Growth, biomass allocation and water use efficiency of two wheat cultivars in a mediterranean environment; a pot experiment under field conditions

Veneklaas, Erik J.; Peacock, J. M.

doi:10.1007/bf01347711

Cited by 9 publications

(15 citation statements)

References 8 publications

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“…). In high‐yielding wheat genotypes, for instance, drought resulted in partitioning of a greater proportion of dry weight in stems instead of both leaves and roots (Veneklaas and Peacock ).…”

Section: Introductionmentioning

confidence: 99%

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Photosynthesis and Remobilization of Dry Matter in Wheat as Affected by Progressive Drought Stress at Stem Elongation Stage

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Brück

Asch

2015

J Agronomy Crop Science

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With increasingly erratic rainfall patterns particularly in drought-prone production systems, the capacity of plants to recover productively from drought spells becomes an important feature for yield stability in rainfed agriculture. Consequently, effects of water management at the stem elongation stage on partitioning and remobilization of dry matter, alteration in photosynthesis and water-use efficiency (WUE), and yield components of wheat plants were studied in a glasshouse pot experiment. The plants were subjected to three soil moisture regimes: well watered during all phenological stages (WW), drought affected during stem elongation and post-anthesis stages (DD) and drought affected during stem elongation and rewatered at post-anthesis stage (DW). Total dry weight substantially decreased by both drought treatments. However, DD plants allocated relatively higher assimilates to roots whereas DW plants remobilized them to the grains. Drought applications resulted in a decrease of grain yield and thousand grain weight while reduction was more pronounced in DD treatment. Relative contribution of post-anthesis photosynthesis to dry matter formation in grain was higher in WW treatment (72.6 %) than DD (68.5 %) and DW (68.2 %) treatments. Photosynthetic rate, gas exchange and transpiration decreased whereas leaf (photosynthetic) and plant level WUE increased with drought applications. However, all these parameters were rapidly and completely reversed by rewatering. Our findings showed that partitioning of dry weight to grain increases with rewatering of wheat plants subjected to drought during stem elongation phase, but the relative contributions of remobilization of stem reserves and postanthesis photosynthesis to grain did not change. Moreover, rewatering of plants at booting stage after a drought period lead to full recovery in photosynthesis and WUE, and a significant although partial recovery of yield components, such as grain yield, TGW and harvest index.

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Section: Introductionmentioning

confidence: 99%

“…It has also been shown that genotypes may vary strongly in biomass partitioning to the different organs under drought conditions (Asch et al 1999). In high-yielding wheat genotypes, for instance, drought resulted in partitioning of a greater proportion of dry weight in stems instead of both leaves and roots (Veneklaas and Peacock 1994).…”

Section: Introductionmentioning

confidence: 99%

Photosynthesis and Remobilization of Dry Matter in Wheat as Affected by Progressive Drought Stress at Stem Elongation Stage

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Brück

Asch

2015

J Agronomy Crop Science

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“…Differences in plant water use efficiency are related to differences in the ratio of photosynthesis and transpiration for potgrown wheat cultivars (Condon et al, 1990;Farquhar and Richards, 1984;Veneklaas and Peacock, 1994). The ratio of the photosynthetic rate and transpiration rate of the leaf has a major influence on plant water use efficiency.…”

Section: Introductionmentioning

confidence: 99%

Yield and water use of wheat (Triticum aestivum) in a Mediterranean environment: Cultivar differences and sowing density effects

et al. 1996

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Yield and water use of wheat (Triticum aestivum) in a Mediterranean environment: Cultivar differences and sowing density effectsRiki van den B o o g a a r d 1'3, Erik J. Veneklaas 1,4, John M. P e a c o c k 2 and H a n s L a m b e r s 1 AbstractYield of eight wheat cuitivars was evaluated under rainfed and irrigated conditions in a Mediterranean environment. Variation in grain yield resulted from variation in both aboveground biorhass production and in harvest index. Under rainfed compared to irrigated conditions, grain yield, biomass and days to heading were decreased, whereas harvest index was increased. Grain yield of the different cultivars under rainfed conditions correlated with that under irrigated conditions in one of the two years. Among cultivars, harvest index under rainfed and irrigated conditions were correlated in both years.Water was used more efficiently for biomass production, and equally efficiently for grain production, under irrigated compared to rainfed conditions. Under rainfed conditions, crop water use efficiency was higher for cultivars developed for rainfed environments than for those developed for high-rainfall or irrigated environments. Cultivars with low-rainfall target environments had the lowest evapotranspiration under rainfed conditions. Under rainfed conditions, differences between the cultivar groups in crop water use efficiency corresponded with trends in water use efficiency of individual plants and with the ratio of photosynthesis to transpiration, measured on plants grown in a growth room.Early in the season, water was used more efficiently for biomass production at high sowing densities than at low sowing densities. Through faster biomass production and ground cover a smaller proportion of the evapotranspired water was lost in soil evaporation and a larger proportion was transpired. However, the net effect was a greater water use in the early phases of growth and consequently a lower water availability later in the season, leading to similar yields regardless of sowing density.

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“…The photosynthesis measurements summarized in Table 1 were carried out under standardized conditions, so actual rates may differ as a result of different illumination, temperature etc. Results from a previous study (Veneklaas & Peacock, 1994) suggest tbat differences in respiration may account for differences in conversion of assimilates to biomass. Mexipak had 9 "o lower WUE^ but only 4% lower WUE^.…”

Section: Cjas Exchangementioning

confidence: 87%

Leaf age‐structure effects on plant water use and photosynthesis of two wheat cultivars

Veneklaas

Boogaard

1994

New Phytologist

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The wheat cultivars ' Kalya Al ' and 'Mexipak 65', grown in pots under field conditions in a Mediterranean climate, differed only slightly in growth and water use on a whole-plant basis, although Mexipak had a smaller leaf area. When expressed on a leaf area basis, plant biomass increase and transpiration ivere significantly' greater in Mexipak. However, pre\'ious gas exchange measurennents on the youngest fully expanded leaf showed only minor differences between the two cultivars. The hypothesis that different patterns of leaf ageing contributed to the differences in plant growth and water use was tested by combining leaf demography and gas exchange measurements. Plants were subjected to two moisture treatments: 'well-watered' (frequent watering to initial soil water content) and 'intermittent drought' (Bve drying-rewatering cycles). Mexipak had, on average, older leaves than Katya in both treatments because of fast early growth, which in turn was due to a larger area of individual leaves rather than a faster leaf appearance rate. StomataJ conductance and net photosynthetic rate wert-nearly the same for the two cultivars, but were considerably reduced by drought and did not fully recover after rewatering. Stomatal conductanci:' and photosynthesis tended to decrease with age, but effects of age or treatment or their interactions were not significant and could not explain the discrepancy between wbole plant and leaf observations. Otie possible explanation is that age effects do exist in lea\es older than those investigated. Another explanation may be that changes in microclimatological conditions caused photosynthesis and transpiration to differ from rates measured under standard conditions.

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Growth, biomass allocation and water use efficiency of two wheat cultivars in a mediterranean environment; a pot experiment under field conditions

Cited by 9 publications

References 8 publications

Photosynthesis and Remobilization of Dry Matter in Wheat as Affected by Progressive Drought Stress at Stem Elongation Stage

Photosynthesis and Remobilization of Dry Matter in Wheat as Affected by Progressive Drought Stress at Stem Elongation Stage

Yield and water use of wheat (Triticum aestivum) in a Mediterranean environment: Cultivar differences and sowing density effects

Leaf age‐structure effects on plant water use and photosynthesis of two wheat cultivars

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