I was looking this up and I'm wondering if so far I'm correct about the following:

  • For the most part eukaryotes do aerobic respiration, which involves glycolysis, the Krebs cycle and oxidative phosphorylation involving ATP synthase and an ETC
  • Prokaryotes can either do aerobic respiration, anaerobic respiration or fermentation, the first two of which require an ETC and ATP synthases, which would be located in the plasma membrane of the prokaryote

If that is the case, I was wondering if there are prokaryotes that only do fermentation, and if so do they have ATP synthases and an ETC? In other words, are there any organisms without ATP synthases and an ETC (which would force them to survive on fermentation alone, unless there is some other method of energy production in prokaryotes that doesn't use ATP synthases and an ETC that I'm missing)?



3 Answers 3


This is an interesting question (I really mean this — see below), for which a straight answer is remarkably difficult to find on the web. When I googled for it I got pages with statements that obligate anaerobic bacteria still had the electron transport chain (ETC) and ATP synthase as there were different electron acceptors other than oxygen. Yes, we know that things are different in thermal vents and hot springs, but what about gas gangrene? I am not a microbiologist, but I did play with the metabolism of some bacteria for a biochemical bioinformatics lab some years ago, so I can give two instances where anaerobic bacteria appear to lack either the ETC or both the ETC and ATP synthase.

Clostridium perfringens

This is the anaerobic fermenting bacterium that leads to gas gangrene in infected wounds and was a major cause of limb loss and mortality in the First World War. The DNA sequence of Clostridium perfringens has been determined. I quote at length from the paper as it describes the fermentation, but italicise the key statement for those who wish to skip this:

We could not find any genes coding for tricarboxylic acid (TCA) cycle- or respiratory-chain-related proteins, in contrast to C. acetobutylicum, which has incomplete TCA cycle enzymes. Similar to C. acetobutylicum, we could construct a pathway map for anaerobic fermentation resulting in the production of lactate, alcohol, acetate, and butyrate, all of which have been commonly detected in C. perfringens cultures. In the fermentation pathway, pyruvate is converted into acetyl-CoA by pyruvate-ferredoxin oxidoreductase (CPE2061), producing CO2 gas and reduced ferredoxin. Electrons from the reduced ferredoxin are transferred to protons by hydrogenase (CPE2346), resulting in the formation of hydrogen molecules (H2) that are released from the cell together with CO2.

The related bacterium, Clostridium acetobutylicum, mentioned in the extract, is also an obligate anaerobe. (It ferments a variety of plant mono- and poly-saccharides to acetone, butanol and ethanol — used to produce explosives in the First World War.) Although it has some enzymes of the TCA-cycle, it is unable to use the cycle oxidatively, and, like Clostridium perifringens, lacks the enzymes of the electron transport chain and an ATP synthase.

Ureaplasma urealyticum (Ureaplasma parvum)

This micro-organism is a micoplasma (Mollicute) rather than a bacterium — i.e. it lacks a cell wall. It infects the human urogenital tract. It lacks the components of an electron transport chain but does possess a functional ATP synthase. It generates a hydrogen ion gradient, not by increasing the hydrogen ion concentration within the inter-membrane space by the oxidation of NADH in the ETC, but by reducing the intracellular hydrogen ion concentration by generating ammonia from urea (plentiful in its habitat) in a reaction catalysed by the urease it encodes. The sequence of the organism and references to previous work on its urease activity can be found here.

Evolutionary considerations

The reason I find this question interesting is that anaerobic organisms preceded aerobic organisms, so the question arises whether there are any contemporary anaerobic bacteria that have evolved from these primaeval anaerobes and have never possessed an electron transport system — or are all contemporary anaerobic organisms lacking an ETC derived from organisms with an ETC (aerobic or using some other electron acceptor) and have just lost these functions through non-use (as is most likely in the examples above)? This question must surely have been considered by those in the field.

  • $\begingroup$ Very nice! These organisms are super interesting. $\endgroup$
    – Roland
    Apr 23, 2016 at 11:26
  • $\begingroup$ Yes. I find them fascinating too. $\endgroup$
    – David
    Apr 23, 2016 at 11:31

Yes there are, though I had to dig a lot to find them. They are called strictly fermentative bacteria.

Lactic acid bacteria (Lactobacillales (Firmicutes)) ferment glucose through pyruvate to lactate using the glycolytic pathway, and include the genera Streptococcus, Lactococcus, Lactobacillus, and Leuconostoc.

From Madigan et al. 2014 Brock biology of microorganisms, 14th edition (PDF):

p. 66.

"Microbial eukaryotes that contain hydrogenosomes carry out a strictly fermentative metabolism. Examples include the human parasite Trichomonas (Sections 17.3 and 32.4) and various protists that inhabit the rumen of ruminant animals (Sections 1.5 and 22.7) or anoxic muds and lake sediments."


"Reversibility of the ATPase explains why strictly fermentative bacteria that lack electron transport chains and are unable to carry out oxidative phosphorylation still contain ATPases. Many important reactions in the cell, such as flagellar rotation and some forms of transport, are coupled to energy from the pmf rather than directly from ATP. Thus, the ATPase of organisms incapable of respiration, such as the strictly fermentative lactic acid bacteria, functions unidirectionally to generate this required pmf from ATP formed during substrate-level phosphorylation in fermentation."

Trichomonas (Excavata) is an eukaryote.

  • $\begingroup$ I'm no expert, but looking at the English, The statement "" strictly fermentative bacteria that lack electron transport chains" <-- doesn't state that all strictly fermentative bacteria lack an electron transport chain, and doesn't state that strictly fermentative bacteria lack an electron transport chain. If I say "birds that have long legs", it suggests there may be birds that don't have long legs. $\endgroup$
    – barlop
    Oct 5, 2017 at 10:46
  • $\begingroup$ That said, I can see how perhaps strictly fermentative bacteria don't have an ETC(perhaps it'd mean they had an ETC but couldn't ever use it, which would perhaps be strange). But anyhow, while it may well be that they don't have one, that quoted text doesn't say that they don't have one. $\endgroup$
    – barlop
    Oct 5, 2017 at 10:48

This is a very late answer, but many Mycoplasmas lack most major metabolic pathways beyond glycolysis; so no electron transport chain, and no tricarboxylic cycle (refer Pollack et a. 2002).


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