Those who inherit a mutant allele of the RB1 tumor-suppressor gene are at risk for developing a bone cancer called osteosarcoma. You suspect that in these cases, osteosarcoma requires a mutation in the second RB1 allele, and you have cultured some osteosarcoma cells and obtained a cDNA clone of a normal human RB1 gene. A colleague sends you a research paper revealing that a strain of cancer-prone mice develops malignant tumors when injected with osteosarcoma cells, and you obtain these mice. Using these three resources, what experiments would you perform to determine:
(a) Whether osteosarcoma cells carry two RB1 mutations
(b) Whether osteosarcoma cells produce any pRB protein
(c) If the addition of a normal RB1 gene will change the cancer-causing potential of osteosarcoma cells?

As part of a cancer research project, you have discovered a gene that is mutated in many metastatic tumors. After determining the DNA sequence of this gene, you compare the sequence with those of other genes in the human genome sequence database. Your gene appears to code for an amino acid sequence that resembles sequences found in some serine proteases. Conjecture how your new gene might contribute to the development of highly invasive cancers.

A study by Bose and colleagues (1998). Blood 92:3362-3367] and a previous study by Biernaux and others (1996). Bone Marrow Transplant 17:(Suppl. 3) S45–S47] showed that BCR-ABL fusion gene transcripts can be detected in 25 to 30 percent of healthy adults who do not develop chronic myelogenous leukemia (CML). Explain how these individuals can carry a fusion gene that is transcriptionally active and yet does not develop CML.