不同品种菠菜叶柄和叶片的硝态氮含量及其与植株生长的关系

温室盆栽试验研究了我国北方不同菠菜品种叶柄和叶片的硝态氮含量及其与植株生长的关系。结果表明,30个菠菜品种地上部分的生长量和硝态氮含量存在显著差异。叶柄和叶片在反映品种间生长量和硝态氮含量变异方面的作用并不相同。叶片占植株地上部鲜重的比例高于叶柄,品种间叶片生长量的差异亦大于叶柄,叶片与植株生长量的正相关关系更为显著。但与生长量的情况不同,叶柄的硝态氮含量、累积总量均显著高于叶片,是菠菜累积硝态氮的主要器官。叶柄硝态氮含量的品种间差异远大于叶片,与植株地上部硝态氮含量的正相关性更为显著。菠菜不同品种之间,叶柄硝态氮含量与地上部鲜重、干重及水分均表现出显著的正相关关系,而叶片硝态氮含量与植株生物量及其各组分之间却无这种关系。     

小白菜适当增铵下硝酸盐累积机理研究

利用NO3--N/NH44+-N为100∶0和75∶25的营养液对两个硝酸盐累积能力显著不同的小白菜品种(上海青和亮白叶1号)进行培养,测定了小白菜叶片、叶柄及根系硝酸盐含量、硝态氮和铵态氮吸收量及各部位硝酸还原酶活性,以探讨适当增铵降低小白菜硝酸盐含量以及小白菜不同品种和不同器官累积硝酸盐能力差异的机理。结果表明,适当增铵使叶片、叶柄和根系硝酸盐含量分别降低了22%、15%和22%,而硝态氮吸收量则降低了7.5%。小白菜各器官硝酸盐含量为叶柄叶片根系。叶片硝酸还原酶活性分别是叶柄和根系的27和9倍,呈现叶片根系叶柄,叶片是硝态氮的主要还原器官。亮白叶1号叶片、叶柄及根系硝酸盐含量分别较上海青高3%、38%和34%,硝态氮吸收量仅较上海青高11%;而叶片、叶柄及根系硝酸还原酶活性则分别较后者降低44%、56%和38%。适当增铵减少硝态氮吸收量是增铵降低硝酸盐含量的主要原因。不同器官的功能与结构的不同决定其累积硝酸盐能力的不同;不同品种硝酸盐累积的差异取决于还原硝态氮能力的差异。     

不同氮形态配比对菠菜营养品质及抗氧化酶活性的影响

通过水培试验研究了不同氮形态配比对菠菜可食部位硝酸盐、草酸、维C含量及POD、CAT、SOD抗氧化酶活性的影响。结果表明:随铵态氮比例的增加,菠菜可食部位的硝酸盐、草酸含量逐渐减少,在完全供铵时含量最少。硝态氮/铵态氮比为25/75时Vc含量最高。在增加铵态氮比例时,POD、SOD和CAT活性有所下降,而在完全供铵时,P0D、S0D、CAT活性最高,MDA含量也最高。     

供氮水平对菠菜产量、硝酸盐和草酸累积的影响

采用溶液培养方法研究了不同供氮水平对菠菜生物量、硝酸盐和不同形态草酸含量的影响。结果表明,供氮水平由4.mmol/L增加到8.mmol/L,菠菜产量显著增加,继续提高氮水平对产量没有显著影响。叶片中的维生素C(Vc)含量随着供氮浓度从4.mmol/L提高到8.mmol/L而显著增加,再增加氮水平,叶片中的Vc含量明显下降;而菠菜叶柄Vc的含量则随供氮水平的提高显著下降。叶片硝酸盐含量随着氮浓度的提高而增加,当供氮水平由4mmol/L增加到8.mmol/L时,叶柄硝酸盐含量显著下降,而氮水平由8.mmol/L提高到20.mmol/L时,叶柄硝酸盐含量则随之升高。供氮浓度从4.mmol/L增加到8.mmol/L,叶片可溶态草酸含量略有下降,再提高供氮水平则明显上升,供氮水平低于12.mmol/L时,叶柄中的可溶态草酸和菠菜叶片和叶柄中的草酸总量则随着氮水平的提高而升高,高于12.mmol/L草酸含量反而降低。由此可见,菠菜在供氮浓度为8mmol/L(N2)时能够获得较高的产量和Vc含量,较低的硝酸盐和草酸含量,表明适宜的供氮水平下可获得高产优质的菠菜。     

光质对菠菜草酸、单宁及硝酸盐积累效应的影响

用彩色荧光灯得到红光、蓝光和黄光，以白光为对照，研究不同光质对菠菜产量，草酸、单宁及硝酸盐积累的影响。结果表明,处理间的菠菜叶柄和叶片硝酸盐和草酸含量的变化不同，但地上部生长量的变化趋势相同。叶片占植株地上部鲜质量的比例高于叶柄。不同处理叶片和叶柄鲜质量依次为白光(对照)>黄光>红光>蓝光。红光处理有利于干物质和碳水化合物的形成与积累。菠菜叶柄的硝酸盐含量显著高于叶片,是积累硝酸盐的主要场所，并且各处理间叶片硝酸盐和单宁含量的差异远大于叶柄。白光和黄光处理下，菠菜叶片草酸含量大于叶柄，而红光和蓝光处理则相反，其中红光处理草酸含量最低。菠菜在红光处理下生物量虽不高，但可极大地降低硝酸盐和草酸含量，提高菠菜品质。     

铵硝比和磷素营养对菠菜生长、氮素吸收和相关酶活性的影响

通过水培试验研究了不同铵硝比的氮素营养和磷素营养对菠菜生长、氮素吸收及硝酸还原酶活性（NRA）和谷氨酰胺合成酶活性（GSA）的影响。结果表明：在供磷水平相同时，菠菜的生物量随着铵硝比的降低而降低，但铵硝比为25：75与0：100两个处理之间没有显著差异；在铵硝比相同时，随着营养液中磷含量的增加，菠菜的生物量随之增加。菠菜茎叶中硝酸盐的含量随着铵硝比和磷水平的降低而升高。不同铵硝比处理，菠菜含氮量没有明显差异，随着磷水平的提高，菠菜植株含氮量有升高的趋势，但各处理之间差异不显著；受到生物量显著差异的影响，菠菜植株中氮素累积量随着铵硝比的降低和磷素水平的增加而增加。在铵硝混合营养条件下，缺磷会显著抑制菠菜对铵态氮和硝态氮的吸收，且磷索缺乏对菠菜吸收硝态氮的抑制作用要大于对铵态氮吸收的抑制作用。铵硝比相同时，随着营养液中磷索供应量的增加，菠菜茎叶中NRA显著增加；但是营养液中铵硝比较高时，会显著抑制菠菜茎叶中NRA，而铵硝比较低时，则有利于提高菠菜的NRA。缺磷会严重抑制GSA；在磷素水平相同时，随着营养液中铵比例的增加，菠菜茎叶中GSA显著增加。为此，在一些硝酸盐含量较高的土壤上栽培蔬菜时，可以采取增施适量磷肥的方法，以降低叶菜的硝酸盐含量。     

不同铵硝比对菠菜生长、安全和营养品质的影响

通过水培试验,研究了等氮条件下5种不同铵硝比对菠菜生长和品质的影响。结果表明:(1)从铵硝比100∶0到0∶100,菠菜地上部鲜重不断增加,铵硝比为0∶100时,菠菜的鲜重达最大值;但铵硝比25∶75和0∶100两个处理菠菜的干物重没有显著差异(p<0.05)。(2)随着铵硝比的降低,菠菜茎叶中硝酸盐、亚硝酸盐的含量均表现为线性增加;菠菜茎叶中可溶性草酸的含量和营养液中铵硝比之间呈现出二次曲线相关,在铵硝比为25∶75时,菠菜茎叶中草酸含量最低。适当增施铵态氮有利于降低菠菜硝酸盐、亚硝酸盐及草酸的含量。(3)增铵可以提高菠菜Vc含量,铵硝比为50∶50的处理菠菜Vc含量最高;随着铵硝比的下降,菠菜茎叶中可溶性糖的含量逐渐降低,而粗蛋白的含量则以铵硝比25∶75处理最高。     

同铵硝比对菠菜生长、安全和营养品质的影响

通过水培试验,研究了等氮条件下5种不同铵硝比对菠菜生长和品质的影响.结果表明：（1）从铵硝比100∶0到0∶100,菠菜地上部鲜重不断增加,铵硝比为0∶100时,菠菜的鲜重达最大值;但铵硝比25∶75和0∶100两个处理菠菜的干物重没有显著差异（p＜0.05）.（2）随着铵硝比的降低,菠菜茎叶中硝酸盐、亚硝酸盐的含量均表现为线性增加;菠菜茎叶中可溶性草酸的含量和营养液中铵硝比之间呈现出二次曲线相关,在铵硝比为25∶75时,菠菜茎叶中草酸含量最低.适当增施铵态氮有利于降低菠菜硝酸盐、亚硝酸盐及草酸的含量.（3）增铵可以提高菠菜Vc含量,铵硝比为50∶50的处理菠菜Vc含量最高;随着铵硝比的下降,菠菜茎叶中可溶性糖的含量逐渐降低,而粗蛋白的含量则以铵硝比25∶75处理最高.     

氮钙配合施用对菠菜产量及品质的影响

采用盆栽的方法,研究不同氮钙配合对菠菜产量、硝酸盐、Vc及草酸含量的影响.结果表明,供钙用量一致时,菠菜生物量在氮用量为0.2 g/kg时最高;在氮用量为0 g/kg和0.4 g/kg时,菠菜的生物量随着钙水平的提高而升高;供氮量为0.2 g/kg时,随着施钙量的增加菠菜生物量先升高后降低;在相同供钙水平下,菠菜可食部位的硝酸盐、草酸总量和可溶态草酸含量随着氮用量的增加而升高;当施氮量为0 g/kg时,增加钙肥可以显著降低菠菜可食部位的草酸总量和可溶态草酸含量;当供氮量为0.2和0.4 g/kg时,可溶态草酸含量和草酸总量均随着钙肥用量的增加而明显降低后升高.在本试验中,氮钙用量分别为0.2 g/kg和0.3 g/kg时,即氮钙用量分别相当于大田用量150 kg/hm2和225 kg/hm2时,菠菜具有最高的生物量,较低的硝酸盐、可溶态草酸和草酸总量,较高的Vc含量.     

不同铵态氮/硝态氮配比营养液对烟草矿质营养吸收与积累的影响

采用营养液培养的方法,研究了不同铵态氮与硝态氮配比(铵硝比)营养液对烟草主要几种矿质养分的吸收与积累的影响。结果表明,在其它养分形态与浓度一致条件下,随着铵硝比从10∶0变化到0∶10,烟草叶片、茎与全株干物质量均增加,但烟草根系干物质量呈倒抛物线型变化,以铵硝比为5∶5时达到最大值(2.31 g)。烟草全株氮、磷、锌含量以铵硝比为7∶3时达到最大,钾、镁、铜、锰等含量随硝态氮含量的增加而显著增加,钙含量以铵硝比为3∶7达到最大值;全株内氮、磷、钙、锌积累量随硝态氮所占比例的增加而增加,以3:7时达到最大值,钾、镁、铜、锰等积累量随硝态氮所占比例的增加而增加。铵硝比从10∶0变化到7∶3时,烟草叶片氮、磷含量随硝态氮所占比例的增加而增加,其中以铵硝比为7∶3时达到最高,钾、镁、铜、锰含量随硝态氮所占比例的增加而增加;而钙含量达到最大值的铵硝比为3∶7,但锌含量总随硝态氮所占比例的增加而降低。氮、磷、钙、锌等在叶片的积累量以铵硝比为3∶7时达到最大值,而钾、镁、铜、锰等积累量总随铵硝比的减少而增加。     

Effects of Nitrogen Levels and Nitrate/Ammonium Ratios on Oxalate Concentrations of Different Forms in Edible Parts of Spinach

Two hydroponic experiments were carried out to investigate the effects of nitrogen (N) levels and forms on the oxalate concentrations of different form in edible parts of spinach. Nitrogen was supplied at five levels (4, 8, 12, 16, 20 mM) in Experiment 1 and five ratios of nitrate (NO₃ ^?) to ammonium (NH₄ ⁺) (100/0, 75/25, 50/50, 25/75, 0/100) at a total N of 8 mM in Experiment 2. Biomass of spinach increased markedly from 4 mM to 8 mM N and reached the flat with further increase in N. The total oxalate and soluble oxalate in leaves and shoots (edible parts) increased significantly with increasing N levels from 4 to 12 mM, while the total oxalate and insoluble oxalate decreased markedly when N level was further increased from 12 to 20 mM. Oxalates of different forms in petioles increased first and then decreased and elevated again with increasing nitrogen levels. In the second experiment, decreasing NO₃ ^?/NH₄ ⁺ ratios markedly increased at first and then significantly decreased the biomass of spinach plants and the maximum biomass was recorded in the treatment of the NO₃ ^?/NH₄ ⁺ ratio of 50:50. The oxalate concentrations of different form in leaves and shoots were all decreased obviously as the ratio of NO₃ ^?/NH₄ ⁺ decreased from 100:0 to 0:100. Concentrations of total oxalate and soluble oxalate in petioles could be reduced by increasing ammonium proportion and were the lowest as the ratio of NO₃ ^?/NH₄ ⁺ was 50:50 and insoluble oxalate decreased as nitrate/ammonium ratio decreased. The concentrations of oxalate forms in leaves were all higher than those in petioles and soluble oxalate was predominant form of oxalates in both trials. It is evident that high biomass of spinach can be achieved and oxalate concentrations of different forms can be reduced by modulating N levels and NO₃ ^?/NH₄ ⁺ ratio, so this will benefit for human health especially for those people with a history of calcium oxalate kidney stones.     

施氮、钾和钼对菠菜不同生长阶段硝态氮积累影响研究初报

采用盆栽试验研究了肥料(氮、钾、钼)互作对菠菜不同生长阶段硝态氮积累的影响。结果表明,施肥对菠菜硝态氮积累的影响整体表现为:柄叶,老叶新叶;与生长前期相比,收获期各部位中硝态氮含量均有下降趋势。不施氮条件下,施钼极显著或显著地降低了菠菜生长前期和收获期叶片中硝态氮含量,降幅分别为19.3%和21.4%;施氮条件下,施钼仅显著降低了菠菜生长前期叶片中硝态氮含量,降幅达21.2%。在本试验条件下,单施钼比钼钾配施更有利于降低菠菜叶片中硝态氮的含量;钾与钼营养的相互效应,以及钾与钼之间如何平衡,似乎是影响施钼效果的关键。     

氮肥形态和用量对蔬菜生长与硝态氮累积的影响

Experiments were carried out on a vegetable field with Peking cabbage (Bvassica pekinensis (Lour.) Rupr.), cabbage (Bvassica chinensis var. oleifera Makino and nemoto), green cabbage (Brassica chinensis L.), spinach (Spinacia oleracea L.) and rape (Brassica campestris L.) to study the effects of N forms and N rates on their growth and nitrate accumulation. The results indicated that application of ammonium chloride, ammonium nitrate, sodium nitrate and urea significantly increased the yields and nitrate concentrations of Peking cabbage and spinach. Although no significant difference was found in the yields after application of the 4 N forms, nitrate N increased nitrate accumulation in vegetables much more than ammonium N. The vegetable yields were not increased continuously with N rate increase, and oversupply of N reduced the plant growth, leading to a yield decline. This trend was also true for nitrate concentrations in some vegetables and at some sampling times. However, as a whole, the nitrate concentrations in vegetables were positively correlated with N rates. Thus, addition of N fertilizer to soil was the major cause for increases in nitrate concentrations in vegetables. Nitrate concentrations were much higher in roots, stems and petioles than in blades at any N rate.     

Effects of Nitrogen and Calcium Nutrition on Oxalate Contents,Forms, and Distribution in Spinach

ABSTRACT

A hydroponic experiment was conducted to study the effects of nitrogen (N) and calcium (Ca) nutrition on oxalate contents of different forms in spinach tissues. Results showed that leaves were the main locations of oxalates in spinach. Total oxalate, soluble oxalate, and insoluble oxalate contents were highest in leaves, followed by petioles and then roots. Soluble oxalate was the dominant form of oxalate in spinach. Nitrogen and Ca²⁺ (calcium ion) concentrations could markedly affect oxalate contents. Soluble oxalate contents in leaves increased obviously with the increase of N concentration until 8 mmol L^?1, above which oxalate content started to decrease. Supplied with the same amount of N, increasing Ca²⁺ concentration reduced soluble oxalate content in leaves. Total oxalate reached the lowest with 5 mmol L^?1 of Ca²⁺ supply. Leaves and petioles had lower total oxalate and lower proportion of soluble oxalate when N and Ca²⁺ concentrations were 8 and 5 mmol L^?1.     

陕西关中设施栽培蔬菜的硝酸盐累积状况分析

研究了陕西关中主要蔬菜产区设施栽培蔬菜的硝酸盐累积现状,探讨了施氮量对蔬菜硝酸盐累积的影响。结果表明,宝鸡、杨凌、咸阳、西安四地的新鲜大棚蔬菜硝酸盐污染严重,部分对硝酸盐敏感的蔬菜如萝卜、芹菜等硝酸盐含量超过无公害蔬菜卫生限量标准。施氮对蔬菜硝酸盐累积量的影响显著,随施氮量的增加,蔬菜可食部分的硝酸盐含量增加。     

Spatiotemporal changes of nitrate and Vc contents in hydroponic lettuce treated with various nitrogen-free solutions

Abstract

Nowadays, off-season leafy vegetables are generally characterized by low vitamin C (Vc) content and high nitrate accumulation due to low light intensity inner protected systems and high-level nitrogen supply. A glasshouse experiment was conducted to investigate the effects of three kinds of nitrogen-free solution treatments before harvest on Vc and nitrate contents in expanded leaf blades, expanded leaf petioles and old leaves of hydroponic lettuce. The results showed that using nitrogen-free solutions could decrease nitrate contents of expanded leaf blades, expanded leaf petioles and old leaves, also nitrate contents in above parts reduced increasingly with treatment time extending. In addition, three nitrogen-free solution treatments increased the Vc content of expanded leaf blades instead of expanded leaf petioles and old leaves. There were instead of significant positive correlations between nitrate contents but Vc contents of expanded leaf blades, expanded leaf petioles and old leaves. To conclude, nitrogen disruption treatment before harvest could effectively reduce nitrate contents in edible parts of lettuce, and also improve Vc content in expanded leaf blade.