Cancer Chemotherapy

Question 1

What is the percentage of cancerous cells which should ideally be killed by treatment ?

Answer 1

Enough for a clinical response

Question 2

Describe the main treatment options for cancer.

Answer 2

1) Surgical excision
2) Radiotherapy
3) Chemotherapy

Question 3

Identify the main groups of drugs used in chemotherapy.

Answer 3

• Alkylating agents
• Antimetabolites
• Cytotoxic antibiotics
• Plant derivatives

Question 4

Identify the most commonly used group of drug in chemo.

Answer 4

Alkylating agents

Question 5

Describe the mechanism of action of Alkylating agents.

Answer 5

• Have properties of forming covalent bonds with suitable nucleophillic substances in the cell under physiological conditions.
• Intrastrand crosslinking of DNA:
- Normally guanine residues in DNA exist predominantly in the keto tautomer.
- This allows them to hydrogen bond with cytosine.
- When the 7 nitrogen of guanine is alkylated it becomes more acidic and the enol tautomer is formed.
- This modified guanine can mispair with thymine residues during DNA synthesis. i.e. G-T not G-C
- Alkylation of the 7 nitrogen destabilises the imidazole ring causes ring cleavage
- This leads to depurination (excision of guanine residues)
- The resulting damage triggers cell death by apoptosis.

Question 6

Identify the major groups of alkylating agents. Give one or two examples for each group.

Answer 6

1) Nitrogen mustards – e.g. cyclophosphamide
2) Ethylenimines - e.g. Thiotepa
3) Alkylsulphonates - e.g. Busulphan
4) Hydrazines and Triazines – e.g. Temozolomide
5) Nitrosoureas – e.g. lomustine, carmustine
6) Platinum based compounds – e.g. cisplatin

Question 7

Describe the mechanism of action of cyclophosphamide.

Answer 7

• Cyclophosphamide (inactive) activated by P450 mixed function oxidases.
• Converted into hydroxycyclophosphamide, which forms aldophosphamide reversibly
• Aldophosphamide transported to other tissues where it forms phosphoramide (cytotoxic) + Acrolein (cytotoxic, responsible for unwanted effect)

Question 8

Identify mesna and describe its importance in chemotherapy treatment.

Answer 8

Medication used in those taking cyclophosphamide to counteract effects of acrolein (to avoid haemorrhagic cystitis).

Question 9

Describe the specific features of Busulphan.

Answer 9

• Selective effect on the bone marrow
• Depresses the formation of granulocytes and platelets in low dosage and red cells in higher dosage.
• Used in chronic granulocytic leukaemia

Question 10

Describe the specific features of Nitrosoureas.

Answer 10

e. g. lomustine, carmustine
- Lipid soluble and
- Can cross the blood-brain barrier, may be used against tumours of the brain and meninges

Question 11

Describe the specific features of Cisplatin.

Answer 11

• water-soluble planar coordination complex containing a central platinum atom surrounded by two chlorine atoms and two ammonia groups.
• action is analogous to that of the alkylating agents. When it enters the cell, Cl- dissociates leaving a reactive complex that reacts with water and then interacts with DNA
• causes intrastrand cross-linking- probably between N7 and O6 of adjacent guanine molecules-which results in local denaturation of the DNA chain.

Question 12

Identify the main groups of antimetabolites. Give one or two examples for each group.

Answer 12

1) Antifolates – e.g. methotrexate
2) Antipyrimidines – e.g. 5-FU, gemcitabine, Cytarabine
3) Antipurines – e.g. mercaptopurine, thioguanine, fludarabine

Question 13

Describe the specific features of Methotrexate.

Answer 13

• Folate analogue (structurally similar) so antifolate
• Usually given orally but can also be given
intramuscularly, IV or intrathecally.
• Low lipid solubility so does not cross the blood brain barrier easily.
• Polyglutamated which means it can be retained within cells for weeks.

Question 14

Describe the specific features of Fluorouracil.

Answer 14

• Fluorouracil (5-FU) interferes with thymidylate synthesis (DTMP).
• It is converted into a fraudulent nucleotide FDUMP. Cannot be converted into DTMP

Question 15

Describe the specific features of Cytarabin.

Answer 15

• Analogue of cytosine but has arabinose and not ribose attached.
• Undergoes phosphorylation to give cytosine arabinoside triphosphate.
• This inhibits DNA polymerase.

Question 16

Describe the specific features of Gemcitabine.

Answer 16

• Analogue of cytarabine.

Question 17

Describe the specific features of Mercaptopurine.

Answer 17

• Converted to 6- mercaptopurine-ribose phosphate, called “Lethal Synthesis”.
• 6 mercaptopurine-ribose-phosphate inhibits a number of enzymes in the de novo synthesis of purines.
• Results in fraudulant nucleotide

Question 18

Describe the main features of Fludarabine.

Answer 18

In its triphosphate form, inhibits DNA polymerase.

Question 19

Describe the structure of the following antimetabolites:

• 5-FU
• Gemcitabine
• Mercaptopurine
• Fludarabine

Answer 19

• 5-FU (F replaces H of uracil)
• Gemcitabine (2 Fs replaces H and OH on ribose ring)
• Mercaptopurine (S substitute in purine)
• Fludarabine (F replaces H of adenosine and arabinose replaces ribose)

Question 20

Identify the main groups of Cytotoxic antibiotics.

Answer 20

• Anthracyclines
• Dactinomycin
• Bleomycin
• Mitomycin

Question 21

Identify the main Anthracyclines.

Answer 21

Doxorubicin

Question 22

Describe the mechanism of action of Doxorubicin.

Answer 22

• Generally, binds to DNA and inhibits both DNA and RNA synthesis.

• During replication of the DNA helix, reversible swivelling needs to take place around the replication fork in order to prevent the daughter DNA molecule becoming inextricably entangled during mitotic segregation.
• The swivel is produced by topoisomerase II, which nicks both DNA strands and subsequently reseals the breaks. Hence, the activity of topoisomerase II is markedly increased in proliferating cells.
• Doxorubicin intercalates in the DNA and its effect is to stabilise the DNA-topoisomerase II complex after the strands have been nicked, thus causing the process to seize up at this point.

Question 23

Describe the mechanism of action of Dactinomycins.

Answer 23

• Intercalates in the minor groove of DNA between adjacent guanosine- cytosine pairs, interfering with the movement of RNA polymerase along the gene and thus preventing transcription
• Also evidence that it has a similar action to the anthracyclines on topoisomerase II

Question 24

Describe the mechanism of action of Bleomycin.

Answer 24

• Group of metal-chelating glycopeptide antibiotics that degrade preformed DNA, causing chain fragmentation and release of free bases
• Action on DNA involves chelation of ferrous iron and interaction with oxygen, resulting in the oxidation of the iron and generation of superoxide and/or hydroxyl radicals
• Most effective in the G2 phase of the cell cycle and mitosis, but it is also active against non-dividing cells

Question 25

Describe the mechanism of action of Mitomycins.

Answer 25

• After enzymic activation in the cells, functions as a bifunctional alkylating agent, alkylating preferentially at O6 of guanine.
• Cross-links DNA and may also degrade DNA through the generation of free radicals.

Question 26

Briefly explain how plant derivatives generally work.

Answer 26

Spindle poisons – affect microtubule function and prevent mitotic spindle formation or top I/ II inhibitors

Question 27

Identify the main groups of plant derivatives. Give a couple of examples for each group.

Answer 27

• Vinca alkaloids (e.g. Vincristine, Vinblastine)
• Taxanes (e.g. Paclitaxcel (taxol), docetaxel)
• Camptothecins (e.g. irinotecan)
• Etoposide

Question 28

Describe the mechanism of action of Vinca alkaloids.

Answer 28

Bind tubulin and prevent polymerisation into microtubules

Question 29

Describe the mechanism of action of Taxanes.

Answer 29

Stabilise (freeze) microtubules

Question 30

Describe the mechanism of action of Camptothecins.

Answer 30

Bind to and inhibit topoisomerase I

Question 31

Describe the mechanism of action of Etoposide.

Answer 31

Inhibits mitochondrial function, nucleoside transport and topoisomerase II

Question 32

Identify the main novel targeted agents.

Answer 32

• Rituximab
• Trastuzumab (Herceptin)
• Imatinib (Gleevec)

Question 33

Describe the function of the following novel targeted agents and the cancer they are usually used against.

• Rituximab
• Trastuzumab (Herceptin)
• Imatinib (Gleevec)

Answer 33

• Rituximab- Targets a B cell surface protein and is used for B cell lymphomas
• Trastuzumab (Herceptin)- Targets epidermal growth factor receptor and is used for breast cancer.
• Imatinib (Gleevec)- Inhibits bcr-abl gene signaling pathways and is used for chronic myeloid leukaemia.

Question 34

What are the main drawbacks of current chemotherapy of cancer ?

Answer 34

• target cell proliferation not the more lethal properties of invasiveness and metastasis
• non-specific cell killers rather than being aimed at the particular changes which make a cell malignant.
• the development of resistance (particularly multi-drug resistance) to anticancer drugs
• remaining cells (tumour stem cells), since total elimination of malignant cells is not possible using therapeutic doses, and the host’s immune response is often not adequate to deal with the remainder
• Patient compliance due to side-effects (risk of not completing the therapy regimen)

Question 35

Identify other approaches to cancer therapy, besides the traditional ways (i.e. traditional chemotherapy, radiation, surgery).

Answer 35

• Kill or remove malignant cells: cytotoxic drugs, surgery & irradiation
• Targeted cytotoxic agents (e.g.antibody-linked toxins or radioactive agents)
• Specifically inactivate components of oncogene signalling pathway, mAbs etc
• Employ tissue-specific proliferation inhibitors: estrogens, anti-estrogens, androgens, anti- androgens, glucocorticoids, gonadotrophin- releasing hormone analogues.
• Enhance host immune response; cytokine-based therapies, gene therapy-based approaches, cell- based approaches (e.g. anti-tumour T cells).
• Reverse drug resistance; inhibitors of multidrug resistance transport
• Antisenseoligonucleotides
• Restore function of tumour suppressor genes: gene
therapy.
• Inhibit tumor growth, invasion, metastasis: inhibitors of angiogenesis, matrix metalloproteinase inhibitors.
• Inhibitors of anti-apoptotic factors or stimulators of pro-apoptotic factors

Question 36

True or False: Cancer treatment may involve a combination of chemotherapy, radiotherapy and surgery

Answer 36

True.

Question 37

Explain the general aim of chemotherapy.

Answer 37

“Killing cancer cells”