The Influence of Season and Phenology on Freezing Tolerance in Silene acaulis L., a Subarctic and Arctic Cushion Plant of Circumpolar Distribution

Changes in the freezing tolerance for Silene acaulis L., a subarcticand arctic species of circumpolar distribution, were examinedto understand the extent of cold hardening and dehardening thatoccurs seasonally and with changes in plant phenology. Shootsof whole plants collected on a mountain ridge near Tromsø,Norway (69° N, 700 m above sea level) were frozen undercontrolled conditions at cooling rates of 3 to 4°C h^-1.The extent of freezing-induced injury was examined both by chlorophyllfluorescence and by visual inspection with a microscope. A freezingtolerance level of -30°C was observed in mid-winter, basedon a 50% lethal point for freezing injury. Loss of cold hardinesswas substantial in mid-summer, with freezing tolerance of -8·5to -9°C observed in mid-July. Plants still covered by snowin mid-July had a freezing tolerance of -12·5 to -13°C.The maintenance of a basic level of freezing tolerance throughoutthe summer may be adaptive in the northern latitude-regionsbecause of the occurrence of episodic frosts during the growingseason.Copyright 1993, 1999 Academic Press Silene acaulis L., Caryophyllaceae, freezing tolerance, chlorophyll fluorescence, cushion plant     

Effect of Temperature, Light, Nutrients and Dehardening on Abscisic Acid Induced Cold Hardiness in Bromus inermis Leyss Suspension Cultured Cells

The effects of culture conditions on abscisic acid (ABA)-inducedfreezing tolerance were determined in smooth bromegrass Bromusinermis Leyss cv. Manchar) cell suspension cultures. Bromegrasscultures initiated with 2 g fr wt of cells achieved maximumfreezing tolerances (greater than –32?C) at 25 to 30?Cin the presence of 75 to 100 µM ABA. High levels of freezingtolerance induced by ABA were correlated with high growth ratesat 25 and 30?C. In control cells, incubation at 10?C inducedoptimum levels of hardiness with minimal growth. Prolonged exposure(6 weeks) of cells to 3?C, with or without ABA, increased freezingtolerance only by several degrees. Exogenous ABA concentrationsgreater than 100 µM were not inhibitory to growth. Repeatedexposure to ABA, however, retarded growth and made the cellstolerant to temperatures below –40?C. Removal of ABA fromthe medium resulted in dehardening of the cells both at 25 and3?C. Nitrogen had a marginal effect on ABA-induced hardeningat 25?C, but inhibited age-dependent hardening of control cellcultures. Light had no effect on the freezing tolerance of culturedcells. Addition of 10% sucrose, 30 min prior to freezing, tobromegrass cells treated with ABA for 4 days increased freezingtolerance more than 15?C. These observations are discussed inrelation to the contrasting behaviour of the low temperatureand photoperiod dependent cold acclimation of plants (Received July 14, 1989; Accepted October 23, 1989)     

Gene expression during cold and heat shock in wheat

Translatable messenger RNAs expression was compared in cold- and heat-stressed winter wheat (Triticum aestivum L. 'Fredrick' and 'Norstar') and spring wheat (T. aestivum L. 'Glenlea'). Polyadenylated RNA isolated from the crown and leaf tissues was translated in a wheat germ cell free system and the acidic and basic in vitro products were resolved by two-dimensional SDS-PAGE and autoradiography. The results showed that low temperature stress rapidly induced two groups of mRNAs. The first group was transient in nature and consists of 18 mRNAs that reached their highest levels of induction after 24 h of low temperature exposure and then decreased to undetectable levels. The second group consists of 53 mRNAs that were also induced or increased rapidly, but maintained their levels of expression during the 4 weeks required to induce freezing tolerance. Among those, at least 34 were expressed at higher levels in the freezing tolerant winter wheat compared with the less tolerant spring wheat. This suggests a possible relation between the expression of these mRNAs and the capacity of each genotype to develop freezing tolerance. In the case of heat shock, 50 mRNAs were induced or increased after 3 h at 40 degrees C. Among these, the expression of only six mRNAs was altered in a similar manner in the three genotypes by both treatments. The remaining mRNAs code for typical heat shock proteins which are different from those induced by low temperature. None of these mRNAs has been associated with the development of freezing tolerance. These results suggest that heat and cold stress are controlled by different genetic systems.     

Polysome Metabolism during Cold Acclimation in Wheat

The content, composition and biological activity of polysomesfrom three wheat genotypes were studied during cold acclimation.The structural integrity of the different polysome populationswas not affected by the hardening temperature. Polysomes werealso found to accumulate at higher level in cold hardened seedlingssuggesting a high protein synthesis capacity during the acclimationperiod. The in vitro translation of polysome-bound mRNAs inthe wheat germ cell-free system showed a high translation potentialof polysomes from cold hardened seedlings compared to that ofcontrol. The electrophoretic analysis of the translation productsby two-dimensional SDS-PAGE revealed the induction of severalnew mRNAs in cold hardened wheat seedlings. The presence ofthese new messengers in the polysomal fraction suggests thatnew messages have already been processed, transported and preferentiallyselected for translation by the ribosomes. The most importantchange was the induction and pronounced synthesis of four peptides[one high mol wt peptide of 200 kDa (pI 6.5) and three smallerones of 58 (pI 7.0), 48 (pI 7.1) and 48 (pI 7.2) kDa respectively]in the freezing tolerant cultivar Norstar. These specific polypeptideswere absent in the freezing sensitive cultivar Glenlea suggestingthat their induction and expression was associated with thefreezing tolerance capacity. (Received January 19, 1990; Accepted August 24, 1990)     

Synthesis of Freezing Tolerance Proteins in Leaves, Crown, and Roots during Cold Acclimation of Wheat

Protein synthesis was studied in leaves, crown, and roots during cold hardening of freezing tolerant winter wheat (Triticum aestivum L. cv Fredrick and cv Norstar) and freezing sensitive spring wheat (T. aestivum L. cv Glenlea). The steady state and newly synthesized proteins, labeled with [³⁵S]methionine, were resolved by one- and two-dimensional polyacrylamide gels. The results showed that cold hardening induced important changes in the soluble protein patterns depending upon the tissue and cultivar freezing tolerance. At least eight new proteins were induced in hardened tissues. A 200 kilodalton (kD) (isoelectric point [pl] 6.85) protein was induced concomitantly in the leaves, crown, and roots. Two proteins were specifically induced in the leaves (both 36 kD, pl 5.55 and 5.70); three in the crown with M_r 150 (pl 5.30), 45 (pl 5.75), and 44 kD (pl > 6.80); and two others in the roots with M_r 64 (pl 6.20) and 52 kD (pl 5.55). In addition, 19 other proteins were synthesized at a modified rate (increased or decreased) in the leaves, 18 in the crown and 23 in the roots. Among the proteins induced or increased in hardened tissues, some were expressed at a higher level in the freezing tolerant cultivars than in the sensitive one, indicating a correlation between the synthesis and accumulation of these proteins and the degree of freezing tolerance. These proteins, suggested to be freezing tolerance proteins, may have an important role in the cellular adaptation to freezing.     

Cold Acclimation, Freezing Resistance and Protein Synthesis in Alfalfa (Medicago sativaL. cv. Saranac)

Mohapatra, S. S., Poole, R. J. and Dhindsa, R. S. 1987. Coldacclimation, freezing resistance and protein synthesis in alfalfa(Medicago sativa L. cv. Saranac).—J. exp. Bot. 38: 1697–1703. Changes in freezing resistance (percent survival at —10°C), pattern of protein synthesis and translatable mRNApopulation during cold acclimation of alfalfa (Medicago sativaL. cv. Saranac) have been examined. Two days of cold acclimationat 4 °C increased freezing resistance from about 6% to 40%,protein content by 200% and total RNA content by 100%. Acclimationfor longer periods did not cause further increases in freezingresistance, protein content or RNA content. Examination of proteinchanges by sodium dodecyl sulphate-polyacrylamide gel electrophoresis(SDS-PAGE) coupled with protein staining, and by fluorographyof in vivo labelled proteins separated by SDS-PAGE, showed thatseveral proteins are increasingly or newly synthesized duringcold acclimation. Analysis of in vitro translation productsby SDS-PAGE and fluorography shows changes in the populationof translatable mRNAs. It is concluded that in this varietyof alfalfa cold acclimation for only 2 d is sufficient to confermaximum freezing resistance, and that changes in proteins duringcold acclimation are regulated most probably at the transcnptionallevel. Key words: Freezing resistance, protein synthesis, cold acclimation, SDS-PAGE, Medicago sativa L.     

Accumulation of 19-kDa Plasma Membrane Polypeptide during Induction of Freezing Tolerance in Wheat Suspension-Cultured Cells by Abscisic Acid

Suspension-cultured cells derived from immature embryos of winterwheat (Triticum aestivum L. cv. Chihoku) were used in experimentsdesigned to obtain clues to the mechanism of the ABA-induceddevelopment of freezing tolerance. Cultured cells treated with50 µM ABA for 5 d at 23°C acquired the maximum levelof freezing tolerance (LT50; -21.6°C). The increased freezingtolerance of ABA-treated cells was closely associated with theremarkable accumulation of 19-kDa polypeptides in the plasmamembrane. The 19-kDa polypeptide components were isolated bypreparative gel electrophoresis and were further separated intoone major (AWPM-19) and other minor polypeptide components byTricine-SDS-PAGE. N-terminal ami no acid sequence of AWPM-19was determined, and a cDNA clone encoding AWPM-19 was isolatedby PCR from the library prepared from the ABA-treated culturedcells. The cDNA clone (WPM-J) encoded a 18.9 kDa hydrophobicpolypeptide with four putative membrane spanning domains andwith a high pi value (10.2). Expression of WPM-1 mRNA was dramaticallyinduced by 50 µM ABA within a few hours. These resultssuggest that the AWPM-19 might be closely associated with theABA-induced increase in freezing tolerance in wheat culturedcells. (Received January 20, 1997; Accepted March 31, 1997)     

Accumulation of a High Molecular Weight Protein during Cold Hardening of Wheat (Triticum aestivum L.)

Electrophoretic patterns of soluble protein fractions from cold-tolerantwinter wheats (Triticum aestivum L. cv. Frederick and cv. Norstar)and cold-sensitive spring wheat (T. aestiaum L. cv. Glenlea)were analysed in hardened and unhardened plants. One and two-dimensionalgel electrophoresis analysis reveals that cold hardening conditionsinduce changes in the soluble protein patterns. The most importantis the accumulation of a high molecular weight protein in therange of 200 kDa. This protein accumulated at higher concentrationin cold-tolerant cultivars compared to the coldsensitive onesuggesting a correlation between the degree of freezing toleranceand the accumulation of this specific protein. In addition,the intensity of three protein bands (mol wt 48, 47 and 42 kDa)increased while that of five others (mol wt 93, 89, 80, 67 and63 kDa) decreased during hardening. These changes occured inthe three cultivars suggesting that they are part of the metabolicadjustments in response to low temperature rather than a specificchange associated with the development of cold hardiness. (Received April 23, 1987; Accepted June 5, 1987)     

Heat-Stable COR (Cold-Regulated) Proteins Associated with Freezing Tolerance in Spinach

While most soluble proteins are coagulated by heating at 100°Cfor 10 minutes, some highly hydrophilic COR (Cold-regulated)proteins remain soluble in aqueous solution (Lin et al. 1990).We report here changes in levels of heat-stable proteins andtheir mRNAs during cold acclimation of spinach (Spinacia oleraceaL.). We analyzed heat-stable proteins and the heat-stable translationproducts from poly(A)⁺RNA generated in a wheat germ system.Heat-stable COR proteins with molecular masses of 140 kDa and85 kDa (CORs 140 and 85), were detected in the leaves of cold-acclimatedplants. Increased levels of CORs 140 and 85 correlated withthe development of freezing tolerance during cold acclimation.Interestingly, CORs 140 and 85 accumulated specifically in theleaves and stems and not in the roots of the cold-acclimatedplants. Consistent with this observation, freezing tolerancewas also induced in leaves and stems, but not in roots. Thesedata strongly suggest that CORs 140 and 85 are closely associatedwith freezing tolerance. Accumulation of COR 85 was also inducedby exogenous ABA, drought, and wounding. The possible rolesof CORs 140 and 85 in plants acclimating to low temperatureis given attention. (Received June 11, 1992; Accepted September 1, 1992)     

Cold-Induced Alterations in Plasma Membrane Proteins That are Specifically Related to the Development of Freezing Tolerance in Cold-Hardy Winter Wheat

The objective of this study was to identify plasma membraneproteins that are specifically induced by cold acclimation inwheat (Triticum aestivum L.). Two cultivars with a marked differencein the genetic ability to cold-acclimate, namely, spring wheat(cv. Chinese Spring) and winter wheat (cv. Norstar), were usedas the experimental material. After four weeks of growth ina cold chamber, the freezing tolerance in the shoots of winterwheat increased to –18°C, whereas it increased onlyto –8°C in the shoots of spring wheat. In the caseof roots from both cultivars, freezing tolerance increased onlyslightly after the growth in the cold environment. Cold acclimationinduced remarkable changes in the electrophoretic patterns ofplasma membrane proteins which depended on both the cultivarand the tissue examined. Levels of polypeptides with molecularmasses from 22 to 31 kDa decreased in both the root and shootplasma membranes from both cultivars. Among these polypeptides,levels of those of 28 and 26 kDa decreased abruptly after oneweek of cold acclimation. By contrast, levels of polypeptidesof 89, 83, 52, 23, 18 and 17 kDa increased specifically in theshoots of winter wheat. The increases in the levels of the 23-,18- and 17-kDa polypeptides were proportional to the developmentof freezing tolerance. Freeze-fracture electron microscopy ofplasma membranes from shoot cells revealed that the number ofintramembrane particles on the fracture faces decreased markedlyin winter wheat after cold acclimation, but to a lesser extentin spring wheat. These results suggest that the plasma membranesmight undergo molecular reorganization during cold acclimation. ¹Contribution no. 3709 from the Institute of Low TemperatureScience, Hokkaido University.     

Expression of a cold-responsive Lt-Cor gene and development of freezing tolerance during cold acclimation in wheat (Triticum aestivum L.).

Time-courses of the development of freezing tolerance and the expression of a cold-responsive gene wlt10 were monitored during cold acclimation in wheat (Triticum aestivum L.). Bioassay showed that cold acclimation conferred much higher freezing tolerance on a winter cultivar than a spring cultivar. Northern blot analysis showed that the expression of wlt10 encoding a novel wheat member of a cereal-specific LT-COR protein family was specifically induced by low temperature. A freezing-tolerant winter cultivar accumulated the mRNA more rapidly and for a longer period than a susceptible spring cultivar. The increase in the amount of mRNA was temporary but the peak occurred at the time when the maximum level of freezing tolerance was attained. The mRNA accumulated more in the leaves than in the roots, and different light/dark regimes modulated the level of mRNA accumulation. Genomic Southern blot analyses using the nulli-tetrasomic series showed that the wlt10 homologues were located on the homologous group 2 chromosomes.     

Early Developments in RNA, Protein, and Sugar Levels during Cold Stress in Winter Rye (Secale cereale) Leaves

Changes in freezing tolerance of winter rye (Secale cerealeL. cv. Voima) were determined for leaf tissues during a 1-weekcold stress, which was performed by transferring the 7-d-oldseedlings from a greenhouse (25°C, long day) to 3°Cand short day conditions. The development of cold hardeningwas shown by using an ion leakage test and by determining theamounts of carbohydrates, soluble proteins and RNA. The firstevidence of the development of freezing resistance was foundafter 1 d at low temperature, i.e. an LT₅₀ value increased from-5 to -7°C. Plants cold treated for 7 d reached an LT₅₀value of -9°C. This increase in freezing tolerance was foundto be associated with the increased levels of soluble carbohydrates,total RNA and soluble proteins. These metabolic changes indicatethe association with adjustment of growth and cell metabolismto low temperatures at the beginning of cold acclimation ofwinter rye.Copyright 1994, 1999 Academic Press Secale cereale L., winter rye, cold stress, proteins, RNA, sugars     

Freezing Tolerance and Alteration of Translatable mRNAs in Alfalfa (Medicago sativa L.) Hardened at Subzero Temperatures

We analyzed changes in populations of translatable mRNAs occurringin crowns of the cold-tolerant alfalfa (Medicago sativa L.)cv. Apica (CT) and the cold-sensitive cv. CUF-101 (CS) aftertheir acclimation at low nonfreezing temperatures and at subzerotemperatures. Both cultivars showed very similar translationprofiles under all treatments. Low temperatures induced significantchanges in the populations of translatable mRNAs. We observeda relationship between the accumulation of cold-regulated (COR)translation products and freezing tolerance within cultivars.Moreover, at least three COR translation products were specificto the CT and might be related to hardiness potential in alfalfa.Whereas extension of the cold acclimation period at 2C reducedcold tolerance, incubation at subzero temperatures increasedor maintained freezing tolerance. This increased hardiness wasassociated with enhanced translation of COR polypeptides andalso with the appearance of new translatable mRNAs. This is,to our knowledge, the first report of altered gene expressionin plants incubated at subzero temperatures. Marked changesin populations of translatable mRNAs at temperatures below freezingmight be related to previous reports that alfalfa achieves maximumhardiness under snow cover when the soil has frozen. Translationin the presence of [³H]glycine showed that a large proportionof the COR genes encode for glycine-rich proteins (GRPs) andthat some of the GRPs are specific to the CT. (Received May 29, 1992; Accepted October 13, 1992)     

Exogenous 4-hydroxybenzoic acid and salicylic acid modulate the effect of short-term drought and freezing stress on wheat plants

Exogenous salicylic acid has been shown to confer tolerance against biotic and abiotic stresses. In the present work the ability of its analogue, 4-hydroxybenzoic acid to increase abiotic stress tolerance was demonstrated: it improved the drought tolerance of the winter wheat (Triticum aestivum L.) cv. Cheyenne and the freezing tolerance of the spring wheat cv. Chinese Spring. Salicylic acid, however, reduced the freezing tolerance of Cheyenne and the drought tolerance of Chinese Spring, in spite of an increase in the guaiacol peroxidase and ascorbate peroxidase activity. The induction of cross tolerance between drought and freezing stress was observed: drought acclimation increased the freezing tolerance of Cheyenne plants and cold acclimation enhanced the drought tolerance. The induction of drought tolerance in Cheyenne was correlated with an increase in catalase activity.     

Regulation of a wheat actin-depolymerizing factor during cold acclimation

We have previously shown that the wheat (Triticum aestivum) TaADF gene expression level is correlated with the plants capacity to tolerate freezing. Sequence analysis revealed that this gene encodes a protein homologous to members of the actin-depolymerizing factor (ADF)/cofilin family. We report here on the characterization of the recombinant TaADF protein. Assays for ADF activity showed that TaADF is capable of sequestering actin, preventing nucleotide exchange, and inducing actin depolymerization. In vitro phosphorylation studies showed that TaADF is a substrate for a wheat 52-kD kinase. The activity of this kinase is modulated by low temperature during the acclimation period. Western-blot analyses revealed that TaADF is expressed only in cold-acclimated Gramineae species and that the accumulation level is much higher in the freezing-tolerant wheat cultivars compared with the less tolerant ones. This accumulation was found to be regulated by a factor(s) encoded by a gene(s) located on chromosome 5A, the chromosome most often found to be associated with cold hardiness. The induction of an active ADF during cold acclimation and the correlation with an increased freezing tolerance suggest that the protein may be required for the cytoskeletal rearrangements that may occur upon low temperature exposure. These remodelings might be important for the enhancement of freezing tolerance.     

Is microtubule disassembly a trigger for cold acclimation?

Cold acclimation was followed in three cultivars of winter wheat (Triticum aestivum L.) that differ in freezing tolerance, using root growth as the indicator. During acclimation (followed through 7 d at 4 degrees C), growth rate progressively recovered. The recovery was fast in the tolerant, slow in the sensitive cultivars. The development of freezing tolerance was followed by a challenging cold shock administered after various time intervals of acclimation. Acclimation proceeded faster in the tolerant cultivars. Microtubules were monitored during the acclimation period. A rapid, but transient partial disassembly in the tolerant cultivars preceded the formation of cold-stable microtubules and the recovery of growth rate. In contrast, this transient disassembly was absent in the sensitive cultivar. When a transient disassembly was artificially generated by a pulse-treatment with the antimicrotubular herbicide pronamide, this could induce freezing tolerance. The appearance of cold-stable microtubules was accompanied by a reduced abundance of type TUA1/2 alpha-tubulin isotypes. These findings are discussed with respect to a role of microtubule disassembly in the sensing of low-temperature stress.