CH3 - Principles of Neoplasia

Question 1

Neoplasia is

Answer 1

new tissue growth that is unregulated, irreversible, and monoclonal

Question 2

What features distinguish neoplasia from hyperplasia and repair?

Answer 2

unregulated, irreversible, and monoclonal

Question 3

Monoclonal means

Answer 3

that the neoplastic cells are derived from a single mother cell

Question 4

Clonality can be determined by?

Answer 4

glucose-6-phosphate dehydrogenase (G6PD) enzyme isoforms.

Question 5

Multiple isoforms

Answer 5

G6PDA, G6PDb, and G6PDc exist; only one isoform is inherited from each parent.

Question 6

lyonization

Answer 6

In females, one isoform is randomly inactivated in each cell by lyonization

Question 7

G6PD is present on what chromosome

Answer 7

X

Question 8

Normal ratio of active isoforms in cells of any tissue is

Answer 8

1:1 (e.g 50% of cells have G6PDa , and 50% ofcells have G6PDG)

Question 9

In hyperplasia what happens to the ratio?

Answer 9

1:1 ratio is maintained in hyperplasia, which is polyclonal (cells are derived from multiple cells).

Question 10

In neoplasia what can be said about the isoform?

Answer 10

Only one isoform is present in neoplasia, which is monoclonal

Question 11

Clonality can also be determined by

Answer 11

androgen receptor isoforms, which are also present on the X chromosome.

Question 12

Clonality of B lymphocytes is determined by

Answer 12

immunoglobulin (Ig) light chain phenotype.

Question 13

Ig is comprised of

Answer 13

heavy and light chains.

Question 14

Each B cell expresses

Answer 14

light chain that is either kappa or lambda.

Question 15

Normal kappa to lambda light chain ratio is

Answer 15

3:01

Question 16

Kappa to lambda ratio in hyperplasia

Answer 16

This ratio is maintained in hyperplasia, which is polyclonal

Question 17

kappa to lambda ratio in lymphoma?

Answer 17

Ratio increases to > 6:1 or is inverted (kappa to lambda ratio = 1:3) in lymphoma, which is monoclonal

Question 18

Neoplastic tumors are

Answer 18

benign or malignant

Question 19

Benign tumors

Answer 19

remain localized and do not metastasize

Question 20

Malignant tumors

Answer 20

(cancer) invade locally and have the potential to metastasize.

Question 21

Tumor nomenclature is based on

Answer 21

lineage of differentiation (type of tissue produced) and whether the tumor is benign or malignant

Question 22

What benign growths result from the epithelium?

Answer 22

Adenoma, papilloma

Question 23

What malignant growths result from the epithelium?

Answer 23

Adenocarcinoma and papillary carcinoma

Question 24

What benign growths result from the mesenchyme?

Answer 24

Lipoma

Question 25

What malignant growths result from the mesenchyme?

Answer 25

Liposarcoma

Question 26

What benign growths result from the lymphocyte?

Answer 26

Does not exist

Question 27

What malignant growths result from the lymphocyte?

Answer 27

Lymphoma/Leukemia

Question 28

What benign growths result from the melanocyte?

Answer 28

Nevus (mole)

Question 29

What malignant growths result from the melanocyte?

Answer 29

Melanoma

Question 30

What is the 2nd leading cause of death in both adults and children?

Answer 30

cancer

Question 31

What are the leading causes of death in adults?

Answer 31

(1) cardiovascular disease (2) cancer (3) cerebrovascular disease

Question 32

What are the leading causes of death in children?

Answer 32

(1) accidents (2) cancer (3) congenital defects

Question 33

What are the most common cancers by incidence in adults?

Answer 33

(1) breast/prostate (2) lung (3) colorectal.

Question 34

What are the most common causes of cancer mortality in adults?

Answer 34

(1) lung (2) breast/prostate (3) colorectal

Question 35

Cancer begins as a

Answer 35

single mutated cell.

Question 36

Approximately how many divisions occur before the earliest clinical symptoms arise?

Answer 36

30

Question 37

Cancers that do not produce symptoms until late in disease

Answer 37

will have undergone additional divisions and, hence, additional mutations.

Question 38

Cancers that are detected late

Answer 38

tend to have a poor prognosis.

Question 39

Goal of screening is

Answer 39

to catch dysplasia (precancerous change) before it becomes carcinoma or carcinoma before clinical symptoms arise.

Question 40

Common screening methods include

Answer 40

1. Pap smear 2. Mammography 3. PSA and DRE 4. Hemoccult test and colonoscopy

Question 41

Pap smear

Answer 41

detects cervical dysplasia (CIN) before it becomes carcinoma

Question 42

Mammography

Answer 42

detects in situ breast cancer (e.g DCIS) before it invades or invasive carcinoma before it becomes clinically palpable

Question 43

PSA and DRE

Answer 43

Prostate specific antigen (PSA) and digital rectal exam detects prostate carcinoma before it spreads

Question 44

Hemoccult test

Answer 44

for occult blood in stool

Question 45

colonoscopy

Answer 45

detect colonic adenoma before it becomes colonic carcinoma or carcinoma before it spreads

Question 46

Cancer formation is initiated by

Answer 46

damage to DNA of stem cells. The damage overcomes DNA repair mechanisms, but is not lethal.

Question 47

Carcinogens are

Answer 47

agents that damage DNA, increasing the risk for cancer.

Question 48

Important carcinogens include

Answer 48

chemicals, oncogenic viruses, and radical ions

Question 49

DNA mutations eventually disrupt

Answer 49

key regulatory systems, allowing for tumor promotion (growth) and progression (spread)

Question 50

Disrupted key regulatory systems include

Answer 50

proto-oncogenes, tumor suppressor genes, and regulators of apoptosis

Question 51

Proto-oncogenes are essential to?

Answer 51

cell growth and differentiation;

Question 52

mutations of proto-oncogenes form

Answer 52

oncogenes that lead to unregulated cellular growth.

Question 53

Categories of oncogenes include

Answer 53

growth factors, growth factor receptors, signal transducers, nuclear regulators, and cell cycle regulators

Question 54

Growth factors induce

Answer 54

cellular growth (e.g PDGFB in astrocytoma),

Question 55

Growth factor receptors

Answer 55

mediate signals from growth factors (e.g. ERBB2 HER2/neu in breast cancer).

Question 56

What do signal tranducers do?

Answer 56

Relay receptor activation to the nucleus (eg. ras)

Question 57

Ras is associated with

Answer 57

growth factor receptors in an inactive GDP-bound state.

Question 58

Aflatoxins

Answer 58

Hepatocellular carcinoma Derived from Aspergillus, which can contaminate stored grains

Question 59

Alkylating agents

Answer 59

leukemia/lymphoma side effect of chemotherapy

Question 60

Alcohol

Answer 60

Squamous cell carcinoma of oropharynx and upper esophagus, pancreatic carcinoma, and hepatocellular carcinoma

Question 61

Arsenic

Answer 61

Squamous cell carcinoma of skin, lung cancer, and angiosarcoma of liver. Arsenic is present in cigarette smoke.

Question 62

Asbestos

Answer 62

Lung carcinoma and mesothelioma. Exposure to asbestos is more likely to lead to lung cancer than mesothelioma.

Question 63

Cigarette smoke

Answer 63

Carcinoma of oropharynx, esophagus, lung, kidney, and bladder. Most common carcinogen worldwide; polycyclic hydrocarbons are particularly carcinogenic.

Question 64

Nitrosamines

Answer 64

Stomach carcinoma, Found in smoked foods, responsible for high rate of stomach carcinoma in japan

Question 65

Naplithylamine

Answer 65

Urothelial carcinoma of bladder. Derived from cigarette smoke

Question 66

Vinyl chloride

Answer 66

Angiosarcoma of liver, occupational exposure; used to make polyvinyl chlurkle (PVC) for use in pipes

Question 67

Nickel, chromium, beryllium, or silica

Answer 67

Lung carcinoma Occupational exposure

Question 68

Oncogenic viruses

Answer 68

EBV, HHV-8, HBV and HCV, HTLV-1, High-risk HPV

Question 69

EBV

Answer 69

Nasopharyngeal carcinoma, Burkitt lymphoma and CNS lymphoma in AIDS

Question 70

HHV-8

Answer 70

Kaposi sarcoma

Question 71

HBV and HCV

Answer 71

Hepatocellular carcinoma

Question 72

HTLV-1

Answer 72

Adult T-cell leukemia/lymphoma

Question 73

High-risk HPV (e.g. subtypes 16, 18, 31, 33)

Answer 73

Squamous cell carcinoma of vulva, vagina, anus, and cervix; adenocarcinoma of cervix

Question 74

Ionizing radiation

Answer 74

(nuclear reactor accidents and radiotherapy) AML, CML and papillary carcinoma of the thyroid. Generates hydroxyl free radicals.

Question 75

Non Ionizing (UVB sunlight is most common source)

Answer 75

Basal cell carcinoma, squamous cell carcinoma, and melanoma of skin

Question 76

Non Ionizing radiation results in?

Answer 76

formation of pyrimidine dimers in DNA, which are normally excised by restriction endonuclease

Question 77

Ras Receptor binding causes

Answer 77

GDP to be replaced with GTP, activating ras.

Question 78

What does activated ras do?

Answer 78

sends growth signals to the nucleus

Question 79

How is Ras deactivated?

Answer 79

inactivates itself by cleaving GTP to GDP; this is augmented by GTPase activating protein

Question 80

Mutated ras

Answer 80

inhibits the activity of GTPase activating protein. This prolongs the activated state of ras, resulting in increased growth signals.

Question 81

Cell cycle regulators mediate what?

Answer 81

progression through the cell cycle (e.g. cyclin and cyclin-dependent kinase).

Question 82

Cyclins and cyclin-dependent kinases (CDKs) do what?

Answer 82

form a complex which phosphorylates proteins that drive the cell through the cell cycle.

Question 83

The cyclin D / CDK4 complex does what?

Answer 83

phosphorylates the retinoblastoma protein, which promotes progression through the G-S checkpoint

Question 84

What do tumor supressor genes do?

Answer 84

Regulate cell growth decreasing (suppress) the risk of tumor formation;

Question 85

What are some classic examples of tumor supressor genes?

Answer 85

p53 and Rb (retinoblastoma)

Question 86

What does p53 regulate?

Answer 86

progression of the cell cycle from G to S phase

Question 87

In response to DNA damage, what does p53 do?

Answer 87

slows the cell cycle and upregulales DNA repair enzymes.

Question 88

PDGFB

Answer 88

Platelet-derived growth factor, overexpression, autocrine loop, astrocytoma

Question 89

FRBB2 [HER2f neu]

Answer 89

Epidermal growth factor receptor, Amplification mechanism, Subset of breast carcinomas

Question 90

RET

Answer 90

Neural growth factor receptor, Point mutation MEN 2A, MEN 2B and sporadic medullary carcinoma of thyroid

Question 91

KIT

Answer 91

Stem cell growth factor receptor, Point mutation, Gastrointestinal stromal tumor

Question 92

RAS gene family

Answer 92

GTP-binding protein, Point mutation, Carcinomas, melanoma, and lymphoma

Question 93

ABL

Answer 93

Tyrosine kinase T(9;22) with BCR CML and some types of ALL

Question 94

What are the nuclear regulators?

Answer 94

C-MYC, N-MYC, L-MYC

Question 95

c-MYC

Answer 95

Transcription factor, t(8;I4) involving IgH, Burkitt lymphoma

Question 96

N-MYC

Answer 96

Transcription factor, Amplification, Neuroblastoma

Question 97

L-MYC

Answer 97

Transcription factor, Amplification, Lung carcinoma (small cell)

Question 98

CCND1 (cyclin D1)

Answer 98

Cyclin t(8;14) involving IgH, Mantle cell lymphoma

Question 99

If DNA repair is not possible, what does p53 do?

Answer 99

induces apoptosis.

Question 100

How does p53 induce apoptosis?

Answer 100

upregulates BAX, which disrupts Bcl2 leading to cytochrome c leaks from the mitochondria activating apoptosis

Question 101

Knudson two-hit hypothesis

Answer 101

both copies of the p53 gene must be knocked out for tumor formation, Both copies of Rb gene must be knocked out for tumor formation

Question 102

Loss of p53 is seen in what percentage of cancers?

Answer 102

> 50% of cancers.

Question 103

p53 Germline mutation results in

Answer 103

Li-Fraumeni syndrome (2nd hit is somatic),

Question 104

Li-Fraumeni syndrome is characterized by?

Answer 104

the propensity to develop multiple types of carcinomas and sarcomas,

Question 105

Rb

Answer 105

regulates progression from G0 to S phase.

Question 106

How does Rb regulate the progression to S phase?

Answer 106

holds the E2F transcription factor, which is necessary for transition to the S phase

Question 107

E2F is released when?

Answer 107

RB is phosphorylated by the cyclinD/cyclin-dependent kinase 4 (CDK4) complex

Question 108

Rb mutation results in

Answer 108

constitutively free E2F, allowing progression through the cell cycle and uncontrolled growth of cells.

Question 109

Sporadic mutation

Answer 109

(both hits are somatic) and it is characterized by unilateral retinoblastoma

Question 110

Rb Germline mutation results in

Answer 110

familial retinoblastoma (2nd hit is somatic) and is characterized by bilateral retinoblastoma and osteosarcoma.

Question 111

What is the function of regulators of apoptosis?

Answer 111

Prevent apoptosis in normal cells, but promote apoptosis in mutated cells whose DNA cannot be repaired (e.g Bcl2)

Question 112

Bcl2

Answer 112

normally stabilizes the mitochondrial membrane, blocking release of cytochrome c

Question 113

Disruption of Bcl2 allows what to happen?

Answer 113

Cytochrome c to leave the mitochondria and activate apoptosis

Question 114

Bcl2 in follicular lymphoma?

Answer 114

it is overexpressed in follicular lymphoma,

Question 115

Why is Bcl2 overexpressed in follicular lymphoma?

Answer 115

t(14;18) moves Bcl2 (chromosome 18) to the Ig heavy chain locus (chromosome 14), resulting in increased Bcl2.

Question 116

How is apoptosis inhibited in follicular lymphoma?

Answer 116

Mitochondrial membrane is further stabilized by overexpressed Bcl2, prohibiting apoptosis.

Question 117

In follicular lymphoma, how does the inhibition of apoptosis lead to lymphoma?

Answer 117

B cells that would normally undergo apoptosis during somatic hypermutation in the lymph node germinal center accumulate, leading to lymphoma.

Question 118

What is necessary for cell immortality?

Answer 118

Telomerase

Question 119

Normally telomeres do what?

Answer 119

shorten with serial cell divisions, eventually resulting in cellular senescence

Question 120

What is the relationship between cancers and telomerase?

Answer 120

cancers often have up regulated telomerase, which preserves telomeres

Question 121

Angiogenesis and tumors

Answer 121

(production of new blood vessels) is necessary for tumor survival and growth.

Question 122

FGF and VEGF

Answer 122

(angiogenic factors) are commonly produced by tumor cells.

Question 123

Tumor survival and the immune system?

Answer 123

Avoiding immune surveillance is necessary for tumor survival

Question 124

Immune surveillance and tumor survival?

Answer 124

Mutations often result in production of abnormal proteins, which are expressed on MHC class 1, CD8+ T cells detect and destroy such mutated cells, Tumor cells can evade immune surveillance by downregulating expression of MHC class 1.

Question 125

How do tumor cells evade immune surveillance?

Answer 125

by downregulating MHC class 1

Question 126

Immunodeficiency and cancer

Answer 126

(both primary and secondary) increases risk for cancer

Question 127

Accumulation of mutations eventually result in what?

Answer 127

tumor invasion and spread

Question 128

Epithelial tumor cells are normally attached to one another by what?

Answer 128

cellular adhesion molecules (e.g., E-cadherin).

Question 129

Downregulalion of E-cadherin leads to what?

Answer 129

dissociation of attached cells

Question 130

How do the tumor cells spread locally?

Answer 130

Cells attach to laminin and destroy basement membrane (collagen type IV) via collagenase. Cells attach to fibronectin in the extracellular matrix and spread locally

Question 131

Metastasis of tumor cells.

Answer 131

Entrance into vascular or lymphatic spaces allows for metastasis (distant spread)

Question 132

What are the routes of metastasis?

Answer 132

Lymphatic, hematogenous, seeding of body cavities

Question 133

Lymphatic spread is characteristic of what?

Answer 133

carcinomas

Question 134

Where does the initial lymphatic spread occur?

Answer 134

In the regional draining lymph nodes

Question 135

Hematogenous spread is characteristic of what?

Answer 135

sarcomas and some carcinomas

Question 136

What are some examples of hematogenous spread?

Answer 136

renal cell carcinoma, hepatocellular carcinoma, follicular carcimoma of the thyroid, choriocarcinoma

Question 137

Seeding of body cavities is characteristic of?

Answer 137

ovarian carcinoma, often involves the peritoneum ‘omental caking’

Question 138

What is omental caking?

Answer 138

where the peritoneum is often involved in ovarian carcinoma

Question 139

Describe benign tumors.

Answer 139

tend to be slow growing, well circumscribed, distinct, and mobile

Question 140

Malignant tumors are usually

Answer 140

rapid growing, poorly circumscribed, infiltrative, and fixed to surrounding tissues and local structures.

Question 141

What is generally required before a tumor can be classified as benign or malignant with certainty?

Answer 141

Biopsy or excision

Question 142

Why is biopsy necessary?

Answer 142

Some benign tumors can grow in a malignant-like fashion, and some malignant tumors can grow in a benign-like fashion.

Question 143

Benign tumors are usually

Answer 143

well differentiated

Question 144

What are some characteristics of benign tumors?

Answer 144

1. Organized growth 2. Uniform nuclei 3. Low nuclear to cytoplasmic ratio 4. Minimal mitotic activity 5. Lack of invasion (of basement membrane or local tissue) 6. No metastatic potential

Question 145

Malignant tumors are classically

Answer 145

poorly differentiated (anaplastic)

Question 146

Characteristics of malignant tumors include

Answer 146

1. Disorganized growth (loss of polarity) 2. Nuclear pleomorphism and hyperchromasia 3. High nuclear to cytoplasmic ratio 4. High mitotic activity with atypical mitosis 5. Invasion (through basement membrane or into local tissue)

Question 147

What is the hallmark of malignancy?

Answer 147

Metastatic potential - benign tumors never metastasize

Question 148

What is the target cell type for the immunohistochemical stain of Keratin?

Answer 148

Epithelium

Question 149

What is the target cell type for the immunohistochemical stain of Vimentin

Answer 149

Mesenchyme

Question 150

What is the target cell type for the immunohistochemical stain of desmin

Answer 150

Muscle

Question 151

What is the target cell type for the immunohistochemical stain of Neurofilament

Answer 151

Neurons

Question 152

What is the target cell type for the immunohistochemical stain of PSA

Answer 152

Prostatic epil helium

Question 153

What is the target cell type for the immunohistochemical stain of ER

Answer 153

Breast epithelium

Question 154

What is the target cell type for the immunohistochemical stain of Thyroglobulin

Answer 154

thyroid follicular cells

Question 155

What is the target cell type for the immunohistochemical stain of chromogranin?

Answer 155

neuroendocrine cells (small cell carcinoma of lung and carcinoid tumors)

Question 156

What is the target cell type for the immunohistochemical stain of S-100?

Answer 156

Melanoma

Question 157

What is used to characterize tumors that are difficult to classify on histology?

Answer 157

Immunohistochemistry

Question 158

What are serum tumor markers?

Answer 158

Proteins released by tumor into serum (e.g PSA)

Question 159

Serum tumor markers are useful for what?

Answer 159

screening, monitoring response to treatment, and monitoring recurrence

Question 160

Elevated levels of serum tissue markers require what?

Answer 160

it requires tissue biopsy for diagnosis of carcinoma (e.g., biopsy of prostate with elevated PSA),

Question 161

What is involved in the grading of cancer?

Answer 161

Microscopic assessment of differentiation (how much a cancer resembles the tissue in which it grows); takes into account architectural and nuclear features

Question 162

What is low grade?

Answer 162

Well differentiated?resembles normal parent tissue

Question 163

What is high grade?

Answer 163

poorly differentiated?does not resemble parent tissue

Question 164

Cancer grading is important for what?

Answer 164

determining prognosis; well-differentiated cancers have better prognosis than poorly-differentiated cancers.

Question 165

What is staging of cancer?

Answer 165

its an assessment of size and spread of a cancer,

Question 166

How does the staging of cancer compare to the grading of cancer?

Answer 166

Key prognostic factor; more important than grading

Question 167

When is the staging of cancer determined?

Answer 167

after final surgical resection of the tumor

Question 168

What is the TNM staging system?

Answer 168

T?tumor (size and/or depth of invasion), N?spread to regional lymph nodes; second most important prognostic factor, M?metastasis; single most important prognostic factor

Question 169

In the TNM staging system what is the most important prognostic factor?

Answer 169

Metastasis