6 - Cell division

Question 1

phases of the cell cycle

Answer 1

Interphase
-> G1
——> G1 checkpoint
-> S
-> G2
——> G2 checkpoint

Mitotic phase
-> mitosis
——-> spindle assembly checkpoint
-> cytokinesis

G0

Question 2

interphase

Answer 2

long periods or growth and normal working , where the cell is carrying out its major functions
-> G1 - first growth phase
-> S - synthesis phase
-> G2 - second growth phase

Question 3

during interphase

Answer 3

• DNA is replicated and checked for errors in the nucleus
• protein synthesis
• mitochondria grow and divide, increasing in number
• chloroplast grow and divide in plant and algal cell
• normal metabolic processes occur - respiration

Question 4

stages of interphase

Answer 4

G1 - the first growth phase: proteins from which organelles are synthesised are produced and organelles replicate, cell increases in size
s - synthesis phase: DNA is replicated in the nucleus
G2 - second growth phase : cell continues to increase in size, energy stores are increased and the duplicated DNA is checked for errors

Question 5

mitotic phase stages

Answer 5

• mitosis - nucleus divides
• cytokinesis - cytoplasm divides and two daughter cells produce

Question 6

what is G0

Answer 6

• the name for when the cell leaves the cycle, either temporarily or permanently

Question 7

why would a cell go into G0

Answer 7

• differentiation - a cell that becomes specialised to carry out a particular function is no longer able to divide. it will carry out this function indefinitely and not enter the cell cycle again
• DNA of a cell may be damaged, if so it is no longer viable, therefore it wont divide and enters a period of permanent cell arrest (G0)

Question 8

Control of the cell cycle

Answer 8

checkpoints are the control mechanism of the cell cycle- they monitor and verify whether the processes at each phase have been carried out accurately before the cell progresses onto the next phase

it ensures the fidelity of cell division

Question 9

what are the checkpoints of the cell cycle

Answer 9

G1 Checkpoint (Restriction Point):

This checkpoint occurs at the end of the G1 phase before the cell enters the S phase.
It assesses whether the conditions are favourable for DNA replication to proceed.
If conditions are not suitable it enters G0

G2 Checkpoint:

This checkpoint occurs at the end of the G2 phase before the cell enters the M phase (mitosis).
It ensures that DNA replication has been completed accurately and that the cell is ready for mitosis.
If DNA damage is detected , the cell cycle may be halted

Spindle Assembly Checkpoint:

This checkpoint occurs during metaphase, after the chromosomes have aligned at the metaphase plate but before the sister chromatids separate.
It monitors the attachment of spindle fibres to the kinetochores of sister chromatids.
If all chromosomes are not properly attached to the spindle apparatus, the cell division process is delayed until proper attachment is achieved, preventing errors in chromosome segregation.

Question 10

why is mitosis important

Answer 10

ensures that both daughters produced are genetically identical
- each have the exact copy of DNA present in the parent cell and have the same number of chromosomes
- growth replacement and repair of tissues
- necessary for asexual reproduction
-

Question 11

chromosome structure and subsets

Answer 11

before replication:
one chromosome has one chromatid

after replication:
one chromosome has two chromatids

after mitotic division:
one chromosome has one chromatid

centromere is where two sister chromatids are joined
together

Question 12

stages of mitosis

Answer 12

prophase
metaphase
anaphase
telophase

Question 13

Prophase

Answer 13

• Chromatin condenses into visible chromosomes.
• The nucleolus becomes less distinct or disappears entirely
• nuclear envelope/membrane breaks down.
• spindle formation begins
  centrioles migrate to opposite poles
• spindle fibres attach to centromeres and start to move chromosomes

Question 14

metaphase

Answer 14

chromosomes are moved by the spindle fibres to form a plane at the centre of the cell, called the metaphase plate, and then held in position

Question 15

anaphase

Answer 15

• centromeres divide
• chromatids are separated and pulled to opposite poles by shortening spindle fibres

Question 16

telophase

Answer 16

• chromatids reach the poles and are now called chromosomes
• nuclear envelop forms around each chromosome
• chromosomes start to uncoil and the nucleolus if formed

Question 17

cytokinesis in animals

Answer 17

• a cleavage furrow forms around the middle of the cell
• the cell-surface membrane is pulled inwards by the cytoskeleton, until its close enough to fuse around he middle forming two cells

Question 18

cytokinesis in plant cells

Answer 18

• cant form cleavage furrow as cell wall is too strong
• vesicles from Golgi apparatus assemble at the centre of the cell
• they fuse together as well as the cell surface membrane- forming two cells
• new sections of the cell wall form along the new sections of the membrane

Question 19

what is meiosis

Answer 19

the nucleus divides twice to form 4 daughter cells which contain half the number of chromosomes than the parent cell- haploid

• this is to form gametes

Question 20

what are homologous chromosomes

Answer 20

are pairs of chromosomes that contain similar genetic information.

They are inherited, one from each parent, and are similar in size, shape, and gene sequence.

Homologous chromosomes carry alleles for the same genes at the same loci, but these alleles may be different variants (alleles) of the gene.

Question 21

allele

Answer 21

different versions of the same gene - have the same locus

Question 22

stages of meiosis

Answer 22

meiosis I - firs division where the homologous chromosomes are separated into two cells

meiosis II - second division the pairs of chromatids are separated forming two more cells- 4 haploid cells are produced

Question 23

Meiosis I

Answer 23

Prophase I
Metaphase I
Anaphase I
Telophase I

Question 24

Meiosis II

Answer 24

Prophase II
Metaphase II
Anaphase II
Telophase II

Question 25

Prophase I

Answer 25

chromosomes condense, nuclear envelope disintegrates, nucleolus disappears and spindle formation begins

-homologous chromosomes pair up to form bivalents
- crossing over also occurs- the exchange of genetic material between homologous chromosomes

Question 26

metaphase 1

Answer 26

• homologous pairs assemble along the metaphase [;ate
• independent assortment happens - the orientation of each homologous pair is random and independent. this results in genetic variation

Question 27

Anaphase 1

Answer 27

• homologous chromosomes are pulled to opposite poles and the chromatids stay joined together
• sections of DNA on the chromatids which became entangle during crossing over break off and rejoin - resulting in the exchange of DNA
• the point where the chromatids break and rejoin is called chiasmata
• this forms recombinant chromatids, with genes being exchanged, which could be different alleles of the same gene, meaning the alleles are different from the original chromatid

genetic variation arises

Question 28

telophase 1

Answer 28

chromosomes assemble at the poles and the nuclear membrane reforms, chromosomes uncoil

cell undergoes cytokinesis and divides into two cells

haploid cells form

Question 29

Prophase II

Answer 29

chromosomes condense and become visible
nuclear envelop breaks down and spindle formation begins

Question 30

metaphase II

Answer 30

individual chromosomes line up on metaphase plate

independent assortment and genetic variation

Question 31

anaphase II

Answer 31

chromatids of the individual chromosomes are pulled to opposite poles after division of centromeres

Question 32

telophase II

Answer 32

chromatids assemble at the poles

chromosomes uncoil to form chromatin

nuclear envelop forms and nucleolus is visible

cytokinesis to form 4 daughter haploid cells
-> they are genetically different from each other and the parent cell (due to crossing over and independent assortment

Question 33

Crossing Over

Answer 33

Bivalents develop. Homologous chromosomes come together to form bivalents.

Chiasmata form. Non-sister chromatids wrap around each other, and they join up at certain points (called chiasmata)

Chromosomes break. The chromosomes can break up at the chiasmata, and sections of chromosomes may swap over between non-sister chromatids. The swapping over is only between non-sister chromatids.

Recombination occurs. The final chromatids still have the same genes, but they may have different alleles

Question 34

Independent Assortment

Answer 34

independent assortment means that each chromosome is inherited randomly and independent of other chromosomes

In meiosis II, each pair of homologous chromosomes is split up. Remember, in any cell the homologous pair consists of two chromosomes which may or may not be identical. When the pair splits up, each daughter cell will receive one chromosome. The allocation of this is completely random – hence we call it independent assortment.

Question 35

Why is meiosis important for producing variation?

Answer 35

Meiosis is important for producing variation because it shuffles the genetic material in a way that leads to the formation of new combinations of alleles, or different versions of genes. This variation contributes to the diversity of traits found in a population and is an important mechanism for the evolution of species.

Question 36

How does meiosis contribute to evolution?

Answer 36

Meiosis contributes to evolution by producing genetic variation that can be selected by natural selection. This variation allows species to adapt to changing environments and helps to drive the process of evolution over time

Question 37

erythrocytes

Answer 37

• flattened biconcave shape = increases surface area
• in mammals they don’t have a nucleus = increases space for haemoglobin
• flexible = able to squeeze through narrow capillaries

Question 38

Neutrophils

Answer 38

• role in the immune system
• multi-lobbed nucleus= easier to squeeze through gaps to get to the site of infection
• granular cytoplasm contains many lysosome that contain enzymes used to attack pathogens

Question 39

sperm cell

Answer 39

• male gametes
• deliver genetic info to the female gamete
• tail/flagellum so they are capable of movement
• contain any mitochondria to supply the energy to swim
• acrosome in top of head contains digestive to digest layers of the ovum and let the sperm penetrate and fertilise

Question 40

Palisade cell

Answer 40

• present in mesophyll
• contains chlorophyll to absorb large amounts of light for PHS
• rectangular and can be closely packed to form a continuous layer
• thin cell walls = increase ROD
• chloroplasts can move in cytoplasm to absorb more light

Question 41

root hair cells

Answer 41

• present in the surfaces of the roots near growing tips
• have long extension called root hairs = increase surface area for RO movement

Question 42

Guard cells

Answer 42

• on the surfaces of leaves and form the stomata
• necessary for CO2 to enter for PHS
• when they lose water they become less swollen and change shape and the stomata closes to prevent water loss
• cell wall of guard cell is thicker on one side so they cell doesn’t change shape symmetrically

Question 43

main categories of tissue in animals

Answer 43

• nervous tissue - adapted to support the transmission of electrical impulses
• epithelial tissue - adapted to cover surfaces
• muscle tissue - contraction
• connective tissue - adapted to hold tissues together or as a transport material

Question 44

squamous epithelium

Answer 44

• made of squamous epithelial cells
• flat
• very thin due to the flat cells that make it up- one cell thick
• to increase ROD
• forms the lining of the lungs
• basement membrane

Question 45

ciliated epithelium

Answer 45

• made of ciliated epithelial cells
  -have hair like structures called cilia that move in a rhythmic manner
• it lines the trachea
• has goblet cells that release mucus to trap any unwanted particles in the air

Question 46

cartilage

Answer 46

• a connective tissue found in outer ear, nose and between bones
• contains fibres of elastin and collagen’ - t is a firm, flexible connective tissue made of chondrocyte cells embedded in an extra cellular matrix
• prevent bones from rubbing together and causing damage

Question 47

muscle

Answer 47

• tissue needs to shorten in length to move bends
• skeletal- contains myofibrils

Question 48

types of tissue in plants

Answer 48

• epidermis - covers the plant
• vascular tissue - adapted for transport of water and nutrients

Question 49

epidermis

Answer 49

• single layer that covers the surface of plants
• closely packed cells
• covered by a waxy, waterproof cuticle to reduce the loss of water
• contains pairs of guard cells that form the stomata which can open close allowing CO2 O2 and H2O in and out

Question 50

xylem

Answer 50

a vascular tissue that transports water and minerals throughout plants
- composed of dead elongated cells strengthened with lignin which provides structural support

Question 51

phloem tissue

Answer 51

vascular tissue
transports organic nutrients like sucrose from the leaves and stems where it is made by PHS to other areas
- made of sieve tubes cells separated by perforated walls called sieve plates

Question 52

organ

Answer 52

collection of tissues that are adapted to perform a particular function un organism

Question 53

organ systems

Answer 53

composed of a number of organs working togehter to carry out a major function in the organism

Question 54

differentiation

Answer 54

the process of a cell becoming specialisd
-> it involves the expression of some genes but not others in the cells genome

Question 55

undifferentiated cells

Answer 55

• cells begin as this (after mitosis and meiosis)
• not adapted for a particular function
• have the potential to differentiate to become any type of cell
• called stem cells

Question 56

stem cell potency

Answer 56

-the ability of a stem cell to differentiate into different cells
- greater the number of cells it can differentiate into, the greater the potency
totipotent
pluripotent
multipotent

Question 57

totipotent

Answer 57

stem cells that can differentiate into any type of cell
- a fertilised egg/ zygote

Question 58

pluripotent

Answer 58

stem cells can form all tissue types but not organisms
- present in early embryos and are the origin of the different type of tissue within the organism

Question 59

multipotent

Answer 59

stem cells that can only form a range of cells within a certain type of tissue

Haematopoietic cells in bone marrow

Question 60

replacement of RBC and WBC

Answer 60

• have no nucleus so and lack of organelles so have a short lifespan - so need to be replaced constantly
• stem cell colonies in bone marrow produce large amounts or RBC
• WBC last for 6hrs
  RBC las 120 days

Question 61

sources of stem cells

Answer 61

• embryonic
• tissue

Question 62

embryonic stem cells

Answer 62

• cells present at early stages of embryo development
• totipotent
• after 7 days a mass of cells- blastocyst has formed and cells ow pluripotent

Question 63

tissue stem cells

Answer 63

• present throughout life
• found in specific areas like bone marrow
• multipotent
• or the umbilical cord

Question 64

sources of plant stem cells

Answer 64

• present in meristematic tissue - found in roots and shoots (apical meristems)
• also found between the phloem and xylem - the vascular cambium
  -> cells here differentiate into into cells in the xylem and phloem
• pluripotent