Floral buds of Agapanthus praecox ssp. orientalis were observed under dissecting and optical microscope to characterize floral organs development and to study relationships between anther development and microsporogen...Floral buds of Agapanthus praecox ssp. orientalis were observed under dissecting and optical microscope to characterize floral organs development and to study relationships between anther development and microsporogenesis. Floral organs differentiation was comprised of 6 distinct stages including nought differentiation, inflorescence bud differentiation, floret primordia differentiation, tepal primordia differentiation, stamen primordia differentiation, and pistil primordia differentiation. Six tepals differentiated almost simultaneously which cross arranged in space and appeared in hexagonal distribution pattern. Six stamens were differentiated inside the tepals at the same time. Finally, 3 carpel primordia differentiated and formed syncarpous pistil. The whole process of floral bud differentiation took approximately 40 d with the first 3 stages developing more slowly than the later 3 stages. Morphology and color of the anther underwent obvious changes during the period between stamen primordia differentiation and anther maturation. Microspores also underwent significant development during this same interval. The relationship between the process of microsporogenesis and anther development has already been made clear by the sauash techniaue.展开更多
Hormones play important roles in vegetative and reproductive processes;however,the regulatory roles of hormones in Nelumbo nucifera(Lotus)growth and development are unclear.In this study,nine types of endogenous hormo...Hormones play important roles in vegetative and reproductive processes;however,the regulatory roles of hormones in Nelumbo nucifera(Lotus)growth and development are unclear.In this study,nine types of endogenous hormones,including gibberellins(GA_1,GA_3,and GA_4),indole-3-acetic acid(IAA),brassinolide(BR),ethylene(ETH),jasmonic acid(JA),abscisic acid(ABA),and zeatin(ZT)were detected in dormant shoot tips,vegetative shoot tips,developing leaf buds,and developing flower buds of lotus.The results indicated that GA,ETH,and BR signaling can promote vegetative and reproductive development of lotus.GA signaling regulates plant height and stimulates flower bud differentiation.GA levels were the highest in the flower buds;exogenous GA3+4 increased plant height by approximately 90%,increased flower quantity by nearly 40%,and advanced flowering by 4 d.Suppressing GA biosynthesis using paclobutrazol decreased plant height and flower quantity by 38%and 87.1%,respectively,and delayed flowering by 15.6 d.ETH signaling has positive regulatory effects on vegetative growth and flower development.The ETH concentration in the developing leaf buds was at least 50%higher than that in other samples.Ethephon spraying led to remarkable increases in plant height and leaf thickness and extended the flowering duration.BR signaling acts as a growth promoter during vegetative and reproductive development in lotus.The highest BR levels were detected in the vegetative shoot tips.External application of28-epihomobrassinolide resulted in growth-promoting phenotypes including longer scapes,thicker leaves,and prolonged flowering.展开更多
Dehydrins(DHNs),as members of the late embryogenesis abundant protein family,play critical roles in the protection of seeds from dehydration and plant adaptation to multiple abiotic stresses.Vitrification is a basic m...Dehydrins(DHNs),as members of the late embryogenesis abundant protein family,play critical roles in the protection of seeds from dehydration and plant adaptation to multiple abiotic stresses.Vitrification is a basic method in plant cryopreservation and is characterized by forming a glassy state to prevent lethal ice crystals produced during cryogenic storage.In this study,ApSK3 type DHN was genetically transformed into embryogenic calluses(EC)of Agapanthus praecox by overexpression(OE)and RNA interference(RNAi)techniques to evaluate the in vivo protective effect of DHNs during cryopreservation.The cell viability showed a completely opposite trend in OE and RNAi cell lines,the cell relative death ratio was decreased by 20.0%in ApSK3-OE EC and significantly increased by 66.15%in ApSK3-RNAi cells after cryopreservation.Overexpression of ApSK3 increased the content of non-enzymatic antioxidants(AsA and GSH)and up-regulated the expression of CAT,SOD,POD,and GPX genes,while ApSK3-RNAi cells decreased antioxidant enzyme activities and FeSOD,POD,and APX genes expression during cryopreservation.These findings suggest that ApSK3 affects ROS metabolism through chelating metal ions(Cu^(2+)and Fe^(3+)),alleviates H_(2)O_(2)and OH·excessive generation,activates the antioxidant system,and improves cellular REDOX balance and membrane lipid peroxidation damage of plant cells during cryopreservation.DHNs can effectively improve cell stress tolerance and have great potential for in vivo or in vitro applications in plant cryopreservation.展开更多
基金supports from the Research Fund for the Doctoral Program of Higher Education of China (200802250010)the National Natural ScienceFoundation of China (30571475)the Key Project of the Shanghai Agricultural Committee (2010-6-2, 2006-4-9)
文摘Floral buds of Agapanthus praecox ssp. orientalis were observed under dissecting and optical microscope to characterize floral organs development and to study relationships between anther development and microsporogenesis. Floral organs differentiation was comprised of 6 distinct stages including nought differentiation, inflorescence bud differentiation, floret primordia differentiation, tepal primordia differentiation, stamen primordia differentiation, and pistil primordia differentiation. Six tepals differentiated almost simultaneously which cross arranged in space and appeared in hexagonal distribution pattern. Six stamens were differentiated inside the tepals at the same time. Finally, 3 carpel primordia differentiated and formed syncarpous pistil. The whole process of floral bud differentiation took approximately 40 d with the first 3 stages developing more slowly than the later 3 stages. Morphology and color of the anther underwent obvious changes during the period between stamen primordia differentiation and anther maturation. Microspores also underwent significant development during this same interval. The relationship between the process of microsporogenesis and anther development has already been made clear by the sauash techniaue.
基金supported by the National Natural Science Foundation of China(Grant No.31971705)Natural Science Foundation of Shanghai(Grant No.21ZR1434200)。
文摘Hormones play important roles in vegetative and reproductive processes;however,the regulatory roles of hormones in Nelumbo nucifera(Lotus)growth and development are unclear.In this study,nine types of endogenous hormones,including gibberellins(GA_1,GA_3,and GA_4),indole-3-acetic acid(IAA),brassinolide(BR),ethylene(ETH),jasmonic acid(JA),abscisic acid(ABA),and zeatin(ZT)were detected in dormant shoot tips,vegetative shoot tips,developing leaf buds,and developing flower buds of lotus.The results indicated that GA,ETH,and BR signaling can promote vegetative and reproductive development of lotus.GA signaling regulates plant height and stimulates flower bud differentiation.GA levels were the highest in the flower buds;exogenous GA3+4 increased plant height by approximately 90%,increased flower quantity by nearly 40%,and advanced flowering by 4 d.Suppressing GA biosynthesis using paclobutrazol decreased plant height and flower quantity by 38%and 87.1%,respectively,and delayed flowering by 15.6 d.ETH signaling has positive regulatory effects on vegetative growth and flower development.The ETH concentration in the developing leaf buds was at least 50%higher than that in other samples.Ethephon spraying led to remarkable increases in plant height and leaf thickness and extended the flowering duration.BR signaling acts as a growth promoter during vegetative and reproductive development in lotus.The highest BR levels were detected in the vegetative shoot tips.External application of28-epihomobrassinolide resulted in growth-promoting phenotypes including longer scapes,thicker leaves,and prolonged flowering.
基金This work was supported by the National Natural Science Foundation of China[Grant Nos.31870686,31971705,and 31670693]the Natural Science Foundation of Shanghai[Grant No.21ZR1434200].
文摘Dehydrins(DHNs),as members of the late embryogenesis abundant protein family,play critical roles in the protection of seeds from dehydration and plant adaptation to multiple abiotic stresses.Vitrification is a basic method in plant cryopreservation and is characterized by forming a glassy state to prevent lethal ice crystals produced during cryogenic storage.In this study,ApSK3 type DHN was genetically transformed into embryogenic calluses(EC)of Agapanthus praecox by overexpression(OE)and RNA interference(RNAi)techniques to evaluate the in vivo protective effect of DHNs during cryopreservation.The cell viability showed a completely opposite trend in OE and RNAi cell lines,the cell relative death ratio was decreased by 20.0%in ApSK3-OE EC and significantly increased by 66.15%in ApSK3-RNAi cells after cryopreservation.Overexpression of ApSK3 increased the content of non-enzymatic antioxidants(AsA and GSH)and up-regulated the expression of CAT,SOD,POD,and GPX genes,while ApSK3-RNAi cells decreased antioxidant enzyme activities and FeSOD,POD,and APX genes expression during cryopreservation.These findings suggest that ApSK3 affects ROS metabolism through chelating metal ions(Cu^(2+)and Fe^(3+)),alleviates H_(2)O_(2)and OH·excessive generation,activates the antioxidant system,and improves cellular REDOX balance and membrane lipid peroxidation damage of plant cells during cryopreservation.DHNs can effectively improve cell stress tolerance and have great potential for in vivo or in vitro applications in plant cryopreservation.
