MODULE 2: FOUNDATIONS IN BIOLOGY - CELL DIVISION + CELLULAR ORGANISATION

Question 1

What does the cell cycle consist of?

Answer 1

Interphase and the M phase (mitosis and cytokinesis)

Question 2

What is interphase divided into?

Answer 2

• Gap phase 1 (G₁)
• Synthesis
• Gap phase 2 (G₂)

Question 3

What are the four stages in Mitosis?

Answer 3

• Prophase
• Metaphase
• Anaphase
• Telophase

Question 4

What happens during interphase?

Answer 4

• Cell carries out normal functions, but prepares for division
• Cell’s DNA is unravelled + replicated to double genetic content
• Organelles also replicated so it has spare ones
• ATP content increased (to provide energy for cell division

Question 5

What happens during prophase?

Answer 5

• Chromosomes condense, getting shorter and fatter
• Tiny bundles or protein (centrioles) start moving to opposite ends of the cell, forming a network of proteins fibres across it called the spindle
• Nuclear envelope breaks down + chromosomes free in the cytoplasm

Question 6

What happens during metaphase?

Answer 6

• Chromosomes (each with two chromatids) line up along the middle of the cell and become attached to the spindle by their centromere
• At this metaphase checkpoint, the cell checks that all the chromosomes are attached to the spindle before mitosis can continue

Question 7

What happens during anaphase?

Answer 7

• The centromeres divide, separating each pair of sister chromatids
• The spindles contract, pulling chromatids to opposite ends of the cell, centromere first

Question 8

What happens during telophase?

Answer 8

• The chromatids reach the opposite poles on the spindle
• They uncoil and become long and thin again
• They’re now called chromosomes again
• A nuclear envelope forms around each group of chromosomes, so there are now two nuclei

Question 9

What happens during cytokinesis?

Answer 9

• The cytoplasm divides
• In animal cells, a cleavage furrow forms to divide forms to divide the cell membrane
• There are now two daughter cells that are genetically identical to the original cell and to each other
• Cytokinesis usually begins in anaphase + ends in telophase
• SEPARATE TO MITOSIS

Question 10

What is a centromere?

Answer 10

This joins two strands (chromatids) in the middle to make up a chromosome during interphase

Question 11

What is mitosis?

Answer 11

Asexual reproduction of a cell. Results in two identical daughter cells

Question 12

What is meiosis?

Answer 12

Sexual reproduction of a cell to produce gametes. Results in four haploid cells

Question 13

What are gametes?

Answer 13

The sex cells (sperm cells in males and egg cells in females)

Question 14

What is a reduction division?

Answer 14

Cells that divide by meiosis have the full number if chromosomes to start with, but the cells that are formed from meiosis have half the number in the end

Question 15

Explain what is meant by haploid

Answer 15

Haploid cells are cells with half the normal number of chromosomes

Question 16

Explain what is meant by diploid

Answer 16

A cell or organism that contains two complete sets of chromosomes (23 pairs of chromosomes or 46 chromosomes)

Question 17

What are the two divisions of meiosis?

Answer 17

• Meiosis I (this is the reduction division - halves the chromosome number)
• Meiosis II

Question 18

What are the stages of Meiosis I?

Answer 18

• Prophase I
• Metaphase I
• Anaphase I
• Telophase I

Question 19

What are the stages of Meiosis II?

Answer 19

• Prophase II
• Metaphase II
• Anaphase II
• Telophase II

Question 20

What happens during prophase I?

Answer 20

• Chromosomes condense (getting shorter and fatter)
• The chromosomes then arrange themselves into homologous pairs and crossing over occurs
• Centrioles start moving to opposite ends of the cell, forming spindle fibres
• The nuclear envelope breaks down

Question 21

What are homologous pairs?

Answer 21

Pairs of chromosomes originating from each parent (one from the mother and one from the father)

(Imagine two chromosomes sitting next to each other in class so they get picked to be in the same group)

Question 22

What is crossing over?

Answer 22

• Occurs between chromatids
• Chromatids from separate chromosomes (bit are in a pair) twist around each other and bits of chromatids swap over
• The chromatids still contain the same genes, but now have a different combination of alleles

Question 23

What happens during metaphase I?

Answer 23

• The homologous pairs line up across the centre of the cell and attach to the spindle fibres by the centromeres

Question 24

What happens during anaphase I?

Answer 24

• The spindles contract, separating the homologous pairs (one chromosome from each pair goes to each end of the cell)

Question 25

What happens during telophase I?

Answer 25

A nuclear envelope forms around each group of chromosomes

Question 26

What happens during prophase II?

Answer 26

• Chromosomes condense, getting shorter and fatter
• Tiny bundles or protein (centrioles) start moving to opposite ends of the cell, forming a network of proteins fibres across it called the spindle
• Nuclear envelope breaks down + chromosomes free in the cytoplasm

Question 27

What happens during metaphase II?

Answer 27

• Chromosomes (each with two chromatids) line up along the middle of the cell and become attached to the spindle by their centromere
• At this metaphase checkpoint, the cell checks that all the chromosomes are attached to the spindle before mitosis can continue

Question 28

What happens during anaphase II?

Answer 28

• The pairs of sister chromatids are separated - each new daughter cell inherits one chromatid from each chromosome
• Four (genetically different) haploid daughter cells are produced - these are the gametes

Question 29

What happens during telophase II?

Answer 29

• The chromatids reach the opposite poles on the spindle
• They uncoil and become long and thin again
• They’re now called chromosomes again
• A nuclear envelope forms around each group of chromosomes, so there are now two nuclei

Question 30

How many cells does meiosis produce?

Answer 30

Four

Question 31

What happens to homologous pairs of chromosomes during meiosis I?

Answer 31

• They cross over during prophase I, where chromatids respective to each chromosome twist around each other and swap chromatids
• These chromosomes contain the same genes, but have a different combination of alleles

Question 32

What two main events during meiosis lead to genetic variation?

Answer 32

• Crossing over of chromatids
• Independent assortment of chromosomes

Question 33

What is independent assortment of chromosomes?

Answer 33

• Each homologous pair of chromosomes in our cells is made up of one chromosome from our mother and one chromosome from our father
• When the homologous pairs line up in metaphase I + are separated in anaphase I, it’s completely random which chromosome from each pair ends up in which daughter cell
• So the four daughter cells produced by meiosis have completely different combinations of those maternal and paternal chromosomes
• This ‘shuffling’ of chromosomes leads to genetic variation in any potential offspring

Question 34

What are stem cells?

Answer 34

Unspecialised cells that can differentiate into different types of cell

Question 35

What are stem cells used for in animals?

Answer 35

To replace damaged cells (e.g. to make new skin or blood cells)

Question 36

What are stem cells used for in plants?

Answer 36

To make new shoots and roots throughout their lives
Stem cells can differentiate into various plant tissues including xylem and phloem

Question 37

Stem cells in bone marrow can differentiate into other cell types. Name two of these cell types

Answer 37

• Erythrocytes (red blood cells)
• Neutrophils (white blood cells that help to fight infection)

Question 38

Where are stem cells found in plants?

Answer 38

Meristems

Question 39

What cell types can stem cells in the root and stem differentiate into?

Answer 39

• Xylem vessels
• Phloem sieve tubes

Question 40

Describe how stem cells might be used to treat Alzheimer’s

Answer 40

• With Alzheimer’s, nerve cells in the brain die in increasing numbers
• This results in severe memory loss
• Researchers help to use stem cells to regrow healthy nerve cells in people with Alzheimer’s

Question 41

Describe how stem cells might be used to treat Parkinson’s

Answer 41

• Patients with Parkinson’s suffer from tremors that they can’t control
• The disease causes the loss of a particular type of nerve cell found in the brain
• These cells release a chemical called dopamine, which is needed to control movement
• Transplanted stem cells may help to regenerate the dopamine-producing cells

Question 42

Name four specialised animal cells

Answer 42

• Neutrophils
• Erythrocytes
• Epithelial cells
• Sperm cells

Question 43

Name three specialised plant cells

Answer 43

• Palisade mesophyll cells
• Root hair cells
• Guard cells

Question 44

Describe how neutrophils are specialised for their functions

Answer 44

• Defend the body against disease
• Flexible shape allows them to engulf foreign particles or pathogens
• The many lysosomes in their cytoplasm contain enzymes to break down the engulfed particles

Question 45

Describe how erythrocytes are specialised for their functions

Answer 45

• Carry oxygen in the blood
• Biconcave disc shape provides a large surface area for gas exchange
• No nucleus so there’s more room for haemoglobin (protein that carries oxygen)

Question 46

Describe how epithelial cells are specialised for their functions

Answer 46

• Epithelial cells cover the surfaces of organs
• Cells joined by interlinking cell membranes + a membrane at their base
• Ciliated epithelia (e.g. in the airways) have cilia that beat to move particles away
• Squamous epithelia (e.g. in the lungs) are very thin to allow efficient diffusion of gases

Question 47

Describe how sperm cells are specialised for their functions

Answer 47

• Have a flagellum (tail) so they can swim to the egg
• They also have a lot of mitochondria to provide energy to swim
• Acrosome (head or part of the head) contains digestive enzymes to enable the sperm to penetrate egg surface

Question 48

Describe how palisade mesophyll cells are specialised for their functions

Answer 48

• Present in leave + do most of photosynthesis
• Contain many chloroplasts, so they can absorb a lot of sunlight
• Thin walls so carbon dioxide can easily diffuse into the cell

Question 49

Describe how root hair cells are specialised for their functions

Answer 49

• Absorb water and mineral ions from the soil
• Large surface area for absorption + thin, permeable cell wall for entry of water + ions
• Cytoplasm contains extra mitochondria to provide energy for active transport

Question 50

Describe how guard cells are specialised for their functions

Answer 50

• Found in pairs, with a gap between them to form a stoma
• In the light, guard cells take up water + become turgid
• Their thin outer walls + thickened inner walls force them to bend outwards, opening the stomata (allows leaf to exchange gases for photosynthesis

Question 51

Definite what is meant by a tissue.

Answer 51

A group of cells, plus any extracellular material secreted by them, that are specialised to work together to carry out a particular function

Question 52

State and briefly describe four animal tissues

Answer 52

• Squamous epithelium - a single layer of flat cells lining a surface (found in many places like alveoli)
• Ciliated epithelium - a layer of cells covered in cilia (found on surfaced where things need to be moved - in trachea where cilia move mucus)
• Muscle tissue - made up of bubbles of elongated cells called muscle fibres | three types: smooth (found in stomach lining), cardiac (found in heart), skeletal (used to move)
• Cartilage - type of connective tissue found in joints - shapes and supports ears, nose and windpipe | formed when cells called chondroblasts secrete an extracellular matrix which they become trapped inside

Question 53

State and briefly describe two plant tissues

Answer 53

• Xylem tissue - has two jobs: transport water around plant + supports the plant | contains hollow xylem vessel cells (dead) and living parenchyma cells
• Phloem tissue - transports sugars around plant | arranged in tubes + is made up of sieve cells,ompanion cells and some ordinary plant cells | each sieve cell has end walls with holes in them, so that sap can move easily through them

Question 54

Define what is meant by an organ

Answer 54

A group of tissues that work together to perform a particular function

Question 55

Name and explain one organ found in plants and one organ found in animals

Answer 55

• Leaves - contain palisade tissue for photosynthesis, as well as epidermal tissue (to prevent water loss from the leaf), and xylem + phloem tissues in the veins
• Lungs - contain squamous epithelial tissue (in the alveoli) + ciliated epithelial tissue (in the bronchi, etc). They also have elastic connective tissue + vascular tissue (in the blood vessels)

Question 56

Define what is meant by an organ system

Answer 56

Organs work together to form organ systems - each system has a particular function

Question 57

Name two organ systems and explain them

Answer 57

• Respiratory system - made up of organs, tissues and cells involved in breathing: lungs, trachea, larynx, nose, mouth and diaphragm
• Circulatory system - made up of the organs involved in blood supply: heart, arteries, veins and capillaries

Question 58

Define totipotent

Answer 58

Can divide and differentiate into any type of cell

Question 59

Define pluripotent

Answer 59

Can self-renew and differentiate into any type of cell except the cells that make up the placenta

Question 60

Define multipotent

Answer 60

Can only differentiate and divide into a limited number of cell types

Question 61

Define unipotent

Answer 61

Can only differentiate into a single type of cell e.g. cardiomyoblasts can only differentiate into cardiomyocytes

Question 62

When can totipotent stem cells be used?

Answer 62

During the first few cell divisions of an embryo

Question 63

What can pluripotent stem cells be used for?

Answer 63

To replace cells and treat human disorders like leukaemia and diabetes

Question 64

What happens at the G₁ checkpoint?

Answer 64

• Chromosomes are checked for damage
• If damage is detected, the cell does not advance to S phase until the damage is repaired

Question 65

What happens at the S checkpoint?

Answer 65

• Chromosomes are checked to ensure they’ve been replicated
• If they haven’t all be successfully replicated, the cell cycle stops

Question 66

What happens at the G₂ checkpoint?

Answer 66

• An additional check for DNA damage occurs after DNA replication
• Cell cycle delayed until necessary repairs have been made

Question 67

What happens at the metaphase checkpoint?

Answer 67

Final check determines whether the chromosomes are corrected attached to the spindle fibres before anaphase

Question 68

What happens during G₁ phase in interphase?

Answer 68

• A signal is received telling the cell to divide again
• Cells make RNA, enzymes and other proteins required for growth

Question 69

What happens during S phase in interphase?

Answer 69

• Relatively short
• DNA in the nucleus replicates - results in each chromosome consisting of two identical sister chromatids

Question 70

What happens during G₂ phase in interphase?

Answer 70

• Cell continues to grow and the new DNA that has been synthesised is checked and any errors are repaired