molecular microbiology bioenergetics bacteriology for 2001

Molecular Microbiology

BioenergeticsBacteriology for 2001

Molecular Microbiology 2

Outline

• Bacterial bioenergetics– What does this mean?– Mitchell’s hypotheses– Why G and mV do not appear in

these lectures

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Bacterial bioenergetics

• What I expect you to understand– electron transport chain and ATP

synthesis– How bacteria are adapted to pursue

life according to Mitchell’s hypotheses

• What is possible irrelevant– measuring PMF– the concept of Gibbs free energy

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How does bacterial metabolism work

• Central pathways of metabolism• Electron transport chain• ATP synthase

• Are these separate entities or do they work together?

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What is the point of the ETC?

• To reduce oxygen to water?• To transport electrons?• To move protons across a

membrane?• All of the above with a side

order of chips?

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Mitchell’s postulates

• Four postulates to explain– respiratory phosphorylation– transport of solutes– all membrane-based enzymology

Molecular Microbiology 7Periplasmic space

Building a chemiosmotic organism

Cell membrane

ATP

ADP + Pi

H+

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Building a chemiosmotic organism

ATP

ADP + Pi

H+

H+ H+ H+

H+

H+

H+

H+

H+H+

ATP

ADP + Pi

H+

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Building a chemiosmotic organism

H+ H+ H+

H+

H+

H+

H+

H+H+

ATP

ADP + Pi

H+

H+Solute

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Mitchell’s postulates

• Four postulates to explain– respiratory phosphorylation– transport of solutes– all membrane-based enzymology

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Postulate 1

• The respiratory or photosynthetic electron transport chains should translocate protons– i.e. the electron transport chain

and other reactions should function as proton pumps

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Building a chemiosmotic organism

ATP

ADP + Pi

H+

H+ H+ H+

H+

H+

H+

H+

H+H+

ATP

ADP + Pi

H+

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Postulate 2

• The ATP synthase should function as a reversible proton-translocating ATPase– f1f0 ATPase– activity in the absence of a PMF– reverse flow in presence of PMF

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Building a chemiosmotic organism

ATP

ADP + Pi

H+

H+ H+ H+

H+

H+

H+

H+

H+H+

ATP

ADP + Pi

H+

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Postulate 3

• Energy-translocating membranes should have a low effective proton conductance– For a chemiosmotic organism to

survive,protons must only be able to move through proteins, and not through membranes

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Building a chemiosmotic organism

ATP

ADP + Pi

H+

H+ H+ H+

H+

H+

H+

H+

H+H+

ATP

ADP + Pi

H+

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Postulate 4

• Energy-transducing membranes should possess specific exchange carriers to permit metabolites to permeate, and high osmotic stability to be maintained, in the presence of a high membrane potential

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Ports, symports, antiports

Solute

Basic port

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Ports, symports, antiports

Solute

Symport

H+

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Ports, symports, antiports

Solute

Antiport

Solute H+or

H+ or

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So what drives ATP synthesis?

• What is the primary pump?• The electron transport chain

pumps 10 protons per NADH + H+

• The NADH + H+ produced during glycolysis etc. is used to create ATP chemiosmotically

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The ETC is the primary pump in aerobic respiratory

organisms

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Bacteria are chemiosmotic

organisms• Paracoccus denitrificans is an

obligately respiratory organism.

• Has an f1f0 ATPase which is coupled to a conventional electron transport chain.

• E. coli is similar but has a strange ETC and can ferment

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The bacterial f1f0 ATPase

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What can pH be used for?

• Solute transport– substrates– drug efflux– maintenance of ionic balance

• Bacterial flagellar motion

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What is the point of the ETC?

• To reduce oxygen to water?• To transport electrons?• To move protons across a

membrane?

Sometimes

How does it all link in?

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H+ H+ H+

H+

H+

H+

H+

H+

H+

ATP

ADP + Pi

H+

H+NADH + H+

reduced FMNNADH + H+

reduced FMN

Reducedelectronacceptor

Carbon Source

GlycolyticPathway

TCA

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Short questions for group work

• What other means are there of generating PMF?

• What other uses can a proton gradient be put to in bacterial cells?

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Section IIChemiosmotic solutions

to environmental problems

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Aerobic neutrophiles

H+

H+

H+

H+

H+

H+

H+

H+

ATP

ADP + Pi

H+

H+Solute

External pH 6-8

Internal pH 6-8

--

--------

-

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Aerobic acidophilesH+ H+

H+

H+

H+

H+

H+

H+

ATP

ADP + Pi

H+

H+Solute

External pH 1-4

Internal pH 5.5

++

++++++++

+

Molecular Microbiology 39

Aerobic alkaliphiles

ATP

ADP + Pi

H+

Na+Solute

External pH 10-11

Internal pH 8.2

--

--------

-

Na+

H+

++

+

++++++

++

H+

Molecular Microbiology 40

Halophiles

ATP

ADP + Pi

H+

Na+Solute

--

--------

-

Na+

H+

++

+

++++++

++

H+

H+

Light

External pH 6-10

Internal pH 6-8

Molecular Microbiology 41

Marine/halotolerant

ATP

ADP + Pi

Na + or H+

Na+Solute

--

--------

-

Na+

H+

++

+

++++++

++

Na+ or H+

External pH 6-10

Internal pH 6-8

Section III

An example of a proton pump

Bateriorhodopsin

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Halobacterium salinarum

• A member of the Archaea• Also known as Halobacterium

halobium • When grown aerobically utilises a

normal respiratory chain

• In the light under very low O2, purple patches appear on their membranes

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Halobacterium salinarum

• Cells lack chlorophyll• Still can generate ATP from

light• Protons are pumped by a

simple (ish) to understand mechanism centered on bacteriorhodopsin

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Bacteriorhodopsin, crystal structure

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Bacteriorhodopsin, crystal structure, showing retinal

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Bacteriorhodopsin, crystal structure, showing retinal, top view

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Clever bacterium

• Halobacterium salinarum possesses four rhodopsins– bacteriorhodopsin (bR)

– halorhodopsin (HR)

– sensory rhodopsins I and II

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See overhead

• Mechanism p184 Nicholls & Ferguson

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References

• Nichols and Ferguson - Bacterial Bioenergetics (Academic Press)

• Lehninger, Stryer or another good biochemistry text book

• ASM News