Cell Structure & Diversity 3- Cell Walls & Respiration

Question 1

What is a plant cell composed of?

Answer 1

Cell wall and protoplast

Question 2

What is the protoplast?

Answer 2

Cell membrane and everything found inside it

Question 3

What structures are unique to plant cells?

Answer 3

Cell wall, plasmodesmata, chloroplasts and central vacuole

Question 4

What is the main component of the cell wall?

Answer 4

Cellulose

Question 5

What is the structure of cellulose?

Answer 5

A glucose polymer that is highly ordered and forms long ribbon-like structures

Question 6

How does the structure of cellulose help the cell wall?

Answer 6

The highly ordered structure of cellulose makes it very strong and when multiple cellulose ribbons cross link to from microfibrils it makes a strong and inert structure.

Question 7

What is the first phase of the cell wall and what is involved?

Answer 7

Crystalline Microfibullar Phase which involves cellulose

Question 8

What is the second phase of the cell wall and what is involved?

Answer 8

Noncrystalline Matrix which involves pectin and hemicellulose polysaccharides as well as a network extension protein

Question 9

What is hemicellulose?

Answer 9

A heterogenous group of polysaccharides. A long chain of one type of sugar and a short side chain forms a rigid structure.

Question 10

What is pectin?

Answer 10

Branched negatively charged polysaccharides which bind water and have gel-like properties.

Question 11

What is the function of extensin?

Answer 11

Extension cross linking of pectin and cellulose dehydrates the cell wall, reduces extensibility and increases strength.

Question 12

What is controlled by extension cross linking?

Answer 12

Expanding of cells

Question 13

Where is the cell wall made?

Answer 13

Outside of the cell

Question 14

What organelles are needed to make the cell wall?

Answer 14

Golgi complex and rough ER

Question 15

What are the organelles needed for in making the cell wall?

Answer 15

Coordinating synthesis and delivery of cellulose microfibrils, polysaccharides (pectin and hemicellulose) and cell wall proteins (extensins)

Question 16

Where are cellulose microfibrils made and what by?

Answer 16

At the plasma membrane by rosettes

Question 17

Where are the polysaccharides made?

Answer 17

At the Golgi complex and then transported to the cell wall using vesicles

Question 18

What makes extensions?

Answer 18

Rough ER

Question 19

How are materials for the cell wall transported?

Answer 19

In vesicles by constitutive exocytosis and the vesicles then fuse to the plasma membrane and release the contents outside

Question 20

What are rosettes attached to?

Answer 20

Cortical Microtubules

Question 21

How do rosettes make microfibrils?

Answer 21

Move along the microtubules and joins glucose molecules together to make the cellulose microfibril

Question 22

What is affected by the way the microtubules are laid?

Answer 22

Where the cellulose is formed and therefore the cell shape

Question 23

What is the middle lamella?

Answer 23

The sticky portion between the cells which sticks them together

Question 24

What are the functions of the cell wall?

Answer 24

Regulating the shape, providing structural support and preventing excessive water uptake

Question 25

What happens if the cellulose microfibrils are randomly orientated?

Answer 25

The cell will expand equally in all directions

Question 26

What happens if the cellulose microfibrils are laid at right angles to the ultimate longitudinal axis?

Answer 26

Cell will expand longitudinally along that axis

Question 27

How does the cell wall provide structural support?

Answer 27

The protoplast pushes against the cell wall making the cell wall become rigid and therefore maintaining the plant structure

Question 28

How does wilting occur?

Answer 28

When the protoplast ins’t pushing against the cell wall

Question 29

What causes wilting?

Answer 29

When water is lost from the cells it reduces the protoplast volume causing it to not press on the cell wall

Question 30

What happens when water enters a plant cell?

Answer 30

The protoplast expands and pushes against the cell walls. Equal and opposite pressure of the cell wall pushing back prevents the cell getting too large

Question 31

What does pressure from the cell do?

Answer 31

Limit the volume of water that can be taken up

Question 32

What are vacuoles important for and why?

Answer 32

Preventing excessive water uptake because they contain water and make up such a large portion of the protoplast

Question 33

What is a vacuole?

Answer 33

An organelle surrounded by a highly selective membrane which is similar to the plasma membrane

Question 34

How does water enter the vacuole?

Answer 34

Passively by osmosis

Question 35

What is found in high concentration in the vacuole and what does this result in?

Answer 35

Solutes which causes water uptake into the vacuole by osmosis

Question 36

What happens when an animal cell is in a hypotonic solution?

Answer 36

It becomes lysed (burst)

Question 37

What happens when a plant cell is in a hypotonic solution?

Answer 37

It becomes turgid (normal)

Question 38

What happens to plant and animal cells in isotonic solution?

Answer 38

They remain normal

Question 39

What happens to animal cells in a hypertonic solution?

Answer 39

It becomes shrivelled

Question 40

What happens to plant cells in a hypertonic solution?

Answer 40

It becomes plasmolyzed

Question 41

Do all plants have a secondary cell wall?

Answer 41

No

Question 42

When is the secondary cell wall produced?

Answer 42

After cell growth has stopped

Question 43

How does the secondary cell wall compare to the primary cell wall?

Answer 43

It is thicker and stronger so therefore provides more structural support

Question 44

What is the structure of the secondary cell wall?

Answer 44

It is made up of multiple layers of microfibrils which are each orientated in different directions so it is thick and strong

Question 45

Where is the secondary cell wall made?

Answer 45

The secondary cell wall is made closer to the cell because the primary cell wall has already been made

Question 46

What are the chemical characteristics of the secondary cell wall?

Answer 46

It is made of more cellulose and less pectin as well as lignin

Question 47

What is lignin?

Answer 47

Lignin is a complex polymer which confers strength and rigidity to the cell wall and also acts to exclude water

Question 48

What does the secondary cell wall provide structure for?

Answer 48

Specific cell types such as water transporting cells and for the whole plane

Question 49

What are plasmodesmata?

Answer 49

Intercellular connections which enable cell to cell communication

Question 50

How is the plasmodesmata made?

Answer 50

The plasma membrane from one cell wraps around to the plasma membrane of the other cell so that it is continuous

Question 51

What is the size of the plasmodesmata?

Answer 51

Small enough to prevent organelle movements although the endoplasmic reticulum is connected through the plasmodesmata

Question 52

What does the plasmodesmata allow?

Answer 52

The free exchange of small molecules

Question 53

Why does the cell need energy?

Answer 53

For mechanical work, to make new materials, for transport and to maintain order

Question 54

What is meant by mechanical work?

Answer 54

Motor proteins moving vesicles around

Question 55

What is meant by making new materials?

Answer 55

For growth and division as enzymatic reactions such as cell division require ATP

Question 56

What is meant by transport?

Answer 56

Molecules moving across membranes against the concentration gradients needs energy.

Question 57

What is the site of cellular respiration?

Answer 57

Mitochondria

Question 58

What is the formula for respiration?

Answer 58

C6H12O6 + 602&raquo_space;> 6CO2 + 6H2O + ENERGY

Question 59

What are the two key compartments of the mitochondria?

Answer 59

Matrix and inner membrane

Question 60

What is the approximate length of mitochondria?

Answer 60

1-10 micrometres long

Question 61

How many mitochondria are in a cell?

Answer 61

1-1000’s per cell depending on its energy requirements

Question 62

What does mitochondria contain?

Answer 62

Mitochondrial DNA and ribosomes but it doesn’t produce all mitochondrial proteins

Question 63

How many membranes does a mitochondrion have?

Answer 63

2

Question 64

What are the names of the membranes in mitochondria?

Answer 64

Inner and outer mitochondrial membrane

Question 65

Where is the matrix found?

Answer 65

Inside the inner mitochondrial membrane

Question 66

What are cristae?

Answer 66

Folds in the inner mitochondrial membrane

Question 67

Why are cristae important?

Answer 67

Because they provide a large surface ares for reactions to occur

Question 68

What is the inter membrane space?

Answer 68

The space between the inner and outer mitochondrial membrane

Question 69

What is respiration?

Answer 69

When chemical energy from glucose is harvested in three stages which each occur in a different location. Therefore the compartments of the mitochondria are essential for respiration.

Question 70

What are the three stages of respiration?

Answer 70

Glycolysis, Pyrivate Oxidation and Citric acid cycle and Oxidative Phosphorylation

Question 71

Where does glycolysis occur?

Answer 71

In the cytosol

Question 72

What happens during glycolysis?

Answer 72

Sugar (glucose) molecules are broken down into two pyruvate molecules which are 3 carbon molecules

Question 73

What is the products of glycolysis?

Answer 73

2 pyruvate molecules, ATP and high energy electrons which are stores in an electron storing NADH molecule

Question 74

Where does Pyruvate oxidation and the citric acid cycle occur?

Answer 74

In the matrix

Question 75

What happens during pyruvate oxidation?

Answer 75

Pyruvate is converted into Acetyl-CoA and carbon dioxide is also released

Question 76

What happens during the citric acid cycle?

Answer 76

Acetyl CoA enters the citric acid cycle which extracts ATP and high energy electrons in the NADH and FADH2 carriers

Question 77

What are the two parts of Oxidative Phosphorylation?

Answer 77

Electron Transport chain and chemiosmosis

Question 78

Where does the electron transport chain occur?

Answer 78

On the cristae

Question 79

What happens during the electron transport chain?

Answer 79

Electron carriers (NADH and FADH2) shuttle high energy electrons to the inner mitochondrial membrane and the electrons move through protein complexes which are embedded in the membrane. As the electrons move, protons are pumped across the membrane into the intermembrane space using the energy lost from the electrons.

Question 80

What complex does NADH electrons enter?

Answer 80

Complex 1

Question 81

What complex do FADH2 electrons enter?

Answer 81

Complex 2 because they have slightly less energy

Question 82

What happens as a result of the electron transport chain?

Answer 82

Protons accumulate in the inter membrane space making the proton concentration different on either side of the membrane which is crucial for chemiosmosis.

Question 83

Where does chemiosmosis occur?

Answer 83

In the inner membrane protein complex - ATP Synthase which spans from the intermembrane space to the mitochondrial matrix.

Question 84

What happens during chemiosmosis?

Answer 84

The proton gradient means that the protons move through ATP synthase and can power ATP synthesis.

Question 85

What is ATP synthesis?

Answer 85

When a phosphate group is added to and ADP molecule to make ATP

Question 86

What does ATP enable?

Answer 86

The continual release of energy

Question 87

What is the cycle of ATP?

Answer 87

It is continually used and regenerated

Question 88

How is water formed during respiration?

Answer 88

The hydrogen ions which move through ATP synthase combine with oxygen that the cell has consumed