Changes in cell wall polysaccharides in the internodes of submerged floating rice

In excised stem segments of floating rice (Oryza sativa L.), as well as in intact plants, submergence greatly stimulates the elongation of internodes. The differences in the composition of cell wall polysaccharides along the highest internodes of submerged and air-grown stem segments were examined. The newly elongated parts of internodes that had been submerged for two days contained considerably less cellulosic and noncellulosic polysaccharides than air-grown internodes, an indication that the cell walls of the newly elongated parts of submerged internodes are extremely thin. In the young parts of both air-grown and submerged internodes, the relative amounts of noncellulosic polysaccharides were equal to those of -cellulose, whereas the relative amounts of -cellulose were higher than those of noncellulosic polysaccharides in the upper, old parts. In the cell-elongation zones of both air-grown and submerged internodes, glucose was predominant among the noncellulosic neutral sugars of cell wall. The relative amount of glucose in noncellulosic neutral sugars decreased toward the upper, old parts of internodes, whereas that of xylose increased.     

Changes in expansin activity and cell wall susceptibility to expansin action during cessation of internodal elongation in floating rice

We investigated the involvement of expansin action in determining the growth rate of internodes of floating rice (Oryza sativa L.). Floating rice stem segments in which rapid internodal elongation had been induced by submergence for 2 days were exposed to air or kept in submergence for 2 more days. Both treatments reduced the elongation rate of the internodes, and the degree of reduction was much greater in air-exposed stem segments than in continually submerged segments. These rates of internodal elongation were correlated with acid-induced cell wall extensibility and cell wall susceptibility to expansins in the cell elongation zone of the internodes, but not with extractable expansin activity. These results suggest that the reduced growth rate of internodes must be due, at least in part, to the decrease in acid-induced cell wall extensibility, which can be modulated through changes in the cell wall susceptibility to expansins rather than through expansin activity. Analysis of the cell wall composition of the internodes showed that the cellulosic and noncellulosic polysaccharide contents increased in response to exposure to air, but they remained almost constant under continued submergence although the cell wall susceptibility to expansins gradually declined even under continued submergence. The content of xylose in noncellulosic neutral sugars in the cell walls of internodes was closely and negatively correlated with changes in the susceptibility of the walls to expansins. These results suggest that the deposition of xylose-rich polysaccharides into the cell walls may be related to a decrease in acid-induced cell wall extensibility in floating rice internodes through the modulation of cell wall susceptibility to expansins.     

Studies of the fiber to crystal transition of sickle cell hemoglobin in acidic polyethylene glycol

The crystallization of deoxygenated sickle cell hemoglobin in acidic (pH 5.2) polyethylene glycol (10%) has been studied in order to determine if the mechanism of crystal formation under such conditions has features in common with the mechanism of crystal formation at higher pH values in the absence of polyethylene glycol. The existence of a common mechanism of crystallization under different conditions is relevant in validating the use of the known high resolution crystal structure to interpret the fiber structure. Our findings indicate that deoxygenated sickle cell hemoglobin crystallization in acidic polyethylene glycol is initiated by fiber formation. Fibers, in turn, convert to larger structures called macrofibers within several hours (Wellems et al., 1981). Fibers and macrofibers (and their respective optical transforms) formed in acidic polyethylene glycol appear to have the same structure as their counterparts formed at higher pH values in the absence of polyethylene glycol. Early in the transition one can observe macrofibers in the process of alignment and fusion. The structural characterization of the intermediates leaves little doubt that crystallization in acidic polyethylene glycol is mediated by the same mechanism as that occurring under more physiological conditions, and that fibers are a metastable intermediate whose ultimate fate is to crystallize.     

Macrofiber structure and the dynamics of sickle cell hemoglobin crystallization

Fibers of deoxyhemoglobin S undergo spontaneous crystallization by a mechanism involving a variety of intermediate structures. These intermediate structures, in common with the fiber and crystal, consist of Wishner-Love double strands of hemoglobin S molecules arranged in different configurations. The structure of one of the key intermediates linking the fiber and crystal, called a macrofiber, has been studied by a variety of analytical procedures. The results of the analysis indicate that the intermediates involved in the fiber to crystal transition have many common structural features. Fourier analysis of electron micrographs of macrofibers confirms that they are composed of Wishner-Love double strands of hemoglobin molecules. Electron micrographs of macrofiber cross-sections reveal that the arrangement of the double strands in macrofibers resembles that seen in micrographs of the a axis projection of the crystal. This orientation provides an end-on view of the double strands which appear as paired dumb-bell-like masses. The structural detail becomes progressively less distinct towards the edge of the particle due to twisting of the double strands about the particle axis. Serial sections of macrofibers confirm that these particles do indeed rotate about their axes. The twist of the particle is right handed and its average pitch is 10,000 Å. The effect of rotation on the appearance of macrofiber cross-sections 300 to 400 Å thick can be simulated by a 15 ° rotation of an a axis crystal projection. The relative polarity of the double strands in macrofibers and crystals can be determined easily by direct inspection of the micrographs. In both macrofibers and crystals they are in an anti-parallel array.On the basis of these observations we conclude that crystallization of macrofibers involves untwisting and alignment of the double strands.     

Effect of osmotic stress on the growth of epicotyls of Cicer arietinum in relation to changes in cell wall composition

The inhibition of growth by polyethlene glycol (PEG)-induced osmotic stress led to modifications in the changes taking place in cell wall composition during normal growth of epicotyls of Cicer arietinum L. cv. Castellana. Epicotyls growing under normal conditions showed a decrease in the amount of pectic fractions and an increase in the hemicellulosic fractions and α-cellulose that led to an increase in the rigidity and a loss in growth capacity. Among the hemicellulosic fractions, the KI-2 fraction (insoluble fraction of 10% KOH-extracted hemicelluloses) seemed to be the only one related to the elongation process and subsequent rigidity. During normal growth a decrease was observed in the total amount of galactose, mainly from the pectic fractions. The inhibition of elongation led to an increase in the amount of the cell walls, due to inhibition of cellular elongation. PEG prevented the increase in the hemicelluloses and the α-cellulose, indicating that these changes were related to elongation. Thus, during the inhibition of elongation there is probably an inhibition of new synthesis that prevents cell wall rigidity and maintains cell wall growth capacity. Changes in the pectic fractions during growth were not affected by the inhibition of elongation, showing that these fractions are related to cell wall loosening rather than to elongation. Study of the cell wall composition confirms the idea that the autolytic process is regulated by changes in the cell wall structure during epicotyl growth     

Pressure built by DNA packing inside virions: enough to drive DNA ejection in vitro, largely insufficient for delivery into the bacterial cytoplasm

Tailed bacteriophage particles carry DNA highly pressurized inside the capsid. Challenge with their receptor promotes release of viral DNA. We show that addition of the osmolyte polyethylene glycol (PEG) has two distinct effects in bacteriophage SPP1 DNA ejection. One effect is to inhibit the trigger for DNA ejection. The other effect is to exert an osmotic pressure that controls the extent of DNA released in phages that initiate ejection. We carried out independent measurements of each effect, which is an essential requirement for their quantitative study. The fraction of phages that do not eject increased linearly with the external osmotic pressure. In the remaining phage particles ejection stopped after a defined amount of DNA was reached inside the capsid. Direct measurement of the size of non-ejected DNA by gel electrophoresis at different PEG concentrations in the latter sub-population allowed determination of the external osmotic pressure that balances the force powering DNA exit (47 atm for SPP1 wild-type). DNA exit stops when the ejection force mainly due to repulsion between DNA strands inside the SPP1 capsid equalizes the force resisting DNA insertion into the PEG solution. Considering the turgor pressure in the Bacillus subtilis cytoplasm the energy stored in the tight phage DNA packing is only sufficient to power entry of the first 17% of the SPP1 chromosome into the cell, the remaining 83% requiring application of additional force for internalization.     

Gibberellic acid promotes growth and cell wall synthesis in Avena internodes regardless of the orientation of cell expansion

Segments cut from the next-to-last (peduncular-1) internode of Avena sativa L. cv. Victory (oat) shoots elongate as much as 10-fold in response to gibberellic acid (GA₃). The objective of the present investigation was to differentiate the effects of GA₃ on growth from its effects on wall synthesis (measured gravimetrically and through the incorporation of [¹⁴C]-glucose) by using several cell wall synthesis inhibitors with widely varying mechanisms of action. Four compounds, viz. monensin, cycloheximide, lanthanum, and galactose. caused (1) relatively little inhibition of either cell wall synthesis or elongation in segments without GA₃, (2) roughly proportionate, dose-dependent inhibition of elongation and wall synthesis in GA₃-treated segments and (3) generally greater inhibition of GA₃-promoted uptake of radioactivity than of wall incorporation or elongation. Two other compounds, colchicine and 2,6-dichlorobenzonitrile (DCB). (1) inhibited GA₃-induced elongation considerably more than cell wall synthesis and (2) caused swelling (radial expansion). especially of GA₃-treated segments. DCB-treated internodal cells apparently compensated for inhibited cellulose synthesis by greater synthesis of matrix polysaccharide (beginning between 3 and 6 h). While normal cellulose synthesis was not required for short-term (up to 6 h) GA₃-induced elongation or for long-term hormone-promoted radial expansion, it was required for sustained GA₃-induced elongation. These results indicate that GA₃-promoted cell wall loosening (manifested as radial expansion) and cell wall synthesis in Avena internodes occur at least partially independently of any hormonal effect on the orientation of microtubules and microfibrils.     

The changes in contents and composition of phenolic acids during cell xylem growth in scots pine

The contents and composition of alcohol soluble phenolic acids were studied during cell xylem growth in the course of wood annual increment formation in the stems of Scots pine. The cells of cambium zone, of two stages of expansion growth and the outset of secondary thickening zone (before lignification) were successively gathered from the stem segments of 25-old pine trees in the period of earlywood xylem formation with constant anatomical and histochemical control. The contents of free and bound forms of phenolic acids, isolated by 80% ethanol from tissues, as well as of their ethers and esters were calculated both per dry weight and per cell. The content and relation of the fractions and the composition of phenolic acid have been found to change significantly from cambium zone to the outset of tracheid secondary thickening. The character of the variations depends on a calculation method. According to the calculation per cell the amount of free and bound phenolic acids and in their composition of esters and especially ethers increased at the first step of expansion growth zone, decreased at the second one and rose again in the outset of secondary wall deposition. In dependence on the stage of cell development the pool of bound phenolic acids exceeded of free acid pool in 2-5 times. Sinapic and ferulic acids dominated in the composition of free hydroxycinnamic acids. The content and composition of hydroxycinnamic acids in ethers and esters depended on cell development phase. In cambium p-coumaric and sinapic acids were principal aglycons in ethers, at other stages these were sinapic and caffeic acids. The esters in cambium zone included essentially p-coumaric acid and at the other stages - sinapic and ferulic acids. At the first phase of growth benzoic acid was connected principally by ester bonds. The pool of these esters decreased from the first phase of growth to the outset of cell wall thickening and in proportion to this the level of free benzoic acid rose.     

Spiral growth and cell wall properties of the gibberellin-treated first internodes in the seedlings of a wheat cultivar tolerant to deep-sowing conditions

The Hong Mang Mai wheat cultivar is tolerant to deep-sowing conditions because it has an elongated first internode that is sensitive to gibberellin (GA₃). The cells in the GA-treated first internodes were approximately 4.2 mm long, twice as long as the untreated Hong Mang Mai first internode cells. The elongation of the first internode of Hong Mang Mai, particularly when treated with GA₃, was accompanied by remarkable spiral growth. In contrast, the first internodes of the GA-insensitive cultivar Norin 10 did not exhibit GA₃-induced elongation or spiral growth. The walls of the first internode cells of GA₃-treated Hong Mang Mai seedlings showed increased extensibility and higher (1→3), (1→4)- β - d -glucanase activity, autolysis and glucan contents than the cell walls of untreated Hong Mang Mai first internodes. The changes in the cell wall extensibility due to GA₃ treatment correlated strongly with the GA₃-induced changes in cell wall glucan content, autolysis, and glucanase activity. GA₃-treated Hong Mang Mai seedlings showed elevated expression of Glucanase EI gene in the first internode compared to GA₃-treated Norin 10. Thus, GA aids first internode elongation in Hong Mang Mai by enhancing glucan turnover and thus increasing cell wall loosening. The spiral growth of the first internode also helps the plant elongate against soil resistance, thereby promoting the deep-sowing tolerance of this cultivar.     

Increases in enzyme levels during the formation of phenolic acids in carrot cell cultures

The levels of glutamic acid dehydrogenase (GDH), phenylalanine ammonia-lyase (PAL), cinnamic acid 4-hydroxylase (CAH) and O-methyltransferase (OMT) were measured during the formation of phenolic acids in carrot cells in suspension culture. Caffeic, ferulic and p-hydroxybenzoic acids were always present as the culture proceded. Total content of these acids increased at the early logarithmic and linear phases. GDH showed high activity at the early logarithmic and stationary phases. PAL activity was much enhanced at the linear and stationary phases. CAH activity was found in actively growing cells, especially at the early and late logarithmic phases OMT behaved similarly to PAL. The increases in GDH and CAH might be responsible for the rapid synthesis of phenolic acid at the early logarithmic phase. The increase in phenolic acid at the linear phase would certainly be due to enhancements of both PAL and OMT. On the other hand, the accumulation of vanillic acid was observed in cells which were transferred and cultured on an agar medium, but not in cells in suspension culture. This accumulation is related to increases in OMT levels and also to changes in the degree of β-oxidation.     

Substitution of Glu122 by Glutamine Revealed the Function of the Second Water Molecule as a Proton Donor in the Binuclear Metal Enzyme Creatininase

Creatininase is a binuclear zinc enzyme and catalyzes the reversible conversion of creatinine to creatine. It exhibits an open-closed conformational change upon substrate binding, and the differences in the conformations of Tyr121, Trp154, and the loop region containing Trp174 were evident in the enzyme-creatine complex when compared to those in the ligand-free enzyme. We have determined the crystal structure of the enzyme complexed with a 1-methylguanidine. All subunits in the complex existed as the closed form, and the binding mode of creatinine was estimated. Site-directed mutagenesis revealed that the hydrophobic residues that show conformational change upon substrate binding are important for the enzyme activity.We propose a catalytic mechanism of creatininase in which two water molecules have significant roles. The first molecule is a hydroxide ion (Wat1) that is bound as a bridge between the two metal ions and attacks the carbonyl carbon of the substrate. The second molecule is a water molecule (Wat2) that is bound to the carboxyl group of Glu122 and functions as a proton donor in catalysis. The activity of the E122Q mutant was very low and it was only partially restored by the addition of ZnCl₂ or MnCl₂. In the E122Q mutant, k_cat is drastically decreased, indicating that Glu122 is important for catalysis. X-ray crystallographic study and the atomic absorption spectrometry analysis of the E122Q mutant-substrate complex revealed that the drastic decrease of the activity of the E122Q was caused by not only the loss of one Zn ion at the Metal1 site but also a critical function of Glu122, which most likely exists for a proton transfer step through Wat2.     

Group 1 and 2 LEA protein expression correlates with a decrease in water stress induced protein aggregation in horsegram during germination and seedling growth

Plants produce an array of proteins as a part of a global response to protect the cell metabolism when they grow under environmental conditions such as drought and salinity that generate reduced water potential. The synthesis of hydrophilic proteins is a major part of the response to water deficit conditions. An increased expression of LEA proteins is thought to be one of the primary lines of defense to prevent the loss of intercellular water during adverse conditions. These LEA proteins are known to prevent aggregation of a wide range of other proteins. In this study we report the water stress induced protein aggregation and its abrogation followed by expression of group 1 and group 2 LEA proteins of water soluble proteomes in horsegram. Water stress caused an increased protein aggregation with magnitude and duration of stress in horsegram seedlings. Tissue-specific expression of LEA 1 protein decreased in the embryonic axis when compared to cotyledons in 24 h stressed seedlings. We found no cross reaction of LEA 1 with proteome of 48 h stressed embryonic axis and 72 h stressed root and shoot samples. However, LEA 2 antibodies were cross reacted with four polypeptides with different molecular mass in shoot tissue samples and found no reaction with root proteome as evidenced from immuno-blot analysis. The role of LEA proteins in relation to protein aggregation during water stressed conditions was discussed.     

Changes in osmotic pressure and cell wall properties during auxin- and ethylene-induced growth of intact coleoptiles of rice

Indole-3-acetic acid and 1-aminocyclopropane-1-carboxylic acid, the precursor of ethylene, stimulated elongation of coleoptiles of seedlings of intact rice ( Oryza sativa L. cv. Sasanishiki) submerged in buffer solution with constant air-bubbling. The osmotic pressure of the cell sap decreased during elongation of coleoptiles. In the presence of 30 μ M aminooxyacetic acid, an inhibitor of ethylene biosynthesis, in-dole-3-acetic acid at 30 μ M accelerated the decrease in the osmotic pressure in the early stage of growth. 1-Aminocyclopropane-1-carboxylic acid at 30 μ M did not influence the decrease in the osmotic pressure.
Both indole-3-acetic acid and 1-aminocyclopropane-1-carboxyIic acid decreased the minimum stress-relaxation time and the relaxation rate of the cell wall, suggesting that both auxin and ethylene induce elongation of rice coleoptiles by stimulating cell wall loosening. These growth regulators caused an increase in the level of glucose in hemicelluloses in the early stage of growth and a decrease in the level in the subsequent last growth phase. Indole-3-acetic acid decreased the hydroxyproline and glucosamine levels per unit dry weight of the cell wall. These changes in the level of cell wall components may be associated with the changes in the mechanical properties of the cell walls caused by auxin and ethylene.     

拥挤试剂PEG2000对不同拓扑结构类弹性蛋白相变的影响

类弹性蛋白（Elastin-like polypeptides,ELPs）是属于弹性蛋白中的一种且具有温控性的生物大分子,本文研究拥挤试剂对不同拓扑结构ELPs相变温度的影响,利用温控-紫外分光光度计研究其相变特性,结果发现,随着PEG2000浓度的增加,T-E-F的相变温度下降11.9~17.1℃;在固定Tadpole-like-E浓度下,随着PEG2000浓度的增加,Tadpole-like-E的相变温度降低11.5~16℃,其中,25 μmol/L的Tadpole-like-E其相变速度缓慢;ELPs浓度越大,其相变温度降低愈大,且PEG2000影响ELPs相变温度的趋势与ELPs的拓扑结构关系不大。另外,在简单的PBS缓冲溶液中加入PEG2000,可以使E-C在浓度＜0.5 mol/L的Na2CO3中发生相变,且随着PEG2000浓度的增加,E-C相变温度逐渐降低。本研究为今后ELPs在复杂体系的应用提供前期的基础研究。     

Gold nanoparticle and polyethylene glycol in neural regeneration in the treatment of neurodegenerative diseases

Gold nanoparticles (GNs) have unique characteristics, for example, stability, biocompatibility, small dimensions, and low toxicity. Several clinical applications have been suggested for GNs, such as diagnosis, imaging, and drug delivery. GNs absorb infrared light, indicating their potential value for imaging. There is growing evidence showing the therapeutic application of GN for drug delivery because of their interaction with the blood-brain barrier and DNA, the latter being associated with their genotoxic effects. GN can also be stimulated to produce high local temperatures, indicating their potential value in photodynamic therapy in the treatment of tumors. The aim of the current review is to summarize the potential applications of GNs in the biomedical field, specifically in neurodegenerative diseases.     

On the Molecular Mechanism of Steric Stabilization of Liposomes in Biological Fluids

Abstract

Liposomes with specific surface modification overcome rapid in vivo uptake by cells of the mononuclear phagocytic system (MPS) resulting in prolonged circulation in the blood. The structure-function relationship of this effect has been examined by measurements both in vitro and in vivo. The results are reviewed and compared with those from liposomes without surface modification. For example, in the best cases with polyethylene glycol-derivatized phosphatidylethanolamine (PEG-PE) up to 35% of the injected dose remains in the blood and less than 10% is taken up by the two major organs of the MPS, liver and spleen, after 24 hr. This compares with less than 1% in the blood and up to 40% uptake for liposomes without PEG-PE. Steric stabilization has been proposed as a theoretical basis for these results, and some initial results testing this basis have been reported. Here, we discuss steric stabilization in terms of the physico-chemical properties of the liposomes.     

Changes in the content of phenolic substances during the growth ofNicotiana tabacum cell suspension culture

The dynamics of changes in the content of four groups of phenolic substances was investigated during the growth cycle of the cell suspension culture ofNicotiana tábacum by means of fractionation. The relative contents of free phenolic acids, their esters, phenolic glycosides, and phenole acids non-extractable with methanol changed in dependence on the growth phase of the culture. A sharp increase, especially in the content of ester- and glycoside-bound phenolics and to a lesser extent also of phenolics belonging to the other two groups, occurred at the end of the lag phase. Then, after a temporary decrease at the early linear phase, the level of phenolics in the three fractions representing bound forms considerably increased again at the late linear and early stationary phases. The synthesized phenolic substances were partially released from the cells into the cultivation medium, which contained 15 to 30 % of the total content of the phenolics in the culture at different phases of the growth cycle. Likely causes of these changes are discussed.