Early events during the establishment of the Gunnera/Nostoc symbiosis

The symbiosis between Gunnera and Nostoc was reconstituted using G. chilensis Lam. and G. manicata Linden, respectively, and three different Nostoc strains. Six stages characterised by specific modifications in both the cyanobiont and the host were recognised during the infection process. Mucilage-secreting stem glands developed on the Gunnera stems independent of the presence of cyanobacteria (Stage I). Soon after addition of the Nostoc isolates to the plant apices, an abundant differentiation of motile hormogonia commenced. The cyanobacteria accumulated in the mucilage on the surface of the gland (Stage II), and the hormogonia then proceeded into the stem tissue through intercellular channels (Stage III). At the channel bases, Nostoc was detected between the cell walls of small, densely cytoplasmic Gunnera cells and also in elaborate folds of these (Stage IV). The Gunnera cell walls subsequently dissolved adjacent to the cyanobacteria and Nostoc entered the host cells (Stage V). Once the intracellular association was formed, a high proportion of the vegetative Nostoc cells differentiated into heterocysts (Stage VI). Nostoc changed from being rich in inclusions (particularly cyanophycin) while on the gland surface into a comparatively non-storing form during penetration and the early intracellular stages. Bacteria were numerous on the gland surface, fewer in the channels, and were never detected within the Gunnera cells, indicating the existence of specific recognition mechanisms discriminating between conceivable microsymbionts. Mechanisms behind mutual adaptations and interactions between the two symbionts are discussed.The technical assistance of Anette Axen and Gary Wife is gratefully acknowledged. Financial support was provided by the Swedish Natural Science Research Council and the Hierta-Retzius foundations.     

Genetic variation at theapcAB,cpcAB,gvpA1, andnifH loci and in DNA methylation among N2-fixing cyanobacteria designatedNostoc punctiforme

Genetic similarity among cyanobacteria of a morphological subgroup ofNostoc was evaluated through a comparison of several specific genes and the extent of DNA methylation. Four of six cyanobacteria were originally cultured from facultative symbioses with higher plants (Gunnera andEncephalartos); these and one free-living isolate had been identified or reputed to beN. punctiforme. No consistent correlation to species or symbiotic history was found from DNA hybridizations to genes coding for phycocyanin (cpcAB), allophycocyanin (apcAB), gas vesicle protein (gvpA1), and dinitrogenase reductase (nifH). One gene (gvpC) was not present, andgvpA1 was a single-copy gene in all strains. The gas vesicle genes were concluded to be potentially useful for broadly characterizingNostoc or at least this subgroup. Incubations ofNostoc genomic DNA with 22 restriction endonucleases indicated a high degree of methylation and similarity of its methylated DNA to that of other heterocystous cyanobacteria. The genetic variation of theNostoc isolates was judged to reflect primarily different soil origins.     

Lichens toGunnera — with emphasis onAzolla

Summary N₂-fixing cyanobacteria occur in symbiotic associations with fungi (ascomycetes) as lichens and with a few green plants. The associated cyanobacterium is always a species ofNostoc orAnabaena. Only a small number of plant genera are involved but there is a remarkable range of host diversity. Associations occur with several bryophytes (e.g.Anthoceros, Blasia, Cavicularia), a pteridophyte (Azolla), cycads (nine genera includingMacrozamia andEncephalartos) and an angiosperm (Gunnera). Except forGunnera, where the cyanobacterium penetrates the plant cells, the cyanobacteria are extracellular with specialized morphological modifications and/or structures of the host plant organs providing an environment which facilitates interaction with the prokaryote.Salient aspects of current knowledge pertaining to the establishment, perpetuation, and functioning of the individual symbioses are summarized. Where possible this includes information concerning recognition and specificity, mode(s) of infection, morphological modifications/adaptations of the host plant and a synopsis of morphological, physiological and biochemical changes common to the symbiotic cyanobacteria. The latter encompasses heterocyst frequencies, enzymes involved in ammonia assimilation, photosynthetic capability and metabolic interaction with the host.TheAzolla-Anabaena symbioses, which have potential agronomic significance as an alternative nitrogen source and maintain continuity with the endophyte through the sexual cycle, are emphasized.     

Fingerprinting of Cyanobacteria Based on PCR with Primers Derived from Short and Long Tandemly Repeated Repetitive Sequences

The presence of repeated DNA (short tandemly repeated repetitive [STRR] and long tandemly repeated repetitive [LTRR]) sequences in the genome of cyanobacteria was used to generate a fingerprint method for symbiotic and free-living isolates. Primers corresponding to the STRR and LTRR sequences were used in the PCR, resulting in a method which generate specific fingerprints for individual isolates. The method was useful both with purified DNA and with intact cyanobacterial filaments or cells as templates for the PCR. Twenty-three Nostoc isolates from a total of 35 were symbiotic isolates from the angiosperm Gunnera species, including isolates from the same Gunnera species as well as from different species. The results show a genetic similarity among isolates from different Gunnera species as well as a genetic heterogeneity among isolates from the same Gunnera species. Isolates which have been postulated to be closely related or identical revealed similar results by the PCR method, indicating that the technique is useful for clustering of even closely related strains. The method was applied to nonheterocystus cyanobacteria from which a fingerprint pattern was obtained.     

The luggage hypothesis: Comparisons of two phototrophic hosts with nitrogen-fixing cyanobacteria and implications for analogous life strategies for kleptoplastids/secondary symbiosis in dinoflagellates

Nostoc and Richelia belong to a group of heterocystous cyanobacteria and are unique within this group in forming intracellular symbioses with phototrophic hosts, the angiosperm Gunnera and the diatoms (algae) Rhizosolenia and Hemiaulus, respectively. The function of the cyanobiont is similar in the symbioses, namely providing fixed atmospheric nitrogen to their hosts; also the cyanobionts are contained in a host compartment, the symbiosome. The evolutionary timescale for the cyanobiont-endosymbiosis formation is in both instances about ≈90 Ma. However, the potentials for further co-evolution of host and microsymbiont, are different. Nostoc is regarded as preyed upon by its host, while in the Richelia-Rhizosolenia symbiosis example the evolution towards a new type of permanent organelle is possible. It is proposed that symbiosis is ruled by divergent host strategies. In the case of Richelia-Rhizosolenia the evolution of a permanent symbiosis is linked to diatom hosts needing to carry the cyanobiont permanently, as it is not available free-living in the oceans. However, in the case of Nostoc/Gunnera, the host exploits an abundant cyanobacterial species. A model where the relative abundance of microsymbionts determines the nature of the symbiosis comes into view: If environmental ratios of host/microsymbiont are so that hosts are the dominating party, then the host has to carry the microsymbiont as luggage (vertical transmission). Likewise, if the ratio of microsymbiont is higher than host, than the host will prey on the microsymbiont (horizontal transmission). The article also discusses the retention of secondary plastids in dinoflagellates. We show that dinoflagellates are organisms that exemplify both types of strategies that is either preying or harbouring a permanent organelle. The difference from the cyanobacterial example is that only parts of the eukaryotic microsymbionts are kept, usually only the plastid. We emphasize that the dinoflagellates can obtain their plastids from various different organisms. The luggage theory offers an explanation to why some dinoflagellate species contain kleptoplastids, while others have permanent, secondary plastids and some have tertiary plastids.     

Diversity of Endosymbiotic Nostoc in Gunnera magellanica (L) from Tierra del Fuego, Chile

Global warming is causing ice retreat in glaciers worldwide, most visibly over the last few decades in some areas of the planet. One of the most affected areas is the region of Tierra del Fuego (southern South America). Vascular plant recolonisation of recently deglaciated areas in this region is initiated by Gunnera magellanica, which forms symbiotic associations with the cyanobacterial genus Nostoc, a trait that likely confers advantages in this colonisation process. This symbiotic association in the genus Gunnera is notable as it represents the only known symbiotic relationship between angiosperms and cyanobacteria. The aim of this work was to study the genetic diversity of the Nostoc symbionts in Gunnera at three different, nested scale levels: specimen, population and region. Three different genomic regions were examined in the study: a fragment of the small subunit ribosomal RNA gene (16S), the RuBisCO large subunit gene coupled with its promoter sequence and a chaperon-like protein (rbcLX) and the ribosomal internal transcribed spacer (ITS) region. The identity of Nostoc as the symbiont was confirmed in all the infected rhizome tissue analysed. Strains isolated in the present study were closely related to strains known to form symbioses with other organisms, such as lichen-forming fungi or bryophytes. We found 12 unique haplotypes in the 16S rRNA (small subunit) region analysis, 19 unique haplotypes in the ITS region analysis and 57 in the RuBisCO proteins region (rbcLX). No genetic variability was found among Nostoc symbionts within a single host plant while Nostoc populations among different host plants within a given sampling site revealed major differences. Noteworthy, interpopulation variation was also shown between recently deglaciated soils and more ancient ones, between eastern and western sites and between northern and southern slopes of Cordillera Darwin. The cell structure of the symbiotic relationship was observed with low-temperature scanning electron microscopy, showing changes in morphology of both cyanobiont cells (differentiate more heterocysts) and plant cells (increased size). Developmental stages of the symbiosis, including cell walls and membranes and EPS matrix states, were also observed.     

Multiple Roles of Soluble Sugars in the Establishment of Gunnera-Nostoc Endosymbiosis

Gunnera plants have the unique ability to form endosymbioses with N₂-fixing cyanobacteria, primarily Nostoc. Cyanobacteria enter Gunnera through transiently active mucilage-secreting glands on stems. We took advantage of the nitrogen (N)-limitation-induced gland development in Gunnera manicata to identify factors that may enable plant tissue to attract and maintain cyanobacteria colonies. Cortical cells in stems of N-stressed Gunnera plants were found to accumulate a copious amount of starch, while starch in the neighboring mature glands was nearly undetectable. Instead, mature glands accumulated millimolar concentrations of glucose (Glc) and fructose (Fru). Successful colonization by Nostoc drastically reduced sugar accumulation in the surrounding tissue. Consistent with the abundance of Glc and Fru in the gland prior to Nostoc colonization, genes encoding key enzymes for sucrose and starch hydrolysis (e.g. cell wall invertase, α-amylase, and starch phosphorylase) were expressed at higher levels in stem segments with glands than those without. In contrast, soluble sugars were barely detectable in mucilage freshly secreted from glands. Different sugars affected Nostoc’s ability to differentiate motile hormogonia in a manner consistent with their locations. Galactose and arabinose, the predominant constituents of polysaccharides in the mucilage, had little or no inhibitory effect on hormogonia differentiation. On the other hand, soluble sugars that accumulated in gland tissue, namely sucrose, Glc, and Fru, inhibited hormogonia differentiation and enhanced vegetative growth. Results from this study suggest that, in an N-limited environment, mature Gunnera stem glands may employ different soluble sugars to attract Nostoc and, once the cyanobacteria are internalized, to maintain them in the N₂-fixing vegetative state.Nitrogen (N) is an essential element for plant growth, but availability of reduced N in the soil is often limiting. Representatives from a wide range of land plants have evolved the ability to form associations with N₂-fixing microbes (Franche et al., 2009). Associations between rhizobia and legume plants are well-characterized examples of plant-bacterial N₂-fixing symbioses. Unlike rhizobia, which generally exhibit narrow host ranges (Kistner and Parniske, 2002), N₂-fixing cyanobacteria are able to form productive associations with a broad range of plants, including bryophytes (hornworts and liverworts), ferns (Azolla), gymnosperms (cycads), and angiosperms (Gunnera; for review, see Rai et al., 2000; Adams et al., 2006). Free-living cyanobacteria within the genus Nostoc can fix N in specialized microoxic cells called heterocysts. The ability of Nostoc to fix N independent of a host environment may facilitate the formation of symbioses with a wide range of plants. Understanding the physiological conditions that enable a plant host to enter into symbiotic associations with cyanobacteria may allow us to extend the benefit of biological N fixation to crops outside the legume family.Nostoc has the ability to differentiate not only into filaments bearing heterocysts but also into transiently motile filaments, known as hormogonia, which enable the cyanobacteria to enter plants (Meeks and Elhai, 2002). Nostoc can be induced to form hormogonia by different environmental stimuli and by a hormogonia-inducing factor released from N-stressed host plants (Meeks and Elhai, 2002; Adams et al., 2006). The attraction of hormogonia to plants is much less specific than that of rhizobia. Hormogonia are attracted to root extracts from either host or nonhost plants and even to certain simple sugars, such as Ara, Glc, and Gal (Nilsson et al., 2006). After entering a plant host, hormogonia revert back to filaments with N₂-fixing heterocysts. Inside the host, further hormogonia formation is suppressed, and heterocysts appear at a frequency of about 30% to 40%, 3- to 4-times higher than that found in free-living Nostoc (Meeks and Elhai, 2002). Although free-living Nostoc species can support N₂ fixation through photosynthesis, under symbiotic conditions they rely on photosynthate from the host plant. In general, the sugars (Suc, Glc, and Fru) known to support heterotrophic growth in the dark by free-living cyanobacteria coincide with those that support nitrogenase activity in Nostoc-plant associations (Meeks and Elhai, 2002). However, the Nostoc-Gunnera association may be exceptional; only Glc and Fru have been shown to sustain nitrogenase activities (Man and Silvester, 1994; Wouters et al., 2000), although Suc anddextrin were able to keep Nostoc alive without light (Wouters et al., 2000). It is evident from cyanobacterial studies that the plant hosts have evolved the ability to regulate cyanobacterial growth and differentiation during symbiotic associations (Meeks and Elhai, 2002).However, because most studies of plant-cyanobacterial associations have focused on the cyanobacterial partner (e.g. Wang et al., 2004; Ekman et al., 2006), the mechanisms through which plant hosts attract, internalize, and maintain cyanobacteria remain to be elucidated (Adams et al., 2006).The Nostoc-Gunnera association is an ideal system with which to study plant-cyanobacteria symbioses, not only because Gunnera is the only genus of angiosperms known to form endosymbioses with N₂-fixing cyanobacteria but also because the association between the two can be readily established in the laboratory (Bergman et al., 1992; Chiu et al., 2005). Nostoc hormogonia enter Gunnera plants through specialized glands located on the stem. As the gland matures, it secretes polysaccharide-rich mucilage that attracts cyanobacteria (Nilsson et al., 2006), supports their growth on the gland surface (Towata, 1985; Chiu et al., 2005), and permits further hormogonia differentiation (Rasmussen et al., 1994). From there, hormogonia enter the gland and penetrate cells near the base of the gland in the stem (Bonnett, 1990; Bergman et al., 1992). Although each gland is only transiently capable of accepting cyanobacteria, new glands continue to form on the stem at the base of each new leaf.In contrast to the development of nodules in legumes, which requires a complex exchange of signals between the two symbiotic partners (Cooper, 2007), stem gland development in Gunnera takes place in the absence of cyanobacteria (Bonnett, 1990). N limitation, however, is a prerequisite for stem gland development (Chiu et al., 2005), as it is for nodulation (Barbulova et al., 2007). We have taken advantage of the N-deficiency-induced gland development in G. manicata to identify factors that enable Gunnera to form endosymbiosis with cyanobacteria. This study investigated changes in the carbohydrate metabolism during Gunnera gland development and discovered that tissue in the mature glands accumulated high levels of soluble sugars prior to the arrival of cyanobacteria. In agreement with this finding, several key genes encoding enzymes for starch/Suc hydrolysis were expressed at higher levels in the gland compared to the stem. Furthermore, we found that various sugars cyanobacteria may encounter as they approach Gunnera glands as opposed to those they would encounter within plant cells differentially affected Nostoc’s ability to form motile hormogonia.     

Developmental patterns related to nitrogen fixation in theNostoc-Gunnera magellanica Lam. symbiosis

Developmental patterns related to nitrogen fixation in the heterocystous cyanobacteriumNostoc harboured in distinct colonies along the stem ofGunnera magellanica Lam. plantlets were examined using successive plant sections. Pronounced morphological, physiological and biochemical alterations in the cyanobacterium were demonstrated. Close to the growing apex the cyanobacterial biomass, contained in smallGunnera cells, was low and consisted mostly of vegetative cells showing a high density of different storage structures except for cyanophycin granules. In contrast, both the total and specific nitrogenase activity and the relative nitrogenase protein level were at maximum within this part; while the frequency of heterocysts increased from zero to 30% within the same area. The nitrogenase protein was localized only in the heterocysts throughout the plant. Further down theGunnera stem there was a progressive increase in both the cyanobacterial biomass and the heterocyst frequency, which finally constituted about 60% of the cyanobacterial cell population. Throughout this part of the stem, cyanophycin granules were frequent in the vegetativeNostoc cells. At the base of the stem, degeneratedNostoc cells dominated and the nitrogenase activity was close to zero, although the nitrogenase protein remained. Degeneration of theNostoc cells and leaf shedding coincided. Both intact plants (approx. 20 mm in height) and plant stem sections (2 mm in length) showed substantial nitrogenase activity, although sectioning caused a 30% reduction in total nitrogenase activity.     

Phylogeny of symbiotic cyanobacteria within the genus <Emphasis Type="Italic">Nostoc</Emphasis> based on 16S rDNA sequence analyses

A phylogenetic analysis of selected symbiotic Nostoc strain sequences and available database 16S rDNA sequences of both symbiotic and free-living cyanobacteria was carried out using maximum likelihood and Bayesian inference techniques. Most of the symbiotic strains fell into well separated clades. One clade consisted of a mixture of symbiotic and free-living isolates. This clade includes Nostoc sp. strain PCC 73102, the reference strain proposed for Nostoc punctiforme. A separate symbiotic clade with isolates exclusively from Gunnera species was also obtained, suggesting that not all symbiotic Nostoc species can be assigned to N. punctiforme. Moreover, isolates from Azolla filiculoides and one from Gunnera dentata were well nested within a clade comprising most of the Anabaena sequences. This result supports the affiliation of the Azolla isolates with the genus Anabaena and shows that strains within this genus can form symbioses with additional hosts. Furthermore, these symbiotic strains produced hormogonia, thereby verifying that hormogonia formation is not absent in Anabaena and cannot be used as a criterion to distinguish it from Nostoc.The GenBank accession numbers for the cyanobacterial 16S rRNA gene sequences determined in this study are AY742447-AY742454.     

Genomic diversity and CRISPR-Cas systems in the cyanobacterium Nostoc in the High Arctic

Nostoc (Nostocales, Cyanobacteria) has a global distribution in the Polar Regions. However, the genomic diversity of Nostoc is little known and there are no genomes available for polar Nostoc. Here we carried out the first genomic analysis of the Nostoc commune morphotype with a recent sample from the High Arctic and a herbarium specimen collected during the British Arctic Expedition (1875–76). Comparisons of the polar genomes with 26 present-day non-polar members of the Nostocales family highlighted that there are pronounced genetic variations among Nostoc strains and species. Osmoprotection and other stress genes were found in all Nostoc strains, but the two Arctic strains had markedly higher numbers of biosynthetic gene clusters for uncharacterised non-ribosomal peptide synthetases, suggesting a high diversity of secondary metabolites. Since viral–host interactions contribute to microbial diversity, we analysed the CRISPR-Cas systems in the Arctic and two temperate Nostoc species. There were a large number of unique repeat-spacer arrays in each genome, indicating diverse histories of viral attack. All Nostoc strains had a subtype I-D system, but the polar specimens also showed evidence of a subtype I-B system that has not been previously reported in cyanobacteria, suggesting diverse cyanobacteria–virus interactions in the Arctic.     

Sub-Cellular Element Analysis of a Cyanobacterium (Nostoc sp.) in Symbiosis with Gunnera manicata by ESI and EELS

Element analysis using electron spectroscopic imaging (ESI) and electron energy loss spectroscopy (EELS) was performed in a symbiotic Nostoc sp. strain found in the upper stem tissue of Gunnera manicata, and in Nostoc PCC 9229, a free-living heterocyst-forming cyanobacterium able to enter into symbiosis with the angiosperm Gunnera in reconstitution experiments. ESI and EELS unequivocally identified the four elements nitrogen (N), sulphur (S), phosphorus (P) and oxygen (O) in different inclusion bodies of these biological specimens. High amounts of nitrogen were solely detected in huge cyanophycin granules in vegetative cells of the symbiotic Nostoc strain, whereas large polyphosphate bodies, containing high amounts of phosphorus, sulphur and oxygen, could be seen in the free-living Nostoc PCC 9229. The latter were usually not present or, when found, very small in vegetative cells of the cyanobiont.     

New insights into the pollen morphology of the genus Gunnera (Gunneraceae)

Pollen grains from ten species of Gunnera, chosen to represent the six different subgenera in the genus, were examined using light and scanning electron microscopy. The aim of the study was to explore characters that have the potential to define different types of pollen within Gunnera and to study the evolution of these characters in light of the phylogeny of the genus. According to our results, there are three main types of pollen in the examined species of Gunnera. Type 1, unique for the South American species G. herteri (subgenus Ostenigunnera), is characterised by an imperfect reticulum with sinuous undulating-creasted muri. A reticulum with equidimensional polygonal lumina is typical for the plesiomorphic type of pollen (type 2) present in subgenera Gunnera, Misandra and Panke. Lastly, pollen grains of subgenera Pseudogunnera and Milligania are characterised by a reticulum with lumina of variable shape and size (type 3). In G. macrophylla (subgenus Pseudogunnera), the lumina in the apocolpia are of a different shape and size from the lumina in the mesocolpia (type 3a), while in G. dentata, G. monoica and G. cordifolia (subgenus Milligania), the lumina are identical in the apocolpium and the mesocolpium (type 3b).

The identification of pollen types will possibly allow the interpretation of the different specimens of Tricolpites reticulatus, the fossil species believed to be allied to the extant Gunnera.

In addition to the revision on the pollen of Gunnera, a brief comparison between the pollen of this genus and its sister group Myrothamnus is reported.     

Effect of Environmental Factors on Cyanobacteria Richness in Some Agricultural Soils

The physicochemical variations of soil, such as temperature, pH, nutrients, and the type of plant cultivation, affect the diversity of cyanobacteria, whether heterocystous or not. The aim of this study was to identify the species of cyanobacteria in a soil and the effect of environmental characteristics on cyanobacteria. Soil samples collected from six different agricultural sites in Al Diwaniyah city/Iraq during September 2016 in the autumn season were analyzed, and the physicochemical characteristics of the samples were measured using approved methods.

The results showed significant correlation and differences between cyanobacteria composition, distribution, and physicochemical factors among soil sites. The Agricultural soil was slightly alkaline and moderately saline and contained abundant nutrients, cations and a high percentage of organic matter. All these characteristics influenced the distribution and diversity of cyanobacteria. Ninety-six species were identified, including four heterocystous species represented by Anabaena, Calothrix, Cylnidrospermum, and Nostoc. However, the non-heterocystous were represented by 13 species: Aphanocapsa, Aphanothece, Arthrospira, Chroococcus, Gloeocapsa, Lyngbya, Merismopedia, Microcystis, Microcoleus, Oscillatoria, Phormidium, Schizothrix, and Spirulina. The dominant species of cyanobacteria was Oscillatoria, followed by Phormidium, Chroococcus, Gleocapsa and Lyngbya. The highest value of Shannon’s and Simpson’s diversities were registered in the Ghammas site, which is a paddy field, but the lowest was registered in the Afak site, cultivated with the alfalfa plant. Soil was classified as finely textured with silty clayey characterization, favorable for cyanobacteria growth.     

Associative Cyanobacteria Isolated from the Roots of Epiphytic Orchids

Associative cyanobacteria were isolated from the rhizoplane and velamen of the aerial roots of the epiphytic orchids Acampe papillosa, Phalaenopsis amabilis, and Dendrobium moschatum and from the substrate roots of A. papillosa and D. moschatum. Cyanobacteria were isolated on complete and nitrogen-free variants of BG-11 medium. On all media and in all samples, cyanobacteria of the genus Nostoc predominated. Nostoc, Anabaena, and Calothrixwere isolated from the surface of the A. papillosa aerial roots, whereas the isolates from the substrate roots were Nostoc, Oscillatoria,and representatives of the LPP group (Lyngbia, Phormidium, and Plectonema, incapable of nitrogen fixation). On the D. moschatum substrate roots, Nostoc and LPP group representatives were also found, as well as Fischerella. On the aerial roots of P. amabilis and D. phalaenopsis grown in a greenhouse simulating the climate of moist tropical forest, cyanobacteria were represented by Nostoc, LPP group, and Scytonema in D. phalaenopsis and by Nostoc, Scytonema, Calothrix, Spirulina, Oscillatoria, and the LPP group in P. amabilis. For D. moschatum, the spectra of cyanobacteria populating the substrate root rhizoplane and the substrate (pine bark) were compared. In the parenchyma of the aerial roots of P. amabilis, fungal hyphae and/or their half-degraded remains were detected, which testifies to the presence of mycorrhizal fungi in this plant. This phenomenon is attributed to the presence of a sheath formed by cyanobacteria and serving as a substrate for fungi.     

Diversity of DNA methylation pattern and total DNA restriction pattern in symbiotic Nostoc

Attempts were made to use total DNA restriction patterns and the response of purified DNA to treatment with restriction endonucleases to characterize several symbiotic Nostoc strains which had been isolated from different host plants cultivated in Italy. Among 27 restriction endonucleases tested, several did not cut any DNA and no significant variation in the susceptibility of the genomes to DNA restriction was seen among the strains. Therefore the Nostoc strains could not be separated into groups based on their different susceptibilities to the action of restriction endonucleases. However, in studies of total DNA restriction patterns, the restriction endonucleases BfrI and HpaI gave unique band patterns for each cyanobacterial isolate. Different profiles were even found in strains isolated from host plants belonging to the same species. The results do not support any definition of symbiotic Nostoc genomic groups or species and show that a tight specificity between the host plant and the cyanobacterium might not exist in the symbiotic associations involving Nostoc.     

念珠藻属植物nifH基因的适应性进化分析

念珠藻(Nostoc)固氮过程关键在于固氮酶的催化,而固氮酶复合物中的铁蛋白(NifH)是由高度保守的nifH基因编码的,该基因是进化史上现存最古老的功能基因之一。该研究选取念珠藻属及近缘类群的nifH基因序列共40条,采用最大似然法构建系统发育树;运行PAML4.9软件,对nifH基因编码蛋白进行生物信息学分析,并使用分支模型、位点模型和分支-位点模型检测该基因的选择位点,探讨nifH基因的适应性进化特征。结果表明:(1)最大似然树显示内类群中该研究物种共分为6个分支(A、B、C、D、E和F),其中D和E是2个大的分支,每个大分支中又各包含2个特殊的小分支A、F和B、C,其中F分支包含新疆古尔班通古特沙漠采集到的9株念珠藻,A分支包含F分支及该研究测定序列的4株葛仙米,B分支包含本研究测定序列的4株地皮菜和3株未定种的念珠藻,C分支包含NCBI数据库中下载的5株念珠藻、鱼腥藻序列和本研究测定序列的1株念珠藻。(2)在所分析的3种进化模型中,仅通过分支-位点模型检测出14个统计学上显著的正选择位点,即1F、2S、3S、4T、5A、6F、7F、8I、9S、10C、17I、27Y、29D和31R位点,表明念珠藻属植物的nifH基因发生了适应性变化,分支-位点模型是研究藻类基因适应性进化较好的模型。     

Ornithine cycle inNostoc PCC 73102: Stimulation of in vitro ornithine carbamoyl transferase activity by addition of arginine

Cells ofNostoc PCC 73102, a free-living cyanobacterium originally isolated from the cycadMacrozamia, were cultured under different conditions and examined for the presence ofin vitro active ornithine carbamoyl transferase (OCT). Cells grown in darkness showed a significant increase ofin vitro OCT activity compared with the activity when grown in light. Addition of external arginine in the growth medium increasedin vitro OCT activity both in light and in darkness. Moreover, the highestin vitro OCT activity was observed in cells grown in darkness and with the addition of external arginine, a sevenfold increase compared with cells grown in light. Native-PAGE in combination with on gel OCT activity stain demonstrated that external arginine induced the presence of twoin vitro active OCT. In addition to the previously described 80 kDa OCT [Physiol Plant 84:275–282, 1992], a secondin vitro active enzyme with a molecular weight of approximately 118 kDa appeared. Western immunoblots, with native cell-free extracts and antibodies directed either against native or denatured OCT purified fromPisum sativum, confirmed that both enzymes were OCT. Moreover, with a denatured cell-free extract only one polypeptide, with a molecular weight of about 40 kDa, was recognized, indicating that the secondin vitro active OCT might be a trimer with three identical subunits.     

16S rRNA-Targeted identification of cyanobacterial genera using oligonucleotide-probes immobilized on bacterial magnetic particles

16S rRNA-targeted identification of cyanobacterial genera, Anabaena,Microcystis, Nostoc, Oscillatoria, Synechococcus wasdeveloped using bacterial magnetic particles (BMPs). 16S rRNA-targetedcapture probes designed from the genus specific region of the 16S rRNAsequence were immobilized on BMPs. Identification of cyanobacteria wasperformed by a sandwich hybridization using the capture probes – BMPconjugates and a digoxigenin (DIG)-labeled detector probe complementaryto the highly conserved 16S rRNA sequence for cyanobacteria. Theluminescence intensity of the probe/target-BMP hybrids was measured afterreaction with alkaline phosphatase conjugated anti-DIG antibody. Fivespecies of cyanobacteria from five different genera were successfullydiscriminated using this magnetic capture system.     

Comparison of DNA restriction fragment length polymorphisms of Nostoc strains in and from cycads

DNA was prepared from cyanobacteria freshly isolated from coralloid roots of natural populations of five cycad species: Ceratozamia mexicana mexicana (Mexico), C. mexicana robusta (Mexico), Dioon spinulosum (Mexico), Zamia furfuraceae (Mexico) and Z. skinneri (Costa Rica). Using the Southern blot technique and cloned Anabaena PCC 7120 nifK and glnA genes as probes, restriction fragment length polymorphisms of these cyanobacterial symbionts were compared. The five cyanobacterial preparations showed differences in the sizes of their DNA fragments hybridizing with both probes, indicating that different cyanobacterial species and/or strains were in the symbiotic associations. On the other hand, a similar comparison of cyanobacteria freshly collected from a single Encephalartos altensteinii coralloid root and from three independently subcultured isolates from the same coralloid root revealed that these were likely to be one and the same organism. Moreover, the complexity of restriction patterns shows that a mixture of Nostoc strains can associate with a single cycad species although a single cyanobacterial strain can predominate in the root of a single cycad plant. Thus, a wide range of Nostoc strains appear to associate with the coralloid roots of cycads.Non-standard abbreviations bp base pairs - kbp kilobase pairs - RFLP's restriction fragment length polymorphisms     

Effect of crowding on the electron transfer process from plastocyanin and cytochrome c<Subscript>6</Subscript> to photosystem I: a comparative study from cyanobacteria to green algae

Plastocyanin and cytochrome c ₆, the alternate donor proteins to photosystem I, can be acidic, neutral or basic; the role of electrostatics in their interaction with photosystem I vary accordingly for cyanobacteria, algae and plants. The effect of different crowding agents on the kinetics of the reaction between plastocyanin or cytochrome c ₆ and photosystem I from three different cyanobacteria, Synechocystis PCC 6803, Nostoc PCC 7119 and Arthrospira maxima, and a green alga, Monoraphidium braunii, has been investigated by laser flash photolysis, in order to elucidate how molecular crowding affects the interaction between the two donor proteins and photosystem I. The negative effect of viscosity on the interaction of the two donors with photosystem I for the three cyanobacterial systems is very similar, as studied by increasing sucrose concentration. Bovine serum albumin seems to alter the different systems in a specific way, probably by means of electrostatic interactions with the donor proteins. Ficoll and dextran behave in a parallel manner, favouring the interaction by an average factor of 2, although this effect is somewhat less pronounced in Nostoc. With regards to the eukaryotic system, a strong negative effect of viscosity is able to overcome the favourable effect of any crowding agent, maybe due to stronger donor/photosystem I electrostatic interactions or the structural nature of the eukaryotic photosystem I-enriched membrane particles.