화이트 클로버에서 마이코라이자 접종이 가뭄스트레스와 관련된 생리학적 요인들을 조사하기 위하여, 마이코라이자 접종 (AM) 또는 비접종구에서 정상관수 (WW) 또는 가뭄 스트레스 처리 (DS)하여 7일동안 주기적으로 잎 수분포텐셜, 상대수분함량, 건물중, 광합성효율, 증산, 기공전도성, 프롤린 및 암모니아 함량을 각각 측정하였다. 모든 조사항목에서 정상적인 관수조건 (대조구)에서는 전 시험기간 중 변화가 매우 적었으며, 마이코라이자 접종에 의한 변화도 매

Seedling drought resistance of three alfalfa cultivars-Medicago sativa L. cv. Aohan, Medicago sativa L. cv. Zhaodong and Medicago sativa L. cv. Tumu No.2 were studied and evaluated. The permeability of plasma membrane, the free proline content and the peroxidase (POD) activity of three alfalfa cultivars were tested at 24h after treating with 20% polyethylene glycol (PEG-6000). The results indicated t㏊t the drought resistance ability of all these varieties was in the order of Medicago sativa L. cv. Aohan, Medicago sativa L. cv. Zhaodong and Medicago sativa L. cv. Tumu No.2.

저온 또는 건조 처리에 따른 토마토 유묘의 생육과 부위별 항산화효소의 반응 양상을 분석한 결과, 토마토 유묘의 생체중은 처리 후 12일째에 대조구에 비해 각각 69.5% 와 50.6% 감소하였다. SOD와 POD의 활성은 대조구에 비해 저온 또는 건조 처리에서 높은 활성을 보였는데, 저온 처리시에는 뿌리에서 더 높은 활성을 보였고 건조 처리에서는 잎과 줄기에서 높은 활성을 보였다. 이러한 결과는 동위효소의 발현양상에서도 일치하였다. GR의 활성은 저온 또는 건조 처리시 대조구보다 높은 활성을 보였는데, 잎과 줄기에서는 저온과 건조 처리간의 차이는 없었지만, 뿌리에서는 건조 처리가 높은 경향을 보였다. GR 동위효소 발현양상은 저온과 건조처리시에는 GR-3 밴드가 잎에서는 발현되어 대조구와 차이가 있었지만, 줄기와 뿌리에서는 큰 차이가 없었다. PPO 활성은 잎에서는 모든 처리에서 차이가 없었지만, 줄기와 뿌리에서는 저온 또는 건조 처리에서 대조구보다 높은 경향을 보였다. 특히 줄기의 PPO 활성은 저온 처리보다 건조처리에서 높았고 뿌리의 PPO 활성은 건조 처리보다 저온 처리에서 높았다. 동위효소의 발현양상에서도 건조처리에서는 줄기에서, 저온 처리에서는 뿌리에서 높은 밀도를 보여 불량 환경에 따른 부위별 반응 차이를 잘 반영해 주었다.

Drought stress is one of major environmental stresses in plants; this leads to reduce plant growth and crop yield. In this study, we selected fungal isolate for mitigating drought stress in pepper plants. To do this, 41 fungi were isolated from rhizosphere or bulk soils of various plants in Jeju, Gangneung, Hampyeong in Korea. Out of 41 isolates, we screened two isolates without phytotoxicity through seed germination of tomato, pepper, and cabbage treated with fungal spores; through following plant assay, we selected GL02 as a candidate for alleviating drought stress in pepper plants. As a result of greenhouse test of pepper plants in drought condition, the stomatal conductance on leaves of pepper plants treated with GL02 was increased, whereras the malondialdehyde (MDA) and electrolyte leakage were decreased compared to that in control plants. When stressed plants were rewatered, stomatal conductance of the plants treated with GL02 was increased; the electrolyte leakage was decreased. Based on internal transcribed spacer (ITS) sequencing analysis, isolate GL02 was belonging to genus Trichoderma. Taken together, drought stress in pepper plants treated with GL02 was alleviated, when it was rewatered after drought-stressed, the plants could be recovered effectively. Therefore, Trichoderma sp. GL02 could be used as a bio-fertilizer to alleviate drought stress in pepper plants.

Chinese cabbage grown during autumn season is confronted with drought conditions for a certain period, especially during the early growth stage. In this study, we investigated the effects of drought stress on plant growth characteristics, as well as free amino acid, carotenoid, and proline in Chinese cabbage. Chinese cabbage seeds (Bulam Plus) were germinated, and all the seedlings were transplanted into plastic containers (28 ㎝ diameter × 22 ㎝ high) containing a commercial growth medium. The soil water content was measured and maintained at 10% for the drought-stressed plants and at 30% for the control plants, for three weeks. The results revealed that plant growth parameters were lower in the drought-stressed plants than in the control plants. The total free amino acid content tended to decrease in both drought-stressed and control plants with time. The total free amino acid content was found to be lower in the drought-stressed plants than in the control plants and the proline content was unaffected. Moreover, at three weeks after treatment, carotenoid content in drought stressed plants was significantly higher than that in the untreated plants. We believe that our study makes a significant contribution to the literature because the effects of drought stress on plant growth parameters, free amino acid, carotenoids, and proline accumulation in autumn growing cultivar of Chinese cabbage have not been widely studied in Korea, and our study provides valuable information in this regard, as Chinese cabbage is consumed throughout the year in Korea.

Background: This study aimed to investigate out the influence of drought stress on the physiological responses of Dendropanax morbifera seedlings. Methods and Results: Drought stress was induced by discontinuing water supply for 30 days. Under drought stress, photosynthetic activity was significantly reduced with decreasing soil water content (SWC), as revealed by the parameters such as Fv/Fm, maximum photosynthetic rate (PN max), stomatal conductance (gs), stomatal transpiration rate (E), and intercellular CO2 concentration (Ci). However, water use efficiency (WUE) was increased by 2.5 times because of the decrease in gs to reduce transpiration. Particularly, E and gs were remarkably decreased when water was withheld for 21 days at 6.2% of SWC. Dendropanax morbifera leaves showed osmotic adjustment of −0.30MPa at full turgor and −0.13 MPa at zero turgor. In contrast, the maximum bulk modulus of elasticity (Emax) did not change significantly. Thus, Dendropanax morbifera seedlings could tolerate drought stress via osmotic adjustment. Conclusions: Drought avoidance mechanisms of D. morbifera involve reduction in water loss from plants, through the control of stomatal transpiration, and reduction in cellular osmotic potential. Notably photosynthetic activity was remarkably reduced, to approximately 6% of the SWC.

Yield of potato is largely influenced by drought stress. This study was conducted in Gangneung and Cheongju during the spring cropping of potato. Potatoes in the Gangneung area were affected by drought but there was no damage due to drought in Cheongju. During the early-growth stage, the contents of inorganic components like available phosphate and growth characteristics of the potato leaf in Cheongju were significantly higher than those in Gangneung but there was no difference after the flowering stage. It was considered that the potato plants cultivated in Cheongju could vigorously grow than that of Gangneung under drought stress. In addition, the content of calcium (Ca), which is a secondary messenger related to aging, was found to be higher in potato plants grown in Cheongju than in Gangneung and accumulated more quickly in potato plants of Cheongju. Because magnesium (Mg) was also found to be higher in potato plants from Gangneung by a wide margin, this phenomenon was thought be related with drought stress. The amounts of all inorganic components absorbed from soil were higher in Cheongju than in Gangneung, showing a relatively higher plant biomass in Cheongju. Correlations of development indexes related to leaf showed less or no relation in Gangneung. According to yield characteristics of the harvest stage, although yield was greatly reduced under drought stress condition, the rate of commercial yield was not significantly affected under the drought stress condition. Consequently, it was considered that these responses to drought stress could be utilized to stabilize potato production under the stressful conditions associated with abnormal climate.

Drought stress is a major agricultural limitation to crop productivity worldwide, especially by which leafy vegetables, plant leaves eaten as vegetable, could be more lethal. The study was carried out to know the effect of drought tolerance plant growth promoting bacteria (PGPB) on water stress of kale seedlings. A total of 146 morphologically distinct bacterial colonies were isolated from bulk soil and rhizosphere soil of leafy vegetables and screened for plant growth promoting microbioassay in greenhouse. Out of them the isolate SB19 significantly promoted the growth of kale seedlings in increasement of about 42% of plant height (14.1 ㎝), 148% of leaf area (19.0 ㎠) and 138% of shoot fresh weight (1662.5 ㎎) attained by the bacterially treated plants compared to distilled water treated control (9.9 ㎝, 7.7 ㎠, 698.8 ㎎). Shoot water content of SB19 treated kale seedlings (1393.8 ㎎) was also increased about 152% compared with control (552.5 ㎎). The SB19 isolated from bulk soil of kale plant in Iksan, Korea, was identified as species of Bacillus based on 16S rRNA gene sequencing analysis. We evaluated the effect of drought tolerance by the Bacillus sp. SB19 on kale seedlings at 7th and 14th days following the onset of the water stress and watering was only at 7th day in the middle of test. In the survey of 7th and 14th day, there were mitigation effect of drought stress in kale seedlings treated with 106 and 107 cell mL-1 of SB19 compared to distilled water treated control. Especially, there were more effective mitigation of drought damage in kale seedlings treated with 107 cell mL-1 than 106 cell mL-1. Further, although drought injury of bacterially treated kale seedlings were not improved at 14th day compared with 7th day, drought injury of 107 cell mL-1 of SB19 treated kale seedlings were not happen rapidly but developed over a longer period of time than 106 cell mL-1 of SB19 or control. The diffidence of results might be caused by the concentration of bacterial suspension. This study suggests that beneficial plant-microbe interaction could be a important role of enhancement of water availability and also provide a good method for improving quality of leafy vegetables under water stress conditions.

Wheat-rye translocation lines are widely used in wheat breeding programmes by reason of biotic stress tolerances. Though there have been a number of researches regarding abiotic stress tolerance, the tolerance of the lines depends on wheat genetic background, not on rye chromosome. Here, we investigated wheat-rye translocation specific transcripts derived from cDNA-AFLP under drought stress, which may help to elucidate the reaction under the stress. ‘OK91G117’ (1BL.1RS translocation) and ‘OK91G144’ (non-translocation) were used as materials, which are near-isolines for 1RS. 25% PEG 6000 was added in culture solution to simulate drought condition and root tissues were sampled at each 0 h, 3 h, 6 h, 12 h, 24 h, and 48 h after PEG treatment for RNA extraction. As a result of cDNA-AFLP, TDFs (transcript derived fragments) that were specific to OK91G117 were sequenced. GO functions of each sequenced TDF were annotated by Blast2GO using standard parameter with cut-off level 3 and mapped to the GO term (i.e. biological process; BP, molecular function; MF, cellular component; CC). The term with “organic substance metabolic process”, “primary metabolic process”, and “cellular metabolic process” account for almost 50 % of BP. The most represented terms among probes classified to MF were “transferase activity” and most of TDF were annotated in “cell part” of CC. In addition, rye-chromatin specific markers were developed by BLAST comparing sequence of TDF with wheat and rye genome data. RT-PCR was conducted to validate expression patterns of selected TDF. Further studies will be needed to elucidate functions of the highly expressed genes under drought stress.

Several E3 ubiquitin ligases have been associated with the response to abiotic and biotic stresses in higher plants. Here, we report that the hot pepper (Capsicumannuum) abscisic acid (ABA)-InsensitiveRINGprotein1gene(CaAIR1) is essential for a hypersensitive response to drought stress. CaAIR1 contains a C3HC4-type RING finger motif, which plays a role for attachment of ubiquitins to the target protein, and a putative transmembrane domain. The expression levels of CaAIR1 are upregulated in pepper leaves by ABA treatments, drought, and NaCl, suggesting its role in the response to abiotic stress. Our analysis showed that CaAIR1 displays self-ubiquitination and localized in the nucleus. We generated CaAIR1-silenced peppers via virus-induced gene silencing (VIGS) and CaAIR1-overexpressing (OX) transgenic Arabidopsis plants to evaluate their responses to ABA and drought. VIGS of CaAIR1 in pepper plants conferred an enhanced tolerance to drought stress, which was accompanied by low levels of transpirational water loss in the drought-treated leaves. CaAIR1-OX plants displayed an impaired sensitivity to ABA during seed germination, seedling, and adult stages. Moreover, these plants showed enhanced sensitivity to drought stress because of reduced stomatal closure and decreased expression of stress-responsive genes. Thus, our data indicate that CaAIR1 is a negative regulator of the ABA-mediated drought-stress tolerance mechanism.

Drought and high salinity are the most important abiotic factors limiting plant development, growth, and crop productivity in agriculture (Munns and Tester 2008, Sengupta and Majumder 2009, Zhu 2002). As sessile organisms, plants are frequently exposed to drought and high salinity conditions, which alter water potential and cause osmotic stress, leading to serious damage to plant tissues (Bartels and Sunkar 2005, Boudsocq and Lauriere 2005). During exposure to water stress, plants display many physiological changes, such as reduction of water content, closure of stomata, and decreased cell enlargement and growth. In addition, severe and continuous water stress in plants causes the cessation of photosynthesis and disturbance of metabolism, and finally results in death (Nath et al. 2005, Shao et al. 2008). To adapt to these abiotic stress conditions, plants show a variety of responses, including the accumulation of abscisic acid (ABA) and expression of a large number of stress-related proteins (Krasensky and Jonak 2012, Lee and Luan 2012, Skriver and Mundy 1990, Stewart and Lee 1974). Although the cellular and molecular responses to environmental stress are well studied (Hasegawa et al. 2000, Thomashow 1999), the mechanisms underlying the functional modifications caused by osmotic stress are yet to be clarified, because of the complexity at the cellular level as well as at the whole plant level (Ashraf and Harris 2004, Flowers 2004, Foolad et al. 2003a, 2003b, Xiong et al. 2002).

Understanding the response of a crop to water deficiency is the first step towards breeding drought-tolerant varieties. In this study, inbred maize (Zea mays L.) lines KS140 and KS141 were subjected to drought stress by withholding water for 10 days at the V5 or V6 leaf stage. Water-deficient plants experienced a decrease in relative leaf water content, stomatal conductance, net CO2 assimilation rate, and water use efficiency compared to well-watered plants. This was accompanied by a decrease in the relative leaf water content that resulted in severe growth retardation in KS140 and KS141. However, leaf chlorophyll content in KS140 was unchanged. To understand the proteome dynamics during the 10-day drought stress in maize leaves, comparative proteome analysis was carried out between the well-watered and water-withheld leaves. Differential expression was observed for 29 protein spots from KS140 and 14 protein spots from KS141, and these were identified using MALDI-TOF mass spectrometry. Among identified proteins, metabolism and stress related proteins were highly were increased by drought stress. This study provides a protein profile of a Korean maize inbred line during drought stress, which will be valuable for future studies of the molecular mechanisms underlying drought resistance and for development of selective breeding markers for drought tolerance in maize.

Steroidal glycoalkaloids which serve the plant defense, are toxic secondary metabolites present in the plants of solanaceae family. The upper safe limit of glycoalkaloids for human consumption is 20mg/KG FW, excess of which may cause severe health disorders. Several factors like drought, high temperature, light exposure, and wounding increase tuber glycoalkaloid content. Among these, drought is an important factor which causes a rapid increase in potato glycoalkaloid content. Glycoalkaloid biosynthetic genes and their expression pattern need to be characterized to regulate the glycoalkaloid accumulation. Three key genes SGT1, SGT2 and SGT3 are demonstrated to be directly participated in the biosynthetic pathway for glycoalkaloid formation. Present study was focused on the study of expression pattern of key genes in GA pathway under drought stress in two different potato cultivars Atlantic and Haryoung which are low and high glycoalkaloid accumulating respectively. Drought stress was imposed by withholding water to the plants grown in pots and control plants kept irrigated. Expression analysis of SGT1, SGT2 and SGT3 was done from the leaf and tuber sample of three time intervals i.e 5, 10 and 20 days after imposing stress. Variation in the expression level of genes was observed in leaf and tuber where the fold increase in expression over control was higher in tuber sample compared to leaf. Expression levels also varied in leaf and tuber among two cultivars. However, expression of SGT1, SGT2 and SGT3 is significant indicating the involvement of these genes in glycoalkaloid accumulation under drought stress.

Susceptible Vitis vinifera responds to Xylella infection with a massive redirection of gene transcription. This transcriptional response is characterized by increased transcripts for phenlypropanoid and flavonoid biosynthesis, ethylene production, adaptation to oxidative stress, and homologs of pathogenesis related (PR) proteins, and decreased transcripts for genes related to photosynthesis. In addition, the results suggest that susceptible genotypes respond to Xylella infection by induction of limited, but inadequate, defense response. We also compared the transcriptional and physiological response of plants treated by pathogen infection, low or moderate water deficit, or a combination of pathogen infection and water deficit. Although the transcriptional response of plants to Xylella infection was distinct from the response of healthy plants to moderate water stress, we observed synergy between water stress and disease, such that water stressed plants exhibit a stronger transcriptional response to the pathogen. This interaction was mirrored at the physiological level for aspects of water relations and photosynthesis, and in terms of the severity of disease symptoms and pathogen colonization, providing a molecular correlation of the classical concept with the disease triangle.

Abiotic environmental stresses cause serious economic losses in agriculture. These stresses include temperature extremes, high salinity and drought. We identified several drought stress-related novel/function unknown coding transcripts (transcription factors and functional genes) and non-coding transcripts (small noncoding transcripts such as microRNA and long noncoding transcripts) using the next generation sequencing method from rice (Oryza sativa L.), and have constructed databases of drought stress-related coding and noncoding transcripts. We used novel gene prediction programs for the selections. The expression level of the each gene was analyzed by real-time PCR. The results ended up the selection of 29 transcription factors, 6 microRNAs and 10 long noncoding RNAs. Currently, we are further characterizing these transcripts. We expect that this study could provide functional information of the drought stress-regulated novel genes, and relationships among novel coding and noncoding transcripts.

물 자원이 제한되거나 관수 설비가 갖추어지지 않은 곳에서 찰옥수수의 한발 피해를 줄이고자, 종실용 옥수수에 대한 수분 스트레스 경감 효과가 보고되어진 살리실산과 앱시식산의 처리 효과를 살펴보았다. 출웅기 9일 전부터 출웅 후 14일까지 관수를 중단하였으며, 생장조절제는 출웅기에 1회 처리하였다. 살리실산과 앱시식산의 처리 농도는 각각 0.5 mM과 0.1 mM이었다. 한발 처리에 의해 ASI가 3.0~3.3일 늘어났으며, 간장은 47~51 cm, 이삭장은 4.6~5.0 cm, 이삭경은 4.4~5.3 mm, 열수는 1.5~2.0개, 수량은 2.4~2.5 Mg/ha 줄었다. 살리실산과 앱시식산의 처리에 의한 한발 피해의 경감 효과는 뚜렷하지 않았다. 찰옥수수에 대한 살리실산과 앱시식산의 한해 경감 효과를 위해서는 수분 부족 스트레스를 받기 이전에 처리하거나, 저농도로 몇차례에 나누어 처리하는 것이 필요한 지에 대한 추후 검토가 필요하다.