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209. 杂交大豆苗期对干旱胁迫的生理响应.

Author

杨玉花, 雷阳, 白志元, 陈妍, 张海平, and 张瑞军

Subjects
*PHOTOSYNTHETIC rates, *MEMBERSHIP functions (Fuzzy logic), *CARBON dioxide, *DROUGHTS, *OSMOREGULATION, *HYDROPONICS, *SOYBEAN
Abstract

【Objective】The present paper aimed to understand the difference of drought resistance among hybrid soybean varieties, thus to select drought tolerant hybrid soybean varieties.【Method】3 hybrid soybean varieties were used as experimental materials and different concentrations of PEG-6000 solution (5%,10% and 20%) hydroponic model were used to simulate drought stress in soybean seedling stage. To identify the physiological response and drought resistance of 3 hybrid soybeans, chlorophyll content, photosynthetic physiological index, osmotic regulator content and antioxidant enzyme activity of leaves in seedling stage were measured after drought stress. 【Result】With the increasing concentration of PEG-6000 solution, there were significant differences in the related drought resistance indicators of the three hybrid soybeans and the growth of soybean seedlings was gradually significantly inhibited. The chlorophyll content of soybean seedlings was detected, and it was found that with the increase of PEG-6000 solution concentration, its content showed an upward trend, the most significant being dominant Hybrid soybean-A-5. In terms of photosynthetic physiological indexes of soybean seedlings, the variation trends of net photosynthetic rate (Pn), transpiration rate (Tr), intercellular carbon dioxide concentration (Ci) and stomatal conductance (Gs) of leaves of three hybrid soybean seedlings showed significant differences. The response of different soybean varieties to drought stress under different treatment conditions was analyzed. The results showed that soybean seedlings could respond to drought stress through osmoregulation and activating antioxidant defense system was analyzed.The content of each substance changed significantly with the increase of stress degree. There were also significant differences among different varieties. The order of drought resistance of 3 hybrid soybeans was obtained by comprehensive analysis of membership function value method, Hybrid soybean-A-5> Hybrid soybean No.6>Jindou 48.【Conclusion】 The photosynthesis inhibition, osmotic adjustment and antioxidant enzyme activities could respond to drought stress of 3 hybrid soybeans. The Hybrid soybean-A-5 can be used as a demonstration of drought resistant hybrid soybean to promotion and demonstration in Huanghuaihai Area. It also provides an important reference for drought resistant breeding of hybrid soybean in later stage. [ABSTRACT FROM AUTHOR]

Published
2022
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210. Morphological, Physiological, Biochemical and Molecular Facet of Drought Stress in Horticultural Crops.

Author

Kumar, R., Berwal, M. K., and Saroj, P. L.

Subjects
DROUGHT management, LEAF morphology, POMEGRANATE, ROOT development, DROUGHTS, DEFOLIATION, DROUGHT tolerance, HORTICULTURAL crops
Abstract

Water stress disrupts horticultural crop growth, development and finally results in low productivity particularly in arid and semi arid parts of the world. Plants require certain physical, chemical and biological factors for their growth and development. Any deviation from these factors may cause aberrant metabolic changes and plant experience a tension known as stress. Water stresses trigger a wide variety of plant responses, ranging from altered gene expression and cellular metabolism to changes in plant growth, leaf morphology and movement and root development and finally productivity. Drought stress modifies photosynthetic rate, relative water content, leaf water potential, and stomatal conductance. Finally, it destabilizes membrane structure and permeability, protein structure and function, leading to cell death. Drought tolerant plants possess various mechanisms like reduction in water loss by reducing stomatal conductance or morphological modification, improving water uptake by developing efficient root systems and accumulation of osmolytes. Management practices employed for drought stress management in horticultural crops include use of drought tolerant crop varieties, use of tolerant root stocks, canopy management, wind breaks, regulated deficit irrigation and partial root zone drying, uses of anti-transpirants etc. The varieties selected should have deep root system (bael, ber), leaf shedding (ber, lasoda, pomegranate), thorns on stem (ker, karonda, ber), stomata at lower side (custard apple), wax coating (ber), thin foliage and leaf orientation (aonla), hair on leaf and sunken stomata (fig, phalsa, ber and lasoda). This paper elaborates physiological, biochemical and molecular mechanism of drought tolerance along with drought stress management in horticultural crops. [ABSTRACT FROM AUTHOR]

Published
2019
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211. 干旱胁迫下水杨酸对桔梗种子萌发及植物激素的影响.

Author

孙晓春, 张惠惠, 黄文静, 杨俊英, 汪荔, and 唐志书

Subjects
SALICYLIC acid, PLANT hormones, GERMINATION, DROUGHTS, POLYETHYLENE glycol, CONTROL groups
Abstract

Copyright of Journal of Agricultural Science & Technology (1008-0864) is the property of Journal of Agricultural Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2019
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212. Intracellular localization of histone deacetylase HDA6 in plants.

Author

Kurita, Kazuki, Sakamoto, Yuki, Naruse, Sota, Matsunaga, Tomoko M., Arata, Hideyuki, Higashiyama, Tetsuya, Habu, Yoshiki, Utsumi, Yoshinori, Utsumi, Chikako, Tanaka, Maho, Takahashi, Satoshi, Kim, Jong-Myong, Seki, Motoaki, Sakamoto, Takuya, and Matsunaga, Sachihiro

Subjects
HISTONE deacetylase, HISTONES, CHIMERIC proteins, HISTONE acetyltransferase, HETEROCHROMATIC genes
Abstract

Histone modification is an important epigenetic mechanism in eukaryotes. Histone acetyltransferase and deacetylase regulate histone acetylation levels antagonistically, leading to dynamic control of chromatin structure. One of the histone deacetylases, HDA6, is involved in gene silencing in the heterochromatin regions, chromocenter formation, and metabolic adaptation under drought stress. Although HDA6 plays an important role in chromatin control and response to drought stress, its intracellular localization has not been observed in detail. In this paper, we generated transformants expressing HDA6-GFP in the model plant, Arabidopsis thaliana, and the crops, rice, and cassava. We observed the localization of the fusion protein and showed that HDA6-GFP was expressed in the whole root and localized at the nucleus in Arabidopsis, rice, and cassava. Remarkably, HDA6-GFP clearly formed speckles that were actively colocalized with chromocenters in Arabidopsis root meristem. In contrast, such speckles were unlikely to be formed in rice or cassava. Because AtHDA6 directly binds to the acetate synthesis genes, which function in drought tolerance, we performed live imaging analyses to examine the cellular dynamics of pH in roots and the subnuclear dynamics of AtHDA6 responding to acetic acid treatment. The number of HDA6 speckles increased during drought stress, suggesting a role in contributing to drought stress tolerance. [ABSTRACT FROM AUTHOR]

Published
2019
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213. Response of Germination Physiology of Cajanus cajan Seeds to Drought Stress: Comparison Between Karst Water and Allogenic Water Treatments.

Author

Fen, Huang, Yang, Cheng, and Jianhua, Cao

Subjects
PIGEON pea, GERMINATION, KARST research, WATER purification, DROUGHTS
Abstract

In this paper, responses of germination physiology of pigeon pea ( Cajanus cajan) seeds to drought stress in karst water environment and non-karst (allogenic) water environment were studied to explore the adaptability of pigeon pea to karst environment. The results showed that: (i) Under drought stress of 20% PEG-6000, the germination rate, vigor index, germination index and biomass of pigeon pea seeds on day 7 cultivated with karst water were all greater than that of the allogenic water treatment group, while the seed germination stress index was significantly smaller than that of the allogenic water treatment group, suggesting that karst water environment was more favorable to pigeon pea seed germination, (ii) Without drought stress, the malondialdehyde (MDA) and superoxide dismutase (SOD) activities of pigeon pea seeds cultivated with karst water were all smaller than that of the allogenic water group. However, under drought stress, the SOD activity was significantly higher than that of allogenic water group, suggesting pigeon pea SOD in karst water was able to more rapidly respond to external drought stress, and increase its own activity to reduce the damage to the plants. And (iii) with and without drought stress, the soluble protein level of the karst water group was higher than that of the allogenic water group, while the free amino acid level was lower than that of the allogenic water group. This difference was more significant with the presence of drought stress, suggesting that the karst water environment was more favorable to the accumulation of soluble proteins and thus produced larger biomass. Hence, pigeon pea is a tree species that is adapted to high-calcium, alkaline environments in karst areas, and is of great significance for the revegetation and rocky desertification control in mountainous karst areas. [ABSTRACT FROM AUTHOR]

Published
2015
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214. 气体信号分子在植物干旱胁迫下的调控作用及机制的研究进展.

Author

张杰, 陈彪, 马晓寒, 郭豪, and 许自成

Subjects
DROUGHT tolerance, CARBON monoxide, HYDROGEN sulfide, PLANT growth, PLANT development, ORIGIN of life
Abstract

Copyright of Journal of Agricultural Science & Technology (1008-0864) is the property of Journal of Agricultural Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2018
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220. Influence of drought stress and N addition on the gas exchange, biochemical and growth traits in Quercus ithaburensis.

Author

Bayar, Esra

Subjects
*DROUGHTS, *DROUGHT management, *WATER efficiency, *CLIMATE change, *OAK, *PHOTOSYNTHETIC pigments, *PHOTOSYNTHETIC rates
Abstract

Forest tree species are likely to be affected by drought due to global climate change. Drought and nitrogen (N) affect plant growth. Therefore, we should understand the mechanisms underlying the N availability and species response to drought for plant development. This paper had two objectives. First, it determined the effects of N addition on water potential, gas exchange parameters, soluble sugar and photosynthetic pigment content, leaf N concentration, and growth parameters under drought stress and well-watered conditions. Second, it searched the drought response of Quercus ithaburensis Decne. subsp. macrolepis (Kotschy) Hedge & Yaltırık seedlings under N conditions with drought stress. In a greenhouse, one-year-old seedlings were exposed to two drought stress and nitrogen addition and three drought cycles. Drought stress significantly reduced stem water potential, relative water content, net photosynthetic rate, stomatal conductance, transpiration rate, leaf area, root collar diameter, seedling height, shoot and root dry weight. On the other hand, it increased water use efficiency and soluble sugar content. N addition is effective on soluble sugar content and photosynthetic pigment content, and promoted leaf N concentrations. Nitrogen addition under well-watered conditions stimulated the growth of Q. ithaburensis seedlings. Drought stress changed the physiological response of Q. ithaburensis seedlings (decreased water potential, net photosynthetic rate, stomatal conductance, and transpiration rate) in the short term, although nitrogen addition under drought stress has not changed the decreasing trend overall. [ABSTRACT FROM AUTHOR]

Published
2022
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223. Sessile oak (Quercus petraea [Matt.] Liebl.) and its adaptation strategies in the context of global climate change: a review

Author

Černý Jakub, Špulák Ondřej, Kománek Martin, Žižková Eliška, and Sýkora Petr

Subjects
ecological demands, mitigation, mixed stands, drought stress, resilience, sustainable management, Forestry, SD1-669.5
Abstract

This paper provides characteristic and a comprehensive overview of the adaptation strategies of sessile oak (Quercus petraea [Matt.] Liebl.) in the context of global climate change (GCC). The GCC is primarily manifested by increasing air temperatures and changing precipitation distribution. It poses a significant challenge to tree species including sessile oak, affecting its capacity for adaptation and survival. Despite the challenge, sessile oak shows significant drought tolerance due to its deep-reaching root system, which allows the tree to use available water more efficiently. Other adaptive strategies include the establishment of mixed stands that increase the resilience and biodiversity of the ecosystem. Adjustments of stand density through tending interventions play a significant role, helping to improve the stress resistance of stands. Additionally, coppice forest cultivation is applied on extremely dry sites. The sessile oak is also significant for its ecological plasticity – its ability to thrive on versatile soil and climatic conditions makes it a promising tree species for future forest management. Mixed stands with sessile oak and other tree species can enhance the ecosystem services of forests and also increase their endurance to GCC events. However, sessile oak faces several challenges, including the increasing risk of damage from pests and pathogens that require targeted measures for its protection and sustainable cultivation. The literature review suggests that a comprehensive understanding of sessile oak’s ecological requirements and interactions with the environment is crucial for its successful adaptation to GCC and the formulation of effective strategies for its protection and use in forest management.

Published
2024
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226. 低场核磁共振分析聚乙二醇对萌发期水稻种子水分吸收的影响.

Author

杨洪伟, 张丽颖, 纪建伟, 王 成, 王晓冬, 宋 平, and 宋 鹏

Abstract

Water absorption is one of the major factors limiting rice seeds germination rate. It is very important to study the drought-tolerance mechanism of rice under drought stress, in order to improve the drought-tolerance capacity of rice and thereby increase the yield. In this paper, 2 varieties of rice seeds were placed in 10%, 20% PEG (polyethylene glycol) 6000 solution and control solution respectively, and moisture variation was analyzed with T2 relaxation spectrum and proton density weighted image of low field nuclear magnetic resonance (NMR) 0, 6, 22, 48, and 72 h later after seed germination. The influence of PEG solution on water absorption was studied, and the regression equation was deduced between relative moisture content and total signal amplitude of nuclear magnetic signal in this paper. The proton density weighted images obtained by the magnetic resonance imaging system can show the absorption and flow patterns of water during the germination of rice seeds directly. The germination test results showed that the drought resistance of H9710 is higher than that of LX1. The proton density weighted image results showed that water molecules enter the seed directly through cracks on the seed surface, and embryo absorbs water molecules and expands downwards firstly. After 24 h, the nutrient in the seeds flows to the seeds embryo to provide adequate nutrition for the growth of the radicle and germ. The seeds absorbed less water and the germination process was inhibited obviously under PEG stress, and the higher the PEG mass fraction, the less the water absorption and the slower the germination process. This is consistent with the results of T2 relaxation spectrum detection. Based on the theory of NMR and multicomponent characteristics of T2 relaxation spectrum, when inversion frequency was 10000 times, the water in rice seeds during germination was categorized into 2 phases, which were short relaxation time standing for bound water and long relaxation time standing for free water. The T2 relaxation spectrum results suggested that the amplitude of NMR signals of the bound water, that of the free water and the total amplitude all increased gradually. The drought tolerance of rice seeds is closely related to the relative water absorption rate after 24 h, and PEG solution inhibits the absorption of water; the higher the PEG mass fraction, the stronger the inhibition. The relative water absorption rate of rice varieties with stronger drought resistance was higher than that with weaker drought resistance. The change of NMR signals directly reflects the moisture distribution and water absorption of rice seeds during germination. In addition, the moisture content of the seeds and the total amplitude of NMR signals were positively correlated(R2=0.983). This indicated that the data obtained by NMR technique were consistent with those obtained by the conventional dry-weight weighing method. Therefore it is a proper method to detect the moisture content in seeds during germination with NMR technique. By this regression equation, the moisture content of each state of water during seed germination can be calculated. These empirical data offer a reference for the study of rice seeds’ response mechanism under drought stress during seed germination and the screening of germplasm resources, and also develop a new nondestructive detecting technology of moisture for plants under stress. [ABSTRACT FROM AUTHOR]

Published
2018
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227. 烤烟伸根期生理特性对干旱胁迫的响应及其抗旱性评价.

Author

童文杰, 邓小鹏, 谢 贺, 王飞兵, 马二登, 李军营, 晋 艳, 徐照丽, and 宋振伟

Subjects
PHOTOSYNTHETIC pigments, RAINFALL, PRINCIPAL components analysis, ROOT development, PHOTOSYNTHETIC rates, ABSCISIC acid, TOBACCO smoke, MEMBRANE lipids, CAROTENOIDS
Abstract

Copyright of Journal of Agricultural Science & Technology (1008-0864) is the property of Journal of Agricultural Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2018
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228. Biometric responses of third ratoon sugarcane varieties under variable water regime.

Author

Rodolfo Junior, Francisco, Ribeiro Junior, Walter Quadros, Ramos, Maria Lucrécia Gerosa, da Silva Batista, Fábio Pedro, de Lima, Cristiane Andréa, and Rocha, Omar Cruz

Subjects
SUGARCANE varieties, DRY farming, IRRIGATION, BIOMETRY, LEAF area index
Abstract

Water deficit is one of the main factors to limit sugar cane production. This paper's goal is to characterize biometrically varieties of sugarcane under different water regimes. The experiment was performed using randomized design with three repetitions in parcels subdivided in time, in which three varieties: RB855156, RB835486 e RB867515 (plots), with absence and presence of irrigation (irrigated and rainfed - subplots) to which the plants were subjected, and data collection in six observations in time (50, 100, 150, 200, 250 and 300 days after cutting - DAC), were the subsubplots. The following biometrics were assessed: mean stem diameter (MSD), mean tiller height (MTH), number of green and completely open leaves (NoFOGL), length and width of +3 leaf (C+3 and L+3, respectively), leaf area index (LAI), leaf area (LA) and productivity. The data were subjected to variance analysis and regression at p<0.05. The variety RB867515 was the one that displayed higher MSD, MTH, C+3 and L+3 biometric values, both in irrigated cultivation and rainfed; it was observed that there was a decrease in NoFOGL values per tiller when the varieties were grown in rainfed conditions; the RB867515 variety had higher productivity, not differentiating to the RB855156, and proved better suited to water stress during the beginning of cultivation cycle. [ABSTRACT FROM AUTHOR]

Published
2018
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229. The influence of growth form and substrate on lichen ecophysiological responses along an aridity gradient.

Author

Pinho, Pedro, Paoli, Luca, Loppi, Stefano, Branquinho, Cristina, and Munzi, Silvana

Subjects
LICHENS, ARID regions, ENDANGERED ecosystems, CLIMATE change, CRUST vegetation
Abstract

In this paper, we investigated whether growth form and substrate in lichens influence their physiological responses along an aridity gradient. Thalli of the foliose lichen Parmotrema perlatum and the fruticose lichen Ramalina canariensis were transplanted in selected rural/forested sites of Southern Portugal characterized by a different aridity index. Physiological parameters including photosynthetic performances, assimilation pigments, ergosterol content and sample viability were measured prior to exposure (winter) and after 6-month exposure (summer). Photosynthetic performances were also investigated in common native foliose and fruticose epiphytic lichens and in fruticose terricolous species. Both transplanted and native lichens showed a decrease in photosynthetic performances in summer and lower performances in sites classified as drier and higher performances in humid forested sites. No relevant differences occurred between epiphytic foliose and fruticose growth forms. However, terricolous fruticose samples showed a significant difference in humid and drier sites and between winter and summer, probably due to microclimatic conditions similarly to other biological crusts. [ABSTRACT FROM AUTHOR]

Published
2017
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230. Tree growth response of Fokienia hodginsii to recent climate warming and drought in southwest China.

Author

Su, Jiajia, Gou, Xiaohua, Deng, Yang, Zhang, Ruibo, Liu, Wenhuo, Zhang, Fen, Lu, Ming, Chen, Yao, and Zheng, Wuji

Subjects
TREE growth, FORESTRY & climate, PLANT-atmosphere relationships, TREE mortality, EFFECT of drought on plants
Abstract

To date, few attempts have been made to assess the influence of climate change on forest ecosystems and on the relationship between tree growth and climate in humid areas of low latitudes. In this paper, we studied the response of tree growth and forest ecosystem to climate change by using Fokienia hodginsii tree-ring cores from the northern Yunnan-Guizhou Plateau, southwest of China. Tree growth correlates the highest ( r = −0.64, p < 0.01) with mean temperature (July-September), but the coefficients were changing with time as revealed by a moving correlation analysis. Tree growth is significantly ( p < 0.05) and positively correlated with January-April mean temperature from AD 1961-1987, while correlations with precipitation are insignificant. In contrast, from 1988 to 2014, tree growth correlated negatively with mean temperature of previous summer and positively with precipitation of previous August-September. This indicated that the limiting factors for tree growth have changed under different climate conditions. The meteorological data suggested that from 1961 to 1987 it was cold and wet in the study area and radial growth is limited by winter and spring temperatures. This restriction is weaker if the climate is appropriate in general. However, from 1988 to 2014, the combined effects of recent warming and decreasing precipitation have led to an increasing response of tree-ring width to drought. In addition, a large proportion of mature F. hodginsii mortality occurred from 2007 to 2013, which corresponds with a drastic reduction of radial growth (narrowest in recent 100 years). The recent drought, induced by decreasing precipitation and increasing temperature, may have passed the threshold which F. hodginsii could tolerate, causing tree growth reduction, tree growth-climate relationship change, as well as catastrophic tree mortality. All these changes may lead to further responses of the local ecosystem to climate change which should be highly regarded. [ABSTRACT FROM AUTHOR]

Published
2017
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231. 杜鹃花属植物干旱胁迫研究进展.

Author

李丹丹, 李晓花, and 张乐华

Subjects
*GENETIC regulation, *MYCORRHIZAL fungi, *WATER use, *GENE expression, *DROUGHTS, *GERMINATION, *RHODODENDRONS
Abstract

As one of the three alpine flowers in the world and one of the ten traditional famous flowers in China, Rhododendron has high ornamental value and broad landscape applications. However, most of them are naturally distributed in high-altitude mountains, and they prefer cool and humid climate for the restriction of genetic mechanism. Drought is the key factor to restrict their ex-situ conservation and landscape application. As Rhododendron have many different species, cultivars and ecological types, distributed in a wide area, the mechanisms of different species or cultivars responses to drought stress are different. In this paper, how Rhododendron responses to drought stress and the effects of exogenous substances on improving the drought resistance of Rhododendron in China and abroad were reviewed from the aspects of seed germination, morphological and anatomical characteristics, physiological and biochemical parameters, gene expression, etc. In addition, the deficiency of current research and the future research directions were also discussed. It is proposed that the water use strategy and drought resistance mechanism of different ecological types and different drought resistances of Rhododendron should be future studied, as well as the gene regulation mechanism of mycorrhizal fungi for improving the drought resistance and the screening of excellent strains. This study provides the basis for the diversity conservation, the exploitation of drought resistance resources and the landscape applications of Rhododendron in China. [ABSTRACT FROM AUTHOR]

Published
2022
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232. 干旱胁迫对栀子内源激素含量的影响.

Author

王得运, 刘培培, 陈云婷, 徐月莹, 周丽, and 罗光明

Subjects
ABSCISIC acid, INDOLEACETIC acid, POLYETHYLENE glycol, DROUGHTS, GIBBERELLIC acid, TIME pressure, DROUGHT management
Abstract

Copyright of Journal of Agricultural Science & Technology (1008-0864) is the property of Journal of Agricultural Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2022
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233. Genome-Wide Characterization of Glyceraldehyde-3-Phosphate Dehydrogenase Genes and Their Expression Profile under Drought Stress in Quercus rubra.

Author

Lim, Hyemin, Denison, Michael Immanuel Jesse, Lee, Kyungmi, Natarajan, Sathishkumar, Kim, Tae-Lim, and Oh, Changyoung

Subjects
PROTEOMICS, RED oak, GENOMICS, GENE expression profiling, GENE families
Abstract

Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) is crucial in plant metabolism and responses to various abiotic stresses. In the glycolysis pathway, glyceraldehyde-3-phosphate (G3P) is oxidized to 1,3-bisphosphate glycerate (1,3-BPG) through the catalytic action of GAPDH. However, the GAPDH gene family in Quercus rubra has been minimally researched. In this study, we identified 13 GAPDH-encoding genes in Q. rubra through a bioinformatics analysis of genomic data. Evolutionary studies suggest that these QrGAPDH genes are closely related to those in Glycine max and Triticum aestivum. We conducted a comprehensive whole-genome study, which included predictions of subcellular localization, gene structure analysis, protein motif identification, chromosomal placement, and analysis of cis-acting regions. We also examined the expression of GAPDH proteins and genes in various tissues of Q. rubra and under drought stress. The results indicated diverse expression patterns across different tissues and differential expression under drought conditions. Notably, the expression of Qurub.02G290300.1, Qurub.10G209800.1, and Qrub.M241600.1 significantly increased in the leaf, stem, and root tissues under drought stress. This study provides a systematic analysis of QrGAPDH genes, suggesting their pivotal roles in the drought stress response of trees. [ABSTRACT FROM AUTHOR]

Published
2024
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234. Overexpression of a ' Paulownia fortunei ' MYB Factor Gene, PfMYB44 , Increases Salt and Drought Tolerance in Arabidopsis thaliana.

Author

Luo, Guijie, Cai, Weijia, Wang, Hao, Liu, Wei, Liu, Xu, Shi, Shizheng, and Wang, Lei

Subjects
MULTIPURPOSE trees, MYB gene, SESAME, DROUGHT tolerance, MOLECULAR cloning
Abstract

Paulownia fortunei (Seem.) Hemsl is a Paulownia Sieb.et tree of the family Scrophulariaceae. It has become an important short-to-medium-term fast-growing multi-purpose tree species in China due to its rapid growth, strong adaptability, and excellent material properties. MYB transcription factors in plants have numerous and diverse functions, playing important roles in various aspects such as plant stress response. To investigate the function of MYB transcription factors in Paulownia fortunei, this study used PCR technology to clone the PfMYB44 gene from Paulownia fortunei. The homology of PfMYB44 and SiMYB44 (Sesamum indicum) was the highest. Expression analysis results showed that PfMYB44 was expressed in the root, stem, young leaf, and mature leaf of Paulownia fortunei, with the highest content in the root. Cold, drought, hot, salt, and ABA treatments could increase the expression level of PfMYB44. Overexpression-PfMYB44 plants were constructed, and physiological and molecular analysis showed that PfMYB44 could positively regulate salt and drought stresses. Under drought stress, the expression levels of AtP5CS, AtCAT1, AtNCED3 and AtSnRK2.4 in transgenic lines were significantly induced. Salt stress induced the expression of AtNHX1, AtSOS1, AtSOS2 and AtSOS3 genes, and the relative expression levels of these genes in transgenic Arabidopsis were higher. In conclusion, the functional study of PfMYB44 laid a certain foundation for the study of Paulownia stress resistance, and was helpful to the study of its stress resistance mechanism and the cultivation of new stress resistance varieties. [ABSTRACT FROM AUTHOR]

Published
2024
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235. Diplodia seriata Isolated from Declining Olive Trees in Salento (Apulia, Italy): Pathogenicity Trials Give a Glimpse That It Is More Virulent to Drought-Stressed Olive Trees and in a Warmth-Conditioned Environment.

Author

Manetti, Giuliano, Brunetti, Angela, Sciarroni, Lorenzo, Lumia, Valentina, Bechini, Sara, Marangi, Paolo, Reverberi, Massimo, Scortichini, Marco, and Pilotti, Massimo

Subjects
OLIVE, XYLELLA fastidiosa, RAINFALL, BOTRYOSPHAERIACEAE, DIEBACK
Abstract

The fungi Botryosphaeriaceae are involved in olive declines in both the world hemispheres and in all continents where this species is cultivated. In Salento (Apulia, Italy), the Botryosphaeriaceae Neofusicoccum mediterraneum and N. stellenboschiana have been reported as the agents of a branch and twig dieback that overlaps with olive quick decline syndrome caused by Xylella fastidiosa subsp. pauca. In this study, we report the finding of Diplodia seriata, another Botryosphaeriaceae species, in Salento in Xylella fastidiosa-infected olive trees affected by symptoms of branch and twig dieback. Given that its presence was also reported in olive in the Americas and in Europe (Croatia) with different degrees of virulence, we were prompted to assess its role in the Apulian decline. We identified representative isolates based on morphological features and a multilocus phylogeny. In vitro tests showed that the optimum growth temperature of the isolates is around 25–30 °C, and that they are highly thermo-tolerant. In pathogenicity trials conducted over eleven months, D. seriata expressed a very low virulence. Nonetheless, when we imposed severe water stress before the inoculation, D. seriata significatively necrotized bark and wood in a time frame of 35 days. Moreover, the symptoms which resulted were much more severe in the trial performed in summer compared with that in autumn. In osmolyte-supplemented media with a water potential from −1 to −3 Mpa, the isolates increased or maintained their growth rate compared with non-supplemented media, and they also grew, albeit to a lesser extent, on media with a water potential as low as −7 Mpa. This suggests that olives with a low water potential, namely those subjected to drought, may offer a suitable environment for the fungus' development. The analysis of the meteorological parameters, temperatures and rainfall, in Salento in the timeframe 1989–2023, showed that this area is subjected to a progressive increase of temperature and drought during the summer. Thus, overall, D. seriata has to be considered a contributor to the manifestation of branch and twig dieback of olive in Salento. Coherently with the spiral decline concept of trees, our results suggest that heat and drought act as predisposing/inciting factors facilitating D. seriata as a contributor. The fact that several adverse factors, biotic and abiotic, are simultaneously burdening olive trees in Salento offers a cue to discuss the possible complex nature of the olive decline in Salento. [ABSTRACT FROM AUTHOR]

Published
2024
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236. Tree Resilience Indices of Norway Spruce Provenances Tested in Long-Term Common Garden Experiments in the Romanian Carpathians.

Author

Alexandru, Alin Madalin, Mihai, Georgeta, Stoica, Emanuel, and Curtu, Alexandru Lucian

Subjects
WOOD, CLIMATE change, TREES, ROMANIANS, GARDENS, NORWAY spruce
Abstract

Provenance trials provide a valuable opportunity to evaluate the impact of extreme events on growth and wood properties. In this study, we have evaluated 81 Norway spruce provenances, tested in three provenance trials established in the Romanian Carpathians in 1972. The response to drought of the Norway spruce provenances has been examined using the following tree resilience indices: resistance, recovery, resilience, and relative resilience. The relationship between climate and growth, the correlations between wood traits, and the coordinates of the origin and tree resilience indices were also analysed. In each provenance trial, there were significant differences between provenances and years regarding wood widths and latewood percentage (LWP). Regarding drought extreme events, the years when they occurred in all three provenance trials were 2000 and 2003. Significant differences between provenances for at least one tree resilience index have been found in all provenance trials, for the year 2000. By using subperiods of 25 years, changes in the relationship between climate and growth have been observed. Several provenances with high radial growth and good resistance and/or recovery have been identified. Provenances that performed better in common garden experiments could be used in assisted migration, even in the proximity of the current natural range. [ABSTRACT FROM AUTHOR]

Published
2024
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237. Precise partial root-zone irrigation technique and potassium-zinc fertigation management improve maize physio-biochemical responses, yield, and water use in arid climate.

Author

Elshamly, Ayman M. S. and Abaza, A. S.

Subjects
MICROIRRIGATION, PLANT defenses, IRRIGATION water, WATER efficiency, DEFICIT irrigation
Abstract

Background: To optimize irrigation water use and productivity, understanding the interactions between plants, irrigation techniques, and fertilization practices is crucial. Therefore, the experiment aims to assess the effectiveness of two application methods of potassium humate combined with chelated zinc under partial root-zone drip irrigation techniques on maize nutrient uptake, yield, and irrigation water use efficiency across two irrigation levels. Methods: Open-field experiments were carried out in two summer seasons of 2021 and 2022 under alternate and fixed partial root-zone drip irrigation techniques to investigate their impacts at two irrigation levels and applied foliar and soil applications of potassium humate or chelated zinc in a sole and combinations on maize. Results: Deficit irrigation significantly increased hydrogen peroxide levels and decreased proline, antioxidant enzymes, carbohydrate, chlorophyll (a + b), and nutrient uptake in both partial root-zone techniques. The implementation of combined soil application of potassium humate and chelated zinc under drought conditions on maize led to varying impacts on antioxidant enzymes and nutritional status, depending on the type of partial root-zone technique. Meanwhile, the results showed that fixed partial root-zone irrigation diminished the negative effects of drought stress by enhancing phosphorus uptake (53.8%), potassium uptake (59.2%), proline (74.4%) and catalase (75%); compared to the control. These enhancements may contribute to improving the defense system of maize plants in such conditions. On the other hand, the same previous treatments under alternate partial root zone modified the defense mechanism of plants and improved the contents of peroxidase, superoxide dismutase, and the uptake of magnesium, zinc, and iron by 81.3%, 82.3%, 85.1%, 56.9%, and 80.2%, respectively. Conclusions: Adopting 75% of the irrigation requirements and treating maize plants with the soil application of 3 g l−1 potassium humate combined with 1.25 kg ha−1 chelated zinc under alternate partial root-zone technique, resulted in the maximum root length, leaf water content, chlorophyll content, yield, and irrigation water use efficiency. [ABSTRACT FROM AUTHOR]

Published
2024
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238. Identification of CKX gene family in Morusindica cv K2 and functional characterization of MiCKX4 during abiotic stress.

Author

Singhal, Chanchal, Singh, Arunima, Sharma, Arun Kumar, and Khurana, Paramjit

Subjects
GOLGI apparatus, GENE expression, GENE families, CHROMOSOME duplication, ABIOTIC stress, DROUGHT tolerance
Abstract

Cytokinin oxidase/dehydrogenase (CKX) is the key enzyme that has been observed to catalyze irreversible inactivation of cytokinins and thus modulate cytokinin levels in plants. CKX gene family is known to have few members which are, expanded in the genome mainly due to duplication events. A total of nine MiCKXs were identified in Morus indica cv K2 with almost similar gene structures and conserved motifs and domains. The cis-elements along with expression analysis of these MiCKXs revealed their contrasting and specific role in plant development across different developmental stages. The localization of these enzymes in ER and Golgi bodies signifies their functional specification and property of getting modified post-translationally to carry out their activities. The overexpression of MiCKX4, an ortholog of AtCKX4, displayed longer primary root and higher number of lateral roots. Under ABA stress also the transgenic lines showed higher number of lateral roots and tolerance against drought stress as compared to wild-type plants. In this study, the CKX gene family members were analyzed bioinformatically for their roles under abiotic stresses. [ABSTRACT FROM AUTHOR]

Published
2024
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239. Transcriptome analysis reveals candidate genes for different root types of alfalfa (Medicago sativa) after water stress induced by PEG-6000.

Author

Wang, Kun, Nan, Li-Li, Xia, Jing, Yao, Yu-heng, Cheng, Jiao, and Chen, Jing-ru

Subjects
TRANSCRIPTION factors, PROTEIN kinases, PLANT hormones, PLANT adaptation, PHYSIOLOGICAL stress, ALFALFA, ABSCISIC acid
Abstract

Background: We aimed to gain insight into the response mechanism of alfalfa (Medicago sativa) to drought stress by recognizing and analyzing drought-responsive genes in the roots of different root types of alfalfa. The rhizomatous-rooted M. sativa cv.'Qingshui' (QS), tap-rooted M. sativa cv.'Longdong' (LD), and creeping-rooted M. varia cv. 'Gongnong No. 4' (GN) were used to analyze the transcriptome information and physiological characteristics of the root systems of the cultivars under simulated drought stress using PEG-6000. Results: It was found that aridity caused a significant increase in the content of osmotic stress substances and antioxidant enzyme activity. The content of malondialdehyde (MDA) in QS was lower than that in LD and GN under moisture stress, indicating a stronger accumulation capacity of osmotic regulatory substances. Based on sequencing results, 14,475, 9336, and 9243 upregulated DEGs from QS, LD, and GN were annotated into 26, 29, and 28 transcription factor families, respectively. QS showed more DEGs than LD and GN. KEGG enrichment analysis identified that DEGs were significantly enriched in metabolic pathways such as amino acid biosynthesis, phenylpropanoid biosynthesis, plant hormone signaling transduction, and MAPK pathways. This suggests a strong correlation between these pathways and drought stress. The results also show that genes associated with ABA hormone signaling (MS. gene93372, MS. gene072046, and MS. gene012975) are crucial for plant's adaptation to drought stress. Conclusions: These genes, such as serine/threonine protein kinases and abscisic acid receptors, play a crucial role in plant hormone signaling and MAPK pathways. They could serve as potential candidate genes for drought resistance research in alfalfa, providing a molecular foundation for studying drought resistance. [ABSTRACT FROM AUTHOR]

Published
2024
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240. Modulatory effects of selenium nanoparticles against drought stress in some grapevine rootstock/scion combinations.

Author

Daler, Selda, Korkmaz, Nesrin, Kılıç, Tuğba, Hatterman-Valenti, Harlene, Karadağ, Ahmet, and Kaya, Ozkan

Subjects
POISONS, LEAF temperature, LEAF area, DROUGHT tolerance, PLANT yields
Abstract

Background: Drought is a significant abiotic stress that adversely affects plant growth, development, and metabolic processes, thereby reducing plant yield, quality, and production, and threatening global food security. In recent years, nanotechnology has emerged as a promising strategy to overcome the existing environmental challenges and has been tested on some plant species. But it is still awaiting investigation for grapevines. The aim of this study was to investigate the potential of selenium nanoparticles (Se-NPs) to modulate some morphological, physiological, and biochemical parameters in grapevine saplings (5 BB/Crimson Seedless, 41 B/Crimson Seedless, and 1103 P/Crimson Seedless) under drought stress conditions. Results: In the study, Se-NP solutions at different concentrations (0 (control), 1, 10, and 100 ppm) were applied by the spray method to wet the entire green surface of grapevine saplings grown under well-irrigated (90–100% field capacity) and drought stress (40–50% field capacity) conditions. Our results showed that 10 ppm Se-NP concentration had the most positive effect, 1 ppm concentration showed limited effects, and 100 ppm concentration led to toxic effects, especially when combined with drought conditions. Se-NP applications at 10 ppm concentration improved the growth parameters (leaf number, leaf area, root fresh and dry weight, shoot fresh and dry weight, etc.) and increased the SPAD index of grapevine saplings under both normal and drought conditions. Additionally, 10 ppm Se-NP applications improved the relative water content (RWC) and stomatal conductance values, proportional to the increases in protein content. On the other hand, under drought conditions, the drought index, leaf temperature, membrane damage index, hydrogen peroxide (H2O2) content, and malondialdehyde (MDA) levels significantly decreased as a result of 10 ppm Se-NP applications, showing an opposite trend. Furthermore, the levels of proline, total phenolics, and antioxidant enzymes (CAT, SOD, and APX) that rose significantly due to drought stress were reduced by 10 ppm Se-NP applications, which also helped to lessen the oxidative stress caused by the drought. Conclusion: The study concluded that foliar application of Se-NPs at 10 ppm significantly enhances drought tolerance in grapevine saplings by improving antioxidant defense, proline and protein accumulation, and overall growth, while lower concentrations are less effective and higher concentrations can cause phytotoxicity. These findings indicate that Se-NPs applications may hold promise not only for grapevines but also for mitigating drought stress effects and improving productivity in other economically important fruit species, warranting further exploration across diverse crop systems. [ABSTRACT FROM AUTHOR]

Published
2024
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241. Elicitors and Biostimulants to Mitigate Water Stress in Vegetables.

Author

Melo-Sabogal, Diana Victoria and Contreras-Medina, Luis Miguel

Subjects
FARMS, CROP management, AGRICULTURE, DROUGHT management, CLIMATE change, NO-tillage, TILLAGE
Abstract

The acceleration of the climate crisis and increased demand for water have caused water stress in many agricultural lands worldwide. This issue is of utmost importance as water stress represents one of the most crucial challenges for the agricultural sector and food security, affecting the growth and yield of crops. Developing agricultural strategies to mitigate the adverse effects of water stress and improve crop stress tolerance and crop yield is therefore crucial. This review aimed to analyze the effect of agricultural practices such as elicitation and biostimulation on mitigating the effects of water stress in vegetables. This manuscript provides relevant and recent information about the studied effects on various vegetable species and their responses under water deficit and agricultural and non-agricultural strategies to mitigate water stress, highlighting the use of elicitors and biostimulants. Inclusion criteria were scientific reports and book chapters published from 2000 to 2024, including keywords as follows: water stress + vegetables, water deficit + effects, drought stress management, agricultural strategies for water stress management, eustressors + water stress, elicitors and biostimulants + water stress mitigation. According to the reported literature, it was found that the physiological, biochemical, and molecular responses of vegetables to water stress depended on factors such as the severity and duration of the water deficit, the plant species, and the phenological state of the plants. Traditional agronomic strategies such as tillage, mulching, and intercropping for crop drought management were evaluated. Recently, alternative strategies for mitigating the effects of water stress have gained significant interest, such as the exogenous application of phytohormones and osmoprotectants, nutrient management, and the use of UV-B light, radiation, and acoustic waves, among others, whose eustressive effects (as biostimulants and elicitors) have been demonstrated. Among these eustressors, those of physical origin show great potential for mitigating water stress. To improve the individual potential of eustressors for water stress mitigation, we proposed the combination of practices such as tillage, mulching, application of hormones and osmoprotectants, and physical elicitors and biostimulants such as gamma rays, He-Ne laser, and UV-B. Further exploration is required to establish doses, application conditions, and effects on water stress mitigation and vegetable yield, underscoring the importance and ongoing nature of this research. [ABSTRACT FROM AUTHOR]

Published
2024
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242. Effects of Rehydration on Bacterial Diversity in the Rhizosphere of Broomcorn Millet (Panicum miliaceum L.) after Drought Stress at the Flowering Stage.

Author

Liu, Yuhan, Mao, Jiao, Xu, Yuanmeng, Ren, Jiangling, Wang, Mengyao, Wang, Shu, Liu, Sichen, Wang, Ruiyun, Wang, Lun, Wang, Liwei, Qiao, Zhijun, and Cao, Xiaoning

Subjects
BROOMCORN millet, BACTERIAL diversity, MICROBIAL diversity, RHIZOBACTERIA, DROUGHT tolerance
Abstract

This study aimed to elucidate responses of the bacterial structure and diversity of the rhizosphere in flowering broomcorn millet after rehydration following drought stress. In this study, the broomcorn millet varieties 'Hequ red millet' (A1) and 'Yanshu No.10′ (A2), known for their different drought tolerance levels, were selected as experimental materials. The plants were subjected to rehydration after drought stress at the flowering stage, while normal watering (A1CK and A2CK) served as the control. Soil samples were collected at 10 days (A11, A21, A1CK1, and A2CK1) and 20 days (A12, A22, A1CK2, and A2CK2) after rehydration. High-throughput sequencing technology was employed to investigate the variations in bacterial community structure, diversity, and metabolic functions in the rhizosphere of the broomcorn millet at different time points following rehydration. The findings indicated that the operational taxonomic units (OTUs) of bacteria in the rhizosphere of broomcorn millet were notably influenced by the duration of treatment, with a significant decrease in OTUs observed after 20 days of rehydration. However, bacterial Alpha diversity was not significantly impacted by rehydration following drought stress. The bacterial community in the rhizosphere of broomcorn millet was mainly composed of Actinobacteria and Proteobacteria. After rewatering for 10 to 20 days after drought stress, the abundance of Sphingomonas and Aeromicrobium in the rhizosphere soil of the two varieties of broomcorn millet decreased gradually. Compared with Yanshu No.10, the abundance of Pseudarthrobacter in the rhizosphere of Hequ red millet gradually increased. A Beta diversity analysis revealed variations in the dissimilarities of the bacterial community which corresponded to different rehydration durations. The relative abundance of bacterial metabolic functions in the rhizosphere of broomcorn millet was lower after 20 days of rehydration, compared to measurements after 10 days of rehydration. This observation might be attributed to the exchange of materials between broomcorn millet and microorganisms during the initial rehydration stage to repair the effects of drought, as well as to the enrichment of numerous microorganisms to sustain the stability of the community structure. This study helps to comprehend the alterations to the bacterial structure and diversity in the rhizosphere of broomcorn millet following drought stress and rehydration. It sheds light on the growth status of broomcorn millet and its rhizosphere microorganisms under real environmental influences, thereby enhancing research on the drought tolerance mechanisms of broomcorn millet. [ABSTRACT FROM AUTHOR]

Published
2024
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243. Identification and Functional Analysis of the EPF/EPFL Gene Family in Maize (Zea mays L.): Implications for Drought Stress Response.

Author

Xia, Hanchao, Wang, Qi, Chen, Ziqi, Sun, Xiaopeng, Zhao, Fangfang, Zhang, Di, Fei, Jianbo, Zhao, Rengui, and Yin, Yuejia

Subjects
WATER shortages, GENE families, GENE expression profiling, GENE expression, DROUGHT tolerance
Abstract

Maize, a vital cereal in global agriculture, faces significant yield challenges due to drought exacerbated by climate change. This study explores the genetic and molecular bases of drought resilience in maize, focusing on the EPF/EPFL gene family known for its role in stomatal regulation. Through a genome-wide analysis across seven grass species, we identified and characterized 16 ZmEPF/EPFL genes in maize. Focusing on their gene structure, expression patterns, and evolutionary relationships. The study integrated genome-wide searches, phylogenetic analysis, gene expression profiling under drought and other abiotic stresses, and qRT-PCR validation to elucidate the functional roles of these genes in drought response. Our results demonstrate that specific ZmEPF/EPFL genes are differentially expressed under varying drought conditions, suggesting their involvement in the plant's adaptive response to water scarcity. Furthermore, interaction analyses reveal that these genes are linked to key processes such as stomatal development and oxidative stress management. This study provides a comprehensive overview of the ZmEPF/EPFL gene family's contribution to stomatal development and drought tolerance, offering insights that could guide future breeding strategies for drought-resistant maize varieties. [ABSTRACT FROM AUTHOR]

Published
2024
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244. Moderate Drought Stress Interferes with the Physiological State and Promotes the Accumulation of Isoflavone in Reproductive Iris domestica Rhizomes.

Author

Ai, Qiang, Dai, Ailin, Han, Mei, Yang, Limin, and Liu, Cuijing

Subjects
SOIL moisture, SECONDARY metabolism, PHYSIOLOGICAL stress, PLANT metabolism, REGULATION of growth
Abstract

Drought stress is one of the main factors affecting the growth and secondary metabolism of plants. Iris domestica, rich in isoflavones, is a common herbal medicine in China. In this study, the effects of drought stress and rehydration on resistance physiological characteristics and the secondary metabolism of two-year-old I. domestica during the vegetative and reproductive growth period were investigated. The results showed that the dry weight and fresh weight of rhizomes and roots under severe drought stress were significantly decreased, while those under moderate drought stress were not significantly changed. Meanwhile, the SOD activities, POD activities, MDA content and Pro content increased to resist drought at D1 and D2. In the vegetative growth period, the changes in isoflavone concentration and the expression levels of genes in isoflavone synthesis were more dramatic. Isoflavone accumulation was promoted, to some extent, in the reproductive growth period under the D1 drought treatment. In the actual production process, different measures, namely short-term stress regulation in the vegetative growth period and moderate drought stress (13.44% < soil water content ≤ 16.8%) in the reproductive growth period, need to be adopted to regulate isoflavone biosynthesis. [ABSTRACT FROM AUTHOR]

Published
2024
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245. Effects of Drought Stress on Photosynthesis and Chlorophyll Fluorescence in Blue Honeysuckle.

Author

Yan, Weijiao, Lu, Yongchuan, Guo, Liangchuan, Liu, Yan, Li, Mingkai, Zhang, Boyuan, Zhang, Bingxiu, Zhang, Lijun, Qin, Dong, and Huo, Junwei

Subjects
WATER use, SOIL moisture, CHLOROPHYLL spectra, PHOTOSYSTEMS, QUANTUM efficiency
Abstract

Blue honeysuckle (Lonicera caerulea L.) is a deciduous shrub with perennial rootstock found in China. The objectives of this study were to explore the drought tolerance of blue honeysuckle, determine the effect of drought stress on two photosystems, and examine the mechanism of acquired drought tolerance. In this study, blue honeysuckle under four levels of simulated field capacity (100%, 85%, 75%, and 65% RH) was grown in split-root pots for drought stress treatment, for measuring the changes in chlorophyll content, photosynthetic characteristics, and leaf chlorophyll fluorescence parameters. The chlorophyll content of each increased under mild stress and decreased under moderate and severe stress. The net photosynthetic rate, transpiration rate, intercellular carbon dioxide concentration, and stomatal conductance of blue honeysuckle decreased with the increase in water stress. However, the water utilization rate and stomatal limit system increased under mild and moderate stress and decreased under severe stress. The maximum fluorescence (Fm), maximum photochemical efficiency, and quantum efficiency of photosystem II decreased with the decrease in soil water content, and the initial fluorescence increased significantly (p < 0.01). With the decrease in soil water content, the energy allocation ratio parameters decreased under severe drought stress. The main activity of the unit reaction center parameters first increased and then decreased. ABS/CSm, TRo/CSm, ETo/CSm, and REo/CSm gradually declined. After a comprehensive analysis, the highest scores were obtained under adequate irrigation (CK). Overall, we concluded that the water irrigation system of blue honeysuckle should be considered adequate. [ABSTRACT FROM AUTHOR]

Published
2024
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246. Photosynthetic Performance, Carbohydrate Partitioning, Growth, and Yield among Cassava Genotypes under Full Irrigation and Early Drought Treatment in a Tropical Savanna Climate.

Author

Santanoo, Supranee, Ittipong, Passamon, Banterng, Poramate, Vorasoot, Nimitr, Jogloy, Sanun, Vongcharoen, Kochaphan, and Theerakulpisut, Piyada

Subjects
SAVANNAS, RAINFALL, TROPICAL climate, TUBERS, PHOTOSYNTHETIC rates
Abstract

In a tropical savanna climate like Thailand, cassava can be planted all year round and harvested at 8 to 12 months after planting (MAP). However, it is not clear how water limitation during the dry season without rain affects carbon assimilation, partitioning, and yield. In this field investigation, six cassava genotypes were planted in the rainy season (August 2021) under continuous irrigation (control) or subjected to drought for 60 days from 3MAP to 5MAP during the dry season (November 2021 to January 2022) with no irrigation and rainfall. After that, the plants were rewatered and continued growing until harvest at 12MAP. After 60 days of stress, there were significant reductions in the mean net photosynthesis rate (Pn), petiole, and root dry weight (DW), and slight reductions in leaf, stem, and tuber DW. The mean starch concentrations were reduced by 42% and 16% in leaves and tubers, respectively, but increased by 12% in stems. At 6MAP after 30 days of rewatering, Pn fully recovered, and stem starch was remobilized resulting in a dramatic increase in the DW of all the organs. Although the mean tuber DW of the drought plants at 6MAP was significantly lower than that of the control, it was significantly higher at 12MAP. Moreover, the mean tuber starch concentration at 12MAP of the drought plants (18.81%) was also significantly higher than that of the controls (16.46%). In the drought treatment, the high-yielding varieties, RY9, RY72, KU50, and CMR38-125-77 were similarly productive in terms of tuber DW and starch concentration while the breeding line CM523-7 produced the lowest tuber biomass and significantly lower starch content. Therefore, for cassava planted in the rainy season in the tropical savanna climate, the exposure to drought during the early growth stage was more beneficial than the continuous irrigation. [ABSTRACT FROM AUTHOR]

Published
2024
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247. Assessment of Trunk Diameter Fluctuation-Derived Indices for Detecting Water Stress in Sweet Cherry Trees.

Author

Blaya-Ros, Pedro J., Blanco, Víctor, Torres-Sánchez, Roque, Soto-Valles, Fulgencio, Espósito, Martín E., and Domingo, Rafael

Subjects
WATER management, CHERRIES, USEFUL plants, IRRIGATION management, DEFICIT irrigation, SWEET cherry
Abstract

The continuous and reliable assessment of crop water status through water indicators enables the sustainable management of water resources, especially in arid or semi-arid climate scenarios exacerbated by climate change. Therefore, the main objective of this study is to determine and compare the sensitivity of indices derived from trunk diameter fluctuations for the accurate and automatic detection of changes in the water status of cherry trees. The water stress indicators examined are maximum daily trunk shrinkage (MDS), trunk growth rate (TGR), early daily trunk shrinkage (EDS), and late daily trunk shrinkage (LDS). During two growing seasons, 'Lapins' sweet cherry trees were subjected to different water stress levels: (i) a control treatment irrigated at 115% of crop evapotranspiration demand to ensure non-limiting water conditions, and (ii) a deficit irrigation treatment, with two irrigation withholding cycles. Vegetative growth was affected by water stress. Trunk daily growth rate and late daily trunk shrinkage exhibited a high variability and did not clearly show differences in plant water status. Both EDS and MDS showed a third-degree polynomial relationship with Ψstem. MDS had a lineal relationship with Ψstem of up to −1.4 MPa; however, further decreases in Ψstem did not necessarily lead to increased MDS. In contrast, EDS became non-linear at −1.8 MPa, making it a more useful plant water indicator than MDS for 'Lapins' sweet cherry trees when detecting severe water stress conditions. The frequencies of both MDS and EDS decreased from 85% to 35% when water stress increased. Therefore, the information provided by MDS and EDS frequencies, along with their daily values, could be useful as irrigation management tools for sweet cherry trees. [ABSTRACT FROM AUTHOR]

Published
2024
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248. Calcium-Dependent Protein Kinase GhCDPK16 Exerts a Positive Regulatory Role in Enhancing Drought Tolerance in Cotton.

Author

Yan, Mengyuan, Chai, Meijie, Li, Libei, Dong, Zhiwei, Jin, Hongmiao, Tan, Ming, Ye, Ziwei, Yu, Shuxun, and Feng, Zhen

Subjects
CALCIUM-dependent protein kinase, COTTON growing, REACTIVE oxygen species, NATURAL fibers, DROUGHT tolerance
Abstract

Cotton is essential for the textile industry as a primary source of natural fibers. However, environmental factors like drought present significant challenges to its cultivation, adversely affecting both production levels and fiber quality. Enhancing cotton's drought resilience has the potential to reduce yield losses and support the growth of cotton farming. In this study, the cotton calcium-dependent protein kinase GhCDPK16 was characterized, and the transcription level of GhCDPK16 was significantly upregulated under drought and various stress-related hormone treatments. Physiological analyses revealed that the overexpression of GhCDPK16 improved drought stress resistance in Arabidopsis by enhancing osmotic adjustment capacity and boosting antioxidant enzyme activities. In contrast, silencing GhCDPK16 in cotton resulted in increased dehydration compared with the control. Furthermore, reduced antioxidant enzyme activities and downregulation of ABA-related genes were observed in GhCDPK16-silenced plants. These findings not only enhanced our understanding of the biological functions of GhCDPK16 and the mechanisms underlying drought stress resistance but also underscored the considerable potential of GhCDPK16 in improving drought resilience in cotton. [ABSTRACT FROM AUTHOR]

Published
2024
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249. Silencing of GhSINAT5 Reduces Drought Resistance and Salt Tolerance in Cotton.

Author

Wang, Yi, Zeng, Jiacong, Yu, Yuehua, and Ni, Zhiyong

Subjects
CROP improvement, SUPEROXIDE dismutase, POLYETHYLENE glycol, PLANT genes, GENETIC engineering
Abstract

The SEVEN IN ABSENTIA (SINA) E3 ubiquitin ligase is widely involved in drought and salt stress in plants. However, the biological function of the SINA proteins in cotton is still unknown. This study aimed to reveal the function of GhSINAT5 through biochemical, genetic and molecular approaches. GhSINAT5 is expressed in several tissues of cotton plants, including roots, stems, leaves and cotyledons, and its expression levels are significantly affected by polyethylene glycol, abscisic acid and sodium chloride. When GhSINAT5 was silenced in cotton plants, drought and salinity stress occurred, and the length, area and volume of the roots significantly decreased. Under drought stress, the levels of proline, superoxide dismutase, peroxidase and catalase in the GhSINAT5-silenced cotton plants were significantly lower than those in the non-silenced control plants, whereas the levels of hydrogen peroxide and malondialdehyde were greater. Moreover, the expression of stress-related genes in silenced plants under drought stress suggested that GhSINAT5 may play a positive role in the plant response to drought and salt stress by regulating these stress response-related genes. These findings not only deepen our understanding of the mechanisms of drought resistance in cotton but also provide potential targets for future improvements in crop stress resistance through genetic engineering. [ABSTRACT FROM AUTHOR]

Published
2024
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250. Genome-Wide Identification of Caffeic Acid O-Methyltransferase Gene Family in Medicago truncatula : MtCOMT13 -Mediated Salt and Drought Tolerance Enhancement.

Author

Cui, Kailun, Lv, Yanzhen, Zhang, Zhao, Sun, Qingying, Yao, Xingjie, and Yan, Huifang

Subjects
DROUGHT tolerance, CATECHOL-O-methyltransferase gene, CAFFEIC acid, GENE families, GENE expression, MEDICAGO
Abstract

Legumes are important grains and forages, providing high-quality proteins, vitamins, and micronutrients to humans and animals. Medicago truncatula is a close relative of alfalfa (Medicago sativa). Caffeic acid O-methyltransferase (COMT), a key gene that is identified to be essential for melatonin synthesis, plays a significant role in plant growth, development, and abiotic stress responses. However, a systematic study on the COMT gene family in M. truncatula has still not been reported. In this study, 63 MtCOMT genes were identified and categorized into three groups. Gene structure and conserved motif analyses revealed the relative conservation of closely clustered MtCOMTs within each group. Duplicated events in MtCOMT members were identified, and segmental duplication was the main mean. Cis-acting element prediction revealed the involvement of MtCOMTs in growth and development and response to light, stress, and plant hormones. RNA-seq data analysis showed that 57 MtCOMTs varied under salt and drought stresses. The RT-qPCR expression patterns showed that MtCOMT9, MtCOMT13, MtCOMT22, MtCOMT24, MtCOMT43, and MtCOMT46 were related to salt and drought responses in M. truncatula. Additionally, Arabidopsis thaliana overexpressing MtCOMT13 displayed superior plant growth phenotypes and enhanced tolerance to salt and drought stresses through higher photosynthetic parameters and activities of antioxidant enzymes, which indicated that MtCOMT13 played an important role in positively regulating plant salt and drought tolerance. These findings contribute to an improved understanding of MtCOMTs' roles in abiotic stress responses in M. truncatula, providing an important theoretical basis and genetic resource for legume species resistance breeding in the future. [ABSTRACT FROM AUTHOR]

Published
2024
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