3.1.1 Biological Molecules

Question 1

What is a polymer?

Answer 1

Molecule made of large number of monomers joined together

Question 2

What are monomers?

Answer 2

Small, basic molecular units

Question 3

Name the 3 elements all carbohydrates contain

Answer 3

C, H & O

Question 4

What are the monomers in carbohydrates?

Answer 4

Monosaccharides

(e.g. glucose, fructose, galactose)

Question 5

What type of sugar is glucose?

Answer 5

Hexose sugar (monosaccharide with 6 carbon atoms in each molecule)

Question 6

Name the 2 types of glucose

Answer 6

alpha (α) & beta (β)

Question 7

Draw the skeletal structure for α-glucose

Answer 7

Question 8

Draw the skeletal structure for β-glucose

Answer 8

Question 9

In alpha glucose the OH is…

Answer 9

below the plane of the ring

Question 10

In beta glucose the OH is…

Answer 10

above the plane of the ring

Question 11

What is a condensation reaction?

Answer 11

Joining together of molecules with a chemical bond & the elimination of a water molecule (it’s released)

Question 12

How are monosaccharides joined together?

Answer 12

By condensation reactions

Question 13

What type of bond is formed between the 2 monosaccharides as molecule of water is released?

Answer 13

A glycosidic bond

Question 14

What is formed when 2 monosaccharides join together?

Answer 14

A disaccharide

Question 15

How is sucrose formed?

Answer 15

Formed from condensation reaction between α-glucose molecule and fructose molecule

Question 16

What is lactose formed from?

Answer 16

From glucose molecule & galactose molecule

Question 17

What is maltose formed from?

Answer 17

From 2 α-glucose molecules

Question 18

What is hydrolysis?

Answer 18

Breaking of the chemical bond between monomers using a water molecule

Question 19

When are polysaccharides formed?

Answer 19

When more than 2 monosaccharides are joined together by condensation reactions

Question 20

Where is starch located in organisms?

Answer 20

Many parts of plants in the form of small grains + large amounts found in seeds & storage organs

Question 21

What is the purpose of starch?

Answer 21

Plants store excess glucose as starch

Question 22

How is starch produced?

Answer 22

Condensation of many α-glucose sub units, which then form hydrogen bonds with molecules in the same chain

Question 23

Starch is a mixture of…

Answer 23

2 polysaccharides of alpha-glucose

Question 24

Name the 2 polysaccharides of alpha-glucose found in starch

Answer 24

• Amylose
• Amylopectin

Question 25

Describe the structure of amylose

Answer 25

Long, unbranched chain of α-glucose

Question 26

Describe how the structure of amylose relates to its function

Answer 26

Angles of the glycosidic bonds = coiled structure → makes it compact = can fit more into a small space (= good for storage)

Question 27

Describe the structure of amylopectin

Answer 27

Long, branched chain of α-glucose

Question 28

Describe the structure of amylopectin relates to its function

Answer 28

Its side branches allow the enzymes that break down starch to get at the glycosidic bonds easily = glucose can be released quickly

Question 29

α-glucose molecules are formed by what type of glycosidic bonds?

Answer 29

1,4 & 1,6 glycosidic bonds

Question 30

Where is glycogen located in organisms?

Answer 30

Stored as small granules mainly in liver and some in muscles

Question 31

What is the purpose of glycogen?

Answer 31

In animals: excess glucose is stored as glycogen

Question 32

Glycogen is a p______…

Answer 32

Polysaccharide of α-glucose

Question 33

Describe glycogen’s structure

Answer 33

Very similar to amylopectin BUT has lots more side branches coming off it + shorter chains

Question 34

Describe how glycogen’s structure relates to its function

Answer 34

• Loads of branches & shorter chains = stored glucose can be released even quicker than in starch → important for energy releases in animals
• Very compact molecule, making it good for storage

Question 35

Why is starch suited for its role? 3x

Answer 35

1. Insoluble in water = doesn’t affect water potential (doesn’t cause water to enter cells by osmosis)
2. Compact = lots of it can be stored in small space
3. When hydrolysed, alpha glucose can be easily transported & used in respiration

Question 36

Describe the test for starch

Answer 36

1. Add iodine dissolved in potassium iodide solution to test sample
2. If starch present = sample changes from browny-orange to blue-black colour

(Carried out at room temp.)

Question 37

Describe the structure of cellulose

Answer 37

• Long, unbranched chains of beta-glucose
• Straight cellulose chains run parallel to each other in cell walls = allows hydrogen bonds to form cross-linkages between chains
• Result: formation of bundles called micro fibrils which then join together to make macro fibrils

Question 38

What is the purpose of cellulose?

Answer 38

To provide rigidity to plant cells

Question 39

How does cellulose prevents the cell from bursting as water enters it by osmosis?

Answer 39

By exerting inward pressure that stops any influx (inrush) of water = makes plant cells turgid

Question 40

Why is it important that stems & leaves are in a turgid state?

Answer 40

To provide maximum surface area for photosynthesis

Question 41

Name the 2 types of sugars

Answer 41

Reducing and non-reducing

Question 42

What is a reducing sugar?

Answer 42

Sugars that can donate electrons to another chemical e.g. Benedict’s reagent

i.e. all monosaccharides and some disaccharides (e.g. maltose and lactose)

Question 43

Describe Benedict’s test for reducing sugars

Answer 43

1. Add Benedict’s reagent (blue) to sample & heat it in water bath that’s been brought to a boil (for 5 mins)
2. Test’s positive = orange/red precipitate
3. Higher the concentration of reducing sugar = further the colour change goes

Question 44

Benedict’s Test for Reducing Sugars:

The colour of the precipitate changes from…

Answer 44

Question 45

Benedict’s Test for Reducing Sugars:

What’s a more accurate way of comparing the amount of reducing sugar in different solutions (than colour change)?

Answer 45

Filter solution & weigh precipitate

Question 46

What does it mean if the result of the reducing sugars test is negative (i.e. no precipitate is formed)?

Answer 46

Means a non-reducing sugar present (disaccharides)

Question 47

Describe the test for non-reducing sugars

Answer 47

1. Boil supernatant (new test sample) with dilute hydrochloric acid (in water bath)
2. Then neutralise it with sodium hydrogencarbonate
   
   1. Check solution is alkaline (with pH paper)
3. Carry out Benedict’s test as you would for a reducing sugar
   
   1. If test’s positive = orange/red precipitate
   2. If test’s negative = solution remains blue = no sugar present

Question 48

In the test for non-reducing sugars, why is dilute hydrochloric acid added?

Answer 48

To hydrolyse, break down, the non-reducing sugar (disaccharide) into monosaccharides

Question 49

Name 5 roles of lipids

Answer 49

1. Energy source
2. Flexibility in plasma membranes
3. Protection
4. Insulation
5. Waterproofing

Question 50

Elaborate on lipids’ role as a energy source

Answer 50

When oxidised, lipids = more than twice as much energy per gram as carbohydrates

Question 51

Elaborate on lipids’ role in plasma membranes

Answer 51

Phospholipids contribute to flexibility of membranes & transfer of lipid-soluble substances across them

Question 52

Elaborate on lipids’ role in protection

Answer 52

Stored around delicate organs

Question 53

Elaborate on lipids’ role in insulation

Answer 53

Fats = slow conductors of heat = help retain body heat

Question 54

Elaborate on lipids’ role in waterproofing

Answer 54

Lipids are insoluble in water ∴ waterproof material

• In plants & insects: waxy cuticle to conserve water
• In mammals: produce oil secretion from sebaceous glands in skin

Question 55

Describe the structure of a triglyceride

Answer 55

One molecule of glycerol with 3 fatty acids attached to it

Question 56

What do fatty acids have?

Answer 56

Have long ‘tails’ made from hydrocarbons

Question 57

Properties in triglycerides differ due to variations in ___ __

Answer 57

fatty acids

Question 58

Name 2 kinds of fatty acids

Answer 58

• Saturated
• Unsaturated

Question 59

Draw a saturated fatty acid

Answer 59

Question 60

Draw a unsaturated fatty acid

Answer 60

Question 61

What does the double carbon bond causes the chain to do?

Answer 61

Causes it to kink

Question 62

Define mono-unsaturated

Answer 62

Single double bond

Question 63

Define polyunsaturated

Answer 63

More than one double bond

Question 64

Describe how a triglycerides forms

Answer 64

1. A fatty acid joins to a glycerol molecule
2. When ester bond is formed = molecule of water is released - condensation reaction
3. Process happens twice more = form a triglyceride

Question 65

Why are triglycerides good energy storage molecules?

Answer 65

Long hydrocarbon tails of fatty acids contains lots of chemical energy = lot of energy released when they’re broken down

∴ contain twice as much energy per gram as carbohydrates

Question 66

Describe how the structure of a triglyceride makes them insouble

Answer 66

• Triglycerides clump together as insoluble droplets in cells ∵ fatty acid tails = hydrophobic
• = tails face inwards = shielding themselves from water with their glycerol heads

Question 67

Where are phospholipids found?

Answer 67

In cell membranes

Question 68

Describe the structure of a phospholipid

Answer 68

One molecule of glycerol with 2 fatty acids + a phosphate group attached to it

Question 69

Draw glycerol

Answer 69

Question 70

Draw the basic structure of a fatty acid

Answer 70

Question 71

Draw a triglyceride

Answer 71

Question 72

Phospholipids:
Phosphate group (the 'head') is \_\_\_\_\_\_\_

Answer 72

hydrophilic (attracts water)

Question 73

Phospholipids:
Fatty acid tails is _______

Answer 73

hydrophobic (repel water)

Question 74

Describe how phospholipids’ structures relates to its function

Answer 74

Phospholipids make up the bilayer of cell membranes

1. Heads are hydrophilic & tails are hydrophobic = form double layer with their heads facing out towards the water on either side
2. Centre of bilayer = hydrophobic = water-soluble substances can’t easily pass through
   
   • Membrane acts as a barrier to those substances

Question 75

Describe the emulison test for lipids

Answer 75

1. Shake test substance with ethanol for few minutes so that it dissolves & then pour solution into water
2. Any lipid will show up as a milky emulsion
3. More lipid there is = more noticeable milky colour will be

Question 76

What are the monomers in proteins?

Answer 76

Amino acids

Question 77

What is formed when 2 amino acids join together?

Answer 77

Dipeptide

Question 78

When is a polypeptide formed?

Answer 78

When more than 2 amino acids join together

Question 79

Proteins are made up of one or more ____

Answer 79

polypeptides

Question 80

What are 3 things all amino acids have? (structure wise)

Answer 80

• Carboxyl group (-COOH)
• Amine group (NH₂)
• R group (aka variable side group)

Question 81

All living things share bank of ___ amino acids

Answer 81

20

Question 82

What changes with each amino acid?

Answer 82

The R group

Question 83

What is glycine’s R group?

Answer 83

H

Question 84

Draw an amino acid

Answer 84

Question 85

How are polypeptides formed?

Answer 85

Formed by amino acids linking together by condensation reactions (molecule of water is released during reaction)

Question 86

What is the name of the bond formed between amino
acids?

Answer 86

Peptide bonds

(Combines -OH from carboxyl group and -H from amino acid)

Question 87

Draw a dipeptide

Answer 87

Question 88

What is the primary structure in proteins?

Answer 88

Sequence of amino acids in polypeptide chain

Question 89

What is the secondary structure in proteins?

Answer 89

• Hydrogen bonds form between amino acids in chain
• = makes it coil into alpha helix or fold into beta pleated sheet

Question 90

What is the tertiary structure in proteins?

Answer 90

• Further folding of whole polypeptide chain
• More bonds form between different parts (R groups) of polypeptide chain:
  
  • Hydrogen bonds
  • Ionic bonds
  • Hydrophobic interactions
  • Disulphide bonds

Question 91

Where do disulphide bonds form?

Answer 91

Between R-groups containing sulfur atoms

Question 92

Where do ionic bonds form?

Answer 92

Form between R groups with charges

Question 93

Describe hydrophobic interactions in proteins

Answer 93

When polypeptide chain folds:

• hydrophobic R-groups are in the interior of the folded chain
• whereas hydrophilic R-groups tend to be on the outside

Question 94

What is the quaternary structure in proteins?

Answer 94

Arrangement of 2 or more polypeptide chains in a protein

Question 95

For proteins made … the tertiary structure form their final 3D structure

Answer 95

proteins made from single polypeptide chain

Question 96

For proteins made from … the quaternary structure is protein’s final structure

Answer 96

proteins made from more than one polypeptide chain (e.g. haemoglobin, insulin, collagen)

Question 97

Describe the structure of an enzyme and a property of them

Answer 97

• Roughly spherical in shape due to tight folding of polypeptide chains
• Soluble (& often have roles in metabolism)

Question 98

Describe the structure of antibodies

Answer 98

• Made up of 2 light (short) polypeptide chains & 2 heavy (long) polypeptide chains bonded together
• Have variable regions: amino acid sequences in these
  regions vary greatly

Question 99

Describe the structure of channel proteins (present in cell membranes) and its function

Answer 99

• Contain hydrophobic and hydrophilic amino acids = cause protein to fold up & form a channel
• These proteins transport molecules and ions across membranes

Question 100

Why are structural proteins physically strong?

Answer 100

Consist of long polypeptide chains lying parallel to each other with cross-link between them

Question 101

Describe the biuret test for proteins

Answer 101

1. Test solution needs to alkaline ∴ add few drops of sodium
   hydroxide solution
2. Then add some dilute copper(II) sulfate solution
   
   1. Protein present = turns purple
   2. No protein = solution stays blue
   3. (Colours are pale so look carefully)

Question 102

Name the 2 types of proteins

Answer 102

Fibrous (strands) & Globular (spherical)

Question 103

Give 3 examples of fibrous proteins

Answer 103

Structural:

collagen, muscles (actin & myosin), keratin

Question 104

Give 3 examples of globular proteins

Answer 104

haemoglobin, enzymes, hormones, antibodies

Question 105

What bond/interaction helps in the tertiary structure helps to form the 3D shape of globular proteins?

Answer 105

Hydrophobic interactions (keep circular shape - hydrophobic centre and hydrophilic outside)