脱共生作用对黑豆蚜氨基酸代谢的影响(英文)

为了解共生菌对黑豆蚜蛋白质、氨基酸代谢的影响 ,用利福平处理黑豆蚜以除去其细胞内共生细菌 ,产生脱共生蚜虫。结果表明 ,被脱去共生菌的蚜虫与未经抗生素处理的正常蚜虫相比 ,7日龄时 ,脱共生蚜虫每毫克鲜重的总蛋白含量降低了 2 9% ,每毫克鲜重的游离氨基酸含量提高了 17%。对黑豆蚜取食的蚕豆苗韧皮部组织中必需氨基酸所占的比例进行分析后发现 ,蚕豆苗韧皮部组织中的必需氨基酸含量仅占 2 0 % ,而有共生菌的黑豆蚜组织中必需氨基酸已达到 4 4% ,脱共生后降低到 37% ,这些结果证明了黑豆蚜的胞内共生菌为其寄主提供了部分必需氨基酸。通过对游离氨基酸组成的分析发现 ,在测定的 17种氨基酸中 ,必需氨基酸中的苏氨酸在共生蚜虫中所占的比例为 2 1 6 % ,在脱共生蚜虫中仅为 16 7%。同样 ,非必需氨基酸中的酪氨酸和丝氨酸 ,在共生蚜虫中分别占总游离氨基酸的 8 9%和 5 6 % ,而在脱共生蚜虫中却分别升高到 2 1 1%和 13 6 %。这些结果表明 ,各种氨基酸比例的失调 ,造成了脱共生蚜虫蛋白质合成受阻和部分游离氨基酸的积累 ,并因此导致蚜虫发育和繁殖的失调。     

刺吸式昆虫次生内共生菌的研究进展

蚜虫作为典型的刺吸式昆虫,需要以取食植物韧皮部汁液来补充营养,几乎所有蚜虫均带有一种能为其提供植物韧皮部缺失营养物质的初生共生菌Buchnera aphidicola。此外,蚜虫还可携带一种或多种次生内共生菌。在众多共生菌—寄主系统中,蚜虫与其所带内共生菌间的互作研究最为透彻。虽然次生内共生菌对寄主的存活和生殖影响并不显著,但其在寄主对环境耐受力、天敌防御能力等方面作用明显。本文在查阅大量蚜虫次生内共生菌相关文献的基础上,着重对蚜虫次生内共生菌的种类及传播规律、次生内共生菌对蚜虫表型的影响、蚜虫次生内共生菌基因组学等方面的研究现状进行综述,以求为刺吸式昆虫次生内共生菌的研究提供参考。     

毛蚜属Chaitophorus蚜虫(半翅目:蚜科:毛蚜亚科)与初级内共生菌Buchnera的演化关系

【目的】蚜虫体内共生菌种类丰富,二者关系十分密切。几乎所有蚜虫都具有一类专性的初级内共生菌Buchnera aphidicola,二者的专性共生关系使蚜虫-Buchnera成为研究共生关系演化的理想模型。本研究对蚜虫-Buchnera在低级阶元水平上的"平行演化假说"进行了验证。【方法】选取在杨属Populus或柳属Salix植物上营同寄主全周期生活的毛蚜属Chaitophorus蚜虫作为研究对象,基于不同来源的分子标记(蚜虫线粒体基因、核基因和内共生菌基因),运用最大似然法和贝叶斯法重建蚜虫和Buchnera的系统树,并利用Tree Map、Jane和Para Fit检验二者是否具有协同系统发生关系。【结果】Tree Map和Jane分析检测到毛蚜属蚜虫与Buchnera具有显著的共成种信号,Para Fit分析结果表明二者的总体关联极为显著。【结论】毛蚜属蚜虫与其初级内共生菌Buchnera在种级及以下水平上符合"平行演化假说",并且二者的演化关系不会受到寄主植物差异的影响。     

松树蜂与其共生真菌的互利共生关系

松树蜂Sirex noctilio Fabricius是一种重要的国际林业检疫性害虫,主要危害针叶树,原产欧亚大陆和北非。近100多年来,先后入侵大洋洲(新西兰和澳大利亚)、南美洲(乌拉圭、阿根廷、巴西和智利)、北美洲(加拿大和美国),以及南非。2013年8月,在中国黑龙江省内首次发现松树蜂,目前发现其主要危害樟子松。松树蜂能与一种淀粉韧革菌属Amylostereum的真菌Amylostereum areolatum(Fr.)Boidin形成严格的互利共生关系,该虫除直接钻蛀树木外,还能通过产卵行为将自身毒素腺体分泌的毒素和体内共生真菌随同虫卵一起注入寄主树木体内,形成"虫-毒-菌"3个致害因子相互协作的特殊危害方式,加速树势的衰弱并造成寄主树木死亡。本文就国内外松树蜂与其共生菌互利共生关系的研究进行了综述,分别从结构与功能的层次上对其互利共生关系进行了梳理和总结,重点阐释了松树蜂与共生菌的营养共生关系,松树蜂携带传播共生菌的机制,共生菌的种群遗传学以及松树蜂毒素和共生菌在危害寄主树木时的协同关系等。以期为开展关于松树蜂的专项研究提供一些合理的建议,同时为积极有效地防控该害虫提供科学依据。     

昆虫内共生菌在昆虫防御中的作用

共生菌在昆虫体内的生长、繁殖过程中起着十分重要的作用,如营养功能、解毒作用、调控生殖及与寄主适应性等等。近些年,一些学者提出了共生菌在寄主抵御天敌等逆境的胁迫时也具有重要的作用。其在寄主防御中的作用可分为3类:(1)昆虫体内共生菌能产生具有抗真菌作用的代谢物,能够抵御病原真菌的入侵,提高寄主的适应性。(2)昆虫抵御寄生蜂的作用与其体内的共生细菌密切相关。(3)共生菌也能产生有毒物质保护寄主免于被捕食。昆虫共生菌在寄主防御中的作用机制除了产生抗菌物质和聚酮类等有毒物质外,还可能通过与水平传播的寄生物(horizontal transmission parasites,HTPs)竞争寄主资源来直接保护寄主。对共生菌的作用的深入研究将有可能进一步明确其功能,并加以利用。     

蚜虫与体内布赫纳氏菌及其次生共生菌的相互关系

对蚜虫与其内共生细菌共生关系的研究进展进行综述。布赫纳氏菌Buchnera普遍存在于蚜虫体内特殊的菌胞中,与蚜虫形成专性共生关系,为宿主蚜虫提供多种必需氨基酸和B族维生素。蚜虫体内的菌胞数量是一个动态变量,受蚜虫体内、外环境因子的影响。在某些蚜虫体内菌胞中还发现有若干种类次生共生细菌,其功能尚不完全清楚,可能与蚜虫的生态学特征有关。对蚜虫与其体内共生菌相互关系的研究提出一些新的问题。     

昆虫体内共生物的功能及进化

<正> 一、共生的类型及研究历史 两种生活在一起的生物彼此互利的现象称为共生(symbiosis)。根据二者的空间关系可分为体外共生、体表共生和体内共生三类。体外共生的现象古已知之,如蚜虫和蚂蚁的互惠便是典型的一例。体表共生是指共生物附着在宿主的体表,如以木质植物隧道中真菌为食的刺胫小蠹能把真菌孢子携带于体壁上的菌穴     

棉田绿盲蝽微生物多样性研究

昆虫在长期的进化过程中与其体内微生物形成了互利共生的关系,共生微生物参与调节寄主的多种生命活动,例如生殖、代谢等。在黄河流域棉区绿盲蝽Apolygus lucorum是棉花的主要害虫之一。为明确绿盲蝽体内共生菌的种类与群落结构,通过HiSeq平台对棉田绿盲蝽体内共生菌的16S rRNA基因V3～V4区进行高通量测序,分析绿盲蝽体内共生菌的种类与多样性。结果显示,变形菌门Proteobacteria(89.18%)、放线菌门Actinobacteria(2.99%)、厚壁菌门Firmicutes(2.48%)为绿盲蝽的3个优势菌门。在属水平上立克次氏体Rickettsia(32.86%)、欧文氏菌属Erwinia(20.21%)为优势菌群。本文初步明确了绿盲蝽体内微生物群落的组成和动态变化,为进一步研究绿盲蝽与共生菌的相互作用提供了基础,为今后从共生菌出发防治绿盲蝽提供新思路。     

稻飞虱酵母类胞内共生菌的组织学研究进展

褐飞虱Nilaparvata lugens体内酵母类共生菌在褐飞虱生长发育和繁殖中起着重要作用,并影响着褐飞虱对寄主植物的致害性变异。该文系统总结了国内外已有的研究成果,讨论了褐飞虱共生菌的分类地位、形态特征、在寄主发育中的功能、侵染途径等,提出了开展褐飞虱生物型形成过程中体内共生菌变异的研究建议,以便利用共生菌来监测田间不同生物型褐飞虱的发生情况,最终实现控菌防虫和对不同生物型的准确预测。     

昆虫病原线虫共生细菌共生性的分子生物学研究进展

嗜线虫致病杆菌属Xenorhabdus和发光杆菌属Photorhabdus细菌隶属肠杆菌科Enterobacteriaceae,对多种害虫致病能力强,分别与斯氏属Steinernema和异小杆属Heterorhabditis昆虫病原线虫互惠共生。该两属共生细菌既存在对昆虫寄主的病原性,又存在与线虫寄主的共生性。共生细菌与其线虫寄主的共生性主要表现以下4方面：（1）细菌产生食物信号诱导滞育不取食的感染期线虫恢复;（2）细菌为线虫生长与繁殖提供营养;（3）细菌能于感染期线虫的肠道定殖与生长;（4）细菌产生杀线虫毒素杀死非共生线虫。本文综述了共生菌以上4方面的共生性及其相关的分子机制。     

Provision of riboflavin to the host aphid,Acyrthosiphon pisum,by endosymbiotic bacteria,Buchnera

Differential cDNA display and quantitative RT-PCR suggested that the riboflavin synthase complex of the aphid endosymbiont, Buchnera, is active only when the symbiotic system is maintained and well organized in young hosts. Since this finding suggested the provision of riboflavin by Buchnera, we examined the effect of dietary riboflavin on the performance of symbiotic and aposymbiotic aphids using chemically-defined diets. Our results indicate: (1) dietary riboflavin is slightly detrimental to young, symbiotic aphids; (2) dietary riboflavin is essential to aposymbiotic aphids; (3) dietary riboflavin remarkably improves the performance of aposymbiotic aphids. These results strongly suggest that young, symbiotic aphids are provided with riboflavin by their endosymbionts, Buchnera.     

Decay of mutualistic potential in aphid endosymbionts through silencing of biosynthetic loci: Buchnera of Diuraphis

Buchnera, the primary bacterial endosymbiont of aphids, is known to provision essential amino acids lacking in the hosts' diet of plant sap. The recent discovery of silenced copies of genes for tryptophan biosynthesis (trpEG) in certain Buchnera lineages suggests a decay in symbiotic functions in some aphid species. However, neither the distribution of pseudogenes among lineages nor the impact of this gene silencing on amino-acid availability in hosts has been assessed. In Buchnera of the aphid Diuraphis noxia, tandem repeats of these pseudogenes have persisted in diverse lineages, and thpEG pseudogenes have originated at least twice within this aphid genus. Measures of amino-acid concentrations in Diuraphis species have shown that the presence of the pseudogene is associated with a decreased availability of tryptophan, indicating that gene silencing decreases nutrient provisioning by symbionts. In Buchnera of Diuraphis, rates of nonsynonymous substitutions are elevated in functional trpE copies, supporting the hypothesis that pseudogene origin and persistence reflect a reduced selection for symbiont biosynthetic contributions. The parallel evolution of trpEG pseudogenes in Buchnera of Diuraphis and certain other aphid hosts suggests that either selection at the host level is not effective or that fitness in these aphids is not limited by tryptophan availability.     

Low and homogeneous copy number of plasmid-borne symbiont genes affecting host nutrition in Buchnera aphidicola of the aphid Uroleucon ambrosiae

The bacterial endosymbiont of aphids, Buchnera aphidicola, often provides amino acids to its hosts. Plasmid amplification of leucine (leuABCD) and tryptophan (trpEG) biosynthesis genes may be a mechanism by which some Buchnera over-produce these nutrients. We used quantitative polymerase chain reaction to assess the leuABCD/trpEG copy variability within Uroleucon ambrosiae, an aphid with a wide diet breadth and range. Both leuABCD and trpEG abundances are: (i) similar for aphids across 15 populations, and (ii) low compared to Buchnera from other aphid species (particularly trpEG). Consequently, the plasmid location of trpEG combined with Buchnera's chromosomal polyploidy may functionally limit, rather than increase, tryptophan production within Uroleucon ambrosiae.     

Changing partners in an obligate symbiosis: a facultative endosymbiont can compensate for loss of the essential endosymbiont Buchnera in an aphid

Almost all aphids harbour an endosymbiotic bacterium, Buchnera aphidicola, in bacteriocytes. Buchnera synthesizes essential nutrients and supports growth and reproduction of the host. Over the long history of endosymbiosis, many essential genes have been lost from the Buchnera genome, resulting in drastic genome reduction and the inability to live outside the host cells. In turn, when deprived of Buchnera, the host aphid suffers retarded growth and sterility. Buchnera and the host aphid are often referred to as highly integrated almost inseparable mutualistic partners. However, we discovered that, even after complete elimination of Buchnera, infection with a facultative endosymbiotic gamma-proteobacterium called pea aphid secondary symbiont (PASS) enabled survival and reproduction of the pea aphid. In the Buchnera-free aphid, PASS infected the cytoplasms of bacteriocytes that normally harbour Buchnera, establishing a novel endosymbiotic system. These results indicate that PASS can compensate for the essential role of Buchnera by physiologically and cytologically taking over the symbiotic niche. By contrast, PASS negatively affected the growth and reproduction of normal host aphids by suppressing the essential symbiont Buchnera. These findings illuminate complex symbiont-symbiont and host-symbiont interactions in an endosymbiotic system, and suggest a possible evolutionary route to novel obligate endosymbiosis by way of facultative endosymbiotic associations.