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(1R,2S,4S)-neoisodihydrocarveol + NADP+
(1R,4S)-isodihydrocarvone + NADPH + H+
-
-
-
r
(2E)-3-methylpent-2-enal + NADPH + H+
2-methylpentanal + NADP+
-
-
-
?
(2R,4R)-carveol + NADP+
(R)-carvone + NADPH + H+
-
-
-
r
(2R,4S)-carveol + NADP+
(S)-carvone + NADPH + H+
-
-
-
r
(2S,4R)-carveol + NADP+
(R)-carvone + NADPH + H+
-
-
-
r
(2S,4S)-carveol + NADP+
(S)-carvone + NADPH + H+
-
-
-
r
(R)-pulegone + NADPH + H+
(1R,4R)-isomenthone + (1R,4S)-menthone + NADP+
-
-
-
?
(S)-pulegone + NADPH + H+
(1S,4S)-isomenthone + (1S,4R)-menthone + NADP+
-
-
-
?
1-cyclohexene-1-carboxaldehyde + NADPH + H+
cyclohexanecarbaldehyde + NADP+
low yields
-
-
?
1-nitrocyclohexene + NADPH + H+
nitrocyclohexane + NADP+
-
-
-
?
1-octen-3-one + NADPH + H+
octan-3-one + NADP+
-
-
-
?
4-coumaryl aldehyde + NADP+
dihydro-4-coumaryl aldehyde + NADPH + H+
-
-
-
?
5-hydroxyconiferyl aldehyde + NADP+
dihydro-5-hydroxyconiferyl aldehyde + NADPH + H+
acrolein + NADPH + H+
? + NADP+
-
-
-
?
caffeoyl aldehyde + NADP+
dihydrocaffeoyl aldehyde + NADPH + H+
-
-
-
?
citral + NADPH + H+
?
low yields
-
-
?
coniferyl aldehyde + NADP+
dihydroconiferyl aldehyde + NADPH + H+
trans-2-nonenal + NADPH + H+
nonanal + NADP+
trans-3-nonen-2-one + NADPH + H+
nonan-2-one + NADP+
-
-
-
-
?
trans-cinnamaldehyde + NADPH + H+
3-phenylpropanal + NADP+
-
-
-
?
[(1E)-1-nitroprop-1-en-2-yl]benzene + NADPH + H+
[(2R)-1-nitropropan-2-yl]benzene + NADP+
optically pure form of compound
-
-
?
[(1Z)-1-nitroprop-1-en-2-yl]benzene + NADPH + H+
[(2S)-1-nitropropan-2-yl]benzene + NADP+
poor enantioselectivity
-
-
?
additional information
?
-
5-hydroxyconiferyl aldehyde + NADP+
dihydro-5-hydroxyconiferyl aldehyde + NADPH + H+
-
-
-
?
5-hydroxyconiferyl aldehyde + NADP+
dihydro-5-hydroxyconiferyl aldehyde + NADPH + H+
only enzyme mutant PaDBR1C56Y, no activity with the wild-type enzyme
-
-
?
coniferyl aldehyde + NADP+
dihydroconiferyl aldehyde + NADPH + H+
-
-
-
?
coniferyl aldehyde + NADP+
dihydroconiferyl aldehyde + NADPH + H+
only enzyme mutant PaDBR1C56Y, no activity with the wild-type enzyme
-
-
?
trans-2-nonenal + NADPH + H+
nonanal + NADP+
-
-
-
?
trans-2-nonenal + NADPH + H+
nonanal + NADP+
-
-
-
-
?
additional information
?
-
enzyme AOR shows acrolein-reducing activity in addition to the cytosolic acrolein detoxification enzyme in leaves of higher plants
-
-
?
additional information
?
-
-
enzyme AOR shows acrolein-reducing activity in addition to the cytosolic acrolein detoxification enzyme in leaves of higher plants
-
-
?
additional information
?
-
-
2-alkenal reductase (AER) catalyzes the reduction of the alpha,beta-unsaturated bond of 2-alkenals to produce n-alkanals
-
-
?
additional information
?
-
recombinant NtRed-1 does not catalyze dehydrogenation of (2S,4S)-carveol, indicating that the recombinant NtRed-1 lacks the catalytic function as allyl-alcohol dehydrogenase, although the recombinant NtRed-1 is designed from the nucleotide sequence of allyl-ADH
-
-
?
additional information
?
-
results indicate that the enzyme catalyzes specifically the dehydrogenation of the secondary alcohols adjacent to the C-C double bond, no oxidation of saturated alcohols
-
-
?
additional information
?
-
the enzymatic reaction is a reversible oxidoreduction and the reaction is enantioselective
-
-
?
additional information
?
-
the recombinant isozyme PaDBR2 has a higher catalytic activity than isozyme PaDBR1 with respect to the reduction of the double bond present in hydroxycinnamyl aldehydes
-
-
?
additional information
?
-
the recombinant isozyme PaDBR2 has a higher catalytic activity than isozyme PaDBR1 with respect to the reduction of the double bond present in hydroxycinnamyl aldehydes
-
-
?
additional information
?
-
-
the recombinant isozyme PaDBR2 has a higher catalytic activity than isozyme PaDBR1 with respect to the reduction of the double bond present in hydroxycinnamyl aldehydes
-
-
?
additional information
?
-
docking of the ligand and substrate into the active cavity, overview. The catalytic efficiency of isozyme PaDBR1 is substantially less than that of PaDBR2, especially towards cinnamyl aldehydes carrying a methoxy group (coniferyl, 5-hydroxyconiferyl and sinapyl aldehydes). No activity with sinapyl aldehyde, cinnamyl aldehyde, 4-coumaric acid, caffeic acid, 4-coumaryl alcohol, caffeyl alcohol, coniferyl alcohol, 5-hydroxyconiferyl alcohol, and sinapyl alcohol
-
-
?
additional information
?
-
docking of the ligand and substrate into the active cavity, overview. The catalytic efficiency of isozyme PaDBR1 is substantially less than that of PaDBR2, especially towards cinnamyl aldehydes carrying a methoxy group (coniferyl, 5-hydroxyconiferyl and sinapyl aldehydes). No activity with sinapyl aldehyde, cinnamyl aldehyde, 4-coumaric acid, caffeic acid, 4-coumaryl alcohol, caffeyl alcohol, coniferyl alcohol, 5-hydroxyconiferyl alcohol, and sinapyl alcohol
-
-
?
additional information
?
-
-
docking of the ligand and substrate into the active cavity, overview. The catalytic efficiency of isozyme PaDBR1 is substantially less than that of PaDBR2, especially towards cinnamyl aldehydes carrying a methoxy group (coniferyl, 5-hydroxyconiferyl and sinapyl aldehydes). No activity with sinapyl aldehyde, cinnamyl aldehyde, 4-coumaric acid, caffeic acid, 4-coumaryl alcohol, caffeyl alcohol, coniferyl alcohol, 5-hydroxyconiferyl alcohol, and sinapyl alcohol
-
-
?
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590
(1R,2S,4S)-neoisodihydrocarveol
pH 8.0, 35°C, NADP+
0.837 - 1.032
(2E)-3-methylpent-2-enal
38
(2R,4R)-carveol
pH 8.0, 35°C, NADP+
52
(2R,4S)-carveol
pH 8.0, 35°C, NADP+
1.9
(2S,4R)-carveol
pH 8.0, 35°C, NADP+
2.5
(2S,4S)-carveol
pH 8.0, 35°C, NADP+
1.4
(R)-pulegone
recombinant NtRed-1, pH 7.0 and 35°C
8.3
(S)-pulegone
recombinant NtRed-1, pH 7.0 and 35°C
0.057 - 0.4
1-nitrocyclohexene
0.0943 - 0.1719
4-coumaryl aldehyde
0.2026 - 0.3081
5-hydroxyconiferyl aldehyde
0.1437 - 0.2214
caffeoyl aldehyde
0.1726 - 0.2099
coniferyl aldehyde
0.0776
trans-2-nonenal
-
with trans-3-nonen-2-one as cosubstrate, in 100 mM Tris (pH 7.2), at 25°C
0.0282
trans-3-nonen-2-one
-
with trans-3-nonen-2-one as cosubstrate, in 100 mM Tris (pH 7.2), at 25°C
0.516 - 1
trans-cinnamaldehyde
additional information
additional information
the Km-values for the (S)-alcohols are one order of magnitude lower than those for the (R)-alcohols, indicating that the enzyme has a higher affinity for the S-configuration than for the R-configuration
-
0.837
(2E)-3-methylpent-2-enal
app. Km value, pH 7.3 and 25°C
1.032
(2E)-3-methylpent-2-enal
app. Km value, pH 5.4 and 25°C
0.057
1-nitrocyclohexene
app. Km value, pH 7.3 and 25°C
0.4
1-nitrocyclohexene
above value, app. Km value, pH 5.4 and 25°C
0.0943
4-coumaryl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR2
0.1183
4-coumaryl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56Y
0.1663
4-coumaryl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56V
0.1719
4-coumaryl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR1
0.2026
5-hydroxyconiferyl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56Y
0.3081
5-hydroxyconiferyl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR2
0.1437
caffeoyl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56Y
0.1812
caffeoyl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR2
0.1933
caffeoyl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56V
0.2214
caffeoyl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR1
0.1726
coniferyl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56Y
0.2099
coniferyl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR2
0.004
NADPH
-
with trans-2-nonenal as cosubstrate, in 100 mM Tris (pH 7.2), at 25°C
0.0058
NADPH
app. Km value, pH 5.4 and 25°C, with 1-nitrocyclohexene
0.032
NADPH
-
with trans-3-nonen-2-one as cosubstrate, in 100 mM Tris (pH 7.2), at 25°C
0.516
trans-cinnamaldehyde
app. Km value, pH 7.3 and 25°C
1
trans-cinnamaldehyde
above value, app. Km value, pH 5.4 and 25°C
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0.003
(1R,2S,4S)-neoisodihydrocarveol
dehydrogenation, pH 8.0, 35°C, NADP+
0.003
(1R,4S)-isodihydrocarvone
hydrogenation to (1R,2S,4S)-neoisodihydrocarveol, pH 7.4, 35°C, NADP+
0.66 - 9.2
(2E)-3-methylpent-2-enal
0.02
(2R,4R)-carveol
dehydrogenation, pH 8.0, 35°C, NADP+
0.025
(2R,4S)-carveol
dehydrogenation, pH 8.0, 35°C, NADP+
0.097
(2S,4R)-carveol
dehydrogenation, pH 8.0, 35°C, NADP+
0.077
(2S,4S)-carveol
dehydrogenation, pH 8.0, 35°C, NADP+
0.012 - 0.032
(R)-carvone
3.3
(R)-pulegone
recombinant NtRed-1, pH 7.0 and 35°C
2.8
(S)-pulegone
recombinant NtRed-1, pH 7.0 and 35°C
1.46 - 11
1-nitrocyclohexene
0.52 - 1.17
1-octen-3-one
0.037 - 0.278
4-coumaryl aldehyde
0.161 - 0.169
5-hydroxyconiferyl aldehyde
0.068 - 0.277
caffeoyl aldehyde
0.118 - 0.134
coniferyl aldehyde
1.3
NADPH
app. Kcat, pH 7.3 and 25°C, with 1-nitrocyclohexene
0.87 - 2.92
trans-2-nonenal
1.1 - 3.5
trans-cinnamaldehyde
0.66
(2E)-3-methylpent-2-enal
app. Kcat, pH 7.3 and 25°C
9.2
(2E)-3-methylpent-2-enal
app. Kcat, pH 5.4 and 25°C
0.012
(R)-carvone
hydrogenation to (2R,4R)-carveol, pH 7.4, 35°C, NADP+
0.032
(R)-carvone
hydrogenation to (2S,4R)-carveol, pH 7.4, 35°C, NADP+
0.01
(S)-carvone
hydrogenation to (2R,4S)-carveol, pH 7.4, 35°C, NADP+
0.025
(S)-carvone
hydrogenation to (2S,4S)-carveol, pH 7.4, 35°C, NADP+
1.46
1-nitrocyclohexene
app. Kcat, pH 7.3 and 25°C
11
1-nitrocyclohexene
value above, app. Kcat, pH 5.4 and 25°C
0.52
1-octen-3-one
app. Kcat, pH 7.3 and 25°C
1.17
1-octen-3-one
app. Kcat, pH 5.4 and 25°C
0.037
4-coumaryl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56V
0.098
4-coumaryl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR1
0.249
4-coumaryl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56Y
0.278
4-coumaryl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR2
0.161
5-hydroxyconiferyl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56Y
0.169
5-hydroxyconiferyl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR2
0.068
caffeoyl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56V
0.132
caffeoyl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR1
0.238
caffeoyl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR2
0.277
caffeoyl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56Y
0.118
coniferyl aldehyde
pH and temperature not specified in the publication, recombinant wild-type isozyme PaDBR2
0.134
coniferyl aldehyde
pH and temperature not specified in the publication, recombinant isozyme PaDBR1 mutant C56Y
0.87
trans-2-nonenal
app. Kcat, pH 7.3 and 25°C
2.92
trans-2-nonenal
app. Kcat, pH 5.4 and 25°C
1.1
trans-cinnamaldehyde
app. Kcat, pH 7.3 and 25°C
3.5
trans-cinnamaldehyde
value above, app. Kcat, pH 5.4 and 25°C
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0.0018
pH and temperature not specified in the publication, purified recombinant wild-type isozyme PaDBR1, substrate coniferyl aldeyde
0.0026
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56A, substrate coniferyl aldeyde
0.0027
pH and temperature not specified in the publication, purified recombinant wild-type isozyme PaDBR1, substrate 5-hydroxyconiferyl aldeyde
0.0041
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56A, substrate 4-coumaryl aldeyde
0.0046
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56A, substrate 5-hydroxyconiferyl aldeyde
0.0078
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56A, substrate caffeoyl aldeyde
0.0079
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56S, substrate 4-coumaryl aldeyde
0.0091
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56S, substrate caffeoyl aldeyde
0.0115
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56S, substrate coniferyl aldeyde
0.0116
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56S, substrate 5-hydroxyconiferyl aldeyde
0.0124
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56V, substrate 4-coumaryl aldeyde
0.015
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56V, substrate caffeoyl aldeyde
0.0177
pH and temperature not specified in the publication, purified recombinant wild-type isozyme PaDBR1, substrate caffeoyl aldeyde
0.022
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56F, substrate 5-hydroxyconiferyl aldeyde
0.0234
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56Y, substrate 5-hydroxyconiferyl aldeyde
0.0237
pH and temperature not specified in the publication, purified recombinant wild-type isozyme PaDBR1, substrate 4-coumaryl aldeyde
0.0239
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56Y, substrate coniferyl aldeyde
0.0271
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56F, substrate coniferyl aldeyde
0.0454
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56F, substrate caffeoyl aldeyde
0.0497
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56Y, substrate caffeoyl aldeyde
0.066
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56F, substrate 4-coumaryl aldeyde
0.0743
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56Y, substrate 4-coumaryl aldeyde
0.11
Red-Toyopearl affinity column chromatography, pH 8.0, 35°C
4.6
DEAE-Toyopearl anion exchange column chromatography, pH 8.0, 35°C
5300
crude extract, pH 8.0, 35°C
0.008 - 4
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56V, substrate 5-hydroxyconiferyl aldeyde
0.008 - 4
pH and temperature not specified in the publication, purified recombinant isozyme PaDBR1 mutant C56V, substrate coniferyl aldeyde
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malfunction
suppression of chloroplastic alkenal/one oxidoreductase represses the carbon catabolic pathway in Arabidopsis leaves during night. Phosphoenolpyruvate carboxylase activity decreases and starch degradation during the night is suppressed in aor (RNAi). In contrast, the phenotype of aor (RNAi) is rescued when aor (RNAi) plants are grown under constant light conditions. The smaller plant sizes observed in aor mutants grown under day/night cycle conditions are attributable to the decrease in carbon utilization during the night. The acrolein reducing activity decreases to about 60% and 75%in aor-1 and aor-4 mutant lines, respectively, compared with the wild-type. Lack of AtAOR in chloroplasts induces oxidative stress. Phenotype analysis, detailed overview
evolution
tyrosine at position 56 of PaDBR2 is highly conserved among oxidoreductases, and is proposed to be involved in binding with NADPH. In isozyme PaDBR1, this position is occupied by a Cystein residue
evolution
tyrosine at position 56 of PaDBR2 is highly conserved among oxidoreductases, and is proposed to be involved in binding with NADPH. In isozyme PaDBR1, this position is occupied by a cysteine residue
physiological function
lipid-derived reactive carbonyl species (RCS) possess electrophilic moieties and cause oxidative stress by reacting with cellular components. Arabidopsis thaliana has a chloroplast-localized alkenal/one oxidoreductase (AtAOR) for the detoxification of lipid-derived RCS, especially alpha,beta-unsaturated carbonyls. The detoxification of lipid-derived RCS by AtAOR in chloroplasts contributes to the protection of dark respiration and supports plant growth during the night
physiological function
-
the aluminium-induced increase in root expression level of gene encoding 2-alkenal reductase (NADP+-dependent) might contribute to plant Al-tolerance by the detoxification of reactive carbonyls
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C56A
site-directed mutagenesis, the mutant shows altered substrate specificity with cinnamoyl aldehydes compared to wild-type enzyme
C56F
site-directed mutagenesis, the mutant shows altered substrate specificity and increased activity with cinnamoyl aldehydes compared to wild-type enzyme
C56S
site-directed mutagenesis, the mutant shows altered substrate specificity with cinnamoyl aldehydes compared to wild-type enzyme
C56V
site-directed mutagenesis, the mutant shows altered substrate specificity with cinnamoyl aldehydes compared to wild-type enzyme
C56Y
site-directed mutagenesis, the mutation turns the substrate selectivity and catalytic efficiency of isozyme PaDBR1 indistinguishable from those of isozyme PaDBR2, Docking arrangement of PaDBR1C56Y with NADP+/p-coumaryl aldehyde, overview. Increased activity compared to wild-type enzyme
additional information
generation of AtAOR (aor) mutants, including a transfer DNA knockout, aor (T-DNA), and RNA interference knockdown, aor (RNAi), lines. Both aor mutants show smaller plant sizes than wild-type plants when they are grown under day/night cycle conditions
additional information
-
generation of AtAOR (aor) mutants, including a transfer DNA knockout, aor (T-DNA), and RNA interference knockdown, aor (RNAi), lines. Both aor mutants show smaller plant sizes than wild-type plants when they are grown under day/night cycle conditions
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Hirata, T.; Tamura, Y.; Yokobatake, N.; Shimoda, K.; Ashida, Y.
A 38 kDa allylic alcohol dehydrogenase from the cultured cells of Nicotiana tabacum
Phytochemistry
55
297-303
2000
Nicotiana tabacum (Q9SLN8)
brenda
Dick, R.A.; Kensler, T.W.
The catalytic and kinetic mechanisms of NADPH-dependent alkenal/one oxidoreductase
J. Biol. Chem.
279
17269-17277
2004
Rattus norvegicus
brenda
Matsushima, A.; Sato, Y.; Otsuka, M.; Watanabe, T.; Yamamoto, H.; Hirata, T.
An enone reductase from Nicotiana tabacum: cDNA cloning, expression in Escherichia coli, and reduction of enones with the recombinant proteins
Bioorg. Chem.
36
23-28
2008
Nicotiana tabacum (Q9SLN8)
brenda
Mansell, D.J.; Toogood, H.S.; Waller, J.; Hughes, J.M.X.; Levy, C.W.; Gardiner, J.M.; Scrutton, N.S.
Biocatalytic asymmetric alkene reduction: crystal structure and characterization of a double bond reductase from Nicotiana tabacum
ACS Catal.
3
370-379
2013
Nicotiana tabacum (Q9SLN8)
brenda
Wu, Y.; Cai, Y.; Sun, Y.; Xu, R.; Yu, H.; Han, X.; Lou, H.; Cheng, A.
A single amino acid determines the catalytic efficiency of two alkenal double bond reductases produced by the liverwort Plagiochasma appendiculatum
FEBS Lett.
587
3122-3128
2013
Plagiochasma appendiculatum (S5TMG0), Plagiochasma appendiculatum (S5U4F4), Plagiochasma appendiculatum
brenda
Takagi, D.; Ifuku, K.; Ikeda, K.; Inoue, K.I.; Park, P.; Tamoi, M.; Inoue, H.; Sakamoto, K.; Saito, R.; Miyake, C.
Suppression of chloroplastic alkenal/one oxidoreductase represses the carbon catabolic pathway in Arabidopsis leaves during night
Plant Physiol.
170
2024-2039
2016
Arabidopsis thaliana (Q9ZUC1), Arabidopsis thaliana
brenda
Zhou, X.X.; Yang, L.T.; Qi, Y.P.; Guo, P.; Chen, L.S.
Mechanisms on boron-induced alleviation of aluminum-toxicity in Citrus grandis seedlings at a transcriptional level revealed by cDNA-AFLP analysis
PLoS ONE
10
e0115485
2015
Citrus maxima
brenda