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Prior-Knowledge Description Expectation Prediction Conclusion Leaf Statistics
Evidence_2474 TIGR01527 HMM None - {{∅}} None - {{∅}} Unexplained
Evidence_84773 TIGR03855 HMM None - {{∅}} None - {{∅}} Unexplained
Evidence_51 TIGR00551 HMM None - {{∅}} True - {{t}} Unconfirmed presence
Component_119 quinolinate synthetase complex, A subunit None - {{∅}} True - {{t}} Unconfirmed presence
Component_118 nicotinate-nucleotide pyrophosphorylase None - {{∅}} True - {{t}} Unconfirmed presence
Component_117 L-aspartate oxidase (or dehydrogenase) None - {{∅}} True - {{t}} Unconfirmed presence
Evidence_54 TIGR00482 HMM None - {{∅}} True - {{t}} Unconfirmed presence
Component_120 nicotinate nucleotide adenylyltransferase None - {{∅}} True - {{t}} Unconfirmed presence
Evidence_50 TIGR00552 HMM None - {{∅}} True - {{t}} Unconfirmed presence
Evidence_48 PF01513 HMM None - {{∅}} True - {{t}} Unconfirmed presence
Component_114 NAD kinase None - {{∅}} True - {{t}} Unconfirmed presence
GenProp0057 NAD(P) biosynthesis from L-aspartate and DHAP~Nicotinamide adenine dinucleotide (NAD+) and nicotinamide adenine dinucleotide phosphate (NADP+) also known as pyridine nucleotides, are cofactors involved in numerous redox reactions through reversible reactions to their reduced forms NADH and NADPH. In bacteria, NAD+ is synthesized in a 5 step reaction (NadABCDE) from L-aspartate and NADP+ is made from NAD+ by the action of NAD kinase. In mammals, an altenative pathway exists in which the intermediate quinolinate is made from L-tryptophan. NAD+ may also be recycled from nicotinamide after nucleosidease cleavage, or synthesized from imported nicotinate (niacin). None - {{∅}} True - {{t}} Unconfirmed presence
Evidence_53 TIGR00550 HMM None - {{∅}} True - {{t}} Unconfirmed presence
Component_116 NAD+ synthetase None - {{∅}} True - {{t}} Unconfirmed presence
Evidence_52 TIGR00078 HMM None - {{∅}} True - {{t}} Unconfirmed presence