Alcohol Dehydrogenase
'Alcohol dehydrogenases' () are a group of
dehydrogenase enzymes that occur in many organisms and facilitate the interconversion between
alcohols and
aldehydes or
ketones. In
humans and many other
animals, they serve to break down alcohols which could otherwise be toxic; in
yeast and many
bacteria, some alcohol dehydrogenases
catalyze the opposite reaction as part of
fermentation.
The
CAS number for this type of the enzyme is [9031-72-5].
In humans
In humans, the enzyme is contained in the lining of the
stomach and in the
liver. It catalyzes the
oxidation of
ethanol to
acetaldehyde:
:CH
3CH
2OH + NAD
+ → CH
3CHO +
NADH + H
+
This allows the consumption of
alcoholic beverages, but its evolutionary purpose is probably the breakdown of alcohols naturally contained in foods or produced by
bacteria in the
digestive tract.
Alcohol dehydrogenase is also involved in the toxicity of other types of alcohol: for instance, it oxidizes
methanol to produce
formaldehyde and
ethylene glycol to ultimately yield
glycolic and
oxalic acids. Humans have at least six slightly different alcohol dehydrogenases. All of them are
dimers (consist of two
polypeptides), with each dimer containing two
zinc ions Zn
2+. One of those ions is crucial for the operation of the enzyme: it is located at the catalytic site and holds the
hydroxyl group of the alcohol in place.
In yeast and bacteria
In
yeast and many
bacteria, alcohol dehydrogenase plays an important part in fermentation:
pyruvate resulting from
glycolysis is converted to acetaldehyde and
carbon dioxide, and the acetaldehyde is then reduced to ethanol by an alcohol dehydrogenase called ADH1. The purpose of this latter step is the regeneration of NAD+, so that the energy-generating glycolysis can continue. Humans exploit this process to produce alcoholic beverages, by letting yeast ferment various fruits or grains.
The main alcohol dehydrogenase in yeast is larger than the human one, consisting of four rather than just two subunits. It also contains zinc at its catalytic site.
Together with the zinc-containing alcohol dehydrogenases of animals and humans, these enzymes from yeasts and many bacteria form the family of "long-chain"-alcohol dehydrogenases.
Brewer's yeast also has another alcohol dehydrogenase, ADH2, which evolved out of a duplicate version of the chromosome containing the ADH1 gene. ADH2 is used by the yeast to convert ethanol back into acetaldehyde, and it is only expressed when sugar concentration is low. Having these two enzymes allows yeast to produce alcohol when sugar is plentiful (and this alcohol then kills off competing microbes), and then continue with the oxidation of the alcohol once the sugar, and competition, is gone.
[1]
Iron-containing alcohol dehydrogenases
A third family of alcohol dehydrogenases, unrelated to the above two, are
iron-containing ones. They occur in bacteria, and an (apparently inactive) form has also been found in yeast. In comparison to enzymes the above families, these enzymes are oxygen-sensitive.
Other alcohol dehydrogenase types
A further class of alcohol dehydrogenases belongs to quinoenzymes and requires quinoid cofactors (e. g. pyrroloquinoline quinone, PQQ) as enzyme-bound electron acceptors. A typical example for this type of enzyme is methanol dehydrogenase of methylotrophic bacteria.
Applications
In fuel cells: Alcohol dehydrogenases can be used to catalyze the breakdown of fuel for an ethanol
fuel cell. Scientists at
Saint Louis University used carbon-supported alcohol dehydrogenase with poly(
methylene green) as an anode, with a
nafion membrane, to achieve about 50 μ
A/cm²
[2].
In biotransformation: Alcohol dehydrogenases are often used for the synthesis of enantiomerically pure stereoisomers of chiral alcohols. In contrast to the chemical process, the enzymes yield directly the desired enatiomer of the alcohol by reduction of the corresponding ketone.
See also
★
Oxidoreductase
External links
★
PDBsum has links to three-dimensional structures of various alcohol dehydrogenases contained in the
Protein Data Bank
★
ExPASy contains links to the alcohol dehydrogenase sequences in
Swiss-Prot, to a
Medline literature search about the enzyme, and to entries in other databases.
★
BRENDA most comprehensive compilation of information and literature references about the enzyme; requires payment for commercial users
★
Radio Free Genome created a musical score from a sequence of alcohol dehydrogenase. MP3 audio version and an open source version of the software used to create it is available.
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