The plasma membrane of an organism is the first line of defense against cold stress, acting like a safety net, protecting and maintaining the shape of cells, recognizing and exchanging signaling molecules and other substances required for various physiological and developmental processes [15]. These processes are facilitated by open spaces in the plasma membrane or by different transporters, pumps and gated channels [16]. For example, during cold acclimation, plants express tonoplast monosaccharide transporters (TMT) to increase sugar levels and maintain cellular homeostasis [17]. Another example is that low temperature induces the expression of annexin in poplar leaves. Annexin can mediate the transport of cytosolic free Ca²⁺ concentration in response to the reactive oxygen species (ROS) generated by cold stress [18].

The major components of the plasma membrane include lipids, proteins and carbohydrates. Changes in the physicochemical properties of the plasma membrane are part of the mechanism by which plants respond to cold stress (Fig. 1) [19]. Pharmacological analysis showed that at 25°C, the expression of cold responsive (COR) gene was induced by membrane stiffening, whereas at 4°C, it was inhibited by membrane fluidization. Plasma membrane fluidity is related to the proportion of desaturated fatty acids. For example, in H. undulatus, cold stress leads to severe oxidation of unsaturated fatty acids at the plasma membrane, leading to cellular damage and apoptosis [20]. Fatty acid desaturase 2 (FAD2) encodes an oleate desaturase enzyme necessary for membrane fluidity. Mutation of FAD2 disrupts some physiological responses to cold stress, such as leaf number and hypocotyl length [21]. Another study has found that the content of phosphatidylglycerol, dipalmitoyl plus the l-palmitoyl-2-(trans-3-hexadecenoyl) in cold-tolerant plants and sensitive plants is significantly different. The content of phosphatidylglycerol, dipalmitoyl plus the l-palmitoyl-2-(trans-3-hexadecenoyl) in cold-tolerant plants is about 3%–19%, in sensitive plants constitutes~26%–65% [22]. In addition, the lipid composition of the plasma membrane and chloroplast envelope changes in cold-acclimated plants, by increasing the unsaturated fatty acid content of the cold-adapted membranes, making them more fluid, consequently increasing cold resistance [23]. Therefore, changes in membrane fluidity can be used to represent the cold signal [24]. In Norway spruce, although there are differences between different varieties, short-term temperature changes has been shown to induce more significant changes in cold resistance than the overall climatic conditions [25]. The primary input of cold signaling may be tiny mechanical forces induced by membrane stiffening. Cold signaling is integrated by the microtubule receptor system and amplified by COLD1-dependent signaling pathways [26]. Some members of the MAP65 family have been shown to reduce the stiffness of microtubules, directly affecting the force transmission of membrane rigidification, possibly by increasing the abundance of unsaturated fatty acids and adaptive reflow of the membrane by microtubules related [27].

Paclitaxel, a compound that stabilizes microtubules, was found to inhibit the development of frost resistance. This suggests that effective activation of frost resistance requires certain microtubule dynamics [1]. Although microtubules do not transduce cold signals, they play a role in induce cold hardening [28]. Deeper research has also shown that when the membrane rigidify rapidly, the reduction in microtubule flexural rigidity (contributed by MAP65-2) prevents microtubule rupture under cold stress, while microtubule bundling is expected to improve force transmission to calcium channels as an actual sensory structure [27].

Calcium (Ca²⁺) is a universal second messenger involved in many aspects of plant development and environmental responses. Abiotic and biotic stresses, such as cold, heat, salt, and pathogen infection, act on Ca²⁺ permeation channels, resulting in transient increases in cytosolic free Ca²⁺ concentration ([Ca²⁺]cyt). These Ca²⁺ signals convert external signals into a variety of intracellular biochemical reactions [29].

Since trees are very large plants, rapid signal transduction in tree systems is critical. Fromm et al. [30] found that fast signals coordinate the physiological activities of trees and that calcium signals are the first step in action potential-dependent fast signals. Trauma-triggered electrical signals can travel long distances and alter photosynthesis in distant leaves. In trees grown under calcium-deficient conditions, the excitability of phloem cells was completely blocked after leaf injury [31]. Calcium-deficient trees also had no apparent gas exchange response after injury. These findings evidenced that calcium channels are involved in the induction of electrical signals at different distances in trees.

After cold stress alters the fluidity of the plasma membrane, it is sensed by Ca²⁺ channels and other plasma membrane proteins, and induces actin filaments depolymerization, triggering an increase in [Ca²⁺] cyt and activating the cold stress response [32,33]. It was found that the G-protein regulator Chilling Tolerance Divergence 1 (COLD1) binds to rice G protein α subunit 1 (RGA1), mediates cold-induced Ca²⁺ influx, and provides cold induction in rice [34]. In spruce mesophyll cells, plasma membrane-associated calcium accumulates strongly in early autumn and then declines after the first frost as cold resistance develops [35]. Ca²⁺ transmits low temperature signals by activating the signaling sensor calmodulin (CAM), which in turn mediates a range of downstream pathways, including development, defense against pathogens, and responses to abiotic stresses such as temperature, drought, salinity, and light [36]. Calcium-related signal transduction usually involves calcium-dependent protein kinases (CDPKs). The expression level of SiCDPK24 in Foxtail millet was significantly increased under cold stress [37]. Populus euphratica overexpressing CDPKs showed enhanced drought and freezing resistance [38]; however, Z. mays overexpressing ZmCPK1 showed reduced cold tolerance, indicating that CDPKs play different roles in cold signal transduction.

Calmodulin-binding transcription activators (CAMTA) proteins belong to a class of transcription factors conserved in eukaryotes that respond to calcium signals by binding to CAM. CAMTA protein senses the increase of Ca²⁺ level and interacts with various calmodulins as a response to cold stress [39]. There are 6 CAMTA genes in Arabidopsis thaliana, among which AtCAMTA3 can act as a positive regulator of AtCBF2 transcription factor by binding to the cis element (CM2 motif) of AtCBF2. In the Atcamta1 Atcamta3 double mutant, the expression of the CBF gene family was reduced by approximately 50% [40].

It has been reported that Ca²⁺/CaM-regulated receptor-like kinases 1 (CRLK1), which encodes a PM-associated serine/threonine kinase regulated by Ca²⁺ signaling, plays a key role in plant responses to cold stress. Under freezing temperature, crlk1 knockout mutant plants showed stronger sensitivity than WT, and the expression of some cold-responsive genes was significantly reduced. These results suggest that CRLK1 positively regulates the cold response in Arabidopsis. Further studies showed that Ca²⁺/CaM is required for the activation of AtCRLK1 kinase (Fig. 1). In the presence of Ca²⁺, AtCRLK1 kinase activity increased with increasing CAM concentration, whereas the CAM antagonist CPZ inhibited CAM-stimulated AtCRLK1 kinase activity. Furthermore, the CaM-binding domain (positions 369–390) at the C-terminus of AtCRLK1 is required for CaM-stimulated kinase activity, and only specific CAM isoforms are responsible for AtCRLK1 activation. These observations suggest the existence of a cold-response pathway for Ca²⁺ signaling regulated by AtCRLK1 [41]. Ca²⁺ signaling is involved in multiple signaling pathways and plays a key role in plant responses to cold stress.

In trees, calcium has been implicated in lignification and dormancy in addition to its involvement in signal transduction, and a reduction in calcium content has led to a reduction in lignin, with concomitant changes in the hardness and elasticity of the secondary wall [42]. At the onset of tree dormancy, calcium is recovered from the leaves to the stem, and calcium levels in the shoot apical meristem and dormant cambium become very low, and when dormancy is broken, activation of the cambium and flushing of the bud induces a marked rise in meristem calcium content, which is associated with the onset of cell division, suggesting that calcium plays a significant role in the activation of this process [43].

The red-to-far-red light ratio (F/FR) is another factor that interacts with components of the circadian oscillator to regulate AtCBF 1 to 3 expression and cold resistance. Arabidopsis mutant studies have shown that phytochrome B (AtPHYB), D (AtPHYD), and AtPHYB interactors, phytochrome interacting factor 4 (AtPIF4) and 7 (AtPIF7), are involved in this process. Under long-day (LD) conditions, phytochrome activation triggers interaction of AtPIF7 with the circadian oscillator Timing of Cab Expression 1 (AtTOC1), followed by binding to the G-box sequence (CAGTG) in the CBF promoter, thereby downregulating CBF Expression. Under short-day (SD) conditions in autumn, this inhibition is alleviated, and PIF7 cooperates with PIF4 to regulate CBF and cold resistance [44]. In-silico gene expression analyses have shown light induction of the CBF pathway to be related to the phytochrome AtPHYA, as a link between AtPHYA and the AtICE1 signaling pathway [45]. However, long-term exposure to SD was reported not to increase the cold tolerance of PHYA-overexpressing poplars [46].

Phytochrome gene expression has also been associated with dormancy; transgenic poplars overexpressing the Avena sativa oat PHYA gene were shown to be insensitive to SDs even within 6 h, whereas wild-type plants stopped growth and germination under a 14-h photoperiod. In Poplar, PttPHYA gene knockout has ceased growth and terminal buds were formed earlier than WT plants at the critical day length of 15.5 h, indicating that SDs-induced seasonal dormancy and cold tolerance of poplars were mediated by the PHYA light signaling pathway. Furthermore, quantitative trait locus analysis revealed that PHYB in poplar is a candidate gene involved in photoperiod sensing and is associated with shoot formation time [13].

The main regulators of transcriptional cold response networks in higher plants are transcription factors of the CBF/DREB1 family, which were originally reported in A. thaliana. CBFs, also known as dehydration responsive element binding (DREB) proteins are highly conserved ABA-independent transcription factors family encoding transcription factors closely related to AP2/ERF DNA-binding protein family members that are rapidly induced upon exposure to 4°C [47,48]. CBF proteins are plant-specific transcription factors. A. thaliana encodes three cold-induced CBF genes, AtCBF1, AtCBF2, and AtCBF3. Transgenic Arabidopsis constitutively expressing AtCBF1, AtCBF2, or AtCBF3 results in increased cold tolerance of plants without exposure to low temperatures [49]. The AtCBF4 gene is not induced by cold, but can also enhance the cold tolerance of plants after overexpression [50]. The homologous gene of DREB1/CBF has been isolated from Triticum aestivum, Brassica napus, O. sativa, H. vulgare, Z. mays and other plants. Overexpression of Arabidopsis DREB1/CBF gene in transgenic B. napus or Nicotiana tabacum can induce the homologous gene of A. thaliana CBF/DREB1 homologous gene and improve the cold and drought tolerance of transgenic plants [51]. In Ipomoea batatas, IbCBF3 can significantly activate downstream IbCORs and IbSINA5 under cold stress, IbSINA5 can also induce multiple IbCORs [52].

The CBF genes are controlled by upstream transcription factors which includes: Inducer of CBF expression (AtICE), calmodulin binding transcription activator 3 (AtCAMTA3), ZAT12, Ethylene Insensitive 3 (AtEIN3), etc. [10]. AtICE1 and AtICE2 bind to the promoter regions of AtCBF1-3 to actively regulate their expression [53]. AtICE1 is respectively subjected to SUMOylation and polyubiquitination mediated by the SUMO E3 ligase AtSIZ1 and the ubiquitin E3 ligase AtHOS1, followed by proteasomal degradation [10]. SIZ1-mediated SUMOylation of AtICE1 controls AtCBF expression by stabilizing AtICE1 [54]. In Arabidopsis, the CBF family is upstream regulated by AtICE1, and under low temperature conditions, AtICE1 induces AtCBF3 by inhibiting transcription of AtMYB15, a repressor of AtCBF [47,48], AtMYB15 (R2R3-MYB family member) also negatively regulates AtCBF gene expression in Arabidopsis [55]. AtMYB15 can express in the absence of cold stress and inhibits AtCBF expression by binding to the AtMYB recognition site of the AtCBF promoter [41]. In addition, AtZAT12, a C2H2 zinc finger transcription factor, also acts as a negative regulator of CBF genes. In Arabidopsis, overexpressing AtZAT12 reduced the expression level of AtCBF under cold stress [56]. As discussed above, several regulatory pathways contribute to fine regulation of CBF-dependent signaling during cold stress. However, the ICE-CBF pathway has been challenged in recent years. Studies have shown that neither Atice1-1 mutant nor AtICE1 overexpression could regulate AtDREB1A/AtICE3 expression. This finding caused an uproar among cold stress researchers, but their results also suggested that hypermethylation in the AtDREB1A promoter region was due to another transgene, not AtICE1. Therefore, although the ICE-CBF pathway has been well studied and established in cold stress signaling, there is still great value in revalidating the pathways and findings associated with this signaling cascade [34,57].

Homologous CBF is also found in woody angiosperms, including Populus, Betula, Citrus reticulata, Prunus persica and Malus pumila. Cold-induced ICE1 and CBF homologues were also identified in several conifers, including Picea glauca, P. sitchensis, and Cryptomeria japonica. The P. persica CBF gene PpCBF1 was overexpressed in M. pumila trees that are normally insensitive to photoperiod, resulting in increased sensitivity to short photoperiods and accelerated growth arrest and leaf senescence. Apparently, the CBF pathway is also integrated into the photoperiodic signaling pathway [58].

The regulation of CBFs in woody plants is complex, showing gene-, tissue- and age-related specificities, as well as temporal differences in induction time, which are not observed in herbaceous plants [59]. Benedict et al. [60] reported different expression patterns of poplar CBF genes in annual and perennial tissues. Xiao et al. [61,62] reported a similar phenomenon in grapes, grape CBFs1-3 were only expressed in young tissues in cold response, while grape CBF4 was expressed in both young and old tissues in cold response. Under LD, birch trees produced CBFs within 15 min of exposure to low temperature [63]. However, CBF induction was delayed and up-regulated for a longer period of time in the SD. Welling et al. [63] further demonstrated that exposure of dormant birch to freezing temperatures (−10°C) after tree thawing only induces CBFs expression and COR gene expression. PpCBFs1-4 were induced by circadian rhythms, especially in leaves, but less so in bark. Differences in expression timing and patterns among peach CBFs may reflect their underlying regulatory complexity [64].

Mitogen-activated protein kinases (MAPKs) play an integral role in integrating multiple intracellular signals transmitted by various stress-induced secondary messengers, thereby activating or inactivating proteins through post-translational phosphorylation of target proteins. In general, the MAPK cascade consists of three kinases acting in succession, with inactive MAPKKKs (MEKKs) activated by stimuli or signaling messengers. The MAPKKKs are activated by phosphorylating MAPKKs at conserved serine/threonines. Activated MAPKKs (MKKs) further activate MAPKs (MPKs) through phosphorylating. Recently, studies have found that MAPK signaling regulates the cold stress response in Arabidopsis through the ICE1 pathway [65].

Teige et al. [66] found that Arabidopsis AtMKK2 is activated by cold stress and controls COR gene expression and plant tolerance to cold stress. AtMKK2 is located downstream of AtMEKK1 and upstream of AtMPK4 and AtMPK6, which are activated by various stresses such as low temperature. Atmkk2 mutant plants were more sensitive to cold stress than WT, while plants overexpressing AtMKK2 exhibited stronger cold tolerance. Furthermore, plants overexpressing AtMKK2 could induce the transcriptional expression of AtCBF even at room temperature. Further studies found that low temperature activates Ca²⁺ signaling-mediated AtCRLK1, which in turn phosphorylates and activates AtMEKK1, an upstream component in the AtMKK2. Activation of AtMKK2 by AtMEKK1 induces the phosphorylation of AtMPK4 and AtMPK6 [67,68].

AtMPK3, AtMPK4, and AtMPK6 were induced within 30 min of cold exposure, suggesting their involvement in cold stress response [65]. In Arabidopsis, AtMPK6 phosphorylates AtMYB15 and reduces its binding to the CBF promoter, thereby releasing its inhibitory effect on AtCBF expression. However, two reports have provided strong genetic and biochemical evidence that AtMPK3/6 are negative regulators of CBF signaling. In Arabidopsis, cold-activated AtMPK3/6 interacts with and phosphorylates AtICE1, reducing its stability and binding activity to the AtCBF3 promoter, resulting in reduced cold tolerance [52,69]. And the AtMEKK1-AtMKK1/2-AtMPK4 cascade promotes the stability of AtICE1 by antagonizing AtMPK3/AtMPK6, thereby regulating the cold-responsive transcription factors AtCAMTA and AtMYB, consequently, enhancing cold tolerance [70].

Calcium signaling is also involved in the MAPK cascade pathway in response to cold stress. Two calcium/calmodulin-regulated receptor-like kinases, AtCRLK1 and AtCRLK2, induce AtMPK4 to inhibit the activation of AtMPK3/6, thereby positively regulating freezing tolerance [69].

In addition to phosphorylation, ubiquitination mediates protein degradation pathways in cold signaling. So far, the most suitable E3 ubiquitin ligase in the CBF signaling pathway is high expression of osmotically responsive gene1 (AtHOS1). AtHOS1 interacts with AtICE1 in the nucleus and promotes its degradation under cold stress. Transgenic plants overexpressing AtHOS1 have shown higher freezing sensitivity. Interestingly, open stomata 1 (AtOST1) mediates phosphorylation of AtICE1 interferes with its interaction with AtHOS1. Thereby, increasing the stability of AtICE1 through antagonizing the AtHOS1 E3 ubiquitin ligase (Fig. 1) [71]. In contrast, AtMPK3/6-mediated degradation of AtICE1 does not affect the AtHOS-AtICE interaction and may act through a different path [52].

Additionally, SUMO E3 ligase-mediated SUMOylation often protects proteins from degradation. In Arabidopsis, AtSIZ1 (SAP and Miz) encodes the SUMO E3 ligase, which is required for cold tolerance. AtSIZ1 can phosphorylate and stabilize AtICE1, thereby promoting the expression of AtCBF. The siz1 null mutant exhibits cold-induced CBF expression and impaired freezing tolerance [72].

Like AtICE1 in Arabidopsis, OsICE1 in rice is also degraded by OsHOS1. Unlike Arabidopsis, OsMPK3-mediated phosphorylation inhibits the degradation of OsICE1. It also disrupts the interaction of OsICE1 with the E3 ubiquitin ligase OsHOS1. This in turn enhances the stability of the OsICE1 protein and its ability to bind to trehalose-6-phosphate phosphatase1 (OsTPP1), which encodes a key enzyme that catalyzes trehalose biosynthesis, thereby enhancing cold tolerance. These findings suggest that MAPK3 plays different roles in cold tolerance in different species, and that the Ca²⁺ and MAPK cascades are important cold signal transducers [14].

Abscisic acid (ABA) is one of the most important hormones in cold stress. ABA increases when stress affects plants. Furthermore, the aba-dependent pathway and the ICE-CBF-COR pathway have overlapping connections in cold tolerance [93]. Numerous studies have shown that ABA can induce an increase in the transcription level of CBF genes, possibly through binding to CRT/DRE elements. It has the potential to promote the activation of CBF. Research in Arabidopsis has shown that, AtHAP5A regulates cold tolerance by binding to the CCAAT motif of AtXTH21, and plants overexpressing AtHAP5A and AtXTH21 are more cold-tolerant than wild-type plants, but less sensitive to ABA [94]. In addition, ABA also plays an important role during cold acclimation and can induce the expression of COR genes [2]. Some genes cooperate with ABA, GA and ethylene to up-regulate COR genes [95]. The ABA signaling pathway also has a positive regulator, the BpUVR8 gene, which regulates the expression of a subset of ABA-responsive genes in ABA-treated Arabidopsis and birch [73].

Li et al. [52] showed in the transcriptome study of pear that the expression of the ABA receptor PYL and the positive regulator SnRK2s were up-regulated at the dormant entry; while the inhibitor of ABA signaling, PP2Cs, remained low during dormancy and decreased with decreasing ABA content and increase until dormancy cessation. In addition, exogenous ABA treatment promoted the expression of SnRK2s and suppressed the expression of PP2Cs.

Gibberellins (GAs) are thought to be involved in plant dormancy. GA1, a biologically active gibberellin, controls Salix subapical meristem responses to SD and LD, leading to growth arrest and growth initiation respectively. SD sensed by PHYA has been shown to block certain steps of GA1 biosynthesis, resulting in the growth arrest of poplar. In addition, it was found that the transcription level of PttRGA1 gene in poplar was highly up-regulated in the dormant cambium, and the PttRGA1 gene was highly similar to AtRGA1, a repressor of gibberellin response. This shows that not only GA levels are altered during dormancy, but also that GA signaling is also regulated in overwintering tissues. Transcript levels of the ABA biosynthesis gene, 9-cis-epoxycarotenoid dioxygenase, did not differ between the dormant cambium and the active cambium [77].

GA is also thought to be involved in the CBF pathway. Under cold stress, CBFs are partially suppressed in the context of GA-related gene mutation. DELLA proteins are repressors of the GA hormone signaling pathway, mainly by regulating the activity of transcription factors in plants. GAs induce DELLA to inhibit protein degradation, thereby controlling many key developmental processes and responses to stresses such as cold. Recently, it has been suggested that AtCBFs promote DELLA stabilization by activating the GA catabolism gene AtGA2ox7 (GA2 OXIDASE7) [96].

Other researches have shown that chemical inhibition of gibberellin biosynthesis combined with lower nighttime temperatures was unable to induce dormancy in hybrid poplar under LD photoperiods [97], suggesting that GAs may play a role in SD photoperiod sensing-mediated sleep initiation pathway functions downstream. The role of GAs (especially GA3 and GA4) in promoting shoot dormancy release is also evident and has been demonstrated in several woody species. In poplar, exogenous GA4 was found to replace the effects of cold stress by upregulating several low temperature-responsive genes, and inducing bud burst. Whereas CBFs overexpression led to upregulation of DELLA and decreased apple growth [98]. So far, it has not been clear whether these GA signaling genes respond directly to environmental signals or whether their expression simply reflects developmental events during dormancy.

Studies have shown that jasmonicacid (JA) positively regulates the ICE-CBF pathway to enhance the cold tolerance of Arabidopsis [99]. Exogenous application of MeJA significantly improved the cold tolerance of plants with or without cold acclimation. Conversely, blocking JA biosynthesis and signaling leads to hypersensitivity to freezing stress. Under cold stress, the biosynthesis of endogenous JA is activated, which is consistent with the regulatory role of JA on cold tolerance. Further mechanistic analysis revealed that several repressors of AtJAZ physically interact with the AtICE1 transcription factor to inhibit its transcriptional activity. Additionally, the overexpression of AtJAZ1 or AtJAZ4 in Arabidopsis inhibited the ICE-CBF signaling pathway and response to cold, and JA was concluded to actively regulate the cold response as an upstream signal of the ICE-CBF pathway. In addition to the ICE-CBF cascade, JA also regulates the expression of some ICE-CBF pathway-independent genes. For example, under cold stress, some genes encoding secondary metabolite biosynthesis enzymes (such as polyamines, glutathione, and anthocyanins) are regulated by JA signaling [100].

The AtJAZ1/2 homologous gene MdJAZ1/2 in apple has a similar function, which can negatively regulate cold tolerance by inhibiting the binding of B-BOX protein MdBBX37 to MdCBF1/4 promoter and inhibiting the interaction between BBX37 and ICE1, evidencing that the exogenous application of promoting inhibition of MdJAZ1/2 [101]. JA has also been implicated in the cold storage (e.g., 5°C or 7°C) of several tropical or subtropical fruits, for example, the application of exogenous MeJA has been shown to induce low temperature tolerance (7°C) in banana (Musa acuminata) fruit [102]. Further analysis showed that two homologous genes of AtMYC2 in bananas (MaMYC2a and MaMYC2b) were rapidly induced after MeJA treatment during cold storage. A yeast two-hybrid analysis indicated that MaMYC2 interacted with MaICE1. Consistent with this, the expression of ICE-CBF cold-responsive pathway genes MaCBF1, MaCBF2, MaCOR1, MaRD2, MaRD5 and MaKIN2 were significantly increased in MeJA-treated banana fruits stored at low temperature (7°C) [103].