去甲基万古霉素菌种低温冷冻、冷干保藏条件优化及10 年菌种保藏效果

【目的】针对去甲基万古霉素产生菌不耐保藏的问题,改进菌种保藏方法,对超低温液氮保藏、-80°C低温冷冻保藏、冷干保藏方法跟踪考察10年保藏稳定性,评价不同保藏方法对去甲基万古霉素产生菌的保藏适用性。【方法】采用甘油作基础保护剂进行超低温液氮保藏和-80°C低温冷冻保藏,采用脱脂牛奶作基础保护剂进行冷干保藏,针对超低温液氮保藏进行降温速率考察,研究非渗透性冷冻保护剂海藻糖、聚乙烯吡咯烷酮(PVP)等对3种保藏方法的冻存影响,对优选出的保藏方法进行10年跟踪考察。【结果】3种保藏方法冻后菌种存活率依次为:-80°C低温冷冻保藏超低温液氮保藏冷干保藏。液氮保藏最适降温速率为快速冷冻。优选出最佳保护剂配方:超低温液氮保藏为甘油8.0%,海藻糖3.5%;-80°C低温冷冻保藏为甘油6.0%,PVP 5.0%;冷干保藏为脱脂牛奶,6.0%海藻糖。采用优化保藏条件,液氮保藏10年存活率稳定在70.6%,菌种发酵水平为入藏水平的92.9%。【结论】在优化条件下,尤以超低温液氮保藏适合于去甲基万古霉素产生菌长期保藏。     

Reactivation of aerobic and anaerobic ammonium oxidizers in OLAND biomass after long-term storage

The biomass of an oxygen-limited autotrophic nitrification/denitrification (OLAND) biofilm reactor was preserved in various ways to find a storage method for both aerobic and anaerobic ammonium-oxidizing bacteria (AerAOB and AnAOB). Storage occurred at −20°C with and without glycerol as cryoprotectant and at 4 and 20°C with and without nitrate as redox buffer. After 2 and 5 months, reactivation of AerAOB and AnAOB was achieved with the biomass stored at 4°C with and without nitrate and at 20°C with nitrate. Moreover, the presence of the AerAOB and AnAOB was confirmed with fluorescent in situ hybridization (FISH). Preservation in a nitrate environment resulted in a lag phase for the AnAOB reactivation. The supplied nitrate was denitrified during storage, and a real-time polymerase chain reaction with nitrifying and denitrifying genes allowed to estimate that at least 1.0 to 6.0% of the OLAND biofilm consisted of denitrifiers. It was concluded that reactivation after long-term storage is possible and that preservation at 4°C without nitrate addition is the recommended storage technique. The possibility to store OLAND biomass will facilitate research on AnAOB and can overcome larger-scale start-up and inhibition problems of novel nitrogen processes involving AnAOB.     

Cryopreservation at −80°C of Agaricus blazei on rice grains

The preservation of Agaricus blazei is generally done by mycelial subculturing, but this technique may cause genetic degenerations. Despite this, there is not an efficient protocol established to preserve this fungus and cryopreservation could be an alternative. This study aimed to evaluate two freezing protocols for cryopreservation at −80°C of A. blazei strains. Five fungus strains grown on rice grains with husk and were transferred to glycerol (10%) in cryovials. Next, the cryovials were submitted to two freezing temperature protocols: (1) cryopreservation starting at 25°C, then at 8°C for 30 min and kept at −80°C; (2) cryopreservation starting at 25°C, then 8°C for 30 min, −196°C for 15 min and kept at −80°C. After 1 year of cryopreservation, the cryovials were thawed in a water bath at 30°C for 15 min and transferred to malt extract agar medium. It was concluded that the one-year cryopreservation process of A. blazei, grown on rice grains and cryopreserved at −80°C in glycerol 10%, is viable. The slow freezing, from 8 to −80°C, is effective whereas the fast freezing, from 8 to −196°C and then to −80°C, is ineffective. The different genetic characteristics among the strains of this fungus do not interfere in the cryopreservation process.     

Storage and preservation of temperate mushroom cultures, agaricus bisporus and pleurotus Florida

Two temperate mushroom cultures namely Agaricus bisporus (U-3) and Pleurotus florida (PAU-5) were evaluated for their physiological (linear growth and biomass production), biochemical (β-1,4 endoglucanase production) and fruiting behaviour after preservation in 10% (v/v) glycerol and storage at room temperature (25–35°C), −20°C and −196°C for 6 months with the objective of establishing the recovery/changes in these fungi after storage. Studies indicated that the viability and recovery of A. bisporus and P. florida is affected by the storage conditions. Both the fungi could be best stored in liquid nitrogen for longer durations but for regular use, conventional sub-culturing was appropriate.     

RNA preservation of Antarctic marine invertebrates

Fifteen species of marine invertebrate commonly occurring in the near-shore environment of Rothera base, Antarctica, were used to test tissue sample storage protocols with regard to preservation of RNA integrity. After animal collection, the tissues were either immediately extracted for RNA or stored at −80°C after having been, either directly flash frozen in liquid nitrogen or preserved in a commercial RNA storage solution, for extraction in the UK. In four cases, direct flash freezing produced enhanced RNA integrity compared with samples in the commercial storage solution. A subset of samples were further tested for the preferred temperature of storage in the commercial reagent. RNA integrity was well preserved at both +4 and −20°C over periods of 2 months, but degradation was rapid in tissues stored at room temperature. Eight out of the fifteen species only produced a single ribosomal band on gel electrophoresis. This survey provides a guide for tissue transport of Polar cold water marine invertebrates.     

Production of lyophilized culture ofLactobacillus acidophilus with preserving cell viability

Optimal lyophilization process was developed for manufacturing the dried product ofLactobacillus acidophilus with high cell viability. Three major factors, freezing rate, specific surface area of samples, and stabilizer type and their synergy were shown to play a crucial role in the development of an effective lyophilization process. Finally we found an optimal combination among three process parameters mentioned above: an exceptionally high cell survival percentage of 90% was achieved using the 8.28 cm⁻¹ specific surface area of samples, slow freezing rate, and a stabilizer composition of 4% skim milk+1% glycerol +0.1% calcium chloride.     

Alternative methods for sampling and preservation of photosynthetic pigments and tocopherols in plant material from remote locations

Current methods for the study of pigments involve freezing in liquid nitrogen and storage at −80°C or lyophilization until HPLC analysis. These requirements greatly restrict ecophysiological research in remote areas where such resources are hardly available. We aimed to overcome such limitations by developing several techniques not requiring freezing or lyophilization. Two species with contrasting foliar characteristics (Olea europaea and Taraxacum officinale) were chosen. Seven preservation methods were designed, optimized and tested in a field trial. These protocols were compared with a control immediately frozen after collection. Pigments and tocopherols were analysed by HPLC. Main artefacts were chlorophyll epimerization or phaeophytinization, carotenoid isomerization, altered de-epoxidation index and tocopherol degradation. Among all methods, sample desiccation in silica gel provides robust samples (pigment composition was unaffected by storage time or temperature) and almost unaltered pigment profiles, except for a shift in epoxidation state. Although liquid nitrogen freezing and subsequent lyophilization or freezer storage were preferred, when these facilities are either not available or not suitable for long-distance transport, desiccation with silica gel, passive extraction in acetone and/or storage of fresh samples in water vapour saturated atmospheres enable a complete pigment characterization. Silica gel is advisable for long-term sample conservation.     

Effects of spray-drying and storage on astaxanthin content of <Emphasis Type="Italic">Haematococcus pluvialis</Emphasis> biomass

The main objective of this study was to evaluate the stability of astaxanthin after drying and storage at different conditions during a 9-week period. Recovery of astaxanthin was evaluated by extracting pigments from the dried powders and analysing extracts by HPLC. The powders obtained were stored under different conditions of temperature and oxygen level and the effects on the degradation of astaxanthin were examined. Under the experimental conditions conducted in this study, the drying temperature that yielded the highest content of astaxanthin was 220°C, as the inlet, and 120°C, as the outlet temperature of the drying chamber. The best results were obtained for biomass dried at 180/110°C and stored at −21°C under nitrogen, with astaxanthin degradation lower than 10% after 9 weeks of storage. A reasonable preservation of astaxanthin can be achieved by conditions 180/80°C, −21°C nitrogen, 180/110°C, 21°C nitrogen, and 220/80°C, 21°C vacuum: the ratio of astaxanthin degradation is equal or inferior to 40%. In order to prevent astaxanthin degradation of Haematococcus pluvialis biomass, it is recommended the storage of the spray dried carotenized cells (180/110oC) under nitrogen and −21°C.     

Maintenance ofRhodotorula rubra isolated from liquid samples of gold mine effluents

TheRhodotorula rubra strain isolated from waste waters of a gold mining plant has demonstrated the ability to grow in the presence of cyanide. The maintenance of this strain in complex organic media leads to a loss of this ability. To preserve the cyanide resistance ofR. rubra we tested the following maintenance methods: subculturing in sterile distilled water, freezing at −20, −40, −70°C, liquid nitrogen freezing and the paper replica method. The ability to grow in the presence of cyanide was preserved and a higher viability level was observed for cells maintained frozen at −70°C, in liquid nitrogen and by the paper replica method. Preservation in distilled water resulted in the lowest viability after twelve months of storage.     

Cryopreservation of the SB-M photosynthetic soybean [Glycine max (L.) Merr.] suspension culture

Summary The photosynthetic cell suspension culture of soybean [Glycine max (L.) Merr. cv. Corsoy] (SB-M) was successfully cryopreserved in liquid nitrogen using a preculture and controlled freezing to −40° C (two-step) freezing method. The effective method included a preculture treatment with gradually increasing levels of sorbitol added to the 3% sucrose already present in the medium. The cells were then placed in a cryoprotectant solution [10% DMSO (dimethylsulfoxide) and 9.1% sorbitol, or 10% DMSO and 8% sucrose], incubated for 30 min at 0° C, cooled at a rate of 1° C/min to −40° C, held at −40° C for 1 h, and then immersed directly into liquid nitrogen. The cells were thawed at 40° C and then immediately placed in liquid culture medium. The cell viabilities immediately after thawing were 75% or higher in all cases where cell growth resumed. The original growth rate and chlorophyll level of the cells was recovered within 40 to 47 d. If the sorbitol level was not high enough or the preculture period too short, growing cultures could not be recovered. Likewise, survival was not attained with cryoprotectant mixtures consisting of 15% DMSO, 15% glycerol, and 9.1% sucrose or 15% glycerol and 8% sucrose. The successful method was reproducible, thus allowing long-term storage of this and certain other unique photosynthetic suspension cultures in liquid nitrogen.     

保藏温度对厌氧氨氧化颗粒污泥特性的影响

为考察保藏温度对厌氧氨氧化污泥颗粒特性的影响,同时优化保藏厌氧氨氧化颗粒污泥温度参数,本试验首先通过HRT调控进水基质负荷培养厌氧氨氧化颗粒污泥,并采用KHCO3和Na HCO3交替提供无机碳源。然后分别在–40℃、4℃、(27±4)℃室温和35℃条件下避光保藏。结果表明,Na HCO3可代替KHCO3作为厌氧氨氧化菌生长的无机碳源。相比于其他保藏温度,4℃保藏能够较好地维持生物量和生物活性,同时能较好地维持颗粒污泥的沉降性能、颗粒污泥和细胞结构完整性。在保藏过程中,一阶衰减指数模型可拟合厌氧氨氧化颗粒污泥生物量及活性的衰减过程,衰减指数与胞溶程度正相关,而且生物量的衰减比活性的衰减更快。同时,颗粒污泥胞外聚合物中蛋白质与多糖的比值(PN/PS)和血红素不能有效指示保藏过程中颗粒污泥沉降性能和活性的变化,而生物活性与胞溶程度呈负相关。     

A simple method for the freeze-preservation of zoospores of the green macroalga Enteromorpha intestinalis

Settled zoospores of the green macroalga Enteromorpha intestinalis were subjected to several different freezing and storing treatments at both cryogenic and non-cryogenic temperatures after which their viability was assessed using a spore germination bioassay. Three different cooling rates were tested: slow cooling at –1°C min⁻¹ and –0.5°C min⁻¹ to end temperatures in the range –20°C to –40°C, and a two-step procedure whereby the spores were frozen to –30°C at a rate of –1°C min⁻¹ prior to immersion in liquid nitrogen at –196°C. Spore viability was also investigated using the cryoprotectants glycerol and dimethyl suphoxide (DMSO), a reduced saline medium and various storage times. In the majority of experiments, the use of a cryoprotectant during the freezing process significantly increased the viability of the spores, with DMSO affording slightly greater protection than glycerol. All treatments produced high viabilities (ranging from 75.3–100.0%) after 5-min storage at the different end temperatures. However, progressively longer storage up to 7 days generally resulted in a marked reduction in viability. This was with the exception of spores frozen in a reduced saline medium; a medium of 75% seawater and either 5 or 10% DMSO greatly increased spore viability, with values of > 40% recorded for spores stored at –20°C for up to 5 weeks. This revised version was published online in July 2006 with corrections to the Cover Date.     

Fruit-body production of test cultures ofFlammulina velutipes preserved for seven years by freezing at three different temperatures

Two strains ofFlammulina velutipes were cultured on PDA plates, and mycelial disks punched out using a cork borer were used for preservation. Five disks of a strain were put into a vial containing one of three cryoprotectants, 10% glycerol, 5% DMSO or 10% polyethylene glycol. Vials were then stored for 7 yr at −20°C, −85°C or liquid nitrogen temperature. The mycelial growth on PDA plates of the cryopreserved mycelial disks, as well as the usual subcultures, were tested two times. After the second test, spawns were prepared for fruit-body production tests by bottle cultivation from selected plates of the second growth tests. The yields of fruit-bodies varied among the cultures derived from the mycelial disks of the same strain preserved under different conditions. Variation in yields was observed even among the mycelial disks preserved at liquid nitrogen temperature, although the range of yield variation was narrower. The yield variation was obvious for the cultures which showed large retardation in the growth test. Four mycelial disks out of the six preserved at −20°C showed higher yields than those preserved at other temperatures. Among the cultures derived from strain FMC224, the control cultures preserved by subculture showed the lowest yield.     

Production of normal young following transfer of mouse embryos obtained by in vitro fertilization using cryopreserved spermatozoa

Spermatozoa from cauda epididymis of mature mice were suspended in preservation solution (Dulbecco's PBS containing raffinose in combination with glycerol, DMSO or skim milk as freezing protective agents). The suspension was frozen by the dry ice-alcohol method and preserved for 1-120 days in liquid nitrogen (-196 degrees C). Highest sperm viability after thawing was obtained with a combination of 10% raffinose and 5% glycerol or with a combination of 10% raffinose and 10% DMSO. These frozen thawed sperm were found to have fertilizing capacity when used for in vitro fertilization. The 2-cell embryos obtained through the above procedures developed into normal pups at a high rate when transferred into the oviducts of pseudopregnant female mice.     

Preservation by freezing of potentially probiotic strains ofLactobacillus rhamnosus

The aim of this work was to detect the best conditions to preserve by freezing potentially probiotic strains ofLactobacillus rhamnosus isolated from food. Four strains isolated from Parmigiano Reggiano cheese, the commercial strainLactobacillus GG and the type strain ATCC 7469T were used in the present study. Two different pre-incubation times (5 and 24 h), three protective media (Skim milk, Skim milk plus glucose and MRS plus glycerol) and two storage temperatures (?20 and ?80 °C) were used for a preservation period of 90 days. A sensible loss of survival of the strains was detected and the acidifying activity decreased depending on the different factors analysed. Moreover, plate counts performed in MRS plus bile salts evidenced that a considerable percentage of cells suffers damages deriving from cold. This study showed that the growth phase of the cells plays an important role for the resistance to the storage by freezing. Finally, Skim milk had the best protective action, showing the highest activity at ?80 °C.     

Studies on Destabilization of Caseinate Complex during Frozen Storage of Milk

Unpasteurized skim milk was storaged in a frozen state at ?7°C or ?20°C for up to several months. There was no increase of non casein and non protein nitrogens, but a slight increase of free tyrosine and a slight decrease of alkaline phosphatase activity were detected when storage period was prolonged. Destabilization occurred solely in caseinate complex, but non micellar casein appeared to be stable.

The contents of calcium and inorganic phosphate in the caseinate complex separated by ultracentrifugation were increased appreciably after frozen storage. The viscosity characteristics of frozen storaged skim milk was also investigated.

Caseinate complex was ultracentrifugally separated from skim milk before and after frozen storage, and then lyophilized. Skim milk itself was also lyophilized before and after frozen storage. Dispersibility was examined on the reconstituted suspension of the lyophilized samples.

The lyophilized sample from frozen storaged milk was much less dispersible than the lyophilized control sample prepared before frozen storage. However, when lyophilized samples were once resolved with reagents such as urea and potassium oxalate and then dialyzed against fresh milk, stable micelle resulted in both samples prepared before and after frozen storage.

Some reduction of dispersibility occurred during lyophilization and subsequent storage in a dried state in the caseinate complex prepared before frozen storage. This reduction was small when skim milk was lyophilized and stored.     

Development of lyophilization procedure ensuring survival of bifidobacteria and preservation of their probiotic potential upon long-term storage

Survival of bifidobacteria and preservation of their morphological characteristics after 12-month storage of lyophilized cells was studied for the strains of Bifidobacterium bifidum and B. animalis isolated and maintained in the microbial collection of the Department of Microbiology, Moscow State University. A combined approach to pre-lyophilization treatment of microorganisms and subsequent storage was developed in order to improve cell survival. Compared to the standard cryoprotector concentrations, sucrose and glucose (5% and higher) in skim milk, as well as freezing at?70°C with subsequent storage at the same temperature resulted in improved survival of bifidobacteria. Under such conditions, the number of viable cells (CFU) after 12 months of storage was two to three orders of magnitude higher than in the case of the standard lyophilization procedure. Investigation of dynamics of resistance of reactivated clones to such gastrointestinal stress factors as gastric juice and bile acids revealed preservation of these properties at all storage modes. However, since the number of surviving cells decreased during storage according to the standard procedure, the number of stress-affected cells was correspondingly lower. Reactivated cultures exhibited high resistance to oxygen, with survival decreasing to 35% of the initial level.     

Proceedings: Preservation of bacteria by freezing at moderately low temperatures

In order to get some basic information for the development of a long-term preservation method by freezing at moderately low temperatures, the viability of 259 strains belonging to 32 genera and 135 species was measured. Cells were suspended in 10% glycerol and stored at ?53 °C for 16 months. About 93%, 88%, and 74% of aerobic bacteria gave viable cell counts higher than 10⁵/ml, 10⁶/ml, and 10⁷/ml, respectively. About 10% of gram-positives and 3% of gram-negatives gave viable cell counts lower than 10⁵/ml. There seemed to be some species—and genus—specificity with respect to viability after frozen storage and liquid paraffin-seal storage. Strains of coryneform bacteria, genera of the family Enterobacteriaceae, and the genus Pseudomonas were generally resistant. Pseudomonas putrefaciens proved to be specifically sensitive. Lactic acid bacteria were subject to sublethal injury, requiring special recovery media. Psychrophilic bacteria were very susceptible to frozen storage. All the tested strains of acetic acid bacteria survived frozen storage well both in 10% glycerol and in 10% honey at ?28 °C for 4.5 years. Honey proved to be a better adjuvant for frozen storage than glycerol. It was suggested from the results that for many kinds of bacteria, long-term preservation by freezing at moderately low temperatures might be possible when appropriate procedures are applied.     

Maintenance and preservation of ectomycorrhizal and arbuscular mycorrhizal fungi

Short- to long-term preservation of mycorrhizal fungi is essential for their in-depth study and, in the case of culture collections, for safeguarding their biodiversity. Many different maintenance/preservation methods have been developed in the last decades, from soil- and substrate-based maintenance to preservation methods that reduce (e.g., storage under water) or arrest (e.g., cryopreservation) growth and metabolism; all have advantages and disadvantages. In this review, the principal methods developed so far for ectomycorrhizal and arbuscular mycorrhizal fungi are reported and described given their distinct biology/ecology/evolutionary history. Factors that are the most important for their storage are presented and a protocol proposed which is applicable, although not generalizable, for the long-term preservation at ultra-low temperature of a large panel of these organisms. For ECM fungi, isolates should be grown on membranes or directly in cryovials until the late stationary growth phase. The recommended cryopreservation conditions are: a cryoprotectant of 10 % glycerol, applied 1–2 h prior to cryopreservation, a slow cooling rate (1 °C min^?1) until storage below ?130 °C, and fast thawing by direct plunging in a water bath at 35–37 °C. For AMF, propagules (i.e., spores/colonized root pieces) isolated from cultures in the late or stationary phase of growth should be used and incorporated in a carrier (i.e., soil or alginate beads), preferably dried, before cryopreservation. For in vitro-cultured isolates, 0.5 M trehalose should be used as cryoprotectant, while isolates produced in vivo can be preserved in dried soil without cryoprotectant. A fast cryopreservation cooling rate should be used (direct immersion in liquid nitrogen or freezing at temperatures below ?130 °C), as well as fast thawing by direct immersion in a water bath at 35 °C.     

Biochemical functionality and recovery of hepatocytes after deep freezing storage

Summary The present study was undertaken to define the conditions for optimal cryopreservation of hepatocytes. Two different freezing procedures were analyzed: a slow freezing rate (SFR) (−2° C/min down to −30°C and then quick freezing to −196° C) and a fast freezing rate (FFR) (direct freezing of tubes to −196° C: −39° C/min). Cells were frozen in fetal bovine serum containing 10% Dimethyl sulfoxide (DMSO). After rapid thawing at 37° C, followed by dilution and removal of the cryoprotectant, cells were plated and several parameters were followed as criteria for optimal cryopreservation of cells. The FFR cells showed no apparent ultrastructural damage after 24 h of culture. Plating efficiency and spreading were similar as controls. Gluconeogenesis from pyruvate and fructose, tyrosine amino transferase induction by glucagon and dexamethasone, urea production, and plasma protein synthesis of FFR cells were similar to those found in control cultures. The FFR procedure, in comparison to the SFR method, seemed to render the best preserved hepatocytes. The financial support for this work was from Fondo de Investigaciones Sanitarias de la Seguridad Social, Grants 41/82 and 48/82.