根瘤形成过程中豆科植物根毛和根外层传递细胞的诱发

对7种豆科植物接种根瘤菌后根部的形态和内部结构进行了研究.结果表明:根瘤菌可诱发根瘤形成部位根段的根毛增生、形变和根外层传递细胞的发育.根外层传递细胞发生在根毛伸长形变时期,一直可持续到根瘤形成,传递细胞壁内突发育过程是先由根表皮细胞外切向壁一侧细胞质膜向细胞质内陷形成囊状壁傍体,次生细胞壁物质在初生壁上沉积并逐渐充满囊状体,最终形成传递细胞典型的壁内突结构.根瘤形成过程中根外层传递细胞的诱发与培养方式(水培、固培)没有直接关系.在不接菌的对照苗的根段内未发现壁内突结构,研究证明豆科植物根外层传递细胞的形成是由根瘤菌诱导所致.     

Formation of Phenolic Compounds in Apogeotropic Roots of Cycad Plants

Formation and location of phenolic compounds in apogeotropic roots (coralloid roots) were studied in six cycad species, which belong to the genera Cycas, Encephalartos, and Ceratozamia. Total contents of soluble phenolic compounds in coralloid roots in all species studied varied insignificantly, with except for Ceratozamia mexicana that accumulated three times higher amounts of phenolic compounds. Phenolic compounds were accumulated in cell walls of cortical parenchyma of coralloid roots, in intercellular spaces, and in specialized storage cells, found in all zones of apogeotropic roots. The greatest number of phenol-storing cells was situated in the cortical parenchyma of the central part of coralloid roots, adjacent to a zone where active symbiotic cyanobacteria were localized, and in the coralloid root basal region lacking viable forms of cyanobionts. It was suggested that phenolic compounds affect the formation of symbiosis between cyanobacteria and apogeotropic roots of cycad plants, as well as their metabolism.     

Mass Transfer Characteristics of Immobilized Cells Used in Fermentation Processes

ABSTRACT:?

There is great commercial interest in using immobilized cells for fermented beverage processes. The process advantages offered by immobilized cells are numerous, but an understanding of the mass transfer characteristics of a given system is needed in order to achieve efficient processes and high quality products. This is especially important in the food and beverage industry where fermentation products contribute to the flavor and aroma of the final product. The fundamental principles of mass transfer in immobilized cell systems are covered in this review. An overview of the current research efforts focused on external and internal mass transfer characteristics of immobilized cells used in fermentation processes is presented. Methods for measuring substrate diffusivities within immobilization matrices and areas requiring further research are discussed.     

Bioaccumulation and effect of cadmium in the photosynthetic apparatus of Prosopis juliflora

In the present study Prosopis juliflora plants grown in hydroponics solution were exposed to 50,100 and 1000 μM CdCl₂. The cadmium uptake, transport and toxicity on the photosynthetic activities in the plants were measured at 48 h after starting cadmium treatments. The results showed that the concentration of Cd²⁺ in P. juliflora tended to increase with addition of Cd²⁺ to hydroponics solution. However, the increase of Cd²⁺ in roots and leaves varied largely. In this sense, the accumulation of Cd²⁺ in P. juliflora roots increased significantly in proportion with the addition of this metal. In contrast a relatively low level of Cd²⁺ transportation index, and bioaccumulation factor were found in P. juliflora at 48 h after of treatments. On the other hand the maximum photochemical efficiency of photosystem II (Fv/Fm) and the activity of photosystem II (Fv/Fo) ratios in P. juliflora leaf treated with Cd²⁺ not showed significantly changes during the experiment. These results suggested that the photosynthetic apparatus of P. juliflora was not the primary target of the Cd²⁺ action. Further studies will be focused in understanding the participation of the root system in Prosopis plants with the rhizosphere activation and root adsorption to soil Cd²⁺ under natural conditions.     

玉米胚乳传递细胞的结构观察研究

以玉米品种'登海11号'为材料,分别于授粉后8、10、15和20 d采集颖果,取所需部位并采用树脂包埋的方法及半薄和超薄切片技术,对玉米胚乳传递细胞进行了显微和超微结构观察.结果显示:(1)胚乳传递细胞的壁内突从外层向内层依次递减,溶质浓度逐步降低,形成了明显的溶质浓度梯度,有利于溶质的运输;(2)中层胚乳传递细胞和内层胚乳传递细胞的邻壁上存在胞间连丝或一些孔径较大的胞壁孔道,从而使溶质更快的进入内层胚乳传递细胞;(3)在壁内突周围存在许多线粒体.研究表明,玉米胚乳传递细胞的结构适合溶质运输.     

Microbial Complexes Occurring on the Apogeotropic Roots and in the Rhizosphere of Cycad Plants

The microbial complexes of soil, the rhizosphere, and the rhizoplane of the apogeotropic (coralloid) roots of cycad plants were comparatively studied. The aseptically prepared homogenates of the surface-sterilized coralloid roots did not contain bacterial microsymbiont, indicating that in the root tissues the symbiosis is a two-component one (plant–cyanobacteria). At the same time, associated bacteria belonging to different taxonomic groups were detected in increasing amounts in the cycad rhizoplane, rhizosphere, and the surrounding soil. The bacterial communities found in the cycad rhizoplane and the surrounding soil were dominated by bacteria from the genus Bacillus. The saprotrophic bacteria and fungi colonizing the cycad rhizosphere and rhizoplane were dominated by microorganisms capable of degrading the plant cell walls. The local degradation of the cell wall was actually observed on the micrographs of the thin sections of cycad roots in the form of channels through which symbiotic cyanobacterial filaments can penetrate into the cortical parenchyma.     

The Effect of Salt and Water Stress on Membrane Lipid Peroxidation in leaf Cells of Halophyte and Non-halophyte

Different concentrations of NaC1 and isoosmotic polyethylene glycol(PEG)were used to treat the seedlings of halophyte Suaede salsa and non-halophyte Prosopis chilensis. Membrane lipid peroxidation malondialdehyde(MDA)content,SOD activity and plasmalemma permeability were determined at different time of treatment. The seedlings of Suaeda salsa showed no or a little response to 0--1. 488 MPa NaCl,but marked response to 1. 984 MPa NaC1. However,there was a greater response to isoosmotic PEG in plasmalemma permeability, SOD activity and MDA content. Prosopis chilensis showed an contrary trend to Suaeda salsa. The MDA content decreased unanimously as three kinds of free-radical scavengers were sprayed on the seedlings of the above plants before NaCl or PEG treatment, but increased with pretreatment of SOD inhibitor. Obviously, the decrease of SOD activity and the increase of MDA content were related to plasma injury, and free-radical did participate the course of salt and/or water stress injury. Their effects of both salt and water stress shared common features in response to the integrity of the cell membrane.     

Boundary Layer Effects in Ion Absorption by Roots and Storage Organs of Plants

In plant nutrition studies with culture solutions it is tacitly assumed that replenishment of ions at the root surface is guaranteed by the turbulence of the stirred solution. That this belief may be erroneous is demonstrated in this study with barley roots and discs of beet roots and potato tubers. At very low concentrations of RbCl (in presence of CaCl₂) the uptake of Rb by roots is strongly controlled by the rate of stirring. The results are interpreted in the light of the Nernst hydrodynamic boundary film which surrounds solids and through which ions must diffuse to reach the root surface. “Film-controlled” and “root-controlled” ion uptake is visualized.     

Distribution and Function of Proteoid Roots and other Root Clusters

Proteoid roots are bottlebrush-like clusters of rootlets which form along lateral roots. They are characteristic of most species of the Proteaceae, which are mainly distributed in Australia and South Africa. Homologous root clusters are present in species of the Casuarinaceae, Mimosaceae, Fabaceae, Myricaceae and Moraceae. Many similarities exist between these species in relation to morphology and function of root clusters. Many are non-mycorrhizal and are highly efficient in phosphorus (P) acquisition. In these species, proteoid roots and proteoid-like root clusters are abundant when grown on infertile soils. Their formation is predominantly affected by the P status of the plants, being induced at low P levels and repressed at high P levels. Proteoid roots and proteoid-like root clusters play an important role in acquisition of P and other mineral nutrients. Although increase in root surface area may be a contributing factor, in many species these roots excrete large amounts of organic acids and phenolics. The excretion of these compounds in a small soil volume gives rise to extensive nutrient mobilization by acidification, reduction and chelation of sparingly soluble forms of P and micronutrients such as Fe and Mn.     

供核细胞对体细胞核移植效率的影响

利用体细胞核移植技术克隆动物、生产转基因家畜具有极大的应用潜力。然而,核移植效率低下、克隆后代形态异常等问题仍然制约着体细胞核移植技术的产业化进展。影响体细胞核移植效率的因素很多,该文着重从供核细胞的类型、细胞体外培养、细胞凋亡及转基因操作等方面阐述其对体细胞核移植效率的影响。     

Effects of salinity on the establishment and early growth of Prosopis argentina and Prosopis alpataco seedlings in two contrasting soils: Implications for their ecological success

Abstract In arid zones, water availability is the most important factor limiting seedling establishment and plant distribution. However, within a region with a defined water regime, the physical and chemical properties of the soil could be the cause of the spatial pattern of plant communities. Prosopis argentina Burk. and Prosopis alpataco Phil. are sympatric at a regional scale but at the local scale they occupy clearly differentiated edaphic niches. Prosopis argentina reaches its ecological optimum in the sandy soils of active dunes, whereas P. alpataco achieves it in heavy, clayish, saline and periodically flooded soils. We studied the effect of salinity, and its interaction with soil type, on the establishment and early growth of these species in order to evaluate their adaptive mechanisms, and to analyse how this was related to the ecological success of these species. Salinity affected emergence and early growth of P. argentina and P. alpataco seedlings differently. Higher salinity led to decreased height, total biomass and shoot and root biomass of plants in both species but the effect was stronger in P. argentina than in P. alpataco, and greater in clayish than in sandy soils. These results would indicate that exclusion of P. argentina from clayish and saline soils would occur during emergence and the first stages of seedling establishment as a consequence of salinity. In P. alpataco other edaphic limitations, like texture or fertility in sandy soils, appear to be always more important. The osmotic effect evidenced by decreasing water and osmotic potentials of plants under saline conditions may be associated with growth reduction in both P. argentina and P. alpataco. However, this factor cannot explain differences in growth between species under salinity. The higher contents of Ca⁺⁺ and K⁺, and the lower contents of Na⁺ in P. alpataco suggest that the greater tolerance of this species depends on its ability to regulate and control absorption and transport of ions.     

Combining Energy Transfer and Optimized Morphology for Highly Efficient Ternary Polymer Solar Cells

Aimed at achieving ideal morphology, illuminating morphology–performance relationship, and further improving the power conversion efficiency (PCE) of ternary polymer solar cells (TSCs), a ternary system is designed based on PTB7‐Th:PffBT4T‐2OD:PC₇₁BM in this work. The PffBT4T‐2OD owns large absorption cross section, proper energy levels, and good crystallinity, which enhances exciton generation, charge dissociation and transport and suppresses charge recombination, thus remarkably increasing the short‐circuit current density (J _sc) and fill factor (FF). Finally, a notable PCE of 10.72% is obtained for the TSCs with 15% weight ratio of PffBT4T‐2OD. As for the working mechanism, it confirmed the energy transfer from PffBT4T‐2OD to PTB7‐Th, which contributes to the improved exciton generation. And morphology characterization indicates that the devices with 15% PffBT4T‐2OD possess both appropriate domain size (25 nm) and enhanced domain purity. Under this condition, it affords numerous D/A interface for exciton dissociation and good bicontinuous nanostructure for charge transport simultaneously. As a result, the device with 15% PffBT4T‐2OD exhibits improved exciton generation, enhanced charge dissociation possibility, elevated hole mobility and inhibited charge recombination, leading to elevated J _sc (19.02 mA cm^?2) and FF (72.62%) simultaneously. This work indicates that morphology optimization as well as energy transfer plays a significant role in improving TSC performance.     

牛体细胞克隆胚胎类ES细胞集落的筛选及其核移植

对第7d的牛体细胞克隆囊胚进行体外增殖培养,分离筛选类ES细胞,并对其进行了传代培养,接种在饲养层上的体细胞克隆囊胚细胞,在传代的24h内增殖形成小集落,2～3d有雀巢状的集落出现,筛选形态相同的细胞集落进行传代培养,4～5代后,皿底出现多个大小不等的多细胞单层集落,将传4～5代的细胞集落接种到无饲养层的4孔培养皿中培养,24h出现多细胞单层集落,4～7d长满皿底,并形成上皮样细胞,呈网状,将其作为核供体细胞进行核移植实验。结果有80%（40/50）核-质融合的移核重构胚发生卵裂,5%（2/40）发育至桑椹胚期,2.5%（1/40）发育至囊胚期,92.5%（37/40）停止在2～4细胞期,结果表明：采用牛体细胞克隆胚胎的类ES细胞进行核移植,具发育形成早期胚胎的潜能。     

Effect of Salt Stress on Ion Channel Selective Permeability of Plasmalemma in Sorghum Roots

100 mmol/L, 200 mmol/L and 300 mmol/L NaC1 was used in proper order to treat three-day old seedlings of Sorghum vulgare Pets. The plasma membrane of roots was isolated and purified by aqueous biphasic partition device. The plasmalemma was incorporated into planar bilayer lipid membrane and ion channels were measured by electrical methods. Ion selective permeabilities (PK: PNa) were assayed in asymmetrical solutions containing 100 mmol/L NaC1 in Cis chamber and 100 mmol/L KC1 in Tran with chamber and were calculated from Goldman-Hodgkin-Kaltz equation. PK: PNa was 3.5 in plasmalemma of control roots and 1.5 in plasmalemma of salt stressed roots. It showed that the changes of ion selective permeability was very significant under salt stress. The importance of the change of ion selective permeability is discussed.     

Tunable Nanoporous Network Polymer Nanocomposites having Size‐Selective Ion Transfer for Dye‐Sensitized Solar Cells

Nanoporous network polymer nanocomposites with tunable pore size for size‐dependent selective ion transport are successfully prepared via the surface‐induced cross‐linking polymerization of methyl methacrylate (MMA) and 1,6‐hexanediol diacrylate (HDDA) on the surfaces of nanocrystalline TiO₂ particles. The morphologies of the porous network polymer layer and nanopores were investigated by transmission electron microscopy (TEM), field emission scanning electron microscopy (FE‐SEM), and Brunauer–Emmett–Teller (BET) experiments. The porous layer size‐selectively screened the ions that contacted the nanocrystalline TiO₂ particles, as demonstrated by ion conductivity measurements, electrochemical impedance spectroscopy (EIS), and transient absorption spectroscopy (TAS).     

Adoptive Transfer of Immunity to Plasmodium berghei by Spleen and Lymph Node Cells from Young and Old Mice*

SYNOPSIS. Different numbers of spleen and lymph node cells of 6-week and 6–8 month A/J mice, immune to Plasmodium berghei, were transferred into normal 4-week old mice. Better protection was observed with 2.5 × 10^s than with 10⁷ spleen cells, and spleen cells afforded better protection than an equal number of lymph node cells. Further, spleen cells from older mice were more effective than those from young animals. Possible mechanisms of immunity transfer are discussed.     

Climatic signals in growth and its relation to ENSO events of two Prosopis species following a latitudinal gradient in South America

Semiarid environments throughout the world have lost a major part of their woody vegetation and biodiversity due to the effects of wood cutting, cattle grazing and subsistence agriculture. The resulting state is typically used for cattle production, but the productivity of these systems is often very low, and erosion of the unprotected soil is a common problem. Such dry‐land degradation is of great international concern, not only because the resulting state is hardly productive but also because it paves the way to desertification. The natural distribution of the genus Prosopis includes arid and semiarid zones of the Americas, Africa and Asia, but the majority of the Prosopis species are, however, native to the Americas. In order to assess a likely gradient in the response of tree species to precipitation, temperature and their connection to El Niño southern oscillation (ENSO) events, two Prosopis species were chosen along a latitudinal gradient in Latin America, from northern Peru to central Chile: Prosopis pallida from a semi‐arid land in northern and southern Peru and P. chilensis from a semiarid land in central Chile. Growth rings of each species were crossdated at each sampling site using classical dendrochronological techniques. Chronologies were related with instrumental climatic records in each site, as well as with SOI and N34 series. Cross‐correlation, spectral and wavelet analysis techniques were used to assess the relation of growth with precipitation and temperature. Despite the long distance among sites, the two Prosopis species presented similar responses. Thus, the two species' growth is positively correlated to precipitation, while with temperature it is not. In northern Peru, precipitation and growth of P. pallida present a similar cyclic pattern, with a period of around 3 years. On the other hand, P. pallida in southern Peru, and P. chilensis also present this cyclic pattern, but also another one with lower frequency, coinciding with the pattern of precipitation. Both cycles are within the range of the ENSO band.     

Rapid Water Inflow and Outflow in Plants with Roots Treated with Salt Solutions of Various Concentrations

A new highly sensitive and rapidly responding gravimetric method was used for the investigation of rapid responses manifesting in water inflow and outflow from roots in the intact seedlings of tomato Lycopersicon esculentumMill. and sunflower Helianthus annuusL. The effects of K⁺, Na⁺, and Ca²⁺chlorides were studied in solutions with concentrations of 0.3–500 mM. Any sudden increase in the osmotic pressure of an external solution brought about a typical gravimetric response in the roots of seedlings that started practically without a lag period and comprised rapid and slow phases of water loss. The total amplitude of the response depended on the osmotic gradient produced by the changes of solutions. Responses were reversible and well reproduced upon the repeated treatment of the same plant if the treatment was noninvasive. The notable characteristics of water inflow and outflow included a very short lag period, a gradual pattern, and a low selectivity to different salts. This was especially true for the initial (rapid) phase of response. However, mono- and bivalent cations showed some specificity of action. Some data suggest the osmotic nature of rapid responses of water uptake and loss by roots. One may assume that a dynamic osmotic equilibrium exists between the root and the outer solution so that any change in the osmotic pressure of the medium would induce an instant and then a more gradual change in the water content. When plotted in logarithmic coordinates, two straight lines with different slopes described the relationship between the gravimetric response and the salt concentration. The point where these lines intersected corresponded to about 50 mM NaCl. Lower and higher salt concentrations seem to induce rapid water inflow and outflow in plant roots by means of different mechanisms.