A Simple and Reliable Method for Hybridization of Homothallic Wine Strains of Saccharomyces cerevisiae

A procedure was developed for the hybridization and improvement of homothallic industrial wine yeasts. Killer cycloheximide-sensitive strains were crossed with killer-sensitive cycloheximide-resistant strains to get killer cycloheximide-resistant hybrids, thereby enabling hybrid selection and identification. This procedure also allows backcrossing of spore colonies from the hybrids with parental strains.     

Occurrence and Growth of Killer Yeasts during Wine Fermentation

Sixteen wine fermentations were examined for the presence of killer yeasts. Killer property and sensitivity to killer action were found in isolates of Saccharomyces cerevisiae but not in isolates of Kloeckera, Candida, Hansenula, and Torulaspora spp. Several killer and killer-sensitive strains of S. cerevisiae were differentiated by colony morphology, and this property was used to monitor their growth kinetics in mixed cultures in grape juice. Killer-sensitive strains died off within 24 to 48 h during mixed-strain fermentation. Killer action was demonstrated at pH 3.0 and pH 3.5 and over the range of 15 to 25°C but depended on the proportion of killer to killer-sensitive cells at the commencement of fermentation. The dominance of killer strains in mixed-strain fermentations was reflected in the production of ethanol, acetic acid, and glycerol.     

The incidence of killer activity of non-Saccharomyces yeasts towards indigenous yeast species of grape must: potential application in wine fermentation

Fourteen killer yeasts were assayed for their ability to kill species of yeast that are commonly associated with fermenting grape must and wine. A total of 147 of a possible 364 killer-sensitive interactions were observed at pH 4.5. Of the killer yeasts studied, Pichia anomala NCYC 434 displayed the broadest killing range. At a pH value comparable with those of wine ferments, pH 3.5, the incidence of killer-sensitive interactions was reduced by 700% across all the yeasts. Williopsis saturnus var. mrakii CBS 1707 exhibited the broadest killing range at the lower pH, killing more than half of the tester strains. Intraspecific variation in sensitivity to killer yeasts was observed in all species where more than one strain was tested. Also, in strains of Pichia anomala, Kluyveromyces lactis and Pichia membranifaciens, the three species in which more than one killer yeast was analysed, intraspecific variation in killer activity was observed.     

Transmission of killer activity into laboratory and industrial strains of Saccharomyces cerevisiae by electroinjection

The killer character was electrically introduced into protoplasts of three yeast strains. These were the killer-negative variant of the K1 killer strain Saccharomyces cerevisiae T 158 C (his-); the killer-sensitive laboratory strain S. cerevisiae AH 215 (leu-, his-); and the killer-sensitive industrial strain S. cerevisiae AS 4/H2 (rho-). The killer dsRNA used for electroinjection was isolated from the super-killer strain S. cerevisiae T 158 C. Optimum numbers of transformed cells were obtained after regeneration and selection in appropriate media if the protoplasts were exposed to three exponentially decaying field pulses of 18.2 kV/cm strength and 40 microseconds duration at 4 degrees C. In the case of the killer-negative variant of S. cerevisiae T 158 C the majority of the protoplasts were transformed, whereas in the case of the two other strains the yield of transformed clones was much less. This latter result is expected if the expression of the electroinjected dsRNA was diminished in these two strains. Gel electrophoresis of the dsRNA of the clones of the three strains supported the conclusion that the transformed clones exhibited killer activity. The transformed clones of all three species were stable.     

Construction of Killer Wine Yeast Strain

A double-stranded RNA plasmid which confers the superkiller phenotype was transferred into a wine yeast (Montrachet strain 522) and its leucine-requiring derivative (strain 694) by cytoduction, using the protoplast fusion technique. The killer wine yeast constructed completely suppressed the growth of killer-sensitive strains of Saccharomyces cerevisiae in yeast extract-peptone-glucose medium at pH 4.5, whereas the killer effect was somewhat decreased at pH 3.5. The wine yeast harboring the killer factor also inhibited the growth of killer-sensitive cells satisfactorily when it was grown in grape juice.     

The ecological role of killer yeasts in natural communities of yeasts

The killer phenomenon of yeasts was investigated in naturally occurring yeast communities. Yeast species from communities associated with the decaying stems and fruits of cactus and the slime fluxes of trees were studied for production of killer toxins and sensitivity to killer toxins produced by other yeasts. Yeasts found in decaying fruits showed the highest incidence of killing activity (30/112), while yeasts isolated from cactus necroses and tree fluxes showed lower activity (70/699 and 11/140, respectively). Cross-reaction studies indicated that few killer-sensitive interactions occur within the same habitat at a particular time and locality, but that killer-sensitive reactions occur more frequently among yeasts from different localities and habitats. The conditions that should be optimal for killer activity were found in fruits and young rots of Opuntia cladodes where the pH is low. The fruit habitat appears to favor the establishment of killer species. Killer toxin may affect the natural distribution of the killer yeast Pichia kluyveri and the sensitive yeast Cryptococcus cereanus. Their distributions indicate that the toxin produced by P. kluyveri limits the occurrence of Cr. cereanus in fruit and Opuntia pads. In general most communities have only one killer species. Sensitive strains are more widespread than killer strains and few species appear to be immune to all toxins. Genetic study of the killer yeast P. kluyveri indicates that the mode of inheritance of killer toxin production is nuclear and not cytoplasmic as is found in Saccharomyces cerevisiae and Kluyveromyces lactis.     

Role of killer character in spontaneous fermentations from NW Spain: ecology,distribution and significance

Summary The presence of killer, resistant and sensitive populations of Saccharomyces cerevisiae along the successive stages of alcoholic fermentation in three vineyards from NW Spain was investigated. The global results showed that approximately 71% were killer-sensitive strains, 6.6% were killer-resistant, and 22.4% belonged to the k₂ killer type. However, there were important differences concerning the presence of the three phenotypes during successive stages of fermentation. Killer populations were isolated at the highest percentages in samples from must and from active alcoholic fermentations. Killer-resistant strains steadily increased during fermentation. Additionally, important differences in these populations were observed among the three vineyards. In this sense, the presence of killer populations was more important in samples from the vineyards with higher average pH values of the must. However, great differences in the distribution of killer phenotype between successive vintages (with the same initial pH of must) belonging to the same vineyard implies the presence of other factors effecting killer behaviour. Offprint requests to: T. G. Villa     

Intergeneric transfer of deoxyribonucleic acid killer plasmids, pGKl1 and pGKl2, from Kluyveromyces lactis into Saccharomyces cerevisiae by cell fusion

Two novel linear deoxyribonucleic acid plasmids, pGKl1 and pGKl2, were isolated from the yeast Kluyveromyces lactis. K. lactis strains harboring the pGK1 plasmids killed a certain group of yeasts, including Saccharomyces cerevisiae, Saccharomyces italicus, Saccharomyces rouxii, K. lactis, Kluyveromyces thermotolerans, Kluyvermyces vanudenii, Torulopsis glabrata, Candida utilis, and Candida intermedia. In this experiment, the pGKl1 and pGKl2 plasmids were intergenerically transferred from a K. lactis killer strain into a non-killer (killer-sensitive) strain of S. cerevisiae by the use of a protoplast fusion technique. Both of the pGKl plasmids replicated autonomously and stably in the new host cells of S. cerevisiae and could coexist with the resident 2-micrometers deoxyribonucleic acid plasmid. The S. cerevisiae cells which accepted the pGKl plasmids expressed the same killer phenotype as that of the donor K. lactis killer and became resistant to the K. lactis killer. The pGKl plasmids existing in the S. cerevisiae cells were cured by treatment with ethidium bromide, and the killer and resistance characters were simultaneously lost. From there results, it was concluded that both the killer and the resistance genes are located on the pGKl plasmids.     

A mathematical model for toxin accumulation by killer yeasts based on the yeast population growth

The accumulation of toxin by killer yeast populations is modelled starting from a mechanistic approach that explains the toxin production in terms of yeast population growth, and takes into account the environmental inactivation of the toxin. A modified Richard's general equation for limited growth is used to define the function that describes the toxin produced in relation to the yeast biomass increase. The relationship between the rates of cell and toxin production is explicitly shown, and the implications of the resulting proportionality factor are discussed. The model parameters have been adjusted and the model has been validated using experimental data of growth and toxin accumulation from cultures of Pichia membranaefaciens in two different media. The differences between both types of cultures are analysed on the basis of parameter estimates and the predicted rate of toxin production per cell. The results support the hypothesis that biomass production and toxin synthesis are controlled in different ways; they also suggest that the composition of the medium could have a distinct effect on toxin synthesis. Model assumptions are discussed in comparison with a previous model for killer-sensitive interaction of Saccharomyces cerevisiae strains.     

Characterization of cytotoxic cells from reovirus-infected SCID mice: activated cells express natural killer- and lymphokine-activated killer-like activity but fail to clear infection.

Severe combined immune deficient (SCID) mice infected orally with reovirus type 1/L die of hepatitis. Leukocytes bearing the cell surface antigens Thy-1.2 and asialoGM-1 (AsGM1) accumulate in the livers of infected animals. These cells display lytic activity toward natural killer-sensitive (YAC-1) and -resistant (P815) cell lines and murine hepatoma line Hepa 1/A1. Although these cells have the capacity to lyse infected hepatoma targets, they cannot clear the virus.     

Expression of pGKL killer 28K subunit in Saccharomyces cerevisiae: identification of 28K subunit as a killer protein.

Saccharomyces cerevisiae and other yeast cells harboring the linear double stranded (ds) DNA plasmids pGKL1 and pGKL2 secrete a killer toxin consisting of 97K, 31K and 28K subunits into the culture medium (EMBO J. 5, 1995-2002 (1986), Nucleic Acids Res., 15, 1031-1046 (1987]. The 28K subunit of the killer toxin was successfully expressed in S. cerevisiae when it was cloned on a circular plasmid with its putative promoter region replaced with that of S. cerevisiae chromosomal genes. The expression of the 28K subunit of the killer toxin in killer-sensitive cells resulted in the death of the host cells. This killing activity by the 28K subunit was prevented by the expression of the killer immunity, indicating that the killing activity of the killer toxin complex was carried out by the 28K subunit. Although the 28K subunit was synthesized as a intact precursor protein with its own signal sequence, it was not secreted into the culture medium but remained in the host cells. This indicated that 28K subunit killed host cells from inside of the cells rather than from outside. We further suggested that 28K killer subunit without 97K and 31K subunits did not kill the killer-sensitive cells from outside.     

Establishment and functional characterization of human herpesvirus 6-specific CD4+ human T-cell clones.

In order to clarify the protective immune responses against a newly identified herpesvirus, human herpesvirus 6 (HHV-6), we established HHV-6-specific human T-cell clones and examined their functional properties. Five CD3+CD4+CD8- T-cell clones, which proliferated in response to stimulation with two different strains of HHV-6 in the presence of autologous antigen-presenting cells but not with herpes simplex virus type 1 or human cytomegalovirus, were established from peripheral blood lymphocytes of a healthy individual. The proliferative response of all T-cell clones to HHV-6 antigen was inhibited by addition of anti-HLA-DR monoclonal antibody, indicating that these clones were human leukocyte antigen (HLA) class II DR restricted. Of the five clones, two lysed HHV-6-infected autologous lymphoblasts, but not HHV-6-infected allogeneic cells or natural killer-sensitive K562 cells (group 1); one showed cytotoxicity against HHV-6-infected autologous lymphoblasts as well as HHV-6-infected allogeneic cells and K562 cells (group 2); and the remaining two showed no cytotoxic activity (group 3). The cytotoxic activity of group 1 was inhibited by addition of anti-HLA-DR monoclonal antibody to the culture, whereas this monoclonal antibody had no effect on the cytotoxicity of group 2 and did not induce the cytotoxicity of group 3. Perforin, which is one of the mediators of cytotoxicity, was abundantly expressed in group 1 and 2 clones. Moreover, all groups of clones produced gamma interferon after culture with antigen-presenting cells followed by HHV-6 antigen stimulation. These results suggest that HHV-6-specific CD4+ T cells have heterogeneous functions.     

A comparison of the suppressor and cytotoxic activities of the blood mononuclear cells during the adoptive immunotherapy of cancer patients using lymphokine-activated killers with a low dose of recombinant interleukin-2]

The suppressor and cytotoxic activities of mononuclear blood cells (MNC) were studied in 70 cancer patients (melanoma, renal carcinoma) undergoing adoptive immunotherapy (AIT). In the course of AIT the patients' MNC were treated in vitro with the recombinant interleukin-2 (RIL-2) in order to generate the lymphokine-activated killer (LAK) cells. Then patients received i/v 2.5-13.6 10(9) autologous LAK cells and RIL-2 (75000 u). Each course included 2-3 repeated infusions; the patients received 1-5 courses according to their clinical conditions. The cytotoxic activity of MNC was assessed by a routine method; but for evaluation of the suppressor activity we used a new technique based on separation of MNS populations in the Percoll gradient. Twenty-four hours after the completion of each AIT course the suppressor activity of MNC decreased drastically up to the zero level in some patients. The decrease in the suppressor activity inversely correlated with the rise in the cytotoxic activity on Mel-I (LAK-sensitive) and K-562 (natural killer-sensitive) target cells. The level of cytotoxicity in some patients reached 51.2%.     

Effect of killer toxin K1 on yeast membrane potential reported by the diS-C3(3) probe reflects strain-and physiological state-dependent variations

The rate and extent of uptake of the fluorescent probe diS-C₃(3) reporting on membrane potential inS. cerevisiae is affected by the strain under study, cell-growth phase, starvation and by the concentration of glucose both in the growth medium and in the monitored cell suspension under non-growth conditions. Killer toxin K1 brings about changes in membrane potential. In all types of cells tested,viz. in glucose-supplied stationary or exponential cells of the killer-sensitive strain S6/1 or a conventional strain RXII, or in glucose-free exponential cells of both strains, both active and heat-inactivated toxin slow down the potential-dependent uptake of diS-C₃(3) into the cells. This may reflect “clogging” of pores in the cell wall that hinders, but does not prevent, probe passage to the plasma membrane and its equilibration. The clogging effect of heat-inactivated toxin is stronger than that exerted by active toxin. In susceptible cells,i.e. in exponential-phase glucose-supplied cells of the sensitive strain S6/1, this phase of probe uptake retardation is followed by an irreversible red shift in probe fluorescence maximumλ _max indicating damage to membrane integrity and cell permeabilization. A similar fast red shift inλ _max signifying lethal cell damage was found in heat-killed or nystatin-treated cells.     

Heterogeneity of allogeneic restriction of human cytotoxic T cell clones specific for Epstein Barr virus

Clones of human cytotoxic T cells (Tc) specific for Epstein Barr virus (EBV) were isolated from peripheral blood lymphocyte (PBL) cultures stimulated repeatedly with autologous EBV-transformed lymphoblastoid cell line (LCL) cells in vitro. The method employed to clone EBV-specific Tc was a limiting dilution technique utilizing T cell growth factor (TCGF). The EBV specificity of Tc clones was determined by showing that they were significantly cytotoxic for autologous LCL cells but not for either autologous PBL or (natural killer-sensitive) K-562 cells. Eight EBV-specific Tc clones derived from a single donor exhibited distinct cytotoxic patterns against allogeneic LCL targets. Two clones were cytotoxic to LCL targets sharing both HLA-A26 and B15 antigens with effectors, and killing by two other clones was strongly restricted to autologous LCL cells. The four remaining clones showed cytotoxicities against various allogeneic LCL targets irrespective of HLA antigen expression. Eight EBV-specific Tc clones derived from a second donor also exhibited a wide spectrum of cytotoxicity to allogeneic LcL targets. We conclude that EBV-specific Tc, induced in vitro, consist of a number of clones with respect to restrictions imposed by the major histocompatibility complex. The determinants regulating these restrictions may include not only private HLA antigenic determinants that are defined by the HLA serotyping, but also undefined HLA antigenic determinants.     

Human cytotoxic T cell clones directed against herpes simplex virus-infected cells. I. Lysis restricted by HLA class II MB and DR antigens

In contrast to general findings that mouse and human cytotoxic T lymphocytes (CTL) are restricted in cytotoxic activity by major histocompatibility complex (MHC) class I antigens, we previously found that some herpes simplex virus (HSV) type I-infected cells that shared no HLA class I antigens with the HSV-1-stimulated lymphocytes were lysed. In this study, we addressed the question of the role of HLA antigens in human T cell-mediated lysis of HSV-1-infected cells by generating clones of HSV-1-directed CTL from two HSV-1-seropositive individuals. CTL clones that lysed autologous HSV-1-infected lymphoblastoid cell lines (LCL), but not natural killer-sensitive K562 cells or uninfected or influenza virus-infected LCL, were tested for cytotoxicity against a panel of allogeneic HSV-1-infected LCL. Clone KL-35 from individual KL lysed only HSV-1-infected LCL sharing the HLA class II MB1 antigen with KL. With all four CTL clones isolated from individual PM, only HSV-1-infected LCL sharing DR1 with PM were lysed. Monoclonal antibody s3/4 (directed against MB1 ), but not TS1/16 or B33 .1 (directed against a DR framework determinant), blocked lysis of autologous HSV-1-infected cells by KL-35. In contrast, B33 .1, but not s3/4, blocked lysis of autologous HSV-1-infected cells by the PM CTL clones but not by KL-35. Together, these results indicate that our five human CTL clones which are directed against HSV-1-infected cells, and which are all OKT3+, OKT4+, OKT8-, are restricted in lytic activity by HLA class II MB and DR antigens. These results suggest that the HLA D region-encoded class II antigens may be important in the recognition and destruction of virus-infected cells by human CTL.     

Inhibition of cytolytic T lymphocyte maturation with ornithine, arginine, and putrescine

L-Ornithine was shown to inhibit the development of cytolytic T lymphocytes (CTL) in mixed lymphocyte cultures (MLC). Lymphokines were unable to reverse the suppressive effect, and cytotoxic activity was not revealed by coupling ornithine-inhibited MLC cells to target cells with phytohemagglutinin (PHA). If addition of ornithine to MLC were delayed, sensitivity of CTL to inhibition was reduced after 24 hr and lost by 48 hr. Suppression of CTL development was not due to a toxic effect. MLC washed free of ornithine after 3 days produced detectable cytolytic activity within 24 hr of secondary culture, and to the same degree as the uninhibited MLC control within 48 hr. Cytotoxic cells generated in secondary cultures were Lyt-2+, did not kill the natural killer-sensitive YAC-1 cell line, and were shown to be antigen-specific by virtue of the findings that cytolysis and cold target inhibition were observed only with cells carrying the original, inducing H-2 haplotype. Cytolysis of target cells by normal CTL effector cells was not inhibited by L-ornithine. MLC depleted of accessory cells so that CTL activation was dependent upon addition of lymphokines remained susceptible to inhibition by ornithine. Our findings indicate that in the ornithine-inhibited MLC, CTL precursors undergo clonal expansion, but their maturation is arrested at a precytolytic stage. L-Arginine and putrescine also suppressed generation of CTL in primary MLC, and cells recovered from arginine- and putrescine-inhibited MLC developed control levels of CTL within 48 hr of secondary culture. Inhibition by putrescine was observed in tissue culture medium supplemented with human serum but not with fetal calf serum, presumably due to the presence of diamine oxidase activity in fetal calf serum. Similar to ornithine, the suppressive effects of arginine and putrescine on T lymphocytes were apparently selective for CTL because they did not inhibit mitogen activation with concanavalin A or the production of interleukin 2 and interleukin 3. These findings are consistent with a hypothesis that the inhibitory effects of ornithine, arginine, and putrescine are mediated by polyamines, and exerted on the differentiative stage of CTL development.     

阴道中益生特性乳杆菌的分离与功能评价

目的 分离健康女性阴道中的乳杆菌并鉴定其益生特性,为开发治疗妇科疾病的复方益生菌制剂提供新型菌株。方法 采集健康女性阴道分泌物并分离筛选乳杆菌,通过16S rDNA序列分析鉴定乳杆菌分离株,并对其产酸性能、产H2O2能力、抑菌能力、产生物膜能力进行检测。结果 从50名健康女性阴道内共分离出179株乳杆菌,其中卷曲乳杆菌101株、詹氏乳杆菌42株、格氏乳杆菌26株、植物乳杆菌5株、唾液乳杆菌3株以及干酪乳杆菌2株。179株乳杆菌中有146株具有产酸能力,发酵液pH值的最低的5株菌分别为卷曲乳杆菌J3、卷曲乳杆菌J8、詹氏乳杆菌J87,植物乳杆菌J75以及格氏乳杆菌J35,其pH分别为4.20、4.23、4.24、4.26及4.36;产H2O2弱阳性菌株有87株、阳性有37株、强阳性有9株,这9株菌分别为卷曲乳杆菌J3、卷曲乳杆菌J8、卷曲乳杆菌J20、詹氏乳杆菌J87,詹氏乳杆菌J90、詹氏乳杆菌J15、格氏乳杆菌J11、植物乳杆菌J75、植物乳杆菌J69以及植物乳杆菌J40;能拮抗大肠埃希菌的菌株有115株、拮抗金黄色葡萄球菌的有84株、拮抗白假丝酵母的有52株;经统计,对三者同时有拮抗作用且作用最强的只有6株,分别为卷曲乳杆菌J3、卷曲乳杆菌J50、卷曲乳杆菌J62、詹氏乳杆菌J87、詹氏乳杆菌J16和格氏乳杆菌J66;不同乳杆菌产生物膜能力数值范围在1.0~5.4,卷曲乳杆菌、詹氏乳杆菌、干酪乳杆菌的生物被膜形成能力显著高于其他三种菌（P<0.05）。在全部179株菌中,卷曲乳杆菌J3和詹氏乳杆菌J87既具有强的产酸能力和产过氧化氢能力,又有较强抑菌活性,同时产生物膜能力也最强。结论 卷曲乳杆菌J3和詹氏乳杆菌J87具有优良的生物学特性,有望成为用于治疗妇科疾病微生态制剂的备选菌株。     

Localization of genes conferring resistance to selected groups of antibiotics in methicillin-resistant strains of Staphylococcus aureus

Localization of genes conferring resistance to MLS, tetracyclines, chloramphenicol, gentamycin and neomycin in 80 MRSA strains isolated from hospital specimens was determined. The obtained results were compared to DNA patterns of the examined strains after digestion with SmaI and separation in pulsed field electrophoresis (PFGE). It was shown that genes of resistance to MLS (ErmI+) in the case of 13 strains were located on chromosome and in the case of 37 strains on plasmids (16 strains had ErmI+ and 21 strains had ErmI-). Genes determining resistance to tetracyclines were localised on chromosome in the case of 39 (23 strains possessed TetK, 11 strains had TetM and 5 strains possessed both TetK and TetM determinants) and in the case of 32 strains on plasmids. Chloramphenicol resistance genes were localised on plasmids in all 30 resistant strains. Genes conferring resistance to gentamycin were present in 31 of the investigated strains on chromosome and in two strains on plasmids. Neomycin resistance genes were plasmid in 34 strains. It was shown that the localization of the resistance genes and the PFGE patterns of the investigated strains were highly correlated.     

替加环素与多粘菌素B对泛耐药鲍曼不动杆菌体外研究

目的为治愈耐舒普深的泛耐药鲍曼不动杆菌（PDR-Ab）提供新药。方法替加环素采用二倍琼脂稀释法,多粘菌素B用E-test条法测分离目标菌株100株的最低抑菌浓度（M IC）,并用WHONET 5.4软件分析数据。结果多粘菌素B对耐舒普深的泛耐药鲍曼不动杆菌株的M IC值分布情况为：1.5 mg/L为2株,1.0 mg/L为9株,0.75 mg/L为9株,0.5 mg/L为38株,0.38 mg/L为34株,0.25 mg/L为8株,均为敏感;替加环素对耐舒普深的泛耐药鲍曼不动杆菌株的M IC值分布情况为：≥32 mg/L为0株、16 mg/L为2株、8 mg/L为3株、4 mg/L为4株、2 mg/L为6株、1 mg/L为9株、0.5 mg/L为30株、0.25 mg/L为33株、0.125 mg/L为9株、0.06 mg/L为2株、0.03 mg/L为2株,敏感率为95.0%,中敏率为3.0%,耐药率为2.0%。结论替加环素或多粘菌素B是目前对耐舒普深的泛耐药鲍曼不动杆菌最有效药物之一。