Decoding the physicochemical basis of resurrection: the journey of lichen Flavoparmelia caperata through prolonged water scarcity to full rehydration
- Author:
- Bhatt U., Singh H., Kalaji H.M., Strasser R.J. & Soni V.
- Year:
- 2024
- Journal:
- BMC Plant Biology
- Pages:
- 24: 1268 [16 p.]
- Url:
- https://doi.org/10.1186/s12870-024-05751-9
Desiccation tolerance is a complex phenomenon observed in the lichen Flavoparmelia ceparata. To understand
the reactivation process of desiccated thalli, completely dried samples were rehydrated. The rehydration process
of this lichen occurs in two phases. The frst phase, characterized by rapid rehydration, involves the conversion of nonfunctional reaction centers (RCs) into functional PSII RCs, and the accumulation of ROS along with the increment
in SOD antioxidant enzyme. These coordinated mechanisms initiate the light reaction of photosynthesis by forming
active light-harvesting complexes (LHCs). This adaptation ensures efcient recovery, as evidenced by specifc energy
fuxes (ABS/RC, TR/RC, ET/RC, and DI/RC), phenomenological fuxes (ABS/CS, TR/CS, ET/CS, and DI/CS), quantum
efciencies (ФP0, ФE0, and ФD0), primary and secondary photochemistry, photochemical and non-photochemical
quenching, and performance index, highlighting the essential role of rapid water uptake in restoring turgor pressure
for cell structure and function maintenance. The interconnected network of antioxidant defenses, including catalase
(CAT) and peroxidase (POD), underscores the plant’s ability to cope with oxidative stress during resilience. The acid
phosphomonoesterase (PME) enzymatic activity corresponds to its role in releasing phosphate for essential cellular
functions and post-rehydration thallus growth. The activity of CAT, GPOD, and PME signifes the gradual reactivation
of lichen F. caperata. Moreover, the investigation into chlorophyll a fuorescence emphasizes the efcient reactivation of the photosynthetic process in F. caperata. In conclusion, lichen F. caperata demonstrates signifcant potential
for desiccation tolerance through the rapid transformation of chloroplasts, chlorophylls, and PSII RCs from their
inactive to active states upon rehydration. This research not only enhances our understanding of desiccation tolerance in resurrection plants but also highlights the importance of lichens, particularly F. caperata, as valuable models
for studying plant resilience in challenging environments.
Keywords Antioxidant, Chlorophyll a fuorescence, Desiccation tolerance, Lichen, Photosynthesis, Resurrection plant.
- Id:
- 37465
- Submitter:
- zpalice
- Post_time:
- Wednesday, 01 January 2025 22:31