2. Factors Affecting Epigenetic Mechanisms and, Therefore, Productivity
Plants are constantly exposed to various environmental stresses, such as nutrient deficiency, drought, heat, salinity, and soil contamination with heavy metals. These stressors can have detrimental effects on plant growth, biomass production, and overall yields (
Figure 1). In order to mitigate losses in agriculture, it is imperative to develop stress-resistant cultivars that can better withstand these challenging conditions. A key aspect in achieving this goal is gaining a deeper understanding of plant stress responses and their regulation, specifically focusing on the chromatin states and histone modification that govern gene expression. By unraveling these epigenetic mechanisms, researchers can uncover novel targets for crop enhancement, leading to the creation of more productive and resilient plants capable of adapting to changing environmental conditions. This research is of the utmost importance for improving agronomic traits and enhancing productivity, thereby ensuring food security in the face of evolving climate change and other environmental pressures
[1,74][28][29].
Figure 1. Plant responses to environmental stresses and the importance of epigenetic regulation on hybrid vigor. Plants face various environmental stresses, impacting growth and yields. Developing stress-resistant cultivars is crucial for agriculture. Understanding plant stress responses and epigenetic regulation, including DNA methylation, histone modification, and miRNA regulation, helps identify targets for crop enhancement. WResearchers used BioRender (BioRender.com) to create this scientific illustration.
2.1. Heat Stress
Temperature is a crucial environmental factor affecting plant growth, biomass, and yields. Temperature changes, both heat and cold, pose a significant challenge to agriculture. Heat stress, in particular, can lead to morphological, physiological, and biochemical changes in plants, including growth retardation, leaf etiolation, and even death
[75][30]. Heat stress induces signaling cascades and triggers the expressions of specific genes
[76][31] and heat-shock proteins (HSPs)
[77][32]. Studies have shown that different plant genotypes exhibit varying degrees of heat tolerance.
The responses of plants to temperature stress involve epigenetic mechanisms, specifically histone posttranscriptional modifications
[23,78,79][33][34][35]. To investigate the impact of heat stress on methylation patterns, researchers have examined methylation levels and changes in cytosine methylation patterns in seedlings of heat-sensitive and heat-tolerant genotypes. The findings revealed that the methylation levels differed between the heat-tolerant and heat-sensitive phenotypes under normal conditions
[80][36]. Upon exposure to heat treatment, methylation increased to a greater extent in the heat-sensitive genotype compared to the heat-tolerant genotype. Interestingly, DNA demethylation events were more prevalent in the heat-tolerant genotype, whereas DNA methylation occurred more frequently in the heat-sensitive genotype. This suggests that changes in DNA methylation patterns are associated with the heat-stress response and adaption in
B. napus L.
[81][37] (
Table 21). Intriguingly, through the use of an MSAP assay, a polymorphic demethylated fragment known as M7 (digested with
EcoRI/
MspI) was identified that was found to be linked to a calcium-transporting ATPase gene. This gene plays a crucial role in facilitating the direct transport of calcium ions
[82][38]. The primary calcium-transporting ATPase present in the plasma membrane and endoplasmic reticulum of plant cells utilizes ATP hydrolysis to transport calcium ions. Thus, the alteration of the Ca
2+ concentration in the cytoplasm due to stress could serve as a primary transduction mechanism, influencing gene expression and biochemical events to enable plant cells to adapt to environmental stresses, including heat stress
[83][39].
The role of histone acetylation, mediated by histone acetyltransferases (HATs) and histone deacetylases (HDACs), has been highlighted in the response to heat stress
[15,18][16][40] (
Table 21). Heat stress triggers thermomorphogenesis in
Arabidopsis, characterized by elongated growth and early flowering, enhancing the cooling capacity of the plant
[15,84][40][41]. HDACs, such as HDA9, play a crucial role in thermomorphogenesis by promoting the expressions of genes involved in this response. For instance, HDA9 interacts with PRW (POWERDRESS) to increase the deacetylation of H3K9 at specific gene loci, such as
PHYTOCHROME INTERACTING FACTOR4 (PIF4) and
YUCCA8 (YUC8), which are essential for thermomorphogenesis
[85][42] (
Table 21). HDA9 activity is also required for
YUC8 expression via the promotion of the eviction of the histone variant H2A.Z from
YUC8 nucleosomes, leading to histone deacetylation at the transcriptional start site and gene body of
YUC8 and allowing its transcriptional activation by PIF4
[86][43]. These findings suggest that histone acetylation and deacetylation could be a valuable strategy for enhancing crop yields under heat-stress conditions, thereby potentially impacting heterosis.
In
Arabidopsis, the activity of HDA15 has been shown to act as a repressor of the response induced by warm temperatures
[87][44], while HDA9 and HDA19 appear to participate indirectly in the response to the same stimulus
[88][45]. At 27 °C,
hda15 mutant seedlings showed elongated hypocotyls compared to Col-0 plants, while the hypocotyls were shorter in
hda9 and
hda19 mutant seedlings. Furthermore, warm-temperature marker genes, such as
HSP20,
IAA3,
IAA19,
IAA29,
YUC8,
SAUR28, and
TCH3, were upregulated in the
hda15 mutant compared to the
hda9 and
hda19 mutants and Col-0 plants. In addition,
HSP20,
IAA19, and
IAA29 genes showed increased levels of H3K14ac in their promoter and 5′ regions. At 20 °C, the
hda15 mutant also showed the upregulation of warm-temperature marker genes, such as
YUCCA8, IAA19,
IAA29,
TCH3, ATHB2, and
XTR7. These results suggest that HDA15 can repress warm-temperature marker genes during normal growth and dissociate from its targets to induce their expressions under elevated-temperature stimuli
[88][45].
2.2. Drought Stress
Water deficiency is a major challenge in agriculture, and plants have been found to respond to this stress through epigenetic modifications, including histone acetylation
[16,89][15][46]. The dynamic activity of HATs/HDAs regulates the response to drought stress in important crops such as rice, wheat, and cotton
[81,90,91][37][47][48]. In
Arabidopsis, H3K9ac has been shown to positively regulate the expressions of drought-response genes
[92][49]. The dynamic activity of HATs and HDAs also regulates the ABA biosynthesis pathway, which is the most important signaling pathway for drought stress in plants and is found in various plant species
[16,18][15][16].
Epigenetic associations with heterosis in response to drought stress have also been observed
[10,93][50][51]. A study conducted on poplar (
Populus euramericana) examined six hybrid genotypes (
P. deltoides ×
P. nigra) subjected to water-deficit conditions. The results revealed a correlation between the morphological traits related to productivity and epigenetic modifiers under drought stress. In the hybrid genotype
Populus deltoides ×
P. nigra, the hypomethylation of DNA was found to be associated with drought stress, while there was a significant increase in histone acetylation, indicating rapid gene expression potentially linked to heat-shock proteins (HSPs)
[93][51] (
Table 21). These findings highlight the potential role of epigenetic mechanisms in mediating heterosis and enhancing drought-tolerance traits in plants.
Various studies have shown a positive correlation between increased
HAT expression and drought tolerance in plants
[16,18][15][16]. In
Brassica rapa, the expressions of nine
HAT genes, including
BraHAC1,
BraHAC2, and
BraHAC3, increased significantly after two and/or four days of drought treatment
[94][52]. Similarly, in
Brachypodium distachyon and
Oryza sativa, the expressions of five HATs (
BdHAG1,
BdHAG3,
BdHAC1,
BdHAC4, and
BdHAF1) and nine
HATs (
OsHAG702//703,
OsHAD704/705/706/711/712/713, and
OsHAM701), respectively, were induced after drought treatment
[90,95][47][53] (
Table 1). Analysis of the promoter region of some of these
HAT genes, such as
OsHAG702,
OsHDA705/706/713, and
OsSRT702, showed the existence of drought-responsive elements, like the MBS
cis-element (MYB-binding site involved in drought inducibility), indicating the participation of specific transcription factors for gene activation
[90][47]. In wheat, the genes
TaHAG2,
TaHAG3, and
TaHAC2, and particularly
TaHAG2, showed significantly higher expressions in the drought-resistant variety BL207 compared to its less-resistant parents, BN64 and ZM16. This indicates the potential involvement of these genes in the drought response of wheat
[91][48]. In
Arabidopsis, drought stress triggered an increase in the H3K9ac levels within the promoter regions of 14 drought-response genes, suggesting a crucial role for H3K9ac in the transcriptional activation of these genes under water-deficit conditions
[92][49]. This mechanism suggests the formation of tertiary protein complexes that enhance gene expression
[96][54].
HDAs generally appear to negatively regulate the expressions of drought-responsive genes. For instance, the HDA9 mutation in Arabidopsis resulted in the upregulation of 47 water-deprivation-response genes and the downregulation of 13 genes compared to wild-type plants. The promoter region of 14 randomly selected upregulated genes in the
hda9 mutant showed increased levels of H3K9ac (>2-fold), indicating that the increased expressions of these genes are due to a decrease in deacetylase activity
[92][49]. Similarly, plants that silenced
AtHDA6 and
AtHDA19 exhibited a hypersensitive phenotype to ABA, resulting in the decreased expressions of ABA-responsive genes (
KAT1,
KAT2,
ABI1,
ABI2,
RD29A, RD29B, and
DREB2A) when treated with ABA
[87][44].
AtHD2C has been implicated in the response to ABA. Transgenic plants overexpressing
AtHD2C exhibited insensitivity to ABA and demonstrated enhanced drought tolerance compared to wild-type plants. Furthermore, the expression of
AtHD2C was repressed by ABA
[97][55], and AtHD2C can physically interact with HDA6 and function in association to regulate the expressions of ABA-responsive genes
[98][56]. Recent studies indicate that AtHDA15, through the transcription factor MYB96, can regulate gene responses mediated by ABA signaling
[99,100][57][58]. The biochemical and molecular mechanisms by which HDA6, HDA9, and HDA15 act to regulate responsive genes for ABA signaling have been described in detail in previous studies
[16,99,101,102][15][57][59][60].
In soybean (
Glycine max), the expressions of the nine
GmHDACs (
GmHDA6,
GmHDA8,
GmHDA13,
GmHDA14,
GmHDA16,
GmSRT2,
GmSRT4,
GmHDT2, and
GmHDT4) were found to decrease after drought treatment
[103][61]. Similarly, in rice, the expression of
OsHDA703/710 was significantly decreased after drought treatment
[90][47]. In wheat, the drought-resistant variety BL207 showed a downregulation of the expressions of
TaHDA2,
TaHDA18, and
TaHDT2 [91][48]. However, in some cases, an increase in
HDAC expression may occur, potentially inhibiting the function of the transcriptional repressors of drought-stress-response genes. For example, in rice, increases in the expressions of
OsHAG702/703,
OsHAM701,
OsHDA704/705/706/711/712/713,
OsHDT701, and
OsSRT702 were observed after drought treatment
[90][47], and in
Hibiscus cannabinus L., five
HcHDA genes (
HcHDA2,
HcHDA6,
HcHDA9,
HcHDA19, and
HcSRT2) were strongly expressed under PEG treatment
[104][62].
The use of epigenetic mechanisms offers promising strategies for enhancing drought tolerance in plants. Modulating the expression or repression of
HDAC has shown significant impacts on drought tolerance in different plant species. For instance, in tobacco, introducing the histone deacetylase 84 KHDA903 from poplar (
Populus alba ×
Populus glandulosa) resulted in the overexpressions of drought-responsive genes (
NtDREB4,
NtDREB3, and
NtLEA), leading to improved drought tolerance
[105][63]. In cotton, overexpressing the histone deacetylase
GhHDT4D, a member of the HD2 subfamily, enhanced drought tolerance by reducing the H3K9ac levels in the promoter region of
GhWRKY33, a negative regulator of cotton’s response to drought, and suppressing its expression
[81][37]. In
Arabidopsis,
AtHD2C and
HDA6 were found to decrease the expressions of ABA-responsive genes by reducing histone H3K9/K14 acetylation and increasing H3K9me2
[98][56]. Conversely, H3K4me3 appears to play an important role in the response to drought stress in
Arabidopsis, as the 5′ ends of most ABA and dehydration-inducible genes exhibited broader H3K4me3 distribution profiles
[106][64]. These findings suggest that alterations in HDAC expression and histone modifications are involved in the plant response to drought stress and hold potential for early stress detection. Additionally, manipulating the transcriptional activation or repression of
HDAC can offer promising avenues for improving drought tolerance across different plant species.