Preservation of Phakopsora pachyrhizi Uredospores

This study compared different temperatures and dormancy‐reversion procedures for preservation of Phakopsora pachyrhizi uredospores. The storage temperatures tested were room temperature, 5°C, ?20°C and ?80°C. Dehydrated and non‐dehydrated uredospores were used, and evaluations for germination (%) and infectivity (no. of lesions/cm²) were made with fresh harvested spores and after 15, 29, 76, 154 and 231 days of storage. The dormancy‐reversion procedures evaluated were thermal shock (40°C/5 min) followed or not by hydration (moist chamber/24 h). Uredospores stored at room temperature were viable only up to a month of storage, regardless of their hydration condition. Survival of uredospores increased with storage at lower temperatures. Dehydration of uredospores prior to storage increased their viability, mainly for uredospores stored at 5°C, ?20°C and ?80°C. At 5°C and ?20°C, dehydrated uredospores showed increases in viability of at least 47 and 127 days, respectively, compared to non‐dehydrated spores. Uredospore germination and infectivity after storage for 231 days (7.7 months), could only be observed at ?80°C, for both hydration conditions. At this storage temperature, dehydrated and non‐dehydrated uredospores exhibited 56 and 28% of germination at the end of the experiment, respectively. Storage at ?80°C also maintained uredospore infectivity, based upon levels of infection frequency, for both hydration conditions. Among the dormancy‐reversion treatments applied to spores stored at ?80°C, those involving hydration allowed recoveries of 85 to 92% of the initial germination.     

How specialized volatiles respond to chronic and short‐term physiological and shock heat stress in Brassica nigra

Brassicales release volatile glucosinolate breakdown products upon tissue mechanical damage, but it is unclear how the release of glucosinolate volatiles responds to abiotic stresses such as heat stress. We used three different heat treatments, simulating different dynamic temperature conditions in the field to gain insight into stress‐dependent changes in volatile blends and photosynthetic characteristics in the annual herb Brassica nigra (L.) Koch. Heat stress was applied by either heating leaves through temperature response curve measurements from 20 to 40 °C (mild stress), exposing plants for 4 h to temperatures 25–44 °C (long‐term stress) or shock‐heating leaves to 45–50 °C. Photosynthetic reduction through temperature response curves was associated with decreased stomatal conductance, while the reduction due to long‐term stress and collapse of photosynthetic activity after heat shock stress were associated with non‐stomatal processes. Mild stress decreased constitutive monoterpene emissions, while long‐term stress and shock stress resulted in emissions of the lipoxygenase pathway and glucosinolate volatiles. Glucosinolate volatile release was more strongly elicited by long‐term stress and lipoxygenase product released by heat shock. These results demonstrate that glucosinolate volatiles constitute a major part of emission blend in heat‐stressed B. nigra plants, especially upon chronic stress that leads to induction responses.     

Frozen fungi: cryogenic storage is an effective method to store Fusarium cultures for the long‐term

Microbial culture collections provide a vast amount of genotypic and phenotypic information which are invaluable resources for future advancements in research. For most microbial strains, cryopreservation in the vapour phase above liquid nitrogen provides the most stable and long‐term storage method. However, in the case of fungal microbes, not all are suited for cryogenic storage and few studies have addressed the effectiveness of storage in the vapour phase above liquid nitrogen on a diverse collection of Fusarium species. In this work, a collection of 374 Fusarium strains from the Fungal Genetics Stock Center, including 24 unique species, were duplicated and sent to the National Laboratory for Genetic Resource Preservation for storage in the vapour phase above liquid nitrogen. After 5 years of storage the entire collection was tested for viability and phenotypic stability by using plating, cellular staining assays, assessing the number of viable cells and measuring the rate of growth of each isolate. Additionally, the rate of growth for ～10% of the isolates were compared with the same isolates which had been stored at ?80°C at the Fungal Genetics Stock Center over the same timeframe to determine if cryopreservation in liquid nitrogen vapour provided a comparable method of storage. All National Laboratory for Genetic Resources Preservation isolates grew after being stored at ?165°C for 5 years. In general, the isolates that were stored at ?165°C grew at a faster rate than the isolates stored at ?80°C for the same period. Of the isolates stored at ?165°C, most had greater than 80% cell viability, however, those isolates that had less than 50% cell viability generally also had fewer conidia germinate. These isolates may be at a greater risk for storage over longer times. In conclusion, storage at ?165°C liquid nitrogen provided reliable preservation of a diverse collection of Fusarium spp. over 5 years, and culture viability data indicates that they will remain viable during additional storage for longer periods.     

Seed reproductive biology of the rare aquatic carnivorous plant Aldrovanda vesiculosa (Droseraceae)

Despite the unprecedented global decline in extant populations of Aldrovanda vesiculosa in the last century, little is known about the reproductive biology of this iconic aquatic carnivorous plant. This study aimed to investigate the role of seed‐based reproduction in the ecology of A. vesiculosa, with particular focus on the interplay between the regulation of seed dormancy by temperature cues and the efficacy of exogenous ethylene gas to act as a germination stimulant, the desiccation capacity and long‐term storage potential of seeds for conservation purposes. Sexual reproduction appears to be extremely limited in both natural and naturalized populations across three continents, with high variability in the success of flowering and seed set between sites and between seasons. Overall, flowering yielded few fertile fruit (6–19% of flowers producing fertile fruit) and seed viability was variable but generally low (29–88%). Fecundity appears to be influenced by seasonal climatic conditions and microhabitat characteristics. Aldrovanda vesiculosa possesses physiologically dormant seeds, with germination stimulated by exposure to ethylene gas (>90% germination) at 25 °C. Seeds appear sensitive to desiccation and sub‐zero temperature storage, with no germination and markedly reduced embryo growth after storage of seeds for >1 month at 15 °C and 15% relative humidity or after short‐term (24 h) storage at ?18 °C. In the absence of significant conservation and restoration initiatives, the continuing decline of dystrophic freshwater wetland habitats globally leaves A. vesiculosa facing extinction. As the successful long‐term storage of seeds appears unfeasible based on the approaches described in this study, other alternatives for germplasm conservation such as cryostorage of vegetative tissues or zygotic embryos must be considered for establishing long‐term ex situ collections of critical germplasm.     

Two methods for the prediction of Mycocentrospora acerina infection on stored carrots

Carrot plants were collected from 26 fields located in different districts in Norway during 1985, 1986 and 1987. Leaves were sampled in the first two years, and roots were sampled in all years. Incidence of Mycocentrospora acerina on the leaves at harvest was correlated (r = 0.82) to the incidence of M. acerina on the roots after storage at 0–1°C for six months (long term storage). Incidence of M. acerina on roots sampled about six weeks before harvest (date c) and placed at 10°C for six weeks (test storage) was correlated (r = 0.84) to incidence of the pathogen after long term storage on roots sampled at harvest (date d). Test storage and long term storage data from parallel samples taken at date d was more strongly correlated (r = 0.90).     

Thermotolerance and rapid cold hardening ameliorate the negative effects of brief exposures to high or low temperatures on fecundity in the flesh fly, Sarcophaga crassipalpis

Although the immediate effects of temperature stress are well documented, the longer‐term effects of such stresses are more poorly known. In these experiments, we investigate the effects of suboptimal and supraoptimal temperatures during pharate adult development on fecundity in the flesh fly, Sarcophaga crassipalpis Macquart. A 1 h cold shock at ?10°C during the red‐eye pharate adult stage decreases the fecundity of both sexes. Induction of rapid cold hardening by pre‐treatment at 0°C for 2 h partially prevents reproductive impairment. Heat shock of pharate adults for 1 h at 45°C also reduces fecundity in both sexes, but inducing thermotolerance by pre‐treatment at 40°C for 2 h affords protection only to females. Males heat shocked at 45°C or first pre‐treated at 40°C consistently fail to transfer sperm to the females. The injury inflicted on males by heat shock is most pronounced when the stress is administered to pharate adults or adults; wandering larvae and true pupae are unaffected. The implications of these data for naturally occurring populations are discussed.     

Viability of dry Trichoderma harzianum spores under storage

Spores of the potential biocontrol agent Trichoderma harzianum P1 were prepared without (M1) and with heat shock (40?°C for 90?min) after fermentation (M2), filtered into a paste and dried over silica gel. M1 and M2 exhibited high viability (55%) and similar initial trehalose contents (4.0 and 5.4%, respectively) after slow drying. No significant differences in viability were found between treatments during storage for 110 days under different temperatures, T (8, 33 and 42?°C) and water activities, a _w (0.03, 0.33 and 0.75). Viability of spores, after storage at a _w =0.03 were 100 and 70% for 8 and 33?°C, respectively. During storage, decrease in trehalose content and viability was faster at a _w =0.75 and 42?°C. Loss of viability was modeled by a first order kinetic model depending on 1/T and a _w . M2 (with heat shock) showed slightly higher trehalose contents than M1 which resulted in 100% viability after 52 days at 8?°C.     

Long-term Preservation of Podosphaera fusca Using Silica Gel

Podosphaera fusca is the main causal agent of cucurbit powdery mildew in Spain and one of the most important limiting factors for cucurbit production worldwide. As an obligate biotrophic parasite, this fungus has been traditionally cultured and conserved by periodical transfers of conidia to fresh plant material. Here we describe a simple protocol for preservation of P. fusca isolates in absence of living tissue based on the dry spore, slow‐freezing technique, and demonstrate that storage of silica gel desiccated conidia at ?80°C is an efficient method for the long‐term preservation of the pathogen.     

Assessment of the influence of different sample processing and cold storage duration on plant free proline content analyses

Introduction – A method which is widely accepted for the analysis of free proline content in plant tissues is based on the use of 3% sulfosalicylic acid as an extractant, followed by spectrophotometric quantification of a proline–ninhydrin complex in toluene. However, sample preparation and storage may influence the proline actually measured. This may give misleading or difficult to compare data. Objective and Methodology – To evaluate free proline levels fresh and frozen strawberry (Fragaria × ananassa Duch.) leaves and soybean [Glycine max (L.) Merr.] hypocotyl tissues were used. These were ground with or without liquid nitrogen and proline extracted with sulfosalicylic acid. A particular focus was the influence of plant sample cold storage duration (1, 4 and 12 weeks at ?20°C) on tissue proline levels measured. Results – The free proline content analyses, carried out in leaves of Fragaria × ananassa Duch. as well as in hypocotyls of Glycine max (L.) Merr., showed a significant influence of the sample preparation method and cold storage period. Long‐term storage of up to 12 weeks at ?20°C led to a significant increase in the measured proline in all samples analysed. Conclusion – The observed changes in proline content in plant tissue samples stored at ?20°C indicate the likelihood of the over‐estimation of the proline content if the proline analyses are delayed. Plant sample processing and cold storage duration seem to have an important influence on results of proline analyses. Therefore it is recommended that samples should be ground fresh and analysed immediately. Copyright © 2010 John Wiley & Sons, Ltd.     

A Simple and Rapid Cryopreservation Technique for Ciliates: A Long‐Term Storage Procedure Used for Marine Scuticociliates

Pseudocohnilembus persalinus is a free‐living marine scuticociliate that, as a new model organism, has been used in a wide variety of studies. However, long‐term laboratory maintenance for this species is mainly achieved by subculture that requires rigorous culture environments and, too often, cultures of the organism die out for a variety of reasons. Successful transport of viable cultures also poses problems for researchers. This study describes a simple and rapid protocol for long‐term cryopreservation of P. persalinus. The effects of physiological states of individuals before freezing, the type and concentration of cryoprotectant, and optimal temperatures for freezing and thawing were assessed. A cryopreservation protocol, using a mixture of 30% glycerol and 70% concentrated P. persalinus cell culture, incorporating rate‐controlled freezing at ?80 °C before liquid nitrogen storage, maintained a high recovery efficiency after 8 wk of storage. These results suggest that broader application of this protocol to build a cryopreserved marine protozoa culture bank for biological studies may be possible.     

Proceedings: Preservation of rust fungi in liquid nitrogen

Spores of rust fungi can be expected to retain viability without loss of infectivity for at least several years when stored in liquid nitrogen (?196 °C). Addition of liquid suspending media is harmful and not necessary. Some rust fungi experience cold-induced dormancy when exposed to less than 0 °C for a minute or longer but germinability is dependably restored on applying a heat shock by heating the spores to 40 °C for at least 15 sec during or after thawing. Most rust fungi are not sensitive to moisture content at the time of freezing but Puccinia striiformis must be vacuum dried before freezimg. The need for heat shock may not show up until several days after thawing. All of the rust strains tested to date have retained their properties to the extent tested and for the duration of storage. Data are available for up to 11 years. Preliminary experiments to preserve saprophytic mycelial cultures of P. graminis have so far failed, with and without use of 10% glycerol and 5% DMSO. The successful preservation of rust spores has made feasible the development of a collection of living rust fungi at ATCC beginning in 1965 and which now has over 80 strains in 20 species in 7 genera.     

野生鸡枞菌种长期保存方法比较

野生鸡枞菌种质资源的有效保存是对野生鸡枞加以保护和利用的前提。以自行分离的5个野生鸡枞菌株作为研究对象,采用蒸馏水保藏法和-80°C冻结保藏法对野生鸡枞菌种长期保存的方法进行了实验研究,蒸馏水法分别保存于室温和4°C,-80°C冻结保藏同时采用程控降温法和泡沫盒降温法,保存20个月后对4种不同方法保存的5个菌株的保存效果进行比较。实验结果表明:蒸馏水室温保存法菌种存活率为100%,萌发期较短,为4-10 d,是一种简便、实用、有效而成本低廉的长期保存方法;-80°C冻结保藏法的存活率为56%-76%,萌发期7-16 d,泡沫盒降温法可以很好地控制降温速度,是一种简便有效的控温方法。     

Solar irradiation levels during simulated long‐ and short‐term heat waves significantly influence heat survival,pigment and ascorbate composition,and free radical scavenging activity in alpine Vaccinium gaultherioides

In the 20th century, annual mean temperatures in the European Alps rose by almost 1 K and are predicted to rise further, increasing the impact of temperature on alpine plants. The role of light in the heat hardening of plants is still not fully understood. Here, the alpine dwarf shrub Vaccinium gaultherioides was exposed in situ to controlled short‐term heat spells (150 min with leaf temperatures 43–49°C) and long‐term heat waves (7 days, 30°C) under different irradiation intensities. Lethal leaf temperatures (LT₅₀) were calculated. Low solar irradiation [max. 250 photosynthetic photon flux density (PPFD)] during short‐term heat treatments mitigated the heat stress, shown by reduced leaf tissue damage and higher F_v/F_m (potential quantum efficiency of photosystem 2) than in darkness. The increase in xanthophyll cycle activity and ascorbate concentration was more pronounced under low light, and free radical scavenging activity increased independent of light conditions. During long‐term heat wave exposure, heat tolerance increased from 3.7 to 6.5°C with decreasing mean solar irradiation intensity (585–115 PPFD). Long‐term exposure to heat under low light enhanced heat hardening and increased photosynthetic pigment, dehydroascorbate and violaxanthin concentration. In conclusion, V. gaultherioides is able to withstand temperatures of around 50°C, and its heat hardening can be enhanced by low light during both short‐ and long‐term heat treatment. Data showing the specific role of light during short‐ and long‐term heat exposure and the potential risk of lethal damage in alpine shrubs as a result of rising temperature are discussed.     

Life from the ashes: survival of dry bacterial spores after very high temperature exposure

We found that spores of Bacillus amyloliquefaciens rank amongst the most resistant to high temperatures with a maximum dry heat tolerance determined at 420 °C. We found that this extreme heat resistance was also maintained after several generations suggesting that the DNA was able to replicate after exposure to these temperatures. Nonetheless, amplifying the bacterial DNA using BOXA1R and (GTG)₅ primers was unsuccessful immediately after extreme heating, but was successful after incubation of the heated then cooled spores. Moreover, enzymes such as amylases and proteases were active directly after heating and spore regeneration, indicating that DNA coding for these enzymes were not degraded at these temperatures. Our results suggest that extensive DNA damage may occur in spores of B. amyloliquefaciens directly after an extreme heat shock. However, the successful germination of spores after inoculation and incubation indicates that these spores could have a very effective DNA repair mechanism, most likely protein-based, able to function after exposure to temperatures up to 420 °C. Therefore, we propose that B. amyloliquefaciens is one of the most heat resistant life forms known to science and can be used as a model organism for studying heat resistance and DNA repair. Furthermore, the extremely high temperature resistivity of these spores has exceptional consequences for general methodology, such as the use of dry heat sterilization and, therefore, virtually all studies in the broad area of high temperature biology.

     

Equilibrium vitrification of mouse embryos at various developmental stages

Previously, we developed a new method by which 2‐cell mouse embryos can be vitrified in liquid nitrogen in a near‐equilibrium state, and then kept at ?80°C for several days. In the present study, we examined whether or not the method was effective for mouse embryos at other developmental stages. Eight‐cell embryos, morulae, and expanded blastocysts of ICR mice were vitrified with ethylene glycol‐based solutions, named EFSc because of their composition of ethylene glycol (30–40%, v/v) and FSc solution. The FSc solution was PB1 medium containing 30% (w/v) Ficoll PM‐70 plus 1.5 M sucrose. The extent of equilibrium was assessed by examining how well vitrified embryos survived after being kept at ?80°C. When 8‐cell embryos and morulae were vitrified with EFS35c or EFS40c and then kept at ?80°C, the survival rate was high even after 4 days in storage and remained high after re‐cooling in liquid nitrogen. On the other hand, the survival of vitrified‐expanded blastocysts kept at ?80°C was low. Therefore, 8‐cell embryos and morulae can be vitrified in a near‐equilibrium state using the same method as for 2‐cell embryos. A high proportion of C57BL/6J embryos at the 2‐cell, 8‐cell, and morula stages vitrified with EFS35c developed to term after transportation on dry ice, re‐cooling in liquid nitrogen, and transfer to recipients. In conclusion, the near‐equilibrium vitrification method, which is effective for 2‐cell mouse embryos, is also effective for embryos at the 8‐cell and morula stages. The method would enable handy transportation of vitrified embryos using dry ice. Mol. Reprod. Dev. 79: 785–794, 2012. © 2012 Wiley Periodicals, Inc.     

First results from conservation studies of chlorophyllous spores of the Royal fern (Osmunda regalis, Osmundaceae)

Pteridophytes spore banks are a promising ex situ conservation tool used to increase the chances of survival of ferns, in fact that large quantities of germplasm with high genetic variation can be conserved in a small space with low economic and technical costs. However, methods to maintain the viability of chlorophyllous spores during storage are less understood.The aim of this study was to investigate the influence of long term storage on the viability of Royal Fern spores, which were stored under different conditions derived from various combinations of temperature and degrees of hydration. Survival and germination tests were performed after 1 and 28 months of storage. Our results showed the highest survival percentages for spores stored under Normal humidity at subzero temperatures (T = ? ?20 °C). These spores received no pre-treatment, dehydration, or cryoprotectants, which resulted in fast germination and gametophyte development which seemed to be stimulated by low temperatures.     

Preservation, mass production and storage ofStagonospora convolvuli, a bioherbicidecandidate for field bindweed (Convolvulusarvensis)

Different solid substrates were investigated as spore production methods for Stagonospora convolvulistrain LA39, a potential bioherbicide for field bindweed (Convolvulusarvensis L.). Up to 4 × 10⁸ spores/g of substratewere yielded on cous-cous (cracked hard wheat). Thespores were as pathogenic as those grown on artificial medium (V-8-juice agar). The air-drying on kaolin and storage at 3 °C kept spores viable and pathogenic for 180 days. Spore germination exceeded70% for the first 140 days and then declined to 50%after 175 days. Less than 5% of spores were still viable after 17 months. The preservation of stock cultures in 10% glycerine at −80 ° C and in liquid nitrogen did not affect viability orpathogenicity of the spores. This revised version was published online in July 2006 with corrections to the Cover Date.