Experiment set12IT016 for Pseudomonas putida KT2440

4-Hydroxybenzoic Acid carbon source

Group: carbon source
Media: MOPS minimal media_noCarbon + 4-Hydroxybenzoic Acid (10 mM) + Dimethyl Sulfoxide (1 vol%)
Culturing: Putida_ML5_JBEI, 96 deep-well microplate; 1.2 mL volume, Aerobic, at 30 (C), shaken=700rpm
By: Matthew Incha on 12-Feb-19
Media components: 40 mM 3-(N-morpholino)propanesulfonic acid, 4 mM Tricine, 1.32 mM Potassium phosphate dibasic, 0.01 mM Iron (II) sulfate heptahydrate, 9.5 mM Ammonium chloride, 0.276 mM Aluminum potassium sulfate dodecahydrate, 0.0005 mM Calcium chloride, 0.525 mM Magnesium chloride hexahydrate, 50 mM Sodium Chloride, 3e-09 M Ammonium heptamolybdate tetrahydrate, 4e-07 M Boric Acid, 3e-08 M Cobalt chloride hexahydrate, 1e-08 M Copper (II) sulfate pentahydrate, 8e-08 M Manganese (II) chloride tetrahydrate, 1e-08 M Zinc sulfate heptahydrate

Specific Phenotypes

For 9 genes in this experiment

For carbon source 4-Hydroxybenzoic Acid in Pseudomonas putida KT2440

For carbon source 4-Hydroxybenzoic Acid across organisms

SEED Subsystems

Subsystem	#Specific
Protocatechuate branch of beta-ketoadipate pathway	7
Chloroaromatic degradation pathway	3
Catechol branch of beta-ketoadipate pathway	2
p-Hydroxybenzoate 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 hydroxylation
• Geraniol degradation
• 2,4-Dichlorobenzoate degradation
• 1- and 2-Methylnaphthalene degradation
• Ethylbenzene degradation
• Biosynthesis of unsaturated fatty acids
• Fatty acid biosynthesis
• Fatty acid elongation in mitochondria
• Fatty acid metabolism
• Valine, leucine and isoleucine degradation
• Lysine degradation
• Histidine metabolism
• Tyrosine metabolism
• Phenylalanine metabolism
• Lipopolysaccharide biosynthesis
• Glycerophospholipid metabolism
• Ether lipid metabolism
• alpha-Linolenic acid metabolism
• Glycosphingolipid biosynthesis - ganglio series
• Benzoate degradation via CoA ligation
• Butanoate metabolism
• Limonene and pinene degradation
• Diterpenoid biosynthesis
• Carotenoid biosynthesis - General
• Anthocyanin biosynthesis
• Alkaloid biosynthesis I
• Alkaloid biosynthesis II
• Biosynthesis of type II polyketide backbone
• Biosynthesis of terpenoids and steroids
• Biosynthesis of plant hormones

MetaCyc Pathways

Pathways that contain genes with specific phenotypes:

Pathway	#Steps	#Present	#Specific
3-oxoadipate degradation	2	2	2
protocatechuate degradation II (ortho-cleavage pathway)	4	4	3
aromatic compounds degradation via β-ketoadipate	9	9	5
toluene degradation III (aerobic) (via p-cresol)	11	7	6
catechol degradation III (ortho-cleavage pathway)	6	6	3
acetoacetate degradation (to acetyl CoA)	2	1	1
superpathway of salicylate degradation	7	7	3
4-methylcatechol degradation (ortho cleavage)	7	5	3
5,6-dehydrokavain biosynthesis (engineered)	10	6	4
ketolysis	3	3	1
benzoyl-CoA biosynthesis	3	3	1
polyhydroxybutanoate biosynthesis	3	2	1
catechol degradation to β-ketoadipate	4	4	1
4-chlorobenzoate degradation	4	2	1
4-sulfocatechol degradation	4	2	1
(2S)-ethylmalonyl-CoA biosynthesis	4	2	1
4-methylphenol degradation to protocatechuate	4	1	1
oleate β-oxidation	35	30	8
valproate β-oxidation	9	7	2
2-methyl-branched fatty acid β-oxidation	14	10	3
adipate degradation	5	5	1
4-hydroxybenzoate biosynthesis III (plants)	5	5	1
adipate biosynthesis	5	4	1
(R)- and (S)-3-hydroxybutanoate biosynthesis (engineered)	5	4	1
4-coumarate degradation (aerobic)	5	4	1
gallate degradation II	5	4	1
ketogenesis	5	3	1
fatty acid β-oxidation II (plant peroxisome)	5	3	1
glutaryl-CoA degradation	5	3	1
superpathway of aerobic toluene degradation	30	13	6
9-cis, 11-trans-octadecadienoyl-CoA degradation (isomerase-dependent, yeast)	10	4	2
fatty acid β-oxidation VII (yeast peroxisome)	5	2	1
bisphenol A degradation	5	2	1
isopropanol biosynthesis (engineered)	5	1	1
pyruvate fermentation to acetone	5	1	1
ethylbenzene degradation (anaerobic)	5	1	1
pyruvate fermentation to hexanol (engineered)	11	8	2
superpathway of aromatic compound degradation via 3-oxoadipate	35	19	6
fatty acid salvage	6	6	1
L-isoleucine degradation I	6	5	1
propanoate fermentation to 2-methylbutanoate	6	4	1
pyruvate fermentation to butanol II (engineered)	6	4	1
mandelate degradation to acetyl-CoA	18	11	3
4-ethylphenol degradation (anaerobic)	6	2	1
4-hydroxymandelate degradation	6	2	1
10-trans-heptadecenoyl-CoA degradation (MFE-dependent, yeast)	6	1	1
jasmonic acid biosynthesis	19	4	3
fatty acid β-oxidation I (generic)	7	5	1
acetyl-CoA fermentation to butanoate	7	4	1
fatty acid β-oxidation VI (mammalian peroxisome)	7	4	1
benzoyl-CoA degradation I (aerobic)	7	3	1
pyruvate fermentation to butanoate	7	3	1
spongiadioxin C biosynthesis	7	2	1
mevalonate pathway II (haloarchaea)	7	1	1
mevalonate pathway I (eukaryotes and bacteria)	7	1	1
2-deoxy-D-ribose degradation II	8	4	1
pyruvate fermentation to butanol I	8	3	1
2-methylpropene degradation	8	2	1
polybrominated dihydroxylated diphenyl ethers biosynthesis	8	2	1
mevalonate pathway IV (archaea)	8	1	1
mevalonate pathway III (Thermoplasma)	8	1	1
isoprene biosynthesis II (engineered)	8	1	1
androstenedione degradation I (aerobic)	25	7	3
phenylacetate degradation I (aerobic)	9	9	1
4-oxopentanoate degradation	9	5	1
superpathway of Clostridium acetobutylicum acidogenic fermentation	9	5	1
benzoate biosynthesis I (CoA-dependent, β-oxidative)	9	3	1
superpathway of testosterone and androsterone degradation	28	7	3
L-glutamate degradation V (via hydroxyglutarate)	10	5	1
superpathway of geranylgeranyldiphosphate biosynthesis I (via mevalonate)	10	4	1
3-phenylpropanoate degradation	10	4	1
L-lysine fermentation to acetate and butanoate	10	3	1
methyl tert-butyl ether degradation	10	2	1
superpathway of cholesterol degradation I (cholesterol oxidase)	42	9	4
superpathway of phenylethylamine degradation	11	11	1
(8E,10E)-dodeca-8,10-dienol biosynthesis	11	6	1
ethylmalonyl-CoA pathway	11	2	1
superpathway of cholesterol degradation II (cholesterol dehydrogenase)	47	9	4
L-glutamate degradation VII (to butanoate)	12	3	1
10-cis-heptadecenoyl-CoA degradation (yeast)	12	2	1
10-trans-heptadecenoyl-CoA degradation (reductase-dependent, yeast)	12	2	1
superpathway of Clostridium acetobutylicum solventogenic fermentation	13	4	1
(4Z,7Z,10Z,13Z,16Z)-docosapentaenoate biosynthesis (6-desaturase)	13	2	1
androstenedione degradation II (anaerobic)	27	5	2
superpathway of glyoxylate cycle and fatty acid degradation	14	11	1
docosahexaenoate biosynthesis III (6-desaturase, mammals)	14	2	1
L-tryptophan degradation III (eukaryotic)	15	3	1
glycerol degradation to butanol	16	9	1
crotonate fermentation (to acetate and cyclohexane carboxylate)	16	4	1
superpathway of Clostridium acetobutylicum acidogenic and solventogenic fermentation	17	6	1
benzoate fermentation (to acetate and cyclohexane carboxylate)	17	4	1
cholesterol degradation to androstenedione I (cholesterol oxidase)	17	2	1
3-hydroxypropanoate/4-hydroxybutanate cycle	18	9	1
toluene degradation VI (anaerobic)	18	4	1
sitosterol degradation to androstenedione	18	1	1
cholesterol degradation to androstenedione II (cholesterol dehydrogenase)	22	2	1
superpathway of cholesterol degradation III (oxidase)	49	5	2
photosynthetic 3-hydroxybutanoate biosynthesis (engineered)	26	19	1
platensimycin biosynthesis	26	6	1
superpathway of ergosterol biosynthesis I	26	3	1
1-butanol autotrophic biosynthesis (engineered)	27	19	1
superpathway of cholesterol biosynthesis	38	3	1
superpathway of aromatic compound degradation via 2-hydroxypentadienoate	42	13	1
superpathway of L-lysine degradation	43	23	1
Methanobacterium thermoautotrophicum biosynthetic metabolism	56	21	1