Proteomic and metabolomic analyses provide insight into production of volatile and non-volatile flavor components in mandarin hybrid fruit

Yu, Qibin; Plotto, Anne; Baldwin, Elizabeth A; Bai, Jinhe; Huang, Ming; Yu, Yuan; Dhaliwal, Harvinder S; Gmitter, Frederick G

doi:10.1186/s12870-015-0466-9

Table 4 KEGG assigned differentially expressed proteins between Temple and Murcott mandarin hybrid fruit in metabolic pathways

From: Proteomic and metabolomic analyses provide insight into production of volatile and non-volatile flavor components in mandarin hybrid fruit

KEGG pathway	Pathway	Enzyme number
Carbohydrate metabolism	Amino sugar and nucleotide sugar metabolism	ec:2.7.7.9, ec:3.2.1.14, ec:5.1.3.2,ec:5.4.2.2
	Ascorbate and aldarate metabolism	ec:1.10.3.3, ec:1.11.1.11, ec:1.6.5.4
	Butanoate metabolism	ec:4.1.1.15
	Tricarboxylic acid cycle (TCA)	ec:1.1.1.37, ec:1.1.1.42, ec:2.3.1.12, ec:2.3.3.1, ec:4.1.1.49
	Fructose and mannose metabolism	ec:2.7.1.11, ec:2.7.1.90, ec:4.1.2.13,ec:5.3.1.1
	Galactose metabolism	ec:2.7.1.11, ec:2.7.7.9, ec:5.1.3.2, ec:5.4.2.2
	Glycerophospholipid metabolism	ec:3.1.4.4
	Glycolysis/Gluconeogenesis	ec:1.2.1.12, ec:2.3.1.12, ec:2.7.1.11, ec:2.7.2.3, ec:4.1.1.1, ec:4.1.1.49, ec:4.1.2.13, ec:5.1.3.3, ec:5.3.1.1, ec:5.4.2.2
	Glyoxylate and dicarboxylate metabolism	ec:1.1.1.37, ec:1.11.1.6, ec:2.3.3.1
	Pentose and glucuronate interconversions	ec:2.7.7.9, ec:3.1.1.11
	Pentose phosphate pathway	ec:1.1.1.49, ec:2.7.1.11, ec:4.1.2.13, ec:5.4.2.2
	Pyruvate metabolism	ec:1.1.1.37, ec:2.3.1.12, ec:4.1.1.49, ec:4.4.1.5
Amino acid metabolism	Alanine, aspartate and glutamate metabolism	ec:2.6.1.1, ec:2.6.1.2, ec:4.1.1.15
	Arginine and proline metabolism	ec:2.6.1.1, ec:3.5.3.1
	beta-Alanine metabolism	ec:4.1.1.15
	Cysteine and methionine metabolism	ec:2.6.1.1
	Glutathione metabolism	ec:1.1.1.42, ec:1.1.1.49, ec:1.11.1.11, ec:1.11.1.12, ec:1.11.1.15, ec:1.11.1.9, ec:2.5.1.18
	Phenylalanine metabolism	ec:1.11.1.7,ec:2.6.1.1
	Phenylalanine, tyrosine and tryptophan biosynthesis	ec:2.6.1.1
	Taurine and hypotaurine metabolism	ec:4.1.1.15
	Tryptophan metabolism	ec:1.11.1.6
	Tyrosine metabolism	ec:2.6.1.1
	Valine, leucine and isoleucine degradation	ec:2.3.1.168
Other secondary metabolites	Isoquinoline alkaloid biosynthesis	ec:2.6.1.1
	Novobiocin biosynthesis	ec:2.6.1.1
	Tropane, piperidine and pyridine alkaloid biosynthesis	ec:1.11.1.6
	Streptomycin biosynthesis	ec:5.4.2.2
Energy metabolism	Carbon fixation in photosynthetic organisms	ec:1.1.1.37, ec:2.6.1.1, ec:2.6.1.2, ec:2.7.2.3, ec:4.1.1.49, ec:4.1.2.13, ec:5.3.1.1
	Carbon fixation pathways in prokaryotes	ec:1.1.1.37, ec:1.1.1.42
	Inositol phosphate metabolism	ec:5.3.1.1
	Methane metabolism	ec:1.1.1.37, ec:1.11.1.6, ec:1.11.1.7, ec:2.7.1.11, ec:4.1.2.13
	Oxidative phosphorylation	ec:3.6.3.6
Lipid metabolism	alpha-Linolenic acid metabolism	ec:5.3.99.6
	Arachidonic acid metabolism	ec:1.11.1.9
	Ether lipid metabolism	ec:3.1.4.4
	Primary bile acid biosynthesis	ec:1.3.1.3
	Steroid degradation	ec:1.1.1.145
	Steroid hormone biosynthesis	ec:1.1.1.145, ec:1.3.1.3
Metabolism of terpenoids and polyketides	Terpenoid backbone biosynthesis	ec:5.3.3.2
Nucleotide metabolism	Arginine and proline metabolism	ec:3.5.3.11
	Cysteine and methionine metabolism	ec:4.4.1.14
	Purine metabolism	ec:3.6.1.3, ec:5.4.2.2
Xenobiotics biodegradation and metabolism	Chlorocyclohexane and chlorobenzene degradation	ec:3.1.1.45
	Drug metabolism - cytochrome P450	ec:2.5.1.18
	Fluorobenzoate degradation	ec:3.1.1.45
	Metabolism of xenobiotics by cytochrome P450	ec:2.5.1.18
	Toluene degradation	ec:3.1.1.45

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