大豆种子储藏性磷对幼苗适应低磷胁迫的作用

选用种子大小不同、磷效率不同的两个大豆品种‘巴西10号’(B10)和‘本地2号’(L2),在不同供磷条件下进行营养液浇灌沙培,从大豆萌发至2片三出复叶完全展开期测定植株主要器官总磷、可溶性磷浓度、子叶可溶性蛋白、酸性磷酸酶比活性、植酸酶比活性的变化动态,探讨储藏性磷在大豆幼苗期适应磷胁迫中的作用。结果发现:(1)磷效率不同的两个大豆品种的种子中磷含量差异显著。(2)大豆萌发和幼苗生长过程中子叶的磷逐渐转入根、茎、叶中,并以转入叶中的磷最多,其中磷高效品种B10在发芽过程中子叶磷向各个器官转移的总磷量要高于磷低效品种L2,且持续时间长。(3)大豆萌发和幼苗生长过程中外源供磷水平显著影响子叶磷的转移,在外源供磷充足条件下各器官中总磷均高于低供磷条件,子叶中磷和外源磷存在补偿关系。(4)磷高效品种B10子叶中酸性磷酸酶活性在低磷条件下显著高于高磷条件,但磷低效品种L2在高、低磷间无显著差异。研究表明,大豆种子储藏性磷在幼苗期耐低磷能力建立方面具有重要作用。     

磷胁迫下大豆酸性磷酸酶活性变化及磷效率基因型差异分析

在3种磷水平处理后,对23个大豆品种的叶片和根尖酸性磷酸酶活性、根冠比、干物质量、全磷含量及磷效率进行测定、比较和分析。结果表明,叶片或根尖酸性磷酸酶活性、叶片或根尖酸性磷酸酶活性相对值、根冠比,磷效率、磷效率相对值之间具有极显著差异(P相似文献   

磷胁迫诱导大豆叶片酸性磷酸酶同工酶的表达

通过田间试验对两种磷处理的274个大豆基因型叶片酸性磷酸酶活性进行筛选,并将其中8个进行营养液栽培试验以研究磷胁迫对其叶片酸性磷酸酶同工酶表达的影响.结果表明,大豆叶片酸性磷酸酶活性存在着明显的基因型差异,不施磷处理提高了大部分(约60%)供试基因型叶片酸性磷酸酶的活性.营养液栽培试验表明,低磷处理普遍提高了所有8个供试大豆基因型叶片酸性磷酸酶的活性.等电聚焦电泳结果表明,供试大豆基因型的老叶和新叶中均有6条酸性磷酸酶的同工酶带.低磷处理显著增加了叶片酸性磷酸酶酶带的活性,但是没有诱导新的酸性磷酸酶酶带产生.研究发现叶片酸性磷酸酶活性可作为反映大豆磷胁迫的酶学指标;磷胁迫诱导大豆叶片酸性磷酸酶活性的增加是由于已有同工酶活性的提高而不是由于特异性酶带的产生.     

磷胁迫诱导大豆叶片酸性磷酸酶同工酶的表达

通过田间试验对两种磷处理的274个大豆基因型叶片酸性磷酸酶活性进行筛选,行将其中8个进行营养液栽培试验以研究磷胁迫对其叶片酸性磷酸酶同工酶表达的影响。结果表明,大豆叶片酸性磷酸酶活性存在着明显的基因型差异,不施磷处理提高了大部分(约60％)供试基因型叶片酸性磷酸酶的活性。营养液栽培试验表明,低磷处理普遍提高了所有8个供试大豆基因型叶片酸性磷酸酶的活性。等电聚焦电泳结果表明,供试大豆基因型的老叶和新叶中均有6条酸性磷酸酶的同工酶带。低磷处理显著增加了叶片酸性磷酸酶酶带的活性,但是没有诱导新的酸性磷酸酶酶带产生。研究发现叶片酸性磷酸酶活性可作为反映大豆磷肋迫的酶学指标;磷胁迫诱导大豆叶片酸性磷酸酶活性的增加是由于已有同工酶活性的提高而不是由于特异性酶带的产生。     

基于SLAF-BSA技术挖掘大豆酸性磷酸酶候选基因及标记开发

磷利用效率与大豆产量密切相关,根尖酸性磷酸酶活性是筛选大豆品种磷效率的重要指标。挖掘酸性磷酸酶活性候选基因并开发其功能标记对获得磷高效功能基因、解析磷利用分子机制和培育磷高效大豆新品种意义重大。本研究利用酸性磷酸酶活性重组自交系群体F12构建了2个极端性状混池DNA文库,通过SLAF-BSA技术,获得了268个与大豆酸性磷酸酶活性关联的SNP,包括12个非同义突变,其中亲本间7个,后代混池间5个;在2个关联候选区域,获得79个酸性磷酸酶活性相关基因,其中第3号染色体的20138271～20268154间4个,17号染色体的14368648～15526449间75个;对该区域内基因进行了功能注释。开发了非同义突变基因Glyma.17G166200.1功能标记GMsnp-B,用该标记检测169份大豆栽培品种基因型,与表型符合率达到82.8%。     

大豆子叶内酸性磷酸酶活性的超微结构定位

开花后３５～５０ ｄ 期间和萌发早期（播种后４～８ ｄ）的大豆（Ｇｌｙｃｉｎｅｍ ａｘ Ｌ．）种子中,酸性磷酸酶主要分布在子叶细胞中的蛋白体内;在内质网内也检测到酸性磷酸酶活性。此外,在萌发早期的部分子叶细胞的质膜外侧及其细胞壁基质中可见密集的酸性磷酸酶活性;而且在近质膜的胞质中常见到一些富含磷酸铅沉淀的胞质小泡,似与质膜融合     

兴安落叶松幼苗对~（32）P的吸收与累积研究

利用３２Ｐ示踪法研究兴安落叶松幼苗在侧根形成前对磷的吸收利用及其在体内的转运。结果表明：兴安落叶松幼苗在侧根形成前能吸收利用外源磷。且由根到茎转运较快,由茎到叶吸收转运缓慢,各部位３２Ｐ累积量依次是根＞茎＞叶,３２Ｐ在根部的累积主要是无机磷形式,在茎、叶部主要是有机磷形式。该时期幼苗酸性磷酸酶活性较低,但地上部酶活性略高,地下部较低．     

低磷胁迫下甘蓝型油菜酸性磷酸酶对磷效率的贡献分析

为探讨低磷胁迫下甘蓝型油菜酸性磷酸酶活性的基因型差异及其与磷效率的关系, 采用土培实验研究了磷高效基因型102和磷低效基因型105对有机磷和无机磷的利用及其根际土壤酸性磷酸酶活性差异; 并采用水培实验研究了甘蓝型油菜根系分泌的酸性磷酸酶及不同叶片酸性磷酸酶的活性差异. 结果表明, 低磷胁迫能诱导根系及根系分泌的酸性磷酸酶活性升高; 土培条件下, 由于酸性磷酸酶的有效性受较多因素影响, 植物的磷营养和磷吸收效率与根系分泌的酸性磷酸酶活性并不直接相关; 缺磷胁迫下重组自交系群体叶片酸性磷酸酶活性与磷利用效率呈显著正相关, 进一步表明低磷诱导的植株叶片酸性磷酸酶活性升高能促进体内磷的再利用, 从而提高磷利用效率.     

模拟增温对中亚热带杉木人工林土壤磷有效性的影响

气候变暖改变与土壤磷循环相关的生物地球化学过程,对陆地生态系统磷循环产生直接或间接影响。为研究亚热带地区杉木人工林土壤磷有效性对增温的响应,开展了模拟增温实验。实验设置对照组及增温组(5℃),经过1.5a的短期增温,对杉木人工林的土壤全磷、有机磷、微生物量磷、有效磷、酸性磷酸酶活性及相关土壤理化性质进行测定,结果表明:增温处理下,土壤酸性磷酸酶活性提高约1.5倍,土壤全磷、微生物量磷以及有机磷含量分别减少了6%、34%和12%,土壤有效磷含量增加25%。可见,短期增温通过提高土壤磷酸酶活性进而促进土壤有机磷矿化和降低土壤微生物固磷量,从而增加土壤磷有效性,但是增温导致潜在可利用的土壤微生物量磷大幅度的降低,将有可能加剧亚热带杉木人工林土壤磷限制。     

不同磷水平配施生物炭对土壤磷有效性

生物炭在提高土壤磷素有效性及促进作物生长方面具有显著作用,但其效果因土壤类型不同存在较大差异。试验以赤红壤(pH 4.91)和褐土(pH 7.24)为供试土壤,设置3种磷肥水平(0、30、90 kg P·hm^-2,分别以不施磷、低磷、高磷表示)配施稻秆生物炭(0、4%)的大豆盆栽试验,研究了不同磷水平下配施生物炭对土壤磷有效性、磷酸单酯酶活性和植株磷吸收的影响。结果表明: 不同磷水平配施生物炭显著提高了两种土壤的速效磷和全磷含量,且低磷水平添加生物炭处理速效磷增幅最大,在赤红壤和褐土的增幅分别为192.6%和237.1%。与低磷相比,赤红壤中低磷配施生物炭处理的碱性磷酸单酯酶活性显著增加78.9%,活性有机磷含量降低39.3%,同时显著促进了植株生长与磷吸收;生物炭添加显著降低了褐土活性有机磷含量,但不同处理对土壤磷酸单酯酶活性和植株生长无显著影响。土壤活性有机磷含量与速效磷含量均呈显著负相关。综上,生物炭对土壤磷有效性的作用因土壤类型和磷肥水平差异而不同,其在赤红壤上对植株生长和磷吸收的促进效应强于褐土,且在低磷条件下效果更佳。本研究为生物炭在减施磷肥和促进大豆磷吸收,特别是在赤红壤上的应用提供了科学依据。     

Differential responses of rice acid phosphatase activities and isoforms to phosphorus deprivation

Acid phosphatases (APases) play a role in the release of phosphate in organic complexes in soil. We investigated tissue- and isoform-specific responses of APases to phosphorus (P) deficiency in three rice genotypes; Dasan-byeo, Sobi-byeo, and Palawan. The levels of shoot APase activity per protein were similar in the three genotypes. They significantly decreased with P deprivation that was longer than seven days. Root APase activity per protein was two- to three-fold higher in Dasan than in Sobi and Palawan. In all genotypes the APase activity increased in P-deficient plants, but the increase was higher in Sobi and Palawan. After 21 days of P deprivation, secreted APase activity increased more than eight-fold in Dasan and two-fold in Sobi and Palawan. Isoform profiles of shoot and root APases were most diverse in Dasan. The activities of the major isoforms in P-deficient shoots decreased in all three genotypes. Depending on the genotypes, further increases in constitutive isoforms and new induction of one to four isoforms occurred in P-deficient roots. The results indicate that tissue and genotype differences in the response of APase to P deficiency are primarily facilitated by the different responses of the isoforms.     

Differential responses of oat cultivars to phosphate deprivation: plant growth and acid phosphatase activities

The effect of phosphate starvation on growth and acid phosphatases (APases) localization and activity in oat tissues was investigated. Oat cultivars (Avena sativa L.??Arab, Polar, Szakal) were grown for 1?C3?weeks in complete nutrient medium (+P) and without phosphate (?P). Pi concentration in plant tissues decreased strongly after culturing on ?P medium. Pi deficit reduced shoot growth, stimulated root elongation and increased ratio of root/shoot in all oat cultivars. Pi deficit had a greater impact on growth of oat cv. Polar than other varieties. A decrease in the internal Pi status led to an increase of acid phosphatase activities in extracts from shoots and roots, and in root exudates. The highest activity of secreted APases was observed for oat cv. Arab, during the third week of growth under Pi-deficient conditions. The activity of extracellular APase was high in young, growing zones of roots of ?P plants. Histochemical visualization indicated high activity of APases in the epidermis and vascular tissues of ?P plants. Pi deficiency increased intracellular APase activity in shoot mainly in oat cv. Polar, whereas APase activity in roots was the highest in oat cv. Szakal. Protein extracts from roots and shoots were run on native discontinuous PAGE to determine which isoform(s) may be affected by Pi deficiency. Three major APase isoforms were detected in all oat plants; one was strongly induced by Pi deficit. The studied oat cultivars differed in terms of acclimation to deficiency of phosphate??used various pools of APases to acquire Pi from external or internal sources.     

模拟氮沉降对低磷胁迫下马尾松生长和磷效率的影响

近年来大气N沉降日趋严重,导致森林土壤有效N含量增加,N/P发生改变,将会影响低P胁迫下林木的生长发育和P效率.本文以马尾松家系为研究对象,设置模拟N沉降与同质低P(介质表层与深层均缺P)、异质低P(介质表层P丰富、深层缺P)耦合的盆栽试验,研究N沉降对马尾松生长性状以及P吸收和利用效率的影响.结果表明： 同质低P下,模拟N沉降对马尾松生长性状和P效率影响较小,但存在显著的N×家系互作效应,家系40×44和71×20在N沉降后生物量增加,家系36×29和73×23生物量降低;异质低P下,模拟N沉降显著增加了马尾松苗高、生物量以及P吸收效率等,其原因是促进了根系生长和表层土壤中根系分布比例的增加.不同P环境下模拟N沉降对马尾松生长的影响,还与植株N/P有关.同质低P环境下,马尾松植株N/P为13.8,植株对N敏感性低,酸性磷酸酶活性增加,但未改善马尾松生长状况.在异质低P环境中,植株N/P为9.7,模拟N沉降显著增加了苗木生物量和P吸收效率,但未显著改变酸性磷酸酶活性.     

不同磷效率小麦品种的磷吸收特性

在丰磷、缺磷条件下,对不同磷效率小麦品种的磷吸收特性进行研究。缺磷条件下,不同磷效率品种成熟期的植株全磷量和生育中后期（挑旗-成熟期）植株磷累积量均以磷高效品种最高,中效品种次之,低效品种最低。不同磷效率品种拔节期、挑旗期和成熟期的磷利用效率差异较小。表明磷高效小麦品种在缺磷条件下子粒产量形成能力的提高。与生育中后期植株具有相对较强的磷素吸收能力有关。缺磷条件下,不同磷效率品种在生育中后期的根系TTC还原力和可溶蛋白含量也以高效品种最高,中效次之,低效最低。表明磷高效小麦品种植株生育中后期根系具有较强的生理功能,是其在缺磷务件下吸磷量增加、产量相对明显提高的重要生理基础。研究表明,不同磷效率小麦品种在磷胁迫条件下的根系酸性磷酸化酶（APase）活性存在显著差异,并在小麦磷吸收效率的调控中具有重要作用。     

Analysis of the contribution of acid phosphatase to P efficiency in Brassica napus under low phosphorus conditions

To understand whether genotypic variation in acid phosphatase (APase) activity in rapeseed (Brassica napus L.) induced by phosphorus (P) deficiency has impact on P efficiency,soil APase activity in the rhizosphere for rapeseed P-efficient genotype 102 and P-inefficient genotype 105 was measured against organic and inorganic P sources in the pot experiment,and the activities of root-secreted APase and leaf intracellular APase were investigated in different P-starvation periods in the nutrient solution.Higher activity of root-secreted APase in B.napus was induced under low P conditions.However,P nutrition and P uptake efficiency of the plants supplied with organic P were not directly related to the activity of root-secreted APase due to several confounding factors affecting APase availability.The higher activity of leaf APase improved P remobilization in plants and played important roles in enhancing P use efficiency,shown by the significant correlation between leaf APase activity and P use efficiency in a rapeseed recombinant inbred population of 135 lines.     

Analysis of the contribution of acid phosphatase to P efficiency in <Emphasis Type="Italic">Brassica napus</Emphasis> under low phosphorus conditions

To understand whether genotypic variation in acid phosphatase (APase) activity in rapeseed (Brassica napus L.) induced by phosphorus (P) deficiency has impact on P efficiency, soil APase activity in the rhizosphere for rapeseed P-efficient genotype 102 and P-inefficient genotype 105 was measured against organic and inorganic P sources in the pot experiment, and the activities of root-secreted APase and leaf intracellular APase were investigated in different P-starvation periods in the nutrient solution. Higher activity of root-secreted APase in B. napus was induced under low P conditions. However, P nutrition and P uptake efficiency of the plants supplied with organic P were not directly related to the activity of root-secreted APase due to several confounding factors affecting APase availability. The higher activity of leaf APase improved P remobilization in plants and played important roles in enhancing P use efficiency, shown by the significant correlation between leaf APase activity and P use efficiency in a rapeseed recombinant inbred population of 135 lines.