14, 15 - Cancer

Question 1

Define cancer

Answer 1

Diseases in which abnormal cells divide w/o control and are able to invade other tissues

Question 2

When are cancer cells formed?

Answer 2

When normal cells lose normal regulatory mechanisms that control growth, differentiation, and multiplication

Question 3

What happens to cancer cells?

Answer 3

Lose the specialized characteristics that distinguish one type of cell from another (loss of differentiation)

Question 4

What is a neoplasm?

Answer 4

New and diseases form of tissue growth

Question 5

Which neoplasms are cancerous? Which aren’t?

Answer 5

• Benign neoplasms = not cancerous

- Malignant neoplasms = cancerous, can invade other parts of the body and give secondary tumours (metastasis)

Question 6

How do carcinogenic chemicals cause cancer?

Answer 6

Induce gene mutations or interfere w/ normal cell differentiation

Question 7

What can initiate carcinogenesis (birth of cancer)?

Answer 7

A chemical or other mutagen (ex: sunlight)

Question 8

What is an example of a gene that can give rise to cancer?

Answer 8

BRCA1/ BRCA2 – tumour suppressor proteins, mutation causes protein to not function properly or not be made

Question 9

What are proto-oncogenes?

Answer 9

Genes which code for proteins involved in the control of cell division and differentiation

Question 10

What can happen if proto-oncogens mutate?

Answer 10

Can disrupt normal cell function and become cancerous; would now be called oncogenes

Question 11

What does Ras gene code for? What happens if its mutated?

Answer 11

• Codes for Ras protein (cell division signaling) and is self-regulating
• If mutated, is continually active leading to continuous division

Question 12

What are anti-oncogenes? What happens to them to cause cancer?

Answer 12

• Tumour suppressor genes

- Inactivation causes cancer

Question 13

What cellular defects can be caused by genetic defects?

Answer 13

• Abnormal signalling pathways; insensitivity to signals
• Abnormalities in cell-cycle regulation
• Evasion of cell death (apoptosis)
• Limitless cell division
• New blood vessels; tissue invasion and metastasis

Question 14

What are the 5 types of cancer? Which is most common?

Answer 14

1) Carcinoma - epithelial cells; most common
2) Sarcoma - connective tissue
3) Lymphoma and leukemia - hemopoietic cells, bone marrow-derived cells that normally mature in bloodstream (leukemia) or lymphatic system (lymphoma)
4) Germinoma - germ cells; testicle and ovarian cancers
5) Blastoma - resembles embryonic tissue; tumour of primitive, incompletely differentiated cells

Question 15

What are the mechanisms of cancer cells?

Answer 15

• DNA synthesis or mitosis to produce new cells
• Cell differentiation to produce specialized cells
• Growth factors and cell surface receptors
• Growth inhibitors and cell surface receptors
• Cell cycle and regulation

Question 16

What are the basis/causes of cancer?

Answer 16

Mutation, chemical, and/or viral

Question 17

What are the 2 types of mutations in cancer?

Answer 17

1) Germ-line -> mutation present in germ cells, hereditary

2) Somatic -> non-inherited change in genetic structure

Question 18

What is the multi-stage theory of cancer?

Answer 18

1) Initial mutations
2) Promotion phase (mutated cell proliferation)
3) Small benign tumour forms and develops (malignant phenotype)
4) Primary malignant tumour forms (progression)
5) Cells break off, lodge at remote sites and secondary tumours form (metastasis)

Question 19

____ was identified as the cause of scrotal cancer

Answer 19

Benzoapyrene (component of soot)

Question 20

What do oncogenic viruses do?

Answer 20

• Insert themselves into host genome
• DNA viruses produce proteins that interact w/ growth regulatory proteins or tumour suppressor genes and may lead to/promote cancer
• Viral genome may be near regulatory genes, producing mutations
• RNA viruses produce double stranded DNA provirus that is inserted into host genome usually near proto-oncogenes

Question 21

How is cancer therapy decided?

Answer 21

Based on specific type, location, and stage of cancer

Question 22

What are the fundamental techniques for cancer therapy? What is involved in each?

Answer 22

• Surgery -> cancer must be in primary tumour stage; must excise entire tumour
• Radiation therapy -> ionizing radiation used to shrink tissues by causing damage to DNA and apoptosis; requires tumour that is localized
• Immunologic therapy -> utilizes immune system to eradicate cancer, boosting levels of lymphocytes to destroy foreign cells, including premalignant and malignant cells
• Chemotherapy

Question 23

What is chemotherapy used for?

Answer 23

• To reduce size of a tumour prior to surgery

- Sensitize tumours to radiation therapy or destroy microscopic tumours after surgery

Question 24

What is chemotherapy used with? What types of tumours is it effective against?

Answer 24

• Used w/ surgery or radiation therapy

- Effective against metastasized tumours or residual tumours after therapy

Question 25

What is the drawback to chemotherapy?

Answer 25

Lack of selectivity (effect both normal and malignant cells)

Question 26

Which classes of drugs are alkylating agents?

Answer 26

• Nitrogen mustards
• Phosphamide mustards
• Nitrosureas
• Platins

Question 27

Which classes of drugs are antimetabolite and nucleoside analogs?

Answer 27

DHFR and thymidylate synthase inhibitors

Question 28

Which classes of drugs are antimitotic agents?

Answer 28

• Vinca alkaloids

- Taxanes

Question 29

What are the various drug categories used for cancer therapy?

Answer 29

• Alkylating agents
• Antimetabolite and nucleoside analogs
• Antitumour antibiotics
• Antimitotic agents
• Miscellaneous antineoplastic
• Hormone therapy
• Combination therapies

Question 30

What do alkylating agents do?

Answer 30

• React w/ DNA, preferentially alkylating in N-7 position of guanine
• May alkylate other sides on DNA bases

Question 31

What do bifunctional alkylating agents do?

Answer 31

Produce inter and intra-strand crosslinks, preventing DNA separation (cytotoxic)

Question 32

What do nitrogen mustards do? What cells are they most effective against? How are they generally administered?

Answer 32

• Nitrogen atom activates chloride by proceeding through aziridinium ion intermediate
• Most effective against rapidly proliferating cells
• Generally administered IV

Question 33

Can cells repair DNA alkylation? If so, how?

Answer 33

• Yes

- Endonuclease cuts damaged strand

Question 34

Which drugs are nitrogen mustards? Which can be given orally? Which is a pro-drug? Which has an active metabolite?

Answer 34

• Melphalan
• Cyclophosphamide *pro-drug, available orally
• Ifosphamide
• Chlorambucil *active metabolite (phenylacetic acid)
• Estramustine phosphate *given orally

Question 35

How is melphalan transported into cells?

Answer 35

L-amino acid transporter

Question 36

Which nitrogen mustard is less likely to form aziridinium ion? Is this beneficial?

Answer 36

• Cyclophosphamide

- Makes it more stable

Question 37

What is a structural characteristic of nitrogen mustards?

Answer 37

Nitrogen atom w/ 2 chloroethyl arms (may or may not be both attached to nitrogen; only 1 attached for ifosfamide)

Question 38

What is special about chlorambucil?

Answer 38

Nitrogen is attached to phenyl group, reducing reactivity and basicity

Question 39

What is special about busulfan?

Answer 39

Has methane sulfonic acid leaving groups, producing mono or di-alkylation of DNA nucleophiles

Question 40

Which drugs are considered “other alkylating”?

Answer 40

• Busulfan
• Thiotepa
• Procarbazine
• Dacarbazine

Question 41

What is special about thiotepa?

Answer 41

• Has aziridine-containing three-membered rings where nucleophiles react, relieiving ring strain
• At physiologic pH, aziridine major form is the less reactive free base, and protonation activates aziridinium ion

Question 42

What is special about procarbazine?

Answer 42

• Alkylation occurs via free radical intermediates instead of electrophile/nucleophile mechanisms (can occur using substituted hydrazines in presence of O2)
• Produces methyl radical which alkylate DNA on C-8 position of guanine

Question 43

What is the mechanism of dacarbazine?

Answer 43

• Not fully understood
• Appears to be metabolically bioactivated through CYP450 enzymes via initial demethylation to MTIC
• Followed by formation of diazomethane which alkylates N-7 position of guanine

Question 44

How are nitrosureas activated?

Answer 44

• In water, urea NH is deprotonated
• Negatively charged oxygen displcaes chloride to give cyclic oxazolidine
• This fragments to give 2-chloroethylisocyanate and vinyl diazohydroxide, which decomposes to give electrophilic vinyl cation

Question 45

Which drugs are nitrosureas? What is special about each compound w/ respect to dosage form?

Answer 45

• Carmustine (more efficiently crosses BBB in comparison to other alkylating agents; IV use)
• Lomustine (more stable in air, used in capsules)
• Streptozocin (sugar group imparts good water solubility)

Question 46

Which drugs are platins? Which is more potent?

Answer 46

• Cisplatin (more potent)

- Carboplatin

Question 47

What is the MOA of cisplatin?

Answer 47

• Like other alkylating agents, alkylates N-7 position of guanine forming intra-strand cross-links
• Needs cis configuration to induce intra-strand cross-links

Question 48

What do intra-strand crosslinks lead to?

Answer 48

• Replication and transcription inhibition

- Cell-cycle arrest and cell death

Question 49

What are the 2 functions of DNA?

Answer 49

1) Act as a template for DNA self-replication

2) Act as a template for production of messenger-RNA

Question 50

What are antimetabolites?

Answer 50

• Compounds closely relate to cellular precursor molecules that are capable of preventing proper use or formation of normal cellular products
• Similar enough to interact or be involved in cellular process, but different enough to alter outcome of the pathway

Question 51

Most antimetabolites are involved in the ______

Answer 51

Biosynthesis of nucleic acids

Question 52

What are useful targets of antimetabolites?

Answer 52

Purines, pyrimidines, and folates

Question 53

What is the modification in pyrimidine-based antimetabolites? What are the possible MOAs?

Answer 53

• Modification may be on pyrimidine ring or on pendant sugar group
• MOA = inhibition of kinases; inhibition of enzymes involved in pyrimidine biosynthesis; incorporation into RNA or DNA, causing misreading; or inhibition of DNA polymerase

Question 54

What is vitamin B9?

Answer 54

Folic acid and folate

Question 55

What is the difference between folate and folic acid?

Answer 55

• Folate is naturally occurring of vitamin B9 found in food; polyglutamate
• Folic acid is synthetically produced in fortified foods; not biologically active, its derivatives tetrahydrofolate and dihydrofolic acid are; has 1 glutamate group (monoglutamate)

Question 56

What is folate used for in the body?

Answer 56

To synthesize DNA, repair DNA, methylate DNA, as well as a cofactor

Question 57

What is the function of thymidylate synthase?

Answer 57

Adds methyl group to dUMP to make dTMP

Question 58

What is dihydrofolate reductase?

Answer 58

• Enzyme that maintains levels of tetrahydrofolate, allowing dTMP to be produced and be used in DNA synthesis
• Catalyzes reduction of folic acid to FH4 (tetrahydrofolate) via FH2 (dihydrofolate), which is followed by addition of single carbon unit to form N5-N10-methylene-FH4, which is used as one-carbon source for conversion of dUMP to dTMP by thymidylate synthase

Question 59

What do dihydrofolate reductase inhibitors cause? Which drug is an example of this?

Answer 59

• Decreased levels of folate cofactors, lowering synthesis of dTMP, slowing DNA synthesis and cell division
• Methotrexate

Question 60

Why is methotrexate effective?

Answer 60

Has additional H-bond doner, producing a stronger binding affinity to DHFR enzyme than FH2, preventing its binding and conversion to N5-N10-methylene-FH4

Question 61

How can methotrexate resistance occur?

Answer 61

• Enhanced expression of DHFR

- Diminished uptake by reduced folate carrier

Question 62

What is leucovorin and when and why is it used?

Answer 62

• Folinic acid

- Used w/ methotrexate to “rescue” bone marrow and GI mucosa cells from methotrexate

Question 63

What is methotrexate used for besides cancer?

Answer 63

• Severe rheumatoid arthritis
• Severe psoriasis
• *Used at much lower doses to reduce toxicity

Question 64

What is the MOA of pralatrexate?

Answer 64

Selectively enters cells expressing reduced folate carrier type 1 (RFC-1), a protein that is overexpressed in certain cancer cells, to ensure enough folate

Question 65

What is the MOA of pemetrexed?

Answer 65

• Inhibits 3 enzymes – thymidylate synthase, dihydrofolate reductase, and glycinamide ribonucleotide formyltransferase
• By inhibiting formation of precursor pyrimidine and purine nucleotides, prevents formation of DNA and RNA

Question 66

What should be given w/ pemetrexed and why?

Answer 66

• Folic acid and vitamin B12

- Prevent bone marrow toxicity

Question 67

What does 5-fluorouracil do? What is the MOA?

Answer 67

• Pro-drug that directly inhibits thymidylate synthase
• 5-fluorouracil catalyzed to fluorodeoxyuridine (by thymidine phosphorylase) which is then phosphorylated to FdUMP, which covalently reacts w/ thymidylate synthase

Question 68

How is 5-fluorouracil metabolized? Are any of the metabolites active?

Answer 68

• Metabolized into 3 active metabolites
  1) Fluorodeoxyuridine monophosphate (FdUMP)
  2) Fluorodeoxyuridine triphosphate (FdUTP)
  3) Fluorouridine triphosphate (FUTP)

Question 69

How is 5-FU converted to fluorouridine monophosphate (FUMP)?

Answer 69

• Either directly by orotate phosphoribosyltransferase (OPRT) w/ phosphoribosyl pyrophosphate (PRPP) as the cofactor
• Or indirectly via fluorouridine (FUR) through sequential action of uridine phosphorylase and uridine kinase

Question 70

What happens to FUMP?

Answer 70

• Phosphorylated to fluorouridine disphosphate (FUDP)
• FUDP can either be further phosphorylated to active metabolite fluorouridine triphosphate (FUTP) or converted to fluorodeoxyuridine disphosphate (FdUDP) by ribonucleotide reductase (RR)
• FdUDP can either be phosphorylated or dephosphorylated to generate active metabolites FdUTP or FdUMP

Question 71

What is a second way of producing FdUMP?

Answer 71

• Conversion of 5-FU to fluorodeoxyuridine (FUDR) by thymidine phosphorylase
• FUDR then phosphorylated by thymidine kinase to FdUMP

Question 72

What is the rate limiting step of 5-FU catabolism in normal and tumour cells?

Answer 72

Dihydropyrimidine dehydrogenase (DPD)-mediated conversion of 5-FU to dihydrofluorouracil

Question 73

Who are at risk of toxicity of 5-FU?

Answer 73

Those who are genetically deficient in DPD b/c DPD breaks down 80% of 5-FU

Question 74

What is the detailed MOA of 5-FU?

Answer 74

• 5-FU metabolized into active metabolite FdUMP
• FdUMP binds to nucleotide-binding site of thymidylate synthase (TS), forming a stable ternary complex w/ TS and N5,N10-methylene-FH4, blocking access of dUMP to binding site and inhibiting dTMP synthesis
• Increased levels of dUTP and imbalances in dNTP pool cause DNA damage

Question 75

What determines the extent of DNA damage from 5-FU?

Answer 75

Levels of pyrophosphatase dUTPase and uracil-DNA glycosylase

Question 76

What allows 5-FU to remain covalently and irreversibly bound to the active site of thymidylate synthase?

Answer 76

Fluorine atom in the position of the hydrogen atom that is normally eliminated

Question 77

What is the effect of cytarabine?

Answer 77

• Active triphosphate inhibits production of 2’-deoxycytidylic acid and DNA-dependent DNA polymerase
• Causes miscoding after incorporation into DNA or RNA

Question 78

What is the effect of gemcitabine?

Answer 78

• First phosphorylated into active triphosphate, which is then incorporated into DNA or RNA leading to cell death
• Also inhibits DNA and RNA synthesis

Question 79

What is the effect of 6-mercaptopurine?

Answer 79

• Converted to 6-thioinosinate and is an inhibitor of production of 5-phosphoribosylamine from 5-phosphoribosyl pyrophosphate (PRPP) in purine biosynthesis
• 6-thioinosinate also inhibits conversion of inosinic acid (IMP) to adenylic acid, and oxidation of IMP to xanthylic acid