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Plant Breeding Approaches in Developing Stress Tolerance
Transgenic plants with HSPs are tolerant to heat stress by minimizing
the protein denaturation with the help of protein homeostasis (Jacob et al.,
2017). Many studies showed that the expression of the HSPs in Arabidopsis
plant and tomato plant has made it resistant to high-temperature stress. In
Glycine max, the expression of the heat shock factor made it tolerant through
the stimulation of the many downstream genes’ expression involved in heat
defense system (Zhang et al., 2015a, b, c). Likewise, the introduction of
VpHSF1 gene in tobacco plants increased the capacity to tolerate high-
temperature stress as compared to nontransgenic tobacco plants (Hu et al.,
2016). The points mentioned above showed that the heat shock factor genes
are the best player to confer heat stress. Therefore, abiotic stress tolerance
can be induced efficiently by transgenic approaches.
6.5.3.2.3 TRANSGENIC APPROACHES FOR SALT STRESS TOLERANCE
Salt accumulation in agricultural land is serious issue crop plants face
regarding disturbed physiology and retarded growth. Salt accumulation is
very severe abiotic stress affecting crop yield globally (Bless et al., 2018).
Recently reported that approx. 77 million hectare of agricultural land is not
suitable for cultivation due to excessive salt accumulation (Bless et al., 2018).
Generally, the soil with more than 4 dS m–1 electrical conductivity (EC)
and 40 mM sodium chloride with 15% exchangeable sodium rate is called
saline soil (Singh, 2015). The main agents involved in soil salinization are low
precipitation, saline water irrigation, poor agronomic practices, and weathering
of rocks. If not checked, more than 50% of agricultural land will be saline land
up to 2050 (Singh, 2018). As other abiotic stresses have a very complicated
regulatory setup, saline stress is complex in regulation and is controlled by
many genes (Munns & Gilliham, 2015). Some studies showed that plants
tolerant to abiotic stress could also manufacture many pathogenic proteins to
mitigate the effect of stress (Negrao et al., 2017). Many pathogenesis-related
proteins among these Osmotin proteins can generate innate immunity in plants
against abiotic stresses (Wan et al., 2017). Osmotic genes taken from tobacco
plants are introduced in strawberry plants showed tolerance against salt stress
(Sripriya et al., 2017). Transgenic chili with the Osmotin genes is tolerant
to salt stress up to 300 mM NaCl, leading to increased antioxidant enzymes
activities and photosynthesis rate (Ullah et al., 2018).
Transgenic cherry tomato having D-galacturonic acid reductase
gene could bear salt stress up to 200 mM and improve the stress defense