Isolation of Three Types of Invertase Genes from Hemerocallis fulva and Their Responses to Low Temperature and Osmotic Stress

doi:10.16420/j.issn.0513-353x.2020-0346

Acta Horticulturae Sinica ›› 2021, Vol. 48 ›› Issue (2): 300-312.doi: 10.16420/j.issn.0513-353x.2020-0346

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Isolation of Three Types of Invertase Genes from Hemerocallis fulva and Their Responses to Low Temperature and Osmotic Stress

BAI Lu, ZHANG Zhiguo, ZHANG Shijie, HUANG Dongmei, QIN Qiaoping^*()

School of Ecological Technology and Engineering,Shanghai Institute of Technology,Shanghai 201418,China

Received:2020-07-27 Revised:2020-12-07 Online:2021-02-25 Published:2021-03-09
Contact: QIN Qiaoping E-mail:qinqp@sit.edu.cn

Abstract

Abstract:

In this study,three invertase genes were cloned from Hemerocallis fulva‘Athlone’,named HfCIN3,HfCWIN1 and HfVIN1. The ORFs of the three invertase genes were 1 941,1 701,1 920 bp,encoding 646,566 and 639 amino acids,respectively,with the similarity of 18.81%-41.86%. The amino acid sequence of HfCIN3 was 75.16%-82.79% similar to those of dendrobium and wild banana,HfCWIN1 was 58.95%-68.88% similar to asparagus and oil palm,and HfVIN1 was 73.4% similar to agave. HfCIN3 had a signal peptide and typical glycoside hydrolases family 100 domain,HfCWIN1 and HfVIN1 had glycosyl hydrolases family 32 domain. HfCWIN1 also contained a 72 amino acid Malectin domain related to cell wall sugar recognition. HfVIN1 contained a possible vacuolar motif“ILPD”and had a typical transmembrane domain at the N terminus. Both HfCWIN1 and HfVIN1 possessed the N-glycosylation and O-β-GlcNAc sites,whereas HfCIN3 only had the O-β-GlcNAc sites. Phylogenetic analysis showed that monocotyledons and dicotyledons could clearly be distinguished regarding different types of invertase;CWIN and VIN were closely related,and HfCIN3,HfCWIN1 and HfVIN1 were clustered in monocots. Transient expression analysis showed 35S:HfCIN3-GFP was expressed in chloroplasts;35S:HfVIN1-GFP was expressed in vacuoles;and 35S:HfCWIN1-YFP was detected in cell walls and guard cells. The expression levels of HfCIN3,HfCWIN1 and HfVIN1 were significantly higher in leaves than that of the root and flower tissues;the expression levels in leaves were HfVIN1 > HfCWIN1 > HfCIN3. After 24 h treatment at 0 ℃,the expression of HfVIN1 was increased by 2.2 times compared with 5 ℃,and the expression level of HfCWIN1 was increased significantly at 0 ℃ compared with the other temperatures. The highest expression of HfVIN3 was recorded at 0 ℃. After 24 h treatment with 5% or 10% PEG,the expression levels of HfCIN3 and HfVIN1 were not significantly different from the control,but that of HfCWIN1 was significantly lower than the control. The CIN activity and gene expression were similar in different tissues,but CWIN and VIN were not consistent with the gene expression. As temperature decreased,CIN declined,CWIN increased at first and then decreased,and VIN decreased at first then increased,and then decreased;PEG induced VIN activity. The enzyme activity and gene expression were not synchronized after the low temperature and osmotic stress treatment,possibly because the gene post-transcriptional modifications played an important role in invertase activity. The results of this study established the differences in subcellular localizations,gene expression patterns and the responses to abiotic stresses among the three various types of Hemerocallis fulva invertase,HfVIN1 responded to low temperature,whereas HfCWIN1 responded to osmotic stress.

Key words: Hemerocallis fulva, sucrose, invertase, abiotic stress, gene expression

CLC Number:

S682.1 ⁺9

BAI Lu, ZHANG Zhiguo, ZHANG Shijie, HUANG Dongmei, QIN Qiaoping. Isolation of Three Types of Invertase Genes from Hemerocallis fulva and Their Responses to Low Temperature and Osmotic Stress[J]. Acta Horticulturae Sinica, 2021, 48(2): 300-312.

Figures/Tables 8

References 30

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用途 Application	引物名称 Primer	引物序列（5′-3′） Sequence
cDNA克隆	HfVIN1-F1/R1	ATGGTACCGGACCAATGGTA/CAAGTTGGGGAAGTGTAAGGTGT
cDNA clone	HfCWIN1-F1/ R1	ATGGCTGCTGGTTCATTGCT/TTAGCTAATTATCGCTTTTGCCA
	HfCIN3-F1/ R1	ATGGGAGTTTGTGATTTATC/TCATACGATATATGTCTTCTTCA
qPCR	HfVIN1-F2/R2	CTCCTCCTCCCTTCCGATTC/CGGGCTTCATTAGTGTTGGG
	HfCWIN1-F2/R2	TGGTTCCGTGACCCTTCTAC/AAGTCCGGACATTCCCACAT
	HfCIN3-F2/R2	TGGCAACTACACAGCAATCG/AGGCCAAGAACCTCCATTGT
pBI221-GFP载体构建补英文。 Construction of PBI221-GFP vector	HfCIN3-F3/R3	gaggatctcgagcggtctagaATGGGAGTTTGTGATTTATC/agcggccgctgtacaggtaccTACGATATATGTCTTCTTCA
	HfVIN1-F3/R3	gaggatctcgagcggtctagaATGGGGTCACGTGACTTGGA/agcggccgctgtacaggtaccCAAGTTGGGGAAGTGTAAGG
	HfCWIN1-F3/R3	gaggatctcgagcggtctagaATGGCTGCTGGTTCATTGCT/agcggccgctgtacaggtaccGCTAATTATCGCTTTTGCCA
pC131-YFP载体构建 Construction of pC131-YFP vector	HfCWIN1-F4/R4	gaggatctcgagcgggaattcATGGCTGCTGGTTCATTGCT/agcggccgctgtacaactagtGCTAATTATCGCTTTTGCCA
qPCR内参补英文 qRT-PCR reference gene	HfUBQ-F/R	AACGTGAAGGCCAAGATAC/AGACGGAGCACCAGGTGGA

用途 Application	引物名称 Primer	引物序列（5′-3′） Sequence
cDNA克隆	HfVIN1-F1/R1	ATGGTACCGGACCAATGGTA/CAAGTTGGGGAAGTGTAAGGTGT
cDNA clone	HfCWIN1-F1/ R1	ATGGCTGCTGGTTCATTGCT/TTAGCTAATTATCGCTTTTGCCA
	HfCIN3-F1/ R1	ATGGGAGTTTGTGATTTATC/TCATACGATATATGTCTTCTTCA
qPCR	HfVIN1-F2/R2	CTCCTCCTCCCTTCCGATTC/CGGGCTTCATTAGTGTTGGG
	HfCWIN1-F2/R2	TGGTTCCGTGACCCTTCTAC/AAGTCCGGACATTCCCACAT
	HfCIN3-F2/R2	TGGCAACTACACAGCAATCG/AGGCCAAGAACCTCCATTGT
pBI221-GFP载体构建补英文。 Construction of PBI221-GFP vector	HfCIN3-F3/R3	gaggatctcgagcggtctagaATGGGAGTTTGTGATTTATC/agcggccgctgtacaggtaccTACGATATATGTCTTCTTCA
	HfVIN1-F3/R3	gaggatctcgagcggtctagaATGGGGTCACGTGACTTGGA/agcggccgctgtacaggtaccCAAGTTGGGGAAGTGTAAGG
	HfCWIN1-F3/R3	gaggatctcgagcggtctagaATGGCTGCTGGTTCATTGCT/agcggccgctgtacaggtaccGCTAATTATCGCTTTTGCCA
pC131-YFP载体构建 Construction of pC131-YFP vector	HfCWIN1-F4/R4	gaggatctcgagcgggaattcATGGCTGCTGGTTCATTGCT/agcggccgctgtacaactagtGCTAATTATCGCTTTTGCCA
qPCR内参补英文 qRT-PCR reference gene	HfUBQ-F/R	AACGTGAAGGCCAAGATAC/AGACGGAGCACCAGGTGGA

理化性质 Characteristics	分子量/kD Molecular weight	pI	不稳定性指数 Instability index	亲水性平均系数 Grand average of hydropathicity	磷酸化位点Phosphoryla- tion sites	糖基化位点Glycosylation site
理化性质 Characteristics	分子量/kD Molecular weight	pI	不稳定性指数 Instability index	亲水性平均系数 Grand average of hydropathicity	磷酸化位点Phosphoryla- tion sites	N-Glycosyl- ation	O-β-GlcNAc
HfCIN3	74.840	6.35	46.98（不稳定Unstable）	-0.275	5	-	√
HfCWIN1	63.496	5.38	38.66（稳定Stable）	-0.326	0	√	√
HfVIN1	71.340	5.33	37.42（稳定Stable）	-0.312	6	√	√

理化性质 Characteristics	分子量/kD Molecular weight	pI	不稳定性指数 Instability index	亲水性平均系数 Grand average of hydropathicity	磷酸化位点Phosphoryla- tion sites	糖基化位点Glycosylation site
理化性质 Characteristics	分子量/kD Molecular weight	pI	不稳定性指数 Instability index	亲水性平均系数 Grand average of hydropathicity	磷酸化位点Phosphoryla- tion sites	N-Glycosyl- ation	O-β-GlcNAc
HfCIN3	74.840	6.35	46.98（不稳定Unstable）	-0.275	5	-	√
HfCWIN1	63.496	5.38	38.66（稳定Stable）	-0.326	0	√	√
HfVIN1	71.340	5.33	37.42（稳定Stable）	-0.312	6	√	√

Isolation of Three Types of Invertase Genes from Hemerocallis fulva and Their Responses to Low Temperature and Osmotic Stress

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