Biotechnology (Cambridge (CIE) IGCSE Biology)
Revision Note
Written by: Phil
Reviewed by: Lára Marie McIvor
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Everyday Products Made with Biotechnology
Biofuels
Yeast is a single celled fungus that uses sugar as its food source
When it respires, ethanol and carbon dioxide are produced (and energy is released)
The alcohol produced by fermentation of glucose can be used as biofuel
The ethanol produced in this reaction is increasingly being used as a biofuel (a fuel made from living organisms rather than a fossil fuel like oil, coal or gas)
In countries such as Brazil, biofuel is partly replacing petrol as the fuel for cars and other vehicles
Plant material is used as the substrate for producing ethanol (as a source of glucose) - it is chopped up into small pieces and mixed with yeast which respires anaerobically and produces ethanol
The liquid is separated from the remaining solids and any water is removed, leaving a concentrated solution of ethanol
Sometimes the waste parts of crop plants, such as the stalks or outer leaves, are used, but in other places, crops are grown specifically to be harvested for making ethanol
In some places, this is causing concern that there is less land available for local people to grow food crops needed for survival
Bread
Yeast will respire anaerobically if it has access to plenty of sugar, even if oxygen is available
This is taken advantage of in bread making, where the yeast is mixed with flour and water and respires anaerobically, producing carbon dioxide:
The carbon dioxide produced by fermentation (anaerobic respiration) of glucose is what makes bread dough rise
The carbon dioxide produced by the yeast during respiration is caught in the dough, causing the bread to rise
Fruit Juice Production
Fruit juice is produced by squeezing the fruits to remove the juice
Chopping the fruit up before squeezing helps to release a lot more juice, but this does not break open all the cells so a lot of juice is lost
By adding an enzyme called pectinase to the chopped up fruit, more juice is released
Pectinase works by breaking down a chemical called pectin that is found inside plant cell walls
Once pectin is broken down, the cell walls break more easily and more juice can be squeezed out of the fruit
Adding pectinase to fruits also helps to produce a clearer juice as larger polysaccharides like pectin can make the juice seem cloudy - once they are broken down into smaller molecules, the juice becomes clearer
Biological Washing Powders
Many stains on clothes are organic molecules – oil from skin, protein from blood, fat and protein from food
Detergents that only contain soap can remove some of these stains when mixed with hot water, but it can take a lot of time and effort and very high temperatures to remove the stains entirely
Biological washing powders contain enzymes similar to the digestive enzymes produced in the alimentary canal that help to break down large food molecules
Using biological washing powders has several advantages, including:
Quickly breaking down large, insoluble molecules such as fats and proteins into smaller, soluble ones that will dissolve in washing water
They are effective at lower temperatures, meaning less energy (and money) has to be used in order to wash clothes to get them clean as washing water does not need to be heated to higher temperatures
They can be used to clean delicate fabrics that would not be suitable for washing at high temperatures
Other Uses of Biotechnology: Extended
Lactose is the sugar found in milk
Human babies are born with the ability to produce lactase, the enzyme that breaks down lactose
In certain areas of the world, many people lose the ability to produce lactase as they get older
This means that they can become lactose intolerant and react badly to the lactose in milk and products made from milk (cheese, yoghurt etc)
Symptoms of lactose intolerance include nausea, flatulence and diarrhoea as their digestive system is upset by the lactose
Milk can be made lactose free by adding the enzyme lactase to it and leaving it to stand for a while to allow the enzyme to break down the lactose
Lactose-free milk is a product made from adding the enzyme lactase to dairy milk to break down the sugars in it
Penicillin Production
Penicillin was the first antibiotic, discovered in 1928 by Alexander Fleming
He noticed that some bacteria he had left in a Petri dish had been killed by the naturally occurring Penicillium mould
The penicillium mould produces a chemical to prevent it being infected by certain types of bacteria
Penicillin produced by the fungus Penicillium inhibits bacterial growth
The chemical was isolated and named penicillin
Since the discovery of penicillin, methods have been developed to produce it on a large scale, using an industrial fermenter
A diagram of an industrial fermenter used to produce large quantities of microorganisms
Fermenters are containers used to grow (‘culture’) microorganisms like bacteria and fungi in large amounts
These can then be used for many biotechnological processes like producing genetically modified bacteria and the penicillium mould that produces penicillin
The advantage of using a fermenter is that conditions can be carefully controlled to produce large quantities of exactly the right type of microorganism
Condition | Why and how it is controlled |
|---|---|
Aseptic precautions | Fermenter is cleaned by steam to kill microorganisms and prevent chemical contamination, which ensures only the desired microorganisms can grow |
Nutrients | Nutrients are needed for use in respiration to release energy for growth and reproduction of the microorganisms |
Optimum temperature | Temperature is monitored using probes and maintained using a water jacket. This ensures an optimum environment for enzymes to increase enzyme activity and prevent denaturation |
Optimum pH | pH is monitored using a probe to check it is at the optimum value for the microorganism being grown. The pH can be adjusted using acids and alkalis |
Oxygenation | Oxygen is required for aerobic respiration to take place |
Agitation | Stirring paddles are used to ensure temperature, pH, nutrients, and oxygen are all distributed evenly throughout the fermenter |
Waste | The contents are filtered to remove waste created by the microorganisms |
Mycoprotein – the process of creating food from a fungus
The fungus Fusarium is cultured (grown) on an industrial scale in fermenters
These fermenters are large vats that can be kept at the optimum pH and temperature for Fusarium to grow
The fungus is grown in aerobic conditions (it is provided with oxygen) and provided with glucose syrup as a food source (to allow the fungus to respire)
The fungus grows and multiplies within the fermenter
The fungal biomass is then harvested and purified to produce mycoprotein
Mycoprotein is a protein-rich food suitable for vegetarians eg. it is used in QuornTM products
Production of Insulin
Genetic modification is changing the genetic material of an organism by removing or altering genes within that organism, or by inserting genes from another organism
The organism receiving the genetic material is said to be ‘genetically modified’, or is described as a ‘transgenic organism’
The DNA of the organism that now contains DNA from another organism as well is known as ‘recombinant DNA’
The gene for human insulin has been inserted into bacteria which then produce human insulin which can be collected and purified for medical use to treat people with diabetes
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