Experiment set6IT026 for Marinobacter adhaerens HP15

L-Phenylalanine

Group: carbon source
Media: DinoMM_noCarbon_HighNutrient + L-Phenylalanine (20 mM), pH=7
Culturing: Marino_ML2, tube, Aerobic, at 30 (C), shaken=200 rpm
Growth: about 4.9 generations
By: Adam on 3/4/2014
Media components: 20 g/L Sea salts, 0.3 g/L Ammonium Sulfate, 0.1 g/L Potassium phosphate monobasic, Wolfe's mineral mix (0.03 g/L Magnesium Sulfate Heptahydrate, 0.015 g/L Nitrilotriacetic acid, 0.01 g/L Sodium Chloride, 0.005 g/L Manganese (II) sulfate monohydrate, 0.001 g/L Cobalt chloride hexahydrate, 0.001 g/L Zinc sulfate heptahydrate, 0.001 g/L Calcium chloride dihydrate, 0.001 g/L Iron (II) sulfate heptahydrate, 0.00025 g/L Nickel (II) chloride hexahydrate, 0.0002 g/L Aluminum potassium sulfate dodecahydrate, 0.0001 g/L Copper (II) sulfate pentahydrate, 0.0001 g/L Boric Acid, 0.0001 g/L Sodium Molybdate Dihydrate, 0.003 mg/L Sodium selenite pentahydrate), Wolfe's vitamin mix (0.1 mg/L Pyridoxine HCl, 0.05 mg/L 4-Aminobenzoic acid, 0.05 mg/L Lipoic acid, 0.05 mg/L Nicotinic Acid, 0.05 mg/L Riboflavin, 0.05 mg/L Thiamine HCl, 0.05 mg/L calcium pantothenate, 0.02 mg/L biotin, 0.02 mg/L Folic Acid, 0.001 mg/L Cyanocobalamin)

Specific Phenotypes

For 8 genes in this experiment

For carbon source L-Phenylalanine in Marinobacter adhaerens HP15

For carbon source L-Phenylalanine across organisms

SEED Subsystems

Subsystem	#Specific
ABC transporter branched-chain amino acid (TC 3.A.1.4.1)	1
Acetyl-CoA fermentation to Butyrate	1
Aromatic amino acid interconversions with aryl acids	1
Butanol Biosynthesis	1
Glutamine, Glutamate, Aspartate and Asparagine Biosynthesis	1
Isoleucine degradation	1
Polyhydroxybutyrate metabolism	1
Threonine and Homoserine Biosynthesis	1
Valine degradation	1
n-Phenylalkanoic acid degradation	1

Metabolic Maps

Color code by fitness: see overview map or list of maps.

Maps containing gene(s) with specific phenotypes:

• Benzoate degradation via CoA ligation
• Butanoate metabolism
• Alkaloid biosynthesis I
• Biosynthesis of unsaturated fatty acids
• Fatty acid metabolism
• Valine, leucine and isoleucine degradation
• Lysine degradation
• Tyrosine metabolism
• Phenylalanine metabolism
• Alkaloid biosynthesis II
• Biosynthesis of plant hormones
• Fatty acid elongation in mitochondria
• Geraniol degradation
• Benzoate degradation via hydroxylation
• Tryptophan metabolism
• Phenylalanine, tyrosine and tryptophan biosynthesis
• Novobiocin biosynthesis
• alpha-Linolenic acid metabolism
• Propanoate metabolism
• Ethylbenzene degradation
• Limonene and pinene degradation
• Biosynthesis of phenylpropanoids
• Biosynthesis of alkaloids derived from shikimate pathway
• Fructose and mannose metabolism
• Ascorbate and aldarate metabolism
• Fatty acid biosynthesis
• Synthesis and degradation of ketone bodies
• C21-Steroid hormone metabolism
• Glutamate metabolism
• Alanine and aspartate metabolism
• Glycine, serine and threonine metabolism
• Methionine metabolism
• Cysteine metabolism
• Lysine biosynthesis
• Arginine and proline metabolism
• Histidine metabolism
• Bisphenol A degradation
• beta-Alanine metabolism
• Nucleotide sugars metabolism
• Polyketide sugar unit biosynthesis
• Aminosugars metabolism
• Lipopolysaccharide biosynthesis
• Glycerophospholipid metabolism
• Ether lipid metabolism
• Linoleic acid metabolism
• Glycosphingolipid biosynthesis - ganglio series
• Pyruvate metabolism
• 1- and 2-Methylnaphthalene degradation
• Tetrachloroethene degradation
• Carbon fixation in photosynthetic organisms
• Retinol metabolism
• Terpenoid biosynthesis
• Diterpenoid biosynthesis
• Carotenoid biosynthesis - General
• Caprolactam degradation
• Anthocyanin biosynthesis
• Insect hormone biosynthesis
• Biosynthesis of type II polyketide backbone
• Biosynthesis of type II polyketide products
• Biosynthesis of terpenoids and steroids
• Biosynthesis of alkaloids derived from ornithine, lysine and nicotinic acid

MetaCyc Pathways

Pathways that contain genes with specific phenotypes:

Pathway	#Steps	#Present	#Specific
L-aspartate degradation I	1	1	1
L-aspartate biosynthesis	1	1	1
3-(4-hydroxyphenyl)pyruvate biosynthesis	1	1	1
benzoyl-CoA biosynthesis	3	3	2
L-phenylalanine biosynthesis III (cytosolic, plants)	2	2	1
atromentin biosynthesis	2	1	1
3-oxoadipate degradation	2	1	1
L-tyrosine degradation II	2	1	1
malate/L-aspartate shuttle pathway	2	1	1
acetoacetate degradation (to acetyl CoA)	2	1	1
L-tryptophan degradation IV (via indole-3-lactate)	2	1	1
L-glutamate degradation II	2	1	1
phenylacetate degradation I (aerobic)	9	9	4
2-methyl-branched fatty acid β-oxidation	14	10	6
adipate degradation	5	5	2
oleate β-oxidation	35	30	14
adipate biosynthesis	5	4	2
5,6-dehydrokavain biosynthesis (engineered)	10	6	4
fatty acid β-oxidation II (plant peroxisome)	5	3	2
glutaryl-CoA degradation	5	3	2
superpathway of phenylethylamine degradation	11	10	4
pyruvate fermentation to hexanol (engineered)	11	8	4
fatty acid salvage	6	6	2
L-phenylalanine biosynthesis I	3	3	1
L-tyrosine biosynthesis I	3	3	1
L-isoleucine degradation I	6	5	2
valproate β-oxidation	9	6	3
pyruvate fermentation to butanol II (engineered)	6	4	2
polyhydroxybutanoate biosynthesis	3	2	1
L-phenylalanine degradation II (anaerobic)	3	2	1
ketolysis	3	2	1
L-asparagine degradation III (mammalian)	3	2	1
propanoate fermentation to 2-methylbutanoate	6	3	2
(R)-cysteate degradation	3	1	1
indole-3-acetate biosynthesis VI (bacteria)	3	1	1
L-tyrosine degradation IV (to 4-methylphenol)	3	1	1
sulfolactate degradation III	3	1	1
fatty acid β-oxidation I (generic)	7	5	2
pyruvate fermentation to butanoate	7	4	2
fatty acid β-oxidation VI (mammalian peroxisome)	7	4	2
benzoyl-CoA degradation I (aerobic)	7	3	2
(8E,10E)-dodeca-8,10-dienol biosynthesis	11	6	3
(2S)-ethylmalonyl-CoA biosynthesis	4	3	1
pyruvate fermentation to butanol I	8	4	2
L-phenylalanine degradation III	4	2	1
L-tyrosine degradation III	4	2	1
superpathway of L-aspartate and L-asparagine biosynthesis	4	2	1
L-tryptophan degradation VIII (to tryptophol)	4	1	1
superpathway of Clostridium acetobutylicum acidogenic fermentation	9	6	2
benzoate biosynthesis I (CoA-dependent, β-oxidative)	9	3	2
(R)- and (S)-3-hydroxybutanoate biosynthesis (engineered)	5	5	1
fatty acid β-oxidation IV (unsaturated, even number)	5	4	1
trans-4-hydroxy-L-proline degradation I	5	3	1
ketogenesis	5	3	1
L-glutamate degradation V (via hydroxyglutarate)	10	5	2
9-cis, 11-trans-octadecadienoyl-CoA degradation (isomerase-dependent, yeast)	10	4	2
fatty acid β-oxidation VII (yeast peroxisome)	5	2	1
isopropanol biosynthesis (engineered)	5	2	1
pyruvate fermentation to acetone	5	2	1
L-tyrosine degradation I	5	2	1
4-hydroxybenzoate biosynthesis III (plants)	5	2	1
3-phenylpropanoate degradation	10	3	2
ethylbenzene degradation (anaerobic)	5	1	1
L-tyrosine degradation V (reductive Stickland reaction)	5	1	1
superpathway of plastoquinol biosynthesis	5	1	1
4-hydroxybenzoate biosynthesis I (eukaryotes)	5	1	1
L-phenylalanine degradation VI (reductive Stickland reaction)	5	1	1
L-tryptophan degradation XIII (reductive Stickland reaction)	5	1	1
benzoate biosynthesis III (CoA-dependent, non-β-oxidative)	5	1	1
C4 photosynthetic carbon assimilation cycle, NAD-ME type	11	6	2
superpathway of L-threonine biosynthesis	6	6	1
TCA cycle VIII (Chlamydia)	6	4	1
methyl ketone biosynthesis (engineered)	6	3	1
L-glutamate degradation VII (to butanoate)	12	4	2
catechol degradation III (ortho-cleavage pathway)	6	2	1
superpathway of sulfolactate degradation	6	2	1
4-ethylphenol degradation (anaerobic)	6	2	1
10-trans-heptadecenoyl-CoA degradation (MFE-dependent, yeast)	6	1	1
coenzyme M biosynthesis II	6	1	1
jasmonic acid biosynthesis	19	4	3
superpathway of Clostridium acetobutylicum solventogenic fermentation	13	6	2
(4Z,7Z,10Z,13Z,16Z)-docosapentaenoate biosynthesis (6-desaturase)	13	2	2
superpathway of glyoxylate cycle and fatty acid degradation	14	11	2
acetyl-CoA fermentation to butanoate	7	5	1
C4 photosynthetic carbon assimilation cycle, PEPCK type	14	9	2
anaerobic energy metabolism (invertebrates, cytosol)	7	4	1
4-methylcatechol degradation (ortho cleavage)	7	2	1
superpathway of salicylate degradation	7	2	1
docosahexaenoate biosynthesis III (6-desaturase, mammals)	14	2	2
mevalonate pathway I (eukaryotes and bacteria)	7	1	1
mevalonate pathway II (haloarchaea)	7	1	1
L-tryptophan degradation III (eukaryotic)	15	5	2
L-valine degradation I	8	7	1
glycerol degradation to butanol	16	10	2
2-deoxy-D-ribose degradation II	8	3	1
crotonate fermentation (to acetate and cyclohexane carboxylate)	16	5	2
2-methylpropene degradation	8	2	1
mevalonate pathway III (Thermoplasma)	8	1	1
isoprene biosynthesis II (engineered)	8	1	1
mevalonate pathway IV (archaea)	8	1	1
androstenedione degradation I (aerobic)	25	6	3
superpathway of Clostridium acetobutylicum acidogenic and solventogenic fermentation	17	8	2
benzoate fermentation (to acetate and cyclohexane carboxylate)	17	5	2
superpathway of aromatic amino acid biosynthesis	18	18	2
superpathway of L-methionine biosynthesis (transsulfuration)	9	7	1
3-hydroxypropanoate/4-hydroxybutanate cycle	18	8	2
4-oxopentanoate degradation	9	4	1
L-phenylalanine degradation IV (mammalian, via side chain)	9	3	1
toluene degradation VI (anaerobic)	18	4	2
aromatic compounds degradation via β-ketoadipate	9	2	1
superpathway of testosterone and androsterone degradation	28	6	3
superpathway of L-tyrosine biosynthesis	10	10	1
superpathway of L-phenylalanine biosynthesis	10	10	1
L-lysine fermentation to acetate and butanoate	10	4	1
superpathway of geranylgeranyldiphosphate biosynthesis I (via mevalonate)	10	4	1
methyl tert-butyl ether degradation	10	2	1
rosmarinic acid biosynthesis I	10	1	1
superpathway of cholesterol degradation I (cholesterol oxidase)	42	8	4
gallate degradation III (anaerobic)	11	3	1
ethylmalonyl-CoA pathway	11	3	1
Spodoptera littoralis pheromone biosynthesis	22	4	2
toluene degradation III (aerobic) (via p-cresol)	11	2	1
(S)-reticuline biosynthesis I	11	1	1
tropane alkaloids biosynthesis	11	1	1
superpathway of cholesterol degradation II (cholesterol dehydrogenase)	47	9	4
superpathway of L-methionine biosynthesis (by sulfhydrylation)	12	12	1
indole-3-acetate biosynthesis II	12	4	1
10-cis-heptadecenoyl-CoA degradation (yeast)	12	2	1
10-trans-heptadecenoyl-CoA degradation (reductase-dependent, yeast)	12	2	1
superpathway of L-isoleucine biosynthesis I	13	13	1
platensimycin biosynthesis	26	7	2
1-butanol autotrophic biosynthesis (engineered)	27	19	2
androstenedione degradation II (anaerobic)	27	4	2
superpathway of rosmarinic acid biosynthesis	14	1	1
superpathway of hyoscyamine (atropine) and scopolamine biosynthesis	16	3	1
superpathway of anaerobic energy metabolism (invertebrates)	17	8	1
cholesterol degradation to androstenedione I (cholesterol oxidase)	17	2	1
superpathway of L-lysine, L-threonine and L-methionine biosynthesis I	18	16	1
mandelate degradation to acetyl-CoA	18	9	1
sitosterol degradation to androstenedione	18	1	1
cholesterol degradation to androstenedione II (cholesterol dehydrogenase)	22	3	1
superpathway of cholesterol degradation III (oxidase)	49	5	2
aspartate superpathway	25	23	1
photosynthetic 3-hydroxybutanoate biosynthesis (engineered)	26	20	1
superpathway of ergosterol biosynthesis I	26	3	1
anaerobic aromatic compound degradation (Thauera aromatica)	27	4	1
Methanobacterium thermoautotrophicum biosynthetic metabolism	56	20	2
superpathway of chorismate metabolism	59	41	2
superpathway of aerobic toluene degradation	30	13	1
superpathway of aromatic compound degradation via 3-oxoadipate	35	10	1
superpathway of cholesterol biosynthesis	38	3	1
superpathway of L-lysine degradation	43	12	1