Deck 18: Cancer Genetics and Genomics

A)adds material to the ends of chromosomes with each cell division.
B)is not expressed and telomere tips erode with each division.
C)removes telomere tips with each division.
D)repairs double strand breaks in DNA.

A)recessive or dominant mutation in a somatic cell.
B)recessive or dominant germline mutation.
C)mutation in a sperm or oocyte.
D)exposure to a cancer-causing virus.

A)contact inhibited.
B)transplantable.
C)invasive.
D)immortal.

A)two
B)three
C)four
D)five

A)tumor cells,abnormal daughter cells,normal cells,and more cancer stem cells.
B)more cancer stem cells only.
C)healthy stem cells and normally differentiated cells.
D)invasive cells and metastatic malignant cells.

A)two gene variants,one dominant and one recessive,and no environmental input.
B)specific combinations of alleles and an environmental factor.
C)specific combinations of an environmental factor and one dominant gene variant.
D)genes that cause death before birth.

A)DNA replication.
B)the formation of mitochondria.
C)cell membrane structure.
D)the cell cycle.

A)somatic
B)sporadic
C)germline
D)benign

A)a germline mutation.
B)two somatic mutations in the same lung cell.
C)exposure to carcinogens.
D)stress from caring for her husband,who had a spinal cord injury.

A)heritable.
B)angiogenic.
C)oncogeniC.
D)dedifferentiateD.

A)benign
B)gateway
C)passenger
D)driver

A)invasiveness.
B)angiogenesis.
C)metastasis.
D)dedifferentiation.

A)metastasis.
B)malignancy.
C)carcinogenesis.
D)microstasis.

A)contact inhibited.
B)transplantable.
C)benign.
D)invasive.

A)all stem cells are also cancer cells.
B)cells may become cancerous by expressing "stemness" genes.
C)stem cells rescue cells that have become cancerous.
D)both stem cells and cancer cells have inactivated telomerase.

A)how old a person is and whether he or she smokes.
B)whether a person has had cancer before and its location in the body.
C)location of the cancerous cell in the tissue and how specialized the cell is.
D)whether or not a person's relatives have cancer.

A)tumor suppressors.
B)transcription factors.
C)proto-oncogenes.
D)oncogenes.

A)passenger
B)driver
C)somatic
D)germline

A)HER2
B)RB1
C)E-cadherin
D)CML

A)act early in the disease.
B)act late in the disease.
C)acted on an initial cell and then reverted to wild type.
D)entered the cells on the same type of virus.

A)translocation that moves a proto-oncogene next to an antibody gene.
B)point mutation in a proto-oncogene.
C)virus that inserts next to a proto-oncogene.
D)deletion of an anti-oncogene.

A)Heterocyclic aromatic amines (HAs)
B)Cruciferous vegetables such as broccoli
C)Red meats
D)Baked potatoes

A)a primary tumor has spread through the blood stream.
B)a primary tumor is yet to invade healthy tissue.
C)all rapidly dividing cells are targeted by the surgery.
D)a patient has multiple tumors spread across his or her body.

A)she has a deletion in the BRCA1 gene that is found in African-American and Ashkenazi Jewish women.
B)her affected breast cells have many extra receptors for epidermal growth factor,and so they receive too many signals to divide.
C)her affected cells have extra genes for epidermal growth factor,sending signals for the cells to divide too frequently.
D)a translocation occurred between chromosomes 7 and 8,generating and activating a breast-specific oncogene.

A)DNA repair gene
B)tumor suppressor gene
C)oncogene
D)teratoma

A)fetal cells that remain in a child or adult,dividing too frequently.
B)continual expression of the telomerase gene,which keeps cells dividing.
C)deletion of cell cycle checkpoint genes.
D)failure to repair damaged DNA,allowing the cell to continue dividing.

A)a proto-oncogene.
B)a fusion protein that acts like a transcription factor,activating cell cycle control genes.
C)a protein that increases growth factor production.
D)a fusion protein that deregulates the cell cycle of myeloid white blood cells.

A)heart cells divide as frequently as do cells in the skin.
B)being exposed to cigarette smoke in the uterus causes lung cancer in infants.
C)cells in a child's kidney divide as frequently as if they were still in a fetus.
D)deletion of the retinoblastoma gene causes an eye tumor.

A)it is translocated next to a highly expressed gene.
B)it is translocated next to a gene that is not being expressed.
C)checkpoints are added to the cell cycle.
D)the cell cycle temporarily runs backwards.

A)APC.
B)TGF.
C)p53.
D)PRL-3.

A)regulates mitosis and meiosis.
B)regulates its own mutation rate.
C)can destabilize the genome when mutant.
D)regulates apoptosis and mitosis.

A)X-linked.
B)incompletely penetrant.
C)translocations.
D)somatic mutations.

A)a translocation of a tumor suppressor gene.
B)an inversion involving a tumor suppressor gene.
C)a deletion of a tumor suppressor gene.
D)activation of a proto-oncogene by a virus.

A)a germinal mutation in one RB allele and no mutation in the other allele.
B)a somatic mutation in each copy of the RB gene in the same cell.
C)a germinal mutation in one RB allele and a somatic mutation in the other allele.
D)a somatic mutation in one of the RB genes in the same area of the retina of one eye.

A)stimulating telomerase activity.
B)stimulating cells to return to a stem-like state of specialization.
C)inhibiting kinases based on genetic information.
D)replacing the nuclei in cancer cells.

A)simplicity.
B)heterogeneity.
C)homogeneity.
D)heterozygosity.

A)slow cancer spread and convert it to a chronic,manageable condition.
B)genetically engineer human beings,making them cancer resistant.
C)suppress cell division and increase the longevity of human cells.
D)genetically engineer cancer cells,making them benign.

A)Chemotherapy
B)Surgery
C)Liquid biopsy
D)Tyrosine kinase inhibitors

A)surgery,chemotherapy,and radiation.
B)nutritional therapy and physical therapy.
C)monoclonal antibodies and cytokines.
D)gene therapy.