Lecture 36

Question 1

What are some strategies to protect nitrogenase from irreversible O2 damage?

Answer 1

1. Anaerobic N2-fixation
   
   • strict anaerobes
   • Facultative anaerobes
2. REspiratory and conformational protection
3. Microaerophilic N2-fixation
4. Compartmentation
   - Heterocysts
   - Root nodules

Question 2

Describe anaerobic N2 fixation strategy

Answer 2

1. strict anaerobes
   - Obligate anaerobes such as Clostridium sp. that can fix N2 only in live anaerobic niche
2. Facultative anaerobes
   - Species such as K. pneumoniae only fix N2 under anaerobic conditions
   • Do not fix N2 under aerobic conditions

Question 3

Explain conformation protection N2 fixing strategy

Answer 3

FeSII protein

• protects nitrogenase from oxidative damage by binding to it
  - Binds nitrogenase when oxidized
  - Releases nitrogenase when reduced

The protein will sense oxygen before nitrogenase=> and change conformation
- Only found in AZOBACTER

Question 4

Explain respiratory protection N2 fixation strategy

Answer 4

High rate of respiration uses up O2 at cell surface results in low enough intracellular [O2] for nitrogenase to function

• Occurs at high [O2] if energy source not limiting

Simple story:

• Oxygen is needed near the membrane for electron transport chain
• No need of oxygen in cytoplasm…
• Use very high rate of respiration to burn the oxygen
• Keeps the cytoplasm anaerobic

=> A. vinelandii respiratory chain adapts to [O2] => they have 2 electron transport chain

Question 5

Explain microaerophilic N2-fixation strategy

Answer 5

Microaerophiles (AZOSPIRILLUM) possess terminal oxidases with high affinity for O2 to allow aerobic respiration at low [O2]

• Azospirillum is commonly used as a plant-growth promoting bacterium (PGPR), inoculated onto cereal crops etc.
• High affinity terminal oxidase “burns up” the O2 at the cell surface, resulting in a very low intracellular [O2]
  => REspiratory protection of nitrogenase
• Aerobic respiration allows cells to generate ATP very efficiently to support N2-fixation
• Microaerophilic diazotrophs perform a delicate balancing act between incompatible processes: N2 fixation and aerobic respiration
• Can use aerotaxis to move in optimal [O2] (low) zones

Question 6

What are the 2 compartmentation strategies?

Answer 6

• Heterocysts

- Root nodules

Question 7

Describe heterocysts

Answer 7

• Single-celled cyanobacteria that can fix N2 only do so at night, when oxygenic photosynthesis is not active
• When N-demand is sensed in cyanbacteria that grow in chains and that can fix N2, some of the vegetative cells differentiate into heterocysts which can fix N2 day or night
• Heterocyst supplied by vegetative cells with disaccharides as carbon and energy source
• Exchance of C and N via microplasmadesmata!!!!

Question 8

How can heterocysts be oxygen free?

Answer 8

Spatial separation of N2-fixation and oxygenic photosynthesis
- NO PS2 (oxygenic) in heterocysts

  - Thick cell wall=O2 barrier 
  - Rapid NH4+ assimilation and movement of fixed N out of heterocyst

Question 9

How do heterocyst and vegetative cells exchange C and N ?

Answer 9

Via microplasmadesmata

Question 10

What organisms can form root nodules? In what plant?

Answer 10

Rhizobia (in legumes)

Frankia sp ( alder)

Question 11

How is O2 concentration regulated in nodules?

Answer 11

1. Root nodule O2 barrier
   
   • Tighly linked, water filled polant cells on periphery
2. O2 transport and binding within the root nodule
   
   • Leghemoglobin
   • Maintains low [dissolved O2] , high flux from outside
3. HIgh rate of respiration by bacteroids
   - Terminal oxidase has high affinity for O2
   - Also functions as a form of respiratory protection

Question 12

What are examples of symbiotic N2-Fixation?

Answer 12

1. Cyanobacteria with plants
   
   • Aquatic fern Azolla with cyanobacterium Anabaena azollae
2. Cyanobacteria with fungi and lichens
3. Actinomycetes with woody plants
   - Frankia (filamentous bacteria) with plants such as Alnus (alder, common in bogs etc. )
   - N2-fixing form (diazovesicles) have thick cell walls => O2 barriers
4. Rhizobium-legume symbiosis
   - Interaction between plant and bacteria species is usually very specific

Question 13

Describe legumes?

Answer 13

Plant family with 15 0000 species
- Most are nodulated by Rhizobia

Very diverse morphology, ecology

Arctic annuals, tropical trees, crop, plants
- Peas, beans, soybean, clover, alfalfa, peanut etc

Legumes and N:

• LEgumes can grow in N-poor soil if nodulated
• Rhizobia can supply plant with all N needed
• Selective advantage over non-legumes in that niche

The plant supplies bacteroids within the nodules an energy sourc in the form of **C4-dicarboxylic acids **

• Plants is in control, and does not invest energy in nodulation and symbiotic N2-fixation if N is not needed

Question 14

What are the steps in root nodule formation?

Answer 14

1. species-specific plant flavonoid signals
2. Rhizobial response
   a. colonization
   b. induction of nod genes and species-specific Nod signals
3. Plant response to specific Nod signal
4. Infection
   a. Infection thread
   b. Contact recognition
5. Nodule and bacteroid development
6. Nutrient exchange