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Learning objectives

  • Define fermentation and explain why it does not require oxygen
  • Describe the fermentation pathways and their end products and give examples of microorganisms that use these pathways
  • Compare and contrast fermentation and anaerobic respiration

Many cells are unable to carry out respiration because of one or more of the following circumstances:

  1. The cell lacks a sufficient amount of any appropriate, inorganic, final electron acceptor to carry out cellular respiration.
  2. The cell lacks genes to make appropriate complexes and electron carriers in the electron transport system.
  3. The cell lacks genes to make one or more enzymes in the Krebs cycle.

Whereas lack of an appropriate inorganic final electron acceptor is environmentally dependent, the other two conditions are genetically determined. Thus, many prokaryotes, including members of the clinically important genus Streptococcus , are permanently incapable of respiration, even in the presence of oxygen. Conversely, many prokaryotes are facultative, meaning that, should the environmental conditions change to provide an appropriate inorganic final electron acceptor for respiration, organisms containing all the genes required to do so will switch to cellular respiration for glucose metabolism because respiration allows for much greater ATP production per glucose molecule.

If respiration does not occur, NADH must be reoxidized to NAD + for reuse as an electron carrier for glycolysis, the cell’s only mechanism for producing any ATP, to continue. Some living systems use an organic molecule (commonly pyruvate) as a final electron acceptor through a process called fermentation . Fermentation does not involve an electron transport system and does not directly produce any additional ATP beyond that produced during glycolysis by substrate-level phosphorylation. Organisms carrying out fermentation, called fermenters, produce a maximum of two ATP molecules per glucose during glycolysis. [link] compares the final electron acceptors and methods of ATP synthesis in aerobic respiration, anaerobic respiration, and fermentation. Note that the number of ATP molecules shown for glycolysis assumes the Embden-Meyerhof-Parnas pathway . The number of ATP molecules made by substrate-level phosphorylation (SLP) versus oxidative phosphorylation (OP) are indicated.

Comparison of Respiration Versus Fermentation
Type of Metabolism Example Final Electron Acceptor Pathways Involved in ATP Synthesis (Type of Phosphorylation) Maximum Yield of ATP Molecules
Aerobic respiration Pseudomonas aeruginosa O 2 EMP glycolysis (SLP)
Krebs cycle (SLP)
Electron transport and chemiosmosis (OP):
2
2
34
Total 38
Anaerobic respiration Paracoccus denitrificans NO 3 , SO 4 −2 , Fe + 3 , CO 2 ,
other inorganics
EMP glycolysis (SLP)
Krebs cycle (SLP)
Electron transport and chemiosmosis (OP):
2
2
1–32
Total 5 36
Fermentation Candida albicans Organics
(usually pyruvate)
EMP glycolysis (SLP)
Fermentation
2
0
Total 2

Microbial fermentation processes have been manipulated by humans and are used extensively in the production of various foods and other commercial products, including pharmaceuticals. Microbial fermentation can also be useful for identifying microbes for diagnostic purposes.

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Source:  OpenStax, Microbiology. OpenStax CNX. Nov 01, 2016 Download for free at http://cnx.org/content/col12087/1.4
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