Lecture 37

Question 1

Describe the step 1 of root nodule formation

Answer 1

1. Species specific plant flavanoid signals

• The root exudates of different legumes species each contain a UNIQUE COKCTAIL OF FLAVONE AND ISOFLAVONE (organic) compounds that function as species-specific chemical ID signals
  
  • Soybean: Genistein, daidzein (isoflavones)
  • Alfalfa : Luteoln (flavone)

Question 2

Describe the step of nodule formation

Answer 2

2. Rhizobial response

A. COLONIZATION
- Rhizobia living in soil can sense and respond to flavonoid signals of their specific root plant (don’t respond to non-host plant species)

• Rhizobia will colonize the rhizosphere, especially near root hair tips
• Quorum sensing determines if sufficient number of rhizobia are present for successful nodule formation )

B. induction of NOD GENES and species-specific NOD SIGNALS
- Bacterial nod genes are induced (only) in response to the specific flavonoid of their host plant

• The nod genes encoded enzymes that synthesize a unique lipochitoologosaccharide (LCO) NOD SIGNAL or NOD FACTOR
  - Short chitin backbone
  - FA side chain
  - Unique R-group decorations for host specificity
• UNIQUE NOD SIGNAL function as species-specific chemical ID response signals that stimulate the specific host plant to initiate root nodule formation

Question 3

What are structural characterstics of the Nod signal or nod factor?

Answer 3

• Short chitin backbone
• FA side chain
• Unique R group

Question 4

The enzyme that synthesize the NOd signal sugar backbone and adds the FA is encoded by which nod genes?

Answer 4

NodABC (common nod genes)

Question 5

The enzymes that decorate the NOd signals in a species-specific manner are encoded by what nod genes?

Answer 5

HOST SPECIFIC nod genes

Question 6

Describe step 3 of the nodule formation

Answer 6

3. Plant reponse to specific Nod signal

• Plants only respond to Nod signal/factor made by their specific symbionts : complex biochemical responses to NF result in changes in gene expression and cellular regulation
  - root hair curling
  - De-differentiation of root inner cortex cells
  - Cell division begins nodule formation

Question 7

Describe step 4 of nodule formation

Answer 7

4. Infection

A. INFECTION THREAD

• Rhizobial cells penetrate into the crook of a root hair
• Tube-like infection thread (IT) forms within root hair
  - Contains a polysaccharide matrix
• Bacteria grow along with the IT until they enter the plant cells

B. CONTACT RECOGNITION

• Plant recognizes that the bacteria in the IT are the correct species
• Plant is on verge of a defense reaction and will abort nodule if it decides the wrong species may be present => This prevents infection by pathogens
• Recognition via perception of bacterial cell surface determinants:
  
  • EXOPOLYSACCHARIDES (EPS)
  • LIPOPOLYSACCHARIDES (LPS)

Question 8

Describe step 5 of nodule formation

Answer 8

5. Nodule and Bacteroid development
   - Infecting Rhizobia are enveloped by a peribacteroid membrane
   - Plant and bacterial cells develop into the speialized nodule tissues necessary for N2-fixation to occur

• Bacteria within peribacteroid membrane stop growing
  - Become terminally differentiated “bacteroids”
  - Bacteroids synthesize nitrogenase then fix N2
• Leghemoglobin produced by the plant functions to:
  - Facilitate rapid transport O2 to the bacteroids
  - Protect nitrogenase from O2 damage by binding free O2

Question 9

What is the function of leghemoglobin?

Answer 9

Facilitate rapid transport of O2 to the bacteroids

Protect nitrogenase from O2 damage by binding free O2

Question 10

Describe step 6 of nodule formation

Answer 10

6. Nutrient exchange => The heart of rhizobium-legume symbiosis

Photosynthesis by plant tields sugards that are:

• Transported to root nodule cells
• Converted to C4-dicarboxylic acids
  
  • Succinate, fumarate, malate, malate

C4-dicarboxylic acids:

 - The bacteroids sole source of energy 
 - Not used for growth by the bacteroids 
 - Oxidized directly via TCA cycle 

This generates energy and reducing power for N2-fixation

Bacteroids provide the plant with fixed nitrogen => NH4+ and alanine

Question 11

Why do bacteroids stop growing?

Answer 11

Free-living rhizobia can grow using malate as carbon and energy source but bacteroids can only use it as an energy source
=> Malate CANNOT be used for growth by bacteroids

=> bacteroids cannot express PEP carboxykinase=> enzyme needed for growth on malate

• Bacteroids cannot be cultured from crushed nodules
• Control of bacteroid growth prevents parasitism/pathogenicity
  => Energy invested by plant is used to fuel N2-fixation

Question 12

What benefit do Rhizobia derive from the symbiosis?

Answer 12

Release of undifferentiated bacteria from the nodule
=> When the nodule or plant dies

• The very small number of infecting cells give rise to many times their number within each nodule
• Cells grow during infection and some are maintained in an undifferentiated viable state in the infection threads
• Undifferentiated cells can be cultured from crushed nodules

Some strains of rhizobia produce rhizopines within the nodule
- Rhizopines are tailor-made NUTRIENTS that can feed rhizobia of the same strain (but not other bacteria) in the rhizosphere