Talking Glossary of Genetic Terms
Cancer is a group of diseases characterized by uncontrolled cell growth. Cancer begins when a single cell mutates, resulting in a breakdown of the normal regulatory controls that keep cell division in check. These mutations can be inherited, caused by errors in DNA replication, or result from exposure to harmful chemicals. A cancerous tumor can spread to other parts of the body and, if left untreated, be fatal.
Cancer, often known as "the Big C". Cancer is not really one disease, but it's a group of diseases, and what they share in common is the feature of uncontrolled cellular growth. Now, cancer in the body normally begins many, many, many years before your doctor actually gives you a diagnosis. It begins when a single cell collects enough genetic mutations that it results in a breakdown of the normal processes that keep cell division in check. So in its simplest terms, cells go wild, and they just start dividing over and over and over in a very uncontrolled way, eventually resulting in a tumor. The mutations may be inherited. That is, you could've gotten them from your mother or your father's DNA. They can be caused by errors in DNA replication, because the machinery in the cell that's responsible for duplication doesn't always work perfectly. Or it could be because of exposure to harmful chemicals; something that happened that you were exposed to when you were a child that you or your family have absolutely no recognition or recollection of. A cancerous tumor can spread to the other parts of the body, and that's called metastasis. And generally, if left untreated, cancer can often be fatal.
Name: Elaine A. Ostrander, Ph.D.
Occupation: Chief and Senior Investigator, Cancer Genetics Branch; Head, Comparative Genetics Section
Biography: Dr. Ostrander's laboratory maps genes responsible for cancer susceptibility in canines and humans. Cancer is the number one killer of dogs. Studying the major cancers in dogs provides a valuable approach for developing a better-understanding of the development of cancer in humans. The clinical presentation, histology, and biology of many canine cancers closely parallel those of humans, so comparative studies of canine and human cancer genetics should be of significant clinical benefit to both. Dr. Ostrander's laboratory is constructing and using high-density maps of the canine genome to identify genes associated with genetic forms of lymphoma, osteosarcoma and kidney cancer.