Experiment set3IT076 for Acidovorax sp. GW101-3H11

LB with Cobalt chloride hexahydrate 0.32 mM

Group: stress
Media: LB + Cobalt chloride hexahydrate (0.32 mM)
Culturing: acidovorax_3H11_ML3a, 24 deep-well microplate; Multitron, Aerobic, at 30 (C), shaken=750 rpm
Growth: about 5.3 generations
By: Mark on 05/19/2015
Media components: 10 g/L Tryptone, 5 g/L Yeast Extract, 5 g/L Sodium Chloride

Specific Phenotypes

For 13 genes in this experiment

For stress Cobalt chloride hexahydrate in Acidovorax sp. GW101-3H11

For stress Cobalt chloride hexahydrate across organisms

SEED Subsystems

Subsystem	#Specific
Transport of Iron	2
Acetyl-CoA fermentation to Butyrate	1
Butanol Biosynthesis	1
Cobalt-zinc-cadmium resistance	1
Glycine and Serine Utilization	1
Heat shock dnaK gene cluster extended	1
Heme and Siroheme Biosynthesis	1
Iron acquisition in Vibrio	1
Isoleucine degradation	1
L-rhamnose utilization	1
Lactate utilization	1
Polyhydroxybutyrate metabolism	1
Pyridoxin (Vitamin B6) Biosynthesis	1
Queuosine-Archaeosine Biosynthesis	1
Respiratory dehydrogenases 1	1
Serine 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:

• Fatty acid metabolism
• Glycine, serine and threonine metabolism
• Benzoate degradation via CoA ligation
• Butanoate metabolism
• Fatty acid elongation in mitochondria
• Valine, leucine and isoleucine degradation
• Geraniol degradation
• Lysine degradation
• Tryptophan metabolism
• Caprolactam degradation
• Biosynthesis of unsaturated fatty acids
• Biosynthesis of plant hormones
• Fructose and mannose metabolism
• Ascorbate and aldarate metabolism
• Bile acid biosynthesis
• C21-Steroid hormone metabolism
• Bisphenol A degradation
• Benzoxazinone biosynthesis
• beta-Alanine metabolism
• Nucleotide sugars metabolism
• Polyketide sugar unit biosynthesis
• Aminosugars metabolism
• Linoleic acid metabolism
• alpha-Linolenic acid metabolism
• Pyruvate metabolism
• Tetrachloroethene degradation
• Glyoxylate and dicarboxylate metabolism
• Propanoate metabolism
• Retinol metabolism
• Porphyrin and chlorophyll metabolism
• Limonene and pinene degradation
• Diterpenoid biosynthesis
• Alkaloid biosynthesis I
• Insect hormone biosynthesis
• Biosynthesis of type II polyketide products
• Biosynthesis of alkaloids derived from shikimate pathway

MetaCyc Pathways

Pathways that contain genes with specific phenotypes:

Pathway	#Steps	#Present	#Specific
long-chain fatty acid activation	1	1	1
fatty acid β-oxidation III (unsaturated, odd number)	1	1	1
benzoyl-CoA biosynthesis	3	3	2
fatty acid salvage	6	5	3
linoleate biosynthesis II (animals)	2	1	1
γ-linolenate biosynthesis II (animals)	2	1	1
oleate β-oxidation (thioesterase-dependent, yeast)	2	1	1
oleate β-oxidation	35	29	17
fatty acid β-oxidation I (generic)	7	5	3
adipate degradation	5	5	2
adipate biosynthesis	5	4	2
fatty acid β-oxidation IV (unsaturated, even number)	5	3	2
glutaryl-CoA degradation	5	3	2
fatty acid β-oxidation II (plant peroxisome)	5	3	2
fatty acid β-oxidation V (unsaturated, odd number, di-isomerase-dependent)	5	2	2
pyruvate fermentation to hexanol (engineered)	11	7	4
(8E,10E)-dodeca-8,10-dienol biosynthesis	11	6	4
2-methyl-branched fatty acid β-oxidation	14	10	5
L-serine biosynthesis I	3	3	1
pyruvate fermentation to butanol II (engineered)	6	5	2
propanoate fermentation to 2-methylbutanoate	6	5	2
L-isoleucine degradation I	6	5	2
valproate β-oxidation	9	7	3
methylglyoxal degradation V	3	2	1
L-cysteine biosynthesis IX (Trichomonas vaginalis)	3	2	1
3-methyl-branched fatty acid α-oxidation	6	3	2
6-gingerol analog biosynthesis (engineered)	6	3	2
methyl ketone biosynthesis (engineered)	6	3	2
oleate biosynthesis I (plants)	3	1	1
alkane biosynthesis II	3	1	1
oleate β-oxidation (reductase-dependent, yeast)	3	1	1
L-glutamate degradation V (via hydroxyglutarate)	10	6	3
benzoyl-CoA degradation I (aerobic)	7	6	2
fatty acid β-oxidation VI (mammalian peroxisome)	7	3	2
pyruvate fermentation to butanoate	7	3	2
superpathway of L-serine and glycine biosynthesis I	4	4	1
L-valine degradation I	8	6	2
phytol degradation	4	3	1
pyruvate fermentation to butanol I	8	4	2
long chain fatty acid ester synthesis (engineered)	4	2	1
phosphatidylcholine acyl editing	4	2	1
oleate β-oxidation (isomerase-dependent, yeast)	4	1	1
wax esters biosynthesis II	4	1	1
phenylacetate degradation I (aerobic)	9	5	2
superpathway of Clostridium acetobutylicum acidogenic fermentation	9	4	2
benzoate biosynthesis I (CoA-dependent, β-oxidative)	9	4	2
sporopollenin precursors biosynthesis	18	4	4
4-hydroxybenzoate biosynthesis III (plants)	5	4	1
3-phenylpropanoate degradation	10	6	2
octane oxidation	5	3	1
(R)- and (S)-3-hydroxybutanoate biosynthesis (engineered)	5	3	1
sphingosine and sphingosine-1-phosphate metabolism	10	4	2
9-cis, 11-trans-octadecadienoyl-CoA degradation (isomerase-dependent, yeast)	10	4	2
benzoate biosynthesis III (CoA-dependent, non-β-oxidative)	5	1	1
superpathway of phenylethylamine degradation	11	6	2
stearate biosynthesis II (bacteria and plants)	6	5	1
stearate biosynthesis IV	6	4	1
methylthiopropanoate degradation I (cleavage)	6	2	1
L-glutamate degradation VII (to butanoate)	12	3	2
stearate biosynthesis I (animals)	6	1	1
superpathway of Clostridium acetobutylicum solventogenic fermentation	13	6	2
superpathway of glyoxylate cycle and fatty acid degradation	14	11	2
L-glutamate degradation XI (reductive Stickland reaction)	7	3	1
ceramide degradation by α-oxidation	7	2	1
icosapentaenoate biosynthesis III (8-desaturase, mammals)	7	1	1
icosapentaenoate biosynthesis II (6-desaturase, mammals)	7	1	1
capsaicin biosynthesis	7	1	1
arachidonate biosynthesis III (6-desaturase, mammals)	7	1	1
Spodoptera littoralis pheromone biosynthesis	22	4	3
L-tryptophan degradation III (eukaryotic)	15	7	2
glycerol degradation to butanol	16	10	2
crotonate fermentation (to acetate and cyclohexane carboxylate)	16	4	2
ceramide and sphingolipid recycling and degradation (yeast)	16	4	2
superpathway of dimethylsulfoniopropanoate degradation	8	2	1
lactate fermentation to acetate, CO2 and hydrogen (Desulfovibrionales)	8	2	1
2-methylpropene degradation	8	2	1
superpathway of Clostridium acetobutylicum acidogenic and solventogenic fermentation	17	7	2
benzoate fermentation (to acetate and cyclohexane carboxylate)	17	5	2
superpathway of sulfate assimilation and cysteine biosynthesis	9	9	1
3-hydroxypropanoate/4-hydroxybutanate cycle	18	10	2
photorespiration I	9	4	1
toluene degradation VI (anaerobic)	18	4	2
methyl tert-butyl ether degradation	10	2	1
suberin monomers biosynthesis	20	3	2
superpathway of fatty acid biosynthesis II (plant)	43	38	4
gallate degradation III (anaerobic)	11	4	1
10-cis-heptadecenoyl-CoA degradation (yeast)	12	2	1
10-trans-heptadecenoyl-CoA degradation (reductase-dependent, yeast)	12	2	1
androstenedione degradation I (aerobic)	25	6	2
platensimycin biosynthesis	26	7	2
(4Z,7Z,10Z,13Z,16Z)-docosapentaenoate biosynthesis (6-desaturase)	13	2	1
1-butanol autotrophic biosynthesis (engineered)	27	19	2
androstenedione degradation II (anaerobic)	27	4	2
superpathway of testosterone and androsterone degradation	28	6	2
superpathway of cholesterol degradation I (cholesterol oxidase)	42	8	3
docosahexaenoate biosynthesis III (6-desaturase, mammals)	14	2	1
palmitate biosynthesis II (type II fatty acid synthase)	31	29	2
superpathway of cholesterol degradation II (cholesterol dehydrogenase)	47	8	3
cutin biosynthesis	16	1	1
cholesterol degradation to androstenedione I (cholesterol oxidase)	17	2	1
cholesterol degradation to androstenedione II (cholesterol dehydrogenase)	22	2	1
superpathway of cholesterol degradation III (oxidase)	49	4	2
photosynthetic 3-hydroxybutanoate biosynthesis (engineered)	26	17	1
superpathway of fatty acids biosynthesis (E. coli)	53	49	2
palmitate biosynthesis III	29	28	1