E to cancer cells. Cells then become dependent for survival on the signaling that results from the activating mutation. Identifying and targeting these mutations should, therefore, lead to death in cancer cells. A striking example of this is the BCR-ABL translocation in chronic myelogenous leukemia (CML). The BCR-ABL gene is formed via a fusion between chromosome 9 and chromosome 22. The resulting gene product is a fusion protein combining the breakpoint cluster region (BCR) with a constitutively active Abl kinase. It is an early event in the course of CML and the newly combined chromosome 9:22 (also known as the Philadelphia chromosome) is present in all transformed cells in CML [68]. There are now several drugs targeting the Bcr-Abl protein and its kinase activity. When GSK343 site individuals with CML develop resistance to these drugs, it is due to secondary mutations in BCR-ABL, not compensation byAuthor Manuscript Author Manuscript Author Manuscript Author ManuscriptSemin Oncol. Author manuscript; available in PMC 2017 February 01.Ryan and Faupel-BadgerPageanother pathway, suggesting that CML is addicted to the specific BCR-ABL oncogene and not evolving to become reliant on altered signaling from other molecules [69]. In CML, the BCR-ABL mutation is the initiating genetic change in the course of the disease, providing an early marker and target for intervention. This example brings up several questions spanning the areas of cancer treatment and cancer prevention. Would it be possible to identify the “driver” and “passenger” mutations in premalignant conditions? Are these concepts and that of oncogene addiction even valid in a premalignant context? Could this information be used to develop successful chemopreventive interventions? Further detailed characterization is needed to understand the somatic landscape of premalignant conditions. It will not be sufficient to study isolated mutations in genes such as EGFR, KRAS and HER-2. As mentioned above, HER-2 is overexpressed in 40 ?0 of DCIS lesions and is amplified in approximately 30 of breast cancers [70]. What this suggests is that the cellular context, timing, and order of genetic mutations are key components classifying a lesion as benign, premalignant or cancerous. Studies need to be conducted in a prospective manner so that we can learn which molecular features predict those that will progress to cancer, and moreover, which mutations might be targets for chemoprevention. We acknowledge, however, that these goals will not be easy to attain. Tissue biopsies will be needed to conduct these studies, and while powerful, whole genome sequencing technologies will need greater sample input than what is often available. There is the possibility of pushing the boundaries of technology even further to detect circulating tumor cells order Metformin (hydrochloride) sloughed off from developing lesions, and to merge that with next generation sequencing to detect specific mutations that can portend a developing malignant tumor. Benign tumors from various lineages display a range of mutated genes, many of which may be considered as driver genes in a cancer context [71]; thus the timing of mutations and the collective repertoire of somatic changes may be the key to knowing whether a lesion is benign or whether it has a high probability of progression to malignancy. Will we be able to define a mutational spectrum that is associated with risk of colorectal cancer in patients with inflammatory bowel disease? And if so, can we detect such mu.E to cancer cells. Cells then become dependent for survival on the signaling that results from the activating mutation. Identifying and targeting these mutations should, therefore, lead to death in cancer cells. A striking example of this is the BCR-ABL translocation in chronic myelogenous leukemia (CML). The BCR-ABL gene is formed via a fusion between chromosome 9 and chromosome 22. The resulting gene product is a fusion protein combining the breakpoint cluster region (BCR) with a constitutively active Abl kinase. It is an early event in the course of CML and the newly combined chromosome 9:22 (also known as the Philadelphia chromosome) is present in all transformed cells in CML [68]. There are now several drugs targeting the Bcr-Abl protein and its kinase activity. When individuals with CML develop resistance to these drugs, it is due to secondary mutations in BCR-ABL, not compensation byAuthor Manuscript Author Manuscript Author Manuscript Author ManuscriptSemin Oncol. Author manuscript; available in PMC 2017 February 01.Ryan and Faupel-BadgerPageanother pathway, suggesting that CML is addicted to the specific BCR-ABL oncogene and not evolving to become reliant on altered signaling from other molecules [69]. In CML, the BCR-ABL mutation is the initiating genetic change in the course of the disease, providing an early marker and target for intervention. This example brings up several questions spanning the areas of cancer treatment and cancer prevention. Would it be possible to identify the “driver” and “passenger” mutations in premalignant conditions? Are these concepts and that of oncogene addiction even valid in a premalignant context? Could this information be used to develop successful chemopreventive interventions? Further detailed characterization is needed to understand the somatic landscape of premalignant conditions. It will not be sufficient to study isolated mutations in genes such as EGFR, KRAS and HER-2. As mentioned above, HER-2 is overexpressed in 40 ?0 of DCIS lesions and is amplified in approximately 30 of breast cancers [70]. What this suggests is that the cellular context, timing, and order of genetic mutations are key components classifying a lesion as benign, premalignant or cancerous. Studies need to be conducted in a prospective manner so that we can learn which molecular features predict those that will progress to cancer, and moreover, which mutations might be targets for chemoprevention. We acknowledge, however, that these goals will not be easy to attain. Tissue biopsies will be needed to conduct these studies, and while powerful, whole genome sequencing technologies will need greater sample input than what is often available. There is the possibility of pushing the boundaries of technology even further to detect circulating tumor cells sloughed off from developing lesions, and to merge that with next generation sequencing to detect specific mutations that can portend a developing malignant tumor. Benign tumors from various lineages display a range of mutated genes, many of which may be considered as driver genes in a cancer context [71]; thus the timing of mutations and the collective repertoire of somatic changes may be the key to knowing whether a lesion is benign or whether it has a high probability of progression to malignancy. Will we be able to define a mutational spectrum that is associated with risk of colorectal cancer in patients with inflammatory bowel disease? And if so, can we detect such mu.