Basidiomycete cryopreservation on perlite: evaluation of a new method

A new cryopreservation method using perlite as a carrier was evaluated on a large set of mycelial cultures of basidiomycetes. The viability and some other characteristics--growth, macro- and micromorphology, and laccase production--of 442 strains were tested after 48-h and then after 3-year storage in liquid nitrogen using a perlite protocol (PP). All (100%) of them survived successfully both 48-h storage and 3-year storage in liquid nitrogen without noticeable growth and morphological changes. Also laccase production was unchanged. The viability and laccase production of a part (250) of these strains were compared with those of the strains subjected to an original agar plug protocol (OP). Using OP, 144 strains (57.6%) out of 250 survived a 3-year storage in liquid nitrogen. The results indicate that the cryopreservation protocol used significantly influences survival of the strains. Markedly better results were achieved using the PP.     

Cryopreservation of filamentous micromycetes and yeasts using perlite

The viability, growth and morphology of 48 strains of Ascomycota (including 17 yeasts) and 20 strains of Zygomycota were determined after a 2-d and then after 1-year storage in liquid nitrogen using a new cryopreservation method with perlite as a particulate solid carrier. In case of Ascomycota, 45 strains (94 %) out of 48 survived both 2-d and 1-year storage in liquid nitrogen, respectively. In case of Zygomycota, all 20 strains survived both storage. In addition, 3 strains of Basidiomycota counted among yeasts were tested and all survived the 1 year storage. In all surviving cultures no negative effects of cryopreservation by this method have been observed after 1-year of storage in liquid nitrogen. The results indicate that the perlite protocol can be successfully used for cryopreservation of taxonomically different groups of fungi and also for fungi which failed to survive other routinely used preservation procedures.     

Long-term preservation of yeast cultures in liquid nitrogen

Nineteen strains of taxonomieally diverse yeast species tested survived freezing and subsequent five-year storage in liquid nitrogen at ™196 °C, using a medium M 2 composed of malt extract, yeast extract, peptone, calf serum and dimethyl sulfoxide. Viability of the yeast cultures after long-term storage ranged from 5 to 97 % (average 62 %) compared with the viability of the cultures prior to freezing. The use of liquid nitrogen refrigeration for preserving yeast cultures is strongly advocated.     

Vermiculite as a culture substrate greatly improves the viability of frozen cultures of ectomycorrhizal basidiomycetes

We assessed a new cryopreservation protocol that uses vermiculite as a culture substrate, called the vermiculite protocol (VP), by assessing the viability, recovery time of hyphae after revival, and colony diameter of cryosensitive ectomycorrhizal basidiomycete strains after storage for 2 weeks or 1 year in a vapour-phase liquid nitrogen tank. Twelve difficult-to-preserve strains of nine species (Amanita citrina, A. pantherina, A. rubescens, A. spissa, Kobayasia nipponica, Lactarius akahatsu, L. hatsudake, Sarcodon aspratus, and Tricholoma flavovirens) that did not achieve good revival after cryopreservation with our previous Homolka’s perlite protocol and modified perlite protocol (MPP) experiments were used to assess the new methodology. Vermiculite and liquid medium were put into a cryotube and inoculated with an agar plug containing mycelia. The cryotube was cultured for various incubation times. After adequate mycelial growth, a mixture of cryoprotectants (5% dimethyl sulfoxide and 10% trehalose [5D10T] or 5% glycerol and 10% trehalose [5G10T]) was placed into the cryotube. The cryotube was frozen in a freezing container in a –80 °C freezer and then stored in vapour-phase liquid nitrogen. In the recovery test, 10 of 12 strains showed 100% revival after 2 weeks of storage in the 5G10T cryoprotectant, and all 12 strains showed 100% revival after 2 weeks of storage in the 5D10T cryoprotectant. Furthermore, all strains were viable after 1 year of storage in a vapour-phase liquid nitrogen tank. Thus, the VP is applicable to a wide range of ectomycorrhizal basidiomycete cultures, including highly cryosensitive strains.     

Long-term viability of preserved eukaryotic algae

Levels of viability of Chlorella emersonii after storage of dried material for one year were 0.1% on rehydration, all other dried organisms examined in this study failed to recover after prolonged storage. In addition, no detectable recovery was observed in any of the algae tested after storage of freeze-dried cultures. Methods have also been developed to cryopreserve a range of microalgae, but no single protocol has been found to be universally satisfactory. Some strains are apparently not able to withstand cryopreservation using known methods, whilst others may be frozen successfully in the absence of cryoprotectant by plunging directly into liquid nitrogen. A two-step protocol (cooling to an intermediate subzero temperature prior to plunging into liquid nitrogen) has been used to cryopreserve the majority of strains. Where this has proven successful, post-thaw viability levels of over 95% have been attained for some algae. This paper demonstrates that, where applicable, cryopreservation allows the long-term preservation of frozen algae with no significant reduction in viability up to 22 years storage. (Previous location of Culture Collection of Algae and Protozoa) This revised version was published online in September 2006 with corrections to the Cover Date.     

Viability of wood-inhabitingBasidiomycetes following cryogenic preservation

The viability of 252 wood-inhabiting strains ofBasidiomycetes was tested after storage under liquid nitrogen, using 10% glycerol as cryoprotectant. 164 strains survived the process: 103Aphyllophorales (out of 138) and 60Agaricales (out of 113). The results indicate that the process of freezing is rather complex and should be more precisely controlled to achieve higher survival.     

Cryopreservation of basidiomycete strains using perlite.

A new alternative method using perlite as a particulate solid carrier in the growth medium with a cryoprotectant was successfully tested for cryopreservation of several basidiomycete species from different genera (Armillaria, Pleurotus, Pluteus, Polyporus) which failed to survive or retain their properties in cryopreservation procedures routinely used in our laboratory. Frozen basidiomycete strains were kept in cryovials submerged in liquid nitrogen and were either immediately after the freezing process or after a 6-month storage thawed and checked for viability, purity and changes in growth, morphology and biochemical characteristics. All cultures survived the cryopreservation procedure and no negative effects of cryopreservation by this method have been observed after 6 months of storage in liquid nitrogen.     

Liquid nitrogen storage of yeast cultures I. Survival,and literature review of the preservation of fungi at ultralow temperatures

All 20 yeast strains of 17 species tested survived 75 days (the length of the experimental period) in liquid nitrogen at-196 C. The components of the more protective of the two freezing media used were (w/v) malt extract 2.5 %, yeast extract 0.25 %, peptone 0.5 %, calf serum 15 % (v/v) and dimethyl sulfoxide 10 % (v/v). Viability of the cells in this medium after rapid uncontrolled freezing and thawing in sealed plastic ampoules ranged from 2 % to 98 % (average 67 %) compared with the viability of the cultures before freezing. In only 4 strains was survival lower than 50 %. (90 references).     

Cryopreservation of four valuable strains of microalgae, including viability and characteristics during 15?years of cryostorage

Recent developments in the technology of cryopreservation have permitted the long-term storage of many strains of microalgae with reliable rates of survival. However, many strains still cannot be recovered from storage in liquid nitrogen. Here, we investigated the effects of various cryoprotectants in achieving comparatively high survival rate around 50%. The strains tested included two freshwater algae, Chlorella vulgaris C-27 and M-207A7, and two marine algae, Nannochloropsis oculata ST-4 and Tetraselmis tetrathele T-501. Cells of these strains were suspended in various cryoprotective solutions and slowly cooled to ?40°C prior to immersion in liquid nitrogen. Little or no cryoprotection was seen with dimethyl sulfoxide (DMSO) alone or in combination with sorbitol or proline; with glycerol alone; or with ethylene glycol (EG) alone. However, survival rates of approximately 50% were observed using a cryoprotectant mixture of 5% DMSO, 5% EG, and 5% proline. Viability persisted during a storage period of 15?years. Similarly, chlorophyll content was not significantly changed during this 15-year interval. Thus, the present study demonstrates the advantage of cryopreservation using liquid nitrogen. We expect that this method will contribute to both basic and applied biology through the establishment of cryopreserved microalgal culture collections.     

Two chlorophyll-binding subunits of the photosystem 2 reaction center complex isolated from the thermophilic cyanobacterium Synechococcus sp

The reaction center of photosystem 2 has been highly purified from digitonin-solubilized thylakoid membranes of the thermophilic cyanobacterium Synechococcus sp. by means of sucrose density gradient centrifugation and electrophoresis on polyacrylamide gels containing digitonin. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of isolated reaction center complex yielded four chlorophyll a proteins named CP2-a, CP2-b, CP2-c, and CP2-d. When reelectrophoresed, CP2-a was transformed to CP2-d, and CP2-b was converted to CP2-a and CP2-d. The reaction center complex consisted of two major polypeptides of 47,000 and 40,000 Da and several minor polypeptides. CP2-b contained a 47,000-Da polypeptide together with 66,000- and 31,000-Da polypeptides, while CP2-a and CP2-d had only a 47,000-Da polypeptide. The apoprotein of CP2-c was a 40,000-Da polypeptide. Absorption spectra of CP2-a, -b, and -d were similar to each other but distinctly different from those of CP2-c at liquid nitrogen temperature. The reaction center complex showed two fluorescence emission bands at 686 and 694 nm at 77 degrees K. CP2-a, -b, and -d emitted the band at 694 nm, whereas the fluorescence peak at 686 nm was associated with CP2-c. It is concluded that the photosystem 2 reaction center complex contains two chlorophyll-binding subunits, CP2-d (or CP2-a) which may be the site of the primary photochemistry of photosystem 2 and CP2-c which may function as the antenna of the reaction center of photosystem 2.     

番木瓜环斑病毒畸叶株系的CP基因克隆和序列分析

采用RT－PCR方法合成了本研究室保存的番木瓜畸叶病毒（PMaLV）的外壳蛋白（CP）基因,将其CP基因克隆进Promega公司的pGEM-T and pGEM-T Easy Vector System（简称T－载体）,并进行了序列分析。结果表明,PMaLV CP基因核苷酸序列全长为861nt,推导其编码287个氨基酸。与番木瓜环斑病毒（PRSV）美国夏威HA株系和澳大利亚W株系的CP基因相比,在第66nt处开始连续缺失3个核苷酸。与PRSV的华南Ys、Sm和G株系以及夏威夷的HA和澳大利亚的W株系相比,其CP基因序列同源率分别为96％、98％、95％、89％和89％。其的氨基酸序列同源率分别为98％、97％、97％、96％和95％。此结果表明,PMaLV属于PRSV的一个株系,不是一种新病毒。因此,我们称其为番木瓜环斑病毒畸叶株系（ML株系）。     

Development of a cryopreservation protocol for long-term storage of black tiger shrimp (Penaeus monodon) spermatophores

The objectives of this study were to determine the effect of cryoprotectants on sperm viability and develop a freezing protocol for long-term storage of P. monodon spermatophores. Spermatophores suspended for 30 min in calcium-free saline (Ca-F saline) containing the cryoprotectants dimethyl sulfoxide (DMSO), ethylene glycol (EG), 1,2-propylene glycol (PG), formamide, and methanol at concentrations of 5, 10, 15, or 20% were studied using a modified eosin-nigrosin staining technique. The smallest reductions in apparent sperm viability occurred with DMSO; therefore, a freezing protocol was developed using Ca-F saline containing 5% DMSO. Spermatophores were cryopreserved using three protocols; cooling to a final temperature of -30, -80 or -80 degrees C and immediately stored in liquid nitrogen (cooling rates of -2, -4, -6, -8, -10, -12, -14 or -16 degrees C/min). Frozen spermatophores were thawed (2 min) at 30, 60, 70, or 90 degrees C. Successful cryopreservation of spermatophores in liquid nitrogen was achieved by a one-step cooling rate of -2 degrees C/min between 25 and -80 degrees C before storing in liquid nitrogen. Optimal thawing was in a 30 degrees C water bath for 2 min; this yielded live sperm after storage in liquid nitrogen for 210 days. Average sperm viability for fresh (97.8+/-2.9%) and cryopreserved spermatophores held for less than 60 days (87.3+/-4.1%) did not differ (P>0.05); however, that for spermatophores stored in liquid nitrogen between 90 and 210 days were lower (P<0.05) and varied from 27.3+/-3.4 to 53.3+/-4.3%. Thawed spermatophores previously held in liquid nitrogen for less than 62 days fertilized eggs (fertilization and hatching rates of 71.6-72.2% and 63.6-64.1%, respectively) at rates comparable to fresh spermatophores (70.8-78.2% and 66.3-67.8%, respectively). In conclusion, sperm within cryopreserved spermatophores stored in liquid nitrogen retained their viability for up to 210 days.     

Long-Term Storage of Infective Microsporidian Spores in Liquid Nitrogen

Thirty-one species of microsporidia, isolated from insects and stored in liquid nitrogen for up to 25 yr, were infectious when removed from liquid nitrogen. The natural hosts of all of these microsporidia were terrestrial insects, representing six different insect orders: Coleoptera, Diptera, Hemiptera, Hymenoptera, Lepidoptera, and Orthoptera. All microsporidia from terrestrial insects that were tested survived storage in liquid nitrogen, while Nosema algerae , a microsporidium from aquatic mosquito hosts did not survive freezing in liquid nitrogen. A Nosema species from the alfalfa weevil, Hypera postica , lost some infectivity in a water storage medium after 25 yr in liquid nitrogen. Liquid nitrogen storage of microsporidian spores in 50% and 100% glycerol media reduced loss of infectivity and is recommended for extended storage of microsporidia from terrestrial insect hosts.     

无细胞百日咳疫苗效价检定用攻击菌液氮保存的稳定性

为了考察无细胞百日咳疫苗效价检定用攻击菌在液氮中保存的稳定性,对液氮保存1~7年的4~9代百日咳攻击菌随机抽取7~11批次样品,采用LD50检测并经统计学处理,分析其样品的毒力变化。试验结果显示,4~9代的百日咳攻击菌液氮保存5年,毒力仍能达到《中华人民共和国药典》三部(2005版)的要求;保存6年和7年,4~7代的百日咳攻击菌毒力仍符合上述要求,8、9代的攻击菌毒力的合格率分别为84%和40%。试验证实,无细胞百日咳效价检定用攻击菌液氮保存5年具有良好的稳定性,可用于无细胞百日咳疫苗的效价检定。     

Specifics of the coat protein gene in Russian strains of the cucumber green mottle mosaic virus

The primary structure of the coat protein (CP) gene was examined for pathogenic strain MS-1 and vaccine strain VIROG-43M of the cucumber green mottle mosaic virus (CGMMV). In CP amino acid composition, strains MS-1 and VIROG-43M are typical representatives of CGMMV: their CPs have 98-100% homology to CPs of other tobamoviruses of the group. The CP gene has the same nucleotide composition in pathogenic MS-1 and vaccine VIROG-43M, indicating that strain attenuation is not determined by this gene. The CP amino acid sequences of the two Russian strains are fully identical to the CP sequences of two Greek strains, GR-3 and GR-5. However, the nucleotide sequences of their genes differ in 13 bp, testifying to the difference between the Russian and Greek strains.     

Specifics of the coat protein gene in Russian strains of the cucumber green mottle mosaic virus

The primary structure of the coat protein (CP) gene was examined for pathogenic strain MS-1 and vaccine strain VIROG-43M of the cucumber green mottle mosaic virus (CGMMV). In CP amino acid composition, strains MS-1 and VIROG-43M are typical representatives of CGMMV: their CPs have 98–100% homology to CPs of other tobamoviruses of the group. The CP gene has the same nucleotide composition in pathogenic MS-1 and vaccine VIROG-43M, indicating that strain attenuation is not determined by this gene. The CP amino acid sequences of the two Russian strains are fully identical to the CP sequences of two Greek strains, GR-3 and GR-5. However, the nucleotide sequences of their genes differ in 13 bp, testifying to the difference between the Russian and Greek strains.     

Isolation and characterization of cesium-accumulating bacteria.

Cesium-accumulating bacteria, strains CS98 and CS402, were isolated from soil by a radioactive autoradiographic method using 137Cs. These strains displayed the rod-coccus growth cycle and contained mesodiaminopimelic acid, mycolic acids, and tuberculostearic acids. The major menaquinone of CS98 was MK-8(H2). On the basis of these characteristics, strain CS98 was identified as Rhodococcus erythropolis and strain CS402 was classified in the genus Rhodococcus. The maximum values of cesium removal efficiencies in the liquid culture containing 10 mumol of cesium per liter for strains CS98 and CS402 were 90 and 47%, respectively. The maximum cesium contents in strains CS98 and CS402 were 52.0 and 18.8 mumol/g (dry weight) of cells, respectively. Maximum values of cesium concentration factors for strains CS98 and CS402 were 3.5 x 10(4) and 3.6 x 10(3), respectively.     

The preservation of salt marsh algae by controlled liquid nitrogen freezing.

Five species of benthic marine algae were preserved by controlled liquid nitrogen freezing and storage over periods extending to 1 year. Only a small percent of the algae survived without cryoprotectant. Nannochloris adamsii was an exception; 67% survived after 12 months of storage. Nitzschia acicularis was the best preserved with 5 glycerol as a cryoprotectant, Dimethylsulfoxide was a better cryoprotectant for N. adamsii and Dunaliella quartolecta. Reducing normal brackish salinity (28‰) of the culture medium to one half (14‰) increased the survival percentages for N. acicularis, Cylindrotheca closterium and Phaeodactylum tricornutum. The morphology and physiology of the species tested were unchanged by long storage time in liquid nitrogen.     

Preservation of basidiomycete strains on perlite using different protocols

For preservation of 31 basidiomycete strains on perlite in cryovials we used five different perlite protocols to compare their applicability in laboratories with different equipment, namely a viability of the controlled freezing device or the electric deep-freezer and liquid nitrogen supply. The viability of the strains, macromorphological characteristics and the production of laccase were tested after 48 h, six months and one year of storage in the respective device. Our results indicated that the different response to the freezing/thawing process is an intrinsic feature of the respective strain. Nevertheless, the highest viability and preservation of laccase production in our tested strains was found when we used pre-freezing to −80 °C at a freezing rate of 1 °C/min in a programmable IceCube 1800 freezer or in freezing container Mr. Frosty before storage in liquid nitrogen or at ultra-low temperature freezer at −80 °C, respectively. The two abovementioned protocols enable all tested strains to survive three successive freezing/thawing cycles without substantial reduction of growth rate. The majority of the strains also do not lose laccase production. Our results showed that direct immersion of the strains into liquid nitrogen or placing them into −80 °C without pre-freezing is not suitable for basidiomycete cryopreservation.     

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。