In order to investigate a better soilless culture medium and the possibility of grass clippings as alternative substrate for peat moss to grow Begonia cucullata Willd. in pots, the seedlings of widely cultivated B. cu...In order to investigate a better soilless culture medium and the possibility of grass clippings as alternative substrate for peat moss to grow Begonia cucullata Willd. in pots, the seedlings of widely cultivated B. cucullata were grown in pots with eight types of soilless substrates: T1(peat: perlite=1:1), T2(peat: perlite: pine bark=1:1:1), T3(corn stover: perlite: pine bark=1:1:1), T4(corn stover: perlite: pine bark=2:1:1), T5(grass clipping: perlite: pine bark=1:1:1), T6(grass clipping: perlite:pine bark=2:1:1), T7(vermiculite: perlite: pine bark=1:1:1) and T8(vermiculite: perlite: pine bark=2:1:1), respectively, in a shade house of Shanghai Chenshan Botanical Garden to evaluate plant growth performance. The results showed that the stem diameter of B. cucullata increased significantly from day 30 to day 60 after potting,and the plant height, leaf number and leaf area increased largest from day 60 to day 90 after potting in all treatments. The growth of plants performed best in T6,with the highest branch number, leaf thickness, flower number, aboveground fresh and dry weights and relative chlorophyll content. Therefore, the substrate with grass clipping: perlite: pine bark=2:1:1 was the best culture medium for growing B. cucullata in this study, and the grass clippings could replace peat moss as alternative substrate for growing B. cucullata in containers.展开更多
为探明大王秋海棠(Begonia rex Putz.)在不同基质、不同激素,不同浓度影响下的生根和成苗情况,筛选出最适宜大王秋海棠的扦插繁殖方式。本试验分析了以基质、激素和浓度这3种因素交互的42个处理组,发现各处理组间生根率、生根质量、成...为探明大王秋海棠(Begonia rex Putz.)在不同基质、不同激素,不同浓度影响下的生根和成苗情况,筛选出最适宜大王秋海棠的扦插繁殖方式。本试验分析了以基质、激素和浓度这3种因素交互的42个处理组,发现各处理组间生根率、生根质量、成苗率、成苗质量差异较大,最终得出C9和C33两个多因素处理组生根成苗率最高,根壮苗强,即以蛭石为扦插基质蘸取200 mg/L NAA和珍珠岩+水苔=1∶1为扦插基质蘸取200 mg/L IBA,最适宜大王秋海棠的扦插繁殖。展开更多
The function of stomata in plants is controlling gas exchange and modulating water balance. The distribution pattern of stomata in most vascular plants follows a certain regulation with at least one normal epidermal c...The function of stomata in plants is controlling gas exchange and modulating water balance. The distribution pattern of stomata in most vascular plants follows a certain regulation with at least one normal epidermal cell between two stomata. However, some plants restricted in several genera of vascular plants have stomatal clusters in which more than one stoma is adjacently arranged with no epidermal cells among them. The developmental process of stomatal clusters in plants, especially in non-mutant (wild type) vascular plants, has rarely been documented, and very few studies concerning the distribution pattern of stomatal clusters on leaf epidermis have been carried out. We reported the developmental mechanism and distribution pattern of stomatal clusters in Begonia peltatifolia Li native to China. The results indicated that the clustered arrangement of meristemoids at the juvenile stage of the leaf development contributed greatly to the pattern of stomatal clusters. Additionally, satellite meristemoids derived from subsidiary cells around the mature stomata also had an impact on the development as well as the pattern of stomatal clusters. Regarding stomatal cluster and singly occurring stoma both as a stomatal unit, we found that the stomatal unit density (i.e., number of stomatal unit per area) increased gradually from the middle part to the edge and the apex of the leaf, while stomatal unit size (i.e., number of stomata per stomatal unit) decreased. The possible reason of this pattern was discussed.展开更多
Begonia, one of the most diverse plant taxa and the fifth or sixth largest angiosperm genus, consists of over1800 accepted species. The number of species recognized within this genus has greatly increased over the pas...Begonia, one of the most diverse plant taxa and the fifth or sixth largest angiosperm genus, consists of over1800 accepted species. The number of species recognized within this genus has greatly increased over the past 20 years, rising from 80 to 200 species in China alone. Based on recent field surveys, the number of begonia species in China is predicted to be between 250 and 300. Given the large number of begonia species that still remain to be described, further taxonomical work is urgently required. This is especially true for Chinese Begonia, in which there is a huge diversity of habitat, habit, plant size, leaf type, flower and fruit morphology, and most species are narrowly distributed in isolated habitats that are subject to negative disturbances from climate change, as well as agricultural and industrial activities. Although the conservation status for the majority of species has been evaluated using the standards of the International Union for Conservation of Nature, the results don't represent the truth in many species, and also about11.5% of which are data-absent. In addition, illegal collection and over-harvesting of wild begonias for ornamental or medicinal use has increased due to the rapid development of internet commerce. Far more often than predicted, these species should be categorized as rare and endangered and require immediate protection. Ex situ conservation of Chinese begonias started in 1995 and over 60% of the total species have been so far introduced into cultivation by several major botanical gardens in China. However, only few research institutions, limited funds and human resources have been involved in Begonia conservation;moreover, no project has conducted reintroduction. Therefore, more conservation-based work remains to be done. Improved conservation of Chinese begonias in the future depends on further field survey, an improved understanding of population diversity, and integrative approaches, including in situ and ex situ conservation, seed banking, and plant reintroduction. Species-targeted conservation zones should be established for endangered species excluded from the existing nature reserves. Additionally, laws pertaining to plant protection should be extended to prevent the illegal collection and transaction of wild plants, particularly for those species with unique habitats and small populations.展开更多
基金Supported by the Science and Technology Project of Shanghai Municipal Greening and City Appearance Administration(F112421)Foundation of Science and Technology Commission of Shanghai Municipality(14DZ2260400)Environmental Protection Science and Technology Project of Hunan Province(XCJZ[2012]347,XCJZ[2013]229)~~
文摘In order to investigate a better soilless culture medium and the possibility of grass clippings as alternative substrate for peat moss to grow Begonia cucullata Willd. in pots, the seedlings of widely cultivated B. cucullata were grown in pots with eight types of soilless substrates: T1(peat: perlite=1:1), T2(peat: perlite: pine bark=1:1:1), T3(corn stover: perlite: pine bark=1:1:1), T4(corn stover: perlite: pine bark=2:1:1), T5(grass clipping: perlite: pine bark=1:1:1), T6(grass clipping: perlite:pine bark=2:1:1), T7(vermiculite: perlite: pine bark=1:1:1) and T8(vermiculite: perlite: pine bark=2:1:1), respectively, in a shade house of Shanghai Chenshan Botanical Garden to evaluate plant growth performance. The results showed that the stem diameter of B. cucullata increased significantly from day 30 to day 60 after potting,and the plant height, leaf number and leaf area increased largest from day 60 to day 90 after potting in all treatments. The growth of plants performed best in T6,with the highest branch number, leaf thickness, flower number, aboveground fresh and dry weights and relative chlorophyll content. Therefore, the substrate with grass clipping: perlite: pine bark=2:1:1 was the best culture medium for growing B. cucullata in this study, and the grass clippings could replace peat moss as alternative substrate for growing B. cucullata in containers.
文摘The function of stomata in plants is controlling gas exchange and modulating water balance. The distribution pattern of stomata in most vascular plants follows a certain regulation with at least one normal epidermal cell between two stomata. However, some plants restricted in several genera of vascular plants have stomatal clusters in which more than one stoma is adjacently arranged with no epidermal cells among them. The developmental process of stomatal clusters in plants, especially in non-mutant (wild type) vascular plants, has rarely been documented, and very few studies concerning the distribution pattern of stomatal clusters on leaf epidermis have been carried out. We reported the developmental mechanism and distribution pattern of stomatal clusters in Begonia peltatifolia Li native to China. The results indicated that the clustered arrangement of meristemoids at the juvenile stage of the leaf development contributed greatly to the pattern of stomatal clusters. Additionally, satellite meristemoids derived from subsidiary cells around the mature stomata also had an impact on the development as well as the pattern of stomatal clusters. Regarding stomatal cluster and singly occurring stoma both as a stomatal unit, we found that the stomatal unit density (i.e., number of stomatal unit per area) increased gradually from the middle part to the edge and the apex of the leaf, while stomatal unit size (i.e., number of stomata per stomatal unit) decreased. The possible reason of this pattern was discussed.
基金supported by the funds from National Natural Science Foundation of China (31570199)the project of Shanghai Landscaping Administration Bureau (F122416)
文摘Begonia, one of the most diverse plant taxa and the fifth or sixth largest angiosperm genus, consists of over1800 accepted species. The number of species recognized within this genus has greatly increased over the past 20 years, rising from 80 to 200 species in China alone. Based on recent field surveys, the number of begonia species in China is predicted to be between 250 and 300. Given the large number of begonia species that still remain to be described, further taxonomical work is urgently required. This is especially true for Chinese Begonia, in which there is a huge diversity of habitat, habit, plant size, leaf type, flower and fruit morphology, and most species are narrowly distributed in isolated habitats that are subject to negative disturbances from climate change, as well as agricultural and industrial activities. Although the conservation status for the majority of species has been evaluated using the standards of the International Union for Conservation of Nature, the results don't represent the truth in many species, and also about11.5% of which are data-absent. In addition, illegal collection and over-harvesting of wild begonias for ornamental or medicinal use has increased due to the rapid development of internet commerce. Far more often than predicted, these species should be categorized as rare and endangered and require immediate protection. Ex situ conservation of Chinese begonias started in 1995 and over 60% of the total species have been so far introduced into cultivation by several major botanical gardens in China. However, only few research institutions, limited funds and human resources have been involved in Begonia conservation;moreover, no project has conducted reintroduction. Therefore, more conservation-based work remains to be done. Improved conservation of Chinese begonias in the future depends on further field survey, an improved understanding of population diversity, and integrative approaches, including in situ and ex situ conservation, seed banking, and plant reintroduction. Species-targeted conservation zones should be established for endangered species excluded from the existing nature reserves. Additionally, laws pertaining to plant protection should be extended to prevent the illegal collection and transaction of wild plants, particularly for those species with unique habitats and small populations.