Winter Survival of Meloidogyne incognita in Six Soil Types

Winter survival of Meloidogyne incognita in six soil types (Fuquay sand, Norfolk loamy sand, Portsmouth loamy sand, muck, Cecil sandy clay loam, and Cecil sandy clay) was determined in microplots at one location from November 1981 to May 1982 and from November 1982 to March 1983. Survival, based on second-stage juveniles (J2) of M. incognita, from November 1981 until May 1982 ranged from 1% in the muck soil to 6% in a Cecil sandy clay loam, but survival rates were much higher the next year following a winter with higher average temperatures. Survival rates of J2 from November to March ranged from 20 to 40% the first winter and from 38 to 87% the second. Soil type did not have a striking effect on the overwintering capabilities ofM. incognita. There were no differences between clay and sand soils, whereas survival of J2 in the muck tended to be lower than in the mineral soils.     

Microbial Biomass, Community Structure and Metal Tolerance of a Naturally Pb-Enriched Forest Soil

The effect of long-term elevated soil Pb levels on soil microbiota was studied at a forest site in Norway, where the soil has been severely contaminated with Pb since the last period of glaciation (several thousand years). Up to 10% Pb (total amount, w/w) has been found in the top layer. The microbial community was drastically affected, as judged from changes in the phospholipid fatty acid (PLFA) pattern. Specific PLFAs that were high in Pb-enriched soil were branched (especially br17:0 and br18:0), whereas PLFAs common in eukaryotic organisms such as fungi (18:2ω6,9 and 20:4) were low compared with levels at adjacent, uncontaminated sites. Congruent changes in the PLFA pattern were found upon analyzing the culturable part of the bacterial community. The high Pb concentrations in the soil resulted in increased tolerance to Pb of the bacterial community, measured using both thymidine incorporation and plate counts. Furthermore, changes in tolerance were correlated to changes in the community structure. The bacterial community of the most contaminated soils showed higher specific activity (thymidine and leucine incorporation rates) and higher culturability than that of control soils. Fungal colony forming units (CFUs) were 10 times lower in the most Pb-enriched soils, the species composition was widely different from that in control soils, and the isolated fungi had high Pb tolerance. The most commonly isolated fungus in Pb-enriched soils was Tolypocladium inflatum. Comparison of isolates from Pb-enriched soil and isolates from unpolluted soils showed that T. inflatum was intrinsically Pb-tolerant, and that the prolonged conditions with high Pb had not selected for any increased tolerance.     

Comparison of the Survival and Metabolic Activity of Psychrophilic and Mesophilic Yeasts Subjected to Freeze-Thaw Stress

A mesophilic yeast, Candida utilis, and a psychrophilic yeast, Leucosporidium stokesii, were subjected to freeze-thaw cycling over the range 25 to -60 C. Viability after freeze-thaw stress was directly correlated with the rate of cooling and the physiological age of the cultures. Rates of glucose fermentation and oxidation could be directly correlated with viability. The optimal cooling rate for both yeast strains was 4.5 to 6.5 C/min; however, their levels of survival obtained at this optimal cooling rate varied considerably. In addition, the psychrophile was less resistant to freeze-thaw stress than was the mesophile.     

Assessment of Pollution-Induced Microbial Community Tolerance to Heavy Metals in Soil Using Ammonia-Oxidizing Bacteria and Biolog Assay

This study attempted to investigate if the tolerance of soil bacterial communities in general, and autotrophic ammonia-oxidizing bacteria (AOB) in particular, evolved as a result of prolonged exposure to metals, and could be used as an indigenous bioindicator for soil metal pollution. A soil contaminated with copper, chromium, and arsenic (CCA) was mixed with an uncontaminated garden soil (GS3) to make five test soils with different metal concentrations. A modified potential ammonium oxidation assay was used to determine the metal tolerance of the AOB community. Tolerance to Cr, Cu, and As was tested at the beginning and after up to 13 months of incubation. Compared with the reference GS3 soil, the five CCA soils showed significantly higher tolerance to Cr no matter which form of Cr (Cr³⁺, CrO₄ ^2?, or Cr₂O₇ ^2?) was tested, and the Cr tolerance correlated with the total soil Cr concentration. However, the tolerance to Cu²⁺, As³⁺, and As⁵⁺ did not differ significantly between the GS3 soil and the five CCA soils. Community level physiological profiles using Biolog microtiter plates were also used to examine the chromate tolerance of the bacterial communities extracted after six months of exposure. Our results showed that the bacterial community tolerance was altered and increased as the soil Cr concentration was increased, indicating that the culturable microbial community and the AOB community responded in a similar manner.     

The Effects of Winter Exposure to Acid Soil Conditions on the Subsequent Survival and Growth of Herbaceous, Forest Perennials: a Preliminary Investigation

For many plant species, growth is limited in acid soils, whichare characterized by high levels of potentially-toxic elementsand low nutrient availability. Although plant-soil interactionsare traditionally studied during the growing season, the highestconcentrations of toxic elements in the soil may occur duringthe winter months. The present study investigated the effectsof a 3-month exposure to either an acid or a reference soil,at temperatures fluctuating around freezing point, on subsequentsurvival and growth of eight herbs (Brachypodium sylvaticum,Carex pilulifera, Geum urbanum, Luzula pilosa, Mycelis muralis,Silene dioica, Stellaria nemorum, Veronica officinalis).Theplants were exposed to ambient weather conditions from Decemberto March, after which they were replanted in fresh referencesoil and transferred to a glasshouse. Their biomass was measured5 weeks later. The plant species differed in their responsesto the soils, in a manner reflecting their natural field distributions.All plants of the most acid-tolerant species survived in bothtreatments, whereas the more sensitive species showed lowersurvival rates after growth in the acid than in the referencesoil. Similar results were found for the regrowth:C. piluliferaandL.pilosa, the most acid-tolerant species, were unaffected by thesoil treatments (ratios between biomass in acid compared toreference soils were 0.8 and 1.1, respectively), whereasG. urbanum,M. muralis, S. nemorumandV. officinaliswere negatively affected(ratios 0.3–0.5). Effects on above- and below-ground biomasswere broadly similar. This preliminary evidence indicates thatsoil chemistry during the winter can be important for both survivaland growth during the vegetative period that follows.Copyright1998 Annals of Botany Company. Acids soils, toxicity, vascular plants, winter exposure.     

Role of Growth Temperature in Freeze-Thaw Tolerance of Listeria spp.

The food-borne pathogen Listeria monocytogenes can grow in a wide range of temperatures, and several key virulence determinants of the organism are expressed at 37°C but are strongly repressed below 30°C. However, the impact of growth temperature on the ability of the bacteria to tolerate environmental stresses remains poorly understood. In other microorganisms, cold acclimation resulted in enhanced tolerance against freezing and thawing (cryotolerance). In this study, we investigated the impact of growth temperature (4, 25, and 37°C) on the cryotolerance of 14 strains of L. monocytogenes from outbreaks and from food processing plant environments and four strains of nonpathogenic Listeria spp. (L. welshimeri and L. innocua). After growth at different temperatures, cells were frozen at −20°C, and repeated freeze-thaw cycles were applied every 24 h. Pronounced cryotolerance was exhibited by cells grown at 37°C, with a <1-log decrease after 18 cycles of freezing and thawing. In contrast, freeze-thaw tolerance was significantly reduced (P < 0.05) when bacteria were grown at either 4 or 25°C, with log decreases after 18 freeze-thaw cycles ranging from 2 to >4, depending on the strain. These findings suggest that growth at 37°C, a temperature required for expression of virulence determinants of L. monocytogenes, is also required for protection against freeze-thaw stress. The negative impact of growth at low temperature on freeze-thaw stress was unexpected and has not been reported before with this or other psychrotrophic microorganisms.Listeria monocytogenes remains a leading cause of deaths due to food-borne illness in the United States and other industrialized nations. Neonates, pregnant women, and immunocompromised people are at high risk for infection (15, 28, 37). Outbreaks of listeriosis tend to involve a relatively small number of closely related strains (“epidemic clones”), primarily of serotype 4b. Several major outbreaks have been attributed to epidemic clone I (ECI) and epidemic clone II (ECII), both of serotype 4b (5, 21).Unlike most other human food-borne pathogens, L. monocytogenes grows over a wide temperature range (1 to 45°C), with optimal growth at approximately 37°C (33). It has been known for some time that expression of several key virulence genes, including hly, encoding the hemolysin listeriolysin O and actA, encoding a protein that mediates actin polymerization required for intracellular pathogenesis, is optimal at 37°C but severely repressed at temperatures below 30°C (22). In contrast, flagellin, motility, and chemotaxis genes are repressed at 37°C but optimally expressed at temperatures below 25°C (9, 10).For an organism such as L. monocytogenes, which is commonly found in the environment but can also colonize and infect warm-blooded animals, temperature is likely to serve as a major signal differentiating environmental from vertebrate host-associated habitats (19). However, with the exception of the thermoregulated phenotypes described above (virulence factor production, motility, and chemotaxis), the impact of growth at different temperatures on specific responses and adaptations of the pathogen remains poorly understood.L. monocytogenes may be exposed to freezing as well as thawing in the course of its existence in natural environments (e.g., soils and water in temperate or cold regions), as well as during the storage and preservation of foods. The organism has been repeatedly isolated from frozen foods (e.g., ice cream) (7). After freezing (−18°C) in laboratory media or in foods and a single thawing cycle, survival depended on strain, freezing medium, and the presence of glycerol as cryoprotectant (13, 14). The freezing and thawing of bacteria grown at 30°C, in combination with essential oil, has been explored as one means to reduce the pathogen in foods (8). The possible role of the general stress sigma factor (sigma B) in survival of bacteria grown at 30°C and exposed to repeated freezing and thawing was also investigated (43). However, there is a surprising dearth of information on the possible impact of growth temperature on tolerance of L. monocytogenes to repeated freezing and thawing (cryotolerance).Studies with another gram-positive psychrotrophic bacterium (Exiguobacterium sibiricum and other Exiguobacterium spp.) revealed that growth in the cold (4°C), or growth on solid media regardless of temperature, resulted in increased tolerance of the bacteria against repeated freezing and thawing (40). It is not known whether low temperature or surface-associated growth may exert similar impacts on the cryotolerance of L. monocytogenes. The objective of the present study was to investigate the impact of growth temperature (4, 25, and 37°C) and of planktonic versus agar growth of L. monocytogenes on protection of the bacteria against repeated freezing and thawing.     

Winter Survival of Pratylenchus scribneri

Population densities of Pratylenchus scribneri in a Plainfield loamy sand soil were sampled from 1 October to 1 May for 4 years. From May to October of each year, the site was planted to Russet Burbank potato and Wis 4763 corn. Percentages of change in population densities of nematodes were computed on the basis of number of nematodes present on 1 October. The decline of P. scribneri between growing seasons was nonlinear, with most mortality occurring in the autumn before the soil froze. Winter survival, defined as the percentage of change in population densities from 1 October to 1 May the following year, ranged from 50 to 136% for nematodes in corn plots and from 15 to 86% for nematodes in potato plots. There was no difference in survival of nematodes of different life stages or among root and soil habitats. Winter survival of nematodes was density-dependent in 3 of 4 years in corn plots and in 1 of 4 years in potato plots. Although predators were present, their abundance was not correlated with the winter survival of nematodes. Cumulative and average snow cover was correlated with the survival of nematodes associated with corn but not with potato. No relationships between other climatic factors and survivorship were detected.     

Caspase Inhibitor Z-VAD-FMK Enhances the Freeze-Thaw Survival Rate of Human Embryonic Stem Cells

Previous study demonstrated that the low survival of human embryonic stem cells (hESC) under conventional slow-cooling cryopreservation protocols is predominantly due to apoptosis rather than cellular necrosis. Hence, this study investigated whether a synthetic broad-spectrum irreversible inhibitor of caspase enzymes, Z-VAD-FMK can be used to enhance the post-thaw survival rate of hESC. About 100 mM Z-VAD-FMK was supplemented into either the freezing solution, the post-thaw culture media or both. Intact and adherent hESC colonies were cryopreserved so as to enable subsequent quantitation of the post-thaw cell survival rate through the MTT assay, which can only be performed with adherent cells. Exposure to 100 mM Z-VAD-FMK in the freezing solution alone did not significantly enhance the post-thaw survival rate (10.2% vs. 9.9%, p > 0.05). However, when 100 mM Z-VAD-FMK was added to the post-thaw culture media, there was a significant enhancement in the survival rate from 9.9% to 14.4% (p < 0.05), which was further increased to 18.7% when Z-VAD-FMK was also added to the freezing solution as well (p < 0.01). Spontaneous differentiation of hESC after cryopreservation was assessed by morphological observations under bright-field microscopy, and by immunocytochemical staining for the pluripotency markers SSEA-3 and TRA-1-81. The results demonstrated that exposure to Z-VAD-FMK did not significantly enhance the spontaneous differentiation of hESC within post-thaw culture.     

Heat Tolerance of Cold Acclimated Puma Winter Rye Seedlings and the Effect of a Heat Shock on Freezing Tolerance

An increase in tolerance to one form of abiotic stress oftenresults in an increase in tolerance to another stress. The heattolerance of Puma rye (Secale cereale) was determined for seedlingseither not cold hardened or hardened under either controlledenvironmental or natural conditions. The heat tolerance wasdetermined either as a function of time at 42°C or the abilityto tolerate a maximum temperature. The seedlings were eithernot heat preconditioned or heat preconditioned before the heatstress. In all cases cold hardened seedlings were more heattolerant than non or partially cold hardened seedlings. Heatpreconditioning had no effect on the heat tolerance of naturallycold hardened seedlings. In contrast, seedlings cold hardenedin a controlled environment chamber, then heat preconditioned,were more heat tolerant than non preconditioned seedlings. Aheat shock of 36°C for 2 h increased the freezing toleranceof non hardened seedlings from –2.5°C to –4.5°C.Analysis of heat shock protein 70 (HSP70) gene expression indicatedthat the HSP70 gene was not induced by cold acclimation andtherefore not directly involved in the increased thermo toleranceobserved. A number of heat stable proteins, simple sugars andlong chain carbohydrate polymers accumulated during the coldacclimation process and may have a role in increasing heat toleranceas well as freezing tolerance. These data suggest cold hardeningincreases heat tolerance, however, a heat shock to non acclimatedseedlings only marginally increased the freezing tolerance ofPuma rye seedlings. ³Present address: Agriculture and Agri-Food Canada, 107 SciencePlace, Saskatoon SK S7N 0X2, Canada.     

Tolerance of Soil Bacterial Complexes to Salt Shock

Investigations showed that bacteria present in soil are resistant to one-day exposure to a saturated solution of ammonium nitrate and can well develop when transferred to laboratory nutrient media. The evaluated number of bacteria in NH₄NO₃-treated soil samples was nearly the same as in native soil samples, while it was 1.5–2.5 times smaller in the former than in the latter case when microbial succession in the soil samples was initiated by wetting them. Bacteria (particularly gram-negative ones) occurring at the early stages of succession were the most sensitive to salt stress. Bacteria in soil were found to be much more resistant to salt stress than the same bacteria isolated in pure cultures.     

Winter Avian Community and Sparrow Response to Field Border Width

Abstract: Transformations of agricultural practices in the southeastern United States have drastically reduced preexisting quantities of strip-cover habitat along field margins. The National Conservation Buffer Initiative has promoted the establishment of herbaceous field borders to restore wildlife benefits once provided by such habitat. We evaluated effects of native warm-season grass field border establishment and width on winter bird response. Narrow (approx. 8-m) field borders represented a marginal improvement to non-bordered margins that were cropped ditch to ditch, whereas wide (approx. 30-m) borders significantly enhanced total avian conservation value, abundance, species richness, and sparrow abundance compared to non- or narrow borders. Furthermore, presence of wide borders altered bird use of row-crop fields. We observed increased sparrow (Emberizidae) abundances in agricultural fields adjacent to wide borders, which likely resulted from enhanced waste grain foraging opportunities. Given these benefits to wintering farmland birds, we advocate the integration of herbaceous field border habitat in agricultural landscapes, particularly borders of enhanced width.     

Effect of Freeze-Thaw Cycles on Bacterial Communities of Arctic Tundra Soil

The effect of freeze-thaw (FT) cycles on Arctic tundra soil bacterial community was studied in laboratory microcosms. FT-induced changes to the bacterial community were followed over a 60-day period by terminal restriction fragment length polymorphism (T-RFLP) profiles of amplified 16S rRNA genes and reverse transcribed 16S rRNA. The main phylotypes of the active, RNA-derived bacterial community were identified using clone analysis. Non-metric multidimensional scaling ordination of the T-RFLP profiles indicated some shifts in the bacterial communities after three to five FT cycles at −2, −5, and −10°C as analyzed both from the DNA and rRNA. The dominating T-RFLP peaks remained the same, however, and only slight variation was generally detected in the relative abundance of the main T-RF sizes of either DNA or rRNA. T-RFLP analysis coupled to clone analysis of reverse transcribed 16S rRNA indicated that the initial soil was dominated by members of Bacteroidetes, Acidobacteria, Alpha-, Beta-, and Gammaproteobacteria. The most notable change in the rRNA-derived bacterial community was a decrease in the relative abundance of a Betaproteobacteria-related phylotype after the FT cycles. This phylotype decreased, however, also in the control soil incubated at constant +5°C suggesting that the decrease was not directly related to FT sensitivity. The results indicate that FT caused only minor changes in the bacterial community structure.     

Starvation-Induced Thermal Tolerance as a Survival Mechanism in a Psychrophilic Marine Bacterium

Carbon-starved cultures of strain Ant-300, a psychrophilic marine vibrio isolated from the Antarctic Convergence, were compared with their nonstarved counterparts for resistance to heat. Specifically, starved and unstarved cells were exposed to 17°C, which is 4°C above the maximum growth temperature, and compared with cells maintained at the optimum temperature (5 to 7°C). Total cell counts, direct viable-cell counts, and plate counts were monitored. At a temperature of 17°C, viability (as indicated by plate counts) was lost within 40 h, with direct viable-cell counts indicating less than 5% viability at this time. However, when cells were carbon starved for 1 week prior to heat challenge, significant plateability was maintained for more than 6 days; direct viable-cell counts of starved cells maintained at 17°C indicated the presence of viable cells for at least 12 days. Because starvation is the normal physiological state of copiotrophic, heterotrophic bacteria in oligotrophic marine waters, these data suggest that starvation conditions may be a significant factor in providing heat tolerance to psychrophiles.     

4种藤本植物对锰污染土壤的耐受性及其生理响应

为筛选对Mn污染土壤具有较高耐受性的藤本植物并探讨其抗Mn生理机制,以薜荔、忍冬、五叶地锦和络石扦插苗为材料,采用模拟Mn污染土壤培养法,配置Mn含量分别为3 000mg/kg(T1)、6 000mg/kg(T2)、9 000mg/kg(T3)和12 000mg/kg(T4)的Mn污染土壤,以不加Mn的土壤为空白对照(CK),研究不同浓度Mn胁迫对4种藤本植物生物量、生长量、不同部位Mn含量、叶绿素含量、丙二醛(MDA)含量及超氧化物歧化酶(SOD)、过氧化物酶(POD)、过氧化氢酶(CAT)活性的影响,并对其耐性指数(Ti)、转移系数(TF)、生物富集系数(BCF)进行了比较分析。结果表明:(1)随着Mn处理浓度的升高,薜荔、五叶地锦、忍冬、络石的生物量、生长量总体呈现下降的趋势,平均耐性指数依次分别为82.48%、84.86%、89.21%和95.41%。(2)地上部分、根系的Mn含量随着Mn处理浓度的增加总体呈现升高的趋势,且根系的Mn含量都高于地上部分,TF值均小于1,地上部分和根系的BCF平均值均依次为:络石忍冬五叶地锦薜荔。(3)随土壤Mn处理浓度的升高植物叶绿素含量总体呈现下降的趋势,MDA含量持续上升,而SOD活性、POD活性、CAT活性呈先升后降的趋势,在T4处理时络石的叶绿素含量和三种抗氧化酶活性下降幅度、MDA上升幅度均低于其他3种植物。研究表明,络石较其他3种植物具有更高的Mn耐受性以及Mn转移能力和富集能力,可作为Mn尾矿污染土壤修复的潜力植物。     

Developmental Regulation of Low-temperature Tolerance in Winter Wheat

Vernalization and photoperiod genes have wide-ranging effectson the timing of gene expression in plants. The objectives ofthis study were to (1) determine if expression of low-temperature(LT) tolerance genes is developmentally regulated and (2) establishthe interrelationships among the developmental stages and LTtolerance gene expression. LT response curves were determinedfor three photoperiod-sensitive LT tolerant winter wheat (Triticumaestivum L. em Thell) genotypes acclimated at 4 °C under8 h short-day (SD) and 20 h long-day (LD) photoperiods from0 to 112 d. Also, three de-acclimation and re-acclimation cycleswere used that bridged the vegetative/reproductive transitionpoint for each LD and SD photoperiod treatment. A vernalizationperiod of 49 d at 4 °C was sufficient for all genotypesto reach vernalization saturation as measured by minimum finalleaf number (FLN) and confirmed by examination of shoot apicesdissected from crowns that had been de-acclimated at 20 °CLD. Before the vegetative/reproductive transition, both theLD- and SD-treated plants were able to re-acclimate to similarLT₅₀(temperature at which 50% of the plants are killed by LTstress) levels following de-acclimation at 20 °C. De-acclimationof LD plants after vernalization saturation resulted in rapidprogression to the reproductive phase and limited ability tore-acclimate. The comparative development of the SD (non-flowering-inductivephotoperiod) de-acclimated plants was greatly delayed relativeto LD plants, and this delay in development was reflected inthe ability of SD plants to re-acclimate to a lower temperature.These observations confirm the hypothesis that the point oftransition to the reproductive stage is pivotal in the expressionof LT tolerance genes, and the level and duration of LT acclimationare related to the stage of phenological development as regulatedby vernalization and photoperiod requirements. Copyright 2001Annals of Botany Company Triticum aestivum L., wheat, low-temperature tolerance, vernalization, photoperiod, phenological development