Assembly of the subcellular parts of <Emphasis Type="Italic">Bryopsis hypnoides</Emphasis> Lamouroux into new protoplasts

The chloroplasts, mitochondria, and protoplasm devoid of mature chloroplasts (PMC) of Bryopsis hypnoides Lamouroux were isolated by low-speed and sucrose density centrifugation. The PMC aggregated in artificial seawater, and then protoplasts without mature chloroplasts (PtMCs) were formed. Transmission electron microscopy and cytochemical studies indicated that there were mitochondria, nuclei, vesicles, and other small cell organelles in the PtMCs. Scanning electron microscopy showed that there were holes on the surface of 1-h PtMCs and then fewer holes on the surface of 24-h PtMCs, suggesting that a healing process occurred. The plasma membrane was formed over the surface of the PtMCs. However, the cell wall was not regenerated, and the newly formed PtMCs were ruptured and died in 3 days. Light intensity during alga maintenance before use influenced significantly (one-way ANOVA, P < 0.0001) on the number of PtMCs formed; the highest number of PtMCs was formed at 20μmol/(m² s). When isolated chloroplasts were transferred into seawater, there were only two or three chloroplasts aggregated together. However, isolated mitochondria and the mixed six layers of cell organelles (separated by sucrose density centrifugation) could not aggregate in the artificial seawater. This indicates that the conjunction of cell organelles is important for their aggregation. Published in Russian in Fiziologiya Rastenii, 2009, Vol. 56, No. 1, pp. 123–130. The text was submitted by the autors in English.     

Culturing the Segments of Bryopsis hypnoides Lamouroux Thalli Regenerated from Protoplast Aggregations

Bryopsis hypnoides Lamouroux was regenerated In vitro from the protoplasm squeezed out from wild algae and the regenerated Individuals had an advantage over Indlvlduala from the wild In terms of growth. Culturing of segments of thalll also showed that segments from the regenerated algae grew better than those from individuals from the wild. The segment that corresponds to a part of a cell, at least a part of the protoplasm, can develop Into a mature Individual, Including rhlzold and thallus, suggesting that a multlnucleate alga, such as B. hypnoides, Is different from higher plants, whose totlpotancy Is based on an Intact cell （or protoplasm）. Further cultivation of mature Individuals from segments Indicated that the organelles In the thallus had two ways In which they could survive when the alga was on the decline： （Ⅰ） the organelles were transferred Into a ball with a gelatinous envelope through a formed pipe and the ball seemed to be capable of being propagated; and （Ⅱ） the organelles were aggregated In the thallus and then moved to the outside. An Interesting result Is that one organelle aggregation located outside the thallus germinated and developed Into a mature alga, although most organelle aggregations gradually lost vitality and died. The results of the present study reveal that the aggregation of organelles can regenerate a stronger organism than Individuals from the wild owing to the complete exchange of genetic material and may possibly enable organelles to survive in unfavorable surroundings.     

REGENERATION OF PROTOPLASTS FROM DISINTEGRATED CELLS OF BRYOPSIS PLUMOSA (DERBESIALES, CHLOROPHYTA)

When injured, the protoplasms come out from the multi-nucleate giant cell of a green alga Bryopsis plumosa and can generate numerous new cells spontaneously. The cell organelles aggregated rapidly in sea water and became covered with a gelatinous envelope within fifteen minutes. A lipid cell membrane was formed inside the envelope within nine to twelve hours. Cytochemical studies using Nile Red and various enzymes revealed that the primary envelope is initially composed of polysaccharides then becoming a polysaccharide-lipid complex. Fluorescein diacetate (FDA) staining showed that the primary envelope has some characteristics of cell membranes including semipermeability and selective transport of materials. The aggregation of cell organelles appears to be mediated by two kinds of material; one in vacuolar sap and the other on the surface of cell organelles. About a thousand new cells were generated from a single disintegrated branch and forty percent of them eventually developed into mature plants.     

植物叶片原生质体分离的可能机制

分析了植物叶片在分离液环境中形成原生质体的过程,文中提出,分离液配方中的酸性物质使植物叶片处于酸性环境中并导致植物正常细胞首先发生细胞壁酸性降解,随后出现原生质体脱离细胞壁进入分离液,继而又进一步发生质膜的酸性降解,使细胞核和细胞器进入分离液中,最终分离液中的细胞器以细胞核为中心进行细胞器重组,最后产生外貌形态一致的新的原生质体。植物细胞壁和质膜是植物细胞的包被系统。植物细胞包被系统的酸性降解使植物细胞器重组并产生新的原生质体成为可能。     

Cell Wall Regenration During Early Development of Mesophyll Protoplasts of Astragalus melilotoides var. tenuis

The techniques of transmission electron microscopy (TEM), electron microscopy (EM) cytochemical visualization of polysaccharide, cell wall flourescence labelling of cell wall and inhibition of wall formation by coumarin treatment were used to explore the cell wall regeneration and its chemical characteristics in mesophyll protoplasts of Astragalus melilotoides var. tenuis. The results showed that after 24 h in culture a number of protruding vesicles, as well as a small amount of fibrillar component were formed on the surface of protoplasts. On day 3, the amount of fibrils increased significantly. On day 5, regenerated primary wall composed of fibrils and granules were observed, in which polysacchaides were detected as result of the periodic acid-silver methenamine reaction. In addition, after 36 h in culture, the protoplasts tended to coalesce, flourescence staining and coumarin treatment demonstrated that the protoplast adhesion was the result of cell wall formation. Based on these data, problems such as the structure of regenerated wall and its chemical nature, etc. were discussed.     

细叶黄芪叶肉原生质体发育早期细胞壁再生的研究

采用透射电镜术、电镜多糖细胞化学染色、细胞壁荧光染色以及香豆素抑制细胞壁再生等方法,对细叶黄芪（Ａｓｔｒａｇａｌｕｓｍ ｅｌｉｌｏｔｏｉｄｅｓ ｖａｒ．ｔｅｎｕｉｓ）叶肉原生质体细胞壁的再生及其化学特点进行了研究。结果表明,离体培养２４ 小时的原生质体表面产生一些突起小泡,有时可见少量纤维组分的形成。培养３ 天时这种纤维组分明显增多。至５ 天时可清楚看到再生壁是由纤维和颗粒构成。六亚甲四胺银染色证明它们都是由多糖组分组成的。另外,培养３６ 小时的原生质体有相互粘连的现象。电镜观察、荧光染色及香豆素处理的研究表明粘连与再生壁的形成有关。根据上述观察结果,对原生质体再生壁的结构及其化学性质等问题进行了讨论     

FROM PROTOPLASM TO SWARMER: REGENERATION OF PROTOPLASTS FROM DISINTEGRATED CELLS OF THE MULTICELLULAR MARINE GREEN ALGA MICRODICTYON UMBILICATUM (CHLOROPHYTA)1

Protoplast regeneration from extruded cytoplasm of the multicellular marine green alga Microdictyon umbilicatum (Velley) Zanardini (Cladophorales, Anadyomenaceae) was investigated. The early process of protoplast formation is comprised of two steps: agglutination of cell organelles into protoplasmic masses followed by generation of a temporary enclosing envelope around them. Agglutination of cell organelles was mediated by a lectin–carbohydrate complementary system. Three sugars, D‐galactosamine, D‐glucosamine, and α‐D‐mannose, inhibited the agglutination process, and three complementary lectins for the above sugars, peanut agglutinin, Ricinus communis agglutinin, and concanavalin A, bound to the surfaces of chloroplasts. Agglutination assay using human erythrocytes showed the presence of lectins specific for the above sugars in the algal vacuolar sap. A fluorescent probe 1‐(4‐trimethylammoniumphenyl)‐6‐phenyl‐a, 3,5‐hexatriene revealed that the envelope initially surrounding protoplasts was not a lipid‐based cell membrane. However, this developed several hours later. Simultaneous fluorescein diacetate and propidium iodide staining showed that the primary envelope had some characteristics of cell membranes, such as semipermeability and selective transport of materials. Also, fluorescein diacetate staining showed esterase activity in the protoplast and relocation of cell organelles and compartmentalization of cytoplasm during the process of regeneration. Both pH 7–9 and salinity 400–500 mM were found to be essentially important for the development of the protoplast envelope. When the basic regeneration process was accomplished, two alternative pathways of development were seen; about 70% of one‐celled protoplasts transformed into reproductive cells within 2 weeks after wounding, whereas others began cell division and grew into typical Microdictyon thalli. Quadriflagellate swarmers were liberated from the reproductive cells, and they germinated into mature individuals. It is therefore suggested that this species may use the wound response as a method of propagation and dispersal.     

Ultrastructural and chemical changes in the cell wall of Haematococcus pluvialis (Volvocales,Chlorophyta) during aplanospore formation

Changes in the ultrastructure and chemistry of the cell wall of the unicellular volvocalean green alga Haematococcus pluvialis were investigated during the transformation of flagellates into aplanospores. The motile biflagellated state exhibited a distinct gelatinous extracellular matrix. Its ultrastructure resembled the typical volvocalean multilayered architecture with a median tripartite crystalline layer. The transformation into the non-motile cell state was characterized by formation of a new layer, a primary wall, within the extracellular matrix. During this process, the initial extracellular matrix remained intact except for the outer layers of the tripartite crystalline layer, which decomposed. Further morphogenesis of the aplanospore resulted in the formation of a voluminous multilayered cell wall. A trilaminar sheath was formed inside the primary wall and the innermost and thickest part was an amorphous secondary wall, consisting mostly of a mannan. Results obtained by staining with the fluorescent dye primuline as well as by acetolysis suggest the occurrence of sporopollenin-like material (algaenan) within the trilaminar sheath of the aplanospore cell wall. The primary wall and the outer remnants of the extracellular matrix disintegrated as the aplanospores aged, and were completely absent in the resting cell state.     

Preparatory studies for the use of plant protoplasts in space research

An experiment using plant protoplasts has been accepted for the IML-1 mission to be flown on a space shuttle in 1991. Preparatory experiments include studies of cell wall formation, cell division, the effect of simulated weightlessness using fast and slow rotating clinostats, and the development and testing of hardware for the IML-1 mission. After 24 h at 25°C, protoplasts isolated from hypocotyls or leaves of rapeseed seedlings, or from carrot suspension cells, show 60, 20 and 15% cell wall formation, respectively. The time course of formation of the cell wall and cell division could be delayed by treatment at low temperatures or immobilization in alginate or agarose. This aspect is of importance in connection with problems of late access to the space shuttle before launch. At 4°C only 18% of the rapeseed hypocotyl protoplasts had formed cell walls after 24 h. Protoplasts immobilised in agarose or alginate gradually regain their cell division capacity and after 72 h the frequencies are 51 and 26%, respectively, compared to non-immobilised control protoplasts. A significant decrease in cell division activity is observed after rotation for 6 h on the slow clinostat. A similar effect is not observed on the fast clinostat. Protoplasts, cultured in the specially designed plant chamber for up to 14 days established cell aggregates which have further developed into plants.     

An Ultrastructural Study on Triggering of Cell Division in Young Pollen Protoplast Culture of Hemerocallis fulva L.

The ultrastructural changes of young pollen protoplasts under culture condition in Hemerocallis fulva were studied. In comparison with the original pollen grains, the pollen protoplasts had been completely deprived of pollen wall, but kept the internal structure intact, including a large vacuole, a thin layer of cytoplasm and a peripherally located nucleus. After 8 days of culture a few pollen protoplasts were triggered to cell division: some of them were just undergoing mitosis with clearly visible chromosomes and spindle fibers; the others already divided into 2-celled units. The two daughter cells were equal or unequal in size but with similar distribution of organelles inside. Besides cell division, there were also free nuclear division, amitosis and formation of micronuclei indicating a diversity of division modes in pollen protoplast culture, A series of changes occurred during the process of induction of cell division, such as locomotion of the nucleus toward the central position, disappearence of the large vacuole, increase of electron density of cytoplasm, increase and activation of organelles, diminishing of starch granules in plastids, etc. However, the regeneration of surface wall was not sufficient it contained mostly vesicles with only a few microfibrits. The wall separating the two daughter cells were either complete or incomplete. The weak capability of wall formation is supposed to be one of the major obstacles which has so far restricted sustained cell divisions of young pollen protoplasts under current culture condition.     

一种有效的双孢蘑菇原生质体制备及瞬时转化体系

原生质体的制备与再生是双孢蘑菇进行遗传转化的基础,通过研究得到制备双孢蘑菇原生质体的最佳条件是：取培养15d的菌丝振荡培养7d,溶壁酶浓度为1mg/mL的0.6mol/L KCl酶解液、温度30℃、45r/min条件下摇培10h,经过富集精制后的原生质体（4×10 ⁶/mL）可进行瞬时转化。利用Ab-eGFP进行转化,在20min、24h、48h后可观察到GFP荧光,并且在24h和48h可恢复细胞壁增殖,瞬时转化后亦可复壁增殖。研究结果为双孢蘑菇原生质体的稳定遗传转化及后续利用原生质体建立CRISPR-Cas9基因组编辑系统等提供一定的理论依据。     

Mannuronan C-5 epimerase activity in protoplasts of Laminaria digitata

Biosynthesis of alginate in algae may be studied by following the cell wall regeneration of brown seaweed protoplasts in culture. The enzyme mannuronan C-5 epimerase will control the composition of the alginate being synthetized.Freshly isolated protoplasts from the thallus of young Laminaria digitata plants showed only low expression of this enzyme. However, after prolonged periods in culture, this activity increased 15-fold. The synthesis of C-5 epimerase by the protoplasts is probably essential for the formation of a new cell wall.After cellular disruption by osmotic shock and centrifugation, most of the epimerase activity resided in the pellet fraction. This may indicate that the enzyme is membrane associated.     

Ultrastructural and biochemical aspects of cell wall reconstitution in recalcitrant (grapevine) and regenerating (tobacco) leaf protoplasts

Summary To identify possible reasons that may contribute to recalcitrance in plant protoplasts, the time course of new cell wall deposition was studied by scanning electron microscopy in protoplasts of a recalcitrant species, the grapevine. Results showed that microfibrils were developed after 2 days of culture, that complete cell wall formation occurred on Day 6 to 7 of protoplast culture, and its ultrastructural appearance was identical to that of grapevine leaf-derived callus cells. In addition, a comparative study was undertaken on [U-¹⁴C]glucose uptake and incorporation in ethanol-soluble, cellulosic, and noncellulosic polysaccharide fractions in protoplasts of grapevine and of a readily regenerating species, tobacco, during culture. There was a significantly higher [U-¹⁴C]glucose uptake by tobacco than by grapevine protoplasts. The label distribution in the ethanol-soluble, cellulosic, and noncellulosic fractions of newly synthesized cell walls differed quantitatively between the two species. In particular, the labeled glucose incorporated in the noncellulosic cell wall fraction was threefold greater in tobacco than in grapevine protoplasts. Differences were also revealed in the monosaccharide composition of this fraction between the two species. Addition of dimethyl sulfoxide to the culture medium resulted in a dramatic increase in [U-¹⁴C]glucose uptake by grapevine protoplasts, whereas it exhibited a limited effect in tobacco protoplasts. It showed no effect on the ultrastructural characteristics of new cell wall nor on the incorporation rate of labeled glucose in the cellulosic and noncellulosic cell wall fractions.     

萱草幼嫩花粉原生质体培养启动细胞分裂的超微结构研究

萱草(Hemerocallis fulva L.)幼嫩花粉,即后期小孢子原生质体在培养8天时进入有丝分裂或已形成二个细胞。此外,还观察到游离核分裂、无丝分裂、微核形成等现象。这显示了花粉原生质体分裂方式的多样性。在启动分裂时发生一系列变化:如细胞核移位、大液泡消失、细胞质电子密度增加、细胞器增多、质体不含淀粉等。再生的细胞壁含许多小泡,很少纤丝,表现出现有培养条件下壁的形成能力薄弱。这是今后改进培养技术需要特别注意的问题。     

ISOLATION AND CHARACTERIZATION OF A CELL WALL‐DEFECTIVE MUTANT OF CHLAMYDOMONAS MONOICA (CHLOROPHYTA)1

Cell wall–defective strains of Chlamydomonas have played an important role in the development of transformation protocols for introducing exogenous DNA (foreign genes or cloned Chlamydomonas genes) into C. reinhardtii. To promote the development of similar protocols for transformation of the distantly related homothallic species, C. monoica, we used UV mutagenesis to obtain a mutant strain with a defective cell wall. The mutant, cw‐1, was first identified on the basis of irregular colony shape and was subsequently shown to have reduced plating efficiency and increased sensitivity to lysis by a non‐ionic detergent as compared with wild‐type cells. Tetrad analysis of crosses involving the cw‐1 mutant confirmed 2:2 segregation of the cw:cw⁺ phenotypes, indicating that the wall defect resulted from mutation of a single nuclear gene. The phenotype showed incomplete penetrance and variable expressivity. Although some cells had apparently normal cell walls as viewed by TEM, many cells of the cw‐1 strain had broken cell walls and others were protoplasts completely devoid of a cell wall. Several cw‐1 isolates obtained from crosses involving the original mutant strain showed a marked enhancement of the mutant phenotype and may prove especially useful for future work involving somatic cell fusions or development of transformation protocols.     

The effect of 8 days of microgravity on regeneration of intact plants from protoplasts

The growth and development of protoplasts of rapeseed (Brassica napus L. cv Line) and carrot (Daucus carota L. cv. Navona) were studied onboard the Space Shuttle‘Discovery’during an 8-day International Microgravity Laboratory [IML-l) mission in January 1992. The Flight experiments were carried out in‘Biorack'. a fully controlled cell biological experimental facility. under microgravity conditions and in a l-g centrifuge. Parallel experiments were performed in a‘Biorack’module on the ground. After retrieval, some samples were subcultured on appropriate media and analysed for callus growth and regeneration to intact plants. The remainder were used for biochemical analysis. Samples fixed on board the Space Shuttle were kept in l% glutaraldehyde fixative at 4°C for 3–7 days for microscopy analysis after retrieval. Protoplasts exposed to microgravity conditions showed a delay in cell wall synthesis. Cells were swollen in appearance and formed cell aggregates with only few cells. Callus were obtained from protoplasts cultured under microgravity (Fogl). on the l-g centrifuge on board the shuttle (Flg), under normal l-g conditions on the ground (G1g) and on a centrifuge on the ground giving 1.4 g (Gl.4g). Regeneration of intact rapeseed plants was obtained from Flg. Glg and G1.4g. However, no plants were regenerated from protoplasts exposed to microgravity (Fog). Biochemical analysis indicated that the microgravity samples (Fog displayed a reduced packed cell volume, an increased concentration of soluble proteins per cell, and a reduced specific activity of peroxidase in the cytoplasm. Morphometric analysis of fixed samples demonstrated that 3-day old protoplasts under microgravity conditions were significantly larger than protoplasts kept on the l-g centrifuge in space. UItrastructural analysis by transmission electron microscopy showed that protoplasts exposed to microgravity conditions for 3 days had larger vacuoles and a slightly reduced starch content compared to Flg cells. Cell aggregates formed under microgravity conditions (Fog) had an average of 2–I cells per aggregate while aggregates formed under Flg had 8–12 cells.     

Phenotypic characterization, genetic analysis and gene-mapping for a brittle mutant in rice

Plant mechanical strength is an important agronomic trait of rice. An ethyl methane sulfonate （EMS）-induced rice mutant, fragile plant 2 （fp2）, showed morphological changes and reduced mechanical strength. Genetic analysis indicated that the brittle of fp2 was controlled by a recessive gene. The fp2 gene was mapped on chromosome 10. Anatomical analyses showed that the fp2 mutation caused the reduction of cell length and cell wall thickness, increasing of cell width, and the alteration of cell wall structure as well as the vessel elements. The consequence was a global alteration in plant morphology. Chemical analyses indicated that the contents of cellulose and lignin decreased, and hemicelluloses and silicon increased in fp2. These results were different from the other mutants reported in rice. Thus, fp2 might affect the deposition and patterning of microflbrils, the biosynthesis and deposition of cell wall components, which influences the formation of primary and secondary cell walls, the thickness of cell walls, cell elongation and expansion, plant morphology and plant strength in rice.     

PURIFICATION AND CHARACTERIZATION OF A LECTIN,BRYOHEALIN, INVOLVED IN THE PROTOPLAST FORMATION OF A MARINE GREEN ALGA BRYOPSIS PLUMOSA (CHLOROPHYTA) 1

When the coenocytic green alga Bryopsis plumosa (Huds.) Ag. was cut open and the cell contents were expelled, the cell organelles agglutinated rapidly in seawater to form protoplasts. Aggregation of cell organelles in seawater was mediated by a lectin–carbohydrate complementary system. Two sugars, N‐acetyl‐d ‐glucosamine and N‐acetyl‐d ‐galactosamine inhibited aggregation of cell organelles. The presence of these sugars on the surface of chloroplasts was verified with their complementary fluorescein isothiacyanate‐labeled lectins. An agglutination assay using human erythrocytes showed the presence of lectins specific for N‐acetyl‐d ‐galactosamine and N‐acetyl‐d ‐glucosamine in the crude extract. One‐step column purification using N‐acetyl‐d ‐glucosamine‐agarose affinity chromatography yielded a homogeneous protein. The protein agglutinated the cell organelles of B. plumosa, and its agglutinating activity was inhibited by the above sugars. Sodium dodecyl sulfate polyacrylamide gel electrophoresis results showed that this protein might be composed of two identical subunits cross‐linked by two disulfide bridges. Enzyme and chemical deglycosylation experiments showed that this protein is deficient in glycosylation. The molecular weight was determined as 53.8 kDa by matrix‐assisted laser desorption/ionization time‐of‐flight mass spectrometry. The N‐terminal 15 amino acid sequence of the lectin was Ser–Asp–Leu–Pro–Thr–X–Asp–Phe–Phe–His–Ile–Pro–Glu–Arg–Tyr, and showed no sequence homology to those of other reported proteins. These results suggest that this lectin belongs to a new class of lectins. We named this novel lectin from B. plumosa“bryohealin.”     

Variations of the Surface Sculpture and Cell Wall Ultrastructure of the Zygospores in Chlamydomonas geitleri (Chlorophyta)

The superficial cell wall ornamentation in the zygospores of the alga Chlamydomonas geitleri Ettl (Chlorophyta) is formed by thickenings of the cell wall which are shaped into a network of anastomosing ribs, sometimes with local wart-like protuberances. Clearly different sculpture patterns (given by presence, arrangement and/or morphological modification of sculpture elements) were accompanied by many transient forms. Sculpture variations occurred even in clonal cultures. In the zygospore cell wall of C. geitleri, the inner, outer and middle layer can be distinguished from the morphological point of view. The relatively thin outer (sporopollenin) layer covers the whole surface of the zygospore wall. The thicker inner layer adhering to the zygospore protoplast forms, either solely or together with the middle layer (possessing a fine meshwork substructure), variously shaped thickening of the zygospore cell wall. Discussed are the ultrastructural morphology of the cell wall in Chlamydomonas zygospores, the striking similarity of the cell wall ultrastructure of zygospores in C. geitleri to the ultrastructure of the cell wall of vegetative cells in some green algae (subfamily Scotiellocystoideae), as well as the extensive morphological variability of the zygospore wall sculpture in C geitleri and its species specificity.     

The role of microtubules and cell-wall deposition in elongation of regenerating protoplasts of Mougeotia

Protoplasts of the filamentous green alga Mougeotia sp. are spherical when isolated and revert to their normal cylindrical cell shape during regeneration of a cell wall. Sections of protoplasts show that cortical microtubules are present at all times but examination of osmotically ruptured protoplasts by negative staining shows that the microtubules are initially free and become progressively cross-bridged to the plasma membrane during the first 3 h of protoplast culture. Cell-wall microfibrils areoobserved within 60 min when protoplasts are returned to growth medium; deposition of microfibrils that is predominantly transverse to the future axis of elongation is detectable after about 6 h of culture. When regenerating protoplasts are treated with either colchicine or isopropyl-N-phenyl carbamate, drugs which interfere with microtubule polymerization, they remain spherical and develop cell walls in which the microfibrils are randomly oriented.