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Cancer Genetics
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What is cancer? From Greek “karkinos” for “crab”
A group of diseases caused by loss of cell cycle control Characterized by abnormal, uncontrolled cell growth
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What causes cancer? Begins with 1 or more mutations in a single somatic cell (a.k.a. the “bad apple”) Mutation allows cell to divide when it normally would not Further cell division produces more abnormal cells Somatic cell mutations may be due to: Carcinogens Inheritance Natural mistakes in replication process Genetic predisposition to mutation/lack of mutational repair Carcinogens are substances that cause DNA-level mutations which lead to cancer
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Pre-cancer and cancer progression
Tumor – growth caused by cell escaping normal cell cycle control Benign – tumor grows in one place Malignant (cancerous) – spreading tumor Local invasion by crab-like “arms” Transportation through bloodstream Metastisis (“not standing still”) – process of spreading of abnormal, malignant cells
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Types of Cancer Carcinomas: solid, epithelial tumors (skin, linings of body cavities) Sarcomas: bone, cartilage, muscle and fat tumors Leukemia: cancers of WBC’s produced in the bone marrow Lymphomas: affect WBC’s in the spleen and lymph nodes
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World view of cancer “Environment-only” view of cancer lead to “War on Cancer” and legislation in 1971 Targeting radiation, viruses, & chemicals Fueled by lack of understanding of biology of disease Genes first implicated in cancer in 1976 War on Cancer led by Richard Nixon
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How Cells Become Cancerous: “The Two-Hit Hypothesis”
Somehow a normal cell is turned “cancerous” Scientists believe it takes two “events” for this to happen Examples of events X-rays Sunlight Drugs Chemicals Turning on of genes Virus exposure Oncogenes These are all known as carcinogens
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Approx 1,500,000 new cases of cancer/year
In US: Approx 1,500,000 new cases of cancer/year Approx 500,000 deaths/year
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Most Frequent Cancer Killers
Men Women Lung Lung Prostate Breast Colon/rectum Colon/rectum Of the >200 types of cancers, 85% are CARCINOMAS
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Mutations and Cancer Mutations can occur:
In somatic cells => sporadic cancer only affecting the individual In germline cells => mutations that are inherited Accounts for 10% of cancers usually require second somatic mutation
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Telomeres and Cancer When telomerase is absent, telomeres are not added. Lack of telomeres signals cessation of cell division.
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Telomeres and Cancer Telomerase is the protein and enzyme complex that adds telomere sequences to the ends of chromosomes. Presence of telomerase and telomeres allows cells to pass a cell cycle checkpoint and divide. Cancer cells never lose their telomeres or telomerase
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Cancer Cells Look & Act Different
Divide continually (given space and nutrients) Heritable mutations: cells with mutations have daughter cells which inherit the same mutations. Transplantable Dedifferentiated: cells lose their specialized identity-they become stem cells Different appearance: reflects dedifferentiation
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Cancer Cells Look & Act Different
Lack contact inhibition: will divide in a crowd of cells and pile on top of each other Induce angiogenesis (local blood vessel formation) Increased mutation rate Invasive: squeeze into any space available Metastasize: cells move to new location in the body
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A Little Known Fact Tumor cells have the ability to re-differentiate into any kind of cells. They grow their own blood vessels and feed themselves Tumors have been removed from patients with hair, teeth, and “mini-organs.”
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Types of cancer-causing genes
Types of proteins Mutated function Normal function Type of gene Growth factors Promotes division - abnormal time or cell type Promotes division (proto-oncogene) Oncogene Checkpoint molecules Fails to suppress division Suppresses cell division Tumor suppressor gene Enzymes for mismatch or excision repair Fail to repair DNA mutations Repair DNA mutations DNA repair gene mutation
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Oncogenes Proto-oncogenes are normal versions of genes which promote cell division. Expression at the wrong time or in the wrong cell type leads to cell division and cancer. Proto-oncogenes are called oncogenes in their mutated form. One copy of an oncogenic mutation is sufficient to promote cell division.
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Oncogenes: Over expression of a normal gene
Viruses integrated next to a proto-oncogene can cause transcription when the virus is transcribed. Moving a proto-oncogene to a new location can separate the coding region from regulatory regions of the gene leading to incorrect expression. Moving a proto-oncogene next to a highly transcribed gene can lead to erroneous transcription of the proto-oncogene.
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How cellular oncogenes may cause cancer
Cellular proto-oncogenes play many different roles in normal cells. These roles include: Growth factors (sis, int-2) Receptors for growth factors (trk, fms) Intracellular signalling proteins (ras, src) Transcription factors (fos, myc) These roles all involve growth and cell division
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How cellular oncogenes may cause cancer
A proto-oncogene may promote cancer by keeping its growth factor permanently on. This causes abnormal growth and cell division The oncogene may also become mutant, causing an abnormal protein to form, again affecting the rate of growth and cell division
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How anti-oncogenes prevent cancer
Also known as tumor suppressors, these genes may function by keeping oncogenes turned off, or producing proteins which keep a cell from dividing repeatedly The turning off of a tumor suppressor gene may cause tumor development One gene, termed p53, is known as the master-tumor suppressor gene It is the most commonly altered gene in human cancers, accounting for over 50% of all diagnosed cases
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How anti-oncogenes prevent cancer
P53 normally functions by doing one of three things to abnormal cells 1.) activate genes to promote DNA repair 2.) activate genes to arrest cell division and slow proliferation 3.) activate genes to promote apoptosis (cell death) The turning on of p53 stops an important cell regulator, leading to tumor growth
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Inherited forms of cancer
Many forms of cancer are caused by multiple hits that involve the activation of oncogenes and the inactivation of tumor suppressor proteins (ex. Colo-rectal cancer) People who have inherited forms of cancer are usually heterozygous for defective genes. Any mutation may hurt the good copy of the gene they have, deactivating their tumor suppressor gene, or activating an oncogene
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Chronic Myelogenous Leukemia
Invariably fatal The Philadelphia Chromosome Reciprocal Translocation long arm of HAS 22 < > small part of HSA 9 2 chromosomal changes Translocation causes oncogene activation First found in 2 men in Philadelphia in 1958 – too many immature WBC crowding out healthy cells Researchers at UPenn found Philadelphia chromosome 1972 – UChicacgo researcher used newly developed stains to twll that the Philadelphia chromosome was a translocated chromosome between 9 & 22 1984 – genes sitting next to each other on either side of breakpoints were identified
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CML HSA 9 gene: Abelson oncogene (abl)
HSA 22 gene: breakpoint cluster region (bcr) bcr-abl fusion gene encodes a form of tyrosine kinase Tyrosine kinase is normal produce to abl bcr-abl fusion version active for too long Cell divides for too long Gleevec- drug that binds ATP-binding pocket of tyrosine kinase, preventing the stimulation of cell division The other fusion gene does not affect health With Gleevec treatment, cancer cells cease division (resistance common, however)
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Burkitt's Lymphoma Common in Africa
Viral induced tumor of the immune system (B cell genes) Usually associated with a reciprocal translocation between chromosomes 8 and 14. Evidence for a oncogene (c-myc)
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Tumor suppressor genes
Cancer can be caused by loss of genes that inhibit cell division. Tumor suppressor genes normally stop a cell from dividing. Mutations of both copies of a tumor suppressor gene is usually required to allow cell division.
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Retinoblastoma A rare childhood eye cancer
Alfred Knudson, 1971 examined cases of retinoblastoma in Houston from and determined: One eye or two with tumor Age of diagnosis Relatives with retinoblastoma Number of tumors per eye Observed that 50% of children of an affected parent were affected. Boys and girls were equally frequently affected. Children with bilateral (both eyes) tumors were diagnosed earlier. First detected in 2000 BC In 1800s, survival only assured with eye removal Today, monitoring & non-invasive treatments begin at birth – full recovery common 1/20,000 infants who develop RB About 50% of those inherit susceptibility to RB by harboring a germline mutant allele
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Knudson’s two hit hypothesis
Two mutations are required, one in each copy of the RB gene (recessive expression) For sporadic cases, retinoblastoma is a result of two somatic mutations Mostly single-eye For familial cases, retinoblastoma is inherited as an autosomal recessive mutation followed by a somatic mutation in the normal allele. Can be both eyes, single eye, or none (“skips” generation) 928-aa long protein encoded
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p53 coordinates cell cycle regulation
p53 acts as a cell cycle protein which determines if a cell has repaired DNA damage. If damage cannot be repaired, p53 can induce apoptosis. More that 50% of human cancers involve an abnormal p53 gene Many different types of mutations in p53 gene e.g. colon, breast, bladder, lung, liver, blood, brain, esophagus, skin Rare inherited mutations in the p53 gene cause a disease called Li-Fraumeni syndrome in which family members have many different types of cancer at early ages. P53 = protein with molecular weight 53,000 daltons Vast majority of p53 mutations are somatic Li-Fraumeni syndrome – family members who inherit mutation in p53 gene have 50% chance of developing cancer by age 30, 90% by age 70
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BRCA1, a breast cancer susceptibility gene
BRCA1 – breast cancer predisposition gene 1 tumor suppressor gene Within families a mutation in BRCA1 leads to breast cancer susceptibility, inherited as a dominant trait. One mutation in the BRCA1 gene is inherited. Tumors in people acquire a second mutation in the normal allele of BRCA1. Lack of any functional BRCA1 leads to cancer cells. At the level of the cell, BRCA1 acts in a recessive manner. BRCA1 – breast cancer predisposition gene 1 – tumor suppressor gene Gene encodes large protein that normally resides in nucleus – activates txp of genes that respond to p53 protein (BRCA1 necessary for DNA repair)
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Complexities in genetic counseling for familial breast cancer
Many mutations are known but not all are associated with disease Some are polymorphisms Individuals with inherited predisposition and individuals with sporadic cancer can be found within the same family. BRCA1 and BRCA2 are not fully penetrant. Occasionally individuals with a mutation do not develop cancer. Risk associated with BRCA1 or BRCA2 mutations depends on interaction with other genes & environmental exposures
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Colon cancer results from genetic alterations in multiple genes
Inherited mutations in the APC gene dramatically increase risk of colon cancer 5% of cases are inherited 1/5,000 in US have precancerous colon polyps
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Environment impacts cancer
Exposure to carcinogens Carcinogens in tobacco smoke are correlated with lung cancer incidence. Exposure to radiation Burns from overexposure to sunlight can cause skin cancer. Variation in diet Fatty diets are correlated with increased estrogen and increased breast cancer.
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The Skin Cancer Epidemic
The most common form of human cancer 1 in 5 lifetime risk. Tenfold increase since 1967!!! Like many cancers, your actions can prevent or limit your chances of having this disease……
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