B1.1

Question 1

Condensation reactions and hyrolysis

What are Marcomolecules?

Answer 1

• A larger molecule made up of many repeating sub-units. (made up of a very large number of atoms and have a relative molecular mass above 10,000 atomic mass units.
• The four macromolecules: Carbohydrates, Lipids, Proteins, Nucleic Acids.

Question 2

Condensation reactions and hyrolysis

What are monomers?

Answer 2

• The small, repeating units that marcomolecules are made up of.
• They are building blocks –> the smallest unit that is still classified as that molecule type.
• Marcomolecules are unique due to it being made up of different monomers.

Question 3

Condensation reactions and hyrolysis

What are Condensation Reactions?

Answer 3

• Involves the formation of the covalent bond between two monomers.
• This happens by removing atoms from each ot the monomers - a hydrogen - from one and a hydroxl group (OH) so that the monomers are reactive.
• The end result is a polymer (first dimer than a polymer once done many times) –> water is formed as a waste product.
• Also referred to as dehydration synthesis/ polymerisation.

Question 4

Condensation reactions and hyrolysis

What are Hydrolysis Reactions?

Answer 4

• The opposite of condensation reactions —> they start with a polymer and break the bonds, to break the polymer into many monomers.
• Water is also split in the process and the hydrogen and hydroxyl from the water is used to stabilise the new monomers.

Question 5

Condensation reactions and hyrolysis

Unique features of Carbon

Answer 5

• carbon atoms have 6 electrons with 4 in the outer shell –> very effective at forming covalent bonds with other carbon atoms or different atoms.
• Can actually form four covalent bonds and can form single/ double bonds giving a wide variety or compouds it can form.
• Can effectively form long chains and rings creating very diverse structural compounds.

Question 6

Condensation reactions and hyrolysis

Polymers are made of Monomers.

Answer 6

• The four main biomolecules (molecules needed for living organisms) –> unique molecules beacuse they each have a different building block (monomer.)

The monomer and polymer combos are:
1) Carbohydrates are made up of monosaccharides
2) Lipds are made up of fatty acids (and glycerol and/or phosphate group.)
3) Proteins are made up of amino acids.
4) Nucleic Acids are made up of nucelotides.

Question 7

Condensation reactions and hyrolysis

Importance of Condensation Reactions

Answer 7

• They are building reactions, so when tissue is built for the body, condensation reactions are used.
• Protein synthesis is an example of condensation reaction that is the most crucial role of every cell.
• When energy is stored in larger carbohydrates, condensation reactions are occurring.

Question 8

Condensation reactions and hyrolysis

Water as the Waste Production of Condensation

Answer 8

• During condensation reations, the previously stable monomers must be reactive.
• This is done by removing something from each monomer –> to do so in a way that creates a safe waste product, a Hydrogen is removed from one monomer and a hydroxyl (OH) from the other.
• The two monomers covalently bond where the elements were removed and the H and OH combine to make water —> water is the waste product.

Question 9

Condensation reactions and hyrolysis

Importance of Hydrolysis Reactions

Answer 9

• when larger macromolecules in human bodies are broken down to use the building blocks, a hydrolysis reaction is occurring. (DIGESTION)
• Polymers are generally consumed and hydrolysis using digestive enzymes breaks food into monomers for use in our bodies.

Question 10

Condensation reactions and hyrolysis

Role of Water in Hydrolysis Reactions

Answer 10

• Once the bond in a polymer is broken, the monomers would be reactice and not stable in that state –> to prevent the polymers from reconnecting, water is also split.
• The hydrogen will go to one monomer and the hydroxyl to anotherm so that both monomers are chemically stable, when they are seperated.

Question 11

Carbohydrates

What is a monosaccharide?

Answer 11

• Means ‘one sugar’, the monomer of all carbohydrates
• Most monosaccharides have 5 or 6 carbons and form rings in aqueous solutions.
• Ribose, Deoxyribose and Glucose are important monosaccharides you already have encoountered.

Question 12

Carbohydrates

What is a polysaccharide?

Answer 12

• Polysaccharide means many sugars.
• when many monosaccharides have chemically bonded together we call it is a polysaccharide.
• “Complex Carbohydrate”
• Polysaccharides can be broken into monosaccharides to provide emergy so consdiered a form of energy storage.
• Also perform important structural functions in cells.

Question 13

Carbohydrates

What is Cellulose?

Answer 13

• Cellulose is a polysaccharide that makes up the cell walls of plants.
• It is a long chain of glucose molecules but alternates between two different forms of glucose (alpha and beta glugose) which makes it distinct from starch and creates bonds between chains.
• Creates long straight fibres making it an ideal structural polymer.
• More organisms lack the enzyme to digest cellulose so it does not provide energy —> also called a dietary fibre.

Question 14

Carbohydrates

Pentose vs Hexose Sugars

Answer 14

All sugars contain a carbon backbone.
- A pentose monosaccharide contains 5 carbons –> examples include fructose and ribose. –> their formula is C5 H10 O5.
- A hexose monosaccharide contains 6 carbons —> example is glucose. —> their formula is C6 H12 O6

Question 14

Carbohydrates

What are Glycoproteins?

Think Glyco - glucose - SUGAR = carbohydrate (bonded to protein)

Answer 14

• When a carbohydrate is actually chemically bonded to another biomolecule to make a ‘conjugated carbon compound.’
• Glycoproteins are a carbohydrate chain bonded to a protein.
• Found in cell membranes where the carbohydrate chain is attatched to a membrane protein.
• Play an important role in cell to cell recognition and communication.

Question 15

Carbohydrates

The Polarity of Glucose

Answer 15

• Glucose has 5 hydroxyl (OH) groups and the oxygen and hydrogen in a hydroxyl are bound by a covalant, polar bond.
• The presence of the 5 polar bonds make glucose a polar molecule.

Question 16

Carbohydrates

Properties of Glucose

Answer 16

Due to it’s polar covalent bonds, glucose has some important chemical properties:
- High molecular stability —> due to covalent bonds
- High solubility in water –> due to polarity
- Easily transportability —> due to solubility
- High energy yield —> result of covalent bonds breaking.

Question 17

Carbohydrates

Alpha Glucose vs Beta Glucose

Answer 17

Glucose can exist in two different forms.
- They have the same elements but when it forms a ring structure (in aqeous solution), the orientation of the hydroxyl and hydrogen on carbon 1 rotate.
- Most polymers use alpha glucose but beta glucose is important in cellulose.

ALAPHA: HO facing down.
BETA: OH facing up.

Question 18

Carbohydrates

The Structure of Starch and Glycogen

Answer 18

Starch and glycogen are both long chains of glucose molecules.
- They form coils/ chains which makes them compact storage molecules.
- The bonds between the glucose molecules are easily broken by hydrolysis to free monosaccharides for celluar respiration.
(plants use starch, animals use glycogen.)

Question 19

Carbohydrates

Amylose and Amylopectin

Answer 19

Starch exists in two forms.
- Amylose: glucoses are connected only to the adjacent glucose (between C1 and C4) to create a linear chain –> that will twist into a helix when long.
- Amylopectin: additional bonding on top of glucoses (between C1 and C6) creates a abranded structure.

About 20% of starch is amylose, and 80% is amylopectin.

Question 20

Carbohydrates

ABO Glycoprotiens

Answer 20

Our red blood cells have specific glycoproteins on them called ABO anigens.
- Different types of ABO antigens differentiate/ distinguish blood types.
- Our immune system build antibiodies to other blood types and not our own –> reason why it’s essential to only recieve compatible blood during a transfusion as the body only recognises these markers.