ETFA


The human ETFA gene encodes the Electron-transfer-flavoprotein, alpha subunit, also known as ETF-α.. Together with Electron-transfer-flavoprotein, beta subunit, encoded by the 'ETFB' gene, it forms the heterodimericElectron transfer flavoprotein. The native ETF protein contains one molecule of FAD and one molecule of AMP, respectively.
First reports on the ETF protein were based on ETF isolated from porcine liver.
Porcine and human ETF transfer electrons from mitochondrial matrix flavoenzymes to Electron transfer flavoprotein-ubiquinone oxidoreductase encoded by the ETFDH gene. ETF-QO subsequently relays the electrons via ubiquinone to complex III in the respiratory chain. The flavoenzymes that transfer electrons to ETF are involved in fatty acid beta oxidation, amino acid catabolism, choline metabolism, and special metabolic pathways. Defects in either of the ETF subunits or ETFDH cause multiple acyl CoA dehydrogenase deficiency, earlier called glutaric acidemia type II. MADD is characterized by excretion of a series of substrates of the upstream flavoenzyes, e.g. glutaric, lactic, ethylmalonic, butyric, isobutyric, 2-methyl-butyric, and isovaleric acids.

Evolutionary relationships

ETF is an evolutionarily ancient protein with orthologues found in all kingdoms of life. ETFs are grouped into 3 subgroups, I, II, and III. The best studied group are group I ETFs that in eukaryotic cells are localized in the mitochondrial matrix space. Group I ETFs transfer electrons between flavoenzymes. Group II ETFs may also receive electrons from ferredoxin or NADH.

Gene, expression, and subcellular localization

The human ETFA gene encoding the alpha subunit of ETF is localized on chromosome 15. It is composed of 12 exons. Little is known about its promoter and transcriptional regulation. Global expression analyses show that it is expressed at substantial levels in most tissues. ETF-α is translated as a precursor protein with an N-terminal mitochondrial targeting sequence. It is posttranslationally imported into the mitochondrial matrix space, where the targeting sequence is cut off.

Posttranslational modifications and regulation

Acetylation and succinylation of lysine residues and phosphorylation of serine and threonine residues in ETF-α have been reported in mass spectrometric analyses of posttranslational modifications . Electron transfer flavoprotein regulatory factor 1 has been identified as a protein that specifically binds ETF and this interaction has been indicated to inactivate ETF by displacing the FAD.

Structure and interaction with redox partners

As first shown for porcine ETF, one chain of ETF-α assembles with one chain of ETF-β, and one molecule each of FAD and AMP to the dimeric native enzyme. The crystal structure of human ETF was reported in 1996. This showed that ETF consists of three distinct domains. The FAD is bound in a cleft between the two subunits and interacts mainly with the C-terminal part of ETF-α. The AMP is buried in domain III. A crystal structure of the complex of one of its interactors, medium-chain acyl-CoA dehydrogenase has been determined. . This identified a so-called recognition loop formed by ETF-β that anchors ETF on one subunit of the homotetrameric MCAD enzyme. This interaction triggers conformational changes and the highly mobile redox active FAD domain of ETF swings to the FAD domain of a neighboring subunit of the MCAD tetramer bringing the two FAD molecules into close contact for interprotein electron transfer.

Molecular Function

Human ETF receives electrons from at least 14 flavoenzymes and transfers them to ETF-ubiquinone oxidoreductases in the inner mitochondrial membrane. ETF:QO in turn relays them to ubiquinone from where they enter the respiratory chain at complex III. Most of the flavoenzymes transferring electrons to ETF are participating in fatty acid oxidation, amino acid catabolism, and choline metabolism. ETF and ETF:QO thus represent an important hub for transfer of electrons from various redox reactions and feeding them into the respiratory chain for energy production.

Genetic deficiencies and molecular pathogenesis

Deleterious mutations in the ETFA and ETFB genes encoding ETF or the ETFDH gene encoding ETF:QO are associated with multiple acyl-CoA dehydrogenase deficiency. Biochemically, MADD is characterized by elevated levels of a series of carnitine conjugates of the substrates of the different partner dehydrogenases of the ETF/ETF:QO hub, e.g. glutaric, lactic, ethylmalonic, butyric, isobutyric, 2-methyl-butyric, and isovaleric acids. Accumulation of substrates and derivatives of the upstream dehydrogenases and energy deficiency upon fasting cause the clinical phenotype. Mostly depending on the severity of the mutation, the disease is divided into three subgroups: type I, type II, and type III. There is no cure for the disease, and treatment is employing a diet limiting protein and fat intake, avoidance of prolonged fasting, both to alleviate the flow through the partner dehydrogenases. In addition, supplementation of riboflavin, the precursor of the FAD co-factor can stabilize mutant ETF and ETF:QO variants with certain missense mutations.