镍离子对尖叶莴苣氮素吸收和生长生理的影响

以‘全年油麦菜’尖叶莴苣为试验材料,采用水培方式,研究3个浓度(0 mg·L^-1、0.1 mg·L^-1、1 mg·L^-1)Ni²⁺在22.4 mg·L^-1 N处理下对尖叶莴苣氮素吸收的生长及生理影响。结果显示：(1)尖叶莴苣根系和地上部生物量随处理时间的增加呈上升趋势。与对照T₁(0 mg·L^-1 Ni²⁺、112 mg·L^-1 N)相比,T₂处理(0 mg·L^-1 Ni²⁺、22.4 mg·L^-1 N)对尖叶莴苣根系及叶片生长具有一定抑制作用,植株鲜重、干重、根冠比、根系长度、平均直径、表面积、体积、根尖数、分根数、叶片表面积和体积在T3处理(0.1 mg·L^-1 Ni²⁺、22.4 mg·L^-1 N)下显著高于对照,T₄处理(1 mg·L^-1 Ni²⁺、22.4 mg·L^-1 N)对尖叶莴苣根系及其叶片生长具有一定促进作用,但对其根尖数和分根数表现出一定抑制性。(2)随着Ni²⁺浓度的增加,尖叶莴苣叶片叶绿素a、叶绿素b和总叶绿素含量呈先升后降的变化规律,且均在T₃处理下显著提高。(3)随着处理时间的增加,尖叶莴苣叶片的净光合速率(P_n)、气孔导度(G_s)和蒸腾速率(T_r)逐渐上升,胞间CO₂浓度(C_i)逐渐下降,且T₃处理叶片的G_s显著高于对照,其C_i最低,P_n最大。(4)施加Ni²⁺对尖叶莴苣有机酸、可溶性蛋白和可溶性糖含量以及SOD和POD活性有显著影响,在T₃处理下有机酸含量降低,可溶性糖和可溶性蛋白含量显著增加,SOD和POD活性显著提高。(5)T₃处理尖叶莴苣根系中N及叶片中B和Ca含量较高;根系中Ni含量高于叶片,T₃处理叶片中的Ni含量较低,Mg含量较高;植株体内Cu含量随Ni²⁺浓度增加而下降。研究表明,外源Ni²⁺处理能影响低氮条件下(22.4 mg·L^-1 N)尖叶莴苣幼苗生长及生理状况,适宜浓度(0.1 mg·L^-1)Ni²⁺可有效提高尖叶莴苣根系对氮素的吸收利用效率,减少氮素施用量,促进尖叶莴苣根系和地上部叶片生长,增加光合色素含量,并提高净光合速率,进而改善植株的产量和营养品质。     

施钾量对设施基质栽培番茄生长生理及其产量和品质的影响

以番茄品种‘184’为材料,采用水肥一体化番茄设施基质栽培模式,以甘肃农业大学植物营养液配方C中钾肥为对照(T₁常规钾肥量),再在配方C中添加不同量钾肥组成T₂(钾肥增量25%)、T₃(钾肥增量50%)、T₄(钾肥增量75%)等处理,探究不同施钾量对设施基质栽培番茄生长、生理、产量及品质的影响,并筛选设施基质栽培条件下最佳施钾量。结果显示：(1)与常规施钾肥量(T₁)相比,增施钾肥处理(T₂-T₄)均可显著提高番茄株高、茎粗、根系活力,且T₃处理的各指标均最高,但增施钾肥对叶片数的影响不显著。(2)增施钾肥处理较T₁均能够显著提高番茄叶片光合色素含量,增强光合和荧光过程,进一步促进光能的吸收与转化,且T₃处理的增幅最高。(3)随着施钾量的升高,增施钾肥处理的番茄单果重、果实产量呈现不同程度的增长趋势,适量增施钾肥处理增幅均达到显著水平,并以T₃番茄产量最高,且较T₁显著增产20.87%。(4)与T₁相比,各施钾处理番茄果实硬度、可溶性总糖、Vc、可溶性蛋白、番茄红素含量等均有不同程度提升,各指标均随着施钾量增加呈先上升后下降的变化趋势,并在T₃处理下达到最优。(5)主成分分析表明,各处理的综合得分依次为T₃＞T₄＞T₂＞T₁。研究发现,在设施基质栽培条件下,适量增施钾肥能显著提高番茄植株光合作用效率,促进植株生长,达到提高果实产量和改善品质的目的,并以常规钾肥增量50%处理的效果最佳。     

硝态和铵态氮配比对水培油麦菜苗期生长及生理特性的影响

采用水培技术,以油麦菜幼苗为材料,研究不同硝铵态氮配比（NO₃^-∶NH₄⁺）对油麦菜苗期地上部和根系生长及生理特性的影响。结果表明：（1）油麦菜地上部和根系硝酸盐含量皆与营养液中NO₃^--N比例呈正相关关系,且各处理均达到无公害蔬菜的标准。（2）随着营养液中NH₄⁺-N比例的增加,油麦菜地上部有机酸含量先降低后升高,且在硝铵态氮配比为5∶5时最低,可溶性糖含量呈上升趋势,而可溶性蛋白质含量先升高后降低,在硝铵态氮配比为5∶5时最高;油麦菜根系有机酸和可溶性糖含量先升高后降低,两者分别在硝铵态氮配比为5∶5和7.5∶2.5时最高,而可溶性蛋白质含量呈下降趋势,在全NO₃^--N时最高。（3）随着营养液中NH₄⁺-N比例的增加,油麦菜地上部和根系中SOD活性先升后降,并分别在硝铵态氮配比为5∶5和7.5∶2.5时最高,而地上部和根系中MDA、脯氨酸含量和POD、CAT活性的变化趋势则与其相反。（4）随着营养液中NH₄⁺-N比例的增加,油麦菜地上部和根系干重皆先升后降,根冠比则逐渐减小;在硝铵态氮配比为7.5∶2.5时干重最大,根冠比适宜且稳定。研究表明,水培油麦菜苗期地上部和根系生长及生理特性受到氮素形态配比的显著影响,且根系的生理响应更敏感;营养液中硝铵态氮配比为7.5∶2.5时,油麦菜受胁迫程度最低,地上部和根系生长较协调,油麦菜生长和生理状况最佳。     

艾司氯胺酮联合舒芬太尼对剖宫产围手术期镇痛、应激指标及抑郁评分的影响

摘要 目的：探究艾司氯胺酮联合舒芬太尼对剖宫产围手术期镇痛、应激指标及抑郁评分的影响。方法：选取2021年1月~2021年10月期间我院收治的行剖宫产手术的180例产妇,采用随机数字表法分为A组、B组、C组各60例。A组胎儿娩出后即刻静脉输注艾司氯胺酮,术后艾司氯胺酮联合舒芬太尼静脉自控镇痛;B组和C组胎儿娩出后不给予艾司氯胺酮,用生理盐水代替;B组术后静脉自控镇痛与A组相同,C组术后给予舒芬太尼静脉自控镇痛。比较三组产妇术后4 h（T₁）、8 h（T₂）、12 h（T₃）、24 h（T₄）、48 h（T₅）疼痛程度[简化McGill疼痛问卷（SF-MPQ）评分]、镇静程度（Ramsay镇静评分）,记录三组术前1 d和术后1 d的应激指标[去甲肾上腺素（NE）、皮质醇（Cor）、促肾上腺皮质激素（ACTH）]水平,比较三组术前1 d和术后3、7 d抑郁程度[爱丁堡产后抑郁量表（EPDS）],比较三组不良反应发生情况。结果：T₁、T₂、T₃时A组视觉模拟评分（VAS）明显低于B、C组（P均<0.05）,T₁、T₂时A组痛分级指数（PRI）感觉分明显低于B、C组（P均<0.05）,T₁、T₂、T₃、T₄、T₅时A组PRI情感分明显低于B、C组（P均<0.05）,T₁时A组现时疼痛强度（PPI）评分明显低于B、C组（P均<0.05）。T₁、T₂、T₃、T₄、T₅时,三组Ramsay镇静评分比较差异均无统计学意义（P均>0.05）。术后1 d,三组NE、Cor、ACTH水平均较术前1 d显著升高（P均<0.05）,术前1 d和术后1 d,三组NE、Cor、ACTH水平比较差异均无统计学意义（P均>0.05）;术后3、7 d时A组EPDS评分明显低于术前1 d和同时间B、C组（P均<0.05）;三组不良反应发生情况对比无显著性差异（P均>0.05）。结论：艾司氯胺酮联合舒芬太尼在剖宫产围术期镇痛中应用效果良好,能够减轻产妇术后早期抑郁程度。     

超重力胁迫下‘平邑甜茶’幼苗叶片生理指标及其转录组分析

该试验以‘平邑甜茶’60 d龄幼苗为材料,设置T₁(5 000 r/min×3 h)、T₂(5 000 r/min×6 h)、T₃(10 000 r/min×3 h)和T₄(10 000 r/min×6 h)超重力处理,以未进行超重力处理为对照(CK),考察超重力处理下幼苗叶片叶绿素、可溶性蛋白、丙二醛、脯氨酸含量和膜透性等与逆境相关的生理指标的变化,并对其进行转录组分析,初步探究‘平邑甜茶’在超重力处理下的转录组响应机制。结果表明：(1)超重力处理造成‘平邑甜茶’幼苗叶片由舒展状生长状态向不同萎缩生长状态转变,其中T₄处理萎缩生长状态明显。(2)超重力处理下,‘平邑甜茶’幼苗叶片叶绿素和丙二醛含量在T₃和T₄处理下显著高于CK, T₁和T₂处理下与CK无显著差异;叶片脯氨酸含量在各超重力处理下均显著高于CK;膜透性在T₄处理下显著高于CK, T₁、T₂、T₃处理与CK无显著差异;可溶性蛋白含量在各超重力处理下均不同程度降低,但均与CK差异不显著。(3)样品测序结果显示,大多数转录本的序列长度在1 000 nt以上,有37 725个,占全部转录本79.15%,且CK、T₂、T₄样品以及相对应的新基因中均以FPKM值小于5.0的转录本数为主,其转录本数依次分别有21 412、20 162、22 368个和1 352、1 411、1 406个,占比分别为45.78%、43.10%、47.82%和81.45%、85.00%、84.70%。(4)GO功能注释与富集分析显示,随着超重力处理强度的加大,差异表达基因在GO富集分类中存在明显不同的途径,说明‘平邑甜茶’对超重力的响应是复杂的,但主要集中在转录因子活性、蛋白质去磷酸化过程方面。(5)差异转录因子表达分析显示,随超重力处理强度的增加表达上调幅度比较大的基因家族有bZIP、WRKY和ERF,其中bZIP和WRKY转录因子家族中的基因表达量均随超重力处理强度的增加呈上升趋势,但ERF家族中的MD01G1177100、MD08G1096000、MD13G1130700基因表达量随超重力处理强度的增加有下降的趋势。研究表明,超重力处理对‘平邑甜茶’幼苗造成了不同程度的伤害,且叶片总叶绿素、丙二醛、脯氨酸含量以及膜透性均受到显著影响,故幼苗叶片中叶绿素、可溶性蛋白、丙二醛及脯氨酸含量以及细胞膜膜透性均可作为评价超重力胁迫的抗性指标;研究推测超重力胁迫对‘平邑甜茶’转录因子的影响主要集中在WRKY、bZIP和ERF转录因子家族。该研究结果为候选抗性基因的挖掘和筛选奠定了理论基础。     

外源H2O2对盐碱胁迫下苹果矮化砧木幼苗生理特性的影响

以2年生苹果矮化砧木M9 T337为试材,采用盆栽试验法,设置浇灌清水(CK)和盐碱胁迫(0.1 mol/L NaCl+NaHCO₃溶液)+ 喷施5种浓度的H₂O₂ ［0(T₁)、0.2 mmol/L(T₂)、0.4 mmol/L(T₃)、0.6 mmol/L(T₄)、0.8 mmol/L(T₅)］ 处理,测定各处理叶片叶绿素含量、光合气体交换参数、渗透调节物质含量、抗氧化酶活性和细胞膜透性,并利用相关性与主成分分析进行综合评价,以探讨外源过氧化氢(H₂O₂)增强其盐碱耐性的生理机制。结果表明：(1)随着盐碱胁迫(T₁)的时间延长,M9 T337幼苗叶片叶绿素a(Chl a)含量、叶绿素b (Chl b)含量、叶绿素总量(Chl t)、净光合速率(P_n)、气孔导度(G_s)、蒸腾速率(T_r)、可溶性蛋白(SP)含量均呈逐渐下降趋势;胞间CO₂浓度(C_i)、可溶性总糖(TSS)含量、脯氨酸(Pro)含量、过氧化氢酶(CAT)活性、抗坏血酸过氧化物酶(APX)活性、相对电导率(REC)、丙二醛(MDA)含量均呈上升趋势;超氧化物歧化酶(SOD)活性、过氧化物酶(POD)活性均呈先升后降趋势。(2)与CK相比,盐碱胁迫+外源H₂O₂(T₂- T₅)处理后M9 T337幼苗叶片各指标均呈现不同幅度变化,且存在明显浓度效应,并以T₃(0.4 mmol/L H₂O₂)处理叶片的Chl a、Chl b、Chl t、SP和G_s降幅最小,C_i、REC、MDA升幅最小,TSS、Pro、APX升幅最大。(3)M9 T337幼苗叶片P_n与T_r、G_s、Chl a、Chl b、Chl t、SP、SOD、POD呈显著正相关,与C_i、MDA、CAT、APX、REC呈显著负相关。(4)综合评价表明,各处理对M9 T337幼苗叶片生理特性的效应依次为：CK>T₃>T₄>T₂>T₅>T₁。研究发现,叶面喷施适宜浓度H₂O₂可有效改善盐碱胁迫下M9 T337幼苗光合能力,显著提高抗氧化酶活性和渗透调节物质的含量,降低细胞膜透性,从而达到缓解盐碱胁迫的作用,并以0.4 mmol/L H₂O₂处理效果最佳。     

硅对生姜叶片水、二氧化碳交换特性的影响

为探讨硅对生姜植株的生理效应,以莱芜大姜为试材,研究了水培营养液中不同硅素水平对生姜植株生长、硅含量及叶片光合作用和蒸腾作用的影响.结果表明：植株各器官硅含量及生物量均随营养液硅素水平的升高而显著增加,1.0 (T₁)、1.5 (T₂)、2.0 (T₃) mmol·L^-1硅(Si)处理植株叶片硅 (SiO₂) 含量分别比CK增加604.4%、834.8%和1130.4%,单株生物量分别比CK增加9.4%、19.4%和22.8%.随着硅素水平的升高,叶片Mg²⁺ TPase、Ca²⁺ ATPase活性及光合速率(P_n)和水分利用效率(WUE)提高,蒸腾速率(T_r)降低.一天中在11:00时,T₁、T₂、T₃处理的生姜叶片P_n和WUE分别比CK提高11.2%、21.8%、28.2%和23.1%、55.9%、54.8%,T_r分别比CK降低6.3%、17.1%和19.2%.此外,硅素还显著提高了生姜叶片光合作用饱和光强、CO2羧化效率及类胡萝卜素含量,但对叶绿素含量无显著影响.本试验条件下,以15～20 mmol·L-1硅素(Si)处理效果最好.     

栽培基质中添加砻糠灰对甜瓜生长和果实品质的影响

为减少不可再生资源草炭的使用,降低无土栽培基质生产成本,以甜瓜品种‘羊角蜜’为试验材料,将砻糠灰和市售成品栽培基质按照不同体积比［1∶5(T₁)、2∶4(T₂)、3∶3(T₃)、4∶2(T₄)、5∶1(T₅)］进行混配,以未添加砻糠灰的市售成品栽培基质为对照(CK),研究不同配比基质的理化性质及其对甜瓜生长、叶片叶绿素含量、光合气体交换参数以及果实品质的影响。结果表明：(1)在市售栽培基质中添加一定量的砻糠灰可显著改善基质通气状况,提高混配基质的pH、电导率(EC),显著抑制基质中微生物数量。(2)与对照相比,适量砻糠灰混配基质能够显著促进甜瓜植株的生长,其中T₂处理下,甜瓜植株的株高、根系活力、根冠比相比于CK分别显著提高了14.69%、19.73%、23.08%。(3)在T₂处理下,甜瓜叶片叶绿素含量、净光合速率、气孔导度、蒸腾速率显著升高。(4)T₂处理下甜瓜横径、纵径、单果重和单株产量与对照相比均显著提高,其单果重增幅达到20.3%,并且果实可溶性糖、可溶性固形物、可溶性蛋白、蔗糖、葡萄糖等含量显著增加,蔗糖合成酶活性和蔗糖磷酸合成酶活性有明显增强。研究发现,混配适量砻糠灰可有效改善栽培基质理化特性,显著促进甜瓜植株生长,提高甜瓜叶片光合作用能力,改善甜瓜果实品质,并以砻糠灰与市售成品栽培基质体积比为2∶4的混配基质配方最为适宜,可替代传统基质用于甜瓜栽培。     

对比分析丙泊酚/依托咪酯混合液分别联合艾司氯胺酮、盐酸舒芬太尼在无痛胃肠镜检查中的应用

摘要 目的：探讨对比分析丙泊酚/依托咪酯混合液分别联合艾司氯胺酮、盐酸舒芬太尼在无痛胃肠镜检查中的应用效果。方法：选取我院2022年1月到2022年12月收治的80例行无痛胃肠镜检查患者作为研究对象,应用随机数字表法将所有患者分为观察组与对照组,每组40例。对照组患者应用丙泊酚/依托咪酯混合液+盐酸舒芬太尼进行静脉麻醉,观察组应用丙泊酚/依托咪酯混合液+艾司氯胺酮进行静脉麻醉,对比两组患者入室时基础值（T₁）、开始镇静时（T₂）、胃镜置入后（T₃）、肠镜置入后（T₄）、操作结束即刻（T₅）五个不同时间血流动力学指标变化,并对比患者麻醉起效时间、麻醉药追加次数、追加麻醉药总量、意识恢复时间、PACU停留时间,对比检查不同时间认知功能情况以及不良反应发生率。结果：两组患者T₁时间舒张压（SBP）、收缩压（DBP）、平均动脉压（MAP）、心率（HR）对比无明显差异（P＞0.05）,观察组患者同组间T₁、T₂、T₃、T₄、T₅时间SBP、DBP、MAP、HR对比无明显差异（P＞0.05）,对照组T₁到T₂时间SBP、DBP、MAP、HR水平降低,到T₃和T₄时间升高,T₅时间恢复平稳,且观察组与对照组相比T₂、T₃、T₄时间SBP、DBP、MAP水平对比差异显著,观察组低于对照组,T₃时间观察组HR低于对照组（P＜0.05）;观察组麻醉起效时间、麻醉药追加次数、追加麻醉药总量、意识恢复时间、PACU停留时间显低于对照组（P＜0.05）;两组患者检查后6 h S100B 蛋白明显升高,检查后1 d的S100B 蛋白逐渐降低,且观察组低于对照组,检查后6 h褪黑素明显降低,检查后1 d的褪黑素逐渐升高,观察组高于对照组（P＜0.05）;观察组患者不良反应发生率明显低于对照组（P＜0.05）。结论：丙泊酚/依托咪酯混合液联合艾司氯胺酮与丙泊酚/依托咪酯混合液联合盐酸舒芬太尼对于无痛胃肠镜检查麻醉效果显著,能够改善患者血流动力学指标波动,减少麻醉药追加次数,且麻醉起效快,苏醒质量好,另外能够进一步改善患者检查后认知功能情况,安全性较高。     

干旱胁迫下4种常用植物幼苗的光合和荧光特性综合评价

老鸭嘴,山毛豆,假连翘和葛藤是常见的矿山植被恢复植物。采用盆栽控制土壤水分的方法,测定了这 4 种幼苗叶片的光合和荧光指标,以期为矿山植被的恢复植物筛选提供依据。结果表明（1）干旱胁迫处理期间,4 种幼苗叶片的净光合速率（P_n）、气孔导度（G_s）、蒸腾速率（T_r）和胞间CO₂ 浓度（C_i）持续下降,复水8 d后P_n均显著增加,老鸭嘴和山毛豆的G_s和T_r恢复到对照水平,山毛豆和葛藤的C_i恢复到对照水平;假连翘幼苗叶片的气孔限制值（L_s）随干旱胁迫时间的延长而逐渐增加,其他3 种幼苗略降后增加,复水8 d后均恢复到对照水平。（2）干旱胁迫处理期间,4 种幼苗叶片的photosystemⅡ（PSⅡ）光能捕获效率（F_v’/F_m’）、实际光化学量子效率（Yield）和表观电子传递速率（ETR）持续降低,8 d时显著小于对照。复水8 d后,F_v’/F_m’小幅波动,Yield和ETR有所恢复,其中葛藤的Yield和山毛豆的ETR恢复到对照水平;4种幼苗叶片的非化学淬灭（NPQ）持续上升,在第8天显著大于对照,复水8 d后,均持续下降,其中葛藤恢复到对照水平。（3）对光合和荧光指标进行主成分分析表明,干旱胁迫下4 种幼苗的抗旱性能大小顺序为山毛豆 > 老鸭嘴 > 假连翘 > 葛藤。     

The physiological mechanism of enhanced oxidizing capacity of rice (Oryza sativa L.) roots induced by phosphorus deficiency

Plants show various responses to phosphorus (P) deficiency. Root oxidizing capacity enhancement is one of adaptive mechanisms for rice (Oryza sativa L.) to P deficiency. However, it remains unclear how P deficiency enhances the root oxidizing capacity. In this study, rice seedlings were treated in P-deficient nutrient solution for different periods. Variations of reactive oxygen species (ROS), antioxidant enzyme activity, root lignin content, root porosity, root oxygen release, total oxidative substances and root structural changes in rice roots in response to P-sufficient and P-deficient treatments were investigated. Results indicated that P deficiency induced the production of H₂O₂ and O ₂ ^·? in roots significantly, which reached their maximum after 1- to 2-day P-deficient treatment. Interestingly, the endogenous total oxidative substances kept stable in rice roots. P deficiency increased the activities of peroxidase and superoxide dismutase by 89.5 and 51.8 % after 4-day P-deficient treatment, respectively. Moreover, one-day P deficiency elevated lignin accumulation. Root porosity of rice seedling under 2-day P-deficient treatment was 19.8 % higher than that under P-sufficient treatment. P deficiency also enhanced the release of both O₂ and total oxidative substances after 1- to 4-day P deficiency. In addition, results from electronic microscopy indicated that the thickness of root cell wall tended to increase after 2-day P-deficient treatment. Taken together, our results suggested that P-deficiency-induced enhancement of root oxidizing capacity in rice roots was probably associated with ROS production, antioxidant enzyme activity increment in root tissues, and the release of O₂ and oxidative substances from root inside to rhizosphere.     

Effect of N concentration and N source on root colonization by Pseudomonas fluorescens 2-79RLI

Wheat (Triticum aestivum L.) was grown in nutrient solution with low or high N supply (NH₄NO₃ as N source). To further evaluate the influence of N form and its interaction with the nutrient solution pH, wheat plants were grown with NH ₄ ⁺ or NO ₃ ^- either in an conventional nutrient solution or in a nutrient solution in which the pH was maintained at pH 6.5 using a pH-stat system. The nutrient solution was inoculated with Pseudomonas fluorescens 2-79RLI, a genetically modified bacterium that contains lux genes activated by a ribosomal promoter. Cell numbers and physiological status of P. fluorescens 2-79RLI (length of the lag phase of bioluminescence) in the rhizosphere were determined at the root tip and in the lateral root zone. Nitrogen deficiency decreased both plant growth and root colonization by P. fluorescens 2-79RLI at the root tip while it had no effect on root colonization in the lateral root zone. The physiological status of P. fluorescens 2-79RLI was not affected by nitrogen deficiency. Ammonium nutrition increased root colonization by P. fluorescens 2-79RLI at the root tip and in the lateral root zone when the pH of the nutrient solution was allowed to change according to the N form provided. Under these conditions, the physiological status of P. fluorescens 2-79RLI was higher in the lateral root zone than at the root tip. In contrast, N source had no effect on root colonization or physiological status of P. fluorescens 2-79RLI in the nutrient solution maintained at pH 6.5. It is concluded that the stimulation of root colonization by NH ₄ ⁺ in the nutrient solution, not maintained at a constant pH, may be due to increased leakage of solutes into the rhizosphere as a result of impaired exudate retention by high H⁺ concentration in the rhizosphere or the apoplast. This revised version was published online in June 2006 with corrections to the Cover Date.     

Effects of ammonium sulphate application on the chemistry of bulk soil,rhizosphere, fine roots and fine-root distribution in a Picea abies (L.) karst. stand

The effect of ammonium sulphate application on the bulk and rhizosphere soil chemistry, elemental concentration of living fine roots (<2 mm in diameter), amounts of living and dead fine roots, root length density and specific root length density were investigated in a 28 year old Norway spruce stand in SW Sweden. The treatments started in 1988. Core samples of the LFH layer and mineral soil layers were sampled in control (C) and ammonium sulphate (NS) treatment plots in 1988, 1989 and 1990. Soil pH and NO₃-S and SO₄-S, Al, Ca, Mg, Mn and K concentrations were measured for both the bulk soil and rhizosphere soil.The pH-values of the bulk and rhizosphere soil decreased in 1989 and 1990 in NS plots compared to control plots, while the SO₄-S concentration increased. The Ca, Mg and K concentration increased in the NS treatment in almost all layers in the bulk and the rhizosphere soil. Ammonium ions may have replaced these elements in the soil organic matter. The NS treatment reduced Mg concentration in fine roots in all layers in 1990. The Al concentrations in the rhizosphere and bulk soil were higher in NS plots in all layers, except at 0–10 cm depth, both in 1989 and 1990. The Al content of living fine roots was higher in NS plots than C plots but the differences were not significant. The NS addition did not affect the P and K contents of fine roots in any soil layer, but the S concentrations of fine roots were significantly higher in NS plots in 1989 and 1990. The fine root necromass was higher in NS than in C in 1990, in the LFH layer, indicating a gradual decrease in the vitality of the fine roots. It was suggested that the NS treatment resulted in displacement of Mg and K from exchange sites in the LFH layer leading to leaching of these cations to the mineral soil. Further application of ammonium sulphate may damage the fine roots and consequently adversely affect the water and nutrient uptake of root systems.     

Soil solution chemistry in the rhizosphere of roots of sessile oak (Quercus petraea) as influenced by lime

This study describes the soil solution chemistry in the rhizosphere of fine roots of sessile oak ( Quercus petraea (M.) Liebl.) grown in rhizotrons. A control was compared with soils treated with an equivalent CaCO₃ of 1.4 t ha^-1 CaO. Solution samples were extracted from the B-horizon using micro suction cups with a suction of _∼40 kPa. Two series of experiments were carried out: one irrigated with rain water (age of seedling 2 to 4 months) and one irrigated with demineralized water (age of seedlings 1.5 to 2 months). Half of the sampling points were choosen close to the roots and half in the bulk soil. In both experiments there was generally no rhizospheric gradient after liming. In contrast, in the control, depletion in the rhizosphere occurred for most of the ions studied (Mg, Ca, Al, K, NO₃ ^-, NH₄ ⁺, Cl^-) in the demineralized water experiment, but this was different when rainwater was used. The latter effect is probably due to the higher solution concentrations in the rainwater experiment but could also be a result of root damage due to low Ca/Al ratios in the rhizosphere solution. It was concluded, that liming improved the chemical composition in the rhizosphere soil solution by increasing overall solute concentration to levels enabling sufficient and easier nutrient uptake by roots. This revised version was published online in June 2006 with corrections to the Cover Date.     

The Use of Agar Nutrient Solution to Simulate Lack of Convection in Waterlogged Soils

Agar at 0.1% in nutrient solution (‘stagnant solution’)was used to prevent turbulence (convection), thus simulatingthe slow gas movements which occur in waterlogged soils. Wheat,aged between 6 and 16 d at the start of the treatment, was usedto test plant growth and development in this stagnant solutionfor 8–15 d. K-MES buffer at 5 mol m^-3was used to retainthe pH of the rhizosphere in the stagnant solution at pH 6.5. The prevention of convection reduced dissolved oxygen concentrationsin the bulk solution from 0.275 to below 0.05 mol m^-3after 1d, while ethylene accumulated over 10 d to 6.5x10^-6m³m^-3(ppm). Aerenchyma of nodal roots grown in stagnant solution comprised22% of the cross sectional area of the root 50 mm behind theroot tip; this was similar to values recorded earlier for nodalroots of wheat in waterlogged soil and contrasts with 7.6% forroots in non-flushed solution without agar (referred to in thispaper as ‘semi-stagnant solution’) and 2.4% in N₂-flushedsolution. Increases in dry weight and numbers of nodal roots with timewere larger for stagnant and N₂-flushed, than for semi-stagnantor aerated solution. In contrast, seminal roots did not growin stagnant solution, while seminal roots in N₂-flushed solutiongrew much less than in semi-stagnant or aerated solution. In the stagnant solution, relatively high concentrations ofN, K and P were required to avoid limitations in mineral uptakeinto the roots, due to the long diffusion pathway from the bulksolution imposed by the lack of convection. Nevertheless, ourdata show that the slow growth imposed by the lack of convectionwas due to factors other than low mineral nutrition. The mostlikely cause was the change in the dissolved gas compositionof the root media, particularly of the rhizosphere. In conclusion, in terms of anatomy and morphology the rootsgrown in the stagnant solution more closely resembled thosefrom waterlogged soil than did those grown in either semi-stagnantor N₂-flushed solution. Triticum aestivum; wheat; waterlogging; lack of convection; aerenchyma; root development; nutrient uptake     

Aerenchyma formation and radial O2 loss along adventitious roots of wheat with only the apical root portion exposed to O2 deficiency

This study investigated aerenchyma formation and function in adventitious roots of wheat (Triticum aestivum L.) when only a part of the root system was exposed to O₂ deficiency. Two experimental systems were used: (1) plants in soil waterlogged at 200 mm below the surface; or (2) a nutrient solution system with only the apical region of a single root exposed to deoxygenated stagnant agar solution with the remainder of the root system in aerated nutrient solution. Porosity increased two‐ to three‐fold along the entire length of the adventitious roots that grew into the water‐saturated zone 200 mm below the soil surface, and also increased in roots that grew in the aerobic soil above the water‐saturated zone. Likewise, adventitious roots with only the tips growing into deoxygenated stagnant agar solution developed aerenchyma along the entire main axis. Measurements of radial O₂ loss (ROL), taken using root‐sleeving O₂ electrodes, showed this aerenchyma was functional in conducting O_2. The ROL measured near tips of intact roots in deoxygenated stagnant agar solution, while the basal part of the root remained in aerated solution, was sustained when the atmosphere around the shoot was replaced by N₂. This illustrates the importance of O₂ diffusion into the basal regions of roots within an aerobic zone, and the subsequent longitudinal movement of O₂ within the aerenchyma, to supply O₂ to the tip growing in an O₂ deficient zone.     

Nutrient composition of Douglas-fir rhizosphere and bulk soil solutions

Rhizosphere soil solution is the direct source of nutrients for plant uptake. The nutrient composition of rhizosphere soil solution can be very different from that of bulk soil solution due to root exudation, nutrient uptake and rhizosphere microorganism activity. This study examined the nutrient composition of Douglas-fir rhizosphere soil solution in two soils belonging to the Nisqually and Pitcher soil series and compared rhizosphere solution with that of bulk soil solution. Fertilized and unfertilized Nisqually soils were also compared. Soil solutions were collected using centrifugation. Results indicated that nutrient concentrations in the rhizosphere solutions were typically higher than that of bulk soil solutions when no fertilizer was applied. Differences in the concentrations of nutrients between the rhizosphere and bulk soil solutions were masked by the addition of fertilizers. Rhizosphere solution pH also appeared to be affected by the concentration of NH₄ and NO₃ in the solution. With a higher concentration of NH₄ relative to NO₃ in the rhizosphere soil solution, the solution pH of the rhizosphere was lower than that of the bulk soil, but with a lower concentration of NH₄ relative to NO₃, the solution pH of the rhizosphere was higher than that of the bulk soil solution.     

Mechanisms of Aluminum Tolerance in Wheat : An Investigation of Genotypic Differences in Rhizosphere pH, K, and H Transport, and Root-Cell Membrane Potentials

Control of rhizosphere pH and exclusion of Al by the plasma membrane have been hypothesized as possible mechanisms for Al tolerance. To test primarily the rhizosphere pH hypothesis, wheat cultivars (Triticum aestivum L. `Atlas 66' and `Scout'), which differ in Al tolerance, were grown in either complete nutrient solution, or 0.6 millimolar CaSO₄, with and without Al at pH 4.50. A microelectrode system was used to simultaneously measure rhizosphere pH, K⁺, and H⁺ fluxes, and membrane potentials (E_m) along the root at various distances from the root apex. In complete nutrient solution, the rhizosphere pH associated with mature root cells (measured 10-40 millimeters from the root apex) of Al-tolerant `Atlas 66' was slightly higher than that of the bulk solution, whereas roots of Al-sensitive `Scout' caused a very small decrease in the rhizosphere pH. In CaSO₄ solution, no significant differences in rhizosphere pH were found between wheat cultivars, while differential Al tolerance was still observed, indicating that the rhizosphere pH associated with mature root tissue is not directly involved in the mechanism(s) of differential Al tolerance. In Al-tolerant `Atlas 66', growth in a CaSO<sub>4</sub> solution with 5 micromolar Al (pH 4.50) had little effect on net K<sup>+</sup> influx, H<sup>+</sup> efflux, and root-cell membrane potential measured in cells of mature root tissue (from 10-40 mm back from apex). However, in Al-sensitive `Scout', Al treatment caused a dramatic inhibition of K⁺ influx and both a moderate reduction of H⁺ efflux and depolarization of the membrane potential. These results demonstrate that increased Al tolerance in wheat is associated with the increased ability of the tolerant plant to maintain normal ion fluxes and membrane potentials across the plasmalemma of root cells in the presence of Al.     

Effects of Bacillus amyloliquefaciens FZB42 on Lettuce Growth and Health under Pathogen Pressure and Its Impact on the Rhizosphere Bacterial Community

The soil-borne pathogen Rhizoctonia solani is responsible for crop losses on a wide range of important crops worldwide. The lack of effective control strategies and the increasing demand for organically grown food has stimulated research on biological control. The aim of the present study was to evaluate the rhizosphere competence of the commercially available inoculant Bacillus amyloliquefaciens FZB42 on lettuce growth and health together with its impact on the indigenous rhizosphere bacterial community in field and pot experiments. Results of both experiments demonstrated that FZB42 is able to effectively colonize the rhizosphere (7.45 to 6.61 Log ₁₀ CFU g⁻¹ root dry mass) within the growth period of lettuce in the field. The disease severity (DS) of bottom rot on lettuce was significantly reduced from severe symptoms with DS category 5 to slight symptom expression with DS category 3 on average through treatment of young plants with FZB42 before and after planting. The 16S rRNA gene based fingerprinting method terminal restriction fragment length polymorphism (T-RFLP) showed that the treatment with FZB42 did not have a major impact on the indigenous rhizosphere bacterial community. However, the bacterial community showed a clear temporal shift. The results also indicated that the pathogen R. solani AG1-IB affects the rhizosphere microbial community after inoculation. Thus, we revealed that the inoculant FZB42 could establish itself successfully in the rhizosphere without showing any durable effect on the rhizosphere bacterial community.