Salinity induced changes in light harvesting and carbon assimilating complexes of Desmostachya bipinnata (L.) Staph

Salinity induced changes in light harvesting and carbon assimilating complexes of Desmostachya bipinnata (L.) Staph

•Desmostachya bipinnata survived in up to 400mM NaCl salinity.•Plants treated with moderate salinity accumulated biomass comparable to control plants.•Stomatal limitation did not influence CO2 fixation rates.•Plants shifted from light harvesting to light protecting mechanisms at high salinity.•Bioch...

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Bibliographic Details
Published in:Environmental and experimental botany Vol. 135; pp. 86 - 95
Main Authors: Asrar, Hina, Hussain, Tabassum, Hadi, Syeda Midhat Sabahat, Gul, Bilquees, Nielsen, Brent L., Khan, M. Ajmal
Format: Journal Article
Language:English
Published: Elsevier B.V 01-03-2017
Subjects:
Carbon fixation
Salt resistance
Stomatal/non-stomatal limitations
Thylakoid membrane proteins
PetD
PAR
A
ETR
Salt resistance
DTT
E
Ci
PSII
HRP
Rubisco
Is
Thylakoid membrane proteins
MDA
Vc,max
PEPC
NPQ
Rd
TBA
RuBP
TPU
Pi
NADP
SDS
PsbA
TBS
WUE
PSI
Stomatal/non-stomatal limitations
gs
OEC
TCA
Fv/Fm
PsbO
ROS
YII
Jmax
Ic
AtpA
Carbon fixation
ATP
Φc
Cyt b6f
qP
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Summary:•Desmostachya bipinnata survived in up to 400mM NaCl salinity.•Plants treated with moderate salinity accumulated biomass comparable to control plants.•Stomatal limitation did not influence CO2 fixation rates.•Plants shifted from light harvesting to light protecting mechanisms at high salinity.•Biochemical and photochemical limitation inhibited photosynthesis at high salinity. The present study was carried out to determine stomatal, photochemical and biochemical limitations of photosynthesis in Desmostachya bipinnata under saline conditions. We hypothesized that processes determining plant growth and photosynthetic rates will be differentially regulated under various salinity treatments. Plants were grown with 0mM, 100mM (moderate) and 400mM (high) NaCl concentrations in a semi-hydroponic quick check system. Production of biomass was not affected by moderate salinity but a significant reduction was observed at high salinity. High salinity decreased stomatal conductance without affecting Ci. Dark respiration increased at moderate salinity compared to control and high salinity. Salinity treatments had no effect on the WUE. Photosynthetic efficiency was improved at moderate salinity compared to the control but was inhibited at high salinity. Net photosynthesis was similar to the control at moderate salinity but was inhibited with a further increase in salinity. Photosynthetic pigments, electron transport rate, and photochemical quenching were not affected at moderate salinity but declined significantly at high salinity. MDA content significantly increased at high salinity suggesting ROS accumulation. A linear decrease in Vc,max, Jmax, TPU and Rubisco content was observed with increasing salinity treatments. Relative expression of photosynthetic complex proteins was either enhanced (D1, PetD, AtpA) or unaffected (PsbO) with moderate salinity but decreased at high salinity with the exception of AtpA. Our data indicates that photosynthesis rates were maintained at moderate salinity. Damages to photochemical reactions and down-regulated expression of chloroplast proteins in combination with biochemical limitations, rather than stomatal limitations, restrained photosynthetic performance of D. bipinnata under high salinity.
ISSN:0098-8472
1873-7307
DOI:10.1016/j.envexpbot.2016.12.008