利用Videometer多光譜成像系統(tǒng)構(gòu)建的Radimax系統(tǒng)用于植物深根研究

    前言：Videometer公司是多光譜成像系統(tǒng)生產(chǎn)商，開(kāi)發(fā)了系列多光譜成像設(shè)備如VideometerLab 4多光譜成像系統(tǒng)、VideometrMR根系多光譜成像系統(tǒng)、VideometerLiq固、液兩用多光譜成像系統(tǒng)并與丹麥歌本哈根大學(xué)聯(lián)合開(kāi)發(fā)了Radimax深根研究用多光譜成像系統(tǒng)，目前利用Videometer系統(tǒng)發(fā)表的文章已經(jīng)超過(guò)了250篇，是當(dāng)前表型研究領(lǐng)域發(fā)表文章多、應(yīng)用廣泛的多光譜成像系統(tǒng)。

摘要

    背景: 根是植物的關(guān)鍵器官，要實(shí)現(xiàn)產(chǎn)量穩(wěn)定，有效利用來(lái)自土壤資源至關(guān)重要。但作物基因型之間的根性狀表型變異多數(shù)還未知，田間根系發(fā)育篩查昂貴且耗力。因此，函待開(kāi)發(fā)在田間進(jìn)行全生長(zhǎng)植物根系性狀、特別是位于土壤深層的根系研究的新方法。

    結(jié)果: 研究人員開(kāi)發(fā)了一種新型表型設(shè)施(RadiMax)用于在半田間條件下研究根系生長(zhǎng)以及土壤資源獲取。設(shè)施包括4個(gè)單元，每個(gè)單元面積為400m²，分別安裝有150根微根管，允許對(duì)0.4 m–1.8 m或 0.7 m–2.8 m土壤深度間隔的根進(jìn)行觀察。根系觀測(cè)通過(guò)多光譜微根光成像系統(tǒng)實(shí)現(xiàn)。植物生長(zhǎng)行與水分梯度垂直，設(shè)施安裝有多深度亞灌溉系統(tǒng)以及移動(dòng)雨棚。水梯度可實(shí)現(xiàn)將根觀測(cè)與冠層脅迫反應(yīng)進(jìn)展相關(guān)聯(lián)。 

    結(jié)論:要驗(yàn)證以上技術(shù)概念，選擇了栽培種春大麥 (Hordeum vulgare L.) ，種植在該系統(tǒng)中進(jìn)行為期兩季的研究。利用該系統(tǒng)可觀測(cè)到不同深根生長(zhǎng)基因型差異，在水梯度下，可觀測(cè)到地上部的生理反應(yīng)。盡管進(jìn)一步技術(shù)開(kāi)發(fā)和技術(shù)驗(yàn)證還在進(jìn)行中，半田間設(shè)施不失為一種在土壤深層鑒別土壤資源有效利用的根基因差異的新方法。

關(guān)鍵詞: 干旱，微根管，氮元素，表型，根，半田間土壤，水

補(bǔ)充：北京博普特科技有限公司是丹麥Videometer公司中國(guó)區(qū)總代理，全面負(fù)責(zé)其系列多光譜成像設(shè)備在中國(guó)市場(chǎng)的推廣、銷(xiāo)售和售后服務(wù)。

Construction of a large-scale semi-feld facility to study genotypic diferences in deep root growth and resources acquisition

Simon Fiil Svane1*，Christian Sig Jensen2 and Kristian ThorupKristensen1

Abstract 

    Background: Roots are vital organs for plants, and the efective use of resources from the soil is important for yield stability. However, phenotypic variation in root traits among crop genotypes is mostly unknown and feld screening of root development is costly and labour demanding. As a consequence, new methods are needed to investigate root traits of fully grown crops under feld conditions, particularly roots in the deeper soil horizons.

    Results: We developed a new phenotyping facility (RadiMax) for the study of root growth and soil resource acquisi tion under semi-feld conditions. The facility consists of 4 units each covering 400 m2 and containing 150 minirhizo trons, allowing root observation in the 0.4 m–1.8 m or 0.7 m–2.8 m soil depth interval. Roots are observed through minirhizotrons using a multispectral imaging system. Plants are grown in rows perpendicular to a water stress gradi ent created by a multi-depth sub-irrigation system and movable rainout shelters. The water stress gradient allows for a direct link between root observations and the development of stress response in the canopy.

    Conclusion: To test the concept and technical features, selected spring barley (Hordeum vulgare L.) c*rs were grown in the system for two seasons. The system enabled genotypic diferences for deep root growth to be observed, and clear aboveground physiological response was also visible along the water stress gradient. Although further technical development and feld validation are ongoing, the semi-feld facility concept ofers novel possibilities for characterising genotypic diferences in the efective use of soil resources in deeper soil layers. Keywords: Drought, Minirhizotron, Nitrogen, Phenotyping, Root, Semi-feld, Soil, Water