Symbiotic relations of human and microorganisms

Symbiosis has been considered as a biological basis of infectious process. Particular attention was paid to the change of paradigm in symbiology and the appearance of a novel term--associative symbiosis. Principal structural-and-functional elements of associative symbiosis were estimated, and 3 vectors of infectious process such as i) host--normaflora, ii) host--associants, iii) associants--indigious microflora (microsymbiocenosis) were isolated. Functions of microsymbionts that determine colonization resistance of the host, and the formation of dysbioses and pathobiocenoses were reviewed. Phenomenon of microbial recognition for "self-nonself" has been revealed on the basis of opportunistic (increase/decrease) interactions on growth persistent (including biofilm formation) peculiarities of a pair "dominant-associant" under conditions of microsymbiocenosis in human. Material was presented to characterize the role of intercellular interactions of symbionts at the level of prokaryotes, pro-eukaryotes under conditions of infectious pathology.     

Symbiosis is a biological basis of infection

Symbiosis has been considered as a biological basis of the infectious process. Attention has been paid to the change of paradigm in symbiology and to the appearance of a new term: associative symbiosis. The main structural-functional elements of associative symbiosis have been assessed, and three vectors of the infectious process have been detected: (1) host-normoflora, (2) host-associants, and (3) associants-indigenous microflora (microsymbiocenosis). Functions of microsymbionts determining host colonization resistance and development of disbioses and pathobiocenoses have been considered. Resistance of organism biotopes to microbes is associated with substrates which are overcome by associants with persistent potential. Antagonism and change of persistent potential in both the infectious agent itself and commensal microorganisms are the basis of symbiont interactions. The given material describes the role of intercellular interactions of symbionts at the level of proprokaryotes, proeukaryotes during the infectious pathology.     

The influence of mineral nitrogen on legume-rhizobium symbiosis

This review of the literature synthesizes the data on physiological mechanisms of the influence of high doses of mineral nitrogen (nitrates and ammonium) on the formation and functioning of legume-rhizobium symbiosis. The participation of phytohormonal and phenolic metabolism and active forms of oxygen and nitrogen in the symbiosis is highlighted. A close connection between these metabolic processes in the formation and functioning of legume-rhizobium symbiosis under a redundant supply of plants by mineral nitrogen is underlined.     

Hormone modulation of legume‐rhizobial symbiosis

Leguminous plants can establish symbiotic associations with diazotropic rhizobia to form nitrogenfixating nodules, which are classified as determinate or indeterminate based on the persistence of nodule meristem. The formation of nitrogen-fixing nodules requires coordinating rhizobial infection and root nodule organogenesis. The formation of an infection thread and the extent of nodule formation are largely under plant control, but vary with environmental conditions and the physiological state of the host plants. Many achievements in these two areas have been made in recent decades.Phytohormone signaling pathways have gradually emerged as important regulators of root nodule symbiosis. Cytokinin, strigolactones(SLs) and local accumulation of auxin can promote nodule development. Ethylene,jasmonic acid(JA), abscisic acid(ABA) and gibberellic acid(GA) all negatively regulate infection thread formation and nodule development. However, salicylic acid(SA) and brassinosteroids(BRs) have different effects on the formation of these two nodule types. Some peptide hormones are also involved in nodulation. This review summarizes recent findings on the roles of these plant hormones in legume-rhizobial symbiosis, and we propose that DELLA proteins may function as a node to integrate plant hormones to regulate nodulation.     

固氮植物的菌根研究

综述了固氮植物菌根研究的概况,并对固氮植物形成菌根的普遍性,固氮植物联合共生的增效作用及逆境条件下菌根技术在固氮植物上的应用前景进行了总结和评述,初步探讨了联合共生体中菌根菌促进固氮植物结瘤固氮的机理。     

Reactive oxygen and nitrogen species and glutathione: key players in the legume-Rhizobium symbiosis

Several reactive oxygen and nitrogen species (ROS/RNS) are continuously produced in plants as by-products of aerobic metabolism or in response to stresses. Depending on the nature of the ROS and RNS, some of them are highly toxic and rapidly detoxified by various cellular enzymatic and non-enzymatic mechanisms. Whereas plants have many mechanisms with which to combat increased ROS/RNS levels produced during stress conditions, under other circumstances plants appear to generate ROS/RNS as signalling molecules to control various processes encompassing the whole lifespan of the plant such as normal growth and development stages. This review aims to summarize recent studies highlighting the involvement of ROS/RNS, as well as the low molecular weight thiols, glutathione and homoglutathione, during the symbiosis between rhizobia and leguminous plants. This compatible interaction initiated by a molecular dialogue between the plant and bacterial partners, leads to the formation of a novel root organ capable of fixing atmospheric nitrogen under nitrogen-limiting conditions. On the one hand, ROS/RNS detection during the symbiotic process highlights the similarity of the early response to infection by pathogenic and symbiotic bacteria, addressing the question as to which mechanism rhizobia use to counteract the plant defence response. Moreover, there is increasing evidence that ROS are needed to establish the symbiosis fully. On the other hand, GSH synthesis appears to be essential for proper development of the root nodules during the symbiotic interaction. Elucidating the mechanisms that control ROS/RNS signalling during symbiosis could therefore contribute in defining a powerful strategy to enhance the efficiency of the symbiotic interaction.     

Intracellular bacteria in ciliates

Ciliates are frequently colonized by other micro-organisms. The large size of ciliate cells offers habitats for hundreds to thousands of bacteria in different compartments, such as cytoplasm, nuclei and even perinuclear spaces. Size, phagocytic feeding habit and other features appear to be favorable pre-adaptations of ciliates for symbiosis with bacteria. Certain intracellular bacteria are permanent symbionts that are not infectious, whereas others are highly infectious. Both types show specific adaptations. With their wide spectrum of phylogenetic positions, intracellular bacteria in ciliates show relationships to different taxa of free-living bacteria and even archaea. Certain symbionts may be deleterious for their host ciliates, whereas others may provide a selective advantage under appropriate conditions or even be essential for the host cells. Depending on the nature of a symbiont, its prevalence in a host population may be low or high. Symbionts that express a killer toxin affecting non-infected ciliates achieve high infection rates in a host population. whereas certain infectious bacteria may only show a low prevalence.     

Role of allelopathic compounds in the regulation and development of legume-rhizobial symbiosis

It was discovered that aromatic compounds isolated from root exudates of three legume species (Pisum sativum L., Vicia faba L. var. major Hartz, and Glycine max L. MERR) and identified as N-phenyl-2-naphthyl amine, dibutyl, and dioctyl esters of ortho-phthalic acid, which are known to work as negative allelopathic substances, are involved in the regulation of legume-rhizobial symbiosis formation after the inoculation of roots with rhizobia under unfavorable conditions for symbiosis.     

A new kind of prion: a modified protein necessary for its own modification

We recently described an infectious protein (prion) unrelated to amyloid formation, that is an enzyme whose precursor can only be activated by the active form of the enzyme. All previously described infectious proteins are self-propagating amyloid forms of chromosomally encoded proteins. The infectious enzyme, vacuolar protease B (PrB), can activate its own precursor in an indefinitely self-propagating process. Transfer from cell to cell of cytoplasm containing active protease B transmits this non-chromosomal gene. The importance of this system is that many protein-modifying enzymes may act on themselves, and if conditions are right, may become prions as well.     

Influence of salt stress on the genetically polymorphic system of Sinorhizobium meliloti-Medicago truncatula

The impacts of salt stress (75 mM NaCl) on the ecological efficiency of the genetically polymorphic Sinorhizobium meliloti-Medicago truncatula system were studied. Its impact on a symbiotic system results in an increase of the partners’ variability for symbiotic traits and of the symbiosis integrity as indicated by: (a) the specificity of the partners’ interactions-the nonadditive inputs of their genotypes into the variation of symbiotic parameters and (b) the correlative links between these parameters. The structure of the nodD1 locus and the plasmid content correlates to the efficiency of the symbiosis between S. meliloti and M. truncatula genotypes under stress conditions more sufficiently than in the absence of stress. Correlations between the symbiotic efficiency of rhizobia strains and their growth rate outside symbiosis are expressed under stress conditions, not in the absence of stress. Under salt stress symbiotic effectiveness was decreased for M. truncatula line F83005.5, which was salt sensitive for mineral nutrition. The inhibition of symbiotic activity for this line is linked with decreased nodule formation, whereas for Jemalong 6 and DZA315.16 lines it is associated with repressed N₂-fixation. It was demonstrated for the first time that salt stress impairs the M. truncatula habitus (the mass: height ratio increased 2- to 6-fold), which in the salt-resistant cultivar Jemalong 6 is normalized as the result of rhizobia inoculation.     

Root-associated n(2) fixation (acetylene reduction) by enterobacteriaceae and azospirillum strains in cold-climate spodosols

N(2) fixation by bacteria in associative symbiosis with washed roots of 13 Poaceae and 8 other noncultivated plant species in Finland was demonstrated by the acetylene reduction method. The roots most active in C(2)H(2) reduction were those of Agrostis stolonifera, Calamagrostis lanceolata, Elytrigia repens, and Phalaris arundinacea, which produced 538 to 1,510 nmol of C(2)H(4).g (dry weight). h when incubated at pO(2) 0.04 with sucrose (pH 6.5), and 70 to 269 nmol of C(2)H(4). g (dry weight).h without an added energy source and unbuffered. Azospirillum lipferum, Enterobacter agglomerans, Klebsiella pneumoniae, and a Pseudomonas sp. were the acetylene-reducing organisms isolated. The results demonstrate the presence of N(2)-fixing organisms in associative symbiosis with plant roots found in a northern climatic region in acidic soils ranging down to pH 4.0.     

Mechanisms in plant growth-promoting rhizobacteria that enhance legume–rhizobial symbioses

Nitrogen fixation is an important biological process in terrestrial ecosystems and for global crop production. Legume nodulation and N₂ fixation have been improved using nodule-enhancing rhizobacteria (NER) under both regular and stressed conditions. The positive effect of NER on legume–rhizobia symbiosis can be facilitated by plant growth-promoting (PGP) mechanisms, some of which remain to be identified. NER that produce aminocyclopropane-1-carboxylic acid deaminase and indole acetic acid enhance the legume–rhizobia symbiosis through (i) enhancing the nodule induction, (ii) improving the competitiveness of rhizobia for nodulation, (iii) prolonging functional nodules by suppressing nodule senescence and (iv) upregulating genes associated with legume–rhizobia symbiosis. The means by which these processes enhance the legume–rhizobia symbiosis is the focus of this review. A better understanding of the mechanisms by which PGP rhizobacteria operate, and how they can be altered, will provide opportunities to enhance legume–rhizobial interactions, to provide new advances in plant growth promotion and N₂ fixation.     

Arbuscular mycorrhizal symbiosis modifies the effects of a nitric oxide donor (sodium nitroprusside;SNP) and a nitric oxide synthesis inhibitor (Nω-nitro-L-arginine methyl ester;L-NAME) on lettuce plants under well watered and drought conditions

Arbuscular mycorrhizal (AM) symbiosis is known to help the host plant to overcome environmental stresses as drought by a combination of multiple mechanisms including enhancing of root water uptake capacity. On the other hand, Nitric oxide (NO) is involved in regulating the response of plants to environmental stresses and colonization process of AM fungi. The objective of this research was to study how AM and non-AM lettuce plants responded to a NO donor (sodium nitroprusside; SNP) or to a NO synthesis inhibitor (Nω-nitro-L-arginine methyl ester hydrochloride; L-NAME) under well watered and drought conditions. Most remarkable results were that L-NAME increased the percentage of AM colonized roots under both water regimes and AM plants modified the shoot:root ratio by both chemicals under well watered conditions. Also, the deleterious effects of SNP treatment were partially prevented by AM symbiosis. Moreover, NO could be involved in the diminution of leaf water content under drought conditions, and SNP treatment seems to favor apoplastic water path inside roots. Therefore, different outcomes of relative water content, stomatal conductance and root hydraulic conductivity observed between AM and non-AM plants could be mediated by NO.     

Extracellular polysaccharides and polysaccharide-containing biopolymers from Azospirillum species: properties and the possible role in interaction with plant roots

This paper reviews the results obtained in studies of the extracellular polysaccharides, lipopolysaccharide-protein complexes, polysaccharide-lipid complexes, lipopolysaccharides, and O-specific polysaccharides from bacteria of the genus Azospirillum. On the basis of present knowledge, the possible roles of the extracellular polysaccharides and polysaccharide-containing complexes of azospirilla in interaction with the roots of plants are discussed. Some pieces of evidence are considered in light of the lectin hypothesis originally proposed for the legume-Rhizobium symbiosis. In the context of these views of Azospirillum-cereal associative pairs, a key process at the early stages of the interaction is the specific reaction of cereal root lectins with the extracellular polysaccharide components, containing N-acetyl-d-glucosamine as part of their structure.     

The Role of Wheat Germ Agglutinin in Plant–Bacteria Interactions: A Hypothesis and the Evidence in Its Support

Wheat plants are known to develop the associative symbiosis with the rhizobacterium Azospirillum brasilense.We studied the interaction of a lectin, wheat germ agglutinin (WGA), which is also found in wheat roots, with A. brasilense, strain sp245. When added to the azospirillum culture to the final concentration of 10^–8to 10^–9M, WGA enhanced IAA production, dinitrogen fixation, and ammonium excretion by bacterial cells. WGA also promoted the synthesis of proteins, both new and those already present in bacterial cells. The hypothesis that WGA is a signal molecule rerouting the bacterial metabolism in the direction favorable for the growth and development of the host plant has been put forward. It is suggested that signal properties of WGA are the basis for one of the functions of this lectin and essential for the effective associative symbiosis.     

Reactive oxygen and nitrogen species in legume-rhizobial symbiosis: A review

Published data on the role of reactive oxygen and nitrogen species (ROS and RNS, respectively) in the formation and functioning of the legume-rhizobial symbiosis are summarized. It is assumed that ROS and RNS fulfill a double function in the legume-rhizobial symbiosis by triggering the mechanisms enabling symbiosis formation and the mechanisms preventing the development of symbiotic structures (i.e., the defensive responses). A hypothetic scheme illustrating the involvement of ROS and RNS in the formation of legume-rhizobial symbiosis is proposed.     

The regulation of arbuscular mycorrhizal symbiosis by phosphate in pea involves early and systemic signalling events

Most plants form root symbioses with arbuscular mycorrhizal (AM) fungi, which provide them with phosphate and other nutrients. High soil phosphate levels are known to affect AM symbiosis negatively, but the underlying mechanisms are not understood. This report describes experimental conditions which triggered a novel mycorrhizal phenotype under high phosphate supply: the interaction between pea and two different AM fungi was almost completely abolished at a very early stage, prior to the formation of hyphopodia. As demonstrated by split-root experiments, down-regulation of AM symbiosis occurred at least partly in response to plant-derived signals. Early signalling events were examined with a focus on strigolactones, compounds which stimulate pre-symbiotic fungal growth and metabolism. Strigolactones were also recently identified as novel plant hormones contributing to the control of shoot branching. Root exudates of plants grown under high phosphate lost their ability to stimulate AM fungi and lacked strigolactones. In addition, a systemic down-regulation of strigolactone release by high phosphate supply was demonstrated using split-root systems. Nevertheless, supplementation with exogenous strigolactones failed to restore root colonization under high phosphate. This observation does not exclude a contribution of strigolactones to the regulation of AM symbiosis by phosphate, but indicates that they are not the only factor involved. Together, the results suggest the existence of additional early signals that may control the differentiation of hyphopodia.     

The Release of Holospora obtusa from Paramecium caudatum Observed with a New Device for Extended In Vivo Microscopy

The macronudeus-specilic bacterium Holospora obtusa is released from its host cell Paramecium caudatum generally after a preceding cell division. Before division, most infectious forms of the bacteria can be found in a connecting strand of the dividing macronucleus. This connecting strand is deformed and finally expelled as a whole from the daughter cells. This process was observed and photographed with a simple device allowing observations for a long lime under a microscope without damage to the living cells. Key words. Bacterium, cytoproct, defecation, infection, macronucleus, symbiosis.