Paper 1: Topic 1 Cell Biology - Cell division (LV)

Question 1

Name the genetic material found in all living cells

Answer 1

DNA

Question 2

State where the genetic material is located in eukaryotic cells

Answer 2

Contained inside the nucleus

Question 3

State where the genetic material is located in prokaryotic cells

Answer 3

Free in the cytoplasm

Exists as a nucleoid and some bacteria can also have additional small loops of DNA called plasmids

Question 4

Describe how DNA is arranged in eukaryotic cells

Answer 4

As a linear chromosomes

Question 5

Explain the term chromosome

Answer 5

A coiled length of DNA

Question 6

State how many chromosomes are found in human somatic (body) cells

Answer 6

46

Question 7

State how many chromosomes are found in human gametes

Answer 7

23

Question 8

Explain the term diploid

Answer 8

A full set of chromosomes

This is represented as ‘2n’

Question 9

Explain the term haploid

Answer 9

Half a set of chromosomes

This is represented as ‘n’

Question 10

Explain the term ‘cell cycle’

Answer 10

A series of events in which a cell grows, replicates its DNA and then divides to form daughter cells

Question 11

How do human somatic cells divide?

Answer 11

Mitosis

Question 12

What is the function of mitosis?

Answer 12

To produce two GENETICALLY identical daughter cells

Question 13

Why do multicellular organisms use mitosis?

Answer 13

To produce new cells:

a) For growth of tissues and organs
b) To repair damaged tissues and organs
* Remember do not just say “growth and repair” you must say ‘of tissues and organs’ as well*

Question 14

Describe what happens to the chromosome number when a cell undergoes mitosis

Answer 14

It is maintained/kept constant

i.e. remains as 2n (diploid)

Question 15

State the 3 main events during mitosis

Answer 15

DNA replication

Division of DNA

Splitting of the cell into 2

Question 16

Explain what events occur inside a human somatic (body) cell BEFORE it takes part in mitosis

Answer 16

The cell increases in size

The sub-cellular structures (organelles) are replicated

The DNA is replicated (copied) so that there is double the quantity of DNA inside the cell

Question 17

Describe the shape of a chromosome after it has replicated

Answer 17

It will appear as a cross

The 2 strands of DNA are held together by a centromere

Question 18

Describe the relationship between the 2 arms of a chromosome after it has replicated

Answer 18

They are genetically identical

This means they carry the same genes and alleles

Question 19

Describe the main events that take place during mitosis Hint: 6 key events

Answer 19

1. The chromosomes line up in the middle of the cell along the equator
2. Special protein fibres pull the chromosomes apart
3. Half of each chromosome is pulled to the opposite pole of the cell
4. Membranes form around the outside of each set of chromosomes (to form 2 nuclei inside the one cell)
5. The cell splits equally into 2

Question 20

Describe how prokaryotic cells divide

Answer 20

Binary fission

Question 21

Explain the key events that occur during binary fission Hint: 4 events

Answer 21

1. The circular DNA (nucleoid) and plasmids replicate
2. The cell increases in size and the circular DNA moves to the poles of the cell
3. The cytoplasm divides and new cell walls are formed
4. 2 daughter cells are formed each has a circular DNA but they can have variable numbers of plasmids

Question 22

Describe the main features of cell division in bacteria

Answer 22

Occurs by binary fission

Occurs very quickly (~once every 20 minutes)

Question 23

How can you calculate the number of bacteria present after a given period of time?

Answer 23

Calculate the number of minutes in the time period

Divide the number of minutes by 20 (to calculate the number of divisions the bacteria will undertake).

Call this answer ‘x’

Calculate 2 to the power ‘x’ i.e. 2^x

This will be the number of cells present after the specified time period.

Question 24

Define the term stem cell

Answer 24

An unspecialised cell that can replicate to produce more unspecialised cells

All these cells can then differentiate to become specialised cells

Question 25

Explain the term differentiation

Answer 25

The process of an unspecialised cell changing its shape, chemical content and organelle content to become a specialised cell

Question 26

What controls differentiation?

Answer 26

The switching on and off of certain genes inside the unspecialised cell

Question 27

State 2 sources of stem cell

Answer 27

Early embryos

Umbilical cord (after birth)

Adult bone marrow

Question 28

What is special about early embryo stem cells?

Answer 28

They can differentiate into ANY type of specialised cell

Question 29

How are adult stem cells different from embryo stem cells?

Answer 29

Embryo stem cells can differentiate into any type of specialised cell but adult stem cells can only differentiate into certain types of specialised cells e.g. red blood cells

Question 30

How can stem cells be used in medical research

Answer 30

Either type of stem cell can be grown in science laboratories to produce clones

These clones can then be stimulated to differentiate into specific specialised cells

Question 31

Explain what is meant by the term ‘specialised cell’

Answer 31

A cell that has changed its shape, chemical content and/or the organelle content of itself to become suited for a specific function

Question 32

Describe what changes occur in stem cell when it differentiates into a red blood cell

Answer 32

Change in shape = it changes from spherical to biconcave

Change in chemical content = it produces a lot of haemoglobin

Change in organelle content = it breaks down its mitochondria and nucleus

Question 33

State 3 examples of how stem cells can be use to cure disease

Answer 33

1. Adult stem cells taken from the bone marrow of a healthy person can be used to replace faulty blood cells in a patient
2. Embryonic stem cells can be used to replace faulty cells e.g. insulin producing cells can be used to treat people with diabetes nerve cells can be used to treat people with spinal cord injuries (paralysis)
3. Stem cells can be used for therapeutic cloning – they are taken from the patient stimulated to differentiate into the required specialised cells and then returned to the same patient.

Question 34

What is the advantage of using a patient’s own stem cells in therapeutic cloning?

Answer 34

The specialised cells formed from the patient’s stem cells are genetically identical to the patient’s cells and are therefore not rejected

Question 35

What are carried on each chromosome?

Answer 35

Each chromosome carries a large number of genes.

Question 36

What is a gene?

Answer 36

A section of DNA that codes for the production of one specific protein

Question 37

Describe how chromosomes are normally found in somatic (body) cells

Answer 37

In body cells the chromosomes are normally found in pairs.

Question 38

Where are stem cells found in plants?

Answer 38

In the meristematic tissue i.e. root tips and shoot tips

Question 39

What is special about meristematic tissue in plants?

Answer 39

Meristem tissue in plants can differentiate into ANY type of plant cell, THROUGHOUT the life of the plant.

Question 40

State two concerns people have with stem cell treatments

Answer 40

The use of stem cells has potential risks such as transfer of viral infection

Some people have ethical or religious objections.

Question 41

State an advantage for horticulturists who use plant stem cells to produce new plants

Answer 41

Stem cells from meristems in plants can be used to produce clones of plants quickly and economically.

Question 42

State 2 benefits of the use of plant stem cells in research and treatments

Answer 42

Rare species can be cloned to protect from extinction.

Crop plants with special features such as disease resistance can be cloned to produce large numbers of identical plants for farmers.

Question 43

Name the two types of reproduction

Answer 43

1. Asexual reproduction
2. Sexual reproduction

Question 44

Define asexual reproduction

Answer 44

• Asexual reproduction involves only one parent and no fusion of gametes
• There is no mixing of genetic information
• This leads to genetically identical offspring (clones)
• Only mitosis is involved

Question 45

Define sexual reproduction

Answer 45

• Reproduction that involves two parents
• It involves the mixing of genetic information
• This leads to variety in the offspring
• The formation of gametes involves meiosis
• It involves the fusing of gametes

Question 46

State the 2 types of gametes that are involved in sexual reproduction in animals

Answer 46

1. sperm
2. ova (egg cells)

Question 47

State the two types of sex cells (gametes) in plants

Answer 47

1. pollen
2. ova (egg cells)

Question 48

Name 3 organisms that reproduce by both asexual and sexual reproduction

Answer 48

• Malarial parasites
• Fungi
• Plants e.g. strawberry plants

Question 49

State how malarial parasites demonstrate both sexual and asexual reproduction

Answer 49

Malarial parasites reproduce asexually in the human host, but sexually in the mosquito

Question 50

State how fungi demonstrate both sexual and asexual reproduction

Answer 50

• Many fungi reproduce asexually by spores
• They also reproduce sexually by spores to give variation

Remember: fungal spores can be produced asexually and sexually

Question 51

Explain why it is an advantage for fungi to be able to produce spores sexually and asexually

Answer 51

• When conditions are favourable the fungi can produce spores asexually to make many identical spores in a short period of time
• When conditions are unfavourable fungi can produce spores sexually to make genetically different spores to increase the chances of surviving the environmental conditions

Question 52

State how some plants demonstrate both sexual and asexual reproduction

Answer 52

• Flowering plants produce seeds sexually
• They also reproduce asexually by runners such as strawberry plants, or bulb division such as daffodils

Question 53

State the type of cell division involved in asexual reproduction

Answer 53

Mitosis

Question 54

State the type of cell division involved in sexual reproduction

Answer 54

Meiosis

Question 55

Which type of reproduction involves the production of haploid cells

Answer 55

Meiosis

Question 56

State the term that describes the fusing of two gametes to form a zygote

Answer 56

Fertilisation

Question 57

How many chromosomes are found in a gamete?

Answer 57

• Half the full number i.e. haploid (n)
• For human cells this is 23

Question 58

How many chromosomes are found in a somatic (body) cell?

Answer 58

• A full set of chromosomes i.e. diploid (2n)
• For human cells this is 46

Question 59

Explain why sexual reproduction causes greater genetic variation than asexual reproduction

Answer 59

• Sexual reproduction involves the fusing of two gametes
• Each gamete contains genetic material from each parent
• The zygote will have half the DNA from the mother and half from the father
• This mixture of genetic information produces variation

Question 60

State the 4 advantages of sexual reproduction

Answer 60

1. It increases genetic variation
2. Genetic variation increases the chances of survival of the species if there is a change in the environment
3. Genetic variation will mean some individuals will be better adapted to the environment and therefore more likely to survive and breed and pass the successful alleles on to the next generation (called natural selection)
4. Scientists can use selective breeding to speed up natural selection

Question 61

State the 5 advantages of asexual reproduction

Answer 61

1. Only one parent is required (so there is no need to find a mate)
2. This means asexual reproduction uses less energy (no energy used in finding a mate, producing gametes)
3. It is also faster (as no time is used in finding a mate)
4. Many genetically identical offspring can be produced when conditions are favourable
5. It maintains genetic stability by producing genetically identical cells

Question 62

Explain the importance of producing haploid gametes

Answer 62

• Gametes must contain half the chromosomes number so that when 2 gametes fuse during fertilisation the chromosome number is restored
• If the gametes had a full set of chromosomes (2n) then the chromosome number would double at each generation

Question 63

How many daughter cells are produced in mitosis?

Answer 63

2

Question 64

How many daughter cells are produced in meiosis?

Answer 64

4

Question 65

State the 3 main stages of mitosis

Answer 65

1. Copies of the genetic information are made
2. The cell divides once to form two daughter cells, each with a full set of chromosomes(2n)
3. All gametes are genetically identical to each other.

Question 66

State the 3 main stages of meiosis

Answer 66

1. Copies of the genetic information are made
2. The cell divides twice to form four gametes, each with a single set of chromosomes
3. All gametes are genetically different from each other

Question 67

State where meiosis occurs

Answer 67

In the reproductive organs

• testes
• ovaries

Question 68

State the type of cell division that occurs in an embryo to form a fetus

Answer 68

Mitosis

Question 69

How does the cell number change as the embryo forms a fetus?

Answer 69

The number of cells increases
The number of cells doubles after each division

Question 70

As the embryo develops the cells become specialised. Name the process involved.

Answer 70

Differentiation

Question 71

Put these structures in order of increasing complexity:
Gamete, fetus, zygote, organism, embryo

Answer 71

Gamete → zygote → embryo → fetus → organism

Question 72

Give an example of asexual reproduction in plants

Answer 72

• Runners e.g. strawberry plants
• Bulbs e.g. daffodils

Question 73

How many pairs of chromosomes are found in a somatic (body)

Answer 73

23

Please note the questions asked you for the number of PAIRS

Question 74

What is the name for the pair of chromosomes that determines biological sex

Answer 74

Sex chromosomes

Question 75

What 2 sex chromosomes are found in all somatic (body) cells of a biological female?

Answer 75

XX

Question 76

What 2 sex chromosomes are found in all somatic (body) cells of a biolgical male?

Answer 76

XY

Question 77

What percentage of female ova will carry an X chromosome?

Answer 77

100%

Question 78

What percentage of male sperm will carry an X chromosome?

Answer 78

50%

Question 79

What percentage of male sperm will carry a Y chromosome?

Answer 79

50%

Question 80

State which gamete will determine the sex of a human at fertilisation

Answer 80

• Male gamete (sperm)
• If the ovum is fertilised by a sperm carrying an X chromosome the individual will be female.
• If the ovum is fertilised by a sperm carrying a Y chromosome the individual will be male.

Question 81

State the genotype of a human male

Answer 81

XY

Question 82

State the genotype of a human female

Answer 82

XX

Question 83

How many chromosomes are found in a gamete?

Answer 83

• Half the full number i.e. haploid (n)
• For human cells this is 23

Question 84

How many chromosomes are found in a somatic (body) cell?

Answer 84

• A full set of chromosomes i.e. diploid (2n)
• For human cells this is 46