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Question 1

Anhydrobiosis:

Answer 1

The ability to dry out completely and rehydrate again. Employed by small aquatic animals, protozoa, bacteria and plants. Lose all water and regain metabolic activity.

Question 2

examples of anhydrobiosis

Answer 2

EXAMPLES:

1) Tardigrades
2) Nematodes
3) Rotifers
4) Springtails
5) Midge larvae
6) Resurrection plants
- All are small, have little/no control over water loss from body, generally aquatic inhabitants where there are, we/dry seasons

Question 3

 Tardigrades + adaptions

Answer 3

• Water bears which live on thin film of water on hydrated mosses, soil and temporary pools
• Phylogenetic group between arthropods and nematodes
  Adaptions:
• They are polyextremophiles (tolerate desiccation, exposure to toxic chemicals, low temperatures, vacuum, high pressure, radiation, extreme pH and anoxia
• Mediated by synthesis of bioprotectants (carbohydrates and proteins), free radicals, specific phospholipids and DNA repair mechanisms

Question 4

Rotifers

Answer 4

• Fresh water animals with reduced bodies
• Polyextremophiles
• Fully asexual (only organisms which has no sexual reproduction in millions of years

Question 5

Midge Larvae

Answer 5

• Polypedilum vanderplankii (insect)
• Live in ephemeral pools in Africa
• Largest known anhybiont, takes 45 minutes to resurrect to previous activity
• Cells highly drought resistant BUT not all cells can re-establish metabolic activity
• Larvae have unusual lipid and sugar composition

Question 6

ressurection plants

Answer 6

• Selaginella lepidophylla (False rose of Jericho), native to chuhuahuan desert
• Reduced roots, thick leaves, survives decades without water
• Able to resurrect within few hours of watering
• Unusual lipid sugar composition

Question 7

Genetic adaptions

Answer 7

• Expression of specific proteins induced by desiccation
• Small heat shock proteins (SHSPs)
• Late embryogenesis abundant proteins (LEA)
  o Evidence: magnolia seeds from 2,000 years old flowered in 1994
  o LEA proteins abundant, a-helix rich, heat stable and hydrophilic proteins
  o Can function of chaperones or stabilise cytoskeleton
  o Dehydrins: group of LEA proteins, bigger and more complex, hydrophilic and range of biological functions

Question 8

2) Biochemical adaptations

Answer 8

• Accumulation of non-reducing disaccharides (sugars not metabolised by cell)
• Trehalose: Tardigrades, nematodes and yeast (detected by HPLC analysis) Trehalose replaces other sugars during dehydration as has a great water retention capacity. Rapid conversion to glycogen upon rehydration in anhydrobiotes.

Question 9

 Importance of water for membrane function

Answer 9

1) Osmosis
2) Vesicle transport
3) Membrane fusion
4) Pathogenesis
5) Irreversible damage of membrane components
- Hard to protect due to lipid membrane

Question 10

Vitrification

Answer 10

: Transformation of the cytoplasm into a glassy state because of freezing/ drying. This retains physical properties of liquid state and is key to long-term survival
 Glass is physically solid/brittle but thermodynamically liquid. IT changes the physics of water between call and maintains organised state
 Protects the membrane and proteins. Without water the lipids are lost
 Creates layer between lipids = traps water

Question 11

vitrification process

Answer 11

1. Cytoplasm transformed through trehalose
2. Cohesive forces between cytosolic components increases (stabilised cells macromolecules, in membranes water replaced by sugars to prevent close approach of lipids)
3. High molecular packing and viscosity = low molecular mobility

Question 12

practical applications

Answer 12

• LEA proteins = cellular stability in industry and medicine, can engineer resistant microbes with LEA proteins
• Trehalose = drought resistance in plants, spray plants with precursors of trehalose or new crops which produce trehalose
• Improved biological stability, biological and medical applications, space program development
• HydRIS vaccines: Deliver vaccines without refrigeration using a coat of trehalose. Can also be used in eye drops, stable at room temperature over several years

Question 13

 Biological discoveries arising from study of anhydrobiotes

Answer 13

1) Asexual rotifers escape lethal fungal parasites by drying up and blowing away/ dispersing
2) Loss of body segments for tardigrades
o HOX genes: Contain unusual number for development while lacking some other proteins
o Loss intermediate body section as unneeded
o Organisms need time to accumulate proteins for survival in dehydration
o Cytosolic/secreted/ mitochondrial heat soluble protein expression in tardigrades
o CAHS: Proteins used to confer tolerance to desiccation as alter vitrification properties in vivo
3) Anhydrobiotes and survival in outer space
o Bio-risk space research of animals and plants exposed to space vacuum
o Organisms taken to space
o 2008 tardigrades survive exposure to space, space vacuum found to have minor effect on survival
o Some survival after receiving a dose of UV radiation of more than 7,000 kJm-2 under space vacuum
o Unknown survival mechanism
o Current experiments: Phobos-Grunt 2009-2011:
 Mission to collect soil from Phobos (mars satellite) and to bring samples to Earth for research
 Larvae of P. vanderplankii are included to test influence of long-term spaceflight on resting stages of invertebrates