Microorganisms

Question 1

What is the structure of bacteria?

• Size
• Components and functions

Answer 1

• Size: not more than 0.01 mm
• May be spherical, rod-shaped, or spiral
• Have cell walls: made of proteins, sugars, and lipids
• Some have a slime capsule inside their cell wall
• Cytoplasm, containing food reserves (glycogen, lipids) and a single chromosome (consisting of a circular DNA strand: plasmid)
• No nucleus: chromosome is just coiled up
• Some have filaments called flagella (for movement)

Question 2

What is Bacteria’s physiology?

• How do they get nutrients?
• How do they respire?
• How do they reproduce?
• How do they carry out heat resistance?

Answer 2

• Some have chlorophyll and can photosynthesize
• Most live in, or on their food.
• They produce and release enzymes, and digest the food outside the cell
• Can respire both aerobically and anaerobically
• They reproduce via binary fission (asexual): chromosome replicates, divide into two, and daughter cells become independent bacterium
• Produce heat-resistant spores. When food cools down, spores germinate to produce new colonies.

Question 3

• Benefits / uses of Bacteria?

- Disadvantages?

Answer 3

1 - Some feed saprotrophically: decomposition of organic matter
- During decomposition: release essential elements. Eg. proteins broken down do ammonia, ammonia turned into nitrates by nitrifying bacteria
2 - Genetic Engineering (more in genetics)
- Though some are disease-causing. (Parasites: derive food from host while host is still alive. Feed on animal or cell cytoplasm, causing diseases.)
- Some also produce toxins (Eg. the one that causes tetanus)

Question 4

What is the structure of viruses?

- components: what they have and don’t have

Answer 4

• There are many different types, and all vary in shape and structure
• Components that all have: Central RNA core, surrounded by a protein coat (called capsid, made of regularly paced protein units called capsomeres)
• Have no nucleus, cytoplasm, organelles, or cell membrane (though some do have membrane outside their protein coat)

Question 5

• How do viruses multiply?
• What does this do to living beings?
• How are they useful?

Answer 5

• Sticks itself to a living cell membrane, injects its DNA or RNA into living cell or fully just enters the cell
• Its caspid gets dispersed, the DNA or RNA takes over host cell’s physiology
• Nucleic acid and capsomeres get used to make new virus particles which escape from the cell
• Host cell may get destroyed, giving rise to disease symptoms
• They are used as vectors to deliver recombinant DNA in genetic engineering (more in genetics)

Question 6

What is the structure of fungi?

• the different types
• Components, functions

Answer 6

• Instead of cells, made of threads called hyphae (they spread through the material and absorb food from it)
• Hyphae are lined with cytoplasm, containing organelles, food (glycogen and lipids), nuclei
• Some species’ hyphae have cross-walls, dividing them into cell-like compartments. each compartment has one or two nuclei in these species
• In the centre of older hyphae: vacuole
• No chlorophyll or starch grains
• A network of hyphae growing through food: mycelium
• Hyphal wall: may have cellulose, or chitin, or both
• Mushrooms and toadstools are the fruiting bodies

Question 7

Fungal Physiology

• Two types, based on nutrition
• How do they reproduce?

ADD STRUCTURE

Answer 7

• Saprotrophs and parasites
• Saprotrophs: feed on dead organic matter. Hyphae secrete enzymes to digest the matter into liquid products, digested products absorbed back (responsible, along w bacteria, for decomposition)
• Parasites: The hyphae penetrate host cell and digest cells and contents
• Can cause plant to die, animals: ringworms, fungal infection
• Reproduce by producing single-celled spores
• Each spore contains: Cytoplasm and nuclei
• When a spore lands on organic matter, germinates to produce mycelium
• Spores are produced asexually, though some do have a sexual process in their lifetime

Question 8

Uses of fungi

• What is penicillum / use?
• What is yeast (features), how does it carry out fermentation?

(come back when doing biotech)

Answer 8

• Penicillium: A type of mould, grow on decaying vegetable matter, damp leather, citrus fruits
• an antibiotic effective against fungal skin disease
• Yeast: Generally don’t form true hyphae: instead, spherical unicellular cells
• Thin cell wall with cytoplasm, contain a nucleus, vacuole and food reserves
• Grow on sugars
• Used in fermentation, their enzymes break down sugars into carbondioxide and alcohol. This provides them with energy through anaerobic respiration

Question 9

Role of Microorganisms in decomposition

• What is decomposition?
• How is it carried out?
• What substances are broken down, and what is formed?
• Uses of decomposition?

Answer 9

• Breakdown of dead organisms as well as waste material e.g faeces and urine
• Carried out by bacteria and fungi
• They feed saprotrophically, secreting digestive enzymes outside their bodies breaking down the organic matter into smaller soluble molecules
• Carbohydrates are respired releasing carbon dioxide
• Proteins are excreted as waste products like ammonia
• Uses: 1 - Hummus formation: dead mater into peat
  2 - Fermentation: making alcohol, bread etc. (more in biotech)
  3 - Putrefication: decomposition of proteins under anaerobic conditions
  4 - Sewage: decomposed by bacteria and fungi

Question 10

Bread production

Answer 10

• Micro-organism used: yeast
• the only required fermentation product: carbondioxide
  1 - Flour, water salt, oil, yeast are mixed to make dough
  2 - Water activates amylase present in flour, it digests starch present to sugar
  3 - Yeast ferments the sugar to alcohol and carbondioxide
  4 - Protein called gluten makes dough sticky and thick, holds the gas bubles
  5 - left to sit at 27’C, CO2 makes it rise
  6 - baked at 200’C. Bubbles expand more, yeast killed, small quantity of alcohol produced evaporates, dough turns into bread.

Question 11

Alcohol production

Answer 11

• cane molasses is used. it should have 50% fermentable sugar (i.e. simple sugars)
  1 - molasses is diluted, sugar concentration brought down to 15% (because enzyme action on sugar needs free water molecules)
  2 - Small quantity of urea (ammonium sulfate) added (for nitrogen)
  3 - yeast culture added (steel tanks)
  4 - resultant fermentation mesh distilled
• conditions: 25 - 30’C temperature, 5 pH

Question 12

Yogurt Production

Answer 12

• Made by fermentation of milk by bacteria
  1 - Fat and protein content is adjusted and the milk is homogenized (mechanical process which breaks up fat droplets)
  2 - Pasteurization (heated to 70’C, cooled quickly to 7’C)
  3 - Starter culture added: A mixture of Streptococcus thermophilus and Lactobacillus Bulgarius
• They act on the milk sugar: Lactose, convert it to lactic acid.
• Lactic acid coagulates the milk protein: Casein, to produce thick consistency
• Fermentation temperature: 46’C
• at the end: cooled to 5’C
• pH: lactic acid makes it 4.4

Question 13

Cheese production

Answer 13

1 - Fat and protein content is adjusted and the milk is homogenized (mechanical process which breaks up fat droplets)
2 - Pasteurization
3 - Culture added: usually Streptococcus or Lactobacillus
- Fermentation temperature: around 40’C
4 - A mixture of enzymes, rennet, is added
- Rennet contains enzyme chymosin: coagulates the casein (milk protein) and forms curds
5 - Liquid part (whey) is drained from curds
6 - Curds are partially dried and compressed
- bacterial enzymes act on the proteins and fats in the curds, partly digesting them to amino acids and fatty acids

Question 14

Fermenters

- features, conditions

Answer 14

• Fermenters: giant tanks, up to 100,000 litres in capacity
• Sometimes called bioreactors
  Used to produce food and drinks , and to grow microorganisms
• Filled with a nutrient solution
• Conditions (temperature, pH, nutrients, oxygen concentration, waste product concentration, sterile conditions) are carefully controlled
• 26’C, 4-5 pH
  Key features:
  1 - cool water jacket for optimum temp
  2 - Air supply
  3 - paddles to stir liquid
  4 - outlet pipe to harvest product
  5 - outlet for waste gases

Question 15

How do antibiotics attack bacteria?

Answer 15

• Bacteriostatic antibiotics: Disrupt production of cell wall, or cause them to burst open, to prevent bacteria from reproducing, or interfere with protein synthesis and arrest bacterial growth
• Bacteriocidal: kill the bacteria

Question 16

Production of penicillin

- process

Answer 16

• The carbohydrate source is sugar, mainly lactose
• produced by the mould Penicillium chrysogenum
• nutrient solution w sugars, minerals, amino acids added
• A starter culture with spores and filaments of Penicillium added
• The mould begins to make penicillin when it starts to use up all the growth medium
• this happens about 40 hours in to incubation period and continues for many days
• Penicillin is secreted out of the cells
• Fermenter now contains a dense mass of cells, unused nutrients, waste products and penicillin solution
• contents are filtered
• penicillin is extracted from the solution using a series of organic solvents
• re-dissolved into a solution of sodium hydrocarbonate and is allowed to crystallise
• can be stored at room temperature, and modified to produce a range of antibiotics

Question 17

• Objective of single-cell protein?
• what micro-organisms are used?
• What is one that has been commercially used, how is it produced, advantages and disadvantages?

Answer 17

• To produce micro-organisms in bulk to use as human food or animal feed.
• Unicellular algae, fungi and bacteria.
• commercially used: mycoprotein made from a fungus: Quorn.
• The fungus is grown in a medium containing glucose and mineral salts, at 30’C, in a fermenter.
• the process is called continuous culture.
• Medium is circulated around, and fungus is filtered off and dried at a steady rate.
• This is cheaper than doing it in batches, because avoids repeated sterilization.
  Disadvantages:
  1 - More expensive than conventional crops
  2 - colorless and tasteless.
  3 - contain toxic amounts of nucleic acids which have to be removed, because of the high nucleus to cytoplasm ratio
  Advantages:
  1 - Rich in protein
  2 - low in fat
  3- good level of dietary fibre
  4 - vegan alternative
  so healthier than most meat options.