1株高效花生根瘤菌的筛选与鉴定

从辽宁多地花生种植土壤及其鲜根瘤初步筛选到30株花生根瘤菌,进一步通过回接盆栽花生,测定花生根瘤数、根瘤干重,以及鲜根瘤固氮酶活性、植株全氮量等,筛选出1株结瘤固氮能力较强花生根瘤菌wz-6,通过16S rDNA序列分析,鉴定为圆明慢生根瘤菌(Bradyrhizobium yuanmingense)。为开发优质花生根瘤菌菌剂奠定基础。     

刺槐核糖体蛋白同源基因RpRPL22在共生结瘤过程中功能研究

目的: 核糖体蛋白(RPs)属于多功能蛋白,能够参与调控细胞生长和响应胁迫条件。RpRPL22是一个从豆科植物刺槐中分离得到的结瘤相关基因,通过序列比对发现其与核糖体大亚基蛋白RPL22高度同源。对其如何通过调控根瘤菌侵染而在共生结瘤过程中发挥重要作用进行了较为深入的探索。方法: 利用实时荧光定量PCR技术(qRT-PCR)分析RpRPL22在接菌后不同时间及不同植物组织的表达变化。利用cDNA末端快速扩增技术(RACE)获得目的基因cDNA全长。通过GFP报告基因进行RpRPL22亚细胞定位分析。通过Gateway BP重组技术构建RNA干扰(RNAi)重组载体,借助电转化法将重组载体转至农杆菌K599,利用农杆菌介导植物根部,接菌后观察和测量植株表型。首先从宏观水平统计观察目的基因是否对结瘤过程有影响,其次从分子水平揭示目的基因在共生结瘤过程的重要功能。结果: 不同接菌时期、不同植物组织目的基因qRT-PCR相对表达量结果显示,几乎在所有取样的接菌时间,目的基因RpRPL22在接菌根中的相对表达量都低于未接菌对照根,只有接菌后第25天除外。在成熟的根瘤中,接菌后第25天该基因的表达量也最高。洋葱表皮和毛状根亚细胞定位结果均显示在椰菜花叶病毒(CaMV)的35S启动子控制下,RpRPL22融合绿色荧光蛋白GFP的荧光信号在细胞核和细胞质有明显的表达。RNAi转化植株的表型统计观察结果,比如植株鲜重、植株的有效结瘤数目较对照组均有明显的降低;同时RNAi转化植株在根瘤菌侵染过程形成的侵染线数目和根瘤原基数目较对照均显著降低。根瘤切片实验用于观察根瘤显微超微结构,结果显示RNAi植株根瘤中固氮区的受菌侵染细胞数目与对照相比明显减少。电镜观察根瘤单个受菌侵染细胞中类菌体形态显示,RNAi根瘤中类菌体侵染细胞胞体多呈不规则形状,皱缩变形严重,环类菌体周间隙空间增大,多共生体融合,表现出细胞凋亡的迹象。对照根瘤中的受菌侵染细胞胞体多呈圆形椭圆形,胞质饱满丰富且分布均匀,细胞发育正常,表明RNAi植株根瘤发育过程明显受阻。结论: 核糖体蛋白(RP)能够参与调控豆科植物共生结瘤过程,相关同源基因RpRPL22可能在起始根瘤菌侵染植物和阻止类菌体降解过程中起重要作用。     

银合欢和苏门答腊金合欢根瘤菌的分离和回接

从银合欢和苏门答腊金合欢的根瘤各分离出三个快生型的根瘤菌,对其形态作了初步的观察。这些根瘤菌可能是同一族的,它们对其寄主植物进行回接和互接均能引起银合欢和苏门答腊金合欢结根瘤,互接形成的根瘤形态与寄主植物的根瘤相同;箭舌豌豆和武宁苕子的根瘤菌不能引起银合欢和苏门答腊金合欢植株结根瘤;分离得到的根瘤菌对银合欢和苏门答腊金合欢均有反馈的增益作用,几个生物学指标均比对照的高;在无菌条件下,全氮培养抑制了根瘤菌对寄主植物结瘤,琼脂固体培养的植株根瘤固氮活性比沙培、水培的高。     

2,4-D诱导固氮螺菌和慢生型大豆根瘤菌在小麦上的结瘤作用及其效果

分别在水培和砂培条件下进行了2,4-D诱导固氮螺菌和慢生型大豆根瘤菌在小麦根上的结瘤试验,结果表明2,4-D能诱发它们在小麦根系上形成“类根瘤”,扫描电镜结果证明只有个别细菌进入小麦根瘤细胞内,在细胞间隙有较多的细菌。用乙炔还原法仅检测到接种大豆根瘤菌的小麦根瘤有微量的固氮酶活性,但在盆栽植株的生长方面,看不到2,4-D,2,4-D+固氮螺菌或2,4-D+根瘤菌对小麦生长的促进作用。     

磁场对大豆共生固氮的效应

恒定磁场处理慢生大豆根瘤菌“005”和接种后的大豆植株,发现磁场可以提高根瘤的固氮活性。在一定的磁场强度(70—100mT)下,固氮活性平均可以提高4—5倍,植株的结瘤数和根瘤重量平均提高2—3倍。从这样的根瘤中所分离出的根瘤菌,由慢生型转变成快生型,在100植株中有17株的根瘤分离出快生菌。生长世代时间和培养溶液中的pH值与慢生型不同,而与快生型相同。     

Rpfan37在刺槐共生结瘤过程中的功能探究

目的:研究刺槐中与磷脂酰肌醇转运蛋白有较高同源性的基因Rpfan37的功能,为探究相关基因参与豆科植物与根瘤菌共生结瘤过程提供新的思路。方法:通过前期研究,建立豆科植物刺槐与共生根瘤菌互作的抑制差减杂交反交文库,筛选疑似与共生结瘤相关的基因。利用PCR技术快速克隆经实时荧光定量PCR技术(qRT-PCR)分析基因在不同接菌时间及不同植物组织的表达。构建RNA干扰(RNAi)重组载体,转农杆菌介导转化植物根部,接种根瘤菌后验证该基因在刺槐共生结瘤过程的功能。结果:基因表达分析显示,在接菌与未接菌的刺槐根中,处理后第15天,Rpfan37表达均显著上调,但接菌与未接菌处理对该基因表达无显著影响;在成熟的根瘤中,该基因仅为低水平表达。RNAi转化植株的鲜重、株高、根长及结瘤数较对照组显著降低。在显微镜下观察到RNAi植株根毛发育异常;与对照相比,RNAi转化植株形成的根毛卷曲、根毛侵染线及根瘤原基数目均显著降低。根瘤石蜡切片结果显示RNAi植株根瘤中的侵染细胞与对照相比明显减少,分析豆血红蛋白表达发现,RNAi植株中根瘤发育成熟过程明显受阻。结论:在豆科植物刺槐中发现的相关基因Rpfan37能够参与刺槐共生结瘤过程,为研究磷脂酰肌醇转运蛋白在共生结瘤过程中的作用提供了新的理论基础。     

一氧化氮对豆科植物结瘤及固氮的影响机制

豆科植物-根瘤菌共生过程受双方基因复杂且精细的调控, 能够产生特异的根瘤结构并可将大气中的惰性氮气(N₂)转化为可被植物直接利用的氨态氮。结瘤与固氮受多种因素影响, 其中, 一氧化氮(NO)作为一种自由基反应性气体信号分子, 可参与调节植物的许多生长发育过程, 如植物的呼吸、光形态建成、种子萌发、组织和器官发育、衰老以及响应各种生物及非生物胁迫。在豆科植物中, NO不仅影响寄主与菌共生关系的建立, 还参与调控根瘤菌对氮气的固定并提高植株氮素营养利用效率。该文主要从豆科植物及共生菌内NO的产生、降解及其对结瘤、共生固氮的影响和对环境胁迫的响应, 阐述了NO调控豆科植物共生体系中根瘤形成和共生固氮过程的作用机制, 展望了NO信号分子在豆科植物共生固氮体系中的研究前景。     

抗药突变菌株的筛选及其回收测定

近年来,对豆科植物需要快速形成有效根瘤的接种剂越来越受人们注意。如果植株在生长早期形成人工接种的根瘤,它就能充分发挥接种剂的固氮效能。为了研究接种剂对某一豆科植物的结瘤率和所接的根瘤菌在土壤及根际的分布状况,七十年代已开始采用血清技术(Date 1974)和     

大豆-根瘤菌共生体系光合与固氮关系研究

水培大豆和田间生长的大豆,接种根瘤菌 Rhizobium B16-11C 后植株全氮含量、叶片叶绿素含量和净光合速率及种子产量都明显增加。比较 Clark 大豆的结瘤品系和不结瘤品系获类似结果。摘除根瘤后3天内叶片净光合速率无明显变化。大豆植株遮阴、去叶或切掉地上部导致根瘤活性明显下降。但去豆荚不能提高根瘤固氮的比活性。根瘤活性的日变化不能用根瘤蔗糖、淀粉含量或周围温度的变化来解释,其控制因子尚待深入研究。     

马桑结瘤固氮与光合作用的关系

马桑(Coriaria sinica)植株的结瘤量、根瘤固氮活性和固氮能力均与植株叶面积和光合能力呈显著的直线相关关系,叶面积大、光合能力强的植株结瘤量大,根瘤固氮活性高,固氮能力强。马桑根瘤固氮活性呈白天升高夜间降低的昼夜变化特点,昼夜变幅为10～20μmol C2H2/g.h,光合作用是引起固氮活性昼夜变化的主要因素,同时受土壤温湿度的影响,遮阴或光照不足将引起马桑结瘤固氮能力的大幅度降低。     

Competition between rhizobia under different environmental conditions affects the nodulation of a legume

Mutualistic symbiosis and nitrogen fixation of legume rhizobia play a key role in ecological environments. Although many different rhizobial species can form nodules with a specific legume, there is often a dominant microsymbiont, which has the highest nodule occupancy rates, and they are often known as the “most favorable rhizobia”. Shifts in the most favorable rhizobia for a legume in different geographical regions or soil types are not well understood. Therefore, in order to explore the shift model, an experiment was designed using successive inoculations of rhizobia on one legume. The plants were grown in either sterile vermiculite or a sandy soil. Results showed that, depending on the environment, a legume could select its preferential rhizobial partner in order to establish symbiosis. For perennial legumes, nodulation is a continuous and sequential process. In this study, when the most favorable rhizobial strain was available to infect the plant first, it was dominant in the nodules, regardless of the existence of other rhizobial strains in the rhizosphere. Other rhizobial strains had an opportunity to establish symbiosis with the plant when the most favorable rhizobial strain was not present in the rhizosphere. Nodule occupancy rates of the most favorable rhizobial strain depended on the competitiveness of other rhizobial strains in the rhizosphere and the environmental adaptability of the favorable rhizobial strain (in this case, to mild vermiculite or hostile sandy soil). To produce high nodulation and efficient nitrogen fixation, the most favorable rhizobial strain should be selected and inoculated into the rhizosphere of legume plants under optimum environmental conditions.     

Failure to fix nitrogen by non-reproductive symbiotic rhizobia triggers host sanctions that reduce fitness of their reproductive clonemates

The legume-rhizobia symbiosis is a classical mutualism where fixed carbon and nitrogen are exchanged between the species. Nonetheless, the plant carbon that fuels nitrogen (N(2)) fixation could be diverted to rhizobial reproduction by 'cheaters'--rhizobial strains that fix less N(2) but potentially gain the benefit of fixation by other rhizobia. Host sanctions can decrease the relative fitness of less-beneficial reproductive bacteroids and prevent cheaters from breaking down the mutualism. However, in certain legume species, only undifferentiated rhizobia reproduce, while only terminally differentiated rhizobial bacteroids fix nitrogen. Sanctions were, therefore, tested in two legume species that host non-reproductive bacteroids. We demonstrate that even legume species that host non-reproductive bacteroids, specifically pea and alfalfa, can severely sanction undifferentiated rhizobia when bacteroids within the same nodule fail to fix N(2). Hence, host sanctions by a diverse set of legumes play a role in maintaining N(2) fixation.     

Changes in ascorbate peroxidase, catalase, guaiacol peroxidase and superoxide dismutase activities in common bean (Phaseolus vulgaris) nodules under salt stress

To analyse nodular antioxidant enzyme expression in response to salt stress, Phaseolus vulgaris genotype BAT477 was inoculated with reference strain CIAT899, and treated with 50 mM NaCl. Plant growth, nodulation and nitrogen fixing activity were analysed. Results showed that: (1) all parameters, particularly in nodules, were affected by salt treatments, and (2) confirmed preferential growth allocation to roots. The ARA was significantly decreased by salt treatments. Protein dosage confirmed that nodules were more affected by salt treatment than were roots. We analysed superoxide dismutase, catalase, ascorbate peroxidase and peroxidase in nodules, roots and a free rhizobial strain. Our results indicated that SOD and CAT nodular isozymes had bacterial and root origins. The SOD expressed the same CuZn, Fe and Mn SOD isoforms in nodules and roots, whereas in free rhizobia we found only one Fe and Mn SOD. APX and POX nodule and root profiles had only root origins, as no rhizobial band was detected. Under salt stress, plant growth, nitrogen fixation and activities of antioxidant defense enzymes in nodules were affected. Thus, these enzymes appear to preserve symbiosis from stress turned out that NaCl salinity lead to a differential regulation of distinct SOD and POX isoenzyme. So their levels in nodules appeared to be consistent with a symbiotic nitrogen fixing efficiency hypothesis, and they seem to function as the molecular mechanisms underlying the nodule response to salinity.     

Growth, nutrition, and nitrogen fixation in grey alder at varied rate of nitrogen addition

Seedlings of grey alder (Alnus incana Moench), nodulated or unnodulated, were investigated at varied relative addition rate of nitrogen. Nitrogen fixation alone, without addition of mineral nitrogen, resulted in an almost optimum nitrogen status but only about half the maximum relative growth rate, probably mainly because of energy costs of nodulation and fixation. The growth deficit due to nodulation was much more than can be explained by the theoretical energy requirement for the amount of nitrogen fixed. Thus, the nitrogen fixation process was not very efficiently used. The nitrogen fixation rate was strongly stimulated by increasing nitrogen addition rate up to high levels. The fixation rate decreased rapidly close to optimum (maximum relative growth rate) and was negligible at maximum growth. A feed-back of mineral nitrogen on photosynthesis increased fixation rate with time, and the relative importance of fixation over mineral nitrogen nutrition increased. However, nitrogen fixation, also at maximum rate, supplied only a small proportion of the nitrogen amount required for maximum growth. The optimum nutrient solutions contained comparatively high nitrogen concentrations to secure free access to nitrogen. The nodules were damaged by this treatment, and it is concluded that the nitrogen additions must be adjusted to the current consumption of the plants to avoid an increased external nitrogen concentration. Strong linear regressions were found between relative growth rate, nitrogen status expressed as percentage content of fresh weight, and relative growth rate in unnodulated seedlings. There was a greater variability in nodulated seedlings than in unnodulated ones, because of the nitrogen fixation. The reactions of unnodulated grey alder were largely the same as previously reported for birch seedlings, but the maximum growth capacity was lower in grey alder. During an initial period of change in the internal nitrogen status, deficiency symptoms appeared, especially in unnodulated seedlings. As in birch, the leaves turned green again at stable nitrogen status, independent of level. The results are in sharp contrast to data from the literature where the external nitrogen concentration was used as the driving variable for the internal nitrogen status. The measured fixation rates for grey alder are much higher than those previously reported. Still, the maximum fixation rate observed is small compared to the total nitrogen uptake rate required for maximum growth, in contrast to reported relationships. These comparisons indicate that increased external nitrogen concentration obscures the real relations between mineral and fixed nitrogen, on one hand because of rapid inhibition of nitrogen fixation and, on the other hand, because of failure to obtain stable optimum nutrition and maximum growth by means of this treatment variable.     

Rhizobial ecology of the woody legumePsorothamnus spinosus in a Sonoran Desert Arroyo

Psorothamnus spinosus seedlings were selected at random and excavated from 10×30 m quadrats along a 270 m transect in a southern Californian desert arroyo. Forty-six of the fifty seedlings excavated (92%) were nodulated. The mean number of nodules/plant was 7.0±3.6. Maximum rooting depth was 40 cm, and most (58.8%) of the nodules were found between 15 and 30 cm depth. The mean root/shoot ratio was 1.4±0.4. The rhizobial population density between 10 to 40 cm depth across all quadrats was non-detectable using a plant infection, most probable number method. All 70 isolates from field nodules were fast-growingRhizobium spp. Two colony morphologies were observed: wet, translucent, and wet, opaque. All isolates tested were effective on bothP. spinosus and another desert woody legume, mesquite (Prosopis glandulosa). Many isolates had a high relative efficiency, and seven of eight efficient isolates had uptake-hydrogenase activity. Root stimulation of the low rhizobial population found in the arroyo and subsequent root nodulation may be an important factor in seedling establishment by woody legumes in N-limited desert arroyo systems.     

Genetics of promiscuous nodulation in soybean: nodule dry weight and leaf color score

The symbiotic relationship between the soybean plant and rhizobium results in fixation of atmospheric nitrogen (N(2)) in the root nodules, with the result that nitrogenous fertilization of the soybean is unnecessary. The effectiveness of nodule formation and N(2) fixation with rhizobial strains is under genetic control with two general categories identified: (1) promiscuous, which produces functional nodules with cowpea-type rhizobial strains; and (2) nonpromiscuous, which forms no or nonfunctional nodules with these strains. The segregation pattern of this promiscuity trait was studied using nodule dry weight (NDW) and leaf color score (LCS) as indicators of N(2) fixation effectiveness. Individual plants in each of six populations [P(1) = nonpromiscuous, P(2) = promiscuous, F(1) = P(1) x P(2) (and the reciprocal cross), BC(1)(P(1)) = F(1) (female) x P(1), BC(1)(P(2)) = F(1) (female) x P(2), F(2)] were scored for these characters after inoculation with a rhizobial strain that would distinguish between both types. For NDW, nonpromiscuity was found to be partially dominant (h/d = 0.37), controlled by four loci. For LCS, nonpromiscuity was shown to be almost completely dominant (h/d = 0.74), controlled by two loci. LCS was a more meaningful estimate of N(2) fixation because it represented the total effectiveness of nodulation to provide nitrogen for the plant.     

Influence of soil fertility on the rhizobial competitiveness for nodulation of <Emphasis Type="Italic">Acacia senegal</Emphasis> and <Emphasis Type="Italic">Acacia nilotica</Emphasis> provenances in nursery and field conditions

Within the framework of our study, we assessed the nodule occupancy of a mixture of various strains of rhizobia to inoculate several provenances of Acacia senegal and Acacia nilotica. The first part of the experiment was carried out under greenhouse conditions where the plants were cultivated in polyvinyl chloride tubes containing an unsterilized Sangalkam soil low in organic matter and nitrogen. The results showed that 4 and 8 months after sowing, rhizobial strains CIRADF 306 and CIRADF 300 were mainly present in nodules of A. nilotica and A. senegal, respectively. After transferring the seedlings to the more fertile soil in Bel Air field station, the molecular analysis of the nodules showed that strain CIRADF 306 was absent from the nodules of A. nilotica, whereas strain CIRADF 305 which occurred only at low nodule occupancy in the nursery, predominated in the field conditions. On the other hand, strain CIRADF 300 occurred in the majority of the nodules from the various provenances of A. senegal. These results demonstrated actual interaction between inoculated rhizobial strains, soil type and host plant genotype in terms of competitiveness, nodulation and symbiotic nitrogen fixation.     

The Rhizobial hemA Gene Is Required for Symbiosis in Species with Deficient [delta]-Aminolevulinic Acid Uptake Activity

Most rhizobial hemA mutants induce root nodules on their respective legume hosts that lack nitrogen fixation activity and leghemoglobin expression. However, a Bradyrhizobium japonicum hemA mutant elicits effective nodules on soybean, and we proposed previously that synthesis and uptake of the heme precursor [delta]-aminolevulinic acid (ALA) by the plant and bacterial symbiont, respectively, allow mutant rescue (I. Sangwan, M.R. O'Brian [1991] Science 251: 1220-1222). In the present work, the B. japonicum hemA mutant MLG1 elicited normal nodules on three hosts, including cowpea, a plant that is not effectively nodulated by a hemA mutant of Rhizobium sp. These data indicate that B. japonicum rather than soybean possesses the unique trait that allows normal nodule development by a hemA mutant. Cowpea expressed glutamate-dependent ALA formation activity in nodules induced by B. japonicum strains I110 or MLG1 and by Rhizobium sp. ANU240. Exogenous ALA was taken up by B. japonicum bacteroids isolated from soybean or cowpea nodules, and the kinetics of uptake were biphasic. By comparison, Rhizobium sp. ANU240 had very low ALA uptake activity. In addition, ALA uptake was observed in cultured cells of B. japonicum but not in cultured cells of three other rhizobial species tested. We suggest that the differential success of legume-rhizobial hemA symbioses is due to an ALA uptake activity in B. japonicum that is deficient in other rhizobia, thereby further validating the ALA rescue hypothesis.     

The Rhizobium--legume symbiosis.

The rhizobia are soil microorganisms that can interact with leguminous plants to form root nodules within which conditions are favourable for bacterial nitrogen fixation. Legumes allow the development of very large rhizobial populations in the vicinity of their roots. Infections and nodule formation require the specific recognition of host and Rhizobium, probably mediated by plant lectins. Penetration of the host by a compatible Rhizobium species usually provokes host root cell division to form the nodule, and a process of differentiation by both partners then ensues. In most cases the rhizobia alter morphologically to form bacteroids, which are usually larger than the free-living bacteria and have altered cell walls. At all stages during infection, the bacteria are bounded by host cell plasmalemma. The enzyme nitrogenase is synthesized by the bacteria and, if leghaemoglobin is present, nitrogen fixation will occur. Leghaemoglobin is a product of the symbiotic interaction, since the globin is produced by the plant while the haem is synthesized by the bacteria. In the intracellular habitat the bacteria are dependent upon the plant for supplies of energy and the bacteroids, in particular, appear to differentiate so that they are no longer able to utilize the nitrogen that they fix. Regulation of the supply of carbohydrate and the use of the fixed nitrogen thus appear to be largely governed by the host.     

新疆干旱区豆科植物结瘤的固氮特性

调查了新疆干旱区72种豆科植物的结瘤固氮活性,其中33种尚未见报道。这些植物所结根瘤在外形上多数不规则,以皮层厚和白色、棕色者居多,与非干旱区的根瘤形态显著不同。根瘤固氮活力相差较大,但比一般豆科植物根瘤活性高,最高者可达当地大豆根瘤的42倍。根瘤活性与宿主的抗逆境能力有关。此外,从11种豆科植物根瘤观察到10种具有吸氢活性。对干旱区豆科共生固氮生理生态的特性进行了讨论。