Comparative study of the effect of ionic and non-ionic surface-active compounds on plasmic membrane of yeast protoplasts]

Lytic effect of some cationic surface-active compounds (SAC) on yeast protoplast plasmic membrane is studied. Comparative analysis of the lytic effect of anionic, cationic and non-ionic SAC is carried out, a correlation between key physico-chemical characteristics of the agents (critical concentration of micellization, hydrophyle-lipophyle balance) and their lytic activity is investigated. A proposition is made on the presence in all biphylic compounds of a hydrophyly gradient, which is due to the effect of hydrophylic group on lipophylic properties of hydrophobic part of the molecule, and possible role of this factor in thelytic effect of biphylic compounds on biological membranes is discussed.     

Lysis of yeast protoplasts under sodium alkyl sulfates treatment]

The lytic action of homologous series of sodium alkyl sulfates on yeast protoplasts was studied. The concentration dependences study allowed to estimate the lytic concentrations C50 of the agents required for the 50% lysis of protoplasts in the suspension. The data concerning the agents micelle formation in the lytic medium allowed to make some suggestions and to produce a model of the lytic action of alkyl sulfates on the plasma membrane of the protoplasts. The amounts of the agents absorbed on the membrane and involved in the interaction followed by the membrane breakdown in the model are evaluated. On the basis of the data obtained it is concluded that sodium dodecyl sulfate displays the highest lytic activity to the yeast protoplast plasma membrane as compared to the other alkyl sulfates used in the study. The results obtained are discussed in terms of the effect of yeast cell wall on the extraction of intracellular proteins from intact yeast cell under sodium alkyl sulfates action.     

Effects of opioid peptides on the cellular immunity in spleen cells from intact nude mice or nude mice bearing human ovarian carcinoma

Summary The present study was designed to explore the effects of opioid peptides on the lytic activity of spleen cells from intact nude mice or nude mice bearing human ovarian cancer cells (KF). When the spleen cells from intact nude mice were incubated with various concentrations of opioid peptides, the ability of the spleen cells to lyse the KF cells was significantly stimulated between 0.05 nM and 50 nM concentrations of all opioid peptides used in this study. The degree of stimulation was most marked at 5 nM opioid peptides and the most marked stimulatory effect was obtained by -endorphin. On the other hand, the lytic activity of spleen cells from nude mice challenged with the KF cells was about two-fold higher than that of intact nude mice, suggesting that spleen cells from nude mice challenged with KF cells have KF-cell-specific cytotoxicity. Even if the spleen cells were incubated with any concentration of -endorphin or [Met]enkephalin indicated, the lytic activity remained unchanged. In contrast, only -endorphin resulted in a significant increase of the lytic activity between 0.5 nM and 50 nM. These results suggest that opioid peptides play a crucial role in immune surveillance mechanisms.     

Lytic action of strepzymes from micromonospora AS

Summary The effect of lytic enzymes of Micromonospora AS on isolated cell walls and intact or heat killed cells of Candida utilis was investigated. Several substances normally used as stabilizers during protoplast formation were tested for their effect on the lytic action of strepzyme M on intact and dead cells: NaCl and KCl markedly inhibited lysis, sucrose only to 40%. Sorbitol and MgSO₄ have no inhibitory effect. MgSO₄ was selected for further research as it was found to protect the protoplasts. Phosphate buffer pH 6.8 should not be used at concentrations above 0.01 m. When grown submerged in shaking flasks or in pilot fermentation tanks, in liquid medium containing yeast cells and salts, Micromonospora AS gave the highest yield of lytic enzymes. The strepzyme M preparation is thermolabile.     

Action of different types of gramicidin S derivatives on bacterial cells and protoplasts

The work was concerned with studying the effect of gramicidin S derivatives with modified free amino groups of ornithine residues on bacterial cells and protoplasts. The substitution of the amino groups with neutral or carboxyl-containing groups eliminated or sharply decreased the antibacterial activity of gramicidin S, its binding to the cells, and the ability to change the permeability of the cytoplasmic membranes of the intact cells. However, the neutral derivatives and the derivative with acidic properties showed a considerable lytic activity when they were incubated with the protoplasts of Micrococcus lysodeikticus, Bacillus megaterium and Bacillus subtilis. Hence, these compounds preserved a certain membranotropic level. Those gramicidin S derivatives with modified ornithine amino groups which possessed basic properties were similar to gramicidin S in the antibiotic activity, the modified permeability of the membranes, the ability to bind with the cells, and the lytic action on the protoplasts.     

Enzymes of the yeast lytic system produced by Arthrobacter GJM-1 bacterium and their role in the lysis of yeast cell walls.

Yeast lytic system produced by Arthrobacter GJM-1 bacterium during growth on baker's yeast cell walls contains a complete set of enzymes which can hydrolyze all structural components of cell walls of Saccharomyces cerevisiae. Chromatographic fractionation of the lytic system showed the presence of two types of endo-beta-1,3-glucanase. Rapid lysis of isolated cell walls of yeast was induced only by endo-beta-1,3-glucanase exhibiting high affinity to insoluble beta-1,3-glucans and releasing laminaripentaose as the main product of hydrolysis of beta-1,3-glucans. This enzyme was able to lyse intact cells of S. cerevisiae only in the presence of an additional factor present in the Arthrobacter GJM-1 lytic system, which was identified as an alkaline protease. This enzyme possesses the lowest molecular weight among other identified enzyme components present in the lytic system. Its role in the solubilization of yeast cell walls from the outer surface by endo-beta-1,3-glucanase could be substituted by preincubation of cells with Pronase or by allowing the glucanase to act on cells in the presence of thiol reagents. The mechanism of lysis of intact cells and isolated cell walls by the enzymes of Arthrobacter GJM-1 is discussed in the light of the present conception of yeast cell wall structure.     

Dispensability of the SAC Depends on the Time Window Required by Aurora B to Ensure Chromosome Biorientation

Aurora B and the spindle assembly checkpoint (SAC) collaborate to ensure the proper biorientation of chromosomes during mitosis. However, lack of Aurora B activity and inactivation of the SAC have a very different impact on chromosome segregation. This is most evident in Saccharomyces cerevisiae, since in this organism the lack of Aurora B is lethal and leads to severe aneuploidy problems, while the SAC is dispensable under normal growth conditions and mutants in this checkpoint do not show evident chromosome segregation defects. We demonstrate that the efficient repair of incorrect chromosome attachments by Aurora B during the initial stages of spindle assembly in budding yeast determines the lack of chromosome segregation defects in SAC mutants, and propose that the differential time window that Aurora B kinase requires to establish chromosome biorientation is the key factor that determines why some cells are more dependent on a functional SAC than others.     

Lysis of intact yeast cells and isolated cell walls by an inducible enzyme system of Arthrobacter GJM-1.

Bacterium Arthrobacter GJM-1 known in the literature as a good producer of alpha-mannanase was found to accumulate in the culture fluid lytic activities against viable yeast cells during growth on isolated cell walls or beta-glucan fractions of yeast. The accumulation of the lytic activities showed an inducible character. The lytic system produced in the medium containing baker's yeast cell walls was capable of complete solubiliaztion of cell wals in vitro. The system lysed viable cells of a number of yeast species and induced their conversion to protoplasts in an osmotically stabilized medium. The lytic system showed different pH and temperature optima when viable cells or isolated cell walls were used as substrates. The pH optimum of the lysis of isolated cell walls was identical with pH optimum of beta-glucanase activities in the crude system. The results pointed out that in the lysis of intact cells, in addition to beta-glucanases, some other factor is involved. Substantial differences in the nature of the outer and the inner surface of cell walls of Saccharomuces cerevisiae were confirmed in this paper based on the different susceptibility to lysis of the cell walls in vivo and in vitro.     

Production and ecological significance of yeast cell wall-degrading enzymes from oerskovia

Motile actinomycetes capable of degrading walls of viable yeast cells were isolated from soil and identified as Oerskovia xanthineolytica. A lytic assay based on susceptibility of enzyme-treated cells to osmotic shock was developed, and 10 of 15 strains of O. xanthineolytica, Oerskovia turbata, and nonmotile Oerskovia- like organisms from other collections were found to possess yeast lytic activities. All lytic strains produced laminaranase and alpha-mannanase, but the amounts, determined by reducing group assays, were not proportional to the observed lytic activities. The Oerskovia isolates demonstrated chemotactic, predatory activity against various yeast strains and killed yeasts in mixed cultures. Of 15 carbon sources tested for production of lytic enzyme, purified yeast cell walls elicited the highest activity. Glucose repressed enzyme production and caused cells to remain in the microfilamentous and motile rod stages of the Oerskovia cell cycle. Crude lytic activity was optimal at pH 5.6 to 7.0 and inactivated by heating for 6 min at 50 degrees C. Partial purification by isoelectric focusing showed that all lytic activity was associated with four beta-(1-->3)-glucanases. The absence of protein disulfide reductase, N-acetyl-beta-d-hexosaminidase, and phosphomannanase in crude preparations indicated that the principal enzyme responsible for yeast wall lysis was a beta-(1-->3)-glucanase that produced relatively little reducing sugar from yeast glucan.     

Requirement of a specific group of sphingolipid-metabolizing enzyme for growth of yeast Saccharomyces cerevisiae under impaired metabolism of glycerophospholipids

Sphingolipids play critical roles in many physiologically important events in yeast Saccharomyces cerevisiae. In this study, we screened for yeast mutants showing high sensitivity to Aureobasidin A, an inhibitor of inositol phosphorylceramide synthase, and found that a lack of SAC1 encoding phosphoinositides phosphatase causes high sensitivity to the inhibitor. Double mutation analysis involving the SAC1 and non-essential sphingolipid-metabolizing enzyme genes revealed that csg1Δ, csg2Δ, ipt1Δ or scs7Δ causes synthetic lethality with deletion of SAC1. As previously reported, SAC1-repressed cells exhibited a reduced cellular phosphatidylserine (PS) level, and overexpression of PSS1 encoding PS synthase complemented the growth defects of scs7Δ, csg1Δ and ipt1Δ cells under SAC1-repressive conditions. Furthermore, repression of PSS1 expression resulted in synthetic growth defect with the deletion of CSG1, IPT1 or SCS7. The growth defects of scs7Δ, csg1Δ and ipt1Δ cells under SAC1- or PSS1-repressive conditions were also complemented by overexpression of Arf-GAP AGE1, which encodes a protein related to membrane trafficking. Under SAC1-repressive conditions, scs7Δ, csg1Δ and ipt1Δ cells showed defects in vacuolar morphology, which were complemented by overexpression of each of PSS1 and AGE1. These results suggested that a specific group of sphingolipid-metabolizing enzyme is required for yeast cell growth under impaired metabolism of glycerophospholipids.     

Lyticase: Endoglucanase and Protease Activities That Act Together in Yeast Cell Lysis

Yeast lytic activity was purified from the culture supernatant of Oerskovia xanthineolytica grown on minimal medium with insoluble yeast glucan as the carbon source. The lytic activity was found to consist of two synergistic enzyme activities which copurified on carboxymethyl cellulose and Sephadex G-150, but were resolved on Bio-Gel P-150. The first component was a β-1,3-glucanase with a molecular weight of 55,000. The K_m for yeast glucan was 0.4 mg/ml; that for laminarin was 5.9 mg/ml. Hydrolysis of β-1,3-glucans was endolytic, yielding a mixture of products ranging from glucose to oligomers of 10 or more. The size distribution of products was pH dependent, smaller oligomers predominating at the lower pH. The glucanase was unable to lyse yeast cells without 2-mercaptoethanol or the second lytic component, an alkaline protease. Neither of these agents had any effect on the glucanase activity on polysaccharide substrates. The protease had a molecular weight of 30,000 and hydrolyzed Azocoll and a variety of denatured proteins. The enzyme was unusual in that it had an affinity for Sephadex. Although the activity was insensitive to most protease inhibitors, it was affected by polysaccharides; yeast mannan was a potent inhibitor. The enzyme did not have any mannanase activity, however. Neither pronase nor trypsin could substitute for this protease in promoting yeast cell lysis. A partially purified fraction of the enzymes, easily obtained with a single purification step, had a high lytic specific activity and was superior to commercial preparations in regard to nuclease, protease, and chitinase contamination. Lyticase has been applied in spheroplast, membrane, and nucleic acid isolation, and has proved useful in yeast transformation procedures.     

Natural killer cells can enhance the proliferative responses of B lymphocytes

In addition to lytic activity against malignant and virally transformed target cells, recent evidence has suggested that natural killer (NK) cells can modulate immune activities such as the suppression of B cell responses through noncytotoxic means. Using human B cells and highly purified autologous NK cells, we have demonstrated that NK cells can substantially augment the proliferative responses of B cells stimulated with the surface immunoglobulin crosslinking agents anti-IgM or Staphylococcus aureus Cowan strain I (SAC). This "enhancer" activity of NK cells was quite potent and was observed at an NK:B cell ratio as low as 0.05. Peak blastogenic responses of B cells cocultured with NK cells in the presence of B cell activators were observed at 2-3 days, similar to the responses of B cells in the absence of NK cells. Using the inhibitor of DNA synthesis mitomycin C, we determined that B cells and not NK cells were proliferating in cocultures of these lymphocytes stimulated with SAC. Activated B cells neither prevented the lysis of the isotope-labeled NK-sensitive target cell line K562 nor formed conjugates with NK cells, suggesting that cell contact was not a prerequisite for the effect. These studies have further expanded the functional repertoire of NK cells to include enhancer as well as suppressor and lytic activities.     

Properties and repeated use of a reversibly soluble-insoluble yeast lytic enzyme

Summary A yeast lytic enzyme was covalently immobilized on an enteric coating polymer, Eudragit S, that is reversibly soluble and insoluble (S-IS) depending on the pH of the reaction medium. The yeast lytic enzyme immobilized on Eudragit S (Y-E) showed a sharp response of solubility to slight changes in pH without decrease in enzymatic activity. The specific activity per amount of enzyme protein of Y-E for dry yeast cells was about two-thirds that of the native enzyme. In both lysis reactions of dry and pressed baker's yeast cells, changing the pH of the reaction medium from 7.0 to 4.8 at an appropriate interval allows the insoluble Y-E and the reaction products (soluble protein for dry yeast cells and invertase and soluble protein for pressed baker's yeast cells) to be repeatedly separated. The reaction method using a reversible S-IS enzyme is a promising procedure for repeated use of the enzyme in a heterogeneous reaction system containing yeast cells as a substrate.     

The Synergistic Effects among β-,3-Glucanases from Oerskovia sp. CK on Lysis of Viable Yeast Cells

Oerskovia sp. CK produced three types of β-1,3-glucanases designated as F-L, F-0 and F-2. F-L showed high lytic activity to viable yeast cells and weak activity to yeast glucan. F-0 and F-2 had little or no lytic activity and strong β-1,3-gIucanase activity.

F-0 or F-2 showed high lytic activities to yeast cells pretreated with small amounts of F-L which did not lysed the cells. Lytic activity of F-0 or F-2 also increased when cells were treated with alkaline pH or with both reducing agents and pH.

From these results, it is supposed that the ineffectiveness of F-0 or F-2 on the lysis of yeast cells might be attributed to a spatial inaccessibility of enzymes to the yeast glucan layer. However, the treatment of F-L, alkaline pH and reducing agents would bring about a modification of cells to give F-0 or F-2 access to the wall glucan and consequently the lysis of cells would occur.     

Cloning and expression in Escherichia coli of the gene for an Arthrobacter beta-(1----3)-glucanase.

When inserted in the correct orientation at the BamHI site of plasmid YRp7, an 8.6-kilobase BamHI fragment of Arthrobacter sp. strain YCWD3 DNA gave Escherichia coli HB101 cells harboring the recombinant plasmid pBX20 the ability to lyse bakers' yeast cell walls or bakers' yeast glucan in agar medium. An extract of the transformed E. coli cells contained an endo-beta-(1----3)-glucanase with the same activity pattern as that of glucanase I produced by Arthrobacter sp. strain YCWD3. Although part of the glucanase activity was contributed by apparently defective molecules, two protein species were found which had high lytic activity on yeast cell walls and adsorbed to microcrystalline cellulose, and both had a single constituent polypeptide with a molecular weight of about 55,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In these properties the protein species were indistinguishable from those glucanase I protein species of Arthrobacter sp. strain YCWD3 which we believe are nearly the intact molecule. We conclude that the cloned fragment of Arthrobacter sp. strain YCWD3 DNA contains the structural gene for glucanase I. A recombinant plasmid obtained by subcloning a PstI fragment of pBX20 into pBR322 caused the transformed E. coli cells to produce apparently defective glucanase molecules only. This observation serves as additional supporting evidence for our conclusion.     

The Cellular Ataxia Telangiectasia-Mutated Kinase Promotes Epstein-Barr Virus Lytic Reactivation in Response to Multiple Different Types of Lytic Reactivation-Inducing Stimuli

The Epstein-Barr virus (EBV) latent-to-lytic switch is mediated by the viral proteins BZLF1 (Z), BRLF1 (R), and BRRF1 (Na). Since we previously showed that DNA-damaging agents (including chemotherapy and irradiation) can induce EBV lytic reactivation and recently demonstrated that wild-type p53 contributes to lytic reactivation, we investigated the role of the ATM kinase during EBV reactivation. ATM phosphorylates and activates p53, as well as numerous other substrates involved in the cellular DNA damage response. Using an ATM inhibitor (KU55933), we found that ATM activity is required for efficient induction of EBV lytic gene expression by a variety of different stimuli, including a histone deacetylase (HDAC) inhibitor, the transforming growth factor β (TGF-β) cytokine, a demethylating agent (5-azacytidine), B cell receptor engagement with anti-IgG antibody, hydrogen peroxide, and the proteosome inhibitor bortezomib. In EBV-infected AGS (gastric) cells, knockdown of ATM, or p53, expression inhibits EBV reactivation. Conversely, treatment of these cells with nutlin-3 (which activates p53 and ATM) robustly induces lytic reactivation in a p53- and ATM-dependent manner. The ability of the EBV R and Na proteins to induce lytic reactivation in EBV-infected AGS cells is ATM dependent. However, overexpression of Z induces lytic gene expression in the presence or absence of ATM activity. Our results suggest that ATM enhances Z promoter activity in the context of the intact EBV genome and that p53 contributes to the ATM effect. Nevertheless, since we found that ATM inhibitors also reduce lytic reactivation in Burkitt lymphoma cells that have no p53, additional ATM substrates must also contribute to the ATM effect.     

Lysis of Yeast Cell Wall by Enzymes from Streptomycetes

This paper deals with yeast cell-wall lytic enzymes formed by Streptomyces with regard to the connection with the cell-wall structure.

In the first place, 29 organisms of β-glucanase-producing Streptomycetes were selected among 777 strains belonging to genus Streptomyces by means of a cylinder-plate method employing the yeast glucan as a substrate. As for these organisms, the depolymerizing activity against the yeast glucan was considered to be mainly due to β-1,3-glucanase activity. Against the heat-treated cell of bakers’ yeast, the crude enzymes merely showed poor lytic activities, however, in the combined employment with some protease preparations, especially with an alkaline protease from St. satsumaensis nov. sp., a remarkable increase of the lytic activities was demonstrated. On the other hand, the intact cell wall of bakers’ yeast, or both the heat-treated and the intact cells of Sacch. cerevisiae 18.29 strain were dissolved very easily by a sole action of β-glucanase or of protease, respectively. In consequence, it seemed that the lysis occurred with different mechanisms in response to differences of substrates. On this subject, the results of investigations and discussions were described in special measure. In addition, the possibility, that some other enzymes than β-glucanase or protease might concern to the lysis of the cell wall, was also investigated and discussed.     

Simple method for the isolation of astaxanthin from the basidiomycetous yeast Phaffia rhodozyma.

A method is described for the quantitative and, possibly, large-scale extraction of astaxanthin from the yeast Phaffia rhodozyma. The method utilizes extracellular enzymes produced by the bacterium Bacillus circulans WL-12, which partially digests the yeast cell wall and renders the carotenoid pigments extractable by acetone or ethanol. Complete recovery of astaxanthin from heat-killed P. rhodozyma cells was obtained after growing B. circulans WL-12 on these yeast cells for 26 h and then extracting the yeast-bacterium mixture with acetone. A bacteria-free lytic system, which gave quantitative extraction of astaxanthin from P. rhodozyma, was obtained by concentrating the culture broth from the growth of B. circulans WL-12 on P. rhodozyma cells. Hydrolytic enzyme activities detected in this concentrate included beta-(1 leads to 3)-glucanase, beta-(1 leads to 6)-glucanase, alpha-(1 leads to 3)-glucanase, xylanase, and chitinase. The lytic system was found to work most efficiently at pH 6.5 and with low concentrations of yeast.     

Simple method for the isolation of astaxanthin from the basidiomycetous yeast Phaffia rhodozyma.

A method is described for the quantitative and, possibly, large-scale extraction of astaxanthin from the yeast Phaffia rhodozyma. The method utilizes extracellular enzymes produced by the bacterium Bacillus circulans WL-12, which partially digests the yeast cell wall and renders the carotenoid pigments extractable by acetone or ethanol. Complete recovery of astaxanthin from heat-killed P. rhodozyma cells was obtained after growing B. circulans WL-12 on these yeast cells for 26 h and then extracting the yeast-bacterium mixture with acetone. A bacteria-free lytic system, which gave quantitative extraction of astaxanthin from P. rhodozyma, was obtained by concentrating the culture broth from the growth of B. circulans WL-12 on P. rhodozyma cells. Hydrolytic enzyme activities detected in this concentrate included beta-(1 leads to 3)-glucanase, beta-(1 leads to 6)-glucanase, alpha-(1 leads to 3)-glucanase, xylanase, and chitinase. The lytic system was found to work most efficiently at pH 6.5 and with low concentrations of yeast.