Relationship Between the Membrane Envelope of Rhizobial Bacteroids and the Plasma Membrane of the Host Cell as Demonstrated by Histochemical Localization of Adenyl Cyclase

By using adenyl cyclase as a marker enzyme, the relationship between the membrane envelope of the bacteroids of rhizobia and the plasma membrane of the host cell was demonstrated histochemically. Electron-dense deposits were found on the outer surface of the plasma membrane of the host cell and on the inner surface of the membrane envelopes of the bacteroids, but not in vacuole membranes, endoplasmic reticula, Golgi apparatus, and mitochondrial membranes. The results suggest that the membrane envelopes of the bacteroids are closely related to the host plasma membrane, and that entry of the bacteroids into the cytoplasm is in a manner similar to endocytosis.     

拟菌体包囊膜的动态变化和宿主细胞与细菌的相互关系

本文初次报道紫云英根瘤的超微结构。用根瘤中段的中心组织作实验材料,以显示受根瘤菌侵染的宿主细胞的一般结构。细菌借助于侵入线进入宿主细胞,发育成拟菌体,为包囊膜所裹。一个包囊膜内一般只有一个拟菌体。包囊膜可以与细胞质内的囊泡和小液泡融合而扩增,导致膜对拟菌体的包裹由紧密到疏松的变化。包囊膜和拟菌体表面都有突起,两者的突起相对接触和融合。对拟菌体包囊膜的动态变化与衰老的关系以及宿主细胞和拟菌体之间物质交换的关系进行了讨论。作者指出包囊膜的扩增和电子透明区域的存在,是拟菌体发育成熟的一个阶段,包囊膜和拟菌体通过互相突起、融合沟通的结构,可能是宿主细胞和细菌之间物质交换功能的一种表现。     

根瘤菌在宿主细胞内的存在形式及其命运

根瘤菌在根瘤宿主细胞内有两种形式：一种为拟菌体、被宿主细胞来源的财膜包裹;另一种为自由生活的营养细胞。前者色大多数,后者只有少数。随着根瘤的衰老,其命运是：拟菌体及其宿主细胞同时衰老以致最终解体,拟菌体不能再入土壤复生;以自由生活的营养细胞形式存在的细菌,不随其宿主细胞的解体而亡,可回复到土壤,一方面在豆科植物和土壤之间循环,一方面维持根瘤菌在土壤中天然的群体生态平衡。     

Forms and Fates of Rhizobial Bacteria Present in the Infected Host Cells of Nodules

There were two forms of rhizobial bacteria present in infected host cells of nodules. One was bacteroids which were enclosed in peribacteroid membrane originated from the infected host cells. The other was rhizobia as vegetative cells. The infected host cells were occupied by most of the bacteroids and a certain number of the vegetative cells respectively. With the nodule senescence, there were two kinds of fate of the bacteria: The bacteroids degenerated togather with the infected host cells at the same time and further disintegrated completely, so it is not possible that the disintegrated bacteroids could be returned into soil to revive: the vegetative cells did not disintegrate and die when the infected host cells senesced, eventually could be turned back into soil. The vegetative cells may play an important role, on the one hand, in cycle between legume and soil, on the other hand, maintain rhizobia in natural balance of population ecosystem.     

Ultrastructural characteristics of the host-symbiont interface in nitrogen-fixing peanut nodules

Summary Nitrogen-fixing peanut root nodules are characterized by their unique structural organization, distinct from other legume nodules. The focus of this study has been in and around the hostsymbiont interface, where the bacterioid and the host cell surface (peribacteroid membrane envelope) interact during symbiosis. The infected nodule cells have revealed the presence of lipid bodies (oleosomes) in intimate association with the peribacteroid membrane, which encloses the large spherical bacteroids with a relatively narrow peribacteroid space. Electron dense structures, referred to as dense bodies have been found attached to the bacteroid outer membranes at the host-symbiont interface. The dense bodies are osmiophilic, amorphous and 3,3-diaminobenzidine positive. The isolated intact bacteroids with dense bodies attached to their cell wall showed significant catalase activity. Many microbodies showing DAB-positive reaction have been found in the host cytoplasm, associated closely with the peribacteroid membrane. These ultrastructural and cytochemical characteristics of peanut root nodules suggest that lipids are utilized during symbiosis and the dense bodies and microbodies may be involved in the catabolic process.Abbreviation DAB 3,3-diaminobenzidine     

箭舌豌豆根瘤液泡中细菌周膜来源的研究

电镜观察结果表明,幼龄箭舌豌豆根瘤侵染细胞的细胞质较少,中央是一些体积较大的液泡。细胞质中侵入线经常可见,由侵入线释放出来的细菌均有细菌周膜。这些细菌只位于细胞质中,不出现在液泡里面。成熟根瘤中的侵染细胞与此不同,它们中有大量的成熟侵染细胞,细胞质丰富,里面充满大量细菌,中央常有一个大液泡。当中央液泡发育到一定程度时,位于其附近的细菌可通过液泡膜内吞、液泡膜与细菌周膜融合及液泡膜破裂3种途径进入液泡,后一种途径常伴有寄主细胞质。液泡中的细菌绝大部分裸露在外,只有个别细菌具有细菌周膜且多位于液泡膜的破损处附近,因此细菌周膜可能是原来就有的。     

Peanut agglutinin-induced structural changes in cowpea Rhizobia as revealed by freeze-etching

The ultrastructure of two strains of cowpeaRhizobium species, JLn(c) and NC-92, was studied especially with regards to the effect of peanut agglutinin on the cell envelope. Freezeetching electron microscopy revealed the structural details of the outer and the cytoplasmic membrane. The topology of both membranes resembled that of other Gram-negative bacteria. The cells displayed marked polarity, expressed in the form of an extracellular polar body (EPB) near one end and a periplasmic bay at the opposite end. The EPB was seen as a polar outgrowth of the outer membrane and resembled in structure the outer membrane. The existence of a polar periplasmic bay as a characteristic feature of cowpea rhizobia is reported here for the first time and has been implicated as a probable site for polysaccharide synthesis. Ruthenium red staining showed a polar mode of capsule initiation in the early exponential phase. Peanut agglutinin was found to enhance the incidence of EPB which is necessary for adhesion of rhizobia to root hairs. This suggests that lectins serve as an important biological stimulus which preconditions the symbiont for successful attachment to root hairs.     

A high-affinity cbb3-type cytochrome oxidase terminates the symbiosis-specific respiratory chain of Bradyrhizobium japonicum.

It has been a long-standing hypothesis that the endosymbiotic rhizobia (bacteroids) cope with a concentration of 10 to 20 nM free O2 in legume root nodules by the use of a specialized respiratory electron transport chain terminating with an oxidase that ought to have a high affinity for O2. Previously, we suggested that the microaerobically and anaerobically induced fixNOQP operon of Bradyrhizobium japonicum might code for such a special oxidase. Here we report the biochemical characteristics of this terminal oxidase after a 27-fold enrichment from membranes of anaerobically grown B. japonicum wild-type cells. The purified oxidase has TMPD (N,N,N',N'-tetramethyl-p-phenylenediamine) oxidase activity as well as cytochrome c oxidase activity. N-terminal amino acid sequencing of its major constituent subunits confirmed that presence of the fixN,fixO, and fixP gene products. FixN is a highly hydrophobic, heme B-binding protein. FixO and FixP are membrane-anchored c-type cytochromes (apparent Mrs of 29,000 and 31,000, respectively), as shown by their peroxidase activities in sodium dodecyl sulfate-polyacrylamide gels. All oxidase properties are diagnostic for it to be a member of the cbb3-type subfamily of heme-copper oxidases. The FixP protein was immunologically detectable in membranes isolated from root nodule bacteroids, and 85% of the total cytochrome c oxidase activity in bacteroid membranes was contributed by the cbb3-type oxidase. The Km values for O2 of the purified enzyme and of membranes from different B. japonicum wild-type and mutant strains were determined by a spectrophotometric method with oxygenated soybean leghemoglobin as the sole O2 delivery system. The derived Km value for O2 of the cbb3-type oxidase in membranes was 7 nM, which is six- to eightfold lower than that determined for the aerobic aa3-type cytochrome c oxidase. We conclude that the cbb3-type oxidase supports microaerobic respiration in endosymbiotic bacteroids.     

Nodule ultrastructure and initial growth of Anadenanthera peregrina (L.) Speg. var. falcata (Benth.) altschul plants infected with rhizobia

The anatomy and ultrastructure of root nodules of Anadenanthera peregrina var. falcata (Leguminosae-Mimosoideae) were analysed, as was plant growth. To ensure that nodules developed, seedlings were inoculated with a mixture of six strains of rhizobia. Nodules were produced that differed in appearance-and probably also effectiveness-but their structure was similar and they showed characteristics typical of indeterminate nodules, such as persistent meristematic tissue and a gradient of cells at different stages of development. Many starch grains were present in inner cortex cells and interstitial cells of infected tissue. Infected cells were densely packed with bacteroids, which contained many poly-beta-hydroxybutyrate granules. The high incidence of these granules, together with high levels of starch accumulation in interstitial cells, suggested low N2-fixation efficiency of the rhizobia isolates used for inoculation. In the symbiosomes of early-senescent infected cells, reticulum-like structures, small vesicles and a fibrillar material were observed; these may be related to bacteroid degradation. In the cytoplasm of late-senescent infected cells, many vesicles and membrane-like structures were observed, probably associated with membrane degradation of bacteroids and peribacteroids. The total biomass of plants inoculated with rhizobia was low and their xylopodia and shoots had low levels of N compared with noninoculated plants fertilized with ammonium nitrate. However, inoculated plants did not show N-deficiency symptoms and grew better than non-inoculated plants without N fertilization. These growth results, together with ultrastructural observations of nodules, suggest that nitrogen fixation of rhizobia isolates associated with Anadenanthera peregrina var. falcata roots is poor.     

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.     

Evolutionary dynamics of rhizopine within spatially structured rhizobium populations

Symbiosis between legumes and nitrogen-fixing bacteria is thought to bring mutual benefit to each participant. However, it is not known how rhizobia benefit from nodulating legume hosts because they fix nitrogen only after becoming bacteroids, which are terminally differentiated cells that cannot reproduce. Because undifferentiated rhizobia in and around the nodule can reproduce, evolution of symbiotic nitrogen fixation may depend upon kin selection. In some hosts, these kin may persist in the nodule as viable, undifferentiated bacteria. In other hosts, no viable rhizobia survive to reproduce after nodule senescence. Bacteroids in these hosts may benefit their free-living kin by enhancing production of plant root exudates. However, unrelated non-mutualists may also benefit from increased plant exudates. Rhizopines, compounds produced by bacteroids in nodules and catabolized only by related free-living rhizobia, may provide a mechanism by which bacteroids can preferentially benefit kin. Despite this apparent advantage, rhizopine genotypes are relatively rare. We constructed a mathematical model to examine how mixing within rhizobium populations influences the evolution of rhizopine genotypes. Our model predicts that the success of rhizopine genotypes is strongly dependent upon the spatial genetic structure of the bacterial population; rhizopine is more likely to dominate well-mixed populations. Further, for a given level of mixing, we find that rhizopine evolves under a positive frequency-dependent process in which stochastic accumulation of rhizopine alleles is necessary for rhizopine establishment. This process leads to increased spatial structure in rhizobium populations, and suggests that rhizopine may expand the conditions under which nitrogen fixation can evolve via kin selection.     

侵染细胞质膜附近小泡的来源及其作用

箭舌豌豆根瘤幼龄侵染细胞的壁和质膜比较光滑,成熟侵染细胞与此不同,不仅细胞壁厚薄均,有较多的胞间连丝,而且质膜常常内陷形成各种突起,然后离质膜形成小泡。这些位于质膜附近的小泡体积较小,多呈圆形,既可单独存在,也可多个聚在一起。在向细胞中央移动中,有的小泡靠近细胞质膜,甚至与细菌周期融合,有的小泡不民附近的小液泡融合变为较大液泡,并常用降解程度不同的细菌位于其中,在衰老侵染细胞中,细胞壁附近有小泡,     

Identification and Characterization of a Bacteroid-Specific Dehydrogenase Complex in Rhizobium leguminosarum PRE

In membranes of Rhizobium leguminosarum bacteroids isolated from nitrogen-fixing pea root nodules, two different protein complexes with NADH dehydrogenase activity were detected. One of these complexes, with a molecular mass of 110 kilodaltons, was also found in membranes of free-living rhizobia, but the other, with a molecular mass of 550 kilodaltons, appeared to be present only in bacteroids. The bacteroid-specific complex, referred to as DH1, probably consists of at least four different subunits. Using antibodies raised against the separate polypeptides, we found that a 35,000-molecular-weight polypeptide (35K polypeptide) in the DH1 complex is bacteroid specific, while the other proposed subunits were also detectable in cytoplasmic membranes of free-living bacteria. Dehydrogenase complex DH1 is also present in bacteroids of a R. leguminosarum nifA mutant, indicating that the synthesis of the dehydrogenase is not dependent on the gene product of this nif-regulatory gene. A possible involvement of the bacteroid-specific DH1 complex in electron transport to nitrogenase is discussed.     

Co-localisation of membranes and actin in growing infected cells of Glycine max root nodules

The root nodule of Glycine max (L.) Merr. is almost spherical at maturity, and its central tissue consists of infected cells filled with numerous symbiosomes containing bacteroids, interspersed with uninfected cells. During the growth of the nodule, the volume of each infected cell and the number of bacteroids per cell increases, and thus abundant membranes are required for the proliferation of symbiosomes. In expanding infected cells, there are areas adjacent to the nucleus that are devoid of bacteroids, but these areas are filled with numerous membranes and actin filaments, surrounded by endoplasmic reticulum membranes, indicating a perinuclear reservoir of newly formed membranes and a role for actin in delivering membranes to proliferating symbiosomes.     

Structure and Organization of Effective Peanut and Cowpea Root Nodules Induced by Rhizobial Strain 32H1

A comparison of the structure and organization of nodular tissuesand bacteroids of peanut and cowpea induced by Rhizobium sp.strain 32H1 was madc 4 to 5 weeks after inoculation when nitrogenaseactivity reaches the peak. Observations revealed major differencesthat may have a role in the different rates of nitrogen fixationshown by the two species. All cell types in cowpca nodules werelarger than those of peanut. The inner cortex of cowpea hadan ‘endodermis-like’ layer of cells which was absentin peanut. All cells in the bactcroidai zone of peanut wereinfected but in cowpca many remained free of bactcroids. Thebacteroid containing cells of peanut were isodianietrical anduniform in size with a central vacuole and a nucleus surroundedby tightly arranged bactcroids enclosed singly in peribacteroidalmembrane sacs. Such cells in cowpea were mostly elongated witha nucleus and one or more vacuoles. The bacteroids within cowpeacells were arranged without any particular order with more spacefor host cellular material. They were mostly present singlyin peribacteroidal membrane sacs which sometimes fused to enclosemore than one bactcroid. The hosts seem to play the dominantrole in the differentiation of nodular tissue and the morphogenesisof bacteroids in symbiotic systems induced by the same strainof Rhizobium. Key words: Peanut, Cowpea, nodule structre     

Cell cycle regulation in the course of nodule organogenesis in Medicago

The molecular mechanisms of de novo meristem formation, cell differentiation and the integration of the cell cycle machinery into appropriate stages of the developmental programmes are still largely unknown in plants. Legume root nodules, which house nitrogen-fixing rhizobia, are unique plant organs and their development may serve as a model for organogenetic processes in plants. Nodules form and are essential for the plant only under limitation of combined nitrogen in the soil. Moreover, their development is triggered by external mitogenic signals produced by their symbiotic partners, the rhizobia. These signals, the lipochitooligosaccharide Nod factors, act as host-specific morphogens and induce the re-entry of root cortical cells into mitotic cycles. Maintenance of cell division activity leads to the formation of a persistent nodule meristem from which cells exit continuously and enter the nodule differentiation programme, involving multiple cycles of endoreduplication and enlargement of nuclear and cell volumes. While the small diploid 2C cells remain uninfected, the large polyploid cells can be invaded and, after completing the differentiation programme, host the nitrogen-fixing bacteroids. This review summarizes the present knowledge on cell cycle reactivation and meristem formation in response to Nod factors and reports on a novel plant cell cycle regulator that can switch mitotic cycles to differentiation programmes.     

Comparing Symbiotic Efficiency between Swollen versus Nonswollen Rhizobial Bacteroids

Symbiotic rhizobia differentiate physiologically and morphologically into nitrogen-fixing bacteroids inside legume host nodules. The differentiation is apparently terminal in some legume species, such as peas (Pisum sativum) and peanuts (Arachis hypogaea), likely due to extreme cell swelling induced by the host. In other legume species, such as beans (Phaseolus vulgaris) and cowpeas (Vigna unguiculata), differentiation into bacteroids, which are similar in size and shape to free-living rhizobia, is reversible. Bacteroid modification by plants may affect the effectiveness of the symbiosis. Here, we compare symbiotic efficiency of rhizobia in two different hosts where the rhizobia differentiate into swollen nonreproductive bacteroids in one host and remain nonswollen and reproductive in the other. Two such dual-host strains were tested: Rhizobium leguminosarum A34 in peas and beans and Bradyrhizobium sp. 32H1 in peanuts and cowpeas. In both comparisons, swollen bacteroids conferred more net host benefit by two measures: return on nodule construction cost (plant growth per gram nodule growth) and nitrogen fixation efficiency (H₂ production by nitrogenase per CO₂ respired). Terminal bacteroid differentiation among legume species has evolved independently multiple times, perhaps due to the increased host fitness benefits observed in this study.Legume-rhizobia interactions vary widely across a diverse paraphyletic group of soil bacteria known for symbiotic nitrogen fixation inside root nodules of over 18,000 species of legumes throughout the world (Lewis et al., 2005). In several legume species, rhizobial cells are induced to swell during their differentiation into nitrogen-fixing bacteroids (Oono et al., 2010). These legume species belong to five different major papilionoid clades (inverted repeat-lacking clade, genistoids, dalbergioids, mirbelioids, and millettioids), a pattern suggestive of convergent evolution. Swelling apparently leads to terminal differentiation; swollen bacteroids no longer divide normally (Zhou et al., 1985). In other legume host species, bacteroid differentiation is less extreme, leading to nonswollen bacteroids. Nonswollen bacteroids are similar in shape and size to free-living rhizobia and divide normally once outside of their nodules. The proximate mechanisms for host-imposed bacteroid swelling have been investigated (Van de Velde et al., 2010), but what drove the repeated evolution of this trait? The multiple independent origins of host traits causing bacteroids to swell suggest that swollen bacteroids may provide more net benefit to legumes. Could the swelling of bacteroids improve nitrogen fixation efficiency (e.g. nitrogen fixed relative to carbon cost)? In this study, we compare symbiotic efficiencies of rhizobia in legume hosts that are evolutionarily diverged but share a common effective rhizobial strain, whose bacteroids are swollen in one host and nonswollen in the other.Variations among host species in benefits and costs of symbiosis with rhizobia are not commonly explored (Thrall et al., 2000) because legume species typically nodulate with only one group of rhizobia (e.g. Sinorhizobium sp. in Medicago), although some legumes and some rhizobia are more promiscuous. Rhizobium sp. NGR234 has the largest known host range but does not fix nitrogen effectively with any legume species currently recognized to induce swelling of rhizobial bacteroids (Pueppke and Broughton, 1999). Some Sinorhizobium fredii strains apparently fix nitrogen in certain cultivars of soybean (Glycine max; hosting nonswollen bacteroids) and alfalfa (Medicago sativa; hosting swollen bacteroids; Hashem et al., 1997), but our efforts to replicate these results did not lead to successful nodulation. Therefore, we studied two strains, a transgenic strain that nodulates beans (Phaseolus vulgaris) and peas (Pisum sativum) and a second wild strain harvested from cowpeas (Vigna unguiculata) that also nodulates peanuts (Arachis hypogaea). Beans and cowpeas are both within the Phaseolid group and do not induce terminal differentiation of rhizobial bacteroids. Peas and peanuts both host terminally differentiated bacteroids but are in distant clades and likely have different genetic origins for traits that induce terminal differentiation (Oono et al., 2010). Also, the swollen bacteroids in peas are branched while those in peanuts are spherical.Differences in symbiotic qualities between swollen and nonswollen bacteroids have been previously explored in peanuts and cowpeas by Sen and Weaver (1980, 1981, 1984), who also hypothesized that swollen bacteroids are more beneficial to the host plant than nonswollen ones. They found 1.5 to 3 times greater acetylene reduction by nitrogenase (as well as plant nitrogen) per nodule mass in peanuts than in cowpeas at multiple nodule ages (Sen and Weaver, 1980). Acetylene reduction per bacteroid was also greater in peanuts than in cowpeas when measuring whole nodules, but this difference disappeared when isolated bacteroids were assayed (Sen and Weaver, 1984). They concluded that swelling of peanut bacteroids per se was not responsible for the higher rate of nitrogen fixation per bacteroid. They suggested that in cowpea nodules, with greater numbers of smaller bacteroids per nodule volume, availability of oxygen to each bacteroid might be restricted such that the rate of oxidative phosphorylation, necessary for nitrogen fixation, is reduced. Fixation rates per bacteroid may be different between hosts due to nodule gas permeability or bacteroid crowding within nodules. However, fixation efficiency (nitrogen fixed per carbon respired) would not necessarily be affected by these and may be more important for the host than the rate of fixation.Rhizobial performances are often compared by measuring the symbiotic benefits, e.g. rates of acetylene reduction or plant growth (Sen and Weaver, 1984; Hashem et al., 1997; Lodwig et al., 2005), but rarely by measuring the symbiotic costs, e.g. carbon consumed or respired. Up to 25% of a legume’s net photosynthate may be required for nitrogen fixation by rhizobia (Minchin et al., 1981). Faster fixation rates (mol nitrogen per s) can be beneficial for hosts, but carbon costs can also be important. Rhizobia that fix more nitrogen per carbon respired could free more carbon for other functions, including the option of supporting more nodules with the same amount of photosynthate. If legumes are sometimes carbon limited, then improved carbon-use efficiency could enhance plant fitness. Measuring both benefits and costs is therefore key to an accurate understanding of the symbiotic performance of a rhizobial strain.While we recognize the many physiological differences between peas and beans or peanuts and cowpeas, the fact that terminal differentiation induced by host legumes evolved multiple times independently (Oono et al., 2010) suggests there may be some consistent host symbiotic benefit, such as improved fixation efficiency. Here, we measured the efficiency of each of two strains as swollen bacteroids in one host and nonswollen bacteroids in another. We measured nitrogenase activity as hydrogen (H₂) production in an N₂-free atmosphere (Layzell et al., 1984; Witty and Minchin, 1998), and compared it to carbon dioxide (CO₂) respiration to estimate return on nodule operation cost. We also compared host biomass growth per total nodule mass growth to estimate return on nodule construction cost. To further assess carbon allocation to the different types of bacteroids, we also measured the average amounts per bacteroid of polyhydroxybutyrate (PHB), an energy storage compound that can comprise up to 50% of bacteroid dry weight (Trainer and Charles, 2006). A greater PHB accumulation per bacteroid may require a decreased allocation of carbon for nitrogenase activity within the bacteroids, and hence, less plant growth per carbon invested in bacteroids. We demonstrate that peas and peanuts that host swollen bacteroids have higher fixation efficiency as well as greater plant return on nodule construction than beans and cowpeas, respectively, nodulated with the same rhizobial strains. PHB was not consistently correlated with plant:nodule growth efficiency with the tested strains. These findings show that swollen bacteroids can indeed provide greater benefits to their legume hosts.     

Mineral constraints to nitrogen fixation

Mineral nturient defiencies are a major constraint limiting legume nitrogen fixation and yield. In this review general techniques for assessing nutrient involvement in symbiotic nitrogen fixation are described and specific methods are outlined for determining which developmental phase of the symbiosis is most sensitive to nutrient deficiency. The mineral nutrition of the Rhizobium component of the symbiosis is considered both as the free living organism in the soil and as bacteroids in root nodules. Rhizobial growth and survival in soils is not usually limited by nutrient availability. Multiplication of rhizobia in the legume rhizosphere is limited by low Ca availability. Nodule initiation is affected by severe Co deficiency through effects on rhizobia. Nodule development is limited by severe B deficiency via an effect on plant cell growth. Fe deficiency limits nodule development by affecting rhizobia and strains of rhizobia differ widely in their ability to acquire sufficient Fe for their symbiotic development. Nodule function requires more Mo than does the host plant, and in some symbioses nitrogen fixation may be specifically limited by low availability of Ca, Co, Cu and Fe. The importance of the peribacteriod membrane in determining nutrient availability to bacteroids is considered. It is concluded that the whole legume-Rhizobium symbiosis should be considered when improving legume growth and yield under nutrient stress conditions. Differences among rhizobial strains in their ability to obtain mineral nutrients from their environment may be agronomically important.     

Critical protective role of bacterial superoxide dismutase in rhizobium-legume symbiosis

In nitrogen-poor soils, rhizobia elicit nodule formation on legume roots, within which they differentiate into bacteroids that fix atmospheric nitrogen. Protection against reactive oxygen species (ROS) was anticipated to play an important role in Rhizobium-legume symbiosis because nitrogenase is extremely oxygen sensitive. We deleted the sodA gene encoding the sole cytoplasmic superoxide dismutase (SOD) of Sinorhizobium meliloti. The resulting mutant, deficient in superoxide dismutase, grew almost normally and was only moderately sensitive to oxidative stress when free living. In contrast, its symbiotic properties in alfalfa were drastically affected. Nitrogen-fixing ability was severely impaired. More strikingly, most SOD-deficient bacteria did not reach the differentiation stage of nitrogen-fixing bacteroids. The SOD-deficient mutant nodulated poorly and displayed abnormal infection. After release into plant cells, a large number of bacteria failed to differentiate into bacteroids and rapidly underwent senescence. Thus, bacterial SOD plays a key protective role in the symbiotic process.     

The role of hopanoids in fortifying rhizobia against a changing climate

Bacteria are a globally sustainable source of fixed nitrogen, which is essential for life and crucial for modern agriculture. Many nitrogen-fixing bacteria are agriculturally important, including bacteria known as rhizobia that participate in growth-promoting symbioses with legume plants throughout the world. To be effective symbionts, rhizobia must overcome multiple environmental challenges: from surviving in the soil, to transitioning to the plant environment, to maintaining high metabolic activity within root nodules. Climate change threatens to exacerbate these challenges, especially through fluctuations in soil water potential. Understanding how rhizobia cope with environmental stress is crucial for maintaining agricultural yields in the coming century. The bacterial outer membrane is the first line of defence against physical and chemical environmental stresses, and lipids play a crucial role in determining the robustness of the outer membrane. In particular, structural remodelling of lipid A and sterol-analogues known as hopanoids are instrumental in stress acclimation. Here, we discuss how the unique outer membrane lipid composition of rhizobia may underpin their resilience in the face of increasing osmotic stress expected due to climate change, illustrating the importance of studying microbial membranes and highlighting potential avenues towards more sustainable soil additives.