作物科学中的环境型鉴定（Envirotyping）及其应用

doi:10.3864/j.issn.0578-1752.2015.17.004

摘要/Abstract

摘要： 全球气候变化正在对地球的环境产生日益重要的影响，而作物生产取决于作物基因型和环境之间的相互作用。利用现代生物学技术可以在分子水平上精细解析作物的基因型及其各个遗传组分对于表现型的贡献；然而对于作物具有重大影响的环境因子，目前，只能通过作物在不同环境下的表现型来推测其综合作用，或对整个试验区的个别环境因子进行对比分析，因而无法对各类环境因子进行深入剖析。笔者首次在国际上提出了环境型鉴定概念，并创造了一个英文新词etyping来表示。在本文中，环境型鉴定用envirotyping来代替。环境型（envirotype）用来描述包括所有影响作物不同生长发育阶段的内部和外部环境因子及其各种组合，外部环境因子主要包括水、肥、气、热、光、土壤、耕作制度和伴生生物等；而环境型鉴定用来表述对所有环境因子的解析和测定。环境型信息可以通过多种方式采集。作物多年多点区域试验积累了大量相关试验点的环境数据；地理信息系统（geographic information system，GIS）和土壤信息系统积累了大量气候、天气、土壤的数据；小型气象站可以监测小范围的天气、降雨、温度、气流等气象因子。众多环境检测仪器的使用，可以大规模采集与植物冠层、植物周边甚至单个试验小区和单个测试材料有关的土壤、光照、温度、水分、病虫害、伴生生物等外界环境因子。环境型信息将日益广泛应用于环境及其特征性鉴定、作物基因型-环境型互作、表现型预测、病虫害流行预测、近等环境型（near iso-envirotype）确定、作物对特定环境的反应研究、农艺组学（agronomic genomics）、精准高效农业等。展望未来，环境型鉴定需要将研究对象聚焦在单个材料的水平，实现单个材料的相关环境因子不同阶段的动态鉴定；需要开发和建立与基因型、表现型相结合的综合信息系统以及相应的决策支撑系统；环境型信息将最终有助于建立基于基因型-表现型-环境型的三维作物生产和研发系统，从而使未来作物育种中的选择建立在此三维空间概念的基础之上，并推动高产高效作物生产体系的建立。

关键词: 作物生产, 环境信息, 环境型, 环境型鉴定, 基因型-环境型互作, 近等环境型, 农艺组学, 表现型预测

Abstract: Global climate changes have increasing impacts on worldwide environments. Crop productivity is largely determined by interaction between the genotype a crop has and the environment surrounding the crop plants. With modern biotechnologies, genotypic contribution to a phenotype can be dissected at molecular level into individual genetic components. However, the environmental factors that have significant impacts on crops have not been dissected individually, and thus their contribution to phenotype can be only inferred by their integrative effect under different types of environments, or described for the whole experimental plot by comparing pairwise major environmental factors. The author proposed a concept of environmental assay for the first time by coining a word “etyping”, which represents “envirotyping”, a more suitable word used in this article. The term “envirotype” is used to describe all internal and external environmental factors and their combinations that affect plants across growth and developmental stages. The external environmental factors include moisture, fertilizers, air, temperature, light, soil properties, cropping system and companion organisms. Envirotyping refers to dissecting and measuring all these environmental factors. Environmental information can be collected through various approaches, including multi-environmental trials with environmental data accumulated related to trial locations; geographic and soil information systems containing environmental data for climate, weather, and soil; and small weather stations that collect factors related to weather, precipitation, temperature and air. Using remote sensing and other instruments, many external environmental factors can be measured for plant canopy, plant surroundings, and even for single plots or individual plants. Environmental information will be increasingly used for environment characterization, genotype-by-environment interaction analysis, phenotype prediction, disease epidemic prediction, near iso-environment construction, understanding of the response of plants to specific environmental factors, agronomic genomics, and precision farming. In the future, envirotyping needs to be improved to zoom into specific plots and individual plants across growth and developmental stages, along with the development of integrative information system and decision support tools to bring genotypic, phenotypic and envirotypic information together. Envirotypic information will finally contribute as a third dimension to the crop research and development system involving genotype-phenotype-envirotype complex. Such efforts will help establish a high-efficient crop breeding and production system based on the concept of the three-dimensional profile.

Key words: crop production, environmental information, envirotype, envirotyping (etyping), genotype-by-environment interaction, near iso-envirotype, agronomic genomics, phenotype prediction

徐云碧. 作物科学中的环境型鉴定（Envirotyping）及其应用[J]. 中国农业科学, 2015, 48(17): 3354-3371.

XU Yunbi. Envirotyping and Its Applications in Crop Science[J]. Scientia Agricultura Sinica, 2015, 48(17): 3354-3371.

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