Studies on the Microstructure and Ultrastructure of Photosynthetic Apparatuses in Azolla

The structures of photosynthetic apparatuses such as leaves, chloroplasts and symbiotic cyanobacterum (blue-green algae) in Azolla-Anabaena azollae associations (Azolla imbricata (Roxb) Nakai) which occur in paddy fields of China were examined using light, scanning and transmission electrn microscopy. Some comparisons were made with A. filiculoides, A. japonica, A. caroliniana, A. pinnata and A. mexicana. Cross sections of A. imbricata were observed by light microscopy and the symbiotic association between the eukaryotic water fern and its prokaryotic blue-green algal symbiont, an Anabaena, was studied. The symbiotic cyanobacterum cells occur not only in a mature leaf cavity, but also in early stages of leaf development, around leaf primordia, and even in macrospores. Under scanning electron microscopy (SEM) it is possible to see stomata and nipples on the surface of dorsal lobes of the fern. The species in the subgenus Euazolla (i.e.A. filiculoides, A. japonica, A. caroliniana and A. mexicana) have rounded nipples, but those in the subgenus Rizosperma (i.e.A. imbricata and A. pinnta) prolate ones. This morphological character is first reported to be related to the taxonomic system. The result of the observation with transmission electron microscopy (TEM) shows that A. filiculoides contains more thylakoides in chloroplasts than A. imbricata does, and the grana lamellae have more stacks in the former than in the latter. The differences are in agreement with the differentiation of the two species in photosynthetic capacity. This may be one of the differences between the two subgenera. The ultrastructures of the symbiotic cyanobacterum are similar to those of free-living Anabaena. The vegetative cells show a typical bilayered cell wall and the heterocysts have a thikened wall. The thylakoid membranes in both heterocysts and vegetative cells are oftenseen forming whirls. During the division of vegetative cells, their contents aggregate and then redistribute.     

Effects of atmospheric SO2 on Azolla and Anabaena symbiosis

The water fern Azolla pinnata R. Br. was fumigated for 1 week with either 25, 50 or 100 nl 1⁻¹ SO₂. The symbiosis of Azolla with Anabaena azollae (spp.) was severely damaged by atmospheric SO₂ even at concentrations as low as 25 nl 1⁻¹, with significant reductions in growth, reduction of C₂H₂, NH₃ assimilation, protein synthesis, and heterocyst development. These disturbances appear to be mainly responsible for the extreme sensitivity of this fern to atmospheric SO₂. Changes in violaxanthin/antheraxanthin and epoxy-lutein/lutein ratios also indicate that free radical products are induced by atmospheric SO₂. These results suggest that the Azolla-Anabaena symbiotic system is a very responsive and reliable lower plant model to study the detailed effects of total sulphur deposition upon the balances between various important plant metabolic processes.     

Electron Microscopic Observation of the Azolla-Anabaena azollae Relationship

The structure of Azolla pinnate leaves was examined by means of light and transmission electron microscopy. Emphasis was put on the ultra structural cytology of leaf cavity hairs both in association with Anabaena and in Anabaena-free cultures of Azolla and on the roles of the hair in substance change between the symbionts. The cavity hairs were multicultural and branched. There were numerous mitochondria, plastids, endoplasmic reticular and ribosome’s in the cytoplasm of the hair. A. marked characteristic of the hair was the cell wall ingrowths; There were large electron-transparent area between the in growing cell wall and the plasmolemma. Some vesicles were found in this area. It was suggested that these vesicles as transporters played the role in transporting substances. Electron microscopy revealed that some differences were present between the basal cell and the terminal branched cell of the hairs. In the latter, the cytoplasma, organelles, growing wall and vesicles were richer in the electron-transparent area than in the former This feature of the terminal branched cell showed that the terminal cell of the hair was more active in absorption and/or secretion of metabolites than that of the basal cell. Some hairs were found near the stem apex of Azolla. It was suggested that these hairs functioned in supplying the nitric compounds for the algae living on the stem apex of Azolla. These algae had no ability to fix nitrogen because of lacking heterocyst. In the absence of Anabaena azollae, the leaf cavity hairs were still present in Azolla pinnata. However, a lot of osmiophilic substances can often be seen in the vacuole of this hair.     

Scanning Electron Microscopic Observation of Symbiotic Relationship of Azolla-Anabaena AzoUae During the Vegetative Growth

The occurrence and development of the hair ceils on the shoot tips and in the leaf cavities of A. filiculoides, A. microphylla, A. pinnata and their algae-free cultures were examined by means of scanning electron microscopy with microdissect technique. The patterns of Anabacna moving into the leave cavities from the shoot tips were investigated on three species of Azolla during their vegetative growth. The results showed that the patterns of symbiotic Anabaena infecting the leaf cavities are similarity among three species of Azolla and may be divided to the four phases which are summarized as follows: 1. occurrence of primary branched hair and adhesion of Anabaena; 2. development of primary branched hair and spreding of Anabaena; 3. building of hair bridge and entrance of Anabaena into the cavities; 4. formation of secondary simple hair and transference of Anabaena within the cavity. These observations resulted in a hypothesis that hair induces and leads its partner. It is suggested that the hair cell is likely to be a structure of Azolla for attracting and recognizing its symbiont in addition to transport substance between fern and algae.     

Azolla: Botany,physiology, and use as a green manure

This is a comprehensive review of literature pertaining to the aquatic fern Azolla and its nitrogen-fixing algal symbiont, Anabaena azollae. The preceding decade has witnessed an explosive growth in research on Azolla, and hopefully this paper will facilitate those efforts. The paper is broken into three major categories: botany, physiology and biochemistry, and agriculture. The botany section includes a world distribution map and reference tables for the 6 Azolla species, and includes the first review of literature on Anabaena azollae. The physiology and biochemistry section covers the range of topics from environmental factors to life processes and nitrogen fixation. Tables on the effect of growth regulators and on the rate of nitrogen fixation measured by acetylene reduction are presented. The agriculture section draws extensively from literature published in the People’s Republic of China and in the Democratic Republic of Vietnam. The major focus of this section is on the history and management practices for Azolla cultivation as a green manure for rice. The effect of weed suppression, use as a fish food and animal fodder, and the insects and diseases of Azolla are also discussed.     

The Effects of Light Quality on the Growth and Development of Anabaena azollae

The blue green algae Anabaena azollae has been isolated from the leaf cavity of water fern Azolla imbricata and grown aseptically in N-free medium. It was used for the study on the effects of white, red, yellow, green and blue light illuminations on the growth, acetylene reduction activity and heteroeyst formation. The results are summarized as follows: The growth rate under white, red and yellow light was greater than under green light and the yield of the former was increased nearly two folds than the latter after 7 days culture. However, the green light enhanced heterocyst formation up to 40% than the other light illuminations. Chlorophyll content was also higher under green light. Nitrogen fixation activity was proportional to the heterocyst formation. Whatever the light quality used, nitrogen fixation activity could be increased up to several folds by adding 0.2% fructose to the culture medium. When the fructose was added to the 5 days culture, green light illumination showed the highest nitrogen fixation activity. The significant reaction of Anabaena azollae to the green light seems to be a physiological feature of the symbiont.     

黄进华 Electron Microscopic Observation of Symbiotic Relationship Between Azolla and Anabaena During the Megaspore Germination and the Sporeling Development of Azolla

The process of establishing symbiotic relationship of Anabaena azollae with its host during the megaspore germination and sporeling development was examined using electron microscope. The observations revealed that most of the Anabaena spores were primarily adhered to the hair cells arisen from the sporeling subsequently introduced into the cavity of the 1st true leaf by the hair ceils. Following the sporeling development, the Anabaena spores were migrated to the newly developing cavities and the branch apex in the same way. The pattern of germination of the Anabaena spore is similar to that of free-living cyanobacteria. Germinating Anabaena spores were only found at shoot apex region and the cavities of the sporeling, 92% of them being onto or near the hair cells which exhibit the ultrastructural characteristics of the transfer cell. The results suggested that Anabaena spore might get the chemical signal stimulating germination or the substance supporting cell multiplication from the host. Some of vegetative cells derived from the Anabaena spore were differentiated in to nitrogen-fixing heterocysts within the cavity. This means that the new generation of the symbiosis between Anabaena and Azolla has begun.     

无藻萍的RAPD分析及其在三膘组满江红种间关系研究中的应用

从满江红Azolla Lam.萍-藻共生体中提取DNA进行的RAPD系统分析通常忽视了满江红样品的异质性。本研究通过获得无藻的满江红,比较有藻萍、无藻萍和离体藻之间的RAPD指纹图谱。发现从有藻萍中提取DNA的扩增反应来源于萍藻双方DNA的共同影响。依引物和植物样本的不同,共生双方对扩增产物的贡献结果不同,说明了用无藻萍进行RAPD检测的重要性。对满江红三膘组5个种的11个无藻萍样本进行了RAPD分析,由9个引物产生的127个DNA多态片段用于计算样本间的Jaccard相似系数和UPGMA树状聚类图。结果     

A Cobalt Requirement for Symbiotic Growth of Azolla filiculoides in the Absence of Combined Nitrogen

Cobalt was shown to be essential for the symbiotic growth of Azolla filiculoides and Anabacna azollac in the absence of fixed nitrogen. Addition of 0.01 μg/liter cobalt resulted in large increases in yield, chlorophyll content and nitrogen fixation as compared to control cultures without cobalt. Cobalt was not required for the growth of Azolla when nitrate nitrogen was supplied. The number of Anabaena azollae cells in the fronds of Azolla appeared to be decreased by ommission of cobalt from the culture medium containing nitrate nitrogen. It is concluded that cobalt is essential for the symbiotic growth of Azolla in the absence of combined nitrogen and it is suggested that the cobalt requirement is associated with the growth of Anabaena azollae.     

Isolation of Agrobacterium sp., strain from the Azolla leaf cavity

Abstract We have isolated a bacterial strain from surface sterilized fronds of the aquatic fern Azolla filiculoides and infer that it occurs in leaf cavities, along with the nitrogen-fixing cyanobacterium Anabaena azollae . This strain grew slowly on rich media, appeared to be Gram-negative, and was identified using a bacteriological multitest system as Agrobacterium sp. This strain, designated AFSR-1, could grow in the presence of 400 ppm of ammonium sulphate. DNA/DNA hydrodization analysis showed that a 16 S ribosomal RNA gene is located in the AFSR-1 strain on an identical DNA restriction fragment as in a strain of Agrobacterium tumefaciens . In addition, it was found that strain AFSR-1 contained DNA regions homologous to the modulation genes nodABC and nodL of Rhizobium trifolii , AFSR-1 contains a cryptic plasmid, and the genetic transfer of a broad-host-range plasmid pLAFR3 to strain AFSR-1 was achieved.     

The ultrastructure of Anabaena azollae in Azolla pinnata

The water fern Azolla pinnata R. Br. was collected in Northwestern India and its structure was examined using scanning and transmission electron microscopy. Emphasis was given to the symbiotic cyanobacterium. Anabaena azollae , and to its relationship to the hairs of the leaf cavities. The cyanobacterial filaments are loosely arranged and often adhere to the protruding hairs and the folded cell walls of the cavities. The vegetative cells show a typical bilayered cell wall. Thylakoids are few and evenly dispersed in mature vegetative cells and appear to lack phycobilisomes. Clusters of polyglucoside granules are distinguished between the thylakoids. Thylakoid membranes are often seen forming whirls and lattices. Polyhedral bodies (carboxysomes) appear particularly frequently in younger cells and in the proximity of polyphosphate bodies. Presence of structured granules, often positioned at both sides of the cross-wall of neighbouring vegetative cells, suggest a positive nitrogen balance. A high frequency of heterocysts is noted, while spores are not observed.
The outer cell wall of the unbranched, mostly two-celled, hairs shows frequent invaginations. The cytoplasma of the mature hair contains numerous organelles, and is penetrated by an electron transparent network with blebs and vesieles appearing. The exchange of metabolites between the symbiotic partners is discussed in relation to the structures noted.     

Mucilage acts to adhere cyanobacteria and cultured plant cells to biological and inert surfaces

Abstract The surfaces of cells of several species of cyanobacteria have been studied using low-temperature scanning electron microscopy (SEM), and have been shown to be covered in a layer of hydrated mucilage. This mucilage is observed in specimens of Anabaena azollae adhering to plant cells in their natural symbiotic niche (the cavity of the fronds of Azolla species) and in samples of the various species of cyanobacteria immobilised on polyurethane and polyvinyl support matrices. The mucilage appears to maintain the close contact observed between the cyanobacteria and these surfaces. Comparable films observed surrounding plant cells immobilised on similar polymeric surfaces are considered to be performing a similar function.     

Taxonomic status ofAnabaena azollae: An overview

Despite the long-standing and widespread use of the symbiotic association between the aquatic fern Azolla and its cyanobacterial symbiontAnabaena azollae to augment nitrogen supplies in rice paddy soils, very little is known about taxonomic aspects of the symbiosis. The two partners normally remain associated throughout vegetative and reproductive development, limiting the opportunities for interchanges. We have used monoclonal antibodies and DNA/DNA hybridization techniques to show that the cyanobacterial partner is not uniform throughout the genus Azolla, and that substantial diversification has occurred. With these procedures it will be possible to characterize genotypes of the cyanobacterium and to monitor experiments aimed at synthesizing new combinations ofAzolla species andAnabaena azollae strains.     

Azolla--a model organism for plant genomic studies

The aquatic ferns of the genus Azolla are nitrogen-fixing plants that have great potentials in agricultural production and environmental conservation. Azolla in many aspects is qualified to serve as a model organism for genomic studies because of its importance in agriculture, its unique position in plant evolution, its symbiotic relationship with the N2-fixing cyanobacterium, Anabaena azollae, and its moderate-sized genome. The goals of this genome project are not only to understand the biology of the Azolla genome to promote its applications in biological research and agriculture practice but also to gain critical insights about evolution of plant genomes. Together with the strategic and technical improvement as well as cost reduction of DNA sequencing, the deciphering of their genetic code is imminent.     

Regulation of glutamine synthetase activity and synthesis in free-living and symbiotic Anabaena spp.

Regulation of the synthesis and activity of glutamine synthetase (GS) in the cyanobacterium Anabaena sp. strain 7120 was studied by determining GS transferase activity and GS antigen concentration under a variety of conditions. Extracts prepared from cells growing exponentially on a medium supplemented with combined nitrogen had a GS activity of 17 mumol of gamma-glutamyl transferase activity per min per mg of protein at 37 degrees C. This activity doubled in 12 h after transfer of cells to a nitrogen-free medium, corresponding to the time required for heterocyst differentiation and the start of nitrogen fixation. Addition of NH3 to a culture 11 h after an inducing transfer immediately blocked the increase in GS activity. In the Enterobacteriaceae, addition of NH3 after induction results in the covalent modification of GS by adenylylation. The GS of Anabaena is not adenylylated by such a protocol, as shown by the resistance of the transferase activity of the enzyme to inhibition by Mg2+ and by the failure of the enzyme to incorporate 32P after NH3 upshift. Methionine sulfoximine inhibited Anabaena GS activity rapidly and irreversibly in vivo. After the addition of methionine sulfoximine to Anabaena, the level of GS antigen neither increased nor decreased, indicating that Glutamine cannot be the only small molecule capable of regulating GS synthesis. Methionine sulfoximine permitted heterocyst differentiation and nitrogenase induction to escape repression by NH3. Nitrogen-fixing cultures treated with methionine sulfoximine excreted NH3. The fern Azolla caroliniana contains an Anabaena species living in symbiotic association. The Anabaena species carries out nitrogen fixation sufficient to satisfy all of the combined nitrogen requirements of the host fern. Experiments by other workers have shown that the activity of GS in the symbiont is significantly lower than the activity of GS in free-living Anabaena. Using a sensitive radioimmune assay and a normalization procedure based on the content of diaminopimelic acid, a component unique to the symbiont, we found that the level of GS antigen in the symbiont was about 5% of the level in free-living Anabaena cells. Thus, the host fern appears to repress synthesis of Anabaena GS in the symbiotic association.     

结合态氮对满江红内生细菌群落组成和结构的影响

研究从超微结构和分子水平上探讨结合态氮对满江红(Azolla)叶腔中以共生藻占优势的微生物群落的影响。为排除外源污染并保留其内生菌的多样性, 采用茎尖组织培养并添加结合态氮等方法, 取得了表面无菌的含藻满江红(AmA)和无藻满江红(AmB)。电镜观察揭示, AmB较AmA的萍体表型有某种程度的修饰。AmA的微生物群落结构以共生藻、内生菌和宿主腺毛及其分泌物组成的生物被膜和藻囊为主要特征, 而AmB的叶腔几乎中空。基于16S rRNA基因和nifH基因的高通量测序结果显示, 生长于无氮培养液的AmA样品的微生物群落有相当高的多样性, 共有17个可操作分类单元(OTU), 分属4个细菌门, 并有一个以Nostoc azollae为优势的固氮微生物亚群包括草螺菌、根瘤菌和Niveispirillum等。而生长于富含结合态氮培养液的AmB样品的群落多样性明显降低, 仅有8个OTU, 且以Nostoc azollae为优势的上述固氮微生物亚群全部消失。研究结果表明, 通过调整氮素营养, 可改变宿主植物的微生物群落组成与结构, 进而改良植物的生长发育。     

Are bacteria the third partner of theAzolla-Anabaena symbiosis?

The development of the prokaryotic colony inAzolla filiculoides indicates thatAnabaena azollae is maintained through the life cycle of the fern and present in the leaves and megasporocarps. The same biological pattern is applied to the bacteria that are also present in these structures and seems to follow a development pattern identical to the cyanobacteria and probably can be considered the third partner of this symbiotic association.     

满江红鱼腥藻与其宿主的遗传多样性和协同性的RAPD分析

从16个代表不同种属或地域来源的满江红样本中分离出共生藻并通过处理获得无藻的满江红宿主,对二者同步进行了RAPD扩增,分别得到了大量DNA多态片段。通过建立满江红鱼腥藻及其宿主的UPGMA聚类关系图,看出二者在遗传分支上存在着一定程度的协同对应关系。但在种内的不同品系间,这种协同性有所减少,发现有的品系的共生藻发生了明显的变异。 Abstract:Symbiotic Anabeana azollae and its host plant Anabeana-free Azolla were isolated from 16 Azolla accessions representing different Azolla species or geographic origins.DNA polymorphic fragments were obtained by simultaneous RAPD amplification of both symbiont and host.The UPGMA clusters of Anabeana azollae and its host Azolla were established separately based on Dice coefficient caculation and a coordinated relationship was shown between Anabeana azollae and its Azolla host along both individual genetic divergence,but this genetic homology was reduced among different strains within Azolla species while the obvious mutants of Anabeana azollae were detected in some Azolla tested strains collected from different geographic area in the same host species.     

The pore of the leaf cavity of Azolla species: teat cell differentiation and cell wall projections

The differentiation of the specialized secretory teat cells of the leaf cavity pore of Azolla species was investigated at the ultrastructural level with emphasis on their peculiar cell wall projections. The results indicated that the projections are formed as soon as the teat cells complete their differentiation and that their production is principally associated with changes in endoplasmic reticulum profiles. The number of projections increases with the teat cell age and is stimulated under salt and P deficiency stresses. Salt stress also promotes their emergence on Azolla species that under normal conditions do not produce projections. Cytochemical tests on different Azolla species showed that the projection composition is almost identical: proteins, acidic polysaccharides, and pectin are always detected. This study revealed that Azolla teat cell projections differ fundamentally from other types of hitherto described cell wall projections that are considered as remnant structures from cell separation. In contrast, in Azolla teat cells projections are actively produced and compounds are excreted by an exocytotic mechanism. The possible role of the projections in the symbiosis of Azolla spp. with Anabaena azollae is discussed.