This study was conducted to investigate the physiological response of sugarcane genotypes to drought and its consequence for stalk yield. Sugarcane genotypes IACSP94-2094, IACSP96-2042 and SP87-365 were subjected to water deficit during the initial growth phase by withholding water. Resistance and sensitivity patterns were defined by the impact of drought on the stalk yield and content of soluble solids in the stalk juice. IACSP94-2094 and SP87-365 were considered drought-resistant genotypes, as the stalk dry matter production and yield of soluble solids were not reduced by the water deficit. Although drought caused reductions in leaf gas exchange in all the genotypes, IACSP96-2042 was most affected when considering the cumulative reduction in photosynthesis throughout the experimental period. This photosynthetic impairment of IACSP96-2042 was related to both non-stomatal and stomatal limitations, whereas photosynthesis in SP87-365 and IACSP94-2094 were only stomatally limited under drought. In general, a reduced photosynthetic sensitivity to water deficit was an important physiological trait for dry matter production in sugarcane plants, and the concentrations of soluble carbohydrates, sucrose, starch and proline in the leaves did not reveal consistent differences between the patterns of resistance and sensitivity. Even though IACSP96-2042 was severely affected by water shortage, this genotype presented a similar stalk yield under drought and the highest stalk yield under well-watered conditions when compared to the other genotypes. This response to variable water conditions is interesting for regions with seasonal drought, whereas the pattern of drought resistance is more appropriate for regions in which drought occurs for long periods during the crop season. Our findings are also discussed from the point of view that increases in sugarcane yield and sustainable agriculture may be reached by choosing the best genotype for each specific environmental condition. I N T RO D U C T I O NWater stress affects many aspects of plant metabolism, such as photosynthesis, which are limited by decreases in stomatal conductance, the first line of defence that is activated even before reductions in the leaf water content (Chaves et al., 2008;Yordanov et al., 2003). In addition to stomatal limitation, photosynthesis is also down-regulated by decreases in total soluble protein and chlorophyll content and photochemical and biochemical inefficiencies, indicating a metabolic limitation under severe stressful §Corresponding author.
RESUMOO crescimento e a distribuição do sistema radicular afetam as respostas das plantas à ocorrência de deficiência hídrica. Este trabalho teve como objetivo avaliar em mudas de laranjeira 'Valência' enxertada sobre limoeiro 'Cravo' ou Poncirus trifoliata ('Trifoliata') o crescimento de raízes, as trocas gasosas (CO 2 e H 2 O), o potencial da água na folha e a distribuição de carboidratos nos diversos órgãos, em plantas submetidas à deficiência hídrica. As mudas foram transplantadas para 32 rizotrons, que permitiam a visualização das raízes, sendo 16 para cada porta-enxerto e submetidas ou não à irrigação. A deficiência hídrica às plantas foi aplicada pela interrupção do fornecimento de água às plantas. A condutância estomática decaiu após o quarto dia sem irrigação, causando redução da fotossíntese, da transpiração e da eficiência de carboxilação. O teor de carboidrato total (sacarose + açúcares redutores + amido) em plantas sem estresse foi maior em 'Trifoliata', e entre os tratamentos com deficiência hídrica foi sempre inferior. As massas secas das plantas sem deficiência hídrica foram maiores, em ambos os porta-enxertos. Entre os tratamentos irrigados e não irrigados, o comprimento das raízes dentro de um mesmo tipo de porta-enxerto foram semelhantes. Porém, o comprimento das raízes de laranjeira 'Valência' sobre 'Cravo' foi significativamente maior. Mesmo sob deficiência hídrica e grande queda da produção fotossintética, as raízes permaneceram crescendo, possivelmente às expensas de substrato mobilizado de outros órgãos.Palavras-chave: Carboidratos, Citrus sinensis, crescimento vegetativo, limoeiro 'Cravo', 'Trifoliata', trocas gasosas.( The growth and distribution of the root system affect the response of the plants to water deficit. This work aim at the to evaluation of 'Valencia' orange budded on 'Rangpur´ lime and Poncirus trifoliata ('Trifoliata') as to root growth, gas exchange (CO 2 and H 2 O), leaf water potential and distribution of carbohydrates in several organs, in plants submitted to water deficit. Plants were transplanted to 32 rizotrons, which allowed root visualization of the roots. Sixteen plants in each rootstock were submitted to irrigation and the other 16 remained without irrigation. Water deficit was induced withholding the water supply. Stomatal conductance declined after the fourth day without irrigation, causing a reduction of the photosynthesis, the transpiration and the carboxilation efficiency. The total carbohydrate content (sucrose + reducing sugars + starch) in plants without water stress was greater in 'Trifoliata', and among the water deficit treatments it was always less. The dry phytomass of the plants without water deficit was greater in both rootstocks. Among the irrigated and non irrigated treatments, the length of the roots same of rootstocks was similar. However, the root lengths of plants on 'Rangpur´ lime were significantly greater than that on 'Trifoliata'. Even under water deficit and great decrease of the photosynthetic production, the roots maintained growth, ...
The water availability at early phenological stages is critical for crop establishment and sugarcane varieties show differential performance under drought. Herein, we evaluated the relative importance of morphological and physiological plasticity of young sugarcane plants grown under water deficit, testing the hypothesis that high phenotypic plasticity is associated with drought tolerance. IACSP95-5000 is a high yielding genotype and IACSP94-2094 has good performance under water limiting environments. Plants were grown in rhizotrons for 35 days under three water availabilities: high (soil water matric potential [Ψm] higher than -20 kPa); intermediate (Ψm reached -65 and -90 kPa at the end of experimental period) and low (Ψm reached values lower than -150 kPa). Our data revealed that morphological and physiological responses of sugarcane to drought are dependent on genotype and intensity of water deficit. In general, IACSP95-5000 showed higher physiological plasticity given by leaf gas exchange and photochemical traits, whereas IACSP94-2094 showed higher morphological plasticity determined by changes in leaf area (LA) and specific LA. As IACSP94-2094 accumulated less biomass than IACSP95-5000 under varying water availability, it is suggested that high morphological plasticity does not always represent an effective advantage to maintain plant growth under water deficit. In addition, our results revealed that sugarcane varieties face water deficit using distinct strategies based on physiological or morphological changes. When the effectiveness of those changes in maintaining plant growth under low water availability is taken into account, our results indicate that the physiological plasticity is more important than the morphological one in young sugarcane plants.
Low temperatures negatively impact the metabolism of orange trees, and the extent of damage can be influenced by the rootstock. We evaluated the effects of low nocturnal temperatures on Valencia orange scions grafted on Rangpur lime or Swingle citrumelo rootstocks. We exposed six-month-old plants to night temperatures of 20ºC and 8ºC under controlled conditions. After decreasing the temperature to 8ºC, there were decreases in leaf CO 2 assimilation, stomatal conductance, mesophyll conductance and CO 2 concentration in the chloroplasts, in plant hydraulic conductivity and in the maximum electron transport rate driven ribulose-1,5bisphosphate (RuBP) regeneration in plants grafted on both rootstocks. However, the effects of low night temperature were more severe in plants grafted on Rangpur rootstock, which also presented reduction in the maximum rate of RuBP carboxylation and in the maximum quantum efficiency of the PSII. In general, irreversible damage due to night chilling was found in the photosynthetic apparatus of plants grafted on Rangpur lime. Low night temperatures induced similar changes in the antioxidant metabolism, preventing oxidative damage in citrus leaves on both rootstocks. As photosynthesis is linked to plant growth, our findings indicate that the rootstock may improve the performance of citrus trees in environments with low night temperatures, with Swingle rootstock improving the photosynthetic acclimation in leaves of orange plants.
The aim of this study was to evaluate the effects of low air temperature during nocturnal (T N ) and diurnal (T D ) periods as well as the substrate temperature (T S ) on photosynthesis of 'Valencia' orange tree grafted on Rangpur lime rootstock. The experiment was carried out in a growth chamber with seven-month-old plants. The plants were exposed to the following temperature regimes: low substrate temperature (LT S , with: T D = 28°C, T N = 20°C, T S = 10°C); low air temperature during night (LT N , with: T D = 28°C, T N = 10°C, T S = 26°C); low temperature during nighttime and also low substrate temperature (LT SN, with: T D = 28°C, T N = 10°C, T S = 10°C); low air temperature during both diurnal and nocturnal periods (LT ND , with: T D = 17°C, T N = 10°C, T S = 26°C); and finally to low air temperature (night and day) and low substrate temperature (LT SND , with: T D = 17°C, T N = 10°C, T S = 10°C). As reference (control), plants were subjected to T D = 28°C, T N = 20°C, and T S = 26°C. Measurements of leaf gas exchange, photochemical activity and carbohydrate concentrations were performed after six days of exposure to each thermal treatment. Compared to the control, all thermal regimes caused reductions in photosynthesis due to diffusive and metabolic limitations. The photoinhibition was transient in plants exposed to night and substrate low temperatures, whereas it was severe and chronic in plants subjected to chilling during the diurnal period. However, the lowest photosynthesis was observed in plants with low substrate temperature of 10°C (in LT S , LT SND and LT SN treatments), regardless of air temperature. The occurrence of cold night and/or its combination with low substrate temperature caused accumulation of starch in leaves. When considering carbohydrate concentrations in stems and roots, it was not possible to establish a clear response pattern to chilling. In conclusion, the low substrate temperature causes a greater reduction of CO 2 assimilation in citrus plants as compared to the occurrence of low air temperature, being such response a consequence of diffusive and biochemical limitations.
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