土壤水分对温室春黄瓜苗期生长与生理特性的影响

以津优1号黄瓜为试验材料．研究了土壤不同水分含量对温室春黄瓜苗期生长与生理特性的影响。结果表明,在土壤水分为田间持水量90％时．黄瓜幼苗长势健壮,茎粗大,根系活力强,叶绿素含量和光合速率高．与其它处理差异显著,说明土壤含水量过高或过低均不利于培育黄瓜壮苗。株高和叶面积随土壤含水量的升高而增加;细胞汁液浓度随土壤含水量的升高而降低．且对植株水分状况反应十分敏感,可以用来作为判断植株水分盈亏状况的生理指标。     

日光温室地面覆盖对嫁接与未嫁接黄瓜生长发育、产量及土壤环境的影响

研究了秸秆、地膜和秸秆+地膜覆盖对日光温室嫁接与未嫁接黄瓜生长发育、产量及土壤环境的影响.结果表明,地面覆盖不仅能促进雌花分化、缩短成瓜时间、增加单瓜重、提高黄瓜产量,而且能降低畸形瓜比例,提高产品的商品性.其中以覆盖秸秆+地膜作用最明显、增产幅度最大,覆盖秸秆和覆盖地膜次之;嫁接黄瓜的处理效果优于未嫁接黄瓜.此外,地面覆盖对土壤环境也具有重要影响,但不同处理之间差异较大.地温日变化呈单峰曲线,5 cm、10 cm地温的波峰出现在14：30,随着土层的加深而波峰推迟出现,峰值也逐渐减小.秸秆覆盖具有降低最高地温和提高最低地温的作用,使土壤温度保持相对稳定;地膜覆盖对最高地温的增幅最大、对最低地温的增幅最小,从而使地温变幅最大;秸秆+地膜覆盖既增温又保温.地面覆盖的土壤呼吸速率均显著高于对照（P＜0.01）,并以秸秆+地膜覆盖的土壤呼吸速率最高,地膜覆盖与秸秆覆盖次之,土壤呼吸速率日变化也呈单峰曲线,与5 cm、10 cm地温日变化趋势一致,峰值出现在14：30左右,土壤呼吸速率与5 cm、10 cm地温达显著或极显著相关.秸秆覆盖与秸秆+地膜覆盖的0～20 cm土层土壤容重显著小于地膜覆盖与对照（P＜0.01）,地膜覆盖的土壤容重略小于对照,随着土层的加深,各处理间土壤容重差异渐小.     

低温胁迫下嫁接对黄瓜叶片SOD和CAT基因表达与活性变化的影响水

研究了低温胁迫下嫁接和自根黄瓜叶片Mn-SOD、Cu/Zn-SOD和CAT mRNA基因表达和酶活性变化及其与抗冷性的关系.结果表明:低温胁迫下,嫁接与自根黄瓜叶片Cu/Zn-SOD、Mn-SOD mRNA基因相对表达量变化分别与其Cu/Zn-SOD、Mn-SOD活性变化相吻合,而CATmRNA相对表达量变化与其CAT活性变化并不一致;嫁接黄瓜叶片Cu/Zn-SOD和Mn-SOD mRNA相对表达量及SOD、Cu/Zn-SOD和Mn-SOD活性均高于自根黄瓜,MDA含量和电解质渗漏率均低于自根黄瓜,嫁接黄瓜较高的SOD基因表达量调控的较高SOD活性是其抗冷性强于自根黄瓜的主要因素;嫁接黄瓜的功能叶CAT mRNA相对表达量略高于自根黄瓜,而幼叶CAT mRNA相对表达量低于后者,但两者CAT活性差异不大,说明低温胁迫对嫁接黄瓜叶片CAT mRNA相对表达量及CAT活性的影响不大.     

云南黑籽南瓜砧木对低温下嫁接黄瓜生理特性的影响

以‘津研4号’黄瓜(Cucumis sativus‘Jinyan No.4’)为接穗,云南黑籽南瓜(Cucurbita ficifoliaBouch啨)和黄瓜为砧木,研究了低温条件下黄瓜/云南黑籽南瓜嫁接株(黄瓜/南瓜)、黄瓜/黄瓜嫁接株和自根黄瓜株叶片的蔗糖(Suc)、葡萄糖(Glc)和可溶性蛋白质(Pr)含量的变化以及叶片羧化效率(CE)及不同叶位叶片、不同节位茎段中异戊烯基腺嘌呤核苷(iPA)含量的差异。结果表明,黄瓜/南瓜嫁接株叶片的Suc、Glc及Pr含量和CE值均显著高于自根黄瓜株和黄瓜/黄瓜嫁接株,自根黄瓜株与黄瓜/黄瓜嫁接株间差异不显著。iPA在嫁接植株和自根植株茎中均呈梯度分布,其含量在生长锥中最高,其次为上部茎段,下部茎段中的含量最低;自根黄瓜株和黄瓜/黄瓜嫁接株茎中的iPA含量显著低于黄瓜/南瓜嫁接株,而叶片中iPA含量显著高于黄瓜/南瓜嫁接株。研究结果表明,以黑籽南瓜为砧木可提高嫁接黄瓜对低温的耐受性。     

高温干热时节黄瓜嫁接技术试验研究

黄瓜通过嫁接有效地利用抗病砧木的根系取代黄瓜的根系,增强抗逆性,防止土传病虫害和连作障碍,明显增加产量。本文采用黑籽南瓜、12号、17号、29号为嫁接砧木,博耐二号黄瓜为接穗,探索在高温季节下黄瓜嫁接的最佳管理技术。通过试验表明,高温干热时节嫁接黄瓜时,日温度控制在25-30℃和湿度通过人工喷雾使叶片湿度控制在98%以上时能有效提高黄瓜嫁接成活率。     

嫁接黄瓜地上部的南瓜根系分泌物对种子萌发的影响

经嫁接黄瓜接穗的南瓜根系分泌物对黄瓜和南瓜的发芽率和胚根、胚轴的伸长均具有明显的抑制作用.分析表明:嫁接黄瓜根系分泌物可以促进黄瓜和南瓜体内吲哚乙酸氧化酶的活性,抑制淀粉酶的活性,从而降低其吲哚乙酸(IAA)水平,影响子叶中贮藏物质的转化和利用,抑制其萌发和生长.     

低温胁迫下嫁接对黄瓜叶片SOD和CAT基因表达与活性变化的影响

研究了低温胁迫下嫁接和自根黄瓜叶片Mn-SOD、Cu/Zn-SOD和CAT mRNA基因表达和酶活性变化及其与抗冷性的关系.结果表明:低温胁迫下,嫁接与自根黄瓜叶片Cu/Zn-SOD、Mn-SOD mRNA基因相对表达量变化分别与其Cu/Zn-SOD、Mn-SOD活性变化相吻合,而CATmRNA相对表达量变化与其CAT活性变化并不一致;嫁接黄瓜叶片Cu/Zn-SOD和Mn-SOD mRNA相对表达量及SOD、Cu/Zn-SOD和Mn-SOD活性均高于自根黄瓜,MDA含量和电解质渗漏率均低于自根黄瓜,嫁接黄瓜较高的SOD基因表达量调控的较高SOD活性是其抗冷性强于自根黄瓜的主要因素;嫁接黄瓜的功能叶CAT mRNA相对表达量略高于自根黄瓜,而幼叶CAT mRNA相对表达量低于后者,但两者CAT活性差异不大,说明低温胁迫对嫁接黄瓜叶片CAT mRNA相对表达量及CAT活性的影响不大.     

不同基因型砧木嫁接黄瓜结瓜盛期光合特性的比较

采用CIRAS-Ⅱ型便携式光合作用系统,对黑籽南瓜和新培育的白籽南瓜A22种不同基因型砧木嫁接黄瓜结瓜盛期的光合特性进行比较。结果表明：在结瓜盛期,2种砧木嫁接黄瓜不同叶位的叶片净光合速率均有一定差异,其中A2嫁接黄瓜中部和下部叶片的净光舍速率显著高于黑籽南瓜嫁接的黄瓜。A2与黑籽南瓜相比其嫁接黄瓜利用光能范围较广且光饱和时净光合速率、RuBP最大再生速率和表观量子效率分别高出黑籽南瓜嫁接的黄瓜23．2％、12．6％和8．2％。2种砧木嫁接的黄瓜CO2饱和点与羧化效率均相近,CO2补偿点A2低于黑籽南瓜嫁接的黄瓜。A2嫁接黄瓜叶片叶绿素a、b及叶绿素总量均明显高于黑籽南瓜嫁接的黄瓜,可溶性蛋白含量与黑籽南瓜嫁接的黄瓜差异不显著。A2嫁接黄瓜的雌花节率和平均单株产量分别高出黑籽南瓜嫁接的黄瓜25．2％和29．4％,A2嫁接黄瓜果实可溶性糖、可溶性蛋白和VC含量分别高出黑籽南瓜嫁接的黄瓜6.3％、15,2％和15．4％。     

地表覆盖对温室黄瓜生长及生理特性的影响

研究了地表覆盖秸秆、地膜和秸秆加膜对日光温室嫁接和非嫁接黄瓜生长与生理特性的影响.结果表明,地表覆盖可有效促进植株生长,嫁接黄瓜覆盖秸秆加膜、地膜与秸秆的株高和茎粗依次比对照增加91、71、57 cm和0127、0.086、0.111 cm,非嫁接黄瓜增幅较小;地表覆盖可增强光合作用,嫁接黄瓜覆盖秸秆加膜、地膜、秸秆的净光合速率分别比对照增加2.63、2.08与1.36 μmol·m^-2·s^-1,非嫁接黄瓜增幅较小;嫁接黄瓜覆盖秸秆加膜和秸秆的叶绿素含量比对照增加1.8%和3.15%,而覆盖地膜的叶绿素含量降低了3.8%,非嫁接黄瓜的叶绿素含量变幅较小;嫁接黄瓜覆盖秸秆加膜、地膜、秸秆的根系活力比对照提高0.98、0.48和0.8 mg TTC·g^-1FW,同一处理的非嫁接黄瓜根系活力增幅较小;地表覆盖可增加单株干物重,提高早期产量和总产量,嫁接黄瓜覆盖秸秆加膜、地膜与秸秆的单株产量比非嫁接黄瓜分别增加16%、5.3%和3.4%.     

土壤水分条件对温室黄瓜需水规律和水分利用的影响

在日光温室盆栽条件下,以不同生育时期为试验因素,采用正交设计研究了不同土壤水分条件在开花期、初瓜期、盛瓜期和生育后期等生育时期对黄瓜蒸腾量、生物量和水分利用效率的影响,并通过黄瓜的需水规律提出实现高产高效的土壤水分对策。研究结果表明：(1)黄瓜对水分的需求基本上呈现为开花期和初瓜期小、盛瓜期大、后期小的规律。需水高峰出现在盛瓜期,需水强度达到3．977mm／d;(2)开花期蒸腾速率为0．544mm／d。此时保持土壤含水量在80％～90％田间持水量范围内,不仅有利于水分的利用,而且可促进同化产物在根冠之间的合理分配;(3)初瓜期对水分的需求大幅度增加,蒸腾速率达到1．956mm／d。80％～90％田间持水量的含水量更有利于果实的形成和生长;(4)盛瓜期对水分的需求也达到了整个生育时期的顶峰,蒸腾速率达到3．83mm／d。90％～100％田间持水量的土壤水分条件可以获得最高产量,并实现水分利用与产量的高效统一;(5)生长后期保持70％～80％田间持水量的土壤含水量即可满足生长对水分的需求;(6)在开花期控制土壤水分为80％～90％田间持水量、初瓜期保持为80％～90％田间持水量、盛瓜期提高为90％～100％田间持水量和后期降至70％～80％田间持水量的土壤水分处理,不仅可获得最高产量,而且可以达到最大的水分利用效率,实现高产高效的统一。     

Indices of water deficit in susceptible and resistant cucumbers in response to infection by cucumber mosaic virus

Indices of water deficit were determined under conditions of non-limited water supply in cucumber mosaic virus (CMV)-infected seedlings of the susceptible cv. Bet Alpha. An increase in the concentration of soluble solids, decrease of water and osmotic potentials, and increase of proline concentration were found in the CMV-infected cotyledons. In the cv. Shimshon, which is resistant to CMV, virus infection caused only a slight change in the concentration of the soluble solids and in the osmotic potential; water potential and proline content were not affected. Concomitantly, infectivity of cotyledons by CMV was much lower in the tolerant cv. Shimshon than in the susceptible cv. Bet Alpha. The possible association of water deficit with virus-induced growth retardation is discussed.     

Involvement of nitric oxide in water stress-induced responses of cucumber roots

The effect of water deficit on nitric oxide (NO) generation was investigated in cucumber (Cucumis sativus cv. Dar) seedling roots using bio-imaging with an NO-selective fluorophor, diaminofluorescein-2-diacetate (DAF-2DA). Roots subjected to mild (5 and 10 h) water deficit showed slightly enhanced NO synthesis in cells of root tips and in the surrounding elongation zone. However, severe (17 h) stress resulted in an intensive NO production localized mainly in and above the elongation zone. Water stress-induced NO generation was blocked by a specific NO scavenger, 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (cPTIO) as well as nitrate reductase (NR) and partially by nitric oxide synthase (NOS-like) inhibitors.A pharmacological approach was used in order to verify the capacity of NO to induce adaptive responses of cucumber roots to water deficit. A positive correlation was found between NO donor (SNP 100 μM and GSNO 100 μM) pretreatment and plant hydration status, measured as relative water content (RWC) during progressive dehydration. At an early stage (5 h) of stress duration NO caused a periodical increase in lipoxygenase (LOX) activity, correlated with time-dependent enhancement of lipid peroxidation. Beginning from 10 h up to severe stress (17 h) exogenous NO was able to diminish LOX activity and alleviate water deficit-induced membrane permeability and lipid peroxidation, measured as TBARS content and visualised by histochemical staining in situ. Observed changes via NO were accompanied by a significant reduction of proline level, suggesting that the accumulation of this osmolyte might not be essential in water stress tolerance. Obtained results clearly indicate that NO augmentation is likely to help the plant at the initial stage of tissue dehydration to trigger efficient mechanisms, mitigating severe water deficit effects in roots of cucumber seedlings.     

水分亏缺和施氮对冬小麦生长及氮素吸收的影响

利用管栽试验研究了不同生育期,水分亏缺和施氮对冬小麦生长及氮素吸收的影响.结果表明：任何生育期水分亏缺都会影响冬小麦的株高、叶面积、干物质累积及对氮素的吸收.冬小麦对水分亏缺的敏感期为拔节期,其次为开花期、灌浆期和苗期.苗期干旱后复水对后期生长有显著的补偿效应,开花期适度干旱后复水对生物量形成和氮素吸收有一定的补偿作用,拔节期干旱对小麦的生长影响明显.相同氮肥处理下, 与不亏水处理比较, 苗期水分亏缺、拔节期水分亏缺、开花期水分亏缺、灌浆期水分亏缺的根系氮素积累量分别平均降低25.82%、55.68%、46.14%和16.34%,地上部氮素积累量分别平均降低33.37%、51.71%、27.01%和2.60%.在相同水分处理下冬小麦含氮量、累积吸收氮量都表现为高氮处理（0.3 g N·kg^-1FM）>中氮处理（0.2 g N·kg^-1FM）>低氮处理（0.1 g N·kg^-1FM）.水分逆境条件下施用氮肥对冬小麦植株生长和干物质累积及氮吸收具有明显的调节效应.     

Response of proteome and morphological structure to short‐term drought and subsequent recovery in Cucumis sativus leaves

Drought is the primary limitation to plant growth and yield in agricultural systems. Cucumber (Cucumis sativus) is one of the most important vegetables worldwide and has little tolerance for water deficit. To understand the drought stress response strategy of this plant, the responses of cucumber to short‐term drought and rewatering were determined in this study by morphological structure and proteomic analyses. The leaf relative water content was significantly decreased under drought, and the cell structure was altered, while rewatering obviously alleviated the symptoms of water shortage and cell damage. A total of 320 and 246 proteins exhibiting significant abundance changes in response to drought and recovery, respectively, were identified. Our proteome analysis showed that 63 co‐regulated proteins were shared between drought and rewatering, whereas most of the responsive proteins were unique. The proteome is adjusted through a sequence of regulatory processes including the biosynthesis of secondary metabolites and the glutathione metabolism pathway, which showed a high correlation between protein abundance profile and corresponding enzyme activity. Drought and recovery regulated different types of proteins, allowing plants to adapt to environmental stress or restore growth, respectively, which suggests that short‐term drought and recovery are almost fully uncoupled processes. As an important component of the antioxidant system in plants, glutathione metabolism may be one of the main strategies for regulating antioxidant capacity during drought recovery. Our results provide useful information for further analyses of drought adaptability in cucumber plants.     

Polyamines induce adaptive responses in water deficit stressed cucumber roots

The aim of this study was to investigate the effect of exogenous polyamines (PAs) on the membrane status and proline level in roots of water stressed cucumber (Cucumis sativus cv. Dar) seedlings. It was found that water shortage resulted in an increase of membrane injury, lipoxygenase (LOX) activity, lipid peroxidation and proline concentration in cucumber roots during progressive dehydration. PA pretreatment resulted in a distinct reduction of the injury index, and this effect was reflected by a lower stress-evoked LOX activity increase and lipid peroxide levels at the end of the stress period. In contrast, PA-supplied stressed roots displayed a higher proline accumulation. The presented results suggest that exogenous PAs are able to alleviate water deficit-induced membrane permeability and diminish LOX activity. Observed changes were accompanied by an accumulation of proline, suggesting that the accumulation of this osmolyte might be another possible mode of action for PAs to attain higher membrane stability, and in this way mitigate water deficit effects in roots of cucumber seedlings.     

消毒、伴生和微生物菌对连作基质性质及黄瓜生长发育的影响

以连续种植2茬的连作基质为对象,采用室内盆栽试验,设置连作基质太阳能消毒、热水消毒、多菌灵消毒、大蒜伴生栽培和施入微生物菌处理以及新基质对照,在种植黄瓜后观测基质理化性质、养分含量、酚类物质含量、相关酶活性的变化以及黄瓜结果期生长发育、光合作用和果实产量的变化,探究不同处理对连作基质栽培黄瓜生长发育影响的机制,以期在生产上为废旧基质重复利用提供新的思路和方法。结果表明:在连作基质栽培黄瓜后,太阳能消毒和热水消毒处理均能显著提高连作基质的pH,同时降低电导率;施入微生物菌处理的基质EC值、速效氮、速效磷、速效钾和总酚含量均显著低于连作基质,而其基质磷酸酶活性和过氧化氢酶活性显著高于连作基质。热水消毒还显著降低连作基质的总酚含量和复合态酚含量。黄瓜生长至结果期,太阳能消毒、热水消毒、多菌灵消毒、大蒜伴生栽培和施入微生物菌均显著增强黄瓜的根系活力和株高;其中热水消毒和施入微生物菌处理的产量增加最为显著,分别比连作基质栽培提高了16.56%和18.40%。可见,连作基质进行热水消毒处理和施入微生物菌处理均能降低基质盐分积累,减少总酚含量,进而显著提高黄瓜的根系活力和光合作用,从而增加产量。     

Deficit and excess of soil water impact on plant growth of Lotus tenuis by affecting nutrient uptake and arbuscular mycorrhizal symbiosis

The impact of deficit and excess of soil water on plant growth, morphological plant features, N and P plant nutrition, soil properties, Rhizobium nodulation and the symbiosis between arbuscular mycorrhizal (AM) fungi and Lotus tenuis Waldst. & Kit. were studied in a saline-sodic soil. Water excess treatment decreased root growth by 36% and increased shoot growth by 13% whereas water deficit treatment decreased both root and shoot growth (26 and 32%, respectively). Differences between stress conditions on shoot growth were due to the ability of L. tenuis to tolerate low oxygen concentration in the soil and the sufficiency of nutrients in soil to sustain shoot growth demands. Water excess treatment decreased pH, and increased available P and labile C in soil. Water deficit treatment decreased available P and also increased labile C. In general, N and P acquisition were affected more by water excess than water deficit. The number of nodules per gram of fresh roots only increased in water excess roots (97%). Under both stress conditions there was a significant proportion of roots colonized by AM fungi. Compared to control treatment, arbuscule formation decreased by 55 and 14% under water excess and water deficit, respectively. Vesicle formation increased 256% in water excess treatment and did not change under water deficit treatment. L. tenuis plants subjected to water deficit or excess treatments could grow, nodulated and maintained a symbiotic association with AM fungi by different strategies. Under water excess, L. tenuis plants decreased root growth and increased shoot growth to facilitate water elimination by transpiration. Under water deficit, L. tenuis plants decreased root growth but also shoot growth which in turn significant decreased the shoot/root ratio. In the present study, under water excess conditions AM fungi reduced nutrient transfer structures (arbuscules), the number of entry points and spore, and hyphal densities in soil, but increased resistance structures (vesicles). At water deficit, however, AM fungi reduced external hyphae and arbuscules to some extent, investing more in maintaining a similar proportion of vesicles in roots and spores in soil compared to control treatment.     

调亏灌溉对菘蓝水分利用及产量的影响

通过探究水分调亏对河西地区膜下滴灌菘蓝(Isatis indigotica)各项生理指标、产量和水分利用的影响,为菘蓝高效节水种植提供理论指导。于2016年在河西走廊中部张掖市民乐县益民灌溉试验站进行菘蓝水分调亏研究,在保持苗期和肉质根成熟期充分灌溉的情况下,在菘蓝营养生长期和肉质根生长期分别进行轻度、中度和重度的水分亏缺处理,并测定各项光合生理指标、产量和水分利用率。结果表明,营养生长期和肉质根生长期的中度与重度水分亏缺显著降低了菘蓝叶片净光合速率、叶面积指数、株高及主根长,并且随水分亏缺程度加重降幅增大;而轻度水分亏缺与对照组的差异不显著。营养生长期和肉质根生长期轻度水分亏缺处理的菘蓝产量与水分利用效率最高,分别达到8 239.56 kg·hm~(–2)和24.11kg·hm~(–2)·mm~(–1);其它水分亏缺处理组产量和水分利用效率均有所降低,与对照组之间差异显著(P0.05),重度水分亏缺处理各项指标均最低。因此,最优的菘蓝水分调控处理为营养生长期和肉质根生长期的轻度水分调亏,能够降低菘蓝耗水量,提高水分利用效率且其产量不会降低。     

不同膜下滴灌方式对设施黄瓜生理特性及水分利用效率的影响

为了探明黄瓜膜下分根交替滴灌的节水效果,为设施黄瓜节水灌溉提供理论依据和技术参数,以‘津优3号’黄瓜为试材,采用随机区组设计,以土壤田间持水量的65%为灌水下限,田间持水量的90%为灌水上限,研究了分根交替滴灌(APDI)、固定1/2根区滴灌(FPDI)和传统滴灌(CDI)3种灌溉模式对黄瓜生长、生理特性、产量与品质及水分利用效率的影响,结果表明:(1)随灌溉处理时间的延长,3种灌溉模式的单株叶面积和株高的差异越来越显著,而茎粗和叶片数差异不显著;(2)与传统滴灌相比,分根交替滴灌模式下黄瓜叶片净光合速率略有下降而蒸腾速率显著降低,水分利用效率显著提高;(3)分根交替滴灌处理下黄瓜可溶性蛋白、可溶性糖含量与传统滴灌相比差异不显著,Vc含量却显著增加;(4)分根交替滴灌模式下黄瓜产量比传统滴灌下降1.5%,而灌水量减少17%,水分利用效率提高18.6%,节水效果显著。综上所述,分根交替滴灌可以在保证设施黄瓜产量没有显著下降的前提下,改善品质和显著提高水分利用效率,可作为设施节水提质增效的一种灌溉模式,推广应用前景广阔。