Abstract
A recent report suggested that the thioredoxin-dependent metabolic regulation, which is widespread in all domains of life, existed in methanogenic archaea about 3.5 billion years ago. We now show that the respective electron delivery enzyme (thioredoxin reductase, TrxR), although structurally similar to flavin-containing NADPH-dependent TrxRs (NTR), lacked an NADPH-binding site and was dependent on reduced coenzyme F420 (F420H2), a stronger reductant with a mid-point redox potential (E'0) of -360 mV; E'0 of NAD(P)H is -320 mV. Because F420 is a deazaflavin, this enzyme was named deazaflavin-dependent flavin-containing thioredoxin reductase (DFTR). It transferred electrons from F420H2 to thioredoxin via protein-bound flavin; Km values for thioredoxin and F420H2 were 6.3 and 28.6 μm, respectively. The E'0 of DFTR-bound flavin was approximately -389 mV, making electron transfer from NAD(P)H or F420H2 to flavin endergonic. However, under high partial pressures of hydrogen prevailing on early Earth and present day deep-sea volcanoes, the potential for the F420/F420H2 pair could be as low as -425 mV, making DFTR efficient. The presence of DFTR exclusively in ancient methanogens and mostly in the early Earth environment of deep-sea volcanoes and DFTR's characteristics suggest that the enzyme developed on early Earth and gave rise to NTR. A phylogenetic analysis revealed six more novel-type TrxR groups and suggested that the broader flavin-containing disulfide oxidoreductase family is more diverse than previously considered. The unprecedented structural similarities between an F420-dependent enzyme (DFTR) and an NADPH-dependent enzyme (NTR) brought new thoughts to investigations on F420 systems involved in microbial pathogenesis and antibiotic production.
Highlights
The thioredoxin (Trx)2 system is key to the cellular redox homeostasis in almost all organisms examined [1,2,3,4,5]
We show that the respective electron delivery enzyme, structurally similar to flavincontaining NADPH-dependent Trx reductases (TrxR) (NTR), lacked an NADPH-binding site and was dependent on reduced coenzyme F420 (F420H2), a stronger reductant with a mid-point redox potential (E0) of ؊360 mV; E0 of NAD(P)H is ؊320 mV
Under high partial pressures of hydrogen prevailing on early Earth and present day deep-sea volcanoes, the potential for the F420/F420H2 pair could be as low as ؊425 mV, making dependent flavin-containing thioredoxin reductase (DFTR) efficient
Summary
Trx reduces Cys-disulfide of target proteins influencing their physical and/or catalytic properties and thereby institutes redox-based regulation of cellular metabolism as well as repairs oxidatively damaged proteins [1,2,3,4,5]. We show that the electron delivery enzyme of the above-mentioned redox regulation system of M. jannaschii is tuned for operation under highly reduced conditions This archaeon carries two Trxs, Mj-Trx which is a typical Trx, and Mj-Trx with unknown activity, and a TrxR (Mj-TrxR) that is. The properties and distribution of DFTR and the conditions prevailing in M. jannaschii’s habitat lead to the proposal that this enzyme developed in the low redox environment of early Earth and gave rise to NTR This implication fits the hypothesis that the Trx-based redox control developed on Earth long before oxygen appeared [20]
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