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Published byDimitri Stain Modified over 9 years ago
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Food production and preservation
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Key Words to define: Autotroph- Heterotroph- Selective breeding- Artificial selection- Fertlisers- Mycoprotein- Food spoilage- Pasteurisation- Irradiation- Sterilisation-
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Ancient Biotechnology ~50,000 years ago - at least two different species of “people” (H.sapiens, H. neanderthalensis) began to pass on cultural traditions. People could “imagine”, share ideas, plan ahead, honor their dead. They began to see the world as something that could be manipulated. 10,000 years ago - the traditions of agriculture and animal husbandry began to develop. Wheat, rye, barley, goats, sheep
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Early Agriculture Even relatively primitive peoples understood that selective breeding had positive outcomes. -larger grain seeds flour -selective breeding of goats and eventually cattle to increase milk production and meat content. Agrarian societies unknowingly participated in genetic manipulation to make useful products for humans. SELECTIVE BREEDING IS BIOTECHNOLOGY
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Selective Breeding of Kale (Brassica oleracea) Cabbage Brussels Sprouts Cauliflower Kohlrabi Kale Modern Example of Selective Breeding
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This is modern Kale. Its ancestor provided the stock for the selective breeding of the other subspecies.
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The large terminal buds of the plant were selected to produce cabbage.
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Large lateral buds were selected to produce Brussels Sprouts
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Principles of artificial selection: Breeders choose features they wish to improve. Individuals with those features are bred together. Offspring with improvement are selected to breed in next generation. Continues over next 10+ years
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Cauliflower was produced by selecting for large, white flower stalks.
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For broccoli, large stems and flower stalks were both selected.
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Kohlrabi was produced by selecting for short, fat stems
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And this is modern Kale. Remember, all of the vegetables that you have seen are the SAME SPECIES - EACH PRODUCED BY SELECTIVE BREEDING; TAKING ADVANTAGE OF WILD TYPE GENES AND NATURAL MUTATIONS.
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Coming to a supermarket near you soon…
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Other examples - crops: Yields of grain (wheat, rice), roots (carrots) and tubers (potatoes) Pest resistance – insects, fungi, bacteria, viruses Better quality – appearance, taste
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Other examples - livestock: Yield of meat, milk, eggs Fast growing breeds Disease resistance ( eg blue tongue disease) Quality – lean, low fat meat
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All the same species – Ovis aries
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Improving the environment improves food production…
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Fertlisers – NPK and Mg: Nitrates – making amino acids Phosphates – DNA, RNA, ATP, phospholipids Potassium – enzyme co-factor; guard cell opening Magnesium – making chlorophyll
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Organic vs inorganic?
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Inorganic: Higher yield, cheaper, trace contaminants Organic; Lower yields, more expensive, no trace contaminants
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Pesticides Herbicides – kill weeds that compete Fungicides – against mildew, blight and rust Insecticides – applied when levels threaten economic loss. Organic – use none of the above. Crop rotation and natural predators (biological control)
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Organic farming
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Use of Microorganisms Bacteria cheese, yogurt, antibiotics Fungi cheeses Yeast ( single celled fungus) bread, beer C 6 H 12 O 6 CO 2 + C 2 H 5 OH Louis Pasteur (1860’s) clearly demonstrated that microbes are responsible for fermentation.
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Produce traditional products in clever, new ways -increase crop productivity, meat production, and milk production “The miracle of Genetic Engineering”
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Mycoprotein Uses a fungus Fusarium ( strain PTA-2684) First discovered in a field in Buckingham in 1967 Now grown on an industrial scale to make ‘Quorn’
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Advantages Microbes grow quickly – high yields in short time. Uses less land to grow; can be set up anywhere Uses waste material ( eg whey) as a substrate No ethical issues with breeding / vegans Low fat or no-fat foods
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Disadvantages Contamination of culture vessels Consumer resistance / suspicion Need to have a substrate, produced by something else. Needs purifying before use
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The future - modifying genetics to produce organisms with new “recombinant” traits. -plants with resistance to disease and parasites. -replacing a defective gene in a crop plant or animal ‘Agrobacterium’
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Food Spoilage Aspergillus fungus – the aflatoxins it produces are carcinogenic
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Preservation – removes one of the conditions that microbe needs to survive…
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Salting / Sugaring Lowers wp. Removes water from microbes by osmosis Eg salted cod, jams
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Pickling Ethanoic acid (vinegar) – lowers pH to <4 Microbe enzymes denature. Eg pickled cabbage, onions
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Heat Treatment -1 Pasteurisation – brief flash heating to 72C for 15 seconds. Kills pathogens but not Lactobacillus, so flavour is preserved.
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Heat Treatment -2 UHT – brief flash heating to 135C for 15 seconds. Kills all bacteria, but flavour is compromised.
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Freezing Water is frozen, so not available to microbes. Enzymes are inactivated. Eg meat
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Irradiation X-rays or Gamma rays kill microbes by denaturing proteins and DNA. Eg fruit, prawns
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Homework: 1. Describe, using examples from agriculture, the principles of selective breeding. 2. Explain the term ‘food spoilage’ and describe how food may be prevented from going ‘off’.
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