Cell Structure

Question 1

What is a eukaryotic cell?

Answer 1

DNA is contained in a nucleus, contains membrane-bound specialised organelles.

Question 2

What is a prokaryotic cell?

Answer 2

DNA is ‘free’ in cytoplasm, no organelles e.g. bacteria & archaea.

Question 3

State the relationship between a system and

specialised cells

Answer 3

Specialised cells → tissues that perform specific function → organs made of
several tissue types → organ systems

Question 4

Describe the structure and function of the cell-surface membrane.

Answer 4

‘Fluid mosaic’ phospholipid bilayer with extrinsic & intrinsic proteins embedded
● Isolates cytoplasm from extracellular environment.
● Selectively permeable to regulate transport of substances.
● Involved in cell signalling / cell recognition.

Question 5

Explain the role of cholesterol in the cell-surface membrane.

Answer 5

Steroid molecule connects phospholipids & reduces fluidity.

Question 6

Explain the role of Glycoproteins in the cell-surface membrane.

Answer 6

Cell signalling, cell recognition (antigens) & binding cells together

Question 7

Explain the role of Glycolipids in the cell-surface membrane.

Answer 7

cell signalling & cell recognition.

Question 8

Describe the structure of the nucleus.

Answer 8

● Surrounded by nuclear envelope, a semi-permeable double membrane.
● Nuclear pores allow substances to enter/exit.
● Dense nucleolus made of RNA & proteins assembles ribosomes.

Question 9

Describe the function of the nucleus.

Answer 9

● Contains DNA coiled around chromatin into chromosomes.
● Controls cellular processes: gene expression determines specialisation & site of mRNA transcription, mitosis, semiconservative replication.

Question 10

Describe the structure of a

mitochondrion.

Answer 10

● Surrounded by double membrane:
- folded inner membrane forms cristae: site of ETC
● Fluid matrix: contains mitochondrial DNA, respiratory enzymes, lipids, proteins.

Question 11

Describe the structure of a chloroplast.

Answer 11

● Vesicular plastid with double membrane.
● Thylakoids: flattened discs stack to form grana; contain photosystems with chlorophyll.
● Intergranal lamellae: tubes attach thylakoids in adjacent grana.
● Stroma: fluid-filled matrix.

Question 12

State the function of mitochondria and chloroplasts.

Answer 12

● Mitochondria: site of aerobic respiration to produce ATP.

● Chloroplasts: site of photosynthesis to convert solar energy to chemical energy.

Question 13

Describe the structure and function of the Golgi apparatus.

Answer 13

Planar stack of membrane-bound, flattened sacs cis face aligns with rER.
Molecules are processed in cisternae vesicles bud off trans face via exocytosis:
● modifies & packages proteins for export
● synthesises glycoproteins

Question 14

Describe the structure and function of a lysosome.

Answer 14

Sac surrounded by single membrane embedded H+ pump maintains acidic conditions contains digestive hydrolase enzymes glycoprotein coat protects cell interior:
● digests contents of phagosome
● exocytosis of digestive enzymes

Question 15

Describe the structure and function of a ribosome.

Answer 15

Formed of protein & rRNA free in cytoplasm or attached to ER.
● Site of protein synthesis via translation:
large subunit: joins amino acids
small subunit: contains mRNA binding site

Question 16

Describe the structure and function of the endoplasmic reticulum (ER).

Answer 16

Cisternae: network of tubules & flattened sacs extends from cell membrane through cytoplasm + connects to nuclear envelope:
● Rough ER: many ribosomes attached for protein synthesis & transport.
● Smooth ER: lipid synthesis.

Question 17

Describe the structure of the cell wall.

Answer 17

● Bacteria:
Made murein.
● Plants:
Made of plasmodesmata: allows molecules to pass between cells, middle lamella acts as boundary between adjacent cell walls.

Question 18

State the functions of the cell wall.

Answer 18

● Mechanical strength and support.
● Physical barrier against pathogens.
● Part of apoplast pathway (plants) to enable easy diffusion of water.

Question 19

Describe the structure and function of the cell vacuole in plants.

Answer 19

Surrounded by single membrane: tonoplast
contains cell sap: mineral ions, water, enzymes, soluble pigments.
● Controls turgor pressure.
● Absorbs and hydrolyses potentially harmful substances to detoxify cytoplasm.

Question 20

Explain some common cell adaptations.

Answer 20

● Folded membrane or microvilli increase SA e.g. for diffusion.
● Many mitochondria = large amounts of ATP for active transport.
● Walls one cell thick to reduce distance of diffusion pathway.

Question 21

State the role of plasmids in prokaryotes.

Answer 21

● Small ring of DNA that carries non-essential genes.

● Can be exchanged between bacterial cells via conjugation.

Question 22

State the role of flagella in prokaryotes.

Answer 22

Rotating tail propels (usually unicellular) organism.

Question 23

State the role of the capsule in prokaryotes

Answer 23

polysaccharide layer:
● Prevents desiccation.
● Acts as food reserve.
● Provides mechanical protection against phagocytosis & external chemicals.
● Sticks cells together.

Question 24

Compare eukaryotic and prokaryotic cells.

Answer 24

both have:
● Cell membrane.
● Cytoplasm.
● Ribosomes (don’t count as an organelle since not membrane-bound).

Question 25

Why are viruses referred to as ‘particles’ instead of cells?

Answer 25

Acellular & non-living: no cytoplasm, cannot self-reproduce, no metabolism.

Question 26

Describe the structure of a viral particle.

Answer 26

● Linear genetic material (DNA or RNA) & viral enzymes e.g. reverse transcriptase.
● Surrounded by capsid (protein coat made of capsomeres).
● No cytoplasm.

Question 27

Describe the structure of an enveloped virus.

Answer 27

● Simple virus surrounded by matrix protein.
● Matrix protein surrounded by envelope derived from cell membrane of host cell.
● Attachment proteins on surface.

Question 28

State the role of the capsid on viral particles.

Answer 28

● Protect nucleic acid from degradation by restriction endonucleases.
● Surface sites enable viral particle to bind to & enter host cells or inject their genetic material.

Question 29

State the role of attachment proteins on viral particles.

Answer 29

Enable viral particle to bind to complementary sites on host cell : entry via endosymbiosis.

Question 30

Describe how optical microscopes work

Answer 30

1. Lenses focus rays of light and magnify the view of a thin slice of specimen.
2. Different structures absorb different amounts and wavelengths of light.
3. Reflected light is transmitted to the observer via the objective lens and eyepiece.

Question 31

Outline how a student could prepare a temporary mount of tissue for an optical microscope.

Answer 31

1. Obtain thin section of tissue e.g. using ultratome or by maceration.
2. Place plant tissue in a drop of water.
3. Stain tissue on a slide to make structures visible.
4. Add coverslip using mounted needle at 45° to avoid trapping air bubbles.

Question 32

Suggest the advantages and limitations of using an optical microscope.

Answer 32

\+ colour image
\+ can show living structures
\+ affordable apparatus
- 2D image
- lower resolution than electron microscopes = cannot see ultrastructure

Question 33

Describe how a transmission electron microscope (TEM) works

Answer 33

1. Pass a high energy beam of electrons through thin slice of specimen.
2. More dense structures appear darker since they absorb more electrons.
3. Focus image onto fluorescent screen or photographic plate using magnetic lenses.

Question 34

Suggest the advantages and limitations of using a TEM.

Answer 34

+ electrons have shorter wavelength than light = high resolution, so ultrastructure visible
+ high magnification (x 500000)
- 2D image
- requires a vacuum = can’t show living structures
- extensive preparation may introduce artefacts
- no colour image

Question 35

Describe how a scanning electron microscope (SEM) works.

Answer 35

1. Focus a beam of electrons onto a specimen’s surface using electromagnetic lenses.
2. Reflected electrons hit a collecting device and are amplified to produce an image on a photographic plate.

Question 36

Suggest the advantages and limitations of using an SEM.

Answer 36

+ 3D image
+ electrons have shorter wavelength than light = high resolution
- requires a vacuum = can’t show living structures
- no colour image
- only shows outer surface

Question 37

Define magnification

Answer 37

Factor by which the image is larger than the actual specimen.

Question 38

Define resolution

Answer 38

Smallest separation distance at which 2 separate structures can be distinguished from one another.

Question 39

Explain how to use an eyepiece graticule and stage

micrometer to measure the size of a structure.

Answer 39

1. Place micrometer on stage to calibrate eyepiece graticule.
2. Line up scales on graticule and micrometer.
3. Count how many graticule divisions are in 100μm on the micrometer.
4. Length of 1 eyepiece division = 100μm / number of divisions
5. Use calibrated values to calculate actual length of
   structures.

Question 40

State an equation to calculate the actual size of a structure from microscopy

Answer 40

actual size = image size/ magnification

Question 41

Outline what happens during cell fractionation

Answer 41

1. Mince and homogenize tissue to break open cells & release organelles.
2. Filter homogenate to remove debris
3. Perform differential centrifugation:

Question 42

Outline what happens during ultracentrifugation

Answer 42

a) Spin homogenate in centrifuge.
b) The most dense organelles in the mixture form a pellet.
c) Filter off the supernatant and spin again at a higher speed.

Question 43

State the order of sedimentation of organelles during differential centrifugation.

Answer 43

most dense → least dense

nucleus → mitochondria → lysosomes → RER → plasma membrane → SER → ribosomes

Question 44

Explain why fractionated cells are kept in a cold, buffered, isotonic solution.

Answer 44

cold: slow action of hydrolase enzymes.
buffered: maintain constant pH.
isotonic: prevent osmotic lysis/ shrinking of organelles.