This work provides some evidences for the saponinproduction of Panax notoginseng callus by using biologi-cally active,wall-related oligosaccharins.In anappropriate concentration,three kinds of oligosaccharinsstimulate...This work provides some evidences for the saponinproduction of Panax notoginseng callus by using biologi-cally active,wall-related oligosaccharins.In anappropriate concentration,three kinds of oligosaccharinsstimulated saponin formation or callus growth.Theconcentration of DO,GO and CO for saponin productionof Panax notoginseng callus culture were 15ppm,15ppmaud 20ppm respectively by comparing saponin yield.Itwas very obvious for DO to increase saponin contentwhen the concentration was 10ppm,and for GO tostimulate callus growth when the concentration was20ppm.It would be a good way to produce saponin byusing oligosaccharins in large scale culture in thefuture.展开更多
Oligosaccharins are potent biomolecules which activate defense responses and resistance in tobacco plants. However, it is not known the systemic behavior of defensive enzymes activated by these elicitors. In this work...Oligosaccharins are potent biomolecules which activate defense responses and resistance in tobacco plants. However, it is not known the systemic behavior of defensive enzymes activated by these elicitors. In this work, the dynamic behavior of key defensive enzymes was evaluated in tobacco plant leaves previously treated through the roots with chitosan polymer (CH), chitosan (COS) and pectic (OGAS) oligosaccharides and Spermine (Sp). All macromolecules tested activated protein levels and defense enzymatic activity in tobacco leaves but with different response dynamics among them and depending on the biochemical variable evaluated. Defense response above control levels were detected since 12 hours after treatments and it consisted in a biphasic behavior with two peaks for PAL (EC 4.3.1.5) and β 1 - 3 glucanase (EC 3.2.1.6) enzymatic activities. The highest enzymatic levels for these enzymes were achieved at 48 hours in plantlets elicited with COS and at 72 hours for those plants treated with chitosan polymer, while the highest POD (EC 1.11.1.6) activity was detected with CH between 48 and 72 hours. These results demonstrated systemic defense activation by oligosaccharins in tobacco whose dynamic of defense response is affected by the kind of oligosaccharins tested. When applying OGAS by foliar spray on tobacco, systemic resistance against Phytoththora nicotianae was induced and plantlets were protected with the low concentration tested by 46% under the bioassays conditions performed. Moreover, enzymatic determinations on roots and leaves previous to plant-pathogen interaction showed increments above 30% of control levels for PAL and POD activities. It means that oligosaccharins activate local and systemic defense responses in plants in the absent of pathogen infection.展开更多
文摘This work provides some evidences for the saponinproduction of Panax notoginseng callus by using biologi-cally active,wall-related oligosaccharins.In anappropriate concentration,three kinds of oligosaccharinsstimulated saponin formation or callus growth.Theconcentration of DO,GO and CO for saponin productionof Panax notoginseng callus culture were 15ppm,15ppmaud 20ppm respectively by comparing saponin yield.Itwas very obvious for DO to increase saponin contentwhen the concentration was 10ppm,and for GO tostimulate callus growth when the concentration was20ppm.It would be a good way to produce saponin byusing oligosaccharins in large scale culture in thefuture.
文摘Oligosaccharins are potent biomolecules which activate defense responses and resistance in tobacco plants. However, it is not known the systemic behavior of defensive enzymes activated by these elicitors. In this work, the dynamic behavior of key defensive enzymes was evaluated in tobacco plant leaves previously treated through the roots with chitosan polymer (CH), chitosan (COS) and pectic (OGAS) oligosaccharides and Spermine (Sp). All macromolecules tested activated protein levels and defense enzymatic activity in tobacco leaves but with different response dynamics among them and depending on the biochemical variable evaluated. Defense response above control levels were detected since 12 hours after treatments and it consisted in a biphasic behavior with two peaks for PAL (EC 4.3.1.5) and β 1 - 3 glucanase (EC 3.2.1.6) enzymatic activities. The highest enzymatic levels for these enzymes were achieved at 48 hours in plantlets elicited with COS and at 72 hours for those plants treated with chitosan polymer, while the highest POD (EC 1.11.1.6) activity was detected with CH between 48 and 72 hours. These results demonstrated systemic defense activation by oligosaccharins in tobacco whose dynamic of defense response is affected by the kind of oligosaccharins tested. When applying OGAS by foliar spray on tobacco, systemic resistance against Phytoththora nicotianae was induced and plantlets were protected with the low concentration tested by 46% under the bioassays conditions performed. Moreover, enzymatic determinations on roots and leaves previous to plant-pathogen interaction showed increments above 30% of control levels for PAL and POD activities. It means that oligosaccharins activate local and systemic defense responses in plants in the absent of pathogen infection.
