苏芸金杆菌感染粘虫后中肠组织学病变的研究

本文描述了Bacillus thuringiensis HD-1纯晶体感染粘虫Mythimna separata 5龄初幼虫后,其中肠肠壁细胞的超微结构变化.电镜观察表明:首先线粒体,发生病变,随后,细胞顶部肿胀、胞质电子密度下降,顶部胞质之下的各种细胞器均受损伤.随着病变加重,柱状细胞基膜内褶及杯状细胞质突起,这两个富含线粒体的区域发生病变最为明显.最终,肠壁细胞解体从基膜脱落.     

Ca~(2 )对叶绿体中超氧物自由基产生以及由ACC形成乙烯的影响

高浓度Ca~(2 )(0.1 mol/L)使叶绿体产生O_2~ 的能力下降,旋转相关时间(τ_c)增大34.3％,即膜的流动性降低,并抑制ACC形成乙烯;衰老时细胞内的Ca~(2 )作用却与此相反;O_2~ 的生成与乙烯的产量成正相关(r=0.941)。EGTA,吩噻嗪和W_7等加入到叶绿体反应体系中,可使O_2~ 的产量下降,ACC形成乙烯减少;相反,亚油酸作为Ca~(2 )载体,却使之明显升高,但亚油酸本身产生乙烯的量比ACC少得多。因此推测:高浓度Ca~(2 )可能影响叶绿体膜的状态,从而影响EFE的构象或者减少O_2~ 的生成,抑制ACC的转化,衰老时细胞内的Ca~(2 )可启动钙信使系统,使O_2~ 的产量升高,而其中膜脂过氧化是衰老的中心环节,因此O_2~ 的升高可能是诱发衰老启动的重要因素。     

中国狭长蝽属初记(半翅目:长蝽科:杆长蝽亚科)

狭长蝽属(Dimorphopterus Stal)为杆长蝽亚科(Blissinae)中较大的一属。身体常成两侧平行的小杆状,多数尚较粗壮,亦有甚狭长者,体黑,被平伏或半直立毛,翅革片白色而有深色斑,常出现短翅型个体。多生活于禾本科植物上,北方地区为害高粱的“高粱长蝽”即属此类。 本属的概念和范围几经变动:Stal 1872年建立此属时,用身体较狭,触角短于头、胸     

基于染色体置换系的普通野生稻耐盐性QTL定位

本研究分别利用SSR标记、InDel标记以及简化基因组测序技术对一套以普通野生稻为供体亲本,9311为受体亲本的染色体置换系进行基因型鉴定,并通过对其不同生育期的耐盐性鉴定,共发掘2个与发芽期耐盐相关的QTL,13个与苗期耐盐性相关的QTL。其中与苗期存活率相关的QTL qSSR5.1、苗期耐盐等级相关的QTL qSSG5.1均被定位于同一位点,该位点对苗期存活率、苗期耐盐等级均具有增效作用,贡献率分别为6.36%、8.13%。在此QTL内包含与非生物胁迫相关基因OsDi19-1。经序列比对发现,OsDi19-1启动子区域在两亲本间存在较大差异,且受到盐胁迫时该基因表达量上升。同时,鉴定出水稻芽期耐盐的优异种质资源CSSL72、苗期耐盐的优异种质资源CSSL23、CSSL153,为水稻育种中耐盐性的改良提供了新的种质资源。     

灵芝线粒体及其对菌丝生长、主要活性成分影响的分析

线粒体是为细胞提供能量（ATP）的细胞器,携带着自己的DNA——mtDNA,已有多种灵芝属菌株的线粒体基因组相继报道,但对于种内的线粒体基因组的分析较少,对核相同、线粒体不同的菌株间差异的研究也鲜有报道。本研究对两株灵芝线粒体基因组进行组装注释,根据差异片段构建分子标记进行种间分类。结果显示：两株灵芝线粒体基因组大小分别为49 233bp、61 563bp的闭环结构,含有15个常见蛋白编码基因,rRNA大小亚基基因及26个携带氨基酸的tRNA基因,其差异区段主要为内含子序列、大亚基及基因间区。根据cob、cox2基因序列能够进行灵芝种间区分,用于灵芝种间鉴定。本研究还根据灵芝119、灵芝无孢的单核菌株构建同核异质体（TY-119、TY-W）,分析线粒体对菌落形态、菌丝生长速度及多糖、三萜成分的影响,结果显示：同核异质体TY-W与TY-119菌落形态上有一定差异,同核异质体TY-W菌丝生长速度为4.77mm/d,是TY-119菌丝生长速度4.50mm/d的1.06倍,同核异质体TY-119菌丝、子实体阶段多糖含量分别为4.45mg/g、12.14mg/g是TY-W菌丝体多糖含量（3.23mg/g）的1.38倍、子实体多糖含量（10.24mg/g）的1.19倍;同核异质体TY-W菌丝、子实体阶段的三萜含量分别为6.82mg/g、11.45mg/g是同核异质体TY-119菌丝体三萜含量（9.26mg/g）的0.74倍,子实体三萜含量（9.10mg/g）的1.26倍。利用高效液相色谱分析同核异质体中灵芝酸含量显示同核异质体TY-W灵芝酸A、灵芝酸E、灵芝酸F含量分别为3.77μg/mL、14.29μg/mL、12.91μg/mL;是TY-119灵芝酸A含量（2.59μg/mL）的1.46倍、灵芝酸E含量（13.65μg/mL）的1.17倍、灵芝酸F含量（12.72μg/mL）的1.06倍。对同核异质体菌丝、子实体阶段多糖、三萜合成通路关键基因（pgm、ugp、gls、hmgs、hmgr、mvd、fps、sqs）表达量进行检测,显示两菌株间多数基因具有显著性差异。结果表明线粒体的不同会影响灵芝菌落形态、菌丝生长速度及多糖、三萜的含量,有助于我们进一步研究线粒体基因组。     

桔黄赛多孢菌胞外胰蛋白酶的酶学特性

桔黄赛多孢菌Scedosporium aurantiacum是慢性肺病患者的常见呼吸道定植菌,在免疫缺陷人群中可引起侵袭性感染,致死率高,但由于致病机理不明,目前仍然缺乏有效的防控手段。我们在前期研究中,通过差异蛋白组学及酶工程技术发现分泌胰蛋白酶是桔黄赛多孢菌的潜在毒力因子,目前对这种蛋白酶的遗传信息、结构及致病机制并不清楚。本研究用Superdex S-200分子筛和DEAE-Sepharose离子交换两种填料将这种蛋白酶分离纯化出来,通过酶谱验证了纯化效果。进一步研究发现,这种胰蛋白酶对bFSR、bLSTR和bEKK 3种底物的水解性能最佳,对zFR和bzLR的水解性能最差。酶解最快的反应所对应的K_m为6.09μmol/L,V_max为13.01μmol/L/s,K_cat为23.65/s;酶解最慢的反应所对应的K_m为29.94μmol/L,V_max为11.35μmol/L/s,K_cat为20.63/s。研究结果对于填补赛多孢菌毒力因子研究的空白、针对毒力因子开发新型的抗真菌药物和治疗方法都具有重要意义。     

FDPS promotes glioma growth and macrophage recruitment by regulating CCL20 via Wnt/β‐catenin signalling pathway

Glioma is one of the most lethal tumours and common malignant in the central nervous system (CNS), which exhibits diffuse invasion and aggressive growth. Several studies have reported the association of FDPS to tumour development and progression. However, the role of FDPS in progression of glioma and macrophage recruitment is not well‐elucidated. In the current study, a remarkable enhancement in FDPS level was observed in glioma tissues and associated with poor prognosis, contributed to tumour growth. FDPS was correlated with macrophage infiltration in glioma and pharmacological deletion of macrophages largely abrogated the oncogenic functions of FDPS in glioma. Mechanistically, FDPS activated Wnt/β‐catenin signalling pathway and ultimately facilitates macrophage infiltration by inducing CCL20 expression. In conclusion, overexpressed FDPS exhibits an immunomodulatory role in glioma. Therefore, targeting FDPS may be an effective therapeutic strategy for glioma.     

Association between METTL3 gene polymorphisms and neuroblastoma susceptibility: A nine‐centre case‐control study

Neuroblastoma ranks as the most commonly seen and deadly solid tumour in infancy. The aberrant activity of m⁶A‐RNA methyltransferase METTL3 is involved in human cancers. Therefore, functional genetic variants in the METTL3 gene may contribute to neuroblastoma risk. In the current nine‐centre case‐control study, we aimed to analyse the association between the METTL3 gene single nucleotide polymorphisms (SNPs) and neuroblastoma susceptibility. We genotyped four METTL3 gene SNPs (rs1061026 T>G, rs1061027 C>A, rs1139130 A>G, and rs1263801 G>C) in 968 neuroblastoma patients and 1814 controls in China. We found significant associations between these SNPs and neuroblastoma risk in neither single‐locus nor combined analyses. Interestingly, in the stratified analysis, we observed a significant risk association with rs1061027 AA in subgroups of children ≤ 18 months of age (adjusted OR = 1.87, 95% CI = 1.03‐3.41, P = .040) and females (adjusted OR = 1.86, 95% CI = 1.07‐3.24, P = .028). Overall, we identified a significant association between METTL3 gene rs1061027 C>A polymorphism and neuroblastoma risk in children ≤18 months of age and females. Our findings provide novel insights into the genetic determinants of neuroblastoma.     

Boosting Polysulfide Redox Kinetics by Graphene‐Supported Ni Nanoparticles with Carbon Coating

Lithium–sulfur batteries have attracted extensive attention because of their high energy density. However, their application is still impeded by the inherent sluggish kinetics and solubility of intermediate products (i.e., polysulfides) of the sulfur cathode. Herein, graphene‐supported Ni nanoparticles with a carbon coating are fabricated by directly carbonizing a metal–organic framework/graphene oxide composite, which is then dispersed on a commercial glass fiber membrane to form a separator with electrocatalytic activity. In situ analysis and electrochemical investigation demonstrate that this modified separator can effectively suppress the shuttle effect and regulate the catalytic conversion of intercepted polysulfides, which is also confirmed by density functional theory calculations. It is found that Ni–C sites can chemically interact with polysulfides and stabilize the radical S₃^?? through Ni? S bonds to enable fast dynamic equilibrium with S₆^2?, while Ni nanoparticles reduce the oxidation barrier of Li₂S and accelerate ion/electron transport. As a result, the corresponding lithium–sulfur battery shows a high cycle stability (88% capacity retention over 100 cycles) even with a high sulfur mass loading of 8 mg cm^?2 and lean electrolyte (6.25 µ L mg^?1). Surprisingly, benefitting from the improved kinetics, the battery can work well at ?50 °C, which is rarely achieved by conventional Li–S batteries.     

Conductive Hole‐Selective Passivating Contacts for Crystalline Silicon Solar Cells

Defect state passivation and conductivity of materials are always in opposition; thus, it is unlikely for one material to possess both excellent carrier transport and defect state passivation simultaneously. As a result, the use of partial passivation and local contact strategies are required for silicon solar cells, which leads to fabrication processes with technical complexities. Thus, one material that possesses both a good passivation and conductivity is highly desirable in silicon photovoltaic (PV) cells. In this work, a passivation‐conductivity phase‐like diagram is presented and a conductive‐passivating‐carrier‐selective contact is achieved using PEDOT:Nafion composite thin films. A power conversion efficiency of 18.8% is reported for an industrial multicrystalline silicon solar cell with a back PEDOT:Nafion contact, demonstrating a solution‐processed organic passivating contact concept. This concept has the potential advantages of omitting the use of conventional dielectric passivation materials deposited by costly high‐vacuum equipment, energy‐intensive high‐temperature processes, and complex laser opening steps. This work also contributes an effective back‐surface field scheme and a new hole‐selective contact for p‐type and n‐type silicon solar cells, respectively, both for research purposes and as a low‐cost surface engineering strategy for future Si‐based PV technologies.