5 - Bacterial Endospores

Question 1

Endospores

Answer 1

• Resistant, dormant spores formed in some genera of bacteria
• Resistant to chemicals, temperature, and radiation
• Confer resistance, survival and dormancy to host bacteria

Question 2

Which bacteria form endospores

Answer 2

• Only members of the low GC subdivision of gram +ves
• Make a single endospore per cell that later germinates to form a single cell

Question 3

Genera of endospore forming bacteria

Answer 3

• Bacillus (rods, aerobic)
• Clostridium (rods, anaerobic)
• Sporosarcina (cocci, aerobic)

Question 4

Swollen sporangium

Answer 4

Spore is wider than the width of the vegetative cell

Question 5

Different locations of endospores

Answer 5

• Terminal
• Subterminal
• Central
• Each location can also be swollen

Question 6

Human significance of endospores

Answer 6

• Set the sterilisation standard
• Medical importance
• Bioterrorism
• Developmental biology
• Pest control in agriculture

Question 7

How did endospores set the sterilisation standard

Answer 7

• Endospores survive hours of boiling, and most chemical disinfectants
• Sterilisation processes must kill endospores (autoclave)

Question 8

Medical importance of endospores

Answer 8

• Several spore-forming species are dangerous pathogens (e.g. tetanus)
• Spores provide a source of contamination & infection

Question 9

Endospore bioterrorism

Answer 9

Use of Bacillus anthracis as a bioterror weapon is based on production and spread of its endospores

Question 10

Endospore developmental biology

Answer 10

increased understanding of differentiation in bacteria

Question 11

Endospore pest control

Answer 11

• Bacillus thuringiensis is
  an insect biopesticide
• Produces a toxic protein

Question 12

What triggers sporulation

Answer 12

• Bacterial response to unfavourable conditions
• Occurs in stationary phase

Question 13

unfavourable conditions that can trigger sporulation

Answer 13

• Absence of nutrients (C, N, P)
• Desiccation (removal of moisture)
• Presence of toxins or antibiotics
• Overcrowding

Question 14

Structure enclosing
cytoplasm in vegetative cells vs endospores

Answer 14

• Vegetative cells: Typical G+ve cell (CW, PM)
• Endospores: Complex of layers

Question 15

Microscopic appearance in vegetative cells vs endospores

Answer 15

• Vegetative cells: non refractile
• Endospores: refractile

Question 16

Enzymatic activity in vegetative cells vs endospores

Answer 16

• Vegetative cells: High
• Endospores: Absent

Question 17

Metabolism in vegetative cells vs endospores

Answer 17

• Vegetative cells: High
• Endospores: Absent

Question 18

Macromolecular synthesis in vegetative cells vs endospores

Answer 18

• Vegetative cells: Present
• Endospores: Absent

Question 19

Resistance (heat, radiation, chemical) in vegetative cells vs endospores

Answer 19

• Vegetative cells: Low
• Endospores: High

Question 20

Sensitivity to lysozyme in vegetative cells vs endospores

Answer 20

• Vegetative cells: Sensitive
• Endospores: Resistant

Question 21

Sustainability in vegetative cells vs endospores

Answer 21

• Vegetative cells: Easy to stain
• Endospores: Special methods needed

Question 22

Cytoplasmic pH in vegetative cells vs endospores

Answer 22

• Vegetative cells: ~7
• Endospores: ~5.5-6

Question 23

Endospore Exosporium

Answer 23

• Outermost layer in SOME species
• Thin glycoprotein layer outside spore coast
• Hair like projections and a basal layer
• Mediates environmental inerations (e.g. adhesion)

Question 24

Endospore Spore coat

Answer 24

• Keratin-like protein layers rich in S-S bonds
• HIghly impermeable
• Provides resistance to chemicals (e.g. lysozyme)

Question 25

Four layers of spore coat

Answer 25

Basement, inner, outer, crust

Question 26

Endospore cortex

Answer 26

• Peptidoglycan with reduced cross linking of NAM residues because cortex PG if modified

Question 27

Function of endospore cortex

Answer 27

Loosely cross-linked flexible cortex may allow spore envelope to expand and contract in response to humidity change

Question 28

Endospore core wall

Answer 28

• Typical cell wall (but no teichoic acids)
• Provides osmotic stability
  at spore germination
• Acts as a primer for regrowth of the vegetative cell wall

Question 29

Endospore inner membrane

Answer 29

Like PM is a good permeability barrier

Question 30

Endospore core

Answer 30

• Cell components typical of
  bacterial cell (nucleoid DNA,
  ribosomes, rRNA, tRNA, etc)
• Components unique to spore

Question 31

Contents of endospore core

Answer 31

• Calcium dipicolinate
• Water content
• Small acid soluble DNA binding proteins (SASPs)
• Phosphoglyceric acid

Question 32

Calcium dipicolinate

Answer 32

• Replaces water
• Absent in normal vegetative cells
• Inserts between DNA bases, helps stabilise the spore DNA and protect it

Question 33

Water content

Answer 33

Low water and lower pH contribute to dormancy and spore survival

Question 34

Small acid soluble DNA binding proteins (SASPs)

Answer 34

• High concentrations
• Alter 3D DNA structure fro, B to A form which is less susceptible to UV damage
• Provide amino acids, carbon and energy for biosynthesis

Question 35

Phosphoglyceric acid

Answer 35

Source of P for ATP generation on germination

Question 36

Endospore ATP, mRNA, amino acids and protein synthesis enzymes

Answer 36

• Absent or insignificant in endospores
• Reflects lack of metabolism

Question 37

Seven stages of endospore formation

Answer 37

1. Axial filament formation
2. Septum formation
3. Engulfment of forespore
4. Cortex formation
5. Coat synthesis
6. Maturation
7. M0ther cell lyses and releases endospore

Question 38

Is endospore cell division symmetrical or asymmetrical

Answer 38

Asymmetrical

Question 39

Coat synthesis

Answer 39

a second impermeable
protective layer forms outside the cortex, and the exosporium forms

Question 40

Axial filament formation

Answer 40

DNA has replicated but not separated

Question 41

How long does endospore formation take

Answer 41

8 hours

Question 42

Genes that control Endospore formation

Answer 42

• spo genes (control of overall sporulation process)
• ssp genes (act inside the endospore, encode SASPs)
• cot genes (act in mother cell, encode spore coat proteins)

Question 43

How have mutation studies elucidated the processes
controlling endospore formation

Answer 43

mutations in particular genes arrest process at different structural and functional stages

Question 44

what systems control sporulation

Answer 44

Controlled by phosphorelay in a two component regulatory system and alternate sigma factors

Question 45

What senses unfavourable environmental conditions (e.g. nutrient depletion)

Answer 45

Sensor kinase proteins such as KinA

Question 46

KinA

Answer 46

• KinA autophosphorylates
• Phosphoryl group then transferred between
  Spo proteins in a phosphorelay
• Eventually Spo0A is phosphorylated

Question 47

spo0A

Answer 47

• Master regulator
• Response regulator protein
• Phosphorylated Spo0A represses genes required for vegetative growth, and activates genes required for
  sporulation

Question 48

Sigma factor genes

Answer 48

• σF (early sporulation gene transcription) and σG (Late sporulation gene transcription)
• Transcribe genes needed in the forespore or the mother cell

Question 49

Two component regulatory system of control of endospore formation

Answer 49

System with with a sensor protein (KinA) and a response regulator protein (spo0A)

Question 50

3 stages involved in breaking endospore dormancy

Answer 50

1. Activation
2. Germination
3. Outgrowth

Question 51

Activation

Answer 51

• Prepares spores for germination
• Requires some form of shock
• Involves damage to spore coat (germination may not occur unless there is coat damage)
• Reversible if a germination agent is absent

Question 52

Germination

Answer 52

• The dormant endospore starts metabolic activity
• Triggered by water and a germination agent (e.g. sugar or amino acid) penetrating the exosporium and coat
• Germination agent interacts with inner membrane receptors, signal sent to activate germination

Question 53

Germination events

Answer 53

1. Cations secreted
2. Spore swells (H2O replaces Ca-DPA)
3. Cortex peptidoglycan is degraded by lytic enzymes (core rehydrates)
4. Initiation of metabolic activity
5. Degradation of coat by proteases
6. Loss of heat resistance
7. SASPs degraded (supplying amino acids, DNA repaired)
8. ATP generated from 3 phosphoglycerate

Question 54

Outgrowth

Answer 54

• Cell components are made in the core (SASPs act as carbon and energy source - makes proteins, RNA, DNA)
• Protoplast emerges
• Vegetative growth is resumed