The ovule is the most important reproductive organ in the pistil of phanerogamae. Camellia oleifera (Theaceae) is an important woody plant producing edible oil in southern China, and its embryo sac structure has a positive effect on seed breeding. In this study, the microstructure, ultrastructure and three‐dimensional structure of the ovule and embryo sac of C. oleifera were observed and described based on a combination of advanced microscopy techniques (SEM, TEM, CLSM). The ovule comprises the inner and outer integument. Large quantities of secretions in the micropylar canal exit and may participate in the guidance of the entry of the pollen tube into the embryo sac. The synergids have a dense cytoplasm, abundant organelles, and strong polarity. Little cytoplasm is present in the egg cell, yet there are many vacuoles. The center of the cell is taken up by a large vacuole, and the cytoplasm is pushed towards the edges to form obvious cytoplasmic cords. The two polar nuclei are large and conspicuous. The antipodal cells degenerate to fulfill a nutritional function.
Recent advances in using biological scaffolds for nanoparticle synthesis have proven to be useful for preparing various nanostructures with uniform shape and size. Proteins are significant scaffolds for generating various nanostructures partly because of the presence of many functional groups to recognize different chemistries. In this endeavor, cocosin protein, an 11S allergen, is prepared from coconut fruit and employed as a potential scaffold for synthesizing Mn3O4 materials. The interaction between protein and manganese ions is studied in detail through isothermal calorimetric titration. At increased scaffold availability, the Mn3O4 material adopts the exact hexamer structure of the cocosin protein. The electrochemical supercapacitive properties of the cocosin–Mn3O4 material are found to have a high specific capacitance of 751.3 F g–1 at 1 A g–1 with cyclic stability (92% of capacitance retention after 5000 CV cycles) in a three-electrode configuration. The Mn3O4//Mn3O4 symmetric supercapacitor device delivers a specific capacitance of 203.8 F g–1 at 1 A g–1 and an outstanding energy and power density of 91.7 W h kg–1 and 899.5 W kg–1, respectively. These results show that cocosin–Mn3O4 could be considered a suitable electrode for energy storage applications. Moreover, the cocosin protein to be utilized as a novel scaffold in protein–nanomaterial chemistry could be useful for protein-assisted inorganic nanostructure synthesis in the future.
Bcakground The dry root and rhizome of Salvia miltiorrhiza are used to treat cardiovascular diseases, chronic pain, and thoracic obstruction over 2000 years in Asian countries. For high quality, Sichuan Zhongjiang is regarded as the genuine producing area of S. miltiorrhiza. Given its abnormal pollen development, S. miltiorrhiza from Sichuan (S.m.-SC) relies on root reproduction and zymad accumulation; part of diseased plants present typical viral disease symptoms and seed quality degeneration. This study aim to detected unknown viruses from mosaic-diseased plants and establish a highly efficient virus-free regeneration system to recover germplasm properties. Results Tobacco mosaic virus (TMV) and cucumber mosaic virus (CMV) were detected from mosaic-diseased plants. Primary apical meristem with two phyllo podium in 0.15–0.5 mm peeled from diseased plants were achieved 73.33% virus-free rate. The results showed that the medium containing MS, 0.5 mg/L 6-BA, 0.1 mg/L NAA, 0.1 mg/L GA3, 30 g/L sucrose and 7.5 g/L agar can achieve embryonic-tissue (apical meristem, petiole and leaf callus) high efficient organogenesis. For callus induction, the optimal condition was detected on the medium containing MS, 2 mg/L TDZ, 0.1 mg/L NAA by using secondary petiole of virus-free plants under 24 h dark/d condition for 21 d. The optimal system for root induction was the nutrient solution with 1/2 MS supplemented with 1 mg/L NAA. After transplant, the detection of agronomic metric and salvianolic acid B content confirmed the great germplasm properties of S.m.-SC virus-free plants. Conclusions A highly efficient virus-free regeneration system of S.m.-SC was established based on the detected viruses to recover superior seed quality. The proposed system laid support to control disease spread, recover good germplasm properties in S.m.-SC.
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