不同外源寡糖对设施黄瓜生理特性及产量和品质影响差异

选择壳寡糖(GT)和复合寡糖(KP)为制剂处理,以大棚常规对照(CG)和清水对照(CK)为对比,分析黄瓜叶片叶绿素相对含量(SPAD)、叶绿素荧光参数和超微结构,根系表观形态和根系活力(RV),以及抗氧化酶和内源激素的变化,比较不同类型寡糖制剂对设施黄瓜生长及产量的调控作用。结果表明:与其他处理相比,KP处理能有效促进黄瓜叶片和根系生长,其SPAD、最大光化学量子产量(Fv/Fm)、光化学淬灭系数(qP)、非光化学淬灭系数(NPQ)和RV均显著增加4.15%~15.63%、6.49%~20.03%、33.33%~152.63%、10.37%~71.62%和8.51%~171.43%;超氧化物歧化酶(SOD)、过氧化物酶(POD)和过氧化氢酶(CAT)活性显著提升6.75%~91.49%、3.85%~97.62%和3.00%~28.15%;此外,促使黄瓜生育后期叶片生长素(IAA)含量显著提高5.43%以上,脱落酸(ABA)含量显著降低4.35%~18.63%;黄瓜产量和可溶性糖含量显著增加13.72%和11.52%以上。比较而言,GT处理对黄瓜根冠生长,内源激素和抗氧化酶活性的影响表现出不稳定性,仅坐果期叶片光合生理特性(SPAD、叶绿素荧光参数和叶片超微结构)和RV有所改善。相较于GT处理,KP处理在促进黄瓜根冠生长,调控抗氧化酶活性和内源激素平衡方面具有明显优势。结合相关性分析发现,黄瓜产量与NPQ、RV、SOD和POD活性呈极显著正相关(P<0.01),与Fv/Fm显著正相关(P<0.05);且SOD和POD活性均与ABA含量显著负相关(P<0.05)。综上,外源复合寡糖主要通过促进黄瓜根冠协调生长,维持生育后期高光合效率、根系活力和叶片功能结构稳定,调节抗氧化酶活性,促进生长激素和抑制生长激素间的平衡,保障生育后期细胞膜功能稳定,延缓叶片自然衰老,实现黄瓜的提质增产。

叶面喷施磷糖类制剂对冬小麦抗干热风影响的作用

2020-2021年小麦生长季,在干热风灾害发生频繁的黄淮海典型麦区进行大田试验,探索不同化学制剂对冬小麦抗干热风的调控作用,以便筛选出高效实用的制剂种类和施用时期。试验共设6个处理,以拔节期或开花期单次喷施磷胺和磷酯为制剂组处理(BA、BZ、HA和HZ处理),以拔节期和开花期均喷施自来水处理作为空白对照(CK),以两个时期均喷施磷酸二氢钾溶液处理作为制剂组对照(CKP)。考察干热风胁迫后小麦灌浆期间叶面积指数(LAI)、叶片荧光参数、籽粒淀粉合成关键酶活性和积累量、籽粒灌浆动态和产量构成因素的变化。试验期间小麦在花后24d和26d遭受了轻度干热风过程,与CKP和CK处理相比,BA处理促进穗粒数增加,理论产量显著提升8.11%和9.82%,且花后30d的LAI也显著增加47.67%;HZ处理更有助于提高千粒重,理论产量增幅为10.03%和11.78%,较其他处理增加旗叶最大光化学效率(Fv/Fm)和光化学淬灭(qP);HA处理能稳定降低非光化学淬灭(NPQ)。遭遇第一次干热风过程后,即花后26d观测结果显示,与CKP处理相比,BZ处理的ADP-葡萄糖焦磷酸化酶(AGPase)活性显著升高19.26%,而HZ处理的束缚态淀粉合成酶(GBSS)和可溶性淀粉合成酶(SSS)活性则分别显著增加2.11%和15.92%。遭遇第二次干热风过程后,即花后30d观测结果显示,HZ处理的直链淀粉和总淀粉含量较CKP处理分别显著提升9.75%和3.74%,在各处理中增幅最高。Richards拟合结果显示,与CKP处理相比,喷施磷糖类制剂处理通过延迟最大灌浆速率出现的时间,以及提高灌浆速率缓解干热风对籽粒危害,其中HA处理的弱势和强势籽粒的最大灌浆速率提升22.71%和18.30%,平均灌浆速率提升了19.27%和12.72%。因此,磷糖类制剂的种类和喷施时期是影响遭受干热风胁迫之后小麦叶片和籽粒生理差异的主要因素,建议磷胺和磷酯制剂喷施的最佳时期分别为拔节期和开花期;综合认为开花期喷施磷酯制剂处理对小麦抗干热风影响的调控效果最优。

干热风对冬小麦不同穗粒位粒重的影响效应

利用自主研制的可移动式干热风发生模拟装置,对耐高温小麦品种济麦22于花后13d(灌浆中期M)和23d(灌浆后期L)进行连续两天的干热风胁迫,设置重度干热风(S)和轻度干热风(M)2个胁迫水平,以明确不同时期和不同等级的干热风灾害对小麦小穗位和粒位粒重分布特征的影响,及其与干热风胁迫程度的关系,为干热风灾害防控提供理论依据。结果表明:不同处理主茎穗和分蘖穗小穗位和粒位粒重均呈现先升后降的二次曲线变化。干热风胁迫会引起小麦穗部小穗位和粒位粒重的降低,表现为灌浆中期干热风胁迫引起小麦穗下部和上部穗粒位总粒重显著降低,对小麦粒位粒重的危害呈现第3粒位(G3)>第1粒位(G1)>第2粒位(G2);灌浆后期胁迫则主要危害小麦穗下部和中部,对小麦粒位粒重的危害表现为G3>G2>G1。初步分析认为,在本模拟试验条件下,灌浆中期干热风引起小麦分蘖穗粒重显著降低,灌浆后期对主茎穗粒重影响更大;灌浆中期和后期干热风胁迫下,小麦G3位粒重减小最为明显。灌浆中期干热风胁迫对小麦粒重的影响大于后期,重度干热风胁迫大于轻度干热风。

血友病A阴囊假肿瘤1例

血友病性假肿瘤(Hemophilicpseudotumor)又称血友病性血囊肿是血友病罕见并发症,由Starker 1918年首先报道。笔者诊治阴囊血友病性假肿瘤一例,现报道于下。1 临床资料1.1 男患,50岁,主诉'确诊血友病A 45年,左侧阴囊肿物15年'入院。患者15年前无意中发现左侧阴囊有一肿物,约鹌鹑蛋大小,不伴疼痛,不伴阴囊红肿胀痛,于当地医院就诊,行阴囊彩超检查提示:阴囊肿物,未系统用凝血因子FⅧ替代治疗.

地膜覆盖对黄土高原地区两种种植密度下玉米叶片代谢组的影响

在黄土高原地区,对覆膜条件下玉米叶片代谢组变化规律的研究是探索覆膜增产生理机制的重要方面。本研究采用气相色谱-四极杆-飞行时间质谱(GC-QTOF)技术,对2种覆膜方式(塑料膜覆盖和不覆盖)、2个密度(7.5×10^(4)株hm^(–2)和10.5×10^(4)株hm^(–2))和2个品种(郑单958和先玉335)的吐丝期玉米叶片进行了代谢组学分析。从差异代谢物个数来看,先玉335对覆膜的响应大于郑单958,较高的种植密度缩小了覆膜与无覆膜处理间叶片代谢的差异。主成分分析表明,覆膜处理和品种均对代谢物组成产生了重大影响。覆膜引起的代谢谱差异主要是由柠檬酸等有机酸和氨基酸造成的;品种引起的代谢组差异主要是由辛酸等烷酸和酚类造成的。相关分析表明,叶绿醇、白藜芦醇、葡萄糖-6-磷酸与玉米籽粒产量呈显著正相关关系,而甘油与之呈显著负相关关系。在覆膜条件下,与呼吸作用及清除光呼吸产物相关的缬氨酸、异亮氨酸及蛋氨酸,与三羧酸循环相关的异柠檬酸以及可减轻光抑制的蛋氨酸、N-乙酰基天冬氨酸等代谢物的水平整体呈升高趋势。以上结果表明,在覆膜条件下,消除光呼吸产物及减少光抑制的相关代谢物的积累是叶片净光合速率提高的代谢基础;抗氧化及能量代谢相关的代谢物在提高产量的过程中发挥了重要作用。

轻度干热风条件下喷施复合寡糖提高冬小麦叶片生理活性和籽粒淀粉合成关键酶活性

【目的】植物刺激素寡糖具有提高作物抗逆能力的功效。研究复合寡糖制剂(KROPICO)提高冬小麦抗干热风的能力,为冬小麦干热风灾害化学防控提供技术支撑。【方法】在干热风灾害发生频繁的典型区域—河北省衡水市进行大田试验。试验设置3个寡糖喷施处理,即拔节期喷施1次(BT)、开花期喷施1次(HT)、拔节期和开花期各喷施1次(BTHT);另设拔节期和开花期分别各喷施1次清水(CK)和KH_(2)PO_(4)(CKP),共5个处理。开花30天时测定了旗叶叶绿素相对含量(SPAD)、离体叶片失水速率(RWL)、叶面积指数(LAI)和淀粉合成关键酶活性,调查了产量和产量构成因素。【结果】试验期间小麦经历了两次轻度干热风胁迫。与CK相比,BTHT处理的小麦旗叶SPAD和LAI值分别显著增加了12.36%和77.78%;BT与BTHT处理能分别显著降低第一次干热风后旗叶叶片失水速率(RWL)15.08%和21.73%,但在第二次干热风后各处理间无明显差异;HT处理的ADP-葡萄糖焦磷酸化酶(AGPase)活性显著提高了16.91%;BTHT处理的束缚态淀粉合成酶(GBSS)和可溶性淀粉合成酶(SSS)活性分别显著提高了12.28%和12.89%。与CKP相比,BTHT和HT处理的LAI显著增加了49.53%~50.47%,BTHT处理的GBSS和SSS活性分别显著增加了6.30%和9.39%,HT处理的AGPase活性提高了14.41%。与CK相比,除HT处理外,其它制剂处理的小麦产量显著增加了6.69%以上,BTHT处理的小麦千粒重比CK也显著增加了5.09%。两次干热风胁迫下,与其他3个制剂处理相比,BTHT处理显著提升了叶片生理特性、籽粒蔗糖—淀粉代谢途径关键酶活性和冬小麦产量。结合相关分析证实,GBSS和SSS活性与产量呈显著正相关(P<0.05),同时,SPAD、LAI和淀粉合成相关酶活性均与产量正相关,RWL则与产量负相关。【结论】拔节期和开花期两次喷施复合寡糖处理(BTHT)可以提高冬小麦旗叶叶绿素和水分含量,提高淀粉合成酶活性,协同提高小麦灌浆后期旗叶生长状况和淀粉积累量,增加粒重,促使轻度干热风胁迫下冬小麦稳产甚至增产。

寡糖对土壤微生物多样性及群落结构的调节作用

土壤微生物种群类型,对土壤质量和作物生长具有重要影响,研究寡糖对土壤微生物种群的影响特征,有助于正确、高效及安全使用寡糖。本研究利用人工气候室进行土壤培养,土壤施加50mg·L^(−1)的壳寡糖(CSOS)和纤维寡糖(COS)溶液,以清水(CK)为对照处理,培养6d后取样,利用高通量测序技术,分析土壤微生物群落结构组成及多样性分布特征。结果表明:壳寡糖(CSOS)和纤维寡糖(COS)处理均显著改变细菌、真菌的群落结构,提高细菌的物种观测数。变形菌门(Proteobacteria)、酸杆菌门(Acidobacteria)、放线菌门(Actinobacteria)、绿弯菌门(Chloroflexi)、芽单胞菌门(Gemmatimonadetes)和拟杆菌门(Bacteroidetes)为优势细菌门,子囊菌门(Ascomycota)、担子菌门(Basidiomycota)和被孢霉门(Mortierellomycota)为优势真菌门。通过组间群落组成比较分析可知,壳寡糖(CSOS)和纤维寡糖(COS)处理均不同程度降低酸杆菌门(Acidobacteria)的相对丰度,增加变形菌门(Proteobacteria)、放线菌门(Actinobacteria)、芽单胞菌门(Gemmatimonadetes)、壶菌门(Chytridiomycota)以及有益菌属溶杆菌属(Lysobacter)、硝化螺旋菌属(Nitrospira)、Haliangium、芽球菌属(Blastococcus)和链霉菌属(Streptomyces)的相对丰度,但与纤维寡糖(COS)相比,壳寡糖(CSOS)处理微生物群落组成的变化幅度更大。此外,壳寡糖(CSOS)和纤维寡糖(COS)处理在调节土壤微生物群落结构上存在一定差异。其中,壳寡糖(CSOS)处理有益菌属Talaromyces的相对丰度增加195%,纤维寡糖(COS)处理有益菌属假单胞菌属(Pseudomonas)的相对丰度增加215%。综上,壳寡糖和纤维寡糖处理均能优化土壤微生物群落的结构组成,其调控差异性有助于理解不同寡糖的调控机制,推动寡糖的应用与推广。

Influence of High Temperature Stress on Net Photosynthesis, Dry Matter Partitioning and Rice Grain Yield at Flowering and Grain Filling Stages

Climate change is recognized to increase the frequency and severity of extreme temperature events. At flowering and grain filling stages, risk of high temperature stress （HTS） on rice might increase, and lead to declining grain yields. A regulated cabinet experiment was carried out to investigate effects of high temperature stress on rice growth at flowering and grain- filling stages. Results showed that no obvious decrease pattern in net photosynthesis appeared along with the temperature rising, but the dry matter allocation in leaf, leaf sheath, culm, and panicle all changed. Dry weight of panicle decreased, and ratio of straw to total above ground crop dry weight increased 6-34% from CK, which might have great effects on carbon cycling and green house gas emission. Grain yield decreased significantly across all treatments on average from 15 to 73%. Occurrence of HTS at flowering stage showed more serious influence on grain yield than at grain filling stage. High temperature stress showed negative effects on harvest index. It might be helpful to provide valuable information for crop simulation models to capture the effects of high temperature stress on rice, and evaluate the high temperature risk.

Effects of different irrigation methods on micro-environments and root distribution in winter wheat fields

The irrigation method used in winter wheat fields affects micro-environment factors, such as relative humidity（RH） within canopy, soil temperature, topsoil bulk density, soil matric potential, and soil nutrients, and these changes may affect plant root growth.An experiment was carried out to explore the effects of irrigation method on micro-environments and root distribution in a winter wheat field in the 2007–2008 and 2008–2009 growing seasons.The results showed that border irrigation（BI）, sprinkler irrigation（SI）, and surface drip irrigation（SDI） had no significant effects on soil temperature.Topsoil bulk density, RH within the canopy, soil available N distribution, and soil matric potential were significantly affected by the three treatments.The change in soil matric potential was the key reason for the altered root profile distribution patterns.Additionally, more fine roots were produced in the BI treatment when soil water content was low and topsoil bulk density was high.Root growth was most stimulated in the top soil layers and inhibited in the deep layers in the SDI treatment, followed by SI and BI, which was due to the different water application frequencies.As a result, the root profile distribution differed, depending on the irrigation method used.The root distribution pattern changes could be described by the power level variation in the exponential function.A good knowledge of root distribution patterns is important when attempting to model water and nutrient movements and when studying soil-plant interactions.

Effects of different concentrations of super-absorbent polymers on soil structure and hydro-physical properties following continuous wetting and drying cycles

Super-absorbent polymers(SAPs)are widely used chemical water-saving materials,which play an active role in the accumulation of soil water and the improvement of soil structure.Little is known about their performance with repeated usage or about factors influencing their efficiency under alternate wetting and drying cycles.In this study,various concentrations of SAP(0,0.1,0.2 and 0.3%)in soil following three continuous wetting and drying cycles(T1,T2 and T3),were studied to determine effects on soil structure stability and hydro-physical properties.The results indicated that the SAP improved soil water supply capacity under conditions of mild drought(T2)and sufficient irrigation(T3)at concentrations of 0.2 and 0.3%,but a reduction was observed under severe drought conditions(T1),which was negatively correlated with the SAP concentration.The physical adsorption of the SAP by soil and the chemical connection between the SAP and soil mineral colloids as Si-O-Si bonds,-OH bonds and different crystalline silica were the important factors that directly lead to the reduction of water retention capacities of the SAP with alternating wet and dry conditions.Compared with the control,the soil liquid phase ratios of the SAP treatments were increased by8.8-202.7%in the T1 and T2 cycles,which would have led to a decrease in the soil air phase ratios.After repeated wetting and drying cycles,the SAP treatments increased the amount of>0.25 mm soil aggregates and the contents of water-stable macro-aggregate(R_(0.25)),and decreased the amount of<0.053 mm soil aggregates,especially with higher concentrations of the SAP.Increases in mean weight diameter(MWD)and geometric mean diameter(GMD),and declines in fractal dimension(D)and unstable aggregates index(E_(LT))were all observed with the SAP treatments,which indicated an improvement in soil stability and structure.It was concluded that the distribution and stability of soil aggregates and soil water supply capacity was closely related to SAP concentration,soil moisture condition and the interaction between the SAP and soil particles.

东北稻田有机肥替代部分氮肥措施下土壤酶群分析

针对东北稻田长期过度依赖化肥的问题,通过田间定位试验研究有机肥替代部分氮肥对土壤酶活性及酶群生态指数的影响,以期为氮肥减施技术途径提供理论依据。试验设常规施肥(对照,CF)和有机肥替代(MS)两个处理,采用微孔板荧光法测定7种土壤碳、氮、磷转化有关酶活性。结果表明:有机肥替代处理较对照显著增加了有机碳(SOC)和速效磷(AP)含量、团聚体稳定性以及土壤C∶N;显著提高了与碳转化有关的α-葡糖苷酶(AG)、β-葡萄糖苷酶(BG)、纤维二糖酶(CBH)、木糖苷酶(XYL)活性和氮转化有关的乙酰氨基葡萄糖苷酶(NAG)活性。酶群生态指数分析结果显示,有机肥替代降低了BG/(NAG+LAP)(LAP:亮氨酸氨基肽酶),表明土壤氮素有效性的相对不足;提高了NAG/LAP,说明有机肥替代促进底物的分解可能相对以真菌通道为主;酶活性均匀度指数没有明显变化,说明其在指示微生物多样性方面可能存在一定的局限性。本研究表明,东北稻田有机肥替代部分化肥在维持水稻高产的同时,有利于改善土壤理化性质和提高土壤酶活性,是实现氮肥减施和培肥地力的有效技术措施。

不同类型土壤水分对保水剂结构和形态的影响效应

为明确不同类型的土壤水分影响下,保水剂与土壤之间的水分交换作用,用土柱实验的方法,模拟地面蒸发和土体脱湿过程,用全反射红外光谱和环境扫描电镜技术观测,比较砂土和壤土连续的失水-复水后保水剂的凝胶质量、价键结构、形貌特征等的变化。结果表明:连续三次灌水后,施于砂土中的保水剂凝胶质量显著大于壤土的保水剂;经历干湿交替过程后,土壤中的Si-O-Si键、-OH、蒙脱石矿物以及无定形氧化硅等会进入保水剂三维网状结构中,致使保水剂的膜结构表面变得不均匀、甚至破裂。初步认为土壤黏粒矿物与保水剂发生不同程度的化学反应,应该是导致保水剂随时间延长吸持水能力降低的主要原因之一。