Identification of QTLs controlling aroma volatiles using a ‘Fortune’ x ‘Murcott’ (Citrus reticulata) population

Yu, Yuan; Bai, Jinhe; Chen, Chunxian; Plotto, Anne; Yu, Qibin; Baldwin, Elizabeth A.; Gmitter, Frederick G.

doi:10.1186/s12864-017-4043-5

BMC Genomics

Table 1 Relative content of the 148 detected juice volatiles in ‘Fortune’ (For), ‘Murcott’ (Mur) and the F₁ progeny in H1–13

From: Identification of QTLs controlling aroma volatiles using a ‘Fortune’ x ‘Murcott’ (Citrus reticulata) population

Compound	Cluster^a	For	Mur	F₁	Compound	Cluster^a	For	Mur	F₁	Compound	Cluster^a	For	Mur	F₁
Acid					Ketones					Furan
Nonanoic acid	B	nd	nd	nd-0.02	Acetone	A	tr^c	0.02^c	nd-0.05^f	2-Pentylfuran	D	nd ^c	0.04^c	nd-0.02^e
Alcohols					2-Butanone	D	nd	nd	nd-tr^e	Aromatic hydrocarbons
Ethanol^b	A	0.01^c	0.05^c	nd-0.12	1-Penten-3-one	D	nd ^c	0.01^c	nd-0.03d	Aromatic hydrocarbons
2-Methyl-2-propanol					2,4-Pentanedione	D	nd	nd	nd-tr^e
2-Methyl-2-propanol	A	0.01	0.01	nd-0.25	4-Methyl-3-penten-2-one					α-Colocalene	D	nd	nd	nd-0.03
1-Octanol	D	tr^c	nd^c	nd-0.08	4-Methyl-3-penten-2-one	D	nd	nd	nd-0.02	Styrene	D	nd	nd	nd-tr
Linalool^b	B	0.01^c	0.06^c	tr-0.97	4-Methyl-3-hexanone					1,3-Pentadiene	B	nd	nd	nd-0.03
(Z)-β-Terpineol	B	tr	nd	nd-0.18^d	4-Methyl-3-hexanone	A	0.01^c	nd^c	nd-0.19
Terpinen-4-ol	B	tr	0.01	nd-0.49	3-Heptanone	D	tr	nd	nd-tr^d	Phenol
α-Terpineol	B	tr^c	0.03^c	nd-0.81	1-Octen-3-one^b	A	nd ^c	0.02^c	nd-0.07^d	2,4-Di-tert-butylphenol
(E)-Carveol^b	B	nd	nd	nd-0.02	2,3-Octanedione	D	nd	nd	nd-0.04^e	2,4-Di-tert-butylphenol	A	tr	nd	nd-0.04
(E)-Nerolidol	C	nd	nd	nd-0.12	6-Methyl-5-hepten-2-one					Sesquiterpenes
Cubenol	C	nd	nd	nd-0.03^e	6-Methyl-5-hepten-2-one	A	nd ^c	0.07^c	nd-0.03^d	α-Cubebene	C	nd	nd	nd-0.18^e
Neointermedeol	D	nd	nd	nd-0.01	Dihydrocarvone	B	nd ^c	0.05^c	nd-0.03^d	α-Copaene	C	tr^c	tr^c	nd-2.13^f
Intermedeol	D	nd	nd	nd-0.01	(E)-Dihydro carvone					β-Elemene	C	nd	nd	nd-0.22^d
Aldehydes					(E)-Dihydro carvone	B	nd ^c	0.02^c	nd-0.03^d	Caryophyllene	B	nd	nd	nd-0.13
Acetylaldehyde	A	tr^c	tr^c	nd-0.01	(D)-Carvone	B	tr^c	0.11^c	nd-0.15^f	α-Guaiene	C	nd	nd	nd-0.09
Methacrolein	D	tr	nd	nd-tr^d	Geranyl acetone	A	nd^c	0.19^c	nd-0.07^f	β-Cubebene	C	nd	nd	nd-0.03
Pentanal	D	nd^c	0.09^c	nd-0.03^d	β-Ionone^b	D	nd	0.01	nd-0.01^d	Aromadendrene	C	nd	nd	nd-0.12
Hexanal^b	D	0.01^c	1.02^c	nd-0.35	Nootkatone^b	D	nd	nd	nd-tr	Spirolepechinene	D	tr^c	nd^c	nd-0.01^e
(E)-2-Hexenal	D	tr^c	0.04^c	nd-0.14	Unknown					RI1465	C	nd	nd	nd-0.15
Heptanal^b	A	tr^c	0.19^c	nd-0.32	RI0547	C	tr	nd	nd-0.04^f	RI1472	C	nd	nd	nd-0.09
(E)-2-Heptenal^b	A	tr	nd	nd-0.19^f	RI0754	A	tr	nd	nd-0.01^e	α-Humulene	C	nd	nd	nd-0.24^d
Octanal^b	A	tr^c	0.09^c	nd-0.17	RI0941	A	0.01^c	tr^c	nd-0.11	(E)-Cadina-1(6),4-diene
(E)-2-Octenal	A	tr^c	0.05^c	nd-0.22^f	RI1005	A	tr^c	nd^c	nd-0.08^d	(E)-Cadina-1(6),4-diene	C	nd	nd	nd-0.36
Nonanal	A	tr^c	0.04^c	nd-0.19	RI1028	D	tr^c	0.04^c	nd-1.25	γ-Muurolene	B	nd	nd	nd-0.2^e
(E)-2-Nonenal^b	A	tr^c	0.03^c	nd-0.1^d	RI1076	B	nd	nd	nd-tr	α-Farnesene	B	nd	nd	nd-0.08
Decanal^b	B	tr^c	0.02^c	nd-1.18	RI1087	A	tr^c	nd^c	nd-0.03^e	Germacrene D	B	nd	nd	nd-0.04
p-Menth-1-en-9-al	B	nd	nd	nd-0.02^d	RI1098	B	tr	nd	nd-0.13^d	RI1495	D	tr^c	nd^c	nd-0.03^e
β-Cyclocitral	B	nd ^c	0.03^c	nd-0.03^f	RI1111	A	tr^c	nd^c	nd-0.04	Epizonarene	C	nd	nd	nd-0.22^e
(E)-2-Decenal^b	A	nd	nd	nd-0.05^e	RI1128	A	tr^c	nd^c	nd-0.09	α-Muurolene	C	nd	nd	nd-0.49
Perillaldehyde	B	nd ^c	0.01^c	nd-2.61^f	RI1155	B	nd	nd	nd-tr^f	Valencene	D	0.03^c	nd^c	nd-0.43^d
Undecanal	B	nd	nd	nd-0.22^e	(+/−)-4-Acetyl-1-methylcyclohexene					α-Selinene	C	tr^c	nd^c	nd-0.26^d
(E)-2-Undecenal	A	nd	nd	nd-0.04	(+/−)-4-Acetyl-1-methylcyclohexene	D	nd^c	0.01^c	nd-tr^e	Premnaspirodiene	D	nd	nd	nd-0.02^e
Dodecanal^b	B	nd	nd	nd-0.61^d	RI1169	B	nd	tr	nd-0.07^f	δ-Cadinene	C	tr^c	nd^c	nd-2.91^f
β-Sinensal	C	nd	nd	nd-0.01	RI1195	B	nd	nd	nd-0.05	Calamenene	C	tr	nd	nd-0.37^d
Esters					RI1211	D	nd	nd	nd-0.03^e	7-epi-α-Selinene	D	tr^c	nd^c	nd-0.03^e
Ethyl acetate	D	0.03	0.03	tr-1.55	RI1219	D	nd	nd	nd-0.02^e	(E)-Cadina-1,4-diene
Ethyl propanoate	D	nd	nd	nd-0.04^d	RI1269	A	tr^c	nd^c	nd-0.05^d	(E)-Cadina-1,4-diene	C	nd	nd	nd-0.34^e
Ethyl 2-methylbutanoate^b					RI1300	D	nd	nd	nd-0.01	α-Cadinene	C	nd	nd	nd-0.07
Ethyl 2-methylbutanoate^b	C	nd	nd	nd-0.01^e	RI1346	D	nd	nd	nd-0.07	α-Calacorene	C	nd	nd	nd-0.06
(Z)-3-Hexenyl acetate					RI1348	B	nd	nd	nd-0.23	Monoterpenes
(Z)-3-Hexenyl acetate	D	nd	nd	nd-0.03^e	RI1385	D	nd	nd	nd-0.04	α-Thujene	C	nd	nd	nd-0.03
Hexyl acetate	D	tr^c	nd^c	nd-tr^e	RI1394	C	nd	nd	nd-0.14^e	α-Pinene	B	0.01^c	0.09^c	tr-2.23
Octyl acetate	B	nd	nd	nd-3.61^d	RI1398	B	nd	nd	nd-0.07	Myrcene^b	B	0.02^c	0.3^c	tr-11.75
Nonyl acetate	B	nd	nd	nd-0.42^e	RI1414	B	nd	nd	nd-1.05^e	α-Phellandrene	B	tr	0.01	nd-0.7
(E)-Carvyl acetate	B	nd	nd	nd-0.19^e	RI1420	B	nd	nd	nd-0.64^e	α-Terpinene	B	tr^c	0.02^c	nd-1.71
Citronellyl acetate	B	nd	nd	nd-0.83^d	RI1428	C	nd	nd	nd-0.02	p-Cymene^b	D	0.01^c	0.1^c	nd-0.16
Neryl acetate	B	nd	nd	nd-0.26^e	RI1483	D	nd	nd	nd-0.01	Limonene	B	0.97^c	12.24^c	0.12–98.92
Geranyl acetate	B	nd	nd	nd-0.1^e	RI1540	C	nd	nd	nd-0.02^e	β-Phellandrene^b	B	tr^c	0.04^c	nd-0.77
Decyl acetate	B	nd ^c	tr^c	nd-1.29^e	RI1549	C	nd	nd	nd-0.11	(E)-β-Ocimene	D	tr^c	nd^c	nd-0.06^d
p-Menth-1-en-9-ol acetate					RI1554	D	nd	nd	nd-tr	γ-Terpinene^b	B	tr	0.04	nd-0.97
p-Menth-1-en-9-ol acetate	B	nd	nd	nd-1.2^d	RI1557	B	nd	nd	nd-0.03^e	Terpinolene^b	B	0.01^c	0.07^c	nd-4.44
RI1561	C	nd	nd	nd-0.02	RI1595	D	nd	nd	nd-0.05	p-Mentha-2,4(8)-diene
					RI1599	C	nd	nd	nd-0.04	p-Mentha-2,4(8)-diene	A	0.01^c	0.01^c	nd-0.15
					RI1603	D	nd	nd	nd-0.08^e	p-Mentha-1,3,8-triene
					RI1606	D	nd	nd	nd-0.04^e	p-Mentha-1,3,8-triene	B	nd^c	tr^c	nd-0.06^d
					RI1609	B	nd	nd	nd-0.01	Allo-ocimene	B	nd	tr	nd-0.01
					RI1649	A	tr^c	tr^c	nd-0.05	Allo-ocimene isomer
					RI1654	B	nd	nd	nd-0.01^e	Allo-ocimene isomer	B	nd	nd	nd-0.02^d

Data are normalized to the internal standard peak area. All values are mean of three biological replicates per genotype
tr. Peak was recognized but the value less than 0.0095
nd. Not detected
^a Clusters according to Fig. 3
^b Aroma active compounds reported by Miyazaki et al. [14]
^c Volatiles significantly different between parental lines ‘Fortune’ (FOR) and ‘Murcott’ (MUR) from the same harvest season (p < 0.05, Student’s t test)
^d Volatiles presented in 50% of the F₁ hybrids (expected ratio 1:1, α =0.05, χ² test)
^e Volatiles presented in 25% of the F₁ hybrids (expected ratio 1:3, α =0.05, χ² test)
^f Volatiles presented in 75% of the F₁ hybrids (expected ratio 3:1, α =0.05, χ² test)

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