丛枝菌根对三叶草根际磷酸酶活性的影响

以三叶草为材料,利用三室隔网培养方法,探讨了取自肥料长期定位试验中多年施用与不施用有机肥的田间小区土壤上,接种菌根菌（G.mosseae）对根际土壤酸性和碱性磷酸酶活性的影响。植物生长9周后,收获测定菌丝生长室土壤酸性磷酸酶和碱性磷酸酶活性,并对磷酸酶产生位点进行细胞化学定位。结果表明,接种丛技菌根菌对根际土壤酸性和碱性磷酸酶活性均有增强作用,但作用程度在有机服小区土壤上要大于无机肥小区土壤。根际土壤酸性磷酸酶原位化学定位结果表明,菌丝周围有明显的酸性磷酸酶的反应产物,说明报外丛枝菌根菌丝能直接向外分泌磷酸酶。     

磷营养水平对不同基因型甜菜根磷酸酶活性的效应

采用无菌条件下的液体培养法,研究了磷素营养水平对甜菜根磷酸酶活性的效应。结果表明,营养液中的供磷水平对甜菜磷酸酶的影响程度因其从根内到根生长介质空间的分布位置、品种和磷酸酶的种类而异。磷对内源酸性和中性磷酸酶的影响明显,各品种的不同磷水平间的酶活性差异均达到了5%以上显著水平;对碱性磷酸酶的作用效果较差,只有V6和V12达到了5%以上显著水平。磷营养水平对不同基因型甜菜根外泌的中性磷酸酶的作用较强,除了V6外,其他3个品种的供磷水平的效应均达到了显著或极显著水平;对酸性和碱性磷酸酶的影响效果稍差,两者均有2个品种对供磷水平高低没有明显反应。从磷酸酶的分布空间上看,根表酸性磷酸酶对磷营养水平的反应最敏感,并且各品种均表现出一致的趋势,即在低磷条件下,各品种甜菜的根表酸性磷酸酶均能得到显著或极显著地增加。磷对甜菜内源和根外泌到营养液中3种磷酸酶之间相关性的影响,依次为碱性磷酸酶>中性磷酸酶>酸性磷酸酶,表现出较强的规律性。     

石灰性土壤小麦根际pH及磷动态变化的研究

本文采用网隔栽培室种植小麦,置于人工气候室内生长,对不同温度条件下土小麦根际及距根不同距离土体中ｐＨ,Ｏｌｓｅｎ-Ｐ及无机磷组分动态变化进行了研究。主要结果有:（１）根际及０～３ｍｍ土体ｐＨ较低,而３～８ｍｍ和８～５０ｍｍ土体ｐＨ较高;（２）Ｏｌｓｅｎ-Ｐ含量为根际＜０～３ｍｍ土体＜３～８ｍｍ和８～５０ｍｍ土体,温度升高,各土层Ｏｌｓｅｎ-Ｐ含量呈降低趋势;（３）距小麦根系越近,Ca2-P、Ａｌ Ｐ、Ｆｅ-Ｐ和Ca8-P含量越低,Ｏ-Ｐ和Ca10-P变化不明显;随时间延长和温度升高,Ca10-P含量有所增加,Ca2-P、Ａｌ-Ｐ、Ｆｅ-Ｐ和Ca8-P含量有所降低,Ｏ-Ｐ含量变化不大     

缺磷对不同耐低磷玉米基因型酸性磷酸酶活性的影响

【目的】酸性磷酸酶活性与土壤及植株体内有机磷的分解和再利用有着密切的关系。本研究以不同耐低磷玉米自交系为材料,研究低磷胁迫下玉米叶片、根组织内以及根系分泌酸性磷酸酶活性的变化及基因型差异,探讨酸性磷酸酶与玉米耐低磷之间的关系,以期更深入地了解玉米耐低磷的生理机制。【方法】以5个典型耐低磷自交系99180T、99239T、99186T、99327T、99184T和2个磷敏感自交系99152S、99270S为试验材料,采用营养液培养方法,设正常磷和低磷两种处理,分别于缺磷处理3、8和12 d时调查取样,测定地上部干重、根干重、叶片中无机磷(Pi)含量、根和地上部磷累积量、根系分泌APase活性以及叶片中APase活性,并于缺磷处理12 d测定根系内APase活性。【结果】1)缺磷使玉米地上部干重下降,根干重、根冠比增加,随着缺磷处理(3 d→8 d→12 d)时间的延长,根干重、根冠比增加幅度增大,且耐低磷自交系根干重增加幅度普遍大于敏感自交系。2)低磷条件下,玉米自交系磷吸收、利用效率存在基因型差异,耐低磷自交系99239T、99180T和99327T磷吸收效率较高,99186T和99184T磷利用效率高,敏感自交系99152S、99270S磷吸收和利用效率均较低。3)低磷处理使玉米自交系叶片无机磷(Pi)含量显著下降,耐低磷自交系99184T、99327T和99239T下降幅度较小,相对叶片无机磷含量较高。4)缺磷诱导玉米根系分泌的APase活性升高。耐低磷自交系99184T和99186T根系分泌APase活性升高幅度较大,其余3个耐低磷自交系未表现出明显优势。缺磷处理3 d、8 d,玉米根系分泌APase活性与磷累积量显著正相关,而12 d时相关性不显著;根系分泌APase活性与磷利用效率在缺磷处理12d时达显著正相关。说明玉米根系分泌APase活性与磷吸收、利用效率相关关系不稳定。5)缺磷处理12 d,各玉米自交系根组织内APase活性与根系分泌APase活性变化情况较一致,两者相关系数r=0.755(P0.05)。6)缺磷条件下各玉米自交系叶片组织内APase活性均有升高趋势,并表现出明显的基因型差异。缺磷处理8 d,耐低磷自交系99184T和99239T叶片组织内APase活性升高幅度最大,其次是99327T和99186T,99180T、99270S和99152S升高幅度较小;缺磷处理12 d,各玉米自交系叶片APase活性仍继续增加,99239T、99184T、99327T和99186T的相对APase活性均较高,99270S和99152S的相对APase活性较低。相关性分析表明,缺磷条件下玉米自交系叶片中相对APase活性与叶片中相对无机磷(Pi)含量显著正相关,与磷吸收、利用效率不显著相关。【结论】低磷诱导玉米叶片、根组织和根系分泌APase活性升高,根组织和根系分泌APase活性的大小与玉米耐低磷能力不完全相关,叶片APase活性与玉米耐低磷能力有较好的一致性。     

石灰性土壤上两种磷效率小麦根际特征差异

采用三室根箱实验,选用黑垆土和潮土两种石灰性土壤,对两种磷水平的磷低效型小麦京411和磷高效型小麦小偃54,进行植株生物量及吸磷量、根际土壤pH值、磷酸酶含量、水溶性磷含量的测定,旨在研究两种磷效率小麦在不同石灰性土壤上的根际特征差异.结果表明,不施磷条件下,两种土壤上,小偃54的根部生物量分别为0.85和4.62 g,均显著高于京411的0.68和3.65 g;小偃54根际土壤的pH值分别比京411低0.07,0.11个单位;在施磷条件下,小偃54的根际土壤水溶性磷分别低于京411 837,1588 μg/kg,达到显著性差异.根际磷酸酶在不同土壤上存在明显的差异,黑垆土在不施磷条件下小偃54的根际土壤磷酸酶含量显著高于京411,在潮土上呈现相反的趋势.试验结果表明,两种磷效率,小麦根际特征在不同土壤上有一定的相似性,同时存在明显差异.     

施氮对小麦根-土界面磷迁移及根际磷素组分变化特征的影响

植物根系养分吸收性能与土壤养分、水分、pH值和温度等环境条件有着密切的关系,同时又影响着近根微区(根际)土壤中养分的迁移和有效性.土壤中磷素在土壤中的迁移和吸收直接与土壤性质有关.     

两个小麦品种对根际土壤中磷的吸收

Inorganic soil phosphorus extractable with sodium bicarbonate(NaHCO3-Pi),soil pH and root hairs length and density in the rhizosphere of two winter wheat cultivars (Tritium aestivum L.cv.Shichum,Sleipner)grown on a high pH Chinese silt loam(52.7 mg NaHCO3-Pikg^-1) and a Danish sandy loam(43.4mg NaHCO3-Pi kg^-1)wer studied to assess how these wheat cultivars differed in phosphorus uptake.The rhizosphere soil pH of two wheat cultivars grown on the two soils were fairly unchanged with increasing distrance from the roo surface.However the root hairs of Shichun were 2.1 times longer than those of Sleipner,Root surface area(RSA) of Shichun increased by 192% due to root hairs whereas root hairs of Sleipner increased RSA by 68% only.Hence the root system of Shichun was in contact with more soil than that of Sleipner,even though Sleipner had a longer root,Grown at the lower pH and level of NaHCO3-Pi in the Danish soil Shichun absorbed more inorganic phosphorus than Sleipner whereas at the higher pH and level of NaHCO3-Pi in the Chinese soil there was no phosphorus uptake difference between the two wheat culivars.     

适宜施氮量对粗齿冷水花根际微域土壤磷组分及磷酸酶活性的影响

  【目的】  适宜施氮可提高磷富集植物对磷过剩土壤的修复效率,研究适宜施氮处理下磷富集植物根际微域土壤磷组分的变化,可为利用磷富集植物提取土壤中过剩的磷提供理论依据。  【方法】  采用多隔层根箱土培试验,以磷富集植物矿山生态型粗齿冷水花为材料,非矿山生态型为对照,设磷处理的P质量浓度为800 mg/kg,氮处理的N质量浓度为0 (CK)和140 mg/kg,分析对比了两种生态型粗齿冷水花磷富集能力及根际微域土壤磷组分与磷酸酶活性的变化。  【结果】  1)适宜施氮量下,两种生态型粗齿冷水花地上部、地下部生物量和磷积累量均显著升高;矿山生态型地上部生物量和磷积累量分别为非矿山生态型的1.28和1.45倍。2)适宜施氮量下,两种生态型根际土壤中H₂O-P和NaHCO₃-Pi含量均增加;土壤H₂O-P和NaHCO₃-Pi含量均在距矿山生态型根际4 mm微域内显著高于非根际土壤,分别在距非矿山生态型根际4和2 mm微域内显著高于非根际土壤;土壤NaHCO₃-Po和NaOH-Pi、NaOH-Po含量在距两种生态型根际6 mm微域内显著低于非根际土壤;土壤HCl-Pi和HCl-Po和Residual-P含量在根际微域和非根际土壤之间无显著变化。不施氮和适宜施氮量下矿山生态型根际微域NaHCO₃-Pi含量均显著低于非矿山生态型,矿山生态型对土壤NaHCO₃-Pi的吸收利用能力更强。3)适宜施氮量下,两种生态型粗齿冷水花根际土壤磷酸酶活性均较对照增加,土壤酸性磷酸酶、碱性磷酸酶活性分别在距根际4和2 mm微域内显著高于非根际土壤,植酸酶活性在距根际8 mm微域内显著高于非根际土壤。不施氮和适宜施氮量下,矿山生态型根际微域土壤磷酸酶活性更高。  【结论】  高磷条件下,适宜施氮量 (140 mg/kg)增加了两种生态型粗齿冷水花根际微域土壤磷酸酶活性,且矿山生态型根际土壤磷酸酶活性更高,有利于根际微域土壤中磷由低有效态组分向高有效态组分转化,从而促进了植株的生长和磷素积累。     

两个品种玉米根际土壤微生物和酶活性对水分胁迫的响应

利用双因素随机试验研究在玉米3个生育期(大喇叭口期、灌浆期和成熟期)水分胁迫对2个品种玉米根际土中微生物的丰度、多样性、群落结构及酶活性(蔗糖酶、脲酶、碱性磷酸酶和脱氢酶)的影响。试验设4个处理,即在水分胁迫和正常供水下分别种植2个玉米品种(“郑单958”和“农华101”)。结果表明:水分胁迫显著抑制了3个生育期根际土中革兰氏阴性细菌和丛枝菌根真菌的丰度以及成熟期的普通细菌和革兰氏阳性细菌丰度,并提高了微生物的均匀度,使群落结构发生明显改变。水分胁迫显著降低了灌浆期根际土中脱氢酶活性、成熟期的碱性磷酸酶和脱氢酶活性;显著提高了成熟期的蔗糖酶活性。灌浆期,“农华101”比“郑单958”根际土中丛枝菌根真菌丰度和脱氢酶活性高,但其微生物多样性和均匀度却较低。水分与品种的交互作用仅对灌浆期根际土中放线菌丰度、灌浆期和成熟期的丛枝菌根真菌丰度和3个生育期的微生物群落结构有显著影响。     

苗期不同化感潜力水稻根际土壤酶活性分析

为揭示化感水稻根际土壤酶活性与水稻化感潜力的关系,在前期研究的基础上,以化感水稻“P1312777”、“IAC47”、“Iguape”和非化感水稻“Lemont”为材料,测定了苗期旱作水稻根际土壤酶活性。结果表明,化感水稻抑制了根际土壤的脱氢酶、过氧化物酶、多酚氧化酶、脲酶活性、纤维素分解酶活性,提高了酸性磷酸酶、、碱性磷酸酶、蔗糖酶、过氧化氢酶活性。脲酶、多酚氧化酶活性与水稻化感潜力呈显著负相关,酸性磷酸酶、碱性磷酸酶与水稻化感潜力呈显著正相关,蛋白酶、脱氢酶活性与其他土壤酶、土壤微生物区系、水稻化感潜力间均无显著相关性。化感水稻降低根际土壤多酚氧化酶活性,有利于根际化感物质的积累,提高了酸性磷酸酶、碱性磷酸酶、蔗糖酶活性,促进土壤磷、碳循环,为实现水稻化感效应奠定基础。     

Changes in phosphorus fractions in three tropical soils amended with corn cob and rice husk biochars

ABSTRACT

The formation of phosphorus (P) compounds including iron-P, aluminum-P and calcium-P in highly weathered tropical soils can be altered upon biochar addition. We investigated the effect of corn cob biochar (CC) and rice husk biochar (RH) pyrolyzed at three temperatures (300°C, 450°C and 650°C) on phosphorus (P) fractions of three contrasting soils. A 90d incubation study was conducted by mixing biochar with soil at a rate of 1% w/w and at 70% field capacity. Sequential P fraction was performed on biochar, soil and soil-biochar mixtures. Increase in most labile P (resin-P_i, NaHCO₃-P_i) and organic P fraction (NaHCO₃-P_o + NaOH-P_o) in CC and RH biochars were inversely related to increasing temperature. HCl-P_i and residual P increased with increasing temperature. Interaction of CC and RH with soils resulted in an increase in most labile P as well as moderately labile P (NaOH-P_i) fractions in the soils. CC increased most labile P in the soils more than RH. The increase in most labile P fraction in soils was more significant at relatively lower temperatures (300°C and 450°C) than 650°C. However, the increase in HCl-P_i and residual P of the soils was more predominant at high temperature (650°C). The study suggested that biochar pyrolyzed at 300–450°C could be used to increase P bioavailability in tropical soils.     

Changes in phosphorus fractions in the rhizosphere of some crop species under glasshouse conditions

The aim of the present study was to evaluate the effect of cultivation of some agronomic plant species on inorganic soil‐P fractions in different sampling zones. The experiment was conducted as a completely randomized design as factorial in three replicates. The factors were plant species (10 different species and control) and soil‐sampling zone (soil adhering to root mat, rhizosphere soil, and nonrhizospheric soil). The thin‐slicing technique was modified and used to sample rhizosphere soil. The percentages of P fractions in the planted and control soils were near 64% apatite (apatite‐P), 24% octa‐Ca‐phosphates (OCP‐P), 7% Fe‐phosphates (Fe‐P), 4% di‐Ca‐phosphates (DCP‐P), 1% Al‐phosphates (Al‐P), and 0% occluded‐P (O‐P). All of the studied plant species decreased significantly all of the inorganic P fractions in soil adhering to root mat and in rhizosphere soil compared to those in nonrhizosphere soil. However, these decreases were not equal for each fraction and the percentage of apatite‐P increased in rhizosphere soil of the plant species. The means of total P, soluble P, DCP‐P, OCP‐P, Al‐P, and Fe‐P were lower in soil adhering to root mat compared to those in rhizosphere soil. However, this difference was only significant for OCP‐P. In contrast, the mean of apatite‐P in soil adhering to root mat was significantly higher than that in rhizosphere soil. The changes of apatite‐P may be more governed by microbial activities (especially mycorrhizal symbiosis) which may be higher in rhizosphere soil compared to soil adhering to root mat.     

黑垆土和红壤上两种磷效率小麦根际特征差异

以磷高效型小麦洛夫林和磷低效型小麦中国春为试材设计三室根箱试验,通过测定两品种小麦生物量、吸磷量、pH值和酸性磷酸酶活性,对比它们在两种磷水平(P 0 mg/kg、P 100 mg/kg)及两种土壤(石灰性黑垆土、酸性红壤)上的根际特征差异。结果表明,黑垆土上增施磷肥,洛夫林和中国春的总生物量分别增加了30.14%和17.75%,总吸磷量分别增加了139.24%和71.72%;红壤上增施磷肥,两小麦总生物量并没有显著增加。根际pH方面,黑垆土上,不施磷条件下,洛夫林和中国春的根际pH值分别降低0.30和0.12个单位,但在红壤上两小麦根际pH值变化不大。酸性磷酸酶方面,PO条件下,黑垆土上两小麦根际酸性磷酸酶活性差异不显著,但红壤上洛夫林酸性磷酸酶活性显著高于中国春。P100条件下,黑垆土上洛夫林酸性磷酸酶活性显著高于中国春,而红壤上两小麦酸性磷酸酶活性差异不大。试验结果表明,在黑垆土和红壤上,两种磷效率小麦根际特征存在差异。     

磷肥减施对玉米根系生长及根际土壤磷组分的影响

【目的】 我国农业过量和不合理施用磷肥现象普遍存在,导致磷资源的浪费,对环境也造成潜在威胁。研究减少磷肥用量对玉米产量、根系形态及根际中磷转化特征的影响,为集约化农业生产体系中磷肥合理施用提供技术基础。 【方法】 在河北省衡水小麦玉米轮作体系下连续三年进行了田间试验,在冬小麦季设置4个P₂O₅用量处理:0、112.5、150.0、187.5 kg/hm2,收获后在原处理小区免耕播种夏玉米。利用WinRHIZO根系分析系统分析获取根长、直径等数据,测定玉米籽粒产量、生物量和地上部磷含量及根际土壤中磷形态等指标。 【结果】 与农民习惯磷肥用量(P₂O₅187.5 kg/hm2)相比,3年磷肥用量减施20%~40%处理(P₂O₅150和112.5 kg/hm2),玉米籽粒产量、根系长度与直径和土壤有效磷含量尚未发生明显变化。但3年不施磷处理,根际土壤有效形态磷含量和玉米籽粒产量开始出现下降趋势。2009年和2010年玉米收获期,不施磷肥处理根际土壤有机磷含量低于非根际土壤。2008年玉米苗期和收获期土壤有机磷分组中,中等活性有机磷含量最高;磷肥减施20%~40%处理苗期根际中中等活性有机磷含量显著低于非根际土壤。土壤无机磷形态分组研究发现:从玉米苗期到收获期,各磷肥处理根际和非根际土壤中Ca₂-P下降明显;而不同磷肥处理间土壤中Ca₁₀-P、Ca₈-P、O-P (闭蓄态磷)、Al-P和Fe-P含量差异不显著。减施磷肥处理2008年玉米苗期根际土壤微生物量P含量较非根际土壤高;与习惯施肥量相比,磷肥减施未明显降低根际土壤微生物量磷。 【结论】 在华北小麦玉米轮作种植体系下,在土壤肥力水平较高地区,连续3年将小麦季磷肥的习惯用量减少20%~40%,对夏玉米产量、根系形态以及根际土壤无机磷、有机磷、微生物量磷含量影响尚不明显,因此,该地区磷肥施用量可从习惯用量的P₂O₅180 kg/hm2减至112.5 kg/hm2。     

小麦蚕豆间作对红壤有效磷的影响及其与根际pH值的关系

在云南红壤上采用田间小区试验,通过测定分蘖～拔节期、孕穗～抽穗期、灌浆～乳熟期不同土层深度小麦根际土壤有效磷(available phosphorus)含量和根际pH值,比较研究了小麦蚕豆间作对小麦根际土壤有效磷含量和pH值的影响,探讨了间作小麦根际pH与根际土壤有效磷之间的相互作用.结果表明,与小麦单作相比,小麦蚕豆间作显著地促进了小麦产量的提高.同时,小麦蚕豆间作促进了小麦根际土壤有效磷含量的提高,分蘖～拔节期、孕穗～抽穗期0-10 cm、10-20 cm土层单、间作差异显著;间作显著降低了分蘖～拔节期10-20 cm土层、孕穗～抽穗期0-10 cm、10-20 cm、20-30 cm土层小麦根际土壤pH.分蘖～拔节期、灌浆～乳熟期,单、间作小麦根际土壤有效磷含量与根际pH呈负相关关系.试验表明,在红壤上间作小麦根际土壤有效磷含量的提高与间作降低根际pH有密切关系.     

Temporal variations in phosphorus fractions and phosphatase activities in rhizosphere and bulk soil during the development of Larix olgensis plantations

Many studies have well reported nutrient deficiency and soil degradation focusing on soil N in pure plantations. However, few papers focused on soil P deficiency during pure plantation afforestation. We examined the variations in P fractions and phosphatase (P‐ase) activities in the rhizosphere and bulk soils in Larix olgensis plantations of 16, 23, 34, and 49 y. Correlation analysis was applied to identify the relationships between available P and other P fractions and P‐ase activities in the rhizosphere soil at different developmental stages. The stepwise regression models were established to explore their relationships with tree growth. The results showed that the deficiency of available P occurred in the rhizosphere micro‐region relative to the bulk soil in the 34‐ and 49‐y‐old stands, which was related to the lower acid phosphatase activity, the deficient Fe‐bound P, and occluded phosphate, as well as to soil pH in the rhizosphere soil during these periods. In addition, tree growth in the young and near‐mature stands was significantly correlated with soil P fractions, and the main P fractions closely related to tree growth were total P, organic P, available P and inorganic P, followed by Ca‐bound P and Fe‐bound P. The decreases in average DBH and average height growth in the near‐mature stand were related to the deficiency of available P in this period. Our results indicate that the development of Larix olgensis plantations affects the bioavailability of P through dynamic changes of P fractions and P‐ase activities, which provides a theoretical base in future afforestation with Larix olgensis plantations.     

不同磷效率油菜根际土壤磷活化机理研究

筛选和培育耐低磷植物是缓解磷矿资源缺乏和提高磷肥利用效率的有效途径之一。本研究在前期材料筛选的基础上,通过根箱试验研究不同磷效率油菜根际土壤磷活化机理,其结果如下:在施磷和不施磷处理条件下,磷高效油菜品种B56（HG）的吸磷量和生物量均高于磷低效品种B10（LG）;两油菜品种根际土壤中的NaHCO3-Pi, NaHCO3-Po和 NaOH-Pi,NaOH-Po四种磷素形态均有显著的亏缺现象;磷高效品种（HG）根际土壤上述四种磷素形态亏缺程度大于磷低效品种（LG）,但Resin-P则出现富集,并且HG的富集程度大于LG,这可能与HG具有较高吸磷能力有关。两油菜品种根际土壤HCl-Pi 和 残渣态磷（Residual-P）没有发生明显的亏缺现象。相比较而言,HG能分泌更多的酸性磷酸酶,该酶活性与NaHCO3-Po含量呈显著的负相关,说明酸性磷酸酶对有机磷矿化起着非常重要的作用。     

Organ-specific allocation pattern of acquired phosphorus and dry matter in two rice genotypes with contrasting tolerance to phosphorus deficiency

ABSTRACT

Our earlier study demonstrated that the landrace of Japonica rice, Akamai exhibits low-P (phosphorous) tolerance mechanisms compared to the conventional type cultivar, Koshihikari. The present study examined the genotypic difference of yield, plasticity of root growth, and internal utilization of acquired P (allocation pattern of biomass and P among different vegetative and reproductive organs) of two contrasting cultivars in response to P-deficiency. Each cultivar was grown until maturity with (+P) and without (–P) P supply in pots (two plants per pot) filled with 15 kg of Regosol soil. Grain yield and yield components were determined along with biomass and P accumulation in different vegetative and reproductive organs. To assess the plasticity of root growth, the soil column in the pot was divided into two equal portions (upper and lower soil layers) in which the root dry weight and length were measured separately. Among the investigated yield components, the number of filled grains per panicle was the key parameter determining genotypic differences of grain yield of two cultivars. P-deficiency had a marked influence on grain filling of Koshihikari where the filled grain percentage under –P condition was reduced by 29% compared to that under +P condition. However, the respective reduction for Akamai was only 11%. Low-P tolerance ability of Akamai imparts a yield advantage over Koshihikari under P-deficient conditions because of the production of the higher number of filled grains per panicle. Akamai explored both upper and lower soil layers of the pot more efficiently in search of P through greater root biomass and length. Akamai grown under P-deficient conditions had remarkably lower P concentrations in less active vegetative tissues (partly and fully senesced leaves) than those of Koshihikari; whereas, more active organs (green leaves and panicles) contained a greater amount of P. Akamai’s higher plasticity to external P availability can be a genetic resource for developing low-P tolerant, high-yielding rice genotypes suitable for predicted future P-limited environments.     

根际pH对玉米利用磷酸单酯和双酯盐的影响

【目的】土壤有机磷在土壤全磷中占有很大比重,是植物潜在的有效磷源,但必须通过磷酸酶的水解作用释放出无机磷才能被植物利用。土壤中有机磷的主要形式为磷酸单酯和磷酸双酯。本研究中,我们探讨了无菌条件下不同形态的氮源引起的根际pH变化如何影响植物对这两种有机磷的活化利用。【方法】采用琼脂无菌培养体系种植玉米,向玉米植株供应两种形态的氮源和磷源, 氮源为硝态氮和铵态氮,磷源为植酸钙和卵磷脂,植酸钙属于磷酸单酯盐,卵磷脂属于磷酸双酯盐。不同的供氮形态会导致根际pH变化,进而研究根际pH变化对磷酸单酯盐和磷酸双酯盐的活化利用所产生的影响。【结果】当给玉米供应铵态氮时,根际pH从5.5降至4.0; 供应硝态氮时,根际pH升至6.6。测定玉米根际的琼脂中根系分泌的磷酸单酯酶和磷酸双酯酶活性发现,磷酸单酯酶活性在pH 6.0~7.0之间最高,磷酸双酯酶活性在pH 7.0~8.0之间达到最高。无论以植酸钙还是卵磷脂为有机磷源,相对于铵态氮处理,硝态氮处理能够使根际保持较高的磷酸单酯酶或磷酸双酯酶活性。有机磷的水解过程由磷酸酶活性和底物有效性两个因素控制,而植酸钙的水解受根际pH影响很大,在一定pH范围内,植酸钙的溶解度随根际pH值降低而升高,有效态磷浓度的增加,使得磷酸酶的底物有效性提高。在供应铵态氮时,根际pH值降低,玉米对植酸钙的利用效率高于硝态氮处理,尽管供硝态氮时磷酸单酯酶活性更高。同时,在供应铵态氮条件下,植株对植酸钙的利用率要显著高于卵磷脂,原因在于虽然磷酸双酯酶和磷酸单酯酶活性较低,由于植酸钙的溶解度较大,它的底物有效性更高。因此,植酸钙处理中植株的磷含量更高。相反,在供应硝态氮时,植酸钙溶解度减小而两种磷酸酶活性较高,卵磷脂处理中植株的磷含量更高。【结论】土壤中有机磷的水解过程由磷酸酶活性和有机磷底物有效性两个因素控制,酶活性与根际pH密切相关。本研究说明土壤有机磷的活化必须首先转化为溶解于水溶液中的状态,才能作为磷酸酶的底物被催化水解。我国长期施用化肥导致北方土壤大范围酸化,这种酸化无疑对土壤固有或随有机物料进入农田的有机磷的活化利用是具有重要贡献的,应该在北方土壤养分管理中应加以考虑。