Enzymes

Enzymes

Respiration

Photosynthesis

Enzymes

Respiration

Photosynthesis

Enzymes (SL)

Standard Level

Metabolism Enzymes Catalysis Specificity Enzyme Activity Enzyme Reactions

SL Content Statements

C1.1.1

Enzymes as catalysts
Students should understand the benefit of increasing rates of reaction in cells.
C1.1.2

Role of enzymes in metabolism
Students should understand that metabolism is the complex network of interdependent and interacting chemical reactions occurring in living organisms. Because of enzyme specificity, many different enzymes are required by living organisms, and control over metabolism can be exerted through these enzymes.
C1.1.3

Anabolic and catabolic reactions
Examples of anabolism should include the formation of macromolecules from monomers by condensation reactions including protein synthesis, glycogen formation and photosynthesis. Examples of catabolism should include hydrolysis of macromolecules into monomers in digestion and oxidation of substrates in respiration.
C1.1.4

Enzymes as globular proteins with an active site for catalysis
Include that the active site is composed of a few amino acids only, but interactions between amino acids within the overall three-dimensional structure of the enzyme ensure that the active site has the necessary properties for catalysis.
C1.1.5

Interactions between substrate and active site to allow induced-fit binding
Students should recognize that both substrate and enzymes change shape when binding occurs.
C1.1.6

Role of molecular motion and substrate-active site collisions in enzyme catalysis
Movement is needed for a substrate molecule and an active site to come together. Sometimes large substrate molecules are immobilized while sometimes enzymes can be immobilized by being embedded in membranes.
C1.1.7

Relationships between the structure of the active site, enzyme–substrate specificity and denaturation
Students should be able to explain these relationships.
C1.1.8

Effects of temperature, pH and substrate concentration on the rate of enzyme activity
The effects should be explained with reference to collision theory and denaturation.
AOS: Students should be able to interpret graphs showing the effects.
NOS: Students should be able to describe the relationship between variables as shown in graphs. They should recognize that generalized sketches of relationships are examples of models in biology. Models in the form of sketch graphs can be evaluated using results from enzyme experiments.
C1.1.9

Measurements in enzyme-catalysed reactions
AOS: Students should determine reaction rates through experimentation and using secondary data.
C1.1.10

Effect of enzymes on activation energy
AOS: Students should appreciate that energy is required to break bonds within the substrate and that there is an energy yield when bonds are made to form the products of an enzyme- catalysed reaction. Students should be able to interpret graphs showing this effect.

Metabolism Enzymes Catalysis Specificity Enzyme Activity Enzyme Reactions

Enzymes (SL)

Standard Level

SL Content Statements

C1.1.1

Enzymes as catalysts

Students should understand the benefit of increasing rates of reaction in cells.

C1.1.2

Role of enzymes in metabolism

C1.1.3

Anabolic and catabolic reactions

C1.1.4

Enzymes as globular proteins with an active site for catalysis

Include that the active site is composed of a few amino acids only, but interactions between amino acids within the overall three-dimensional structure of the enzyme ensure that the active site has the necessary properties for catalysis.

C1.1.5

Interactions between substrate and active site to allow induced-fit binding

Students should recognize that both substrate and enzymes change shape when binding occurs.

C1.1.6

Role of molecular motion and substrate-active site collisions in enzyme catalysis

Movement is needed for a substrate molecule and an active site to come together. Sometimes large substrate molecules are immobilized while sometimes enzymes can be immobilized by being embedded in membranes.

C1.1.7

Relationships between the structure of the active site, enzyme–substrate specificity and denaturation

Students should be able to explain these relationships.

C1.1.8

Effects of temperature, pH and substrate concentration on the rate of enzyme activity

C1.1.9

Measurements in enzyme-catalysed reactions

AOS: Students should determine reaction rates through experimentation and using secondary data.

C1.1.10

Effect of enzymes on activation energy

AOS: Students should appreciate that energy is required to break bonds within the substrate and that there is an energy yield when bonds are made to form the products of an enzyme- catalysed reaction. Students should be able to interpret graphs showing this effect.