营养共生

It is primarily concluded that in the alpine area, fungi infect roots of the Cypripedium species for nutrients they need for their subsistence and multiply, and the Cypripedium species use them as nutrients, thus, processing mixotrophy.

并由此对高海拔环境下二者的共生关系进行了初步的探讨：真菌侵入杓兰根部以获得自身生存和繁衍所需的营养物质，杓兰利用真菌菌丝消解后的营养物质，进行混合营养。

It would be meaningful to screen Rhizobium strains with high symbiotic nitrogen fixation activity for developing microbial manure agents.

是营养价值很高的饲用作物，也是北京地区大力发展的牧草品种之一，筛选与之共生固氮的根瘤菌，用于微生物肥料的生产，具有重要意义。

The invention relates to a method for the fast establishment of DSE and plant symbiotic culture system and the application of the method, in particular to a method for the fast establishment of dark septate endophytes and plant symbiotic culture system and the application of the method, belonging to the field of applied microbiology, plant nutrition and ecology.

本发明涉及一种快速建立DSE与植物共生培养体系的方法及其应用，具体为快速建立深色有隔内生真菌与植物共生培养体系的方法及其应用，属于应用微生物学、植物营养和生态学领域。

Dipterocarpaceae seedlings have the ability to establish the fungal symbiont, which helps them to absorb nutrients and water from mature plants and benefits to their growth, especially in the extreme deficiency of resources.

龙脑香科植物幼苗能通过与真菌形成共生体从成年植株获得营养和水分供应而生长，尤其在资源亏缺的条件下更为明显。

Dipterocarpaceae seedlings have the ability to establish the fungal symbiont, which helps them to absorb nutrients and water from mature plants and benefits to their growth, especially in the extreme deficiency of resources.

龙脑香科植物幼苗能通过与真菌形成共生体从成年植株获得营养和水分供应而促进幼苗生长，尤其在资源亏缺的条件下更为明显。

The results showed that at the beginning stage of being attacked by Chinesis white pine beetle and their symbiotic blue-stain fungus, PAL, PPO, SOD activities and MDA content significantly increased in the phloem of P. armandi, and decreased with the increase of the number of D. armandi and the attacking on the xylem and phloem of P. armandi from blue-stain fungus, then reached the minimum level in withering stage of P. armandi. But the contents of nutrition materials in the phloem, such as water, protein, glucide, fat, amylum and so on, declined with the infestation of D. armandi and symbiotic fungus. In summary, the resistance of physiology and biochemistry in the phloem of P.

结果表明，在华山松大小蠹和共生蓝变真菌危害初期，华山松韧皮部内的苯丙氨酸解氨酶、多酚氧化酶、超氧化物歧化酶活性均显著提高，丙二醛含量明显增加；但随着华山松大小蠹种群数量的增加和蓝变真菌对华山松韧皮部和木质部组织危害的加剧，韧皮部组织内的PAL、PPO和SOD活性逐渐降低，在枯立木阶段降至最低；与此同时，华山松韧皮部内的水分及蛋白质、糖类、粗脂肪、淀粉等营养物质含量，则随华山松大小蠹和共生蓝变真菌危害的加剧而不断减少。

Mycorrhiza is a mutualistic symbiosis between plants and fungi, and ectomycorrhiza is an important type of mycorrhiza.

菌根是一种植物营养根与土壤真菌形成的共生体，在自然界中分布广泛。

Mycorrhiza is a mutualistic symbiosis between plants and fungi, and ectomycorrhiza is an important type of mycorrhiza.

菌根是一种植物营养根与土壤真菌形成的共生体，在自然界中分布广泛。外生菌根真菌是菌根真菌的重要类群，其宿主植物约占陆地植物总数的3%左右。

There were a great deal of kinds of the grass with high quality and quantity fed to fish To determine the best symbiosis ecosystem of fish and grass on a closed system circulated yearly, several cold and warm grass was selected to analyse the adaptability and nutrition absorbed. It indicted that Lolium multiform Lam. and lemarthria compressa were the best option due to high adaptability of wetness, high coarse protein, fat and fibre and so on in the leaf, high biomass, high bio-filtration effect of N and P, adaption to the low or high temperature, resist to the plant diseases and insect pests, and the food of fish whose forage was grass.

鱼用优质高产牧草的种类繁多，为确定最佳的鱼草共生周年循环系统，本文选择几种冷季牧草和暖季牧草进行生长适应性与营养吸收研究，分析表明，多花黑麦草和扁穗牛鞭草是最佳的冷季牧草和暖季牧草，它们耐水性强，叶片中所含的粗蛋白、粗脂肪、粗纤维等化学成分高，植株的生物量也高，生物过滤养殖废水中的氮和磷效果好，而且可以适应外界环境的低温或高温，抵抗病虫侵害，同时为草食性鱼类喜欢食用。

In this paper five strains of Arbuscular mycorrhizal fungi inoculums were used in organic soil before tomato seed sowing.

丛枝菌根是生活在陆生植物根际的有益共生微生物，大多数作物、蔬菜、果树和观赏植物均可形成丛枝菌根共生体〔1，2〕，由于有机栽培下营养物质转化吸收不如化肥效果迅速，不能完全满足蔬菜生长需求，因此产量一般较低。

commensalism：偏利共生

在自然界,两种生物在一起生活的现象非常普遍. 这种现象是生物在长期演化过程中逐渐形成的,称为共生(symbiosis). 从营养、居住和利害关系看,生物种间的共同生活方式一般可分为互利共生(mutual-ism)、偏利共生(commensalism)和寄生(parasitism)三种类型.

oscillation：振动

认为H+流的振动(oscillation)可能参与了根的回旋转头运动. 菌根是土壤中特有的真菌与植物根的共生联合体. 植物有了菌根,就可以通过无数细长菌丝和菌索吸收土壤中的营养和水分,扩大根系的吸收面积,提高吸收能力.

rhizobium：根瘤菌

此类特异性微生物转而通过分泌高铁载体 (Siderophore),增加土壤中铁的生物有效性,从而提高了根系对铁的吸收.此外,与植物根系共生的一些微生物也会改善植物的铁营养,这种作用可能包括: 根瘤菌 (Rhizobium) 的结瘤作用,增强植物耐缺铁的生理响应;

Rhizobium japonicum：大豆根瘤菌

共生固氮微生物技术发挥其特定功能作用不可忽视,那就是大豆根瘤菌(Rhizobium japonicum)与大豆植物建立了互为有利的共生关系,这种共生的特殊性就是固定大气游离的氮素(N2),为双方营养之所需.

syntrope, syntrophism：营养共生

"合成醋","synthetic vinegar" | "营养共生","syntrope, syntrophism" | "虹吸,虹吸管","syphon, siphon"

trophobiosis：取食共生, 营养共生

saturation adsorption 饱和吸附 | trophobiosis 取食共生, 营养共生 | installment delivery 分期交货

trophobiosis：取食共生

trophic nucleus 营养核 | trophobiosis 取食共生 | trophoblast 滋养层

trophobiosis：营养共生

trophiclevel 生态食性层次 | trophobiosis 营养共生 | trophoblast 滋养母细胞

rhizobia：根瘤菌

丛枝菌根真菌(Arbuscular Mycorrhizal Fungi,AMF)-豆科植物-根瘤菌(Rhizobia)三者形成的共生体,是植物与微生物共生中的一种特殊类型.本文对这种共生体中微生物与植物之间的营养关系;AMF和根瘤菌双接种豆科植物的效应以及影响双接种效应的因素;

root nodule bacteria：根瘤菌

根瘤菌(root nodule bacteria)是与豆科植物共生.形成根瘤并固定空气中的氮气供植物营养的一类杆状细菌.这种共生体系具有很强的固氮能力.已知全世界豆科植物近两万种.根瘤菌是通过豆科植物根毛.侧根杈口(如花生)或其他部位侵入.形成侵入线.进到根的皮层.刺激宿主皮层细胞分裂.形成根瘤.根瘤菌从侵入线进到根瘤细胞.继续繁殖.