1.Identification and differential expression of miRNA related to seed dormancy of Paris polyphylla var. chinensis.
Cheng-Cai ZHANG ; Hong-Juan WANG ; Hui-Hui LIANG ; Zhen GAO ; Li-Na LUO ; Chao HE ; Zeng-Xu XIANG
China Journal of Chinese Materia Medica 2020;45(24):5958-5966
The purpose of this study was to explore the expression pattern of miRNA in the process of embryo dormancy and provide a reference for the mechanism of regulating seed dormancy and germination by miRNA. We used high-throughput sequencing technology, bioinformatics analysis and real-time fluorescent quantitative PCR(qPCR) technology to sequence, screen and identify miRNAs of dormant and dormant embryos. The results showed that there were 23 811 977, 24 276 695, 20 611 876 and 20 601 811 unique sequences in the four sample libraries during the period of dormancy and dormancy release. MiRNAs are mainly distributed between 21 and 24 nt, among which the length of 24 nt occurred most frequently. A total of 31 known miRNAs were identified, belonging to 13 different families. 93 new miRNAs were predicted by bioinformatics software. Ten miRNAs(mir156 a-5 p, mir160 a-5 p, mir160 h-1, mir169 a-5 p, mir157 d, mir159 a-1, mir395-3, mir156 f-5 p, mir156-2 and mir171 a-3 p) were screened out. In this study, 10 miRNAs related to seed dormancy release were identified. The target genes mainly involved carbohydrate metabolism, plant hormone signal transduction, cell division and growth. The results of qRT-PCR showed that the sequencing results were consistent with the actual results.
Gene Expression Regulation, Plant
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Humans
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Liliaceae
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MicroRNAs
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Plant Dormancy
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RNA, Plant
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Seeds
2.Transcriptome analysis of seed embryo in dormancy and dormancy release state of Thesium chinense.
Cheng-Cai ZHANG ; Zhen GAO ; Li-Na LUO ; Zi-Xuan ZHANG ; Jiang WANG ; Fu-Hua LU ; Zeng-Xu XIANG
China Journal of Chinese Materia Medica 2020;45(16):3837-3843
We used exogenous GA_3 to break the seed dormancy of Thesium chinense. We used high-throughput sequencing technology was used to sequence the transcriptome of dormant seed embryos and dormancy breaking seed embryos of Th. chinense, and the data was analyzed bioinformatically and systematically. The results showed that exogenous GA_3 could effectively break the seed dormancy of Th. chinense; 73 794 up-regulated genes and 42 776 down regulated genes were obtained by transcriptome sequencing; 116 570 diffe-rential genes were annotated by GO function to GO items such as metabolism process, cell process, cell, cell component, binding and catalytic activity. A total of 133 metabolic pathways were found by Pathway analysis of 26 508 differentially expressed genes. In the process of dormancy release, DEGs were mainly enriched in translation, carbohydrate metabolism, folding, classification, degradation and amino acid metabolism. Based on the annotation results in KEGG database, 20 metabolic pathways related to dormancy release were found. Dormancy release of Th. chinense seeds is a complex biological process, including cell morphology construction, secondary metabolite synthesis, sugar metabolism and plant signal transduction, among which plant hormone signal transduction is one of the key factors to regulate dormancy release. The results of qRT-PCR showed that the sequencing results were consistent with the actual results.
Gene Expression Profiling
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Gene Expression Regulation, Plant
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Plant Dormancy
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Plant Growth Regulators
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Santalaceae
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Seeds
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Transcriptome
3.Effects of low temperature on dormancy breaking and growth after planting in bulbs of Tulipa edulis.
Ying YANG ; Zai-Biao ZHU ; Qiao-Sheng GUO ; Yuan-Yuan MIAO ; Hong-Liang MA ; Xiao-Hua YANG
China Journal of Chinese Materia Medica 2015;40(1):48-52
The effect of low temperature storage on dormancy breaking, sprouting and growth after planting of Tulipa edulis was studied. The results showed that starch content and activity of amylases significantly decreased during 10 weeks of cold storage, soluble protein content raised at first then decreased, and the peak appeared at the 6th week. However, total soluble sugar content which in- creased slowly at first than rose sharply and reducing sugar content increased during the storage duration. The bulbs with cold storage treatment rooted in the 6th week, which was about 2 weeks earlier than room temperature storage, but there were less new roots in the late period of storage. After stored at a low temperature, bud lengths were longer than that with room temperature treatment. Cold storage treatment could promote earlier emergence, shorten germination time, prolong growth period and improve the yield of bulb, but rarely affect the emergence rate. It was not beneficial to flowering and fruiting. The results indicated that 6-8 weeks of cold storage was deemed to be the key period of dormancy breaking preliminary.
Cold Temperature
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Plant Dormancy
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Plant Roots
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chemistry
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growth & development
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physiology
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Tulipa
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chemistry
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growth & development
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physiology
4.Seed dormancy mechanisms of Pseudostellaria heterophylla and its germination characteristics.
Chenghong XIAO ; Weike JIANG ; Tao ZHOU ; Qiang AI ; Houxi XIONG ; Mingwu LIAO
China Journal of Chinese Materia Medica 2012;37(14):2067-2070
OBJECTIVESeed dormancy mechanisms, breaking dormancy and the optimal germinating conditions were studied to improve reproductive efficiency and quality standard of Pseudostellaria heterophylla.
METHODThe P. heterophylla seeds were stratified into wettish sand for 65 days under the temperature of -2-3 degrees C, embryo length and germination dynamic change of seeds were measured in prophase every other 10 days and in middle every other 5 days. The influences on seed germination and seedling growth under different temperatures, germination beds were investigated.
RESULTThe P. heterophylla seeds embryo morphology was unchanged in stratification. The seeds could not germinate at stratification within the first 35 days. The germination rate and germination energy of seeds increased with the stratification time after 35 days. Germination rate, germination energy, plant height and fresh weight under the 10 degrees C were significantly higher than those under other temperatures. Germination rate, germination energy, plant height, fresh weight and dry weight of plant in sand bed were higher than those of plant in other beds, and seed mildew rate and abnormal seedling proportion of plant in sand bed were less than those of plant in other beds.
CONCLUSIONThe dormancy of P. heterophylla seeds is mainly the physiological post-maturation. The optimal germination conditions of seeds is 10 degrees C the culture of sand. The dormancy was broke under -2-3 degrees C of wettish sand for 45-50 days in practice.
Caryophyllaceae ; growth & development ; Germination ; Light ; Plant Dormancy ; physiology ; Seeds ; physiology ; Temperature
5.Advances of studies on seed biology of Bupleurum chinense.
Ruyu YAO ; Xingfu CHEN ; Yuanfeng ZOU ; Xingwang YANG ; Baolin ZHANG ; Yao YANG
China Journal of Chinese Materia Medica 2011;36(17):2429-2432
Bupleurum chinense is a commonly used Chinese medicinal material, which has been used medicinally in China for over 2000 years, the development of it is of great value. There have been great advances of studies on its embryology and seed biology in recent years. In this paper, we make a review of the growth of its embryo and fruit, the characteristics of dormancy and storage and the germination of its seed. Besides, we summarize the reasons of its low germination rate and the achievements in improving the situation, for the purpose of providing reference in research on seed physiology of B. chinense.
Bupleurum
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chemistry
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growth & development
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physiology
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Drugs, Chinese Herbal
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analysis
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Plant Dormancy
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Seeds
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chemistry
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growth & development
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physiology
6.Dormancy characteristics and breaking method of seeds from Epimedium wushanense.
Jiayi FAN ; Qiaosheng GUO ; Zuoyi LIU ; Guosheng ZHU ; Ning ZHOU ; Yong HE
China Journal of Chinese Materia Medica 2010;35(24):3242-3245
OBJECTIVETo research the mechanism of dormancy and find out the breaking method for the seeds of Epimedium wushanense.
METHODThe water permeability of seed coat was tested by weighing seeds. The germination inhibitor of the seeds were determined with biotic measurement. The development of embryos, germination rate and germination potential were determined after stratification.
RESULTThe water permeability of seed coat was 41.86% after 5 h. The extracts of seeds had strong inhibition effects to the length growth of cabbage seedlings. The growth and development of embryos under the cold stratification (5 degrees C) were better than that under the other conditions. The embryo rate extended from 15.39% to 86.21% after 90 d. Germination rate and germination potential after stratification under 5 degrees C were significantly higher than that under other temperatures.
CONCLUSIONThe results showed that there was no obstacle of water permeability on the test of E. wushanense, after-ripening of embryogenesis and the germination inhibitor of the seed were the main reason for the seed dormancy. The cold stratification would be an effective way for breaking of the dormancy, which could significantly promote the seed embryogenesis and increase germination rate comparing to other methods.
Epimedium ; drug effects ; growth & development ; physiology ; Plant Dormancy ; drug effects ; physiology ; Seeds ; drug effects ; growth & development ; physiology ; Solvents ; pharmacology ; Temperature ; Time Factors ; Water ; pharmacology
7.Study on winter dormancy of Thesium chinense and its phenological phase.
Ling-shan SONG ; Xiao-ming ZHANG ; Qiao-sheng GUO ; Lu CHEN ; Chang-lin WANG
China Journal of Chinese Materia Medica 2015;40(23):4585-4590
In order to explore reasonable artificial cultivation pattern of Thesium chinense, the biological characteristics and nutrients change in the process of winter dormancy of T. chinense was studied. The phenological period of T. chinense was observed by using fixed-point notation and the starch grains changes were determined dynamically by PAS-vanadium iron hematoxylin staixjing method. Soluble sugar and starch content were measured by anthrone-sulfuric acid method and amylase activity was determined by DN'S method. The results showed that the normal life cycle of T. chinense was two years. T. chinense was growing by seed in the first year, but growing by the root neck bud in the second year. During the process of dormancy, starch and soluble sugar could mutual transformation in different periods. T. chinense had sufficient carbohydrate to maintain growth and also a lot of small molecules to improve their ability to fight against adversity.
Plant Dormancy
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Plant Leaves
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chemistry
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growth & development
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metabolism
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Plant Roots
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chemistry
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growth & development
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metabolism
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Plant Stems
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chemistry
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growth & development
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metabolism
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Santalaceae
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chemistry
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growth & development
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metabolism
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Seasons
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Starch
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analysis
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metabolism
8.Study on seeds dormancy release and physiological change of Thesium chinense.
China Journal of Chinese Materia Medica 2012;37(6):760-763
OBJECTIVETo study the seeds dormancy release and physiological change of Thesium chinense.
METHODTo release dormancy, the seeds of T. chinense were treated with chemical reagent and stratification under 3-5 degrees C.
RESULTWhen washed with flowing water for 24 h, then soaked in 500 mg x L(-1) GA3 for 24 h, finally, treated with stratification method under 3-5 degrees C for 150 day, the split rate of T. chinense seeds reached 22%, crude fat decreased 50%, total sugar and dissolvability sugar increased 3-4 times, ABA decreased more than 90%, GA3 increased more than 5 times.
CONCLUSIONThe seeds dormancy of T. chinense can be released with the method of washing with flowing water for 24 h, then soaking in 500 mg x L(-1) GA3 for 24 h, finally, treated with stratification method under 3-5 degrees C for 150-180 day.
Abscisic Acid ; pharmacology ; Carbohydrates ; analysis ; Cold Temperature ; Fats ; analysis ; Germination ; physiology ; Gibberellins ; pharmacology ; Magnoliopsida ; drug effects ; physiology ; Plant Dormancy ; drug effects ; physiology ; Plant Growth Regulators ; pharmacology ; Plants, Medicinal ; drug effects ; physiology ; Seeds ; drug effects ; physiology ; Time Factors ; Water ; pharmacology