Cell extracts of the proteolytic and hyperthermophilic archaea Thermococcus litoralis, Thermococcus sp. strain ES-1, Pyrococcus furiosus, and Pyrococcus sp. strain ES-4 contain an enzyme which catalyzes the coenzyme A-dependent oxidation of branched-chain 2-ketoacids coupled to the reduction of viologen dyes or ferredoxin. This enzyme, termed VOR (for keto-valine-ferredoxin oxidoreductase), has been purified from all four organisms. All four VORs comprise four different subunits and show amino-terminal sequence homology. T. litoralis VOR has an M r of ca. 230,000, with subunit M r values of 47,000 (␣), 34,000 (), 23,000 (␥), and 13,000 (␦). It contains about 11 iron and 12 acid-labile sulfide atoms and 13 cysteine residues per heterotetramer (␣␥␦), but thiamine pyrophosphate, which is required for catalytic activity, was lost during purification. The most efficient substrates (k cat /K m > 1.0 M ؊1 s
؊1; K m < 100 M) for the enzyme were the 2-ketoacid derivatives of valine, leucine, isoleucine, and methionine, while pyruvate and aryl pyruvates were very poor substrates (k cat /K m < 0.2 M ؊1 s
؊1) and 2-ketoglutarate was not utilized. T. litoralis VOR also functioned as a 2-ketoisovalerate synthase at 85؇C, producing 2-ketoisovalerate and coenzyme A from isobutyryl-coenzyme A (apparent K m , 250 M) and CO 2 (apparent K m , 48 mM) with reduced viologen as the electron donor. The rate of 2-ketoisovalerate synthesis was about 5% of the rate of 2-ketoisovalerate oxidation. The optimum pH for both reactions was 7.0. A mechanism for 2-ketoisovalerate oxidation based on data from substrate-induced electron paramagnetic resonance spectra is proposed, and the physiological role of VOR is discussed.In the last decade, a remarkable group of microorganisms capable of growing at temperatures around 100ЊC have been isolated from geothermally heated habitats (59,60). Virtually all of these so-called hyperthermophiles are classified as archaea (formerly archaebacteria [68]). Most of them are obligately anaerobic organisms and obtain energy for growth by either fermentation, sulfate reduction, or methanogenesis (1, 2, 28). The fermentative hyperthermophiles typically require elemental sulfur (S 0 ), which is reduced to H 2 S, for growth, although some, such as species of Pyrococcus and Thermococcus, grow well in the absence of S 0 (22,38,48). A characteristic of these organisms is their ability to ferment peptides, and some can also utilize carbohydrates (28,59,60). The pathways of carbohydrate fermentation have recently been shown to resemble the well-known bacterial pathways but with some unique additions and possibly a combination of different pathways (29,46,56).Only limited information is available on the degradation of amino acids by hyperthermophilic archaea (2, 28). Several of these organisms have been shown to contain high protease (9, 21, 33), glutamate dehydrogenase (16,19,40,54) and aromatic amino acid transaminase (3, 4) activities, and these enzymes have been purified from one or more species. In addition, three ...
