Coenzyme A transferases (CoA-transferases) are transferase enzymes that catalyze the transfer of a

coenzyme A Coenzyme A (CoA, SHCoA, CoASH) is a coenzyme, notable for its role in the synthesis and oxidation of fatty acids, and the oxidation of pyruvate in the citric acid cycle. All genomes sequenced to date encode enzymes that use coenzyme A as a subs ...

group from an

acyl-CoA Acyl-CoA is a group of coenzymes that metabolize fatty acids. Acyl-CoA's are susceptible to beta oxidation, forming, ultimately, acetyl-CoA. The acetyl-CoA enters the citric acid cycle, eventually forming several equivalents of ATP. In this way ...

donor to a

carboxylic acid In organic chemistry, a carboxylic acid is an organic acid that contains a carboxyl group () attached to an R-group. The general formula of a carboxylic acid is or , with R referring to the alkyl, alkenyl, aryl, or other group. Carboxylic ...

acceptor. Among other roles, they are responsible for transfer of CoA groups during

fermentation Fermentation is a metabolic process that produces chemical changes in organic substrates through the action of enzymes. In biochemistry, it is narrowly defined as the extraction of energy from carbohydrates in the absence of oxygen. In food ...

and metabolism of

ketone bodies Ketone bodies are water-soluble molecules that contain the ketone groups produced from fatty acids by the liver (ketogenesis). Ketone bodies are readily transported into tissues outside the liver, where they are converted into acetyl-CoA (acetyl- ...

. These enzymes are found in all three domains of life ( bacteria,

eukaryotes Eukaryotes () are organisms whose cells have a nucleus. All animals, plants, fungi, and many unicellular organisms, are Eukaryotes. They belong to the group of organisms Eukaryota or Eukarya, which is one of the three domains of life. Bacte ...

archaea Archaea ( ; singular archaeon ) is a domain of single-celled organisms. These microorganisms lack cell nuclei and are therefore prokaryotes. Archaea were initially classified as bacteria, receiving the name archaebacteria (in the Archaebac ...

Reactions

As a group, the CoA transferases catalyze 105 reactions at relatively fast rates. Some common reactions include :Acetyl-CoA + Butyrate

\rightleftharpoons

Acetate + Butyryl-CoA :Acetyl-CoA + Succinate

\rightleftharpoons

Acetate + Succinyl-CoA :Acetoacetate-CoA + Succinate

\rightleftharpoons

Acetoacetate + Succinyl-CoA :Formate + Oxalate

\rightleftharpoons

Formate + Oxalyl-CoA These reactions have different functions in cells. The reaction involving acetyl-CoA and butyrate (), for example, forms butyrate during fermentation. The reaction involving acetyl-CoA and succinate () is part of a modified TCA cycle or forms acetate during fermentation. The reaction involving acetoacetate-CoA and succinate () degrades the ketone body acetoacetate formed during ketogenesis. Many enzymes can catalyze multiple reactions, whereas some enzymes are specific and catalyze only one.

Families

The CoA-transferases have been divided into six families (Cat1, OXCT1, Gct, MdcA, Frc, CitF) based on their amino acid sequences and reactions catalyzed. They also differ in the type of catalysis and their crystal structures. Despite some shared properties, these six families are not closely related (<25% amino acid similarity). Three families catalyze CoA-transferase reactions almost exclusively. The Cat1 family catalyzes reactions involving small acyl-CoA, such as acetyl-CoA (), propionyl-CoA (,), and butyryl-CoA (). The OXCT1 family uses oxo (,) and hydroxy acyl-CoA (,). The Frc family uses unusual acyl-CoA, including CoA thioesters of oxalate (,), bile acids (), and aromatic compounds (,(). Two families catalyze CoA-transferase reactions, but they also catalyze other transferase reactions. The CitF family catalyzes reactions involving acetyl-CoA and citrate ), but its main role is as an acyl-ACP transferase (as part of citrate lyase; ). The MdcA family catalyzes reactions involving acetyl-CoA and malonate (), but it too is an acyl-ACP transferase (as part of malonate decarboxylase; ). The Gct family has members that catalyze CoA-transferase reactions, but half of the members do not. They instead catalyze hydrolysis or other reactions involving acyl-CoA. Historically, the CoA-transferases were divided three families (I, II, III). However, members of families I (Cat1, OXCT1, Gct) are not closely related, and the family is not monophyletic. Members of family II (CitF, MdcA) are also not closely related.

Types of catalysis

Most CoA transferases rely on

covalent catalysis Enzyme catalysis is the increase in the reaction rate, rate of a process by a Biomolecule, biological molecule, an "enzyme". Most enzymes are proteins, and most such processes are chemical reactions. Within the enzyme, generally catalysis occurs ...

to carry out reactions. The reaction starts when an acyl-CoA (the CoA donor) enters the active site of the enzyme. A

glutamate Glutamic acid (symbol Glu or E; the ionic form is known as glutamate) is an α-amino acid that is used by almost all living beings in the biosynthesis of proteins. It is a non-essential nutrient for humans, meaning that the human body can syn ...

in the active site forms an adduct with acyl-CoA. The acyl-CoA breaks at the thioester bond, forming a CoA and carboxylic acid. The carboxylic acid remains bound to the enzyme, but it is soon displaced by CoA and leaves. A new carboxylic acid (the CoA acceptor) enters and forms a new acyl-CoA. The new acyl-CoA is released, completing the transfer of CoA from one molecule to another. The type of catalysis differs by family. In Cat1, OXCT1, and Gct families, the catalytic residue in the active site is a glutamate. However, the glutamate in the Cat1 family is in a different position than in the OXCT1 and Gct families. In the Frc family, the catalytic residue is an aspartate, not a glutamate. In MdcA and CitF families, covalent catalysis is not thought to occur.

Crystal structures

Crystal structures have been determined for 21 different enzymes. More structures have been determined, but they belong to putative enzymes (proteins with no direct evidence of catalytic activity). All CoA-transferases have alternating layers of α helices and β sheets, and thus they belong to the α/β class of proteins. The number and arrangement of these layers differs by family. The Gct family, for example, has extra layers of α helices and β sheets compared to Cat1 and OXCT1 families. Further, all enzymes have two different domains. These domains can either occur on the same polypeptide or can be separated between two different polypeptides. In some cases, the genes for the domains are duplicated in the genome.

Occurrence in organisms

CoA transferases have been found in all three domains of life. The majority have been found in bacteria, with fewer in eukaryotes. One CoA transferase has been found in archaea. Two CoA-transferases been found in humans. They include

3-oxoacid CoA-transferase In enzymology, a 3-oxoacid CoA-transferase () is an enzyme that catalyzes the chemical reaction :succinyl-CoA + a 3-oxo acid \rightleftharpoons succinate + a 3-oxoacyl-CoA Thus, the two substrates of this enzyme are succinyl-CoA and 3-oxo acid ...

() and

succinate—hydroxymethylglutarate CoA-transferase In enzymology, a succinate-hydroxymethylglutarate CoA-transferase () is an enzyme that catalyzes the chemical reaction :succinyl-CoA + 3-hydroxy-3-methylglutarate \rightleftharpoons succinate + (S)-3-hydroxy-3-methylglutaryl-CoA Thus, the two s ...

().

Role in disease

Mutations in two different CoA-transferases have been described and lead to disease in humans.

() uses the ketone body acetoacetate. Mutations in the enzyme cause accumulation of acetoacetate and ketoacidosis. The severity of ketoacidosis depends on the mutation. The enzyme

() uses glutarate, a product of tryptophan and lysine metabolism. Mutations in this enzyme cause accumulation of glutarate (glutaric aciduria).

References

{{reflist EC 2.8.3 Transferases