Core Practical 4: Investigating the Rate of Enzyme Reactions (Edexcel International A Level Biology): Revision Note
Investigating the Rate of Enzyme Reactions
Temperature
Enzymes have a specific optimum temperature – the temperature at which they catalyse a reaction at the maximum rate
Lower temperatures either prevent reactions from proceeding or slow them down:
Molecules move relatively slow
Lower frequency of successful collisions between substrate molecules and active site of enzyme
Less frequent enzyme-substrate complex formation
Substrate and enzyme collide with less energy, making it less likely for bonds to be formed or broken (stopping the reaction from occurring)
Higher temperatures speed up reactions:
Molecules move more quickly
Higher frequency successful collisions between substrate molecules and active site of enzyme
More frequent enzyme-substrate complex formation
Substrate and enzyme collide with more energy, making it more likely for bonds to be formed or broken (allowing the reaction to occur)
However, as temperatures continue to increase, the rate at which an enzyme catalyses a reaction drops sharply, as the enzyme begins to denature:
Bonds (eg. hydrogen bonds) holding the enzyme molecule in its precise shape start to break
This causes the tertiary structure of the protein (ie. the enzyme) to change
This permanently damages the active site, preventing the substrate from binding
Denaturation has occurred if the substrate can no longer bind
Very few human enzymes can function at temperatures above 50°C
This is because humans maintain a body temperature of about 37°C, therefore even temperatures exceeding 40°C will cause the denaturation of enzymes
High temperatures causes the hydrogen bonds between amino acids to break, changing the conformation of the enzyme
The effect of temperature on the rate of an enzyme-catalysed reaction
Examiner Tips and Tricks
When answering questions about reaction rates for enzyme-catalysed reactions, make sure to explain how the temperature affects the speed at which the molecules (enzymes and substrates) are moving and how this, in turn, affects the number of successful collisions.
pH
All enzymes have an optimum pH or a pH at which they operate best
Enzymes are denatured at extremes of pH
Hydrogen and ionic bonds hold the tertiary structure of the protein (ie. the enzyme) together
Below and above the optimum pH of an enzyme, solutions with an excess of H+ ions (acidic solutions) and OH- ions (alkaline solutions) can cause these bonds to break
This alters the shape of the active site, which means enzyme-substrate complexes form less easily
Eventually, enzyme-substrate complexes can no longer form at all
At this point, complete denaturation of the enzyme has occurred
Where an enzyme functions can be an indicator of its optimal environment:
Eg. pepsin is found in the stomach, an acidic environment at pH 2 (due to the presence of hydrochloric acid in the stomach’s gastric juice)
Pepsin’s optimum pH, not surprisingly, is pH 2
The effect of pH on the rate of an enzyme-catalysed reaction for three different enzymes (each with a different optimum pH)
When investigating the effect of pH on the rate of an enzyme-catalysed reaction, you can use buffer solutions to measure the rate of reaction at different pH values:
Buffer solutions each have a specific pH
Buffer solutions maintain this specific pH, even if the reaction taking place would otherwise cause the pH of the reaction mixture to change
A measured volume of the buffer solution is added to the reaction mixture
This same volume (of each buffer solution being used) should be added for each pH value that is being investigated
Examiner Tips and Tricks
Temperature can both affect the speed at which molecules are moving (and therefore the number of collisions between enzyme and substrate in a given time) and can denature enzymes (at high temperatures). pH, however, does not affect collision rate but only disrupts the ability of the substrate to bind with the enzyme, reducing the number of successful collisions until eventually, the active site changes shape so much that no more successful collisions can occur.
Enzyme concentration
Enzyme concentration affects the rate of reaction
The higher the enzyme concentration in a reaction mixture, the greater the number of active sites available and the greater the likelihood of enzyme-substrate complex formation
As long as there is sufficient substrate available, the initial rate of reaction increases linearly with enzyme concentration
If the amount of substrate is limited, at a certain point any further increase in enzyme concentration will not increase the reaction rate as the amount of substrate becomes a limiting factor
The effect of enzyme concentration on the rate of an enzyme controlled reaction
Substrate concentration
Substrate concentration affects the rate of reaction
The higher the substrate concentration the faster the rate of reaction
More substrate molecules means more collision between enzyme and substrate so the more likely an active site will be used by a substrate
The is only the case up until a certain concentration of substrate, at which point a saturation point is said to have been reached
At this point all active sites are occupied and increasing the substrate concentration will not affect the rate of the reaction
Substrate concentration will decrease over time (if no new substrate is added)
The rate of reaction will therefore decrease over time
This means the initial rate of reaction will be fastest throughout the reaction
The effect of substrate concentration on the rate of an enzyme controlled reaction
Practical: Investigating the rate of enzyme reactions
The progress of enzyme-catalysed reactions can be investigated by:
Measuring the rate of formation of a product
Measuring the rate of disappearance of a substrate
There are many enzymes that can be used in this practical; some common examples are catalase, amylase and protease
The initial rate of reaction can be calculated to determine the effect of changing enzyme or substrate concentrations
The initial rate of reaction is at the start of the reaction
You can calculate the initial rate of reaction using a graph of results showing volume of product/substrate against time
Draw a tangent to the graph through the origin
Calculate the gradient of the tangent - this is the initial rate of reaction
How to calculate the initial rate of reaction from a graph
Effect of enzyme concentration on the rate of reaction
You can measure how fast a product is made in a reaction
Apparatus
Catalase solution at five different concentrations (enzyme)
Hydrogen peroxide solution (substrate)
Buffer solution (to keep the pH constant)
Boiling tube
Bung and delivery tube
Measuring cylinder
Water trough
Stopwatch
The apparatus set up to investigate how changing the concentration of catalase affects the volume of oxygen produced
Method
Add a set volume of hydrogen peroxide solution to a boiling tube
Add a set volume of buffer solution to the same boiling tube
Invert a full measuring cylinder into a trough of water
Place the end of the delivery tube into the open end of the measuring cylinder and attach the other end to a bung
Add a set volume of one concentration of catalase to the boiling tube and quickly place the bung into the boiling tube
Record the volume of oxygen collected in the measuring cylinder by the water displaced every 10 seconds for 60 seconds
Repeat the experiment twice more and calculate the average volume of oxygen produced at each 10 second interval
Repeat the whole experiment for the different concentrations of catalase
Plot the average volume of gas produced against time for each concentration
Compare the initial rate of reaction of each of the concentrations
Results
As the concentration of catalase increases the volume of oxygen produced would increase
This is because there would be more available active sites for hydrogen peroxide to use
The volume of oxygen would plateau out after the initial rate of reaction due to the substrate decreasing, having been converted into the product (oxygen)
An example of a set of results for one concentration of catalase showing the volume of oxygen produced per second
Effect of substrate concentration, temperature and pH on the rate of reaction
Another investigation is to measure how fast a substrate is removed from a reaction
This can be done using a range of substrate concentrations to investigate how changing concentration effects the rate of the reaction
The breakdown of starch by amylase is a good example of how to investigate the effect of substrate concentration on the rate of the reaction
Iodine solution can be added to a starch solution to create a solution with a blue-black appearance
This will provide a measurable way of determining the rate at which starch is broken down to maltose using a colorimeter
The colorimeter will measure how the absorbance of the starch solution change over a period of time once amylase is added to it
This can be repeated for a range of different starch concentrations and a graph of absorbance against time can be plotted
Results should show a fast initial rate of reaction and then plateau out as the substrate is converted into product(s) and all available active sites become occupied by the increasing concentration of substrate
The investigation can be repeated by altering the pH (use buffer solutions) or temperature
Examiner Tips and Tricks
When investigating the effect of enzyme concentration, pH or temperature on the rate of an enzyme catalysed reaction, it is important to provide an abundance of substrate to prevent it from becoming a limiting factor.
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