Isolation of Sperm Cells from the Pollen of Plumbago zeylanica

Intact sperm cells of Plumbago zeylanica were released from mature pollen grains near anthesis using osmotic shock with 20% sucrose. Sperm cell yields of up to 75% can be attained by differential centrifugation using a clinical centrifuge with concentrations of up to 8.8 × 10⁶ cells/milliliter. Such `gametoplasts' remain intact for up to 24 hours according to Evan's blue exclusion and can be used for characterization or physiological manipulation.     

The Use of Non-permeating Pigments for Testing the Survival of Cells

The survival of cells may be tested within 5 min by mountingtissue sections in solutions of Evan's blue (0.05 to 0.25 percent w/v). Live cells retain their semi-permeable propertiesand therefore exclude Evan's blue, whereas dead cells becomepigmented as the dye penetrates.     

Relationship between Salt Tolerance and Resistance to Polyethylene Glycol-Induced Water Stress in Cultured Citrus Cells

Salt-tolerant selected cells of Shamouti orange (Citrus sinensis) and Sour orange (Citrus aurantium) grew considerably better than nonselected cells at any NaCl concentration tested up to 200 millimolar. Also, the growth response of each treatment was identical in the two species. However, the performance of cells of the two species under osmotic stress induced by polyethylene glycol (PEG), which is presumably a nonabsorbed osmoticum, was significantly different. The nonselected Shamouti cell lines were significantly more sensitive to osmotic stress than the selected cells. The salt adapted Shamouti cells were apparently also adapted to osmotic stress induced by PEG. In Sour orange, however, the selected lines had no advantage over the nonselected line in response to osmotic stress induced by PEG. This response was also similar quantitatively to the response of the selected salt-tolerant Shamouti cell line. It seems that the tolerance to salt in Shamouti, a partial salt excluder, involves an osmotic adaptation, whereas in Sour orange, a salt accumulator, such an adaptation apparently does not occur. PEG-induced osmotic stress causes an increase in the percent dry weight of salt-sensitive and salt-tolerant cells of both species. No such increase was found under salt stress. The size of control and stressed cells is not significantly different.     

Relationship of blood vessels to small intensely fluorescent cells in the autonomic ganglion.

In our experiments we observed the relationship of the blood vessels to the small, intensely fluorescent cells (SIF cells) in the lower mesenteric ganglion of the cat. We injected the solution of Evan's blue into the ganglia and processed them with the fluorescent histochemical method by Falck and Hillarp. We observed that the SIF cells are placed in the ganglia closely to the blood vessels or closely round them. When observing lager groups of SIF cells placed at the edge of the ganglia a dense network of the blood vessels was observed among these cells.     

Optimization of Parameters for Isolation of Protoplasts from the Antarctic Sea Ice Alga Chlamydomonas Sp. ICE-L

The present study was initiated to provide a systematic protocol for producing protoplasts from the Antarctic sea ice alga Chlamydomonas sp. ICE-L suitable for physiological studies. The results showed that the mixtures of 3.0% Cellulase R-10 and 2.0% Macerozyme R-10 were most effective for isolating protoplasts from this alga. Optimum pH and temperature for hydrolytic enzyme reaction were pH 6.0 and 15^∘C, respectively. Mannitol and sorbitol were found to be the excellent osmotic stabilizers. Growth conditions of the algae prior to enzyme treatment also influenced the yield of protoplasts greatly. At the optimized condition, protoplast production was 47.8%, and the viability of isolated protoplasts was more than 97.6% as confirmed by Evan's blue staining.     

渗透稳定剂的互补效应及某些渗透稳定剂对蓝藻细胞壁的降解作用

由多种盐组成的复合渗透稳定剂用于分离蓝藻原生质球的效力与单一盐溶液相比较,其作用多数显示加强,但对原生质球稳定性的影响随盐类组合而异。若干种盐类,如酒石酸铵、硫酸铵和硫酸镁,对蓝藻细胞壁表现一定的降解作用,以酒石酸铵作用最强,可用于分离原生质球。此种原生质球透明度较差,但对低渗敏感     

拟南芥ANAC055基因突变体对高盐和渗透胁迫的响应

高盐和渗透等非生物胁迫是影响农作物产量和品质的重要因素,非生物胁迫发生时,植物通过体内各类转录因子启动胁迫应答反应,进而降低非生物胁迫对植物的损伤。本研究筛选出植物特异性转录因子ANAC055编码基因的纯合T-DNA插入突变体SALK_152738,测序分析发现T-DNA插在ANAC055基因的3'UTR区域。实时荧光定量PCR结果表明叶中ANAC055基因表达量最高;与野生型相比,突变体叶、茎和花中ANAC055基因表达量分别下降了40%、50%和70%。高盐胁迫后,野生型和突变体叶中ANAC055基因表达量分别比对照上升了320%和55.4%;而渗透胁迫时,该基因叶中的表达量分别比对照下降了47.7%和56.3%;电子表达谱分析发现该基因根中的表达可受高盐和渗透等多种非生物胁迫的诱导表达。高盐和渗透胁迫时野生型和突变体幼根的生长均受到明显抑制,但高盐胁迫对突变体根生长的抑制作用比对野生型根生长的抑制作用更大。上述分析表明拟南芥ANAC055基因可受高盐和渗透等非生物胁迫的诱导表达,并且其在拟南芥幼根的生长发育过程中具有一定的作用,本研究有助于进一步明确其在非生物胁迫过程中的作用。     

Reorganization of interphase microtubules in root cells of <Emphasis Type="Italic">Medicago sativa</Emphasis> L. during acclimation to osmotic and salt stress

We examined the organization of microtubule system of interphase cells in roots of Medicago sativa L. during acclimation to salt and osmotic stress at different concentrations of NaCl, Na₂SO₄, and mannitol. We identified morphological changes of tubulin cytoskeleton in different root tissues during the acclimation to salt and osmotic stress: (1) decreased density of the cortical microtubule network, (2) random orientation of cortical microtubule bundles, (4) thickening of the bundles, (3) nonuniform density of the bundles, (4) fragmentation of the bundles, and (5) formation of microtubule converging centers. Network thinning and thickening of the bundles were observed both under osmotic and salt stress. Random orientation of cortical microtubules was visualized under osmotic stress but not during salt stress. Fragmentation of microtubule bundles took place under salt stress with a high concentration of mannitol. Formation of microtubule converging centers was common under prolonged action of sodium sulfate, less evident under sodium chloride, and not found after mannitol treatment. Our data show that, in alfalfa root cells, cortical microtubules rearrange not only in response to different ions, but also to osmotic pressure. Thus, the signaling pathways and molecular mechanisms inducing reorganization of the microtubule system may be triggered by sodium cations, as well as by sulfate and chloride anions at concentrations that do not cause irreversible cell damage.     

Solutes Involved in Osmotic Adjustment to Increasing Salinity in Suspension Cells of Alternanthera philoxeroides Griseb

Cell recovery from osmotic stress was studied in suspension cell cultures from Alternanthera philoxeroides [Mart.] Griseb. Changes in different classes of cellular solutes were measured after cells were transferred from 0 to 200 mM NaCl (high salt) to obtain an integrated picture of the solute pools involved in osmotic adjustment. By 2 h, cellular [Na⁺] and [Cl⁻] had increased several-fold, potentially accounting for the osmotic adjustment that produced a rapid recovery of cell turgor. There was a four-fold increase in the concentration of quaternary ammonium compounds (QAC) by 12 h and a slower increase for several days afterward. Betaine aldehyde dehydrogenase (BADH) is required for synthesis of glycine betaine, a QAC produced by a range of organisms in response to osmotic stress. Western-blot analysis for BADH suggested that glycine betaine was a significant component of the QAC solutes. The amount of BADH was generally similar at different sampling times for control and high salt cells, unlike previous reports of stimulation by osmotic stress in intact plants of some species. Between 3 and 7 days after cell transfer to high salt, other organic solutes increased in concentration and [Na⁺] and [Cl⁻] decreased. In A. philoxeroides, high [Na⁺] and [Cl⁻] produce rapid osmotic adjustment but organic solutes apparently replace these potentially harmful inorganic ions after the recovery of turgor.     

Accumulation of Trehalose as a Compatible Solute under Osmotic Stress in Euglena gracilis Z

ABSTRACT. The photosynthetic protozoon Euglena gracilis, accumulated a large amount of trehalose in the cells under salt or osmotic stresses. Radioactivity of [14C] paramylon, a β-1,3-polyglucan which was stored in the cells of E. gracilis. was degraded rapidly and this radioactivity was almost stoichiometrically incorporated into trehalose. The interconversion of trehalose from paramylon by salt or osmotic stresses was dependent on the concentrations or osmotic pressures, suggesting that E. gracilis accumulate trehalose as an osmoprotectant. After the removal of salt or osmotic stresses, trehalose was gradually degraded, however, it was not converted into paramylon.     

苜蓿愈伤组织盐适应过程中的溶质积累

通过一步筛选获得耐1.0％NaCl的苜蓿愈伤组织(S-1)。比较盐适应(S-1)和未经适应愈伤组织(S-0)在1.0％NaCl培养基上溶质积累的情况,渗透势的下降S-0略低于S-1;S-0细胞变小,S-1细胞无明显变化,含水量S-0比S-1下降多,Na~ 和Cl~-大量积累,S-0低于S-1,K~ 浓度升高,但含量下降,S-0比S-1下降多,脯氨酸和可溶性还原糖含量的增加S-0远高于S-1。对于含盐培养基上S-0和S-1渗透调节模式的差异及溶质积累与盐适应的关系,可以认为增加Na~ 和Cl~-积累是苜蓿愈伤组织盐适应的主要方面,脯氨酸和可溶性还原糖的增加在渗透适应上只起部分作用。     

Development of callus and suspension cultures of potato resistant to NaCl and mannitol and their response to stress

Callus and suspension cultures adapted to various concentrations of NaCl or mannitol were developed from the cultivated potato Solanum tuberosum cv. Desire. Growth of the calli was less inhibited by mannitol than by iso-osmotic concentrations of NaCl. Reduction of growth by both NaCl and mannitol was considerably lower in osmotically adapted calli than in non-adapted ones. Salt-adapted suspension cultures that grew in the medium to which they had been originally adapted had a shorter lag in growth as well as a shorter time required to achieve the maximum growth, as compared with non-adapted cells. Suspension cultures adapted to NaCl concentrations higher than 150 mM were obtained only after preadaptation to osmotic stress. Adaptation of these cells was found to be stable. Accumulation of Na⁺ was lower and level of K⁺ was more stable in osmotically adapted than in non-adapted calli, when both were exposed to salt. Potassium level in NaCl-adapted calli exposed to saline medium was lower than that in non-adapted calli in standard medium. The maximum of Cl^– and Na⁺ accumulation was reached at higher external salt concentration in salt-adapted than in non-adapted suspension cultures. In both callus and suspension cultures, Cl^– accumulated more than Na⁺. Potassium level decreased more in non-adapted than in NaCl-adapted suspension cultures. The decrease of osmotic potential in osmotically adapted calli exposed to mannitol and in salt-adapted calli and suspension cultures exposed to salt was correlated to the increase of the external concentration. Such a correlation was not found in osmotically adapted calli exposed to salt. Non-electrolytes were found to be the main contributors to the decrease is osmotic potential in both callus and suspension cultures.     

The relationship between the osmotic fragility of human erythrocytes and cell age

Erythrocytes in a normal blood sample are hemolyzed over a range of hypotonic salt concentrations. In order to investigate the relationship between the distribution of osmotic fragilities and the distribution of cellular ages, the osmotic fragility has been compared with three indices of cellular age. The activity of glutamic-oxalacetic transaminase (GOT) and the percentage hemoglobin A_1C were measured in samples hemolyzed in different hypotonic salt concentrations. The osmotic fragility curve was also obtained for cells of different density separated by centrifugation. These experiments indicate that the fragility distribution is not an accurate reflection of the distribution of cellular ages. The mean fragility for older cells is higher than that of younger cells. However, cellular aging does not produce a gradual increase in osmotic fragility. Instead, it seems to produce changes which can both increase and decrease the fragility, resulting in a broader distribution of fragilities with some of the older cells actually less fragile than the younger ones.     

Osmotic sensitivity in relation to salt sensitivity in germinating barley seeds

Abstract Cultivars of barley (Hordeum vulgare L.) were tested for germination sensitivity to progressively higher concentrations of salt, mannitol, and betaine. The three solutes were equally inhibitory at equal osmotic potential, but there was a consistent difference in osmotic sensitivity between two cultivars, CM-67 and Briggs (Briggs was the most sensitive). There was no difference between the two cultivars in salt or water uptake from salt solutions during imbibition. Brief presoaking in water did not improve salt resistance, indicating that a hydration-dependent decrease in membrane permeability is not involved in salt tolerance. The calcium content of Briggs was higher than CM-67. These results suggest that salt inhibits barley germination primarily by osmotic effects, and that salt influx during imbibition does not play a role in this inhibition. A hypothesis regarding salt effects on germination is discussed.     

Understanding Saline and Osmotic Tolerance of Populus euphratica Suspended Cells

Tolerance of Populus euphratica suspended cells to ionic and osmotic stresses implemented respectively by NaCl and PEG (6000) was characterized by monitoring cell growth, morphological features, ion compartmentation and polypeptide patterns. The cells grew and proliferated when submitted to stresses of 137 mM NaCl or 250 g l⁻¹ PEG, and survived at 308 mM of NaCl, showing tolerance to saline and particularly osmotic stress. They were resistant to plasmolysis and had dense cytoplasms, large nuclei and nucleoli, and evident cytoplasmic strands under high saline and osmotic stress. The sequestration of Cl⁻ into the vacuoles was observed in the cells stressed with 137 and 223 mM NaCl. The cellular protein profile was modified by high salt and osmotic stress and showed 28 kDa polypeptides up-regulated by both NaCl and PEG, and 66 and 25 kDa polypeptides up-regulated only by high NaCl stress. The salt tolerance of P. euphratica cells might be related to their capacity of adapting to higher osmotic stress by maintaining cell integrity, sequestrating Cl⁻ into vacuoles and modulating polypeptides that reflect cellular metabolic adaptations.     

Protoplasts surviving freezing to -196 C and osmotic dehydration in 5 molar salt solutions prepared from the bark of winter black locust trees

Free protoplasts were prepared from the living bark tissue of the trunk of summer and winter black locust trees by enzymic digestion of thin slices of the tissue for 3 hours in a medium containing 2% Onozuka cellulase, 2% Rhozyme pectinase, and 2% Driselase in mannitol solutions using 0.4 molar mannitol for summer tissue and 1.0 molar mannitol for winter tissues. Cleaned suspensions of protoplasts and also thin slices of tissue with cells intact were frozen to temperatures of −10 C, −20 C, −30 C, −40 C and liquid nitrogen in sucrose and balanced salt solutions. Similar suspensions of protoplasts were also subjected to strong osmotic dehydration (plasmorrhysis) in a series of balanced salt solutions of increasing molarity. Tests for survival showed that protoplasts retain the same properties of either extreme susceptibility or extreme resistance to injury by freezing or osmotic dehydration as the cells from which they are prepared. Winter protoplasts showed capability for tolerating freezing to −196 C and plasmorrhysis in 5 molar salt solutions. These results indicate that protoplasts are a valid and useful system for investigating the properties of the protoplasm and surface membranes associated with the seasonal development of extreme hardiness in the cells of woody plants.     

Stress‐induced pyruvate accumulation contributes to cross protection in a fungus

It is commonly observed that microorganisms subjected to a mild stress develop tolerance not only to higher doses of the same stress but also to other stresses – a phenomenon called cross protection. The mechanisms for cross protection have not been fully revealed. Here, we report that heat shock induced cross protection against UV, oxidative and osmotic/salt stress conditions in the cosmopolitan fungus Metarhizium robertsii. Similarly, oxidative and osmotic/salt stresses also induced cross protection against multiple other stresses. We found that oxidative and osmotic/salt stresses produce an accumulation of pyruvate that scavenges stress‐induced reactive oxygen species and promotes fungal growth. Thus, stress‐induced pyruvate accumulation contributes to cross protection. RNA‐seq and qRT‐PCR analyses showed that UV, osmotic/salt and oxidative stress conditions decrease the expression level of pyruvate consumption genes in the trichloroacetic acid cycle and fermentation pathways leading to pyruvate accumulation. Our work presents a novel mechanism for cross protection in microorganisms.