Effects of mucilage on seed germination of the desert ephemeral plant Plantago minuta Pall. under osmotic stress and cycles of wet and dry conditions

To test the role of the seed mucilage of Plantago minuta Pall. in regulating germination under osmotic stress and cycles of hydration and dehydration, two experiments were carried out using seeds with intact mucilage and mucilage‐free seeds. In Experiment 1 seeds were immersed in a range of iso‐osmotic polyethylene glycol solutions (?1.15 to 0 MPa) for 14 days; any ungerminated seeds were transferred to deionized water to investigate the recovery germination. In Experiment 2 seeds were immersed in deionized water for 24 h, and were then incubated on filter paper for an additional 13 days to ensure complete desiccation before reimbibition to test the germination recovery percentage. Under mild osmotic stress (?0.73 to 0 MPa), the intact seeds with mucilage were shown to have higher germination rates than the mucilage‐free seeds, indicating that the mucilage led to a “fast sprouting” germination strategy under mild osmotic stress. However, when seeds were exposed to high osmotic stress (?1.15 MPa), the mucilage apparently slowed the germination rate, resulting in a “risk‐balancing” germination strategy. Extreme drought induced by polyethylene glycol solution and the desiccation pretreatment accelerated germination rates compared to non‐pretreated seeds; both germination potential and recovery percentage of the mucilage seeds were significantly higher than that of the mucilage‐free seeds. Our results revealed that the seed mucilage of P. minuta plays a crucial role in regulating seed germination rates and the germination strategies adopted by controlling seed water absorption when the seeds experience different osmotic stresses or alternating wet and dry conditions.     

Formaldehyde treated gelatin as a gel exclusion agent.

A high molecular weight fraction of gelatin precipitated from a solution of Difco gelatin with polyethylene glycol has several favourable properties in gel exclusion chromatography. To manufacture the gel exclusion agent, the gelatin was dissolved in hot water, allowed to set in the cold and rendered insoluble by reaction with formaldehyde. When finely disrupted and used as bed material in columns this gel is capable of separating protein components from mixtures of proteins of widely different molecular weights. Favourable properties include elasticity at relatively low concentration, its availability and its inexpensive nature.     

Formaldehyde Treated Gelatin as a Gel Exclusion Agent

A high molecular weight fraction of gelatin precipitated from a solution of Difco gelatin with polyethylene glycol has several favourable properties in gel exclusion chromatography. To manufacture the gel exclusion agent, the gelatin was dissolved in hot water, allowed to set in the cold and rendered insoluble by reaction with formaldehyde. When finely disrupted and used as bed material in columns this gel is capable of separating protein components from mixtures of proteins of widely different molecular weights. Favourable properties include elasticity at relatively low concentration, its availability and its inexpensive nature.     

Phosphorus contamination in polyethylene glycol

Concentrations of Fe, Mn, Cu, Zn, Ca, Mg, K, and P were examined in untreated and ion exchange resin-treated solutions of polyethylene glycol, molecular weight 3000 to 3700, polyethylene glycol (PEG 4000). Relatively high levels of P were found in untreated PEF-4000 solutions. The concentration of contaminating P in solutions prepared from untreated PEG 4000, even at high water potentials (−1 to −3 bars), was greater than what is usually found in soil solution. Occurrence of significant amounts of P in untreated PEG could introduce problems in experiments where ³²P and PEG are used together and where phosphate interactions may occur.     

Detection and molecular weight determination of polyethylene glycol-modified hirudin by staining after sodium dodecyl sulfate-polyacrylamide gel electrophoresis.

This article describes a general method for detecting pegylated proteins directly after SDS-PAGE. The proteins to which polyethylene glycol (PEG) molecules are attached are stained with a barium iodide solution. The staining is based on the formation of a barium iodide complex with PEG. The described method combines a specific staining of PEG molecules with the high resolution of the SDS-PAGE method. It is shown that pegylated protein is detectable on SDS-PAGE as well as on IEF at concentrations that are not detectable by Coomassie protein staining. This paper also describes the determination of the molecular weight of pegylated hirudin by calibrating SDS-PAGE with polyethylene glycol of different molecular weight. Under the conditions used, PEG showed linear mobility during electrophoresis. However, the use of nonpegylated proteins as standards resulted in incorrect molecular weight values due to the lower mobility of the pegylated protein during electrophoresis. The method described might reflect a general method for determining molecular weight of pegylated proteins.     

Effect of osmotic priming, rinsing and storage on the germination and emergence of carrot seed

Carrot seed, osmotically primed in polyethylene glycol solution (273 g/kg water) for 10 days at 15°C, was given 0–5 rinsing cycles, where each cycle comprised agitating the seed in 10 times its own bulk volume of distilled water for 20 to 30 s. Priming decreased the germination and emergence times whether the seeds were rinsed or not, and these effects were maintained even after storage for 450 days. The number of rinsing cycles had no effects, except that seed given five rinsing cycles deteriorated after 270 days storage.     

A Theory for the Displacement of Proteins and Viruses with Polyethylene Glycol

The displacement action of polyethylene glycol of different molecular weights may be linked to the ability of the polymers to form coiled particles in solution. From conclusions drawn from their sedimentating properties in centrifugal fields the polyethylene glycols of low molecular weights, as expected, are les randomly coiled than those of higher molecular weight. It is suggested that protein molecules have the ability to diffuse into the coils of the polyethylene glycol from which they are excluded when the random coiling increases with increasing polymer concentration. From considerations based on the interaction of the polymer filament with the displaced particle the distribution of the substance between the coils and the intermolecular spaces may be predicted semi-quantitatively.     

A theory for the displacement of proteins and viruses with polyethylene glycol.

The displacement action of polyethylene glycol of different molecular weights may be linked to the ability of the polymers to form coiled particles in solution. From conclusions drawn from their sedimentating properties in centrifugal fields the polyethylene glycols of low molecular weights, as expected, are less randomly coiled than those of higher molecular weight. It is suggested that protein molecules have the ability to diffuse into the coils of the polyethylene glycol from which they are excluded when the random coiling increases with increasing polymer concentration. From considerations based on the interaction of the polymer filament with the displaced particle the distribution of the substance between the coils and the intermolecular spaces may be predicted semi-quantitatively.     

Evaluation of water stress control with polyethylene glycols by analysis of guttation

The water relations of pepper plants (Capsicum frutescens L.) under conditions conducive to guttation were studied to evaluate the control of plant water stress with polyethylene glycols. The addition of polyethylene glycol 6000 to the nutrient solution resulted in water relations similar to those expected in soil at the same water potentials. Specifically, xylem pressure potential in the root and leaf became more negative during a 24-hour treatment period, while osmotic potential of the root xylem sap remained constant. The decrease in pressure potential was closely correlated with the decrease in osmotic potential of the nutrient solution. In contrast, the addition of polyethylene glycol 400 to the nutrient medium resulted in a reduction of osmotic potential in the root xylem sap; this osmotic adjustment in the xylem was large enough to establish an osmotic gradient for entry of water and cause guttation at a nutrient solution osmotic potential of −4.8 bars. Pressure potential in the root and leaf xylem became negative only at nutrient solution osmotic potentials lower than −4.8 bars. About half of the xylem osmotic adjustment in the presence of polyethylene glycol 400 was caused by increased accumulation of K⁺, Na⁺, Ca²⁺, and Mg²⁺ in the root xylem. These studies indicate that larger polyethylene glycol molecules such as polyethylene glycol 6000 are more useful for simulating soil water stress than smaller molecules such as polyethylene glycol 400.     

2. A Theory for the Displacement of Proteins and Viruses with Polyethylene Glycol

ABSTRACT

The displacement action of polyethylene glycol of different molecular weights may be linked to the ability of the polymers to form coiled particles in solution. From conclusions drawn from their sedimentating properties in centrifugal fields the polyethylene glycols of low molecular weights, as expected, are less randomly coiled than those of higher molecular weight. It is suggested that protein molecules have the ability to diffuse into the coils of the polyethylene glycol from which they are excluded when the random coiling increases with increasing polymer concentration. From considerations based on the interaction of the polymer filament with the displaced particle the distribution of the substance between the coils and the intermolecular spaces may be predicted semi-quantitatively.     

Agarose: a possible universal gel exclusion agent

Granulated agarose gels suitable for gel exclusion chromatography of proteins of any molecular weight may now be prepared. This was made possible by the observation that agarose solutions of 16% polysaccharide may be prepared by displacing 8% agarose from solution with 8% polyethylene glycol Mr 6000. The displaced polysaccharide concentrates in a viscous mass occupying half the volume of the original carbohydrate solution. By diluting the displaced polysaccharide with hot watery solutions of electrolyte and allowing the solutions to congeal, gels of any desired concentration, ranging from low to the maximum of 16%, may be prepared.     

Initiation and regulation of water deficit-induced abscisic acid accumulation in maize leaves and roots: cellular volume and water relations

Water deficit-induced ABA accumulation in relation to cellular water relations was investigated in maize root and leaf tissues. While polyethylene glycol (PEG) treatment led to a significant increase of ABA content in both root and leaf tissues, ethylene glycol (EG), a permeable monomer of PEG, had no effect on ABA accumulation at similar or much lower osmotic potentials. A rapid and massive accumulation of ABA in leaf tissues occurred at a specific threshold of PEG 6000 concentration, about 20% (w/v), and closely coincided with the start of the tissue weight loss and the obvious decrease of cellular osmotic potential. Pretreatment with EG lowered the cell sap osmotic potential and also lowered the capability of both root and leaf tissues to accumulate ABA in response to further air-drying or PEG treatment. When samples were dehydrated and incubated under pressure, a method to maintain high water potential and pressure potential during dehydration, ABA accumulation was similar to those dehydrated and incubated under atmospheric pressure. Such results suggest that both the absolute water potential and pressure potential per se had no direct effects on the dehydration-induced ABA accumulation. The results have provided evidence that the initiation of ABA accumulation is related to the weight loss of tissues or changes in cellular volume rather than the cell water relation parameters, and the capability of ABA accumulation can be regulated by cellular osmotic potential.     

Comparison of two methods for callus culture and plant regeneration in wheat (Triticum aestivum)

Callus growth and development involve a complex relationship between the explants used to initiate callus, the constituents of the medium and the environmental conditions during culturing. Use of high molecular weight osmotica such as polyethylene glycol (PEG-4000) results in non-solidification of agar medium used for culturing and selection. Thus, a new filter paper bridge technique was compared with the existing agar medium for callus initiation, multiplication, and plant regeneration of wheat. The yield of both total and embryogenic callus was doubled and significantly higher number of regenerants was obtained on filter paper bridges compared to agar medium.     

Development and germination of pecan somatic embryos derived from liquid culture

Aggregates of globular and pre-globular stage somatic embryos from suspension cultures of pecan (Carya illinoensis Koch) were cultured on solidified media for embryo development. Embryo aggregates and pre-globular stage embryo masses were given various treatments to further ontologic development. A 2- to 4-wk mild dehydration of the embryo aggregates suppressed recurrent embryogenesis, promoted development of globular embryos into cotyledonary stage embryos, and enhanced plant development beyond germination. Fine embryogenic tissue masses filtered from suspension formed cotyledonary-staged embryos when the collection filters were plated on solified medium. The embryogenic capacity of preglobular stage embryo masses was compared between media supplemented with varying concentrations of polyethylene glycol (molecular weight 8 000) vs. filter overlays. The filter paper overlays were not necessary for embryo development. An inverse relationship was found between the number of embryos that developed and the concentration of polyethylene glycol in the medium. However, this relationship was reversed for ability of embryos to germinate and develop into a plant.     

Semipermeable membrane system for subjecting plants to water stress

A system was evaluated for growing plants at reproducible levels of water stress. Beans (Phaseolus vulgaris L.) were grown in vermiculite, transferred to a semipermeable membrane system that encased the root-vermiculite mass, and then placed into nutrient solutions to which various amounts of polyethylene glycol (PEG) 20M were added to control solution water potential. The membrane (Spectrapor 1) had a minimum molecular weight cutoff that excluded the PEG 20M. The plants equilibrated with the nutrient solution within 1 to 4 days, and exhibited normal diurnal water relations. Use of the semipermeable membrane system to induce water stress reduces many of the problems associated with hydroponic media.     

Cryoprotection of purified rat kidney transamidinase by polyethylene glycol.

Polyethylene glycol is a water-soluble polymer which is widely used in the pharmaceutical, cosmetic, and chemical industries. In this study, it is shown that polyethylene glycol is an effective cryoprotectant of rat kidney transamidinase purified from both the mitochondria and cytosol. Much of the activity is lost when the purified enzyme is frozen and thawed in sodium-potassium phosphate buffer in the absence of cryoprotectants. Polyethylene glycols with molecular weights of 4000 to 10,000 were effective cryoprotectants. However, polyethylene glycols with a molecular weight of 1000 or lower inhibited the purified enzyme. A concentration of only 0.01% polyethylene glycol 4000, 8000, or 10,000 was required for complete cryoprotection. In addition to polyethylene glycol, 0.5 mM ethylenediaminetetraacetic acid was required in the phosphate buffer for complete cryoprotection. The stabilization of purified transamidinase by polyethylene glycol will facilitate characterization experiments designed to compare the properties of the mitochondrial and cytosolic isozymes.     

An Apparatus for the Concentration of Large Volumes of Dilute Protein Solutions to A Predetermined Volume

An apparatus was designed and manufactured that can be used for the concentration of large quantities of dilute protein solutions to a predetermined volume. The method is based on the osmotic transfer of water to a concentrated hydrophilic polymer (poly ethylene glycol, PEG) through a protein-stopping dialysis membrane and is a refinement of a method previously reported by van Oss. The apparatus is made of perspex. Concentration takes place through a commercially available dialysis tube and is aided by a 40% polyethylene glycol solution. Large volumes (5) of dilute protein solution could be reduced to 50 ml at a rate of 30 ml per hour with no significant loss in biological activity.     

An apparatus for the concentration of large volumes of dilute protein solutions to a predetermined volume

An apparatus was designed and manufactured that can be used for the concentration of large quantities of dilute protein solutions to a predetermined volume. The method is based on the osmotic transfer of water to a concentrated hydrophilic polymer (poly ethylene glycol, PEG) through a protein-stopping dialysis membrane and is a refinement of a method previously reported by van Oss. The apparatus is made of perspex. Concentration takes place through a commercially available dialysis tube and is aided by a 40% polyethylene glycol solution. Large volumes (5l) of dilute protein solution could be reduced to 50 ml at a rate of 30 ml per hour with no significant loss in biological activity.     

Effects of turgor potential on 1-aminocyclopropane-1-carboxylic acid uptake into the vacuolar compartment and ethylene production in tomato pericarp slices

While solute transport and ethylene production by plant tissue are sensitive to the osmotic concentration of the solution bathing the tissue, the influence of tissue water relations and specifically tissue turgor potential on the kinetics of 1-aminocyclopropane-1-carboxylic acid (ACC) uptake into the vacuolar compartment and ethylene production have not been examined. 1-Aminocyclopropane-1-carboxylic acid transport and ethylene production were examined in tomato (Lycopersicon esculentum Mill. cv. Liberty) pericarp slices incubated in solutions having a range of mannitol, polyethylene glycol 3350 and ethylene glycol concentrations known to affect tissue water relations. Tissue osmotic and turgor potentials were derived from osmolality measurements of cell saps recovered by freeze-thawing and corrected for the contribution of the free-space solution. When relatively nonpermeable (mannitol or polyethylene glycol 3350) osmotica were used, both ACC uptake and ethylene production were greatest at a solution osmolality of 230 milliosmolal where tissue turgor potential ranged between 120 and 140 kPa. At higher and lower turgor potentials, the high-affinity saturating component of ACC uptake and ethylene production were inhibited, and ACC efflux from the vacuolar compartment was increased. The inhibition of ACC uptake was evident as a decrease in V_max with no effect on K_m. Turgor potential changes caused by adjusting solution osmolality with mannitol or polyethylene glycol 3350 were accompanied by changes in the osmotic potential and water potential of the tissue. The effects of turgor potential vs the osmotic and water potentials of tomato pericarp slices were differentiated by comparing responses to nonpermeable osmotica and mixtures of nonpermeable and permeable osmotica. Ethylene glycol-mannitol mixtures had effects on the osmotic potential and water potential of the tissue similar to those of nonpermeable osmotica but had less effect on tissue turgor, ACC transport and ethylene production. Incubating tissue in solutions without nonpermeable osmotica osmotically shocked the tissue. Increasing solution osmolality with ethylene glycol in the absence of nonpermeable osmotica increased tissue turgor and ethylene production. The present study indicates that tissue turgor is an important factor affecting the kinetics of ACC uptake into the vacuolar compartment and ethylene production in tomato pericarp slices.     

水体病毒浓缩方法的建立和优化研究

采用氯化钙(CaC l2)、聚乙二醇(PEG,pH7.0)、聚乙二醇(PEG,pH11.5)、三氯化铝(A lC l3)沉淀、Am icon Utcra超滤离心装置和硝酸纤维素吸附膜6种浓缩方法,浓缩人工添加于水体的1型脊髓灰质炎疫苗病毒(PV1),并对浓缩实验条件进行选择和优化。结果表明,CaC l2和聚乙二醇(pH7.0)沉淀法适用于浓缩大容量水体中的病毒,而超滤离心管浓缩法适用于小容量水体,这3种浓缩方法的病毒回收率均达到100%。