Cancer Notes

Question 1

Cell cycle control system

Answer 1

Functions to trigger and coordinate events of the cell cycle.

The cycle is run by proteins that control the system (i.e. anaphase only happens after metaphase if the proteins tell it to)

There are checkpoints that need the go-ahead by the proteins at the G1 point, end of G2 point, and middle of Mitosis point

Question 2

G0 cells

Answer 2

Cells that do not continue to divide, but instead stop at the G1 phase unless damage occurs, or they receive a signal from a growth factor to continue dividing

Question 3

Growth factor

Answer 3

Binds to a receptor protein at the surface of the cell, which then starts a signal transduction pathway to the next protein, until it reaches the cell control system. (A game of telephone)

If some thing goes wrong in the game of telephone, it can lead to cancer

Question 4

Cancer

Answer 4

A disease of the cell cycle where cells don’t heed the normal signals that regulate the cycle, rather, they divide excessively, and may invade other tissues of the body.

Starts with a single cell that gets converted from a normal cell to a cancer cell. This happens after there is a mutation in one or more genes that encode for proteins in the cell cycle control system. (Can usually be detected and destroyed but if not will keep dividing and form a tumour)

Question 5

Tumour

Answer 5

An abnormally growing build up of body cells.

Question 6

Benign tumour

Answer 6

When these abnormally growing cells remain at the original site and don’t invade other tissues / the blood

Can usually be simple removed by surgery

Question 7

Malignant tumour

Answer 7

When the tumour can invade neighbouring tissues, and have cells that can travel through the blood or lymphatic system, and spread to other parts of the body.

This is when someone is said to have cancer

Question 8

Metastasis

Answer 8

The spread of cancer cells beyond their original site by traveling through blood or lymph

Question 9

Precancerous

Answer 9

A term used when something may develop into cancer, if not treated, or may not.

Question 10

Hyperplasia

Answer 10

A type of precancerous tumour in which there is a tumour of normal looking cells that grow faster than usual.
(a HYPER build up of normal cells)

Some may be pre-cancerous, but most are not.

Question 11

Atypia

Answer 11

A type of precancerous tumour in which the cells are slightly abnormal. Sometimes caused by healing and inflammation.
(ATYPICAL!)

Some are precancerous.

Question 12

Metaplasia

Answer 12

A type of precancerous tumour in which there is a change from the types of cells normally found in that part of the body. They look normal, but don’t belong there.
(The regular cells MET up in a different location)

Most are not precancerous.

Question 13

Dysplasia

Answer 13

A precancerous tumour in which there are abnormal cells, more cells than normal, grow faster than normal, and aren’t arranged like normal cells.
(DYS = defective -> abnormal cells)

These are precancerous.

Question 14

Carcinoma in situ

Answer 14

The most severe type of pre-cancerous tumour. The cells are very abnormal, though they have not yet grown into nearby tissue.
(Couldn’t come up with a fun way of remembering this one because it’s too unfun because it’s high risk)

There is a high risk for becoming cancerous.

Question 15

Carcinomas

Answer 15

Cancers that originate covering or linings of the body, such as a skin, or the lining of an intestine.

These are the most common of cancers. They also affect the largest amount of surface area in the body.

(CarSKINomas)

Question 16

Sarcomas

Answer 16

Cancer that arises in tissues that support the body such as bone, muscle, and cartilage

(Think of SARCOMeres - what makes muscle tissue)

Question 17

Leukemia / lymphomas

Answer 17

Cancers of the blood forming tissues, such as bone marrow, spleen, and lymph nodes

(Think EMIA - term for something abnormal in the blood)

Question 18

Blastoma

Answer 18

Tumours which originate from embryonic tissue or immature cells.

More common in children than adults.

(The kids are not having a BLAST)

Question 19

Oncogene

Answer 19

A single gene that causes a normal cell to become cancerous

Can come from a virus (ex. Hepatitis B)

Question 20

Pronto-oncogene

Answer 20

A normal gene that has the potential to become an oncogene.

Many code for proteins that stimulate cell division or turn of proteins that suppress cell growth

(a PRE oncogene)

Question 21

What are the 3 ways a pronto-oncogene can lead to cancer?

Answer 21

1. A mutation that turns the pronto oncogene into an oncogene. (Most cancers require 4 or more mutations to develop)
2. Having multiple copies of the gene due to an error in DNA replication.
3. Movement of the gene to a new location where it transcription is promoted.

Question 22

Paclitaxel

Answer 22

A type of chemotherapy that freezes the mitotic spindles after they form so that the cell division cannot happen.

(Freezer PACks the spindles)

Question 23

Vinblastine

Answer 23

A type of chemotherapy that prevents the mitotic spindle from forming so the cells cannot divide

PreVINts the spindles from forming)

Question 24

Hormonal treatments

Answer 24

Drugs that are designed to prevent cancer cells from receiving signals necessary for continued growth and division.

Question 25

Specific inhibitors

Answer 25

Drugs that work by targeting specific proteins and processes that are relative to cancer cells in order to stop their growth and division.

(Inhibit = stop)

Question 26

Antibodies

Answer 26

The use of antibodies to target cancer cells. They work by either depriving the cancer cells of necessary signals, or causing direct death of cells.

Question 27

Biological response modifiers

Answer 27

Treatments involving the use of naturally occurring proteins to stimulate the bodies own defence against cancer.

Question 28

Vaccines

Answer 28

Used to stimulate the bodies defence against cancer, usually contain proteins produced by cancer cells. Aims to increase the response of the body against cancer cells.

Question 29

Tumour suppressor genes

Answer 29

Genes that slow down cell division by using proteins that they encoded to help prevent uncontrolled cell growth.

Question 30

Mutagens

Answer 30

Substances that caused mutations

Ex. X-rays and ultraviolet radiation

Question 31

Stem cell theory of cancer

Answer 31

Each organ in the body contains specific stem cells that control reproduction/growth of an organ by replacing damaged or aged cells.

It is believed that cancerous stem cells may trigger reproduction and growth of cells within a cancer. Even if you get rid of the majority of the tumour if you do not get rid of these underlying stem cells, it may come back.

Question 32

Telomeres

Answer 32

Structures found at the end of a human chromosome that contain many repeating units of a specific DNA sequence

A cells age, telomeres shorten and when they become too short the cell can no longer divide.

Question 33

Telomerase

Answer 33

An enzyme that lengthens the telomeres, and adds on more repeating units of DNA sequences.

This enzyme in commonly found in cancer cells, so it helps cancer cells continue to divide way past the time when normal cells would stop dividing. (Usually would stop after 50 division)

Question 34

Angiogenesis

Answer 34

A process that rapidly dividing cancer cells used to stimulate the formation of new blood vessels towards them

(Angi = vessels)

Question 35

Ras oncogene example

Answer 35

Normally the ras gene produces a relay protein.

If there is an ras oncogene, it will produce a hyperactive relay protein that can function even without a growth factor.

Present in 30% of cancers

Question 36

p53 oncogene example

Answer 36

Normally a p53 gene will produce a transcription factor protein (help turn certain genes on/off)

A p53 oncogene will produce a faulty transcription factor protein that fails to make a protein that stops cell division

Present in 50% of cancers

Question 37

Carcinogens

Answer 37

(aka “cancer causing agents”)

Factors that alter DNA and make cells cancerous

Ex. Cigarette smoke, UV rays

Question 38

Does cancer run in families?

Answer 38

It can, individuals may receive a oncogene allele from a parent, and are more likely to develope cancer than individuals without such mutations

But the majority of cancers are not associated with a inherited mutation from parent to offspring, they arise from environmental factors (like UV exposure)

Question 39

What are the best and worst types of cancer based on survival rates

Answer 39

Best:
Thyroid and testicular cancer (97% survival rate)

Worst:
Pancreas cancer (10% survival rate)

Question 40

What are the most notable risk factors for cancer?

Answer 40

1. Smoking
2. Unhealthy lifestyle
3. Alcohol
4. Sunlight / tanning beds
5. Cancer-related infections (HPV, Hep B)
6. Environmental/occupational hazards (ex. asbestos, air pollution)