Freeze or dehydrate: only two options for the survival of subzero temperatures in the arctic enchytraeid<Emphasis Type="Italic"> Fridericia ratzeli</Emphasis>

Hygrophilic soil animals, like enchytraeids, overwintering in frozen soil are unlikely to base their cold tolerance on supercooling of body fluids. It seems more likely that they will either freeze due to inoculative freezing, or dehydrate and adjust their body fluid melting point to ambient temperature as has been shown for earthworm cocoons and Collembola. In the present study we tested this hypothesis by exposing field-collected adult Fridericia ratzeli from Disko, West Greenland, to freezing temperatures under various moisture regimes. When cooled at –1 °C min^–1 under dry conditions F. ratzeli had a mean temperature of crystallisation (T_c) of –5.8 °C. However, when exposed to temperatures above standard T_c for 22 h, at –4 °C, most individuals (90%, n= 30) remained unfrozen. Slow cooling from –1 °C to –6 °C in vials where the air was in equilibrium with the vapour pressure of ice resulted in freezing in about 65% of the individuals. These individuals maintained a normal body water content of 2.7–3.0 mg mg^–1 dry weight and had body fluid melting points of about –0.5 °C with little or no change due to freezing. About 35% of the individuals dehydrated drastically to below 1.1 mg mg^–1 dry weight at –6 °C, and consequently had lowered their body fluid melting point to ca. –6 °C at this time. Survival was high in both frozen and dehydrated animals at –6 °C, about 60%. Approximately 25% of the animals (both frozen and dehydrated individuals) had elevated glucose concentrations, but the mean glucose concentration was not increased to any great extent in any group due to cold exposure. The desiccating potential of ice was simulated using aqueous NaCl solutions at 0 °C. Water loss and survival in this experiment were in good agreement with results from freezing experiments. The influence of soil moisture on survival and tendency to dehydrate was also evaluated. However, soil moisture ranging between 0.74 g g^–1 and 1.15 g g^–1 dry soil did not result in any significant differences in survival or frequency of dehydrated animals even though the apparent wetness and structure of the soil was clearly different in these moisture contents.Abbreviations DW dry weight - FW fresh weight - MP melting point - RH relative humidity - Tc crystallisation temperatures - WC water contentCommunicated by I.D. Hume     

A fine-structural study of the freeze-preservation of plant tissue cultures

Summary Suspension culture cells of sycamore (Acer pseudoplatanus L.) and carrot (Daucus carota L.) were frozen to ultralow temperatures under rapid ( 100 °C s^–1) and slow, controlled (1 or 2 °C min^–1) rates, in the presence and absence of cryoprotective compounds. After storage at –196 °C, cells were recovered by thawing either slowly, in air at room temperature (ca. 20 °C min^–1) or rapidly, in a water bath at 40 °C (ca. 100 °C min^–1). The ultrastructure of the thawed cells was examined by thin-sectioning and compared with unfrozen controls and cells examined in the frozen state. Cells frozen rapidly, in the presence of cryoprotectants, or frozen slowly in their absence, suffered serious ultrastructural damage and a total loss of viability. Carrot cells frozen at a rate of 2 °C min^–1 in the presence of cryoprotectants and thawed at either rate, yielded up to 70% of viable cells. The recovered aggregates of carrot cells comprised some centrally located, seriously damaged cells and, at the periphery, groups of cells with a high electron opacity neighbouring well preserved cells, showing little ultrastructural modification compared with unfrozen controls. The highest rate of survival of sycamore cells (ca. 30%) was observed when they were frozen at a rate of 1 °C min^–1 and thawed rapidly. In all recoverd cells of sycamore some ultrastructural modifications were evident. These included: dilation of mitochondria, plastids, golgi and ER cisternae and the nuclear envelope, decrease in polysomes, increase in nuclear and cytoplasmic microfilaments and changes in nuclear and nucleolar granularity. The probable causes and timing of the ultrastructural changes and their effects on the potential for regrowth of the recovered cells are discussed.     

Cryopreservation of periwinkle,Catharanthus roseus cells cultured in vitro

A procedure for prolonged cryogenic storage of periwinkle cell cultures is described. Cells derived from periwinkle, Catharanthus roseus (L.) G. Don, and subcultured as suspension in 1-B5C nutrient medium have been frozen, stored in liquid nitrogen (–196°C) for 11 weeks, thawed and recultured. Maximal survival was achieved when 3–4 day-old cells precultured for 24 h in nutrient medium with 5% DMSO were frozen at slow cooling rates of 0.5 or 1°C/min prior to storage in liquid nitrogen. The only loss in viability of cells occurred subsequent to treatment with DMSO. Abbreviations: DMSO, dimethylsulfoxide; 2,4-D, 2,4-dichlorophenoxyacetic acid; TTC, triphenyltetrazolium chloride.NRCC No. 20082     

Vorläufige Ergebnisse von Untersuchungen an eingefrorenen und bei tiefen Temperaturen bestrahlten Lymphozyten

Zusammenfassung Lymphozytenkulturen werden nach Zugabe von Glyzerin als Gefrierschutzsubstanz zunächst gemeinsam mit ungefähr 1 °C/min Abkühlgeschwindigkeit bis zum vollständigen Erstarren eingefroren und dann mit verschiedener Geschwindigkeit ( 200 °C pro min und 3 bis 5 °C/min) auf verschieden tiefe Temperaturen (–22, –80 und –196 °C) gebracht. Alle eingefrorenen Proben weisen nach 24 h Kulturdauer eine kleinere, nach 48 h Kulturdauer eine wesentlich höhere Mitoserate als die Kontrollgruppe (unbehandelte, nicht eingefrorene Plasmaproben) auf. In den schnell auf –196 °C abgekühlten Proben wurden in beiden Fällen (24 h und 48 h Kulturdauer) keine Metaphaseplatten gefunden. Die Zellkonzentrationen waren nur bei den schnell auf –196 °C abgekühlten Kulturen stark verringert. Die Chromosomenaberrationsrate der eingefrorenen Kulturen ist nicht signifikant erhöht.

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Preliminary results of investigations of lymphocytes, frozen and irradiated at low temperaturesI. The effects of cooling rate, low temperature, and incubation time on frozen lymphocytes

Summary Peripheral human lymphocytes were cooled to the temperature of solidification at a rate of less than 1 °C/min using glycerol as a protective agent against the effects of freezing. After solidification at temperatures of –10 to –15 °C and cooling to about –22 °C one group of the samples was thawn and the others were cooled rapidly to –80 or –196 °C by immersion into solid carbon dioxide or liquid nitrogen. Other samples of the frozen cell suspension were cooled down to the same temperatures much slower at a cooling rate of 3 to 5 °C/min. After rapid thawing in a 25 °C water bath the cell suspensions were removed from glycerol and cultured for 24 or 48 h before stopping mitoses by adding colchicine. The samples frozen at –22 °C, the samples cooled both rapidly and slowly to –79 °C, and the ones cooled slowly to –196 °C showed a lower rate of mitosis when colchicine was added after 24 h and a significantly higher rate of mitosis after 48 h of incubation before adding colchicine as compared to the controls (untreated, unfrozen plasma). In the culture frozen rapidly to –196 °C no metaphases could be found. The cell concentrations before and after freezing showed no significant differences except those of the culture frozen rapidly to –196 °C. The chromosome aberration rate is not significantly increased.

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Herrn Prof. Dr. H. A. Künkel zum 60. Geburtstag gewidmet.     

Effect of four fluctuating temperature regimes on cui-ui,Chasmistes cujus,survival from egg fertilization to swim-up,and size of larvae produced

Synopsis We evaluated cui-ui,Chasmistes cujus, swim-up success, time of hatching and swim-up, and size of larvae at swim-up under four fluctuating temperature regimes (8.9–15.0, 12.2–18.3, 15.0–21.1, and 17.8–23.9° C). The greatest swim-up success was at the 8.9–15.0° C regime and the lowest at the 15.0–21.1° C regime. Hatching and swim-up time varied inversely with incubation temperature. The largest (and presumably the most fit) larvae were in the 8.9–15.0° C treatment, whereas the smallest were in the 17.8–23.9° C treatment. Cui-ui appeared best adapted to the coolest of the four temperature regimes.     

Validation of Radiation Dose Received by Frozen Unprocessed and Processed Bone during Terminal Sterilisation

Fresh frozen femoral heads (FH) and frozen processed bone (FP) are widely used as a source of allograft bone. The FP bone and some of the FH are terminally sterilised by the National Blood Service Tissue Services (NSBTS), via application of a minimum 25 kGy gamma radiation dose. To comply with the Guidelines for the Blood Transfusion Services in the United Kingdom (2002), frozen musculoskeletal tissue must be maintained below −40 °C during storage and transit. In practice, NBSTS stores bone long-term in −80 °C freezers. During transport for irradiation, a temperature of circa −79 °C is maintained by packing the bone in dry ice. An evaluation of the radiation dose received by bone has previously been made via dosimeters located within the tissue and dry ice, however, some evidence suggests that low temperature can influence the accuracy of the dosimeter readings. The aim of this study was to determine the actual radiation dose received by FH and FP bone during the irradiation process. This was accomplished by comparing radiation dose readings from dosimeters placed in dry ice with dosimeters placed in a dry ice substitute of similar dimensions and density i.e., polytetrafluoroethylene (PTFE) at ambient temperature. New packing formats were developed for both FH and FP bone such that 15 FH or 3 kg of FP bone could be irradiated in one transport box at any given time in a standardised fashion. The data show that low temperature consistently increased dosimeter readings 10–27%, and that radiation dose always fell within the range of 25–40 kGy (FH = 25.1–35.7 kGy; FP bone = 25.2–32.4 kGy).     

Physiology of cold hardiness in cocoons of five earthworm taxa (Lumbricidae: Oligochaeta)

Earthworm cocoons are mostly found in the uppermost soil layers and are therefore often exposed to low temperatures during winter. In the present study, cocoons of five taxa of earthworms were investigated for their tolerance to freezing, melting points of cocoon fluids and dehydration of cocoons when exposed to a frozen environment. Embryos of the taxa investigated were freeze intolerant. The melting points of fully hydrated cocoon fluids were high (above –0.3°C) and thermal hysteresis factors were absent. Exposure to a frozen environment caused the cocoons to dehydrate drastically and dehydrated cocoons showed significantly lower super-cooling points than fully hydrated cocoons, reducing the risk of freezing for dehydrated cocoons. It is proposed therefore that the cold-hardiness strategy of the earthworm cocoons is based on dehydration upon exposure to subzero temperatures in the frozen environment. Cocoons of three surface-dwelling taxa, Dendrobaena octaedra, Dendrodrilus rubidus tenuis and Dendrodrilus rubidus norvegicus had lower supercooling points and survived frost exposure better than cocoons of two deeper-dwelling taxa, Aporrectodea caliginosa and Allolobophora chlorotica. One of the investigated taxa, D. r. norvegicus, was collected from a cold alpine habitat. However, it was not more cold hardy than the closely related D. r. tenuis collected from a lowland temperate habitat. D. octaedra was the most cold hardy taxon, its cocoons being able to withstand –8°C for 3 months and –13.5°C for 2 weeks in frozen soil.Abbreviations dw dry weight - fw fresh weight - SCP supercooling point     

A Comparative Analysis of the Ice Nucleation Activity of Pseudomonad Cells and Lipopolysaccharides

The paper deals with the study of the ice nucleation activity of the cells, extracellular lipopolysaccharides (ELPSs), lipopolysaccharides (LPSs), and LPS structural components (lipid A, core oligosaccharide, and O-specific polysaccharide) of Pseudomonas fluorescens, P. syringae, P. fragi, and P. pseudoalcaligenes. Aqueous suspensions of intact cells of P. syringae IMV 1951 and IMV 185 began to freeze at –1 and –4°C, respectively. This suggests that these cells possess ice nucleation activity. Aqueous cell suspensions of two other strains, P. fluorescens IMV 1433 and IMV 2125, began to freeze at lower temperatures than did distilled water (–9°C), which suggests that the cells of these strains possess antifreeze activity. The ice nucleation activity of the bacterial strains studied did not show any correlation with their taxonomic status. The ice nucleation activity of ELPSs depended little on their concentration (within a concentration range of 0.2–0.4%). In most cases, the ice nucleation activity of ELPSs, LPSs, and LPS structural components differed from that of the intact cells from which these biopolymers were obtained. This may indicate that the biopolymers under study play a role in ice nucleation but this role is not crucial. The relationship between the structure of LPSs and their effect on ice nucleation is discussed.     

Effect of incubation temperature on green sturgeon embryos, <Emphasis Type="Italic">Acipenser medirostris</Emphasis>

Regulation of river flow and the amount of winter rainfall are the major factors affecting the water temperature of the spawning grounds, for green sturgeon in the Klamath River. During the primary spawning period of green sturgeon, mid-April to June, the water temperature may vary from 8 to 21°C. To estimate the potential implications of this modified thermal regime, we examined the survival and development in three progeny groups of green sturgeon embryos from zygote to hatch, at constant incubation temperatures (11–26°C). Temperatures 23–26°C affected cleavage and gastrulation and all died before hatch. Temperatures 17.5–22°C were suboptimal as an increasing number of embryos developed abnormally and hatching success decreased at 20.5–22°C, although the tolerance to these temperatures varied between progenies. The lower temperature limit was not evident from this study, although hatching rate decreased at 11°C and hatched embryos were shorter, compared to 14°C. The mean total length of hatched embryos decreased with increasing temperature, although their wet and dry weight remained relatively constant. We concluded that temperatures 17–18°C may be the upper limit of the thermal optima for green sturgeon embryos, and that the river thermal regime during dry years may affect green sturgeon reproduction.     

The distribution,structure, and composition of freshwater ice deposits in Bolivian salt lakes

Freshwater ice deposits are described from seven, high elevation (4117–4730 m), shallow (mean depth <30 cm), saline (10–103 g l^-1) lakes in the southwestern corner of Bolivia. The ice deposits range to several hundred meters in length and to 7 m in height above the lake or playa surface. They are located near the lake or salar margins; some are completely surrounded by water, others by playa deposits or salt crusts. Upper surfaces and sides of the ice deposits usually are covered by 20–40 cm of white to light brown, dry sedimentary materials. Calcite is the dominant crystalline mineral in these, and amorphous materials such as diatom frustules and volcanic glass are also often abundant.Beneath the dry overburden the ice occurs primarily as horizontal lenses 1–1000 mm thick, irregularly alternating with strata of frozen sedimentary materials. Ice represents from 10 to 87% of the volume of the deposits and yields freshwater (TFR <3 g l^-1) when melted. Oxygen isotope ratios for ice are similar to those for regional precipitation and shoreline seeps but much lower than those for the lakewaters. Geothermal flux is high in the region as evidenced by numerous hot springs and deep (3.0–3.5 m) sediment temperatures of 5–10°C. This flux is one cause of the present gradual wasting away of these deposits. Mean annual air temperatures for the different lakes probably are all in the range of -2 to 4°C, and mean midwinter temperatures about 5°C lower. These deposits apparently formed during colder climatic conditions by the freezing of low salinity porewaters and the building up of segregation ice lenses.     

Über die kalorischen Eigenschaften von gefrorenen Erythrozyten

Zusammenfassung Durch osmotische Schwellungen wurde der Wassergehalt menschlicher Erythrozyten in einem bestimmten Konzentrationsbereich verändert. Diese Erythrozyten mit unterschiedlichem Wassergehalt wurden in einer Ultrazentrifuge der Firma Christ dicht gepackt und bei einer Temperatur von –72 °C eingefroren. Anschließend wurde die mittlere Enthalpiedifferenz der Erythrozytensedimente mit einem Differential-Scanning-Kalorimeter der Firma Perkin-Elmer im Temperaturbereich von –47 °C bis 0 °C bestimmt. Beim Auftauen der Sedimente wurde kein Phasenübergang gemessen, der auf einen Schmelzvorgang einer eutektischen Mischung hinweist, wie er bei Salzlösungen auftritt. Unter bestimmten Annahmen führt eine Analyse der Meßergebnisse nach der Theorie binärer Mischungen zu der Aussage, daß ein erheblicher Teil des Zellwassers die kalorischen Eigenschaften des freien Wassers besitzt. Ein genauer Wert für die Masse des gebundenen Wassers kann im Rahmen der vorliegenden Messungen noch nicht angegeben werden.

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Caloric properties of frozen erythrocytes

Summary Erythrocytes with different water content were tightly packed in an Ultracentrifuge (Beckman) and frozen at a temperature of –72 °C. With a Differential Scanning Calorimeter (Perkin-Elmer) the enthalpy difference of the packed erythrocytes was measured in the temperature range from –47 °C to 0 °C. When the frozen sediments were thawed, there was no phase transition which corresponds to an eutectic mixture as it exists in salt solutions. Under certain conditions the analysis of the experimental results by means of the theory of binary mixtures shows that most of the water in the cells exhibits the caloric properties of the free water. At the present time a precise value for the mass of the bound water in the erythrocyte cannot be given. The thermodynamic analysis shows the contributions of the different components in the red blood cell to the measured partial enthalpy differences.

     

Urea and chloride sensitivities of coelacanth hemoglobin

Synopsis At pH 6.96–6.98, 20°C and in the absence of inorganic ions, the O₂ affinity of thawed Latimeria chalumnae hemoglobin was 1.53–1.86 mmHg; cooperativity was 1.00–1.13. These values are essentially the same as those in the literature for samples that had never been frozen. There was no clear effect of either urea (up to> 3M) or KCl (up to> 1M) on O₂ binding. Thus the hemoglobins of the coelacanth, as well as those of most of the elasmobranchs examined, are insensitive to urea, a major intracellular osmolyte in these groups and a denaturing agent in higher vertebrates. However, the absence of comparable information on more primitive hemoglobins and also on teleost hemoglobins precludes a clear evolutionary interpretation of the origin of urea sensitivity of the hemoglobins in higher vertebrates.     

Freezing Injury in Onion Bulb Cells: II. Post-thawing Injury or Recovery

Onion (Allium cepa L.) bulbs were subjected for 12 days to either a moderate freeze (−4 C) or a severe freeze (−11 C). They were then thawed slowly over ice. During 7 to 12 days following the thaw, the injury progressed with time in the severely frozen bulbs, but appeared completely repaired in the moderately frozen bulbs. This was shown by the following post-thawing changes.     

Extracellular ice and cell shape in frost-stressed cereal leaves: A low-temperature scanning-electron-microscopy study

Low-temperature scanning electron microscopy was used to examine transverse fracture faces through cereal leaf pieces subjected to frost. Specimens were studied before and after sublimation of the ice. The position of extracellular ice in the leaf was inferred from the difference between the specimen before and after sublimation and from ridges and points which occurred in the extracellular ice during sublimation. Steps in the fracture surface indicated that the fracture plane passed through the extracellular ice crystals as well as through cells and also helped identify extracellular ice. The cells in controls were turgid and extracellular ice was absent. Leaf pieces from hardened rye were excised and frost-stressed to-3.3°,-21° and-72°C, cooling at 2–12°·h^-1. Cell collapse and extracellular ice were evident at-3.3°C and increased considerably by-21° C. At-21° and-72°C the leaf pieces were mainly filled with extracellular ice and there were few remaining gas spaces. The epidermal and mesophyll cells were laterally flattened, perpendicular to their attachment to adjacent cells, and phloem and vascular sheath cells were more irregularly deformed. Leaf pieces from tender barley were cooled at 2°C·min^-1 to-20° C; they were then mainly filled with extracellular ice, and the cells were highly collapsed as in the rye. In rye leaves frozen to-3.6° C before excision, ice crystals occurred in peri-vascular, sub-epidermal and intervening mesophyll spaces. In rye leaf pieces frozen to-3.3° C after excision or to-3.6° C before excision, mesophyll cells were partly collapsed even when not covered by ice, indicating that collapse of the cell wall, as well as the enclosed protoplast, was driven by dehydration. No gas or ice-filled spaces were found between wall and the enclosed protoplast. It is suggested that this can be explained without invoking chemical bonding between cell wall and plasma membrane: when the wall pores are filled by water, the pore size would reduce vapour pressure so making penetration of the wall by ice or gas less likely.Abbreviations SEM scanning electron microscopy     

Effects of freezing on membranes and proteins in LNCaP prostate tumor cells

Fourier transform infrared spectroscopy (FTIR) and cryomicroscopy were used to define the process of cellular injury during freezing in LNCaP prostate tumor cells, at the molecular level. Cell pellets were monitored during cooling at 2 °C/min while the ice nucleation temperature was varied between − 3 and − 10 °C. We show that the cells tend to dehydrate precipitously after nucleation unless intracellular ice formation occurs. The predicted incidence of intracellular ice formation rapidly increases at ice nucleation temperatures below − 4 °C and cell survival exhibits an optimum at a nucleation temperature of − 6 °C. The ice nucleation temperature was found to have a great effect on the membrane phase behavior of the cells. The onset of the liquid crystalline to gel phase transition coincided with the ice nucleation temperature. In addition, nucleation at − 3 °C resulted in a much more co-operative phase transition and a concomitantly lower residual conformational disorder of the membranes in the frozen state compared to samples that nucleated at − 10 °C. These observations were explained by the effect of the nucleation temperature on the extent of cellular dehydration and intracellular ice formation. Amide-III band analysis revealed that proteins are relatively stable during freezing and that heat-induced protein denaturation coincides with an abrupt decrease in α-helical structures and a concomitant increase in β-sheet structures starting at an onset temperature of approximately 48 °C.     

Frozen-thawed human blood monocytes respond reproducibly to activation stimuli: Implications for screening of BRMs

The purpose of this study was to identify the optimal freezing conditions for human blood monocytes to allow their recovery and use forin vitro screening of activation stimuli. Human monocytes separated from buffy coats of healthy blood donors were suspended at a density of 1 × 10⁷ cells/ml in freezing medium consisting of 70% medium: 20% fetal bovine serum: 10% DMSO frozen in a stepdown freezer, and stored at –180°C. Monocytes were thawed at different times up to 4 months later. Viability was >90%. Fresh monocytes from different donors and frozen monocytes thawed at different times were incubated with different concentrations of lipopolysaccharide, muramyl tripeptide, muramyl dipeptide, or lipopeptide. Tumoricidal activity and IL-1 production of fresh monocytes varied greatly among the 5 different preparations. In contrast, the frozen monocytes (thawed at different times) produced uniform levels of antitumor activity and IL-1 production. These results show that monocytes recovered from frozen storage maintain their ability to respond to activation stimuli in a uniform and reproducible manner. Thus, the use of frozen-thawed monocytes is recommended for screening of macrophage activating agents.     

Homeothermy in adult salmon sharks, <Emphasis Type="Italic">Lamna ditropis</Emphasis>

Salmon sharks, Lamna ditropis, belong to a small group of sharks that possess vascular counter-current heat exchangers (retia mirabilia) allowing retention of metabolically generated heat, resulting in elevated body temperatures. The capacity of free-swimming lamnid sharks to regulate rates of heat gain and loss has not been demonstrated. Using acoustic telemetry, we recorded swimming depth and stomach temperature from four free-swimming salmon sharks in Prince William Sound, Alaska. Temperature data were obtained over time periods ranging from 3.8 to 20.7 h. Temperature profiles of the water column were obtained concurrently for use as estimates of ambient temperature. Mean stomach temperature among four individuals tracked ranged from 25.0 to 25.7°C. These sharks defended specific elevated temperatures regardless of changes in ambient temperature, which ranged from about 5–16°C. The maximum observed elevation of stomach temperature over ambient was 21.2°C. Because stomach temperatures were so strictly maintained relative to changes in ambient temperature, a thermal rate coefficient, k, (°C min^–1 °C thermal gradient^–1) for cooling of 0.053 min^–1 was obtained via a `control' experiment with a dead salmon shark. We show that free-swimming adult salmon sharks maintain a specific stomach temperature independent of changes in ambient temperature through a combination of physical and physiological means, and essentially function as homeotherms. This unique ability is probably the underlying factor in the evolutionary niche expansion of salmon sharks into boreal waters and in their ability to actively pursue and capture highly active prey such as salmon.     

Intracellular ice formation and growth in MCF-7 cancer cells

Direct cell injury in cryosurgery is highly related to intracellular ice formation (IIF) during tissue freezing and thawing. Mechanistic understanding of IIF in tumor cells is critical to the development of tumor cryo-ablation protocol. In aid of a high speed CMOS camera system, the events of IIF in MCF-7 cells have been studied using cryomicroscopy. Images of ‘darkening’ type IIF and recrystallization are compared between cells frozen with and without ice seeding. It is found that ice seeding has significant impact on the occurrence and growth of intracellular ice. Without ice seeding, IIF is observed to occur over a very small range of temperature (∼1 °C). The crystal dendrites are indistinguishable, which is independent of the cooling rate. Ice crystal grows much faster and covers the whole intracellular space in comparison to that with ice seeding, which ice stops growing near the cellular nucleus. Recrystallization is observed at the temperature from −13 °C to −9 °C during thawing. On the contrary, IIF occurs from −7 °C to −20 °C with ice seeding at a high subzero temperature (i.e., −2.5 °C). The morphology of intracellular ice frozen is greatly affected by the cooling rate, and no ‘darkening’ type ice formed inside cells during thawing. In addition, the intracellular ice formation is directional, which starts from the plasma membrane and grows toward the cellular nucleus with or without ice seeding. These results can be used to explain some findings of tumor cryosurgery in vivo, especially the causes of insufficient killing of tumor cells in the peripheral area near vessels.     

A new and rapid method of making permanent preparations of large numbers of house-dust mites for light microscopy

A method is described for the transfer to microslides of large numbers of mites extracted from house dust, in a single operation. Mites were frozen in water in a watch glass at –20°C. The ice was then everted onto a siliconeized microslide and the meltwater evaporated off on a hotplate at 55°C. Mounting medium and coverslip were then added in the normal way. The technique avoids the difficulty and tedium of transferring individual mites to a microslide and the haphzard and messy process of transfer in liquid medium via a pipette.     

Frozen storage stimulates the formation of embryo-like structures and elongating shoots in explants from mature Larix decidua and L. x eurolepsis trees

Branches were collected from a Larix decidua and a L. x eurolepis tree, both 36 years old, in mid-winter. These branches were placed in freezers at –5°C, –10°C, and –18°C. Primordial shoot explants were excised after 2 to 9 months of frozen storage. The material remained viable at all three temperatures for at least 9 months. The frozen storage stimulated formation of embryo-like structures that were capable of forming shoots with elongated stems.Abbreviations 1/2 LM half strength Litvay medium