豌豆-玉米216和豌豆-玉米18的生物学性状比较

将豌豆的染色体及其片段作为供体,玉米细胞作为受体,在一定的条件下导入到受体玉米的细胞中,和受体细胞的玉米染色体进行染色体杂交,形成豌豆-玉米的杂交染色体,并分化培育获得豌豆-玉米染色体杂交植株。这些杂交植株产生剧烈变异,与对照玉米比较,其茎秆、叶片、果穗、籽粒等生物学性状均发生明显变化,由这些变异株中选育了两个不同的株系。对其中的豌豆-玉米216和豌豆-玉米18杂交植物的制作和生物学性状的比较作一简要的分析报道。

覆膜对玉米间作豌豆干物质积累与分配的影响

分别对玉米、豌豆带进行覆膜、不覆膜处理做大田试验,研究豌豆-玉米间作体系的产量和干物质积累与分配的变化。结果表明：覆膜比不覆膜显著提高了作物的籽粒产量和生物学产量。单作覆膜比不覆膜玉米增产9%,豌豆增产21%;间作经济产量,玉米覆膜豌豆不覆膜处理的玉米比间作无膜处理的玉米增产11.70%,全膜覆盖比间作无膜处理的豌豆增产24.40%。土地当量比（LER）除玉米不覆膜豌豆覆膜的小于1外,其他处理LER为1.09～1.24,表现出明显的间作优势。两作物养分向籽粒的转移率和贡献率均为茎大于叶,覆膜提高了干物质向籽粒的转移率和贡献率。玉米覆膜豌豆不覆膜处理是本研究中间作优势最明显的覆膜方式,而玉米不覆膜豌豆覆膜处理会造成资源浪费,不利于豌豆-玉米间作体系的产量积累。

带型及施氮水平对玉米间作豌豆群体光分布的影响

【目的】针对绿洲灌区优化间作群体受光结构缺乏理论依据,间作增产技术依据不足等问题,旨在为构建利于提高光能利用率的间作模式提供理论依据.【方法】以玉米间作豌豆为研究对象,在不施氮、传统施氮量减施1/3、传统施氮量和3∶4带型(3行玉米∶4行豌豆)、2∶4带型(2行玉米∶4行豌豆)配置下,研究了玉米间作豌豆群体内的光分布及消光特征.【结果】在整个生育期,与单作相比,间作有利于群体内的光分布,间作底层光强高于单作,豌豆高25.7%~156.7%,玉米高50%~316.2%.间作底部的透光率也高于单作,豌豆高51.2%~55.9%,玉米高236.9%~237.8%.豌豆上部第2层光强间作比单作高32.4%~103.0%,玉米高1.1%~39.5%.随施氮量的增加底层透光率降低,3∶4和2∶4传统施氮间作处理较减施1/3氮肥和不施氮间作模式冠层底部光强低,且3∶4间作处理的受光结构优于2∶4间作处理.【结论】玉米/豌豆间作为3∶4带型,施肥量为450kg/hm2是最适宜试区玉米/豌豆间作群体光照结构的模式参数.

高等植物的第三类杂交——染色体杂交

本文综述了高等植物的三种类型的杂交,并着重介绍了第三类杂交——染色体杂交的基本原理、技术路线和笔者得到的一些成果,及其与花粉传粉杂交、原生质体融合杂交和基因工程的区别与联系.

再论高等植物染色体杂交

本文介绍了人类至今研究和创新染色体的简要过程,探讨了植物杂交的定义,说明了染色体杂交作物安全性的原因.

Emergy assessment of three home courtyard agriculture production systems in Tibet Autonomous Region, China

Home courtyard agriculture is an important model of agricultural production on the Tibetan plateau. Be- cause of the sensitive and fragile plateau environment, it needs to have optimal performance characteristics, including high sustainability, low environmental pressure, and high economic benefit. Emergy analysis is a promising tool for evaluation of the environmental-economic performance of these production systems. In this study, emergy analysis was used to evaluate three courtyard agricultural production models： Raising Geese in Corn Fields （RGICF）, Con- ventional Corn Planting （CCP）, and Pea-Wheat Rotation （PWR）. The results showed that the RGICF model produced greater economic benefits, and had higher sustainability, lower environmental pressure, and higher product safety than the CCP and PWR models. The emergy yield ratio （EYR） and emergy self-support ratio （ESR） of RGICF were 0.66 and 0.11, respectively, lower than those of the CCP production model, and 0.99 and 0.08, respectively, lower than those of the PWR production model. The impact of RGICF （1.45） on the environment was lower than that of CCP （2.26） and PWR （2.46）. The emergy sustainable indices （ESIs） of RGICF were 1.07 and 1.02 times higher than those of CCP and PWR, respectively. With regard to the emergy index of product safety （EIPS）, RGICF had a higher safety index than those of CCP and PWR. Overall, our results suggest that the RGICF model is advantageous and provides higher environmental benefits than the CCP and PWR systems.