Scientia Agricultura Sinica ›› 2021, Vol. 54 ›› Issue (16): 3502-3513.doi: 10.3864/j.issn.0578-1752.2021.16.012

• HORTICULTURE • Previous Articles     Next Articles

Purification, Characterization and Expression of Ionically Bound Peroxidase in Litchi Pericarp during Coloration and Maturation of Fruit

GUO ZhiXiong1,2(),SUN LengXue2,ZHENG JiaMin2,CAI CanJun2,WANG Bei2,LI KaiTuo2,PAN TengFei1,2,SHE WenQin1,2(),CHEN GuiXin1,2,PAN DongMing1,2   

  1. 1Institute of Postharvest Science and Technology of Horticultural Products, Fujian Agriculture and Forestry University, Fuzhou 350002
    2College of Horticulture, Fujian Agriculture and Forestry University, Fuzhou 350002
  • Received:2020-09-18 Accepted:2020-12-08 Online:2021-08-16 Published:2021-08-24
  • Contact: WenQin SHE E-mail:gzhhs@163.com;wenqinshe@163.com

Abstract:

【Objective】 In a previous study, the considerable activity of ionically bound peroxidase (BPox) was found in litchi pericarp. The BPox revealed a close relationship with the fruit maturation, but its role was unclear. This work was aimed to elucidate the biochemical properties and gene expression pattern of BPox for the further investigation of its involvement in the process of litchi coloration and maturation.【Method】The mature pericarp of litchi (Litchi chinensis Sonn. cv. Wuye) was used as material, and the BPox was extracted and purified through column chromatography of Streamline Phenyl, CM-52, Phenyl Sepharose and Superdex-200, respectively. The optimal pH and temperature, the substrate specificity and the inhibitors were measured, respectively. The Km values of BPox for guaiacol and (-)-epicatechin and Vmax values were determined by using double reciprocal plots, respectively. The purified Bpox protein was conducted to SDS-PAGE and in-gel digestion by trypsin, and the sequences of the peptide fragments were identified by using MALDI tandem TOF MS. Total RNA was isolated from litchi pericarp, and the cDNA encoding BPox was cloned. The fruits were harvested 58, 69, 76, 80 and 90 days after full blooming (DAFB), the determination of BPox activity changes in the pericarp and the analysis of BPox gene expression using real-time quantitative PCR, were performed, respectively.【Result】Two most major fractions of ionically bound cationic peroxidase, named BPox-2 and BPox-3, were purified from litchi pericarp, respectively. The apparent molecular weights of the two isoforms were the same, and were estimated to be 30 and 34 kD by gel filtration and SDS-PAGE, respectively. For the BPox-2 and the BPox-3, the optimal pH was 6.0, and the optimal temperature was 40℃ and 45℃, respectively. In the presence of H2O2, similar substrate affinity was revealed, while guaiacol and (-)-epicatechin (EC) were the favorable substrates for the two BPoxs. The metal ions test exhibited poor effect on the activity and the most effective inhibitors for litchi BPoxs were dithiothreitol, ascorbate and L-cysteine. The Km values of BPox-2 and BPox-3 for guaiacol were 2.97 and 2.58 mmol∙L-1, and the Vmax values were 38.60×106and 19.85×106 U∙mg-1, respectively. The Km values of BPox-2 and BPox-3 for EC were 3.49 and 3.24 mmol∙L-1, and the Vmax values were 38.72×106 and 23.06×106 U∙mg-1, respectively, illustrating that the catalytic efficiency (Vmax/Km) of BPox-2 was higher than that of BPox-3. The result of MALDI TOF MS demonstrated differences of peptide mass fingerprint (PMF) between the BPox-2 and the BPox-3; however, a common peptide fragment digested from the two peroxidases corresponding to the amino acid sequence of TASLSAANSDLPSPFADLATLIAR was identified by tandem MS and Mascot database search. The ORF of cDNA for litchi BPox2, containing 960 bp in length was cloned, encoding a polypeptide of 319 amino acid residue. The results of analysis revealed that, the polypeptide coded by the cDNA contained a putative 26-mer signal peptide and was absent of vacuolar sorting sequence on the C-terminus, and only one potential N-glycosylation site was found in the sequence. The molecular weight and the pI value of the mature polypeptide were predicted to be 31.35 kD and 7.71, respectively. The activity of BPox was very weak in the pericarp of young fruit. From the onset of pericarp coloration at 76 DAFB, the BPox activity increased remarkably, and then, it rose significantly coinciding with the subsequent process of fruit maturation until 90 DAFB. The qPCR results showed that the transcript level of BPox2 gene was low in the pericarp of young fruit at 58 DAFB and 69 DAFB. It increased dramatically, reached a peak at 76 DAFB, being 60.56-fold of that at 69 DAFB, and then declined. The transcript level increased significantly with the process of fruit maturation at 90 DAFB.【Conclusion】Characterization of the BPox illustrated that, its pH optimal, temperature optimal and substrate specificity etc., were similar to those of soluble peroxidases (SPox) in litchi pericarp and other plant peroxidases; however, the catalytic efficiency (Vmax/Km) of BPox for guaiacol and EC was much higher than that of litchi SPox. The results of MALDI MS/MS identification suggested that the BPox-2 and the BPox-3 were the two isoforms coded by the BPox2 gene and distinct due to different post-translational modification. The molecular weight of the predicted mature polypeptide coded by the BPox2 cDNA was near to that of the purified protein, suggesting its relative low degree of post-translational modification. Litchi BPox played a role in the pericarp maturation and was regulated at the transcriptional level.

Key words: litchi, ionically bound peroxidase, purification, MALDI MS/MS identification, gene expression, coloration and maturation

Fig. 1

Cationic ion exchange chromatography profile (A), the native cathode gel electrophoresis and activity staining pattern (B) of BPox eluted from the CM-52 cellulose column"

Fig. 2

Molecular weight estimation of BPox-2/3 by gel filtration on Superdex 200 The standard mixture (Bio-Rad) contains thyroglobulin (670 kD), g-globulin (158 kD), ovalbumin (44 kD), myoglobin (17 kD) and vitamin B12 (1.36 kD)"

Fig. 3

SDS-PAGE pattern of the BPox-2 and BPox-3 purified from litchi pericarp M: Premixed protein marker (broad, Takara); 1: Total protein of litchi pericarp extracted according to the method described by LI et al[22]; 2, 3: Purified BPox-2 and BPox-3, respectively"

Fig. 4

Effect of pH on the activities of BPox-2 and BPox-3"

Fig. 5

Effect of temperature on the activities of BPox-2 and BPox-3"

Table 1

Specific activity of BPox-2/3 for different substrates"

底物
Substrate
波长
Wavelength (nm)
BPox比活力
Specific activity of
BPox (×105 U∙mg-1)
BPox-2 BPox-3
愈创木酚 Guaiacol 470 116.03±1.41 31.38±0.45
(-)-表儿茶素 (-)-Epicatechin 440 61.66±1.87 62.71±0.40
4-甲基邻苯二酚4-Methylcatechol 420 16.85±0.21 3.93±0.07
焦性没食子酸 Pyrogallol 420 11.75±0.13 3.61±0.17
邻苯二酚 Catechol 420 8.37±0.19 3.45±0.34
没食子酸 Gallic acid 420 3.82±0.09 0.88±0.16
氯原酸 Chlorogenic acid 420 3.09±0.29 0.84±0.01
4-甲氧基酚 4-Methoxyphenol 420 0.88±0.09 0.53±0.18
对苯二酚 Hydroquinone 420 0.44±0.09 0.48±0.07
间苯二酚 m-Dihydroxybenzene 420 0 0
藜芦醇 Veratryl alcohol 420 0 0
苯甲醇 Benzylalcohol 310 0 0

Table 2

Effects of metal ions and inhibitors on the activity of BPox-2/3"

抑制剂
Inhibitor
终浓度
Concentration
(mmol∙L-1)
BPox-2相对活性
Relative activity
of BPox-2
BPox-3相对活性
Relative activity of BPox-3
CuSO4 0 1 1
0.1 1.05±0.016 1.18±0.008
1 1.05±0.003 1.06±0.01
MnSO4 0.1 0.92±0.009 0.87±0.019
1 0.74±0.013 0.78±0.01
CaCl2 0.1 0.98±0.010 0.99±0.002
1 0.88±0.011 0.89±0.03
FeCl3 0.1 0.92±0.009 0.91±0.020
1 0.77±0.026 0.85±0.03
EDTA 0.1 0.93±0.007 0.95±0.005
1 0.89±0.06 0.93±0.03
L-Cysteine 0.1 0.15±0.005 0.22±0.001
1 0.019±0 0.058±0
DTT 0.1 0.03±0.003 0
1 0 0
ASA
0.1 0 0
1 0 0

Fig. 6

Double reciprocal plots of guaiacol catalyzed by BPox-2(A) and BPox-3(B), respectively"

Fig. 7

Double reciprocal plots of (-)-epicatechin catalyzed by BPox-2(A) and BPox-3(B), respectively"

Fig. 8

Peptide mass fingerprinting of BPox-2a from MALDI-TOF MS"

Fig. 9

Peptide mass fingerprinting of BPox-3a from MALDI-TOF/MS"

Table 3

Peptide fragment sequences of BPoxs identified by MALDI MS/MS"

BPox 质荷比
m/z
序列号
Protein ID
肽段序列
Peptide fragment sequence
BPox-2a 964.3965 gi|696949335 FDNSYYR
1575.7296 MGNISPLTGTNGEIR (Oxidation M)
2402.1899 TASLSAANSDLPSPFADLATLIAR
BPox-2b 964.4012 gi|696949335 FDNSYYR
2402.2012 TASLSAANSDLPSPFADLATLIAR
BPox-3a 2402.2175 gi|696949335 TASLSAANSDLPSPFADLATLIAR
BPox-3b 1575.7279 gi|696949335 MGNISPLTGTNGEIR (Oxidation M)
2402.2183 TASLSAANSDLPSPFADLATLIAR

Fig. 10

cDNA sequence and its deduced amino acid sequence of BPox in litchi pericarp The underlined indicates the peptide fragment digested from litchi BPox isomers of which the sequence was identified by MALDI TOF MS/MS. A Putative signal peptide (green) and a potential glycosylation site (blue) were signed as well, respectively"

Fig. 11

Changes of appearance (a), BPox activity (b) and BPox2 gene expression (c) in litchi pericarp during the fruit coloration and maturation"

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