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Eun Ji Bae,NaRae Han,Byoung Woon Kim,Haeyoung Na 한국육종학회 2014 한국육종학회 심포지엄 Vol.2014 No.07
Investigation of flowing time, flower structure, microspore density, microspore vitality and microspore-derived embryo (MDE) formation rate according to the light quality treatment on broccoli donor plant was accomplished. The material was 08-8-3 line yielding high MDE production rate having 4.0 ± 0.5 mm flower bud length. The donor plant was cultivated with light quality treatment of red LED light, red+blue+white LED light and fluorescent light. The light intensity was 50 μ molm-2s-1 and photoperiod was 16/8 hours (light/dark). The flowering time was fastest at red LED light treatment compared to the other light treatment condition. 100.0, 36.4 and 18.2% of flower bud with longer stigma length than floral leaf which reported high MDE production rate were found under red LED light, Red+Blue+White LED light and fluorescent lights respectively. The microspore density and MDE production rate per single flower bud was highest at Red LED light. Suitable flower bud and high MDE production rate could be achieved in a short period if using LED light to broccoli donor plant cultivation. The above result is thought to be very useful for the development of a new cultivar of broccoli and other many crops including Brassica using haploid breeding technology. This journal was supported by the National Research Foundation
Induction of Microspore-derived Embryos According to Heat Shock, Dark Incubation, and Washing Medium
Yeon Kyeong Kim,Sung Un Kim,NaRae Han,Eun Ji Bae,Byoung Woon Kim,Haeyoung Na 한국육종학회 2014 한국육종학회 심포지엄 Vol.2014 No.07
Heat shock pretreatment, dark culture period and washing medium could have marked effects on microspore embryogenesis. A heat shock pretreatment of microspores at 32.5°C for 48 hours gave high production rate of microspore-derived embryo (MDE) when compare to shorter and longer period. The yield of MDE increased significantly when microspore cultured for 15 days at 25℃ in dark condition followed by heat shock pretreatment. MDE were browned and lost vitality when dark treatment period extended longer than 15 days. This is caused by an insufficient oxygen and light for growing embryo which already formed during dark treatment period. The vitality of a microspore isolated from flower bud stored at 4℃ become decreased at the very first day and the vitality of microspore stored at 4℃ in the form of flower bud itself become decreased from the 5th day after storage. This shows the possibility of getting a certain period of storage for a suitable flower bud in MDE formation. The yield of MDE was most effective when isolated microspore was had with MS medium compared to B-5 and NLN medium and also showed most effective result with sucrose 130 gL-1 in additional sucrose concentration. The above result is thought to be very useful for the development of a new cultivar of radish and other many crops including Brassica using haploid breeding technology.
Narae Han,Jiwoong Wi,Sungoh Im,Ka-Min Lim,Hun-Dong Lee,Won-Joong Jeong,Geun-Joong Kim,Chan Song Kim,Eun-Jeong Park,Mi Sook Hwang,최동욱 한국조류학회I 2021 ALGAE Vol.36 No.3
An increase in seawater temperature owing to global warming is expected to substantially limit the growth of marine algae, including Pyropia yezoensis, a commercially valuable red alga. To improve our knowledge of the genes involved in the acquisition of heat tolerance in P. yezoensis, transcriptomes sequences were obtained from both the wild-type SG104 P. yezoensis and heat-tolerant mutant Gy500. We selected 1,251 differentially expressed genes that were up- or downregulated in response to the heat stress condition and in the heat-tolerant mutant Gy500, based on fragment per million reads expression values. Among them, PyHRG1 was downregulated under heat stress in SG104 and expressed at a low level in Gy500. PyHRG1 encodes a secretory protein of 26.5 kDa. PyHRG1 shows no significant sequence homology with any known genes deposited in public databases to date. However, PyHRG1 homologs were found in other red algae, including other Pyropia species. When PyHRG1 was introduced into the single-cell green alga Chlamydomonas reinhardtii, transformed cells overexpressing PyHRG1 showed severely retarded growth. These results demonstrate that PyHRG1 encodes a novel red algae-specific protein and plays a role in heat tolerance in algae. The transcriptome sequences obtained in this study, which include PyHRG1, will facilitate future studies to understand the molecular mechanisms involved in heat tolerance in red algae.