Topic 1: Biological Molecules

Question 1

Monomers

Answer 1

Small, basic molecular units that can form a polymer (e.g. monosaccharides, amino acids and nucleotides).

Question 2

Polymers

Answer 2

Large, complex molecules composed of long chains of monomers joint together.

Question 3

Condensation reaction

Answer 3

Forms a chemical bond between monomers, releasing a molecule of water.

Question 4

Hydrolysis reaction

Answer 4

Breaks the chemical bond between monomers using a water molecule.

Question 5

Hydrogen bond

Answer 5

Weak bonds between a slightly positively charged hydrogen atom in one molecule and a slightly negatively shared atom in another molecule.

Question 6

80%

Answer 6

What percentage of a cell’s contents does water make up?

Question 7

Metabolite

Answer 7

A substance formed in or used by metabolism.

Question 8

Metabolism

Answer 8

The chemical processes that occur within a living organism in order to maintain life.

Question 9

Metabolic rate

Answer 9

A reaction involved in metabolism.

Question 10

Polar covalent bond

Answer 10

A covalent bond in which the atoms have an unequal attraction for electrons, and so the sharing is unequal.

Question 11

Specific heat capacity

Answer 11

The energy required to raise the temperature of 1 gram of a substance by 1°C.

Question 12

Latent heat of vaporisation

Answer 12

The thermal energy required for a liquid to vaporise to a gas or the amount that is released when a gas condenses to a liquid.

Question 13

δ

Answer 13

Slightly

Question 14

Bipolar molecule

Answer 14

A molecule which has a slightly negative charge at one end and a slghtly positive charge at the other.

Question 15

Cohesion

Answer 15

The attraction between molecules of the same type

Question 16

Sugar

Answer 16

A general term for monosaccharides and disaccharides.

Question 17

Monosaccharides

Answer 17

The simplest sugars and the building blocks of carbohydrates

Question 18

Carbon, hydrogen and oxygen

Answer 18

What elements do all carbohydrates contain?

Question 19

Hexose sugar

Answer 19

A monosaccharide with six carbon atoms in each molecule (e.g. glucose)

Question 20

Isomers

Answer 20

Molecules with the same molecular formula as each other, but with the atoms connected in a different way (different structures).

Question 21

Hydroxyl group

Answer 21

-OH group

Question 22

Disaccharide

Answer 22

Formed when two monosaccharides join together (in a condensation reaction).

Question 23

Glycosidic bond

Answer 23

The bond that forms in a condensation reaction.

Question 24

Maltose

Answer 24

A disaccharide formed by two α−glucose molecules joining together by a glycosidic bond (in a condensation reaction).

Question 25

Sucrose

Answer 25

A disaccharide formed by a glucose molecule and a fructose molecule joined together by a glycosidic bond (in a condensation reaction).

Question 26

Lactose

Answer 26

A disaccharide formed by a glucose molecule and a galactose molecule joined together by a glycosidic bond (in a condensation reaction).

Question 27

Reducing sugars

Answer 27

Includes all monosaccharides and some disaccharides.

Question 28

Add Benedict’s reagent (blue) to a sample and heat it in a water bath that’s been brought to the boil. If the test’s positive it will form a coloured precipitate - solid particles suspended in the solution.

Answer 28

Test for reducing sugars

Question 29

Blue (none), green (very low conc.), yellow (low conc.), orange (medium conc.), red (high conc.)

Answer 29

What are the colours formed in the reducing sugars test?

Question 30

1. Do Benedict’s test and it should stay blue/negative.
2. (with a fresh sample) Boil with acid then neutralise with alkali.
3. Heat with Benedict’s reagent and if the test’s positive it will form a coloured precipitate - solid particles suspended in the solution.

Answer 30

Test for non-reducing sugars

Question 31

Carbohydrates

Answer 31

What are polysaccharides?

Question 32

Large numbers of monomers (monosaccharides) bonded together in a condensation reaction

Answer 32

What are polysaccharide molecules made from?

Question 33

Quantitative

Answer 33

Numerical results, this data is objective (not effected by personal opinion).

Question 34

Qualitative

Answer 34

Non-numerical results, this data tends to be subjective (affected by personal opinion).

Question 35

Semi-quantitative

Answer 35

Results that give some idea about quantities but aren’t very precise.

Question 36

Polysaccharide made of α−glucose monomers bonded together.

Answer 36

What are starch and glycogen?

Question 37

Add iodine in potassium iodide solution (yellow/orange at start).
Positive result: goes blue-black.

Answer 37

What is the test for starch?

Question 38

Only in animals

Answer 38

Where is starch found?

Question 39

Only in animals

Answer 39

Where is glycogen found?

Question 40

Helical - compact.
Polymer of glucose - provides glucose to be respired for energy release.
Insoluble in water - osmotically inactive (doesn’t affect osmosis).
Branched - more ends so faster hydrolysis for glucose release.
Large molecule - cannot escape from cell across cell-surface membrane.

Answer 40

What are the structures and functions of starch and glycogen in cells?

Question 41

Soluble

Answer 41

Is glucose soluble or insoluble in water?

Question 42

Insoluble

Answer 42

Is glycogen soluble or insoluble in water?

Question 43

More ends can be acted on simultaneously by enzymes. It is therefore more rapidly blocked down to form glucose monomers, which are used in respiration. This is important to animals which have a higher metabolic rate and therefore respiratory rate than plants because they are more active.

Answer 43

Why is glycogen more branched than starch?

Question 44

In plants. It makes up the cell walls and makes it string and stops the cell from bursting due to osmotic pressure.

Answer 44

Where is cellulose found?

Question 45

A long, straight and unbranched chain of β-glucose monomers joined to each other by glycosidic bonds.

Answer 45

What is a cellulose molecule?

Question 46

Hydrogen bonds

Answer 46

What are cellulose molecules joined to get her by?

Question 47

Microfibrils (which provide rigidity/strength to the cell)

Answer 47

What do cellulose molecules joined together by hydrogen bonds form?

Question 48

β-glucose monomers are used rather than α-glucose monomers.
β-glucose monomers are alternately flipped over with respect to each other.

Answer 48

Why are cellulose molecules straight rather than helical?

Question 49

Strong

Answer 49

Hydrogen bonds are individually weak, but are many of them together in a network strong or weak?

Question 50

Starch/glycogen contains alpha glucose; Cellulose contains beta glucose.
Starch/glycogen is helical/coiled; cellulose is straight.
Starch/glycogen is branch; cellulose is unbranched.
Starch/glycogen can’t form microfibrils; cellulose can for microfibrils.
All of the glucose monomers in starch/glycogen are the same way up; the glucose monomers in cellulose are alternately flipped over with respect to each other.

Answer 50

Describe four ways in which the structure of starch/glycogen is different from the structure of cellulose.

Question 51

Cellulose molecules are straight which allows them sit sit parallel to each other and make a strong network of many hydrogen bonds.

Answer 51

Why can cellulose form microfibrils?

Question 52

Both are polysaccharide made up of glucose monomers.
Both contain glycosidic bonds (between monomers).
Both contain carbon, hydrogen and oxygen.

Answer 52

Describe three ways in which the structure of cellulose is similar to the structure of starch.

Question 53

Long/straight/unbranched chains (of glucose);
(joined to each other by) hydrogen bonds;
Form microfibrils;
Provide rigidity/strength/support.

Answer 53

The structure of cellulose is related to its role in plant cell walls. Explain how.

Question 54

Lipids

Answer 54

What is the cell-surface membrane in cells and membranes around organelles made up of?

Question 55

The flexibility for membranes and the transfer of lipid-soluble substances across them.

Answer 55

What does the phospholipids in cell membranes contribute to the cells?

Question 56

Energy store, waterproofing, insulation, protection.

Answer 56

What are the roles of lipids?

Question 57

When oxidised (reacted with oxygen), lipids provide more than twice the energy as the same mass of carbohydrate and release valuable water.

Answer 57

Explain why lipids are a good energy store.

Question 58

Lipids are insoluble in water and therefore useful as a waterproofing. Both plants and insects have want, lipid cuticles that conserve water, while mammals produce an oil secretion from the sebaceous glands in the skin.

Answer 58

Explain how lipids are used in waterproofing.

Question 59

Fats are slow conductors if heat and when stored beneath the body surface help to retain body heat. They also act as electrical insulators in the myelin sheath around nerve cells.

Answer 59

Explain how lipids are used as insulation.

Question 60

Fat is often stored around delicate organs, such as the kidney.

Answer 60

Explain how lipids are used for protection.

Question 61

Add ethanol then add water and shake.
Positive result: white/milky emulsion.

Answer 61

What is the test for lipids?

Question 62

Lipids are insoluble in water, so when water is added and shaken, the lipids (which are dissolved in the ethanol) collect together to form an emulsion of lips droplets in the water.

Answer 62

How does the emulsion test for lipids work?

Question 63

The condensation of one molecule of glycerol and three molecules of fatty acid. The condensation reaction between glycerol and each fatty acid (RCOOH) forms an ester bond and a molecule of water is given off.

Answer 63

How are triglycerides formed?

Question 64

RCOOH

Answer 64

What is the general formula for a fatty acid?

Question 65

A carboxyl group

Answer 65

What does COOH represent?

Question 66

A hydrocarbon chain, consisting of only hydrogen and carbon atoms. It can vary in length and in the number of double bonds between carbon atoms.

Answer 66

What is the R group in fatty acids?

Question 67

Saturated fatty acids have no double bonds between carbon atoms.
Unsaturated fatty acids have at least one double bond between carbon atoms.

Answer 67

What is the difference between saturated and unsaturated fatty acids?

Question 68

Mono-unsaturated

Answer 68

Why is a fatty acid with one double bond between carbon atoms called?

Question 69

Polyunsaturated

Answer 69

What is a fatty acid with more than one double bond between carbon atoms called?

Question 70

They make the molecule bend. Therefore, they cannot be packed together so closely, making them liquids.

Answer 70

What do the double bonds in fatty acids cause?

Question 71

Triglycerides and phospholipids

Answer 71

What are two types of lipid?

Question 72

Triglycerides

Answer 72

What is the main chemical that makes up fats and oils?

Question 73

High ratio of energy-storing carbon-hydrogen bonds to carbon atoms.
Low mass to energy ratio.
Large, non-polar molecules.
High ratio of hydrogen to exogenous atoms.

Answer 73

What is the structure of triglycerides?

Question 74

They are an excellent source if energy because C-H contain a large amount of chemical energy.

Answer 74

Explain the importance of triglycerides having a high ration of energy-storing carbon-hydrogen bonds to carbon atoms.

Question 75

This makes them good storage molecules because lots of energy can be stored in a small volume. This is especially beneficial to animals as it reduces the mass they have to carry as they move around.

Answer 75

Explain the importance of triglycerides having a low mass to energy ration.

Question 76

This makes them insoluble in water. As a result their storage does not affect osmosis in cells or the water potential of them.

Answer 76

Explain the importance of triglycerides being large, non-polar molecules.

Question 77

Triglycerides release water when oxidised and therefore provide an important source of water, especially for organisms living in dry deserts.

Answer 77

Explain the importance of triglycerides having a high ratio of hydrogen to oxygen atoms.

Question 78

Lipids provide more energy per gram than carbohydrates when aerobically respired.
Therefore a lower mass of lipid needs to be stored relative to carbohydrate.
Lipid is therefore a lighter energy storage product - major advantage if an organism (or see) needs to move around.

Answer 78

Why do organisms that move (e.g. animals) and parts of organisms that move (e.g.some plant seeds) use lipids rather than carbohydrates as an energy store?

Question 79

Fish need to be flexible to swim. Fat, which is solid, would make this difficult.
Fish oils are rich in polyunsaturated fatty acids that keep the lipid liquid, even at the low temperatures encountered in the water.

Answer 79

Why do fish tend to store their lipids as oils rather than fats?

Question 80

What is a triglyceride with 3 of the same fatty acids called?

Answer 80

A simple triglyceride

Question 81

What is a triglyceride which doesn’t have 3 of the same fatty acids called?

Answer 81

A mixed triglyceride

Question 82

How are phospholipids different from triglycerides?

Answer 82

One of the fatty acids of a triglyceride is substituted by a phosphate-containing group.

Question 83

What elements do a phosphate group contain?

Answer 83

Phosphorus and oxygen

Question 84

What is in the hydrophilic head of a phospholipid?

Answer 84

Glycerol, phosphate group

Question 85

Why is the head in a phospholipid hydrophilic?

Answer 85

It contains polar covalent bonds and is the rife polar. This allows the head to be attracted towards water molecules.

Question 86

Why is the head in a phospholipid hydrophobic?

Answer 86

It has absolutely no charge and is therefore non-polar. This means that they are repelled by water.

Question 87

What is the phospholipid bilayer?

Answer 87

A double layer of phospholipids with the heads facing out towards from on either side and the tails pointing in away from the water on the inside.

Question 88

What is a NH2 group?

Answer 88

Amine group

Question 89

What is the R group in a protein?

Answer 89

A side chain

Question 90

What are the 4 different types of R groups in proteins?

Answer 90

Non-polar, polar, negatively charged, positively charged

Question 91

Describe how a peptide bond is formed between two amino acids to form a dipeptide. [2]

Answer 91

Condensation reaction;
Between amine and carboxyl

Question 92

What is a peptide bond?

Answer 92

The bond that holds amino acids together. It is formed in a condensation reaction between the OH group in the carboxyl in one amino acid and a H in the amine groups in another amino acid. The result is a covalent bond between carbon and nitrogen and a water molecule is given off.

Question 93

What are polypeptides?

Answer 93

Polymers formed by the condensation of many amino acids.

Question 94

What is primary structure in a protein?

Answer 94

The sequence of amino acids in a polypeptide chain.

Question 95

Describe how monomers join to form the primary structure of a protein.

Answer 95

Condensation reaction between amino acids;
Forming peptide bonds;
Creating a (specific) sequence/order of amino acids

Question 96

What is secondary structure in a protein?

Answer 96

The folding of a polypeptide chain due to hydrogen bonding between the N-H group of one peptide bond and the C=O group of another to create a structure such as an alpha helix or beta pleated sheet.

Question 97

The secondary structure of a polypeptide is produced by bonds between amino acids. Describe how. [2]

Answer 97

Hydrogen bonds;
Between N-H (group of one amino acid) and C=O (group of another amino acid);
Forming β pleated sheets / α helix

Question 98

What is tertiary structure?

Answer 98

The specific three-dimensional folding of a protein due to the relative positioning of binding between R groups, specifically hydrogen bonds, ionic bonds and disulphide bonds.

Question 99

What is a disulphide bridge?

Answer 99

A covalent bond between two sulfur atoms, each on a different R group.

Question 100

It is possible for two proteins to have the same number and type of amino acids, but different tertiary structures. Explain why. [2]

Answer 100

Different primary structure;
Forms ionic/hydrogen/disulphide bonds in different places.

Question 101

What is quaternary structure?

Answer 101

Two or mor polypeptide chains are bonded together to make the final protein. Not every protein has quaternary structure.

Question 102

Describe how the structure of a protein depends on the amino acids it contain. [5]

Answer 102

Structure is determined by (relative) position of amino acids/R groups/interactions;
Primary structure is sequence of amino acids;
Secondary structure formed by hydrogen binding (between amino acids);
Tertiary structure formed by interactions (between R groups);
Creates active site in enzymes / Creates complementary shapes in antibodies/carrier proteins/receptor (molecules);
Quaternary structure contains >1 polypeptide chain
Or
Quaternary structure formed by interactions/bonds between polypeptides.

Question 103

What is the test for proteins? [2]

Answer 103

Add biuret (reagent);
(Positive result) purple/lilac/violet

Question 104

A dipeptide consists of two amino acids joined by a peptide bond. Dipeptide may differ in the type of amino acids they contain. Describe two other ways in which all dipeptide are similar and one way in which they might differ. [3]

Answer 104

All contain an amine group/NH2 (at end);
All contain a carboxyl group/COOH (at end);
All contain two R groups;
All contain C, H, N and O;
The R groups may be different

Question 105

What is the meaning of hydroxylating?

Answer 105

Addition of hydroxyl group