Effects of short-term salinity on leaf gas exchange of the fig (Ficus carica L.)

1993 ◽  
Vol 148 (1) ◽  
pp. 21-27 ◽  
Author(s):  
S. D. Golombek ◽  
P. Lüdders
Keyword(s):  
Gas Exchange ◽  
Leaf Gas Exchange ◽  
Ficus Carica ◽  
Short Term

scholarly journals Biochemical Responses and Leaf Gas Exchange of Fig (Ficus carica L.) to Water Stress, Short-Term Elevated CO2 Levels and Brassinolide Application

Horticulturae ◽  
2021 ◽  
Vol 7 (4) ◽  
pp. 73
Author(s):  
Zulias Mardinata ◽  
Tengku Edy Sabli ◽  
Saripah Ulpah
Keyword(s):  
Water Stress ◽  
Drought Stress ◽  
Gas Exchange ◽  
Elevated Co2 ◽  
Leaf Gas Exchange ◽  
Ficus Carica ◽  
Short Term ◽  
Biochemical Responses ◽  
Co2 Levels ◽  
Ambient Co2

The identification of the key components in the response to drought stress is fundamental to upgrading drought tolerance of plants. In this study, biochemical responses and leaf gas exchange characteristics of fig (Ficus carica L.) to water stress, short-term elevated CO2 levels and brassinolide application were evaluated. The ‘Improved Brown Turkey’ cultivar of fig was propagated from mature two- to three-year-old plants using cuttings, and transferred into a substrate containing 3:2:1 mixed soil (top soil: organic matters: sand). The experiment was arranged as a nested design with eight replications. To assess changes in leaf gas exchange and biochemical responses, these plants were subjected to two levels of water stress (well-watered and drought-stressed) and grown under ambient CO2 and 800 ppm CO2. Water deficits led to effects on photosynthetic rate, stomatal conductance, transpiration rate, vapour pressure deficit, water use efficiency (WUE), intercellular CO2, and intrinsic WUE, though often with effects only at ambient or elevated CO2. Some changes in content of chlorophyll, proline, starch, protein, malondialdehyde, soluble sugars, and activities of peroxidase and catalase were also noted but were dependent on CO2 level. Overall, fewer differences between well-watered and drought-stressed plants were evident at elevated CO2 than at ambient CO2. Under drought stress, elevated CO2 may have boosted physiological and metabolic activities through improved protein synthesis enabling maintenance of tissue water potential and activities of antioxidant enzymes, which reduced lipid peroxidation.

scholarly journals Determining the Effects of Abscisic Acid Drenches on Evapotranspiration and Leaf Gas Exchange of Tomato

HortScience ◽  
2011 ◽  
Vol 46 (11) ◽  
pp. 1512-1517 ◽  
Author(s):  
Manuel G. Astacio ◽  
Marc W. van Iersel
Keyword(s):  
Abscisic Acid ◽  
Gas Exchange ◽  
Shelf Life ◽  
Water Use ◽  
Water Loss ◽  
Leaf Gas Exchange ◽  
Short Term ◽  
Leaf Physiology ◽  
Rate Dependent ◽  
Short Period

It is common for plants in the retail market to receive inadequate water and lose aesthetic value within a short period of time. The plant hormone abscisic acid (ABA) is naturally produced in response to drought conditions and reduces transpiration (E) by closing the stomata. Thus, ABA may lengthen shelf life of retail plants by reducing water loss. Two studies were conducted to look at effects of ABA on plant water use and shelf life over a 13-day period and short-term effects of ABA on leaf physiology. The objective of the short-term study was to determine how quickly 100-mL drenches of 250 mg·L−1 ABA solution affect leaf gas exchange of tomatoes (Solanum lycopersicum ‘Supersweet 100’). ABA drenches reduced stomatal conductance (gS), E, and photosynthetic rate (Pn) within 60 min. After 2 h, E, gs, and Pn were reduced by 66%, 72%, and 55% respectively, compared with the control plants. In the13-day study, ABA was applied to tomatoes as a 100-mL drench at concentrations ranging from 0 to 1000 mg·L−1 and ABA effects on water use and time to wilting were quantified. Half of the plants were not watered after ABA application, whereas the other plants were watered as needed. In general, higher ABA concentrations resulted in less water use by both well-watered and unwatered plants. ABA delayed wilting of unwatered plants by 2 to 8 days (dependent on the dose) as compared with control plants. In well-watered plants, ABA reduced daily evapotranspiration (ET) for 5 days, after which there were no further ABA effects. Negative side effects of the ABA application were rate-dependent chlorosis of the lower leaves followed by leaf abscission. These studies demonstrate that ABA drenches rapidly close stomata, limit transpirational water loss, and can extend the shelf life of retail plants by up to 8 days, which exemplifies its potential as a commercially applied plant growth regulator.

Assimilation and release of internal carbon dioxide by woody plant shoots

1970 ◽  
Vol 48 (7) ◽  
pp. 1351-1354 ◽  
Author(s):  
W. żelawski ◽  
F. P. Riech ◽  
R. G. Stanley
Keyword(s):  
Gas Exchange ◽  
Woody Plants ◽  
Woody Plant ◽  
Leaf Gas Exchange ◽  
Soluble Sugars ◽  
Pinus Elliottii ◽  
Short Term ◽  
Transpiration Stream ◽  
Pine Seedlings ◽  
Plant Shoots

This study was undertaken to determine whether tree stems can reassimilate internal CO2 produced by respiration or whether this CO2 is evolved and could possibly interfere with measurements of leaf gas exchange. Radioactive CO2 was added to the stem transpiration stream of slash pine seedlings (Pinus elliottii Engelm.) and the distribution of 14C studied in shoots and needles exposed to dark and light conditions.Photosynthesis decreases the amount of internal CO2 evolved. Large amounts of 14CO2 from the transpiration stream are incorporated into organic compounds of needles and stems, primarily into ethanol-soluble sugars and organic acids, and in time, small amounts of 14C occur in the ethanol-insoluble materials.These results indicate that respiratory CO2 transported in the transpiration stream of woody plants can be reused in photosynthesis or possibly other metabolic processes. Internal CO2 is also evolved to the atmosphere in large amounts, but related research indicates it diffuses primarily out of the stem tissue not the needles. The evolved CO2 supplied from stems does not significantly affect short term measurements of needle gas exchange in pine seedlings.

Effects of short-term soil flooding on stomata behaviour and leaf gas exchange in barley plants

2005 ◽  
Vol 49 (2) ◽  
pp. 317-319 ◽  
Author(s):  
R. Y. Yordanova ◽  
A. N. Uzunova ◽  
L. P. Popova
Keyword(s):  
Gas Exchange ◽  
Leaf Gas Exchange ◽  
Short Term ◽  
Soil Flooding

scholarly journals Influence of Spring and Fall Drought Stresses on Growth and Gas Exchange during Stress and Posttransplant of Container-grown Magnoli ×soulangiana `Jane'

2002 ◽  
Vol 127 (1) ◽  
pp. 38-44 ◽  
Author(s):  
R. Thomas Fernandez ◽  
Robert E. Schutzki ◽  
Kelly J. Prevete
Keyword(s):  
Drought Stress ◽  
Stomatal Conductance ◽  
Gas Exchange ◽  
Leaf Gas Exchange ◽  
Growth Index ◽  
Severe Drought ◽  
Severe Stress ◽  
Flower Number ◽  
Short Term ◽  
Whole Plant

Responses of Magnolia ×soulangiana (Soul.-Bod.) `Jane' (`Jane' saucer magnolia) to consecutive short term pretransplant drought stresses and recovery after transplanting were evaluated beginning October 1997 and June 1998. Plants were subjected to one (mild) or two (moderate) 3-day drought stress periods or a two 3-day and one 4-day (severe) drought stress period, each separated by two rewatering periods over 24 hours. One day after each stress period, plants were transplanted into the field and well watered to monitor recovery from stress. Plant response was determined by measuring whole-plant CO2 assimilation, leaf gas exchange (CO2 assimilation, transpiration, stomatal conductance) and canopy growth throughout stress and recovery periods. Whole-plant and leaf CO2 assimilation were lower for the stressed treatments for most of the measurements taken during stress in the fall and spring. After release from stress and transplanting, leaf CO2 assimilation returned to control levels for mild and moderate fall stresses within 2 to 3 d by the next measurement, while it was over 3 weeks until recovery from the severe stress. There was no difference in leaf gas exchange following release from stress and transplanting during the spring stress. More rapid defoliation occurred for the severe fall-stressed plants compared to the controls after release from stress in the fall. Flower number was reduced in spring for the fall-stressed plants. At termination of the experiment, the growth index was lower for severe fall-stressed plants but there were no differences for other fall stress treatments. There was no increase in growth for control or stressed plants for the spring experiment.

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