2024 May 2 - Tennessee Weekly Drought Summary

Tennessee Climate Office, East Tennessee State University

02 May 2024

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Tennessee Climate Office

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2024 May 9 - Tennessee Weekly Drought Summary

Tennessee Climate Office, East Tennessee State University

09 May 2024

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Tennessee Climate Office

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2024 May 16 - Tennessee Weekly Drought Summary

Tennessee Climate Office, East Tennessee State University

16 May 2024

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Tennessee Climate Office

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2024 May 23 - Tennessee Weekly Drought Summary

Tennessee Climate Office, East Tennessee State University

23 May 2024

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Tennessee Climate Office

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2024 June 13 - Tennessee Weekly Drought Summary

Tennessee Climate Office, East Tennessee State University

13 June 2024

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Tennessee Climate Office

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2024 June 20 - Tennessee Weekly Drought Summary

Tennessee Climate Office, East Tennessee State University

20 June 2024

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Tennessee Climate Office

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2024 July 4 - Tennessee Weekly Drought Summary

Tennessee Climate Office, East Tennessee State University

04 July 2024

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Tennessee Climate Office

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2024 July 11 - Tennessee Weekly Drought Summary

Tennessee Climate Office, East Tennessee State University

11 July 2024

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Physiological response of loblolly pine seedlings to moisture-stress conditioning and their subsequent performance during water stress

Seiler, John R.

January 1984

The effect of moisture stress conditioning on the drought tolerance and performance of three open-pollinated families of loblolly pine (Pinus taeda I.) during water stress were investigated. Seedlings were subjected to prolonged sublethal drought treatments which included a watered control, a moderate stress treatment (MWS, seedlings watered only when needle water potential reached -0.8 MPa) and a severe stress treatment (SWS, seedlings watered only when water potential reached -1.4 MPa). After the conditioning period, numerous physiological and morphological parameters were measured, and performance of seedlings during water stress evaluated. Significant decreases in needle osmotic potential occurred in moisture stress conditioned seedlings. As a result, turgor in conditioned seedlings was equal to or greater than control seedlings even at lower needle water potentials. Photosynthesis vas decreased greatly with reduced needle water potential. However, the MWS and SWS seedlings maintained photosynthesis to water potentials 0.15 and 0.45 MPa lower than control seedlings, respectively. This response is likely the result of both osmotic adjustment, and an acclimation of the photosynthetic process resulting in less non-stomatal inhibition of photosynthesis at low needle water potentials. Initial needle conductance and transpiration, but not photosynthesis, were reduced greatly by the conditioning treatments, and resulted in improved water-use efficiency in conditioned seedlings. The response of stomata to changing vapor pressure deficit was increased through moisture stress conditioning. Boot growth was affected more by moisture stress than shoot growth, causing a decrease in root/shoot ratio. Changes in root morphology as a result of conditioning are not likely to improve the drought tolerance of loblolly pine seedlings. SWS conditioning significantly improved the height growth increment and resulted in slightly greater shoot and root biomass of outplanted, containerized seedlings after the first growing season, despite these seedlings being much smaller at the time of planting. Differences between seed sources did occur in the experiments, with a source from Texas generally showing the least response to moisture stress conditioning. / Ph. D.

LD5655.V856 1984.S445

Effects of Drought on Gene Expression in Maize Reproductive and Leaf Meristem Tissues as Revealed by Deep Sequencing

Kakumanu, Akshay

02 August 2012

Drought is a major environmental stress factor that poses a serious threat to food security. The effects of drought on early reproductive tissue at 1-2 DAP (days after pollination) is irreversible in nature and leads to embryo abortion, directly affecting the grain yield production. We developed a working RNA-Seq pipeline to study maize (Zea mays) drought transcriptome sequenced by Illumina GSIIx technology to compare drought treated and well- watered fertilized ovary (1-2DAP) and basal leaf meristem tissue. The pipeline also identified novel splice junctions - splice variants of previously known gene models and potential novel transcription units. An attempt was also made to exploit the data to understand the drought mediated transcriptional events (e.g. alternative splicing). Gene Ontology (GO) enrichment analysis revealed massive down-regulation of cell division and cell cycle genes in the drought stressed ovary only. Among GO categories related to carbohydrate metabolism, changes in starch and sucrose metabolism-related genes occurred in the ovary, consistent with a decrease in starch levels, and in sucrose transporter function, with no comparable changes occurring in the leaf meristem. ABA-related processes responded positively, but only in the ovaries. GO enrichment analysis also suggested differential responses to drought between the two tissues in categories such as oxidative stress-related and cell cycle events. The data are discussed in the context of the susceptibility of maize kernel to drought stress leading to embryo abortion, and the relative robustness of actively dividing vegetative tissue taken at the same time from the same plant subjected to the same conditions. A hypothesis is formulated, proposing drought-mediated intersecting effects on the expression of invertase genes, glucose signaling (hexokinase 1-dependent and independent), ABA-dependent and independent signaling, antioxidant responses, PCD, phospholipase C effects, and cell cycle related processes. This work was supported by the National Science Foundation Plant Genome Research Pro- gram (grant no. DBI0922747), iPlant Collaborative (NSF DBI-0735191) and also NSF ABI1062472. / Master of Science in Life Sciences

Drought

Illumina

RNA-Ser

Maize

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Leaf Meristem