Exam 4: Cancer

Question 1

Epigenetic changes

Answer 1

process that alters gene activity without changing DNA sequence and leads to modifications that can be transmitted to the cell’s progeny - can lead to cancer

Question 2

proto-oncogene

Answer 2

gene associated with control of cell division, act to promote cell growth

Question 3

Oncogene

Answer 3

mutated proto-oncogene
excessively active in growth promotion - enhanced gene expression, production of hyperactive protein product, etc.
preserves activity of protein but results in excessive protein production or disrupts normal control of function
typically dominant mutation

Question 4

Tumor suppressor genes

Answer 4

normally function to inhibit cell growth and division

mutations that inactivate tumor suppressor genes allow for inappropriate cell division

Question 5

Caretaker genes

Answer 5

protect integrity of genome
ie DNA repair enzymes
when inactivated by mutation cells accumulate damaged DNA at a higher rate

Question 6

Metastatic cancer

Answer 6

cancer that spreads to other parts of body

Question 7

6 capabilities that cell must acquire to be transformed into invasive tumor

Answer 7

Self-sufficiency in growth signals
Insensitivity to antigrowth signals
Evading apoptosis
Limitless replicative potential
Sustained angiogenesis
Tissue invasion and metastasis

Question 8

Self-sufficiency in growth signals

Answer 8

oncogene products act to send inappropriate growth signals

Question 9

Insensitivity to antigrowth signals

Answer 9

Loss of tumor suppressor fuction leads to loss of sensitivity to antigrowth signal

Question 10

Evading apoptosis

Answer 10

needs to block cell death to become cancerous

mutations of components of pathway that lead to apoptosis

Question 11

Limitless replicative potential

Answer 11

need to not senescence - which limits replication

Reactivates telomerase to lead to unlimited cell division potential

Question 12

Sustained angiogenesis

Answer 12

cells achieve ability to promote and sustain angiogenesis (growth of blood vessels) to deliver oxygen and nutrients to tumor

Question 13

Tissue invasion and metastasis

Answer 13

changes in expression of cell surface molecules leads to ability to migrate & invade nearby tissues
increase in expression of proteases that degrade extracellular matrix

Question 14

dominant mutation

Answer 14

only one allele needs to be mutated for effect to be seen

i.e. gain of function like oncogenic

Question 15

ErbB1/HER 1

Answer 15

receptor for epidermal growth factor (EGF), tyrosine kinase
activates MAP kinase cascade & cell growth/proliferation
proto-oncogene - mutation converts to consitutively active forms

Question 16

ErbB1 constitutively active mutation

Answer 16

truncates protein & removes extracellular binding domain - activation of kinase domain
signal to grow delivered in absence of appropriate stimulus

Question 17

HER2 constitutively active mutation

Answer 17

point mutation allows receptor dimerization and autophosphorylation in absence of ligand

Question 18

Overexpression of HER2 protein seen in

Answer 18

many breast cancers

Overabundance of receptors allows cell to respond to very low concentrations of EGF = active more often

Question 19

Ras constitutively active mutation

Answer 19

dominant mutations that favor GTP binding
Ras turned on without ligand binding
Very common in human cancers, especially pancreas & intestinal

Question 20

c-Fos and c-Myc

Answer 20

transcription factors that activate genes needed for cell cycle progression (cyclins)
mutations stabilize mRNA/encoded protein, stays longer, inappropriate activation of growth promoting genes

Question 21

Burkitt’s lymphoma

Answer 21

caused by inappropriate Myc activity
translocation moves c-myc gene from chromosome 8 to chromosome 14
myc gene now continually expressed (close to new promotor regions) and B-cell becomes cancerous

Question 22

recessive mutation

Answer 22

damage to both alleles of gene required to give rise to unregulated cell proliferation
typically found in tumor suppressor genes

Question 23

two hit model

Answer 23

same gene in same cell needs to get both alleles mutated for affect to be seen - somatic mutation - more rare

Question 24

Retinoblastoma

Answer 24

Hereditary: inherit one mutated copy of RB1 gene, second somatic mutation results in retinal cell with no functional Rb protein = tumor formation more likely because lack of inhibition of cell division cyclins
Tumors develop in both eyes
Sporadic: two separate mutations required in cell

Question 25

Mutations in p53

Answer 25

most common genetic alterations found in human cancers (over 50%)
Absence of p53 causes cells to divide with many problems (can’t activate p21 used in cell cycle arrest or signal apoptosis of damaged cell)
homotetramer - mutation in one allele will reduce p53 activity

Question 26

Li-Fraumeni syndrome

Answer 26

heritable, increased susceptibility to a variety of cancers
dominant inheritance, early onset of tumors, presence of multiple tumors and multiple affected family members
Inheritance of mutant TP53 allele - disrupts function of p53 tetramer & cells with damaged DNA free to divide & accumulate more damage, leading to tumor development

Question 27

HPV-induced cervical cancer

Answer 27

caused by HPV
virus produces two proteins, E6 & E7
E6 inhibits p53 by binding to it
E7 inhibits Rb by binding to it (and displacing E2F which increases cell proliferation)
E6 & E7 induce cell proliferation in absence of mutations

Question 28

Neurofibromatosis 1

Answer 28

due to loss of function mutations in NF1 gene - codes for neurofibromin, which accelerates rate at which Ras hydrolyses bound GTP to inactive GDP
Loss of NF1 means slower inactivation of Ras and longer Ras signaling (increased cell proliferation)
causes hyperpigmented skin patches, neurofibromas, benign growths on iris
Loss of both alleles develop neurofibromatosis - tumors of sheath cells that surround nerves

Question 29

HBOC (hereditary breast and ovarian cancer)

Answer 29

inherited autosomal dominant
mutations in BRCA1 and BRCA2 lead to increased risk of breast and ovarian cancer
Loss of BRCA1/BRCA2 function impedes delivery of effector proteins to sites of double-stranded DNA breaks = accumulation of mutations

Question 30

BRCA1 & BRCA2

Answer 30

involved in HBOC
repair of double-stranded DNA breaks through homologous recombination (both) and other repair pathways/checkpoints (BRCA1)
Deliver various effector proteins to sites of double-stranded DNA breaks
lack of function allows for accumulation of mutations

Question 31

hypoxia

Answer 31

stimulates oxygen-sensitive transcription factor HIF-1-alpha-beta
pairing of alpha/beta HIF-1 promotes angiogenesis & encoding of vascular endothelial growth factor (VEGF)

Question 32

VEGF (vascular endothelial growth factor)

Answer 32

production results in development of angiogenic gradient, stimulating growth of new blood vessels
activated by HIF-1 alpha/beta

Question 33

E-cadherin

Answer 33

hold epithelial cells together

in cancer cells breaks down and cells are freed from primary tumor

Question 34

matrix metalloproteases (MMPs)

Answer 34

secreted by tumor

breaks down basement membrane

Question 35

intravasation

Answer 35

tumor cells enter circulation

Question 36

extravasation

Answer 36

exit from bloodstream
begins with adhesion to and digestion of blood vessel wall
then cells migrate through extracellular matrix & can divide

Question 37

adenoma

Answer 37

benign tumor

Question 38

carcinoma

Answer 38

malignant tumor

Question 39

FAP (familial adenomatous polyposis)

Answer 39

inherited condition from mutation of APC gene, which encodes for tumor suppressor APC - downregulates growth promoting signals that come through WNT pathway
results in thousands of adenomatous polyps in colon
Colorectal adenocarcinoma develops in untreated pts by middle age

Question 40

Beta-catenin

Answer 40

Activated by WNT signals (which free it from APC destruction complex)
free beta-catenin translocates into nucleus, where it increases transcription of genes including cyclin D & Myc = upregulated cellular proliferation

Question 41

APC destruction complex

Answer 41

APC binds to beta-catenin and results in beta-catenin destruction
absence of APC causes constitutive activation of WNT pathway and beta-catenin not destroyed/enter nucleus/ cell proliferation

Question 42

WNT pathway

Answer 42

WNT signals inhibition of APC/beta-catenin destruction complex and cell proliferation by beta-catenin
Absence of WNT signal prevents beta-catenin from entering nucleus

Question 43

Mutation in APC gene

Answer 43

leads to FAP
constitutive activation of WNT pathway without APC & beta-catenin upregulation of cell proliferation (mutations in Ras, p53, etc lead to malignant tumors)
part of machinery that attaches microtubules to chromosomes in mitosis - loss of function can cause aneuploidy & genomic mutations
Loss of APC function key to colon cancer development

Question 44

HNPCC (hereditary nonpolyposis colorectal carcinoma)

Answer 44

defects in pathway of DNA mismatch repair - MSH2 or MLH1
MSH2- identifies DNA containing mismatch errors
MLH1- repairs errors
Inherit one defective copy from parent - other copy lost, DNA mismatch repair defective & mutations accumulate at increased rate
Tend to accumulate mutations in microsatellite repeats - prone to replication errors normally repaired by mismatch repair
Results in mutations of Bax - allow for survival of genetically abnormal cells that would normally be destined for death by apoptosis

Question 45

Mutations in Bax

Answer 45

Seen in people with HNPCC

mutations in Bax allow for survival of genetically abnormal cells that would usually be destined for death by apoptosis

Question 46

chronic myeloid leukemia

Answer 46

translocation between chromosomes 9 & 22 - Philadelphia chromosome
fusion of BCR & ABL1 genes results in hybrid Bcr-Abl tyrosine kinase = cell proliferation

Question 47

Bcr-Abl tyrosine kinase

Answer 47

constitutively active & stimulates cell proliferation

Question 48

imatinib mesylate (Gleevec)

Answer 48

inhibitor of Bcr-Abl kinase to treat CML (chronic myeloid leukemia)

Question 49

nilotinib (Tasigna) & dasatinib (Sprycel)

Answer 49

Bcr-Abl kinase inhibitors

Question 50

Tamoxifen

Answer 50

interfers with estrogen receptor function
can be used to treat ER+ cancers (breast cancers taht express high levels of estrogen receptor)
deprives cells of estrogen signal that stimultes their cell growth

Question 51

Trastuzumab (Herceptin)

Answer 51

antibody that binds to the extracellular domain of HER2/Neu and has anti-tumor effects - inhibits HER2/Neu tyrosine kinase activity (cell growth via MAP kinase cascade)
Kills cell

Question 52

rituximab

Answer 52

treats non-Hodgkin’s lymphoma (antibodies interact with antigens on tumor cell surfaces & lead to cell death)

Question 53

bevacizumab

Answer 53

treats colon and lung cancer (antibodies interact with antigens on tumor cell surfaces & lead to cell death)

Question 54

cetuximab and panitumumab

Answer 54

treats colorectal cancer and head and neck cancer (antibodies interact with antigens on tumor cell surfaces & lead to cell death)