Zn²⁺ binds to several conserved amino acids in C2H2-type zinc finger proteins (generally Cys and His) to form a relatively independent region of the protein. Eukaryotic C2H2-type zinc finger proteins generally contain a specific conserved sequence consisting of 25 to 30 amino acids: C-X2~4-C-X3-P-X5-L-X2-H-X3-H (Shimeld, 2008; Finn et al., 2013). Two pairs of histidines at the C-terminus of the α-helix and the two cysteines at the end of the β-strand bind to Zn²⁺ to form a tetrahedral structure. Zn²⁺ is sandwiched between an α-helix and two antiparallel β-strands; the stability of the ββα structural system is maintained by the interlaced linkage provided by Zn²⁺ (Figure 1). The presence of Zn²⁺ ensures that the stability of the entire zinc finger structure and the normal helical structure are maintained (Wolfe et al., 2000; Alam et al., 2019).

Most C2H2 zinc finger proteins in plants contain the highly conserved sequence QALGGH in their zinc finger domains: such proteins are referred to as Q-type zinc finger proteins. Unlike proteins containing the QALGGH sequence, a class of C2H2-type zinc finger proteins do not contain any conserved motifs in the zinc finger region are known as C-type proteins (Agarwal et al., 2007; Liu et al., 2015b).

According to the number and distribution of zinc fingers, C2H2-type zinc finger proteins in plants are divided into four categories: (1) proteins containing one C2H2 zinc finger (single-C2H2); (2) proteins containing three C2H2 zinc fingers (triple-C2H2 [tC2H2]); (3) proteins containing more than three adjacent C2H2 zinc fingers (multiple-adjacent-C2H2 [maC2H2]); and (4) proteins containing several C2H2 zinc finger pairs that are widely separated (separated-paired-C2H2 [spC2H2]) (Wang et al., 2019).

Although many C2H2 transcription factors show transcriptional activation activity, there is no general rule about particular domains that function as transcriptional activators among the various types of domains, such as proline-rich, serine-rich, glutamine-rich, and threonine-rich domains (De Pater et al., 1996; Kiełbowicz-Matuk, 2012; Tang et al., 2019). Many C2H2-type zinc finger proteins function as transcriptional activators during plant growth and abiotic stress, but the activation domain is poorly understood (Sakamoto et al., 2000; Xu et al., 2007; Zhou et al., 2011; Zhang et al., 2016a). Several stress-related C2H2-type zinc finger proteins contain a proline-rich region between the NLS and L-box motifs, which is considered to be the activation domain (Sakamoto et al., 2000).

The associated amphiphilic repression (EAR) motif (^L/_FDLN ^L/_F(x)P) in plants is present in class II AP2/ERF proteins and in the C-termini of C2H2-type zinc finger proteins (TFIIIA class). The EAR motif reduces the underlying transcriptional level of the reporter gene, as well as the transcriptional activation activity of other TFs (Kazan, 2006). The conserved EAR motif in class II ERF TFs plays a key role in their inhibitory activity. For example, the C-terminal inhibitory domain of AtERF4 is DLDLNL; if a mutation occurs in this domain, the protein's inhibitory function is abolished (Ohta et al., 2001; Han et al., 2019a).

C2H2-type zinc finger proteins with EAR motifs play important roles in regulating abiotic-stress-related gene expression under conditions such as salt, drought, and low temperature (Han and Fu, 2019). The DLNL sequence (DLN-box) at the C-terminus of STZ, with trans-activation activity, functions in the transcriptional activation of DREB1A under salt stress (Sakamoto et al., 2004; Kazan, 2006; Zhang et al., 2016c; Li et al., 2018), while the DLN-box is not the only domain that determines the transcriptional inhibitory activity of C2H2 zinc finger proteins (Huang et al., 2009a).

Plant C2H2-type zinc finger proteins have unique structural features: the conserved, unique QALGGH (Q-type C2H2) motif and the long variable spacers between adjacent zinc finger domains (Klug and Schwabe, 1995; Takatsuji, 1999; Lyu and Cao, 2018). Both features are thought to be important for DNA-binding activity in plants (Kubo et al., 1998; Brayer et al., 2008). A mutation of any amino acid in QALGGH sequence except Q will cause the protein to completely lose its ability to bind to DNA, whereas a mutation in Q will greatly reduce its DNA binding ability (Kubo et al., 1998; Gourcilleau et al., 2011). Of course, characteristic region of a leucine-rich box (L-box) has also been identified to be related to protein interactions in these proteins (Sakamoto et al., 2000; Ciftci-Yilmaz et al., 2007). Bioinformatics tools such ZF Models (zinc finger specificity prediction based on the random forest model) (Gupta et al., 2014), ZifRC (zinc finger recognition code) (Najafabadi et al., 2015), and B1H screening of the C2H2-ZF domain (Persikov et al., 2015) have also been used for binding sequence prediction based on the C2H2-type zinc finger motif.

In addition to binding to DNA, C2H2-type zinc finger proteins can recognize RNA. Zinc fingers comprehensively recognize specific bases and specific folding backbones in diverse RNA structures (Brown, 2005; Lin and Lin, 2018). Contact with the phosphoric acid skeleton in RNA is essential for the recognition of this molecule. A phage display assay showed that the amino acids at positions −1 and +2 of the α-helix in C2H2 zinc finger proteins are important for RNA binding (Mcbryant et al., 1995).

Zinc finger proteins interact with other zinc finger proteins or other types of protein to regulate target gene expression (Brayer and Segal, 2008; Song et al., 2010). Zinc finger proteins interact with other zinc finger proteins to bind to other DNA sequences or to prevent binding to the corresponding DNA sequences, thereby regulating gene transcription and expression, the potential for mediating protein interactions is much larger compared to DNA binding (Shi and Berg, 1995; Mackay and Crossley, 1998; Gamsjaeger et al., 2007; Brayer et al., 2008; Yengo et al., 2018).

Salt stress is a serious problem that limits crop production worldwide (Munns and Tester, 2008; Chen et al., 2018). Many C2H2-type TFs act as transcriptional activators or repressors to regulate plant responses to salt stress (Han et al., 2014). Salt stress generates ionic, osmotic, and oxidative stress to plants (Song et al., 2011; Liu et al., 2018). C2H2-type zinc finger proteins participate in salt tolerance by influencing salt-regulated genes.

One way that C2H2-type zinc finger proteins can improve plant salt tolerance is by helping maintain ionic balance. STZ, the first salt-tolerance-related zinc finger protein identified, eliminates the Na⁺ sensitivity of calcineurin-deficient yeast. STZ appears to be partially dependent on ENA1/PMR2, a P-type ATPase required for Li⁺ and Na⁺ efflux in yeast. STZ might enhance salt tolerance in plants by regulating the expression of downstream ion-balance-related genes (Lippuner et al., 1996). Arabidopsis AZF1 and AZF3 respond rapidly to salt stress and may improve salt tolerance by regulating downstream ENA1-like genes (Sakamoto et al., 2000; Sakamoto et al., 2004). In rice, the ZFP182 promoter appears to respond only to monovalent cations such as Na⁺. Therefore, ZFP182 might regulate downstream ion-transport-related genes, such as Na⁺ transporter genes, in the salt regulatory signaling pathway (Huang et al., 2007). Finally, TaZNF improves salt tolerance in wheat by increasing the excretion of Na⁺ and reducing stomatal aperture (Ma et al., 2016).

C2H2-type zinc finger proteins also improve salt tolerance by increasing the concentrations of osmotic adjustment substances. ZFP252 (Xu et al., 2008) and ZFP179 (Sun et al., 2010) improve salt tolerance in rice by increasing the contents of free proline and soluble sugars and upregulating various genes involved in the biosynthesis of osmotic substances, such as OsDREB2A, OsP5CS, OsProT, and OsLea3. In addition, IbZFP1 in sweet potato (I. batatas (L.) Lam.) (Wang et al., 2016), ZFP3 (Zhang et al., 2016a), and AtSIZ1 (Han et al., 2019b) in Arabidopsis enhance plant salt tolerance by increasing proline biosynthesis and accumulation.

C2H2-type zinc finger proteins also improve plant salt tolerance by increasing the ability to scavenge ROS. Arabidopsis plants constitutively expressing ZAT10 show enhanced expression of the ROS scavenging enzymes ascorbate peroxidase1 (APX1), APX2, and Fe-superoxide dismutase1 (FSD1) (Mittler et al., 2006). Transgenic tomato and Arabidopsis plants overexpressing SlZF3 show significantly increased levels of ascorbic acid. Bimolecular fluorescence complementation (BiFC) and Co-Immunoprecipitation (Co-IP) experiments show that SlZF3 directly binds CSN5B, a key component of the COP9 signalosome; CSN5B can promote the degradation of AsA in Arabidopsis by binding to VTC1, so the interaction of SlZF3 and CSN5B inhibited the binding of CSN5B to VTC1, which contributes to AsA biosynthesis (Li et al., 2018).

Many C2H2-type zinc finger proteins enhance plant salt tolerance through abscisic acid (ABA)-mediated signaling pathways. In addition to high salt, AZF2 (Sakamoto et al., 2000; Sakamoto et al., 2004) and StZFP1 (Tian et al., 2010) respond rapidly to ABA, suggesting that they improve salt tolerance via an ABA-dependent pathway. In Thellungiella, ThZF1, like AZF2, regulates downstream gene expression under salt stress (Xu et al., 2007). Transgenic Arabidopsis plants harboring GhDi19-1 and GhDi19-2 from cotton were more sensitive to salt and ABA than the wild type, suggesting that these genes are involved in plant adaptation to salt stress via the ABA signaling pathway (Li et al., 2010).

The mitogen-activated protein kinase (MAPK) cascade is involved in various biotic and abiotic stress responses. ZAT6-overexpressing lines in Arabidopsis show improved seed germination under salt stress via ZAT6's effects on the MAPK cascade. ZAT6 interacts with the stress-responsive MAPK MPK6, and the phosphorylation of ZAT6 by MPK6 is required to improve salt tolerance during seed germination (Liu et al., 2013b). OsZFP213-overexpressing rice lines are more salt tolerant than wild-type and RNAi lines. Yeast two-hybrid, pull-down, and BiFC experiments demonstrate that OsZFP213 interacts with OsMAPK3 to regulate salt tolerance (Zhang et al., 2018).

C2H2-type zinc finger proteins can improve plant salt tolerance via several mechanisms simultaneously, such as promoting ionic balance, scavenging ROS, and increasing the levels of osmotic adjustment substances. GsZFP1 from soybean enhances salt tolerance in transgenic alfalfa by maintaining ionic balance, removing peroxides, and increasing the levels of osmotic adjustment substances (Tang et al., 2013). TaZFP1 overexpression lines show improved salt tolerance due to increased photosynthesis, osmolyte accumulation, and ROS scavenging. RNA-seq analysis show that TaZFP1 regulates photosynthesis, osmolyte metabolism, and ROS-homeostasis-related genes involved in salt stress (Sun et al., 2019a). AtRZFP enhances salt tolerance by increasing ROS scavenging and maintaining Na⁺ and K⁺ homeostasis (Zang et al., 2016).

C2H2-type zinc finger proteins can also improve salt tolerance via other mechanisms. ZAT7 may enhance salt tolerance by interacting with the miRNA-transport-related proteins WRKY70 and HASTY (Ciftci-Yilmaz et al., 2007). A DST loss-of-function rice mutant shows enhanced salt tolerance due to increased stomatal closure and reduced stomatal density (Huang et al., 2009b). ZjZFN1 from Zoysia japonica increases salt tolerance in transgenic Arabidopsis. RNA-seq analysis of these plants suggests that ZjZFN1 regulates phenylalanine metabolism, α-linolenic acid metabolism, and phenylpropanoid biosynthesis during salt stress (Teng et al., 2018).

Osmotic stress is induced by many abiotic stresses such as salinity, cold, and drought stress (Bashir et al., 2019). Osmotic stress causes physiological drought, ion imbalance, oxidative damage, and growth inhibition in plants (Yamaguchi-Shinozaki and Shinozaki, 2006). The ability of plants to resist osmotic stress is related to their ability to alter osmotic pressure and increase the biosynthesis of osmotic regulators (Zhu, 2016).

The C2H2 zinc finger proteins ZAT12 (Davletova et al., 2005b) and ZAT10 (Mittler et al., 2006) are involved in regulating the osmotic stress pathway in Arabidopsis. Both ZAT10-overexpressing lines and zat10 mutant showed enhanced tolerance to osmotic stress (Mittler et al., 2006). ZAT10 is phosphorylated by MPKs that are thought to function in abiotic stress tolerance (Nguyen et al., 2012). ZAT10 is a positive regulator of osmotic stress responses that is regulated by MAP kinases in Arabidopsis (Nguyen et al., 2016). In rice, RZF71 was strongly induced by 20% PEG6000 treatment, suggesting that RZF71 plays an important role in the response to osmotic stress (Guo et al., 2007). Moreover, six C2H2-type zinc finger proteins were reported to be involved in osmotic stress responses in poplar (Gourcilleau et al., 2011). Finally, heterologously expressing GmZAT4 from soybean enhanced the tolerance of Arabidopsis to 20% PEG treatment. Expression analysis of marker genes indicated that GmZAT4 enhances osmotic stress tolerance via an ABA pathway in both soybean and Arabidopsis (Sun et al., 2019b).

Cold snap often cause serious damage to plants and can kill plants when severe (Liu et al., 2016; Wang et al., 2017). A comprehensive understanding of the mechanism underlying cold damage in plants would help resolve the problem of cold stress injury (Yang et al., 2013; Cheng et al., 2014; Sui, 2015; Pareek et al., 2017).

C2H2 zinc finger proteins enhance cold resistance by directly regulating downstream cold-related genes in plants. For instance, ZAT12 regulates cold acclimation by controlling the expression of 15 cold-suppressed genes and 9 cold-inducible genes. ZAT12 also downregulates the expression of CBF genes, suggesting it plays a negative role in plant adaptation to cold stress (Vogel et al., 2005). Transgenic Arabidopsis and tobacco (Nicotiana tabacum) plants overexpressing SCOF-1 show increased expression of COR (cold-regulated) genes and enhanced cold tolerance. The SCOF-1 transgenic plants recover from chilling stress more rapidly than the control, and the T2 generation of SCOF-1 transgenic Arabidopsis still expresses cold regulatory genes, such as COR15a, COR47, and RD29B, at higher levels than the wild type at normal growth temperatures. SCOF-1 does not directly interact with the CTR/DRE, ABRE, or cis-acting elements in the promoter regions of COR genes in vitro, but yeast two-hybrid experiments demonstrated that SCOF-1 interacts with SGBF-1. Interestingly, SCOF-1 significantly enhances the activity of SGBF-1 bound to ABRE sequences in vitro, thereby promoting COR genes' expression and enhancing cold tolerance. The interaction of these two proteins is required for the participation of ABRE in the expression of cold-regulated genes to enhance cold tolerance. In addition, SCOF-1 increases cold tolerance in transgenic sweet potato (Kim et al., 2011) and transgenic potato (Kim et al., 2016). SlCZFP1 enhances cold tolerance in transgenic Arabidopsis and rice by inducing the constitutive expression of COR or cold-responsive genes (Zhang et al., 2011). The cold-stress-related gene COR6.6 was significantly upregulated in GmZF1 transgenic plants, suggesting that GmZF1 regulates cold stress resistance in transgenic Arabidopsis by binding to the COR6.6 promoter region (Yu et al., 2014). In banana, the overexpression of MaC2H2-2 and MaC2H2-3 significantly represses the transcription of MaICE1, a key component of the cold signaling pathway. Therefore, MaC2H2s might enhance cold resistance in banana by suppressing the transcription of MaICE1(Han and Fu, 2019).

C2H2 zinc finger proteins can enhance plant cold resistance by increasing the levels of osmotic substances. ZFP182 significantly enhances cold tolerance in rice overexpression lines by increasing the expression of OsP5CS and OsLEA3 and the accumulation of osmoprotectants (Huang et al., 2012). GmZF1 improved cold resistance in transgenic Arabidopsis by increasing proline and soluble contents and reducing membrane lipid peroxidation under cold stress (Yu et al., 2014).

Finally, several C2H2-type zinc finger proteins regulate low-temperature stress through the ABA signaling pathway. SCOF-1 enhances plant cold tolerance through ABA-dependent signaling pathways (Kim et al., 2001). GmZF1 is highly induced by ABA treatment, suggesting that GmZF1 might participate in an ABA-dependent signaling pathway (Yu et al., 2014).

Drought is an important factor limiting plant growth worldwide, inducing adverse reactions such as osmotic imbalance, membrane system damage, and decreased respiratory and photosynthetic rates. Drought not only hinders plant growth and metabolism at various stages but also affects crop quality and yields (Bartels and Sunkar, 2005; Liu et al., 2015a; Guo et al., 2018).

C2H2 zinc finger proteins enhance plant drought resistance by increasing the levels of osmotic adjustment substances. For example, rice plants overexpressing ZFP252 have a significantly higher survival rate than wild-type and antisense-ZFP252 plants under drought stress. The overexpression lines exhibit enhanced expression of stress-related genes, such as Oslea3, OsP5CS, and OsProT, which contribute to the accumulation of osmotic substances (Xu et al., 2008). Overexpressing OsMSR15 (Zhang et al., 2016c) and ZFP3 in transgenic Arabidopsis (Zhang et al., 2016a) confers increase in drought tolerance by maintaining higher proline contents, reducing electrolyte leakage, and increasing stress-responsive gene expression.

C2H2 zinc finger proteins also enhance drought resistance by improving the ability to scavenge ROS. ZFP245 improves drought resistance in rice by enhancing the activities of the ROS scavenging enzymes superoxide dismutase (SOD) and peroxide (POD) and increasing resistance to H₂O₂ (Huang et al., 2009a). When ZxZF from the highly drought-tolerant plant Zygophyllum xanthoxylum is expressed under the control of the drought-inducible promoter rd29A in Arabidopsis and poplar, the resulting transgenic plants have significantly increased photosynthetic efficiency, ROS, and scavenging ability (Chu et al., 2016). ZAT18 knock down mutant exhibits reduced drought tolerance, while the overexpression lines show higher leaf water content and higher antioxidant enzyme activity than wild-type plants under drought stress (Yin et al., 2017).

C2H2 zinc finger proteins also enhance drought resistance via the ABA and other signaling pathways. Under dehydration stress, AZF2 expression is lower in the aba1 and abi1 mutants than in the wild type, indicating that AZF2 confers drought stress tolerance through an ABA-dependent pathway (Sakamoto et al., 2004). GmZFP3 plays a negative role in plant tolerance to drought stress. Transgenic Arabidopsis plants of GmZFP3 show enhanced expression of ABA-related marker genes, including DREB2A, LHY1, MYB2, RCI3, PAD3, CCA1, and UGT71B6, suggesting that GmZFP3 regulates the drought stress response through an ABA-dependent signaling pathway (Zhang et al., 2016b). Transgenic plants overexpressing OsMSR15 show hypersensitivity to exogenous ABA. Transgenic plants also showed increased expressions of a number of stress-responsive genes, including RD29A and DREB1A under drought stress, which suggested that OsMSR15 may play important roles in response to drought stress both in ABA-dependent and -independent pathways (Zhang et al., 2016c). In the ZAT18 overexpression lines, RNA-seq analysis revealed the enrichment of pathways, such as hormone metabolism, stress response, and signaling pathways; stress-related genes, such as COR47, ERD7, LEA6, RAS1, and hormone-signaling-transduction-related genes, such as JAZ7 and PYL5, appear to be the downstream target genes of ZAT18 (Yin et al., 2017).

C2H2-type zinc finger proteins can also improve plant drought resistance through various mechanisms at the same time. Transformation with CgZFP1 (Gao et al., 2012) and DgZFP3 (Liu et al., 2013a) from chrysanthemum, BcZAT12 from tomato (Rai et al., 2013), and IbZFP1 from sweet potato (Wang et al., 2016) improve drought resistance in transgenic plants by increasing the levels of osmotic adjustment substances, improving ROS scavenging ability, and regulating downstream stress response genes. The Arabidopsis azf2 mutant expressing the Thellungiella halophila gene ThZF1 driven by the 35S promoter displays a flowering time phenotype similar to that of the wild type under drought stress. ThZF1 and AZF2 can both activate the transcription of AtEPSP (Xu et al., 2007). GsZFP1 overexpression enhances drought tolerance in transgenic alfalfa. The expression levels of stress-responsive marker genes, including MtCOR47, MtRAB18, MtP5CS, and MtRD2, were much higher in these plants than in the wild type under drought stress (Luo et al., 2012a).

Abiotic stress usually leads to the production of ROS. Low levels of ROS benefit plant growth and development by functioning as signals and might play other important roles as well (Choudhury et al., 2017), while the excessive accumulation of ROS causes secondary damage to plants. In the presence of excessive ROS, C2H2 zinc finger proteins are expressed at higher levels to help maintain stable ROS levels in plants (Gadjev et al., 2006).

The expression of antioxidase genes that are associated with ROS scavenging under abiotic stress can be regulated by C2H2 zinc finger proteins (Liu et al., 2017). Ascorbate peroxidase 1 (Apx1) is an important scavenger of H₂O₂ in plants (Rizhsky et al., 2004). The expression levels of TF genes ZAT12 and ZAT7 increase with increasing H₂O₂ levels in the loss-of-function mutant apx1. Plants lacking ZAT12 are more sensitive to high H₂O₂ contents than wild-type plants (Rizhsky et al., 2004; Davletova et al., 2005a). APX1, APX2, and FeSOD1 are significantly upregulated in ZAT10 and ZAT12 transgenic lines, but are significantly downregulated in zat10 loss-of-function mutants under high-light stress (Mittler et al., 2006). DST directly binds the promoter region of peroxidase24 precursor to regulate its expression and reduces the accumulation of H₂O₂ in plants (Huang et al., 2009b). SOD and POD activity is significantly enhanced in ZFP245 and ZFP179 overexpression rice plants, thereby increasing resistance to abiotic stress and ROS at the seedling stage (Huang et al., 2009a; Sun et al., 2010). Under water and oxidative stress, overexpressing ZFP36 reduces the damage from ROS by increasing SOD and APX activity, whereas ZFP36-RNAi lines exhibit severe ROS damage due to reduced SOD and APX activity (Zhang et al., 2014).

C2H2-type zinc finger proteins participate in antioxidative stress responses through ABA and MAPK signaling pathways. ZFP36 is significantly induced by ABA-triggered increases in H₂O₂ and OsMPK activity. ZFP36 also increases the expression levels of NADPH oxidase and MAPK genes in the ABA signaling pathway. These findings indicate that ZFP36 is involved in regulating the crosstalk among NADPH oxidase, H₂O₂, and MAPK in the ABA signaling pathway (Zhang et al., 2014).

Plants are highly sensitive to strong light. The ability of plants to withstand strong light depends on the duration of light exposure and light quality (Yang et al., 2019). Overexpressing the C2H2-type zinc finger protein gene RHL41, which is identical to the ZAT12 gene in Arabidopsis, significantly improved resistance to high-light conditions, as manifested by dramatic changes in plant morphology, such as increased production of thin-walled tissues of the barrier and increased anthocyanin and chlorophyll contents (Iida et al., 2000). The expression of ZAT12 increases in response to light stress (Iida et al., 2000; Davletova et al., 2005b). Perhaps ZAT12 is part of the active oxygen scavenging signal transduction pathway, which responds to H₂O₂ produced during light stress (Davletova et al., 2005b). ZAT10 expression is induced by light stress, and ZAT10-overexpressing transgenic lines showed enhanced tolerance to photo-inhibitory light stress (Mittler et al., 2006; Kilian et al., 2007). Under high-light stress, the levels of Apx1, Apx2, and iron superoxide dismutase 1 (FSD1) significantly increased in ZAT10-overexpressing transgenic plants, whereas suppressed expression was observed in ZAT10 knockout plants, suggesting that the increased tolerance of ZAT10-overexpressing plants to high light results from the specific expression of ROS clearance-related genes (Miller et al., 2008). However, to date, few studies have focused on the roles of zinc finger proteins in plant responses to high-light stress; more work needs to be done in this area.