Chloroplast structure after water and high-temperature stress in two lines of maize that differ in endogenous levels of abscisic acid

Chloroplast structure in mesophyll cells from the high-level abscisic acid (ABA) line of maize (Zea mays L.), ZPBL 1304, and the low-level ABA line, ZPL 389, was studied in response to leaf dehydration and high temperature (45 C). Thirteen-day-old seedlings were exposed to 7-d soil drying followed b...

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Bibliographic Details
Published in:International journal of plant sciences 1992-06, Vol.153 (2), p.186-196
Main Authors: Ristic, Z. (University of Alberta, Edmonton, Alberta, Canada), Cass, D.D
Format: Article
Language:English
Subjects:
ABA
ACIDE ABSCISSIQUE
ACIDO ABSCISICO
AGOTAMIENTO POR EL CALOR
Arid soils
Botany
CALOR
CELL STRUCTURE
CELL ULTRASTRUCTURE
CHALEUR
CHLOROPLAST ENVELOPE MEMBRANES
CHLOROPLASTE
CHLOROPLASTS
CLOROPLASTO
Corn
COUP DE CHALEUR
Dehydration
DROUGHT
DROUGHT RESISTANCE
DROUGHT STRESS
Drying
ESTRES DE SEQUIA
ESTRUCTURA CELULAR
Flood damage
GENOTIPOS
GENOTYPE
GENOTYPES
HEAT
HEAT EXHAUSTION
HEAT STABILITY
HEAT STRESS
HEAT TOLERANCE
High temperature
LINE DIFFERENCES
MESOFILO
MESOPHYLL
MESOPHYLLE
Physiology
Plants
PLASMA MEMBRANES
PLASTE
PLASTIDIOS
PLASTIDS
RESISTANCE A LA SECHERESSE
RESISTANCE A LA TEMPERATURE
RESISTENCIA A LA SEQUIA
RESISTENCIA A LA TEMPERATURA
SECHERESSE
SEQUIA
STRESS DU A LA SECHERESSE
STRUCTURE CELLULAIRE
Temperature
TEMPERATURE RESISTANCE
THYLAKOID MEMBRANES
THYLAKOIDS
WATER STRESS
ZEA MAYS
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Summary:Chloroplast structure in mesophyll cells from the high-level abscisic acid (ABA) line of maize (Zea mays L.), ZPBL 1304, and the low-level ABA line, ZPL 389, was studied in response to leaf dehydration and high temperature (45 C). Thirteen-day-old seedlings were exposed to 7-d soil drying followed by either 6-h or 24-h heat stress. Seven-day soil drying followed by 6-h high-temperature stress did not affect chloroplasts in line ZPBL 1304 but damaged many chloroplasts of line ZPL 389; chloroplast-envelope membranes were broken and not distinct, and many thylakoids were swollen. Seven-day soil drying followed by 24-h heat stress affected chloroplasts in both lines, but changes in chloroplast structure were greater in ZPL 389 than in ZPBL 1304. The main damage to the chloroplasts in ZPBL 1304 included thylakoid swelling, disruption of the chloroplast envelope, and distortion of chloroplast shape. Chloroplasts in ZPL 389 suffered severe damage: their shape was irregular, envelope membranes were not visible, grana were barely recognizable, and many lipid droplets were visible inside the chloroplast. Modifications in chloroplast structure were reversible in ZPBL 1304. Chloroplasts in ZPL 389 were irreversibly damaged after heating for 24 h. Chloroplast structure differences between lines under stress conditions were likely the result of genotypic differences in leaf dehydration, and possibly the result of genotypic differences in thermal stability of chloroplast membranes. The results support the hypothesis that higher levels of endogenous ABA can indicate drought and heat resistance in maize.
ISSN:1058-5893
1537-5315
DOI:10.1086/297021