Molecular control of cold acclimation in trees

Frost tolerance is an acquired characteristic of plants that is induced in response to environmental cues preceding the onset of freezing temperatures and activation of a cold acclimation program. In addition to transient acclimation to low non-freezing temperatures and enhancing survival to short frost episodes during the growth season, perennial woody plants need additionally to survive the cold winter months. Trees have evolved a complex dynamic process controlling the development of dormancy and freezing tolerance that secures accurate initiation and termination of the overwintering process. Although the phenology of overwintering has been known for decades, only recently has there been progress in elucidating the molecular mechanisms of dormancy and freezing tolerance development in perennial plants. Current molecular and genomic studies indicate that herbaceous annual and woody perennial plants share similar cold acclimation mechanisms. Both the signal processes controlling cold acclimation and the cold-regulated target genes appear to be shared by herbaceous and woody plants. However, the dormancy development during overwintering brings new players in the molecular control of seasonal cold acclimation of woody perennials.     

Interplay between low-temperature pathways and light reduction

Low temperature is one of the major factors that adversely affect crop yields by causing restraints on plant growth and productivity. However, most temperate plants have the ability to acclimate to cooler temperatures. Cold acclimation is a process which increases the freezing tolerance of an organism after exposure to low, non-freezing temperatures. The main trigger is a decrease in temperature levels, but light reduction has also been shown to have an important impact on acquired tolerance. Since the lowest temperatures are commonly reached during the night hours in winter time and is an annually recurring event, a favorable trait for plants is the possibility of sensing an imminent cold period. Consequently, extensive crosstalk between light- and temperature signaling pathways has been demonstrated and in this review interesting interaction points that have been previously reported in the literature are highlighted.Key words: cold acclimation, light-reduction, signaling pathways, photoperiodism, circadian clock, light quality     

Development of freezing tolerance in different altitudinal ecotypes of <Emphasis Type="Italic">Salix paraplesia</Emphasis>

Salix paraplesia was used as an experimental model to investigate the effect of short day photoperiod (SD) and low temperature (LT) on development of freezing tolerance and on endogenous abscisic acid (ABA) contents. We characterized differences in SD and LT-induced cold acclimation in three ecotypes from different altitudes. The results demonstrated that cold acclimation could be triggered by exposing the plants to SD or LT alone, and that a combination of the different treatments had an additive effect on freezing tolerance in all ecotypes studied. However, the high altitudinal ecotype was more responsive to SD and LT than the low altitudinal ecotype. Development of freezing tolerance induced by SD and LT was accompanied by changes in ABA contents which were ecotype-dependent. Although the stem had higher initial freezing tolerance, the leaves developed freezing tolerance more quickly than the stem and thus leaves may provide an interesting experimental system for physiological and molecular studies of cold acclimation in woody plants.     

Quantitative proteomic analysis of short photoperiod and low-temperature responses in bark tissues of peach (<Emphasis Type="Italic">Prunus persica</Emphasis> L. Batsch)

In the temperate climate of the northern hemisphere, winter survival of woody plants is determined by the ability to acclimate to freezing temperatures and to undergo a period of dormancy. Cold acclimation in many woody plants is initially induced by short photoperiod and low, non-freezing temperatures. These two factors (5°C and short photoperiod) were used to study changes in the proteome of bark tissues of 1-year-old peach trees. Difference in-gel electrophoresis technology, a gel-based approach involving the labeling of proteins with different fluorescent dyes, was used to conduct a quantitative assessment of changes in the peach bark proteome during cold acclimation. Using this approach, we were able to identify differentially expressed proteins and to assign them to a class of either ‘temperature-responsive’ or ‘photoperiod-responsive’ proteins. The most significant factor affecting the proteome appeared to be low temperature, while the combination of low temperature and short photoperiod was shown to act either synergistically or additively on the expression of some proteins. Fifty-seven protein spots on gels were identified by mass spectrometry. They included proteins involved in carbohydrate metabolism (e.g., enolase, malate dehydrogenase, etc), defense or protective mechanisms (e.g., dehydrin, HSPs, and PR-proteins), energy production and electron transport (e.g., adenosine triphosphate synthases and lyases), and cytoskeleton organization (e.g., tubulins and actins). The information derived from the analysis of the proteome is discussed as a function of the two treatment factors: low temperature and short photoperiod. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

A global reorganization of the metabolome in Arabidopsis during cold acclimation is revealed by metabolic fingerprinting

Many plants, including Arabidopsis , increase their freezing tolerance in response to low, non-freezing temperatures. This process is known as cold acclimation and involves many complex biochemical changes at the level of the metabolome. Our goal was to examine the effects of cold acclimation on the metabolome using a non-targeted metabolic fingerprinting approach. Multivariate data analyses indicate that, in Arabidopsis, a global reprogramming of metabolism occurs as a result of cold acclimation. By measuring an entire spectrum of putative metabolites based on mass-to-charge ( m / z ) ratios, vs. an individual or group of metabolite(s), a comprehensive, unbiased assessment of metabolic processes relative to cold acclimation was determined. Whereas leaves shifted to low temperature present metabolic profiles that are constantly changing, leaves developed at low temperature demonstrate a stable complement of components. Although it appears that some metabolic networks are modulated by the environment, others require development under low-temperature conditions for adjustment. Understanding how metabolism as a whole is regulated allows the integration of cellular, physiological and ecological attributes in a biological system, a necessity if complex traits, such as freezing tolerance, are to be modified by breeding or genetic manipulation.     

Effects of MPK3 and MPK6 kinases on the chloroplast architecture and function induced by cold acclimation in Arabidopsis

Photosynthesis Research - Exposure to low, non-freezing temperatures develops freezing tolerance in many plant species. Such process is called cold acclimation. Molecular changes undergone during...     

植物抗寒及其基因表达研究进展

植物经过逐渐降低的温度从而提高抗寒能力 ,这个过程被人们称为低温驯化。植物低温驯化过程是一个复杂的生理、生化和能量代谢变化过程 ,这些变化主要包括膜系统的稳定性、可溶性蛋白的积累和小分子渗透物质 ,比如脯氨酸、糖等 ,这些变化中的一些是植物抗寒必需的 ,而另外一些变化不是必需的。主要对冷害和低温生理生化变化、低温诱导表达基因的功能和作用、低温驯化的调节机制及其信号转导方面进行了综述。通过差别筛选 c DNA文库的方法已经鉴定了许多低温诱导表达、进而提高植物抗寒能力的基因 ,其中有脱水素、COR基因和 CBF1转录因子等。低温信号的感受、转导和调节表达是低温驯化的关键环节 ,低温信号的转导过程与干旱胁迫之间具有一定的交叉 ,这为利用 ABA等来提高植物抗寒能力成为可能 ,相信不久的将来人们可以通过提高植物抗寒能力从而增加经济产量成为现实。     

The organ-dependent abundance of a Solanum lipid transfer protein is up-regulated upon osmotic constraints and associated with cold acclimation ability

The expression of a gene isolated from cDNA differential screening and encoding a lipid transfer protein, designated as SsLTP1, was analysed at the protein level in two groups of Solanum species and lines differing in cold acclimation capacity. Under control conditions, the SsLTP1 was localized in all aerial organs of S. sogarandinum and S. tuberosum plants. Western analysis of subcellular extracts indicated that the protein possesses an intracellular localization. The protein abundance was found to vary as a function of organ type, the highest levels being observed in flowers, stems, and young leaves. During low temperature treatment, no change in protein level was noticed in either the S. tuberosum cv. Irga, which displays a low capacity for cold acclimation, or in a S. sogarandinum line which has lost its cold acclimation capacity. By contrast, low temperature induced a noticeable increase in SsLTP1 level in stems and leaves of S. sogarandinum and S. tuberosum cv. Ursus plants, which are able to acclimate to cold, indicating that SsLTP1 could participate in the processes leading to freezing tolerance. In other respects, SsLTP1 accumulation was observed both in cold-acclimating and in non-acclimating Solanum species when subjected to water deficit or to salt treatment. These data indicate that SsLTP1 gene expression is regulated in an organ-dependent manner and through distinct pathways under non-freezing low temperature and during osmotic treatments.     

木本植物抗寒性概述(综述)

抗寒性是植物适应和忍耐低温胁迫的能力,是复杂的多基因特征,其研究历史悠久。近些年的研究为理解植物如何响应外界低温并获得抗寒性提供了重要线索。本文概述了低温下木本植物冰核及其传播、深度过冷却与玻璃化形成、低温锻炼的生理学与遗传调控、低温锻炼的分子生物学与遗传工程等方面的进展,以期为人们在维持重要作物高产的同时提高其抗寒性提供参考。     

Cryoprotectin: a plant lipid-transfer protein homologue that stabilizes membranes during freezing

Plants from temperate and cold climates are able to increase their freezing tolerance during exposure to low non-freezing temperatures. It has been shown that several genes are induced in a coordinated manner during this process of cold acclimation. The functional role of most of the corresponding cold-regulated proteins is not yet known. We summarize our knowledge of those cold-regulated proteins that are able to stabilize membranes during a freeze-thaw cycle. Special emphasis is placed on cryoprotectin, a lipid-transfer protein homologue that was isolated from cold-acclimated cabbage leaves and that protects isolated chloroplast thylakoid membranes from freeze-thaw damage.     

Freezing exposure releases bud dormancy in Betula pubescens and B. pendula

Bud dormancy in woody plants is released by long-term exposure to non-freezing chilling temperatures, whereas freezing temperatures have been considered to have little or no effect. However, the present results demonstrate that short-term exposure to freezing can release bud dormancy in Betula pubescens (Ehrh.) and B. pendula (Roth). Short-term freezing during the dormancy induction phase improved the release of bud dormancy only if an adequate level of dormancy had been reached. In fully dormant or chilled plants both the percentage and the speed of bud-burst increased, the more so the lower the temperature. Our results rule out the possibility that endogenous abscisic acid could be directly involved in the physiological control of bud dormancy release. The fast, easily applicable method presented here for bud dormancy release could further investigations into the biochemical and biophysical background to the process. The mechanisms of bud dormancy release and its relationship to cold acclimation are discussed in the light of these results, as also are the implications of the findings for modelling of bud dormancy.     

Biochemical and physiological mechanisms related to cold acclimation and enhanced freezing tolerance in poplar plantlets

Temperature is one of the abiotic factors limiting growth and productivity of plants. In the present work, the effect of low non-freezing temperature, as inducer of 'cold acclimation', was studied in poplar. Actively growing plantlets of Populus tremula  ×  Populus tremuloides cv. Muhs 1 were used, and cold treatment consisted in whole plants exposure to 4°C in controlled conditions. Leaves of cold-treated poplars were shown to be acclimated, as an increase of their freezing tolerance was measured using electrolyte leakage. Chlorophyll fluorescence measurements revealed a decrease in photosystem II efficiency while the pigment contents of leaves did not vary. In contrast, after 1 week of cold exposure, an accumulation of pigments was noted in the stems near the apex of the stressed plants as confirmed by chromatographic analyses. Simultaneously, a rapid accumulation of osmoprotectants, i.e. carbohydrates (measured by spectrometry), and of stress indicators (e.g. putrescine) occurred; changes in protein patterns also arose. Indeed, Western blot studies revealed that the expression of three families of stress-related proteins, i.e. dehydrins, stress protein 1 and heat-shock protein 70, was activated or induced by low temperatures. This study complements a previous work on proteomic and individual carbohydrates and provides insight in the ability of poplar plantlets to cold acclimate and to cope with low temperatures by diverse mechanisms (growth cessation, carbohydrate, pigment, polyamine and protein accumulations) related to stress response or involved in acclimation process.