Two varieties of winter wheat,Bei Nong 2(B. N. 2)and Jing 411(J. 411),were selected for osmotic adjustment study. At wheat growing stages,from recovery period to mature period,leaf relative water content(LRWC) ,water ...Two varieties of winter wheat,Bei Nong 2(B. N. 2)and Jing 411(J. 411),were selected for osmotic adjustment study. At wheat growing stages,from recovery period to mature period,leaf relative water content(LRWC) ,water potential(LWP)and saturated osmotic potential (LSOP) were positively correlated to soil relative water content (SRWC) and decreased as SRWC descended at each growth stage,and the decreasing range exhibited B. N. 2【J. 411. The turgor pressure(TP)of both the varieties decreased less than LRWC and LWP. It was shown that both varieties had a osmotic adjustment ability(OAA) ,and the decreasing range presented B. N. 2【J. 411. Both the varieties had a TP tubercle in TP vs SRWC graph at heading and filling stages,and their OAA was the strongest at these two stages.展开更多
Salinity is a major stress that adversely affects growth and productivity in plants. There are species that tolerate this stresswithin the genus Atriplex. Four species, A. lampa, A. crenatifolia, A. nummularia and A. ...Salinity is a major stress that adversely affects growth and productivity in plants. There are species that tolerate this stresswithin the genus Atriplex. Four species, A. lampa, A. crenatifolia, A. nummularia and A. argentina were compared for their ionaccumulation and water relations under saline conditions. A greenhouse study was conducted by irrigating the four species with NaCIsolutions at concentrations 0%, 1%, 2% and 4% starting when plants were six months old. Plants were harvested 45 d after startingthe salinity treatments and analyzed for their ion contents. In the four Atriplex species, Na^+ and Cl^- contents in plants increased, whileCa^2+ and Mg^2+ decreased with the increase of salinity in the irrigation solution. The results suggested that A. argentina and A.nummularia were able to maintain a higher leaf relative water content (RWC) at low leaf water potential, which was associated witha greater capacity of osmotic adjustment. A. lampa showed lower ion accumulation and minor osmotic adjustment than the otherspecies. It can be concluded that the accumulation of ions favors the lower osmotic potential and contributes to osmotic adjustment inthese halophytes.展开更多
The objective of this work was to evaluate the effect of different water deficiency and rehydration levels on the concentrations of osmoregulators in two plant species(Hymenaea courbaril and H. Stigonocarpa) in the ...The objective of this work was to evaluate the effect of different water deficiency and rehydration levels on the concentrations of osmoregulators in two plant species(Hymenaea courbaril and H. Stigonocarpa) in the Amazon. We adopted a 2×5×5 factorial system,referring to 2 species(H. courbaril and H. stigonocarpa)and 5 stages of hydration and rehydration. The five hydration and rehydration stages were established in:(1)Control treatment E0;(2) Plants with 13 days of stress after incubation—E13;(3) Plants with 26 days of stress E26;(4)The plants that were established after 26 days after incubation and rehydrated for two days(RD2);(5) rehydrated for two days(RD4). The plants that were established after 26 days after incubation and rehydrated for four days. The experiment totaled fifty young plants with five replicates.Biochemical measurements were performed at the beginning of the experiment(E0) at 13(E13) and 26(E26) days after the water stress, in which the plants were rehydrated,repeating the analyses after two(RD2) and four(RD4)days. Both species increased the sucrose concentration by18%, with a decrease of 52% in starch content. The RD4 time presented the highest mean starch concentration(0.19 mmol g-1 of the residue for H. courbaril and0.27 mmol g;of residue for H. stigonocarpa). Increased proline concentrations were recorded for controls until RD2 for both species. For glycine betaine, the highest increases in treatments E26 and RD2 were observed for the H. courbaril species. Our rehydration period was not sufficient for total recovery of pre-stress concentrations of all studied solutes.展开更多
Long-term excessive application of nitrogen fertilizer induces secondary salinization of soil,which results in inhibiting plant growth.In addition,soil moisture deficiency also affects plant growth.To investigate the ...Long-term excessive application of nitrogen fertilizer induces secondary salinization of soil,which results in inhibiting plant growth.In addition,soil moisture deficiency also affects plant growth.To investigate the effects of excessive nitrogen fertilizer and soil moisture deficiency on the antioxidant enzyme system,plant water relations analyzed through pressure-volume(P-V)curve,and photosynthetic light response parameters in tomato(Solanum lycopersicum L.Myoko)seedlings,an indoor experiment of about 50 d was conducted using two irrigation water amounts based on field capacity(soil moisture deficiency:50%-80%;adequate water:70%-80%),two nitrogen fertilizer rates(moderate nitrogen;excessive nitrogen fertilizer:0.585 g/pot)and two types of irrigation water(tap water and microbial diluent).The results showed that excessive nitrogen fertilizer(N)and soil moisture deficiency(W)reduced the biomass of tomato seedlings.In comparison to CK(combination of adequate water and tap water quality),microbial dilution(EM)increased plant biomass by 5.2%.Also,the nitrogen application increased chlorophyll relative contents(SPAD).The maximum net photosynthetic rate(Pc)decreased with nitrogen application and increased with EM application and irrigation amount.Excessive nitrogen application increased the plant nitrate reductase activity(NR).The plant NR in the N treatment showed a 13.0%increase compared to CK,and the plant NR in the treatment of nitrogen application with water deficiency(WN)increased 34.0%compared to water deficiency(W).After applying excessive nitrogen,N,EM-N,WN,EM-WN respectively increased the plant nitrate reductase activity by 13.0%,22.9%,34.0%,and 28.6%,compared with the corresponding treatment with moderate nitrogen(i.e.,CK,EM,W and EM-W).In addition,the activities of antioxidant enzymes[superoxide dismutase(SOD),peroxidase(POD)and catalase(CAT)]in four treatments of nitrogen application(N,EM-N,WN,EM-WN)also increased significantly.Both soil moisture and nitrogen fertilizer significantly affect the parameters of osmotic adjustment,which is manifested in the reduction of osmotic potential(π_(FT)),and the increase in the osmotic concentration(C_(osm))and concentration difference(ΔC_(osm)).But the decrease in the relative water content of apoplast(ζ_(ap))indicated that water deficiency and excessive nitrogen reduced the water absorption and water retention capacity of tomatoes to a certain extent.In conclusion,excessive nitrogen application and soil moisture deficiency inhibit plant growth significantly in this experiment.Meanwhile,microbial dilution can alleviate excessive nitrogen fertilizer and water stress to some extent,but the effect was not significant.展开更多
We aimed to study impact of drought stress on physiological traits of field grown 8 durum and 14 bread wheat genotypes. Drought caused decrease of leaf gas exchange parameters—photosynthesis rate (Pn), stomatal condu...We aimed to study impact of drought stress on physiological traits of field grown 8 durum and 14 bread wheat genotypes. Drought caused decrease of leaf gas exchange parameters—photosynthesis rate (Pn), stomatal conductance (gs), and transpiration rate (E), an increase of intercellular CO2 concentration (Ci). Area (LA) and dry mass of leaves per stem, leaf area index (LAI) of genotypes significantly reduced from booting to watery ripe stages. Water deficiency led to a decrease of chlorophyll a, b (Chla,b) and carotenoids (Car (x+c) content, relative water content (RWC). Water stress more affected on LA than leaf dry mass of wheat genotypes, leaf specific mass (LSM) increased. The Chl(a+b) content, Pn and yield of bread wheat genotypes were relatively higher than durum wheat ones. Physiological traits may be reliable for selection of drought tolerant wheat genotypes.展开更多
Drought stress is an important factor affecting plant growth and development.It will provide a theoretical basis for cultivating new stress-resistant varieties and improving water utilization rate of plants by studyin...Drought stress is an important factor affecting plant growth and development.It will provide a theoretical basis for cultivating new stress-resistant varieties and improving water utilization rate of plants by studying the regulation mechanism of osmotic adjustment and water transportation under drought stress,and understanding the physiological and biochemical characteristics and stress resistance mechanism.展开更多
为了探讨油菜素内酯对植物耐盐性的调控,以甘蓝型油菜"南盐油1号"为试验材料,研究了外源24-表油菜素内酯(24-EBL)对100、200 mmol/L Na Cl胁迫下油菜幼苗干重(DW)、相对含水量(RWC)、渗透调节能力(OAA)、叶片气体交换参数、...为了探讨油菜素内酯对植物耐盐性的调控,以甘蓝型油菜"南盐油1号"为试验材料,研究了外源24-表油菜素内酯(24-EBL)对100、200 mmol/L Na Cl胁迫下油菜幼苗干重(DW)、相对含水量(RWC)、渗透调节能力(OAA)、叶片气体交换参数、气孔限制值(Ls)等的调节效应,还测定了不同器官的Na+、K+、Cl-含量,并计算各器官的K+/Na+和SK,Na。结果表明:(1)在不同浓度的盐胁迫下,油菜幼苗DW显著下降,胁迫下外源喷施10-12、10-10、10-8、10-6mol/L 24-EBL作用下,油菜植株干重均不同程度的上升,且植株干重都在10-10mol/L 24-EBL(EBL2)处理下达到最大值,分别比100、200 mmol/L Na Cl胁迫下增加29%和20%。与对照相比,非盐胁迫下外源喷施10-12、10-10、10-8、10-6mol/L 24-EBL,油菜幼苗植株干重与对照相比均无显著变化。(2)不同Na Cl浓度胁迫下,油菜叶片的RWC显著下降,外施EBL2可显著提高油菜叶片的RWC和OAA。(3)不同浓度Na Cl胁迫下,油菜幼苗叶片净光合速率(Pn)、气孔导度(Gs)、胞间CO2浓度(Ci)和蒸腾速率(Tr)均不同程度下降,而Ls显著上升,而外喷EBL2可不同程度的提高Pn、Gs、Ci、Tr,降低Ls。(4)与对照相比,Na Cl胁迫下油菜幼苗叶片、叶柄和根的Na+和Cl-含量均显著上升,Na Cl浓度愈高,Na+和Cl-含量上升愈显著。而K+含量均下降,外源EBL2可显著降低幼苗各器官的Na+和Cl-含量,对幼苗叶片K+含量没有影响,但提高了叶柄和根中的K+含量。上述表明,合适浓度的24-EBL外喷可明显提高油菜的耐盐水平,且不同浓度Na Cl胁迫下,最适24-EBL浓度均为10-10mol/L。主要是因为外源喷施24-EBL能显著改善离子稳态和渗透调节能力,从而改善盐胁迫下油菜幼苗的光合作用、水分状况,提高其耐盐性。而24-EBL对盐处理下油菜植株气孔限制的显著改善是其促进其光合、水分利用的重要原因,也是其对100 mmol/L Na Cl处理的油菜生长调控效果优于200 mmol/L Na Cl处理的重要原因之一。结果还显示,在叶片中,24-EBL外施可通过排Na+和Cl-来维持植株离子稳态,而对K+影响不大;在根、茎中可通过排Na+、排Cl-、吸K+维持稳态。展开更多
文摘Two varieties of winter wheat,Bei Nong 2(B. N. 2)and Jing 411(J. 411),were selected for osmotic adjustment study. At wheat growing stages,from recovery period to mature period,leaf relative water content(LRWC) ,water potential(LWP)and saturated osmotic potential (LSOP) were positively correlated to soil relative water content (SRWC) and decreased as SRWC descended at each growth stage,and the decreasing range exhibited B. N. 2【J. 411. The turgor pressure(TP)of both the varieties decreased less than LRWC and LWP. It was shown that both varieties had a osmotic adjustment ability(OAA) ,and the decreasing range presented B. N. 2【J. 411. Both the varieties had a TP tubercle in TP vs SRWC graph at heading and filling stages,and their OAA was the strongest at these two stages.
文摘Salinity is a major stress that adversely affects growth and productivity in plants. There are species that tolerate this stresswithin the genus Atriplex. Four species, A. lampa, A. crenatifolia, A. nummularia and A. argentina were compared for their ionaccumulation and water relations under saline conditions. A greenhouse study was conducted by irrigating the four species with NaCIsolutions at concentrations 0%, 1%, 2% and 4% starting when plants were six months old. Plants were harvested 45 d after startingthe salinity treatments and analyzed for their ion contents. In the four Atriplex species, Na^+ and Cl^- contents in plants increased, whileCa^2+ and Mg^2+ decreased with the increase of salinity in the irrigation solution. The results suggested that A. argentina and A.nummularia were able to maintain a higher leaf relative water content (RWC) at low leaf water potential, which was associated witha greater capacity of osmotic adjustment. A. lampa showed lower ion accumulation and minor osmotic adjustment than the otherspecies. It can be concluded that the accumulation of ions favors the lower osmotic potential and contributes to osmotic adjustment inthese halophytes.
基金supported by the Universidade Federal Rural da Amazonia
文摘The objective of this work was to evaluate the effect of different water deficiency and rehydration levels on the concentrations of osmoregulators in two plant species(Hymenaea courbaril and H. Stigonocarpa) in the Amazon. We adopted a 2×5×5 factorial system,referring to 2 species(H. courbaril and H. stigonocarpa)and 5 stages of hydration and rehydration. The five hydration and rehydration stages were established in:(1)Control treatment E0;(2) Plants with 13 days of stress after incubation—E13;(3) Plants with 26 days of stress E26;(4)The plants that were established after 26 days after incubation and rehydrated for two days(RD2);(5) rehydrated for two days(RD4). The plants that were established after 26 days after incubation and rehydrated for four days. The experiment totaled fifty young plants with five replicates.Biochemical measurements were performed at the beginning of the experiment(E0) at 13(E13) and 26(E26) days after the water stress, in which the plants were rehydrated,repeating the analyses after two(RD2) and four(RD4)days. Both species increased the sucrose concentration by18%, with a decrease of 52% in starch content. The RD4 time presented the highest mean starch concentration(0.19 mmol g-1 of the residue for H. courbaril and0.27 mmol g;of residue for H. stigonocarpa). Increased proline concentrations were recorded for controls until RD2 for both species. For glycine betaine, the highest increases in treatments E26 and RD2 were observed for the H. courbaril species. Our rehydration period was not sufficient for total recovery of pre-stress concentrations of all studied solutes.
基金This work was financially supported by the National Natural Science Foundation of China(51509068)Fundamental Research Funds for the Central Universities(B200202093).
文摘Long-term excessive application of nitrogen fertilizer induces secondary salinization of soil,which results in inhibiting plant growth.In addition,soil moisture deficiency also affects plant growth.To investigate the effects of excessive nitrogen fertilizer and soil moisture deficiency on the antioxidant enzyme system,plant water relations analyzed through pressure-volume(P-V)curve,and photosynthetic light response parameters in tomato(Solanum lycopersicum L.Myoko)seedlings,an indoor experiment of about 50 d was conducted using two irrigation water amounts based on field capacity(soil moisture deficiency:50%-80%;adequate water:70%-80%),two nitrogen fertilizer rates(moderate nitrogen;excessive nitrogen fertilizer:0.585 g/pot)and two types of irrigation water(tap water and microbial diluent).The results showed that excessive nitrogen fertilizer(N)and soil moisture deficiency(W)reduced the biomass of tomato seedlings.In comparison to CK(combination of adequate water and tap water quality),microbial dilution(EM)increased plant biomass by 5.2%.Also,the nitrogen application increased chlorophyll relative contents(SPAD).The maximum net photosynthetic rate(Pc)decreased with nitrogen application and increased with EM application and irrigation amount.Excessive nitrogen application increased the plant nitrate reductase activity(NR).The plant NR in the N treatment showed a 13.0%increase compared to CK,and the plant NR in the treatment of nitrogen application with water deficiency(WN)increased 34.0%compared to water deficiency(W).After applying excessive nitrogen,N,EM-N,WN,EM-WN respectively increased the plant nitrate reductase activity by 13.0%,22.9%,34.0%,and 28.6%,compared with the corresponding treatment with moderate nitrogen(i.e.,CK,EM,W and EM-W).In addition,the activities of antioxidant enzymes[superoxide dismutase(SOD),peroxidase(POD)and catalase(CAT)]in four treatments of nitrogen application(N,EM-N,WN,EM-WN)also increased significantly.Both soil moisture and nitrogen fertilizer significantly affect the parameters of osmotic adjustment,which is manifested in the reduction of osmotic potential(π_(FT)),and the increase in the osmotic concentration(C_(osm))and concentration difference(ΔC_(osm)).But the decrease in the relative water content of apoplast(ζ_(ap))indicated that water deficiency and excessive nitrogen reduced the water absorption and water retention capacity of tomatoes to a certain extent.In conclusion,excessive nitrogen application and soil moisture deficiency inhibit plant growth significantly in this experiment.Meanwhile,microbial dilution can alleviate excessive nitrogen fertilizer and water stress to some extent,but the effect was not significant.
文摘We aimed to study impact of drought stress on physiological traits of field grown 8 durum and 14 bread wheat genotypes. Drought caused decrease of leaf gas exchange parameters—photosynthesis rate (Pn), stomatal conductance (gs), and transpiration rate (E), an increase of intercellular CO2 concentration (Ci). Area (LA) and dry mass of leaves per stem, leaf area index (LAI) of genotypes significantly reduced from booting to watery ripe stages. Water deficiency led to a decrease of chlorophyll a, b (Chla,b) and carotenoids (Car (x+c) content, relative water content (RWC). Water stress more affected on LA than leaf dry mass of wheat genotypes, leaf specific mass (LSM) increased. The Chl(a+b) content, Pn and yield of bread wheat genotypes were relatively higher than durum wheat ones. Physiological traits may be reliable for selection of drought tolerant wheat genotypes.
基金Supported by Thousand Talents Program for High-end Innovative Talents of Qinghai Province(2020,2022).
文摘Drought stress is an important factor affecting plant growth and development.It will provide a theoretical basis for cultivating new stress-resistant varieties and improving water utilization rate of plants by studying the regulation mechanism of osmotic adjustment and water transportation under drought stress,and understanding the physiological and biochemical characteristics and stress resistance mechanism.
