''Acetobacterium'' is a genus of anaerobic, Gram-positive bacteria that belong to the

Eubacteriaceae The Eubacteriaceae are a family of Gram-positive bacteria in the order Clostridiales. Phylogeny The currently accepted taxonomy based on the List of Prokaryotic names with Standing in Nomenclature (LPSN) and the National Center for Biotechnology ...

family. The

type species In zoological nomenclature, a type species (''species typica'') is the species name with which the name of a genus or subgenus is considered to be permanently taxonomically associated, i.e., the species that contains the biological type specime ...

of this genus is ''Acetobacterium woodii''. The name, ''Acetobacterium'', has originated because they are acetogens, predominantly making acetic acid as a byproduct of anaerobic metabolism. Most of the species reported in this genus are homoacetogens, i.e. solely producing acetic acid as their metabolic byproduct. They should not be confused with

acetic acid bacteria Acetic acid bacteria (AAB) are a group of Gram-negative bacteria which oxidize sugars or ethanol and produce acetic acid during fermentation. The acetic acid bacteria consist of 10 genera in the family Acetobacteraceae. Several species of acetic ...

which are aerobic, Gram-negative

Alphaproteobacteria Alphaproteobacteria is a class of bacteria in the phylum Pseudomonadota (formerly Proteobacteria). The Magnetococcales and Mariprofundales are considered basal or sister to the Alphaproteobacteria. The Alphaproteobacteria are highly diverse and ...

. Other acetogens use the Wood–Ljungdahl pathway to reduce CO or CO₂ and produce acetate, but what distinguishes ''A.woodii'' and other ''Acetobacterium'' from other acetogens is that it conserves energy by using an Rnf complex to create a sodium gradient rather than a proton gradient. This means that ''A.woodii'' would need sodium in its environment in order to make ATP. When reducing CO₂ to acetate the ''Acetobacterium'' uses the Wood–Ljungdahl pathway with CO₂ as the electron acceptor. However, the Acetobacterium can use other electron acceptors like caffeate. To use caffeate as an electron acceptor the bacterium couples hydrogen dependent caffeate reduction with electrons from hydrogen and uses sodium ions as coupling ions. The step in the electron transport chain that creates the sodium gradient is the ferredoxin-dependent reduction of NAD⁺. One application of ''Acetobacterium'', is that ''A. woodii'' could be used in the transformation of tetrachloromethane to dichloromethane and carbon dioxide by reductive dechlorinations, but the reactions taken to get to the final product are unknown. This reaction is useful because the products, CO₂ and dichloromethane are less toxic than tetrachloromethane. Another application of ''A.woodii'' is that it can reduce the effects of greenhouse gases since A.woodii can be used to convert CO₂ and CO into acetyl-CoA which could then be used to make other chemicals like ethanol and acetate. The production of ethanol by ''Acetobacterium'' using chemolithotrophic methods is important because ethanol can be used as a biofuel. By using the ethanol that is produced by the bacterium researchers aim to create a sustainable way to create energy.

References

Eubacteriaceae Bacteria genera {{Clostridia-stub