For example, whereas women in the general population have a lifetime ovarian cancer risk of about 1.1 percent, those with alterations in BRCA1 experience a risk of 39 to 58 percent, and those with a BRCA2 mutation have an 11 to 29 percent risk. For male breast cancer, changes in BRCA1 or BRCA2 are associated with as much as a 1.2 or 7.1 percent risk, respectively, by age 70; by comparison, risk of male breast cancer in the general population is 0.1 percent. In the case of prostate cancer, the risk among men in the general population is roughly 10 percent. However, among men with BRCA1 mutations, the risk is 7 to 26 percent, and, among those with BRCA2 mutations, the risk is as much as about 60 percent by age 80. Impacts on pancreatic cancer are also substantial, with a 5 percent risk imparted by BRCA1 alterations and a 5 to 10 percent risk from changes in BRCA2. Pancreatic cancer risk in the general population is about 1 percent.

Personal, social, and ethical significance

The discovery of BRCA mutations and the ability to screen for them have had important impacts not only on medicine but also on ethical considerations involving genetic privacy, on personal identity, and on societal awareness of genetic testing. For example, screening for BRCA mutations, in providing information about cancer risk, has empowered individuals, giving them the ability to engage in proactive decision-making about their personal health. With knowledge of test results, individuals can make informed decisions regarding frequency of screening, lifestyle modifications, and prophylactic surgeries, such as mastectomy. However, individuals who choose to undergo mastectomy or other prophylactic surgeries that alter physical appearance may subsequently struggle with body image.

BRCA mutations and screening have also given rise to an assortment of social and ethical concerns, particularly regarding the lack of treatment options available for persons with positive test results and the disclosure of information, such as to family members, employers, and insurers. In the United States the Genetic Information Nondiscrimination Act (GINA; 2008) was implemented to protect genetic privacy and to prevent discrimination based on genetic information. Similar laws exist in other parts of the world, such as the Charter of Fundamental Rights in the European Union. Furthermore, BRCA mutations have raised ethical questions about reproductive decisions, such as the use of preimplantation genetic diagnosis or in vitro fertilization, which may prevent the inheritance of mutations by offspring but may also be viewed as genetic selection.

Kara Rogers