132 resultados para Respiration.
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Microcoleus vaginatus isolated from a desert algal crust of Shapotou was cultured in BG-11 medium containing 0.2mol l(-1) NaCl or 0.2mol l(-1) NaCl plus 100mg l(-1) sucrose, extracellular polymeric substances (EPS) or hot water-soluble polysaccharides (HWP), respectively. Photosynthetic oxygen evolution rates, photosystem 11 activity (Fv/Fm) and dark respiration of NaCl-stressed cells were enhanced significantly by the added sucrose or EPS under salt stress conditions (0.2mol l(-1) NaCl). Compared with cells treated with salt alone, sodium contents in cells reduced significantly; the content of cellular total carbohydrate did not change, and intracellular sucrose, water-soluble sugar increased significantly following the addition of exogenous carbohydrates. Sucrose synthase (SS) activity of NaCl-stressed cells increased following the addition of sucrose, and sucrose phosphate synthase (SPS) activity of NaCl-stressed cells increased following the addition of exogenous sucrose, EPS or HWP compared with cells stressed with NaCl only. The results suggested that the extruded EPS might be re-absorbed by cells of M. vaginatus as carbon source, they could increase salt tolerance of M. vaginatus through the changes of carbohydrate metabolism and the selective uptake of sodium ions. (C) 2003 Elsevier Science Ltd. All rights reserved.
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Chlorella pyrenoidosa was cultured with 350 and 700 p.p.m.v. CO2 at varied levels of light to see the impacts of doubled atmospheric CO2 concentration on its growth and photosynthesis. The CO2 enrichment did not affect the growth rate (mu), but significantly increased the cell density when light was sufficiently supplied. The CO2 enrichment significantly depressed light-saturated photosynthesis and dark respiration in the cells grown under a high-light regime, but not those under a low-light regime. The light-saturating point for photosynthesis and photosynthetic efficiency was not affected by the CO2 enrichment under either the high-light or low-light conditions.
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The effects on photosynthesis of CO, and desiccation in Porphyra haitanensis were investigated to establish the effects of increased atmospheric CO2 on this alga during emersion at low tides. With enhanced desiccation, net photosynthesis, dark respiration, photosynthetic efficiency, apparent carboxylating efficiency and light saturation point decreased, while the light compensation point and CO2 compensation point increased. Emersed net photosynthesis was not saturated by the present atmospheric CO2 level (about 350 ml m(-3)). and doubling the CO2 concentration (700 ml m(-3)) increased photosynthesis by between 31% and 89% at moderate levels of desiccation. The relative enhancement of emersed net photosynthesis at 700 ml m(-3) CO2 was greater at higher temperatures and higher levels of desiccation. The photosynthetic production of Porphyra haitanensis may benefit from increasing atmospheric CO2 concentration during emersion.
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Diurnal photosynthesis of Nostoc flagelliforme was investigated at varied levels of CO2 concentrations and desiccation in order to estimate the effects of enriched CO2 and watering on its daily production. Photosynthetic activity was closely correlated with the desiccated status of the algal mats, increased immediately after watering, reached a maximum at moderate water loss, and then declined with further desiccation. Increased CO2 concentration enhanced the diurnal photosynthesis and raised the daily production. Watering twice per day enhanced the daily production due to prolonged period of active photosynthesis. The values of daily net production were 1321280 mumol CO2 g (d. wt)(-1) d(-1), corresponding to about 0.6-6.1% daily increase in dry weight. High-CO2-grown mats required higher levels of photon flux density to saturate the alga's photosynthesis in air. Air-grown mats showed higher photosynthetic affinity for CO2 and higher levels of dark respiration compared with high-CO2-grown samples.
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Photosynthetic responses of rewetted Nostoc flagelliforme to CO2, desiccation, light and temperature were investigated under emersed conditions in order to characterize its ecophysiological behaviour in nature. Net photosynthesis increased to a maximum rate at about 30 % water loss, then decreased, while dark respiration always decreased with the progress of desiccation. Light-saturated photosynthesis and dark respiration were significantly reduced at 8 degreesC, but remained little affected by changes of temperature within the range of 15-35 degreesC. Photosynthetic efficiency (alpha) was maximal at the beginning of desiccation and then reduced with increased water loss. Saturating irradiance for photosynthesis was about 194-439 mu mol quanta m(-2) s(-1), being maximal at about 30 % water loss. No photoinhibition was observed at irradiances up to 1140 mu mol m(-2) s(-1). Light compensation points were about 41-93 mu mol m(-2) s(-1). Photosynthesis of N. flagelliforme was CO2-limited at the present atmospheric CO2 level. The CO2-saturated photosynthesis increased with increase of irradiance (190-1140 mu mol m(-2) s(-1)) and temperature (8-25 degreesC) and decreased significantly with water loss (0-75 %). Photosynthetic affinity for CO2 was sensitive to temperature and irradiance. The CO2 compensation point (Gamma) increased significantly with increased temperature and was insensitive to irradiance. Desiccation did not affect Gamma values before water loss exceeded 70 %. Photorespiratory CO2 release did not occur in N. flagelliforme at the current atmospheric CO2 level.
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Superoxide dismutase activity in water hyacinth leaves was not sensitive to small changes in environmental pH, but declined markedly with greater pH changes. KCN inhibited superoxide dismutase activity, suggesting that the enzyme was mainly composed of the Cu-Zn form. Low temperature (2-degrees-C) treatment caused a decline in superoxide dismutase activity. This effect became more pronounced as the treatment time was prolonged. Furthermore, the decline was much more significant than reductions of glucose-6-phosphate dehydrogenase activity or respiration under comparable conditions. With increasing physiological age, superoxide dismutase activity declined and was significantly lower in old than in young leaves. Therefore, superoxide dismutase activity might be employed as one of physiological parameters in studying leaf senescence.
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为探讨黄土丘陵区草地植被自然恢复过程中土壤微生物活性的变化特征及其影响因素,采用"时空互代"法采集宁夏云雾山自然保护区8个不同植被恢复年限的春、夏两季0~20cm和20~40cm的土样,用室内密闭静态培养—碱液吸收法测定了新鲜和风干土样的基础呼吸。结果表明:土壤基础呼吸随植被恢复年限增加呈增加趋势,土壤呼吸强度和累积呼吸量都表现为植被恢复73年和78年较高,而耕地和植被恢复3年最低。采样季节对呼吸强度测定有较大影响,春季土样能更好地反映土壤微生物活性的变化。风干土样可以通过预培养后测定土壤的呼吸作用,且能更加稳定地反映不同土壤之间的差异。在测定土壤基础呼吸时,利用1d或3d的培养平均值能更稳定地表现不同土壤的特性。累积呼吸量可较呼吸强度更直观地反映不同土壤的微生物活性。土壤有机质和全氮含量与土壤呼吸强度密切相关。
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依据黄土旱塬区黑垆土上中国科学院长武站长期定位试验(始于1984年),于2008年3月到6月,测定了冬小麦连作系统中返青期、拔节期、抽穗期、灌浆期和收获期土壤呼吸日变化、生育期变化以及土壤可溶性有机碳(Dissolved organic C,DOC)和微生物量碳(Soil microbial biomass C,MBC),研究了施肥措施对土壤呼吸、DOC和MBC的影响以及土壤呼吸与碳组分之间的关系。研究涉及6个处理:休闲地(F)、不施肥(CK)、有机肥(M)、氮肥(N)、氮磷肥(NP)和氮磷有机肥(NPM)。结果表明,冬小麦连作系统中土壤呼吸的日变化格局呈单峰曲线,最高值出现在12:00左右(拔节期)和14:30左右(成熟期),最小值出现在0:00~3:00之间或6:00左右;冬小麦土壤呼吸速率拔节期最高,其次是灌浆后期,抽穗期最低;不同施肥条件下,各生育期土壤呼吸速率大小顺序:NPM>M>NP>N>CK>F。土壤水分亏缺是导致抽穗期和灌浆期土壤呼吸速率降低的重要原因。各施肥处理DOC含量高低顺序为灌浆期>抽穗期>成熟期>返青期>拔节期;除M,NPM处理MBC含量拔节期>灌浆期外,各施肥处理MBC含量高低顺序...
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土壤呼吸在全球碳收支中占有重要的地位,笔者对草地生态系统土壤呼吸在陆地生态系统碳平衡中的作用、土壤呼吸的分类及其影响因素等方面进行了综述。结果表明,草地生态系统土壤呼吸在不同时间空间各组分所占比例不同,生物、非生物及人为活动等因素对草地土壤呼吸影响各异,主要从土壤温度、气候变暖、土壤湿度、降水、干旱化、土壤C/N等非生物因素,叶面积指数、植物光合作用、植被凋落物等生物因素以及人类干扰活动等方面具体阐述这些因素变化对土壤呼吸产生的影响,并对草地土壤呼吸的Q10值及各影响因素间的交互作用进行归纳总结。提出草地生态系统土壤呼吸研究存在的问题和今后重点发展方向,并对未来草地生态系统土壤呼吸的研究工作做了进一步的展望。
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试验研究了在延安日光温室不同前茬作物条件下,黄瓜随着生长季节的变化其产量和品质及土壤呼吸和酶活性的动态变化。结果表明,前茬为豇豆的黄瓜产量和土壤碱性磷酸酶活性较高,前茬为番茄的黄瓜可溶性糖含量和土壤呼吸强度较高,前茬为四季豆的黄瓜维生素C含量较高,前茬为翻青玉米的黄瓜硝酸盐含量和土壤脲酶活性较高,前茬为翻青黑豆的土壤蔗糖酶活性较高。从提高黄瓜产量的角度出发,豇豆-黄瓜是最佳模式,而从改善黄瓜品质的角度出发,番茄-黄瓜和四季豆-黄瓜是最优模式
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water wind erosion crisscross region; soil respiration rate; seasonal changes; land use pattern; soil temperature; soil moisture; 【摘要】 以黄土高原水蚀风蚀交错区神木县六道沟小流域为研究区,采用动态密闭气室法对植物生长季节(2007年5~10月)5种土地利用方式的土壤呼吸速率进行了测定,并结合水热因子,对不同土地利用方式间土壤呼吸速率的差异性以及其和温度、含水量之间的关系进行了分析。结果表明:5种土地利用类型土壤呼吸速率季节性变化均呈现单峰型曲线,与气温变化趋势一致,其7、8月份土壤呼吸速率均显著高于其它月份(P<0.05);生长季节土壤CO2平均释放速率顺序为:长芒草地>苜蓿地>柠条地>农地>沙柳地,草地在生长前期和旺盛期土壤呼吸强度均显著高于农地和灌木林地;除沙柳地和苜蓿地以外,在土壤呼吸与所有温度指标的关系中,与10cm深度的土壤温度相关性最好,且除沙柳地外,其它4种土地利用类型均与之达到显著相关;农地土壤呼吸对温度的响应最敏感(Q10值为2.20),除沙柳地(Q10值为1.48)外,其它4种土地利用类型Q10值均在2.0左右,接近于全球Q10的平均水平;通过Van’t Hoff模型估算,2007年植物整个生长季节(5~10月份),5种土地利用类型土壤呼吸量从高到低依次为:苜蓿地259gC·m-2,长芒草地236gC·m-2,柠条地226...
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采用时空互代法,以典型侵蚀环境纸坊沟流域不同封禁年限的狼牙刺群落和杂灌群落为研究对象,选取放牧地和天然次生林为参照,分析了生态恢复过程中土壤微生物生物量、呼吸强度、代谢商及理化性质的演变特征。结果表明,封禁后土壤理化性质明显改善;微生物生物量随封禁年限的延长变化显著,阳坡随封禁年限增加土壤微生物生物量逐渐增加,25 a后微生物生物量碳、氮、磷较封禁前分别增加252%、161%和174%,但显著低于天然侧柏林,仅为其39.0%、41.8%和53.7%;阴坡封禁前10年微生物生物量迅速增加,随后增加幅度减缓,呈波动式缓慢上升趋势;封禁25 a后微生物生物量碳、氮、磷分别增加108%、93%和102%,但明显低于天然杂灌丛群落和辽东栎林,仅为辽东栎林的54.4%、49.1%和40.1%。土壤呼吸强度在封禁5 a后增大明显,且随着年限增加逐渐上升,阳坡25 a时达到最大值,而阴坡15 a时达到最大值,随后开始有所下降,25 a后降至最低点,但仍显著高于放牧地,相同封禁年限的土壤呼吸强度阴坡明显高于阳坡。qCO2随着封禁进程逐渐降低,25 a后达到最低值。相关性分析显示微生物生物量碳、氮、磷、呼吸强度、qCO2与土壤养...
Resumo:
土壤呼吸是森林生态系统碳循环的重要组成部分,对土壤呼吸的主要组分根系呼吸和土壤微生物呼吸进行分离并量化,对于了解土壤碳释放规律、估算生态系统土壤碳的年际通量以及预测气候变化条件下根系或土壤微生物对土壤碳释放格局的影响具有重要意义。本文采用挖壕法测定辽东山区蒙古栎林、杂木林和胡桃楸林的土壤表面CO2通量,并同步分析土壤水热因子及土壤有机质、N含量、根系生物量、土壤酶活性、土壤微生物生物量等。研究结果表明:(1)辽东山区次生林0-10cm土壤有机质含量为9.29-18.15%,全氮含量为0.43-0.90%,pH值为5.67-6.19;次生林生长季细根生物量平均为152.61- 447.79 g/m2,粗根生物量平均为255.42-507.42 g/m2,根系总量平均为540.93-955.22 g/m2;土壤酶活性季节变化明显,且具垂直分布特征,蒙古栎林的土壤转化酶、淀粉酶和脱氢酶活性最高,胡桃楸林最低,胡桃楸林过氧化氢酶活性相对最大;土壤微生物量碳、氮的季节变化呈明显的单峰曲线并与土壤温度相关,土壤微生物量碳氮之间具显著相关性(P<0.05)。(2)次生林土壤总呼吸、根呼吸和土壤微生物呼吸具明显的日、季变化规律,生长季根呼吸贡献相对较低,胡桃楸林根呼吸贡献率为34.0-34.8%,蒙古栎林为17.9-28.4%,杂木林为14.7-35.3%;土壤微生物呼吸贡献率为66.0-85.3%,高于根呼吸贡献率,说明辽东山区次生林土壤微生物呼吸决定土壤总呼吸的变化趋势。(3)土壤呼吸与地下5cm土壤温度呈指数函数关系,土壤总呼吸的Q10值为1.29-2.30,微生物呼吸的Q10值为1.28-2.09,根呼吸的Q10值为1.29-3.72;土壤总呼吸、微生物呼吸、根呼吸与土壤含水量均无明显相关关系;蒙古栎林根呼吸与细根生物量显著相关,杂木林根呼吸与粗根生物量及根系总生物量显著相关,胡桃楸林根呼吸与根系生物量总量显著相关(P<0.05);微生物呼吸与淀粉酶、转化酶、脱氢酶、过氧化氢酶均无显著相关性(除胡桃楸林与过氧化氢酶显著相关);微生物呼吸与土壤微生物量碳、氮均呈显著线性相关关系(P<0.05)。(4)蒙古栎林土壤总呼吸、根呼吸、土壤微生物呼吸年际碳释放量分别为572.78、147.78和425.59 g C m-2a-1,杂木林分别为403.12、108.92、297.51 g C m-2a-1,胡桃楸林分别为519.47、173.75、345.72 g C m-2a-1;生长季和非生长季通过根呼吸释放的碳量均小于分解土壤有机质的微生物呼吸释放的碳量,非生长季次生林土壤碳释放量为39.21-152.04 g C m-2a-1,占全年呼吸总量的10-29%,说明冬季土壤碳释放量不能忽略。
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土壤是陆地生态系统最大的碳库,其碳储量是大气碳储量的两倍。土壤呼吸是土壤碳库的最大输出途径。在干旱半干旱区降雨格局以及土壤水分条件的变化对土壤呼吸的影响具有重要意义。本研究以半干旱区科尔沁沙地东部樟子松人工林为研究对象,通过室内培养模拟研究、野外降雨量控制研究和降雨频率模拟及干湿交替模拟试验,研究了科尔沁沙地半干旱人工林生态系统土壤呼吸对水分变化的响应趋势,探讨了降雨格局变化对土壤呼吸的影响,结果表明: (1)土壤呼吸速率随温度和土壤含水量的升高分别呈指数和线性增长;温度和土壤含水量分别影响着土壤呼吸对土壤水分和温度的敏感性; (2)降雨量变化影响土壤呼吸日动态变化,降水量增加30%,土壤24h释放CO2量升高了35.9%,当降水量减少30%时,土壤24h释放的CO2量降低了59.6%,而且干旱降低了土壤呼吸日动态变化的幅度; (3)降雨量变化对土壤呼吸月季动态具有一定影响。降雨量增加30%,8~10月土壤总呼吸CO2释放速率升高40.7%~166.4%,土壤异养呼吸CO2释放速率升高40.5%~194.3%;降雨量降低30%使降雨较频繁的8月份土壤总呼吸CO2释放速率降低34.0%~70.0%,土壤异养呼吸CO2释放速率下降20.9%~ 64.0%,而在降雨较少的9~10月份降雨量的减少对土壤呼吸则没有显著影响; (4)降雨量的变化对土壤总呼吸和异养呼吸温度敏感性有一定影响。当降雨量减少30%时,土壤总呼吸的Q10值由5.4下降到2.22,土壤异养呼吸的Q10值由4.84下降到1.81; (5)用温湿度耦合作用经验模型Rt = 0.307e0.0064(W·T)来描述三个降雨处理样地土壤呼吸速率与土壤温度及土壤含水量的关系,可以解释土壤呼吸速率变异的80.2%; (6)在较高的温度条件下,降雨频率增加一倍时,土壤呼吸速率将升高约24%;当温度较低时,降雨频率对土壤呼吸速率的影响不显著; (7)土壤呼吸随着干旱程度的增加而逐渐下降,但当进行降水模拟后,土壤呼吸值迅速升高,可升高降水前的41.0% ~ 128%,而后又迅速下降,呈现明显的脉动(pulse)效应。
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由于含油污水灌溉、原油储存运输和石油冶炼过程中导致的泄漏事故等原因,石油类物质已经成为环境中的主要污染物之一。石油烃污染物对土壤微生物遗传多样性和群落结构的影响在国外已有一些报道,但有关于石油烃污染对稻田土壤微生物生态系统的影响一直以来一直没有一个全面和系统的认识。本论文首次采用传统微生物培养方法、常规生化分析方法与PC树DGGE等现代分子生态学研究方法相结合的手段系统评价了长期石油污水灌溉对中国最大的石油类污水灌区-沈抚灌区的稻田土壤微生物种群数量、细菌群落组成、多样性及代谢活性的影响。结果表明,总石油烃(Total Petloleum hydrocarbon/TPH)在灌区干渠和支渠中的积累和分布趋势大体上是上游地区较严重,下游地区较轻,并且与土壤中有机质含量呈显著正相关。在目前的污染程度下,石油污水能够刺激土壤好氧异养细菌(Aerobic heterotrophic bacteria/AHB)和真菌的生长,其数量与TPH含量呈显著正相关。细菌基因多样性与TPH含量呈显著负相关,细菌群落中的优势菌群为变形细菌β-亚群和γ-亚群的菌种。土壤脱氢酶、过氧化氢酶、多酚氧化酶活性和土壤底物诱导呼吸(substrate-induced respirationSIR)与土壤中TPH含量呈显著正相关,而土壤脉酶活性则与之呈显著负相关。实验室110天不同浓度石油烃胁迫模拟试验结果表明,当石油烃胁迫浓度低于1000mgk扩时可以被定义为轻度污染,土壤中AHB大量增殖,细菌多样性和群落结构可在处理第30天和第50天得到恢复;当石油烃胁迫浓度为5000mg·kg~(-1)-10000mg·kg~(-1)时可以被定义为中度污染,AHB数量显著增加,放线菌和真菌数量显著降低,土壤细菌多样性在培养前巧天显著降低,至培养结束时有逐渐恢复的趋势,细菌群落结构发生明显改变,土壤脱氢酶、多酚氧化酶、脉酶的活性及土壤SIR受到一定程度的抑制,但能够显著刺激土壤过氧化氢酶活性的提高。当石油烃胁迫浓度为10000mg·kg~(-1)-50000mg·kg~(-1)时可以被定义为重度污染,对AHB生长的刺激作用更为显著,土壤细菌多样性在培养前15天显著降低并不可恢复,群落组成与对照差异很大,所有土壤酶和SIR均受到严重抑制。从沈抚灌区上游地区旱田土壤、灌渠底泥和实验室高浓度石油烃胁迫土壤中筛选出了4株TPH生物降解率在60%以上的高效石油烃降解菌并鉴定其归属,这些菌株均能够利用正构烷烃、单环和多环芳烃及环烷烃。
