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Biology and Biotechnology of Environmental Stress Tolerance in Plants, Volume 3
HSP22.0, and HSP18.2 having distinct expression levels from Heat Shock-
inducible non-memory genes like HSP70 and HSP101, their expression rises
shortly following Heat Shock and then rapidly decreases. HSP22.0, a heat
stress-induced gene, is implicated in heat stress memory. Heat stress causes
the deposition of active histone marks in both the HSP22.0 and HSP70
genes, with H3K4me3, H3K4me2, as well as H3K9Ac. However, once the
plants were returned to their natural state, the levels of these three HSP70
markers dropped to baseline levels. HSP22.0, on the other hand, maintained
H3K4me3 and me2 levels high, however, H3K9Ac levels remain the same
(Lämke et al., 2016). Although several studies have shown that distinct
histone modifications mediate transcriptional memory, it is still unknown
how adverse conditions cause changes in epigenetic alterations (Berger,
2007; Heard & Martienssen, 2014; Zheng et al., 2017). The generation of
transgenerational memory in the offspring, helps the plant to achieve well-
balanced survival and reproductive mechanism. DNA methylation in rice
takes place due to drought stress and more than 40% of this epimutation are
carried to the next progeny. By this time, the tiller number get decreased
and showed an increasing rate of seed set. The theory of maintaining a DNA
methylation state due to rain-lessness in progeny, aids towards water defi
ciency stress response as well as prolonged adaptability to water deficiency
stress environment. Following the selective pressure of comparatively long-
term environmental stress, offspring generations produced a higher balance
between “survival strategy” and “reproductive strategy” than the parental
generations, resulting in fewer effective tillers and higher seed setting rates
than that of the parental generations (Zheng et al., 2017). DNA methylation
has been shown to have a role in the transgenerational memory towards
heavy metal toxicity on Oryza sativa. The P1B subfamily belonging to heavy
metal-transporter P-type ATPases (HMAs) plays a function in the absorption
and translocation of heavy metals in plants. Level of HMAs increases in
relation to heavy metal stressor, as well as transgenerational gene expression
memory have been revealed even when heavy metals were removed (Cong
et al., 2019) (Table 12.1).
12.7 BIOINFORMATICS TOOLS USED IN STUDYING EPIGENETICS
OF PLANT STRESS
Abiotic stressors are among the most significant aspects limiting agricultural
output. Understanding the molecular mechanisms of abiotic stressors in