본 연구는 원통형 종이포트를 활용한 토마토 육묘시, 염스트레스를 활용하여 고온기 도장 억제가능성을 검토하기 위하여 수행되었다. 시험구는 K2SO4, KCl과 KH2PO4을 각 5, 10 dS·m-1로 처리하였고, 또한, 토마토 모종에 고염도의 칼륨을 처리하여 수분 및 저온스트레스 환경에서의 적응성 및 생존성을 조사하였다. 조사결과, 처리 농도가 높아질수록 지상·지하부 건물중, 옆면적, 순동화율 (NAR)이 감소하고, 경경과 충실도는 증가하였다. 수분 스트레스 처리 이후, 대조구는 심한 위조현상을 보였지만, KCl처리구는 양호하였다. 상대수분함량은 대조구에서 23%, KCl처리구에서 8% 감소 하였다. 또한, 대조구에 비하여 KCl 처리구는 저장시(9, 12 및 15°C) 모종의 손상 비율이 낮았다. 이와 같은 결과로 보아, KCl과 같은 고농도의 칼륨 처리가 원통형 종이포트 토마토 육묘의 도장 억제에 효과적이며 환경 스트레스 내성을 향상시키는 것으로 판단된다.
선박이나 컨테이너로 수출입되는 곡류 및 박류는 검역용 훈증제인 메틸브로마이드(이하 MB)와 인화수소(이하 PH3)를 사용하는데, 처리 온도/수용비/선적방식에 따라 충분한 배기시간을 필요로 한다. 현장에서 배기시간 미설정으로 검역관 및 방제기술자에게 훈증제 TLV(Threshold Limit Value)-TWA(Time Weighted Average) 기준 이상의 농도에 노출될 위험이 있으므로, 소독 전, 후 작업자 안전을 고려하여 각 훈증제 별 작업자 안전기준에 적합한 배기시간이 설정되어야 한다. 따라서, 실내 훈증상에서 곡류(쌀, 대두) 및 박류(대두박, 주정박)를 대상으로 현행 소독처리기준으로 소독 후 탈착되는 가스농도를 측정해 MB 1 ppm, PH3 0.3 ppm 수준 이하로 감소되는 배기시간을 조사하였다. 조사결과 TLV-TWA 기준이하의 수준으로 감소되는데 필요한 배기시간은 주정박/대두박/대두에 MB가 처리된 경우는 모두 30시간, 쌀에 PH3가 처리된 경우는 30분이 소요되는 것을 확인하였다.
Background : This study was conducted to determine the impact of temperature elevated and the effect of transplanting times based on climate change scenario on growth of 2-year-old korean ginseng (Panax ginseng C. A. Meyer.) in temperature gradient chambers (TGC). Methods and Results : As a plant materials, ‘Yunpoong’ was cultivated in TGC at ambient temperature(Amb), Amb+2℃, Amb+4℃ and Amb+6℃ respectively. Ginseng was also transplanted on March 29, April 12 and 26 respectively. Investigation on characteristic of aerial parts were carried out on 28, 56, 84 and 112 days after transplanting and characteristic of roots were conducted on October 19. As transplanting time was faster and temperature was higher, the growth of aerial parts were increased. Compared with those of ginseng transplanted on March 29 with Amb, the root weight which tend to decrease depending on late transplanting time and high temperature decreased about 11.1%, 35.4% and 42.4% in Amb+ 2℃, Amb+4℃ and Amb+6℃ respectively. Ginseng transplanted on April 12 and 26 decreased about 20.9%, 33.9% respectively. Conclusion : Consequently, the more transplanting time extend, the more quantity increased in all temperature treatment. So, it is possible to increase in quantity to advance transplanting time although high temperature will be caused by the climate change.
The transcriptomes of four ginseng accessions such as Cheonryang (Korean ginseng cultivar), Yunpoong (Korean ginseng cultivar), G03080 (breeding line of Korean ginseng), and P. quinquefolius (American ginseng) was characterized. As a result of sequencing, total lengths of the reads in each sample were 156.42 Mb (Cheonryang cultivar), 161.95 Mb (Yunpoong cultivar), 165.07 Mb (G03080 breeding line), and 166.48 Mb (P. quinquefolius). Using a BLAST search against the Phytozome databases with an arbitrary expectation value of 1E-10, over 20,000 unigenes were functionally annotated and classified using DAVID software, and were found in response to external stress in the G03080 breeding line, as well as in the Cheonryang cultivar, which was associated with the ion binding term. Finally, unigenes related to transmembrane transporter activity were observed in Cheonryang and P. quinquefolius, which involves controlling osmotic pressure and turgor pressure within the cell. The expression patterns were analyzed to identify dehydrin family genes that were abundantly detected in the Cheonryang cultivar and the G03080 breeding line. In addition, the Yunpoong cultivar and P. quinquefolius accession had higher expression of heat shock proteins expressed in Ricinus communis. These results will be a valuable resource for understanding the structure and function of the ginseng transcriptomes.
Previously, the wheat non-specific lipid transfer proteins (TaLTP), members of a small multigene family, appear to show a complex pattern of expression regulation. For further assessment of expression diversity of the TaLTP genes, we have attempted to evaluate their expression profiles of responses to abiotic stresses via the semi-quantitative RT-PCR method. The expression profiles revealed that the TaLTP genes in group A evidenced highly similar (but not identical) responses against abiotic stresses, whereas much differential expression pattern among genes in each group. The four promoters of TaLTP1, TaLTP7, and TaLTP10 of group A and TaLTP3 of group B were fused to a GUS reporter gene and the recombinant genes were introduced into Arabidopsis. The promoters of TaLTP1, TaLTP7 and TaLTP10 of group A, drove strong but various GUS expression in cotyledons, hypocotyls, epidemic and sub-epidemic cells of young shoots and leaves, floral organs as well as siliques. By contrast, the promoter of TaLTP3 just directed trace expression in cotyledons, young emerged leaves and epidemic cells of flower ovaries. The promoter of TaLTP1 directed the expression in root system whereas the promoters of TaLTP1 and TaLTP10 showed some degree of expression during seed development. The expression diversity of TaLTP genes suggests their multiple physiological functions, evidencing subfunctionalization over evolutionary time.