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Plantarray植物(wu)高通量生理學特征監測系統

一套高通量、以植物生理學為基礎的高精度表型系統，可以完成整個植物生長周期中不同環境下的SPAC因子的測量。

以色列(lie)Plant-DiTech公司的(de)Plantarray監(jian)測系統是(shi)一套高通(tong)量(liang)(liang)，以植(zhi)(zhi)(zhi)物(wu)生(sheng)理學為基礎的(de)高精度表型(xing)系統，可以完成整(zheng)個(ge)植(zhi)(zhi)(zhi)物(wu)生(sheng)長周期(qi)中不(bu)同環境下的(de)SPAC（Soil-Plant-Atmosphere Continuum， 土壤(rang)植(zhi)(zhi)(zhi)物(wu)大氣連續(xu)(xu)體）因子的(de)測量(liang)(liang)。連續(xu)(xu)不(bu)間斷的(de)獲(huo)取陣列(lie)內(nei)所有植(zhi)(zhi)(zhi)物(wu)的(de)監(jian)測數(shu)據，實時監(jian)控和及時調整(zheng)每個(ge)培(pei)養(yang)容器中的(de)土壤(rang)條件(jian)，包(bao)含土壤(rang)水分(fen)、鹽分(fen)。

Israeli Center of Research Excellence facility in Rehovot

>>Plantarray監測系統的主要優點<<

? 生理學特征的監測和數據高通量分析，如生長速率、蒸騰速率、水分利用率、氣孔導度等特征；

? 連續控制不同的土壤和水分環境（如干旱、鹽分或化學物質）；

? 理想的實驗平臺：

? 3-4周的實驗相當于4-6個月的人工工作；

? 操作簡單，維護費用幾可忽略；

? 靈活的設計能夠滿足任何溫室中不同方面的科學研究需求。

? 實時統計分析-為了數據的可靠快速分析，提供多階乘ANOVA或配對T檢驗；

? 實驗目的-在實驗運行中為了確保處理的效果可以獲取最優化的實驗參數；

? 快速定量選擇-提供植物對于不同環境需求生理反應的評級和評分的簡況；

? 復雜實驗通過簡要圖像呈現生理參數與環境條件的空間和時間關系，顯示趨勢、異常和比率。

>>Plantarray監測系統應(ying)用領域(yu)<<

? 非生物逆境脅迫研究，比如：干旱、淹水、營養、有毒物質等脅迫研究；

? 在農作物、蔬菜、樹木、藥用植物、燃料作物等方面的育種研究；

? 根系的土壤穿透力、水通量研究；

? 生物激素與養分研究；

? 生理生態學研究等。

>>Plantarray監測(ce)(ce)系統測(ce)(ce)量參數<<

? 直接測量特性：

? 計算特性：

>>參(can)考(kao)文獻<<

Negin et. al., (2016) The advantages of functional phenotyping in pre-field screening for drought-tolerant crops. Functional Plant Biology DOI: 10.1071/FP16156.

Faber et. Al., (2016) Cytokinin activity increases stomatal density and transpiration rate in tomato. Journal of Experimental Botany DOI: 10.1093/jxb/erw398.

Halperin et. Al., (2016) High-throughput physiological phenotyping and screening system for the characterization of plant–environment interactions. The Plant Journal 10.1111/tpj.13425.

Xu et. al., (2015) Natural variation and gene regulatory basis for the responses of asparagus beans to soil drought. Frontiers in plant sciences DOI: 10.3389/fpls.2015.00891.

Lugassi et. al., (2015) Expression of Arabidopsis Hexokinase in Citrus Guard Cells Controls Stomatal Aperture and Reduces Transpiration. Frontiers in plant sciences DOI:10.3389/fpls.2015.01114.

Moshelion and Altman, (2015) Current challenges and future perspectives of plant and agricultural biotechnology. Trends in Biotechnology. 33, 337-342.

Moshelion et. al., (2014) Role of aquaporins in determining transpiration and photosynthesis in water-stressed plants: crop water-use efficiency, growth and yield. Plant Cell & Environment DOI: 10.1111/pce.12410.

Bedada et. al., (2014) Transcriptome sequencing of two wild barley (Hordeum spontaneum L.) ecotypes differentially adapted to drought stress reveals ecotype-specific transcripts. BMC Genomics DOI: 10.11861471-2164-15-995.

Tracy Lawson et. al., (2014) Mesophyll photosynthesis and guard cell metabolism impacts on stomatal behavior. New Phytologist DOI: 10.1111nph.12945.

Kelly et. al., (2014) Relationship between hexokinase and the aquaporin PIP1 in the regulation of photosynthesis and plant growth. PLoS One. 9 : DOI:10.1371/ journal.pone.0087888.

Kelly et. al., (2013) Hexokinase mediates stomatal closure. The Plant Journal 75, 977–988 DOI: 10.1111/tpj.12258.

Nir et. al., (2013) The Arabidopsis gibberellin methyl transferase 1 suppresses gibberellin activity, reduces whole-plant transpiration and promotes drought tolerance in transgenic tomato. Plant cell and Environment 37, 113–123.

Sade et. Al., (2012) Risk-taking plants: Anisohydric behavior as a stress-resistance trait. Plant Signaling & Behavior DOI org/10.4161/psb.20505.

Sade et. al., (2010) The Role of Tobacco Aquaporin1 in Improving Water Use Efficiency, Hydraulic Conductivity, and Yield Production Under Salt Stress. Plant Physiology 152:1-10.

Wallach et. al., (2010) Development of synchronized, autonomous, and self-regulated oscillations in transpiration rate of a whole tomato plant under water stress. Journal of Experimental Botany 61:3439–3449.

Sade et. al., (2009) Improving plant stress tolerance and yield production: is the tonoplast aquaporin SLTIP2;2 a key to isohydric to anisohydric conversion? New Phytologist. 181: 651–661.