55 research outputs found

    Rubisco activities, properties, and regulation in three different C4 grasses under drought

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    In C4 plants, water deficit may decrease photosynthetic CO2 assimilation independently of changes in stomatal conductance, suggesting decreased turnover by ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco). The activity and biochemistry of Rubisco was studied in three different C4 grasses: Paspalum dilatatum, Cynodon dactylon, and Zoysia japonica. The objectives were to characterize the C4 Rubisco in these species and to identify factors associated with decreased photosynthetic rates caused by drought. Rubisco isolated from each of the three C4 grasses was characterized by smaller specificity factors (SC/O), larger Michaelis–Menten constants for CO2 (Kc) and O2 (Ko), and larger maximum carboxylation velocities (Vc) than Rubisco from wheat, which can be rationalized in terms of the CO2-rich environment of C4 Rubisco in the bundle sheath. During leaf dehydration the quantity and maximum activity of Rubisco remained unchanged but the initial and total activities declined slightly, possibly due to increased inhibition. Tight-binding inhibitors were present in the light but were more abundant in the dark, especially in Z. japonica, and increased in quantity with drought stress. The inhibitor from darkened leaves of Z. japonica was identified as 2-carboxyarabinitol-1-phosphate (CA1P). Consistent with the presence of CA1P, the total activity of Rubisco was decreased after 12 h darkness in Z. japonica. Ribulose-1,5-bisphosphate (RuBP) in the leaves decreased with drought stress, to quantities approximating those of Rubisco catalytic sites. The magnitude of the decrease in RuBP suggested that, at least in C. dactylon and Z. japonica, it could contribute to the drought-induced decrease in photosynthesis

    Photosynthesis by six portuguese maize cultivars during drought stress and recovery

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    Photosynthesis, chlorophyll fluorescence and leaf water parameters were measured in six Portuguese maize (Zea mays L.) cultivars during and following a period of drought stress. The leaf relative water content (RWC) responded differently among cultivars but, except for cultivar PB369, recovered close to initial values after watering was restored. Photosynthetic rate and stomatal conductance decreased with drought but more slowly in cultivars PB269 and PB260 than in cultivars AD3R, PB64, PB304 and PB369. Water use efficiency (WUE) decreased during the water stress treatment although with cultivar PB260 the decrease was marked only when the RWC fell below 40%. Recovery of WUE was seen with all cultivars except PB369. The maximum quantum efficiency of photosystem II, the photochemical quenching coefficient, the electron transport rate in PSII and the estimated functional plastoquinone pool tended to decrease with drought, while the non -photochemical quenching coefficient increased. The parameters estimated from chlorophyll fluorescence did not recover in PB369, during re - watering. The results show that PB260 and PB269 were the most tolerant and PB369 was the least tolerant cultivars to water stress. The variation found amongst the cultivars tested suggests the existence of valuable genetic resources for crop improvement in relation to drought tolerance

    The ER luminal binding protein (BiP) mediates an increase in drought tolerance in soybean and delays drought-induced leaf senescence in soybean and tobacco

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    The ER-resident molecular chaperone BiP (binding protein) was overexpressed in soybean. When plants growing in soil were exposed to drought (by reducing or completely withholding watering) the wild-type lines showed a large decrease in leaf water potential and leaf wilting, but the leaves in the transgenic lines did not wilt and exhibited only a small decrease in water potential. During exposure to drought the stomata of the transgenic lines did not close as much as in the wild type, and the rates of photosynthesis and transpiration became less inhibited than in the wild type. These parameters of drought resistance in the BiP overexpressing lines were not associated with a higher level of the osmolytes proline, sucrose, and glucose. It was also not associated with the typical drought-induced increase in root dry weight. Rather, at the end of the drought period, the BiP overexpressing lines had a lower level of the osmolytes and root weight than the wild type. The mRNA abundance of several typical drought-induced genes [NAC2, a seed maturation protein (SMP), a glutathione-S-transferase (GST), antiquitin, and protein disulphide isomerase 3 (PDI-3)] increased in the drought-stressed wild-type plants. Compared with the wild type, the increase in mRNA abundance of these genes was less (in some genes much less) in the BiP overexpressing lines that were exposed to drought. The effect of drought on leaf senescence was investigated in soybean and tobacco. It had previously been reported that tobacco BiP overexpression or repression reduced or accentuated the effects of drought. BiP overexpressing tobacco and soybean showed delayed leaf senescence during drought. BiP antisense tobacco plants, conversely, showed advanced leaf senescence. It is concluded that BiP overexpression confers resistance to drought, through an as yet unknown mechanism that is related to ER functioning. The delay in leaf senescence by BiP overexpression might relate to the absence of the response to drought

    Identification of drought-responsive microRNAs in Medicago truncatula by genome-wide high-throughput sequencing

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    <p>Abstract</p> <p>Background</p> <p>MicroRNAs (miRNAs) are small, endogenous RNAs that play important regulatory roles in development and stress response in plants by negatively affecting gene expression post-transcriptionally. Identification of miRNAs at the global genome-level by high-throughout sequencing is essential to functionally characterize miRNAs in plants. Drought is one of the common environmental stresses limiting plant growth and development. To understand the role of miRNAs in response of plants to drought stress, drought-responsive miRNAs were identified by high-throughput sequencing in a legume model plant, <it>Medicago truncatula</it>.</p> <p>Results</p> <p>Two hundreds eighty three and 293 known miRNAs were identified from the control and drought stress libraries, respectively. In addition, 238 potential candidate miRNAs were identified, and among them 14 new miRNAs and 15 new members of known miRNA families whose complementary miRNA*s were also detected. Both high-throughput sequencing and RT-qPCR confirmed that 22 members of 4 miRNA families were up-regulated and 10 members of 6 miRNA families were down-regulated in response to drought stress. Among the 29 new miRNAs/new members of known miRNA families, 8 miRNAs were responsive to drought stress with both 4 miRNAs being up- and down-regulated, respectively. The known and predicted targets of the drought-responsive miRNAs were found to be involved in diverse cellular processes in plants, including development, transcription, protein degradation, detoxification, nutrient status and cross adaptation.</p> <p>Conclusions</p> <p>We identified 32 known members of 10 miRNA families and 8 new miRNAs/new members of known miRNA families that were responsive to drought stress by high-throughput sequencing of small RNAs from <it>M. truncatula</it>. These findings are of importance for our understanding of the roles played by miRNAs in response of plants to abiotic stress in general and drought stress in particular.</p

    Variação do potencial da água da folha com o desenvolvimento da planta de batatinha (Solanum tuberosum L. cv. 'Bintje')

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    A manutenção de um balanço hídrico favorável à planta é uma condição reconhecidamente necessária para assegurar a seqüência das reações metabólicas que se desenvolvem nas células vegetais. Os deficits de água¹ nas plantas poderiam ser quantitativamente avaliados a partir de determinações do teor ou do estado de energia da água dos tecidos. Neste trabalho, o potencial osmótico das hastes e folhas, o potencial da água da folha e as relações entre este e o teor relativo de água da folha foram determinados em plantas de batata (Solanum tuberosum L.) adequadamente supridas com água do solo, em condições de campo. Os resultados revelaram que os potenciais determinados variaram durante o ciclo fenológico. Assim, o potencial da água da folha foi sendo reduzido com o desenvolvimento das plantas. Após o completo desenvolvimento vegetativo, não foi possível identificar qualquer tendência definida, crescente ou decrescente. Esta variação modificou as relações entre o potencial e o teor relativo de água da folha, de tal maneira, que o potencial associado a um determinado teor relativo de água, foi sendo reduzido a medida que as plantas se desenvolveram. A par destes resultados, pode-se concluir que o potencial da água da folha não parece ser um indicador seguro da existência de déficits fisiológicos de água na planta. O conhecimento do teor relativo de água, associado ao potencial, poderia contribuir decisivamente para fornecer uma avaliação mais precisa da condição da água nos tecidos vegetais.The maintainance of a favorable plant water budget is a condition generally regarded to assure the sequence of cell metabolism. Plant water deficits should be quantitatively evaluated through the determination of tissue water content or tissue water content or tissue water potential. In this work the osmotic potential of stems and leaves, the leaf water potential, and the relative water content-water potential relationships were determined in adequately irrigated patatoes (Solanum tuberosum L.) growing in the field. The results showed that potentials changed during the growing season. Leaf water potential decreseased with aging of the plants and after the complete vegetative growth it was not possible to observe any definite trend, either increasing or decreasing. This change affected relative water content-water potential relationships, so that the relationships shifted to progressively lower water potential for a given relative water content. The data indicated that leaf water potential does not seem a reliable indicator of physiological water deficits. The knowledge of relative water content associated with leaf water potential measurement would provide a more precise condition of water in the plant tissues

    Enzymes of assimilatory sulfate reduction in leaves of Pisum sativum: Activity changes during ontogeny and in vivo regulation by H2S and cyst(e)ine

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    Enzyme activities of assimilatory sulfate reduction were measured in leaves of Pisum sativum L., cv. Vatters Frühbusch, during their ontogenetic development, and during treatment with H2S and cyst(e)ine. Ribulose bisphosphate (RuBP) carboxylase (EC 4.1.1.39) and ferredoxin‐dependent nitrite reductase (Fd‐NiR, EC 1.7.7.1) were measured for comparison. In etiolated pea leaves, ATP‐sulfurylase (ATPase, EC 2.7.7.4), adenosine 5′‐phosphosulfate sulfotransferase (APSSTase), ferredoxin‐dependent sulfite reductase (Fd‐SiR, EC 1.8.7.1) and O‐acetyl‐L‐serine sulfhydrylase (OASSase, EC 4.2.99.8) activities were measured in appreciable rates, while neither RuBP carboxylase nor Fd‐NiR activities could be detected. During the first 2–7 days after transfer into the light all enzyme activities increased. After reaching maximal activities, ATPase, APSSTase, and Fd‐SiR activities decreased in all leaves to low or indetectable levels during the following 3–6 days. RuBP carboxylase, Fd‐NiR and OASSase, on the other hand, decreased slowly and were still at high levels of activity at the end of the experiment. Fumigation of pea plants with 1.5 μl l−1 H2S delayed the initial increase and the subsequent decrease of ATPase activity by 1–3 days. APSSTase activity decreased for 1–2 days, increased rapidly during the next 4–6 days and retained a high level of activity until the end of the experiment as did Fd‐SiR. One to two days after the beginning of fumigation the leaves started to accumulate high amounts of cyst(e)ine. When pea plants with excised roots were placed on a nutrient solution containing cyst(e)ine, APSSTase activity decreased more on 0.2 and 0.5 mM than on 1.0 mM. Fd‐SiR activity was only slightly decreased on 1.0 mM cyst(e)ine. Neither Fd‐NiR nor RuBP carboxylase activities were affected
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