Functional Analysis of Water Channels in Barley Roots

Katsuhara, Maki; Akiyama, Yoshitake; Koshio, Kazuki; Shibasaka, Mineo; Kasamo, Kunihiro

doi:10.1093/pcp/pcf102

Cited by 120 publications

(128 citation statements)

References 32 publications

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“…On the other hand, salt and water stresses induced the accumulation of ZmTIP2-3 transcripts [118]. Similar findings on the dominance of symplastic water transport were obtained using transgenic tobacco plants expressing an antisense construct of the tobacco NtAQP1 gene that encodes another PIP1b isoform [25], while Barley HvPIP2;1 is a plasma membrane aquaporin and its expression was downregulated after salt stress in barley [38]. Two aquaporin-encoding transcripts were found to be down-regulated during the first 15 and 60 min of a salt treatment, respectively.…”

Section: Effects Of Water and Nutrient Stress On Aquaporinssupporting

confidence: 70%

“…The high level of expression of ZmTIP1 in maize tissues (root epidermis, root endodermis, small parenchyma cells surrounding mature xylem vessels in the root, and so on) facilitates rapid flow of water through the tonoplast to permit osmotic equilibration between the cytosol and the vacuolar content, and to permit rapid transcellular water flow through living cells when required. Specific plasma membrane aquaporins of the PIP1 subfamily are expressed in sieve elements and guard cells [37] Barley HvPIP2:1 is a plasma membrane aquaporin and its expression was down-regulated after salt stress in barley [38].…”

Section: Aquaporin Gene Expression and Diurnal Fluctuationsmentioning

confidence: 99%

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Aquaporin structure–function relationships: Water flow through plant living cells

Zhao

Shao

Chu

2008

Colloids and Surfaces B: Biointerfaces

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Plant aquaporins play an important role in water uptake and movement-an aquaporin that opens and closes a gate that regulates water movement in and out of cells. Some plant aquaporins also play an important role in response to water stress. Since their discovery, advancing knowledge of their structures and properties led to an understanding of the basic features of the water transport mechanism and increased illumination to water relations. Meanwhile, molecular and functional characterization of aquaporins has revealed the significance of their regulation in response to the adverse environments such as salinity and drought. This paper reviews the structure, species diversity, physiology function, regulation of plant aquaporins, and the relations between environmental factors and plant aquaporins. Complete understanding of aquaporin function and regulation is to integrate those mechanisms in time and space and to well regulate the permeation of water across biological membranes under changing environmental and developmental conditions.

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Section: Effects Of Water and Nutrient Stress On Aquaporinssupporting

confidence: 70%

Section: Aquaporin Gene Expression and Diurnal Fluctuationsmentioning

confidence: 99%

Aquaporin structure–function relationships: Water flow through plant living cells

Zhao

Shao

Chu

2008

Colloids and Surfaces B: Biointerfaces

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“…Its expression was generally down-regulated upon drought stress. The aquaporin PIP has been found to function in water transport through the plasma membrane in many plant species (46)(47)(48)(49). The down-regulation of the aquaporin TDF 83 in wheat leaves under drought stress may be due to an a empt to avoid the possible loss of water.…”

Section: Discussionmentioning

confidence: 99%

Identification of Differentially Expressed Genes by cDNA-AFLP Technique in Response to Drought Stress in Triticum durum

Melloul

Iraqi²,

Alaoui

et al. 2014

Food. Technol. Biotechnol.

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SummaryDrought is the single largest abiotic stress factor leading to reduced crop yields. The identifi cation of diff erentially expressed genes and the understanding of their functions in environmentally stressful conditions are essential to improve drought tolerance. Transcriptomics is a powerful approach for the global analysis of molecular mechanisms under abiotic stress. To identify genes that are important for drought tolerance, we analyzed mRNA populations from untreated and drought-stressed leaves of Triticum durum by cDNA --amplifi ed fragment length polymorphism (cDNA-AFLP) technique. Overall, 76 transcript--derived fragments corresponding to diff erentially induced transcripts were successfully sequenced. Most of the transcripts identifi ed here, using basic local alignment search tool (BLAST) database, were genes belonging to diff erent functional categories related to metabolism, energy, cellular biosynthesis, cell defense, signal transduction, transcription regulation, protein degradation and transport. The expression pa erns of these genes were confi rmed by quantitative reverse transcriptase real-time polymerase chain reaction (qRT--PCR) based on ten selected genes representing diff erent pa erns. These results could facilitate the understanding of cellular mechanisms involving groups of genes that act in coordination in response to stimuli of water defi cit. The identifi cation of novel stress-responsive genes will provide useful data that could help develop breeding strategies aimed at improving durum wheat tolerance to fi eld stress.

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“…Three PIPs: HvPIP2;1, HvPIP1;3, and HvPIP1;5, were first identified and barley PIPs were analyzed by the authors and collaborators [12]. Absolute amounts of these 3 transcripts were determined in the roots of barley seedlings.…”

Section: Water Transport Of Barley Pipsmentioning

confidence: 99%

“…During several hours to days of salt or osmotic stress, the down-regulation of several aquaporins including HvPIP2;1 was observed in many plant species [10,12,29,32]. A decrease in the level of aquaporins and reduction of Lp can prevent cell death due to continuous dehydration and gain time for intracellular osmotic adjustment.…”

Section: Water Transport Of Barley Pipsmentioning

confidence: 99%

Barley plasma membrane intrinsic proteins (PIP Aquaporins) as water and CO2 transporters

Katsuhara

Hanba

2008

Pflugers Arch - Eur J Physiol

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We identified barley aquaporins, and demonstrated that one, HvPIP2;1, transports water and CO 2 . Regarding water homeostasis in plants, regulations of aquaporin expression were observed in many plants under several environmental stresses. Under salt stress, a number of plasma-membrane type aquaporins were down-regulated, which can prevent continuous dehydration resulting in cell death. The leaves of transgenic rice plants that expressed the largest amount of HvPIP2;1 showed a 40% increase in internal CO 2 conductance compared with leaves of wild-type rice plants. The rate of CO 2 assimilation also increased in the transgenic plants. The goal of our plant aquaporin research is to determine the key aquaporin species responsible for water and CO 2 transport, and to improve plant water relations, stress tolerance, CO 2 uptake/assimilation, and plant productivity via molecular breeding of aquaporins.

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Functional Analysis of Water Channels in Barley Roots

Cited by 120 publications

References 32 publications

Aquaporin structure–function relationships: Water flow through plant living cells

Aquaporin structure–function relationships: Water flow through plant living cells

Identification of Differentially Expressed Genes by cDNA-AFLP Technique in Response to Drought Stress in Triticum durum

Barley plasma membrane intrinsic proteins (PIP Aquaporins) as water and CO2 transporters

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