丙型肝炎病毒感染的体外培养细胞的抗原表达

建立丙型肝炎病毒（HCV）体外感染细胞模型,观察其感染细胞的HCV抗原表达,用抗HCV抗体和HCVRNA阳性及阴性血清感染MOLT-4细胞,制备细胞片进行免疫酶染色。结果显示HCV感染MOLT-4细胞4天和阴性对照HCV抗原均为阴性;感染后7天胞浆内可见HCV抗原阳性免疫反应产物;15天阳性细胞达到高峰,43天仍可见少量阳性细胞。结果表明HCV体外感染MOLT-4细胞胞浆内观察到HCV抗原表达。     

常发性害虫白背飞虱与潜在性害虫电光叶蝉的种内竞争效应比较(英文)

实验室研究表明若虫期拥挤显著延长了白背飞虱Sogatellafurcifera的发育历期 ,但电光叶蝉Reciliadorsalis的历期受影响不显著 ;白背飞虱的若虫存活率、两种的性比、产卵前期和繁殖力不显著。若虫期高密度下的白背飞虱短翅率、电光叶蝉的若虫存活率显著降低。繁殖力和成虫寿命在成虫期也拥挤的条件下将进一步受到影响。特定年龄生命表分析表明拥挤对白背飞虱的综合影响程度比对电光叶蝉小。常发性、潜在性昆虫对若虫期、成虫期拥挤的反应并不总是如文献中所言表现为繁殖力的差异 ,本研究表明内禀增长力可较完整地描绘这种反应。白背飞虱作为一常发性昆虫与潜在性昆虫电光叶蝉的生态学特性的差异表现在 :未成熟期短、繁殖力和产出卵速率均高 ,因而内禀增长力也高。     

柯萨奇病毒B组3型VP1基因的体外表达鉴定

将克隆的CVB3 VP1基因亚克隆至真核表达载体pCEP4构建CVB3 VP1的真核表达质粒pCEP4-CVB3VP1.pCEP4-CVB3VP1转染HeLa细胞,蛋白印迹试验证明该表达体系可以在体外表达能为CVB3中和抗体识别的VP1蛋白.本研究为CVB基因疫苗的研究提供了实验依据.     

复制缺陷型腺病毒载体介导hVEGF cDNA在C2C12和NIH3T3细胞中的表达

 为提高hVEGFcDNA在心肌中的表达 ,降低在其它组织中表达可能产生的不良反应 ,用PCR法得到人磷酸肌酸激酶 (MCK)增强子和CMV核心启动子 .利用克隆技术构建了含双拷贝MCK增强子 (m)和人巨细胞病毒 (CMV)核心启动子 (c)的嵌合启动子 (mmc) ,构建真核表达质粒pK3 mmcLacZ ,制备受mmc嵌合启动子调控的重组腺病毒Ad mmcVEGF .经X gal染色、β 半乳糖苷酶定量分析、RT PCR、hVEGFELISA定量分析、VEGF活性测定等研究表明 ,mmc启动VEGF基因在小鼠肌细胞C2C12和NIH3T3细胞中能有效表达且具有一定的肌细胞特异表达功能     

抗HBcAg人源性单链抗体细胞内表达及其抗病毒复制的实验研究

应用人源性抗HBcAg单链抗体细胞内表达技术,探讨抗HBV复制基因治疗的应用价值.应用噬菌体展示和基因重组技术,从HBV感染的外周血淋巴细胞克隆了人源性抗HBcAg单链抗体,并重组至逆转录病毒载体.以人肝癌细胞smmc-7721和PLC/PRF/5为靶细胞进行基因共转染,分别测定实验组细胞上清中的HBsAg和HBeAg,与对照组做比较,观察抗HBcAg单链抗体细胞内表达的抗病毒治疗作用.结果显示,在急性HBV感染的细胞株中,抑制病毒复制效率为49%～61%,在慢性病毒感染细胞,抑制率为41%～54%.实验结果表明,应用单链抗体细胞内表达技术,在抗病毒治疗研究中具有潜在的应用价值.应对HBV的4个开放阅读框架编码产物进行全面的对比研究,以发现抑制效率高、实用价值大的靶基因.     

Static and dynamic light scattering approach to the hydration of hemoglobin and its supertetramers in the presence of osmolites.

We used static and dynamic light scattering for comparing the mass (MW) and hydrodynamic radius (R(h)) of several hemoglobin systems, namely human hemoglobin, bovine hemoglobin, human hemoglobin cross-linked with a sebacyl residue, and bovine hemoglobin cross-linked with an adipoyl residue. We measured the MW and R(h) of these systems in 0.1M phosphate buffer at pH 7.0 in the absence and in the presence of either betaine or glycerol up to 1.7 molal concentrations. The 90 degrees scattering was measured with a photon counting machine equipped with a diode laser at 783 nm. The Rayleigh ratio [R(theta)] of the instrument was estimated using R(theta) = 7.19E-6 cm(-1) for toluene at 783 nm. The refractive index increment of hemoglobin solutions was measured using a laser beam at 750 nm. We estimated a value dn/dc = 0.210 cm3/g in the absence and dn/dc = 0.170 in the presence of 1.7 molal osmolites. For all systems both in liganded and unliganded form, the static light scattering data showed a 16% mass increase with increasing concentration of osmolites. The hydrodynamic radii of all investigated systems in the presence and absence of osmolites were close to 3.17 nm. Assuming a partial specific volume nu = 0.739 for hemoglobin, and using spherical geometry, the estimated average hydration volume of hemoglobin was 32.6 L/mole in the absence of osmolites. It decreased to 23.5 L/mole in the presence of 1.7 molal osmolites. Assuming that the density of water in the hydration volume is D = 1.0 g/cm3, the hydration of Hb was 0.51 gH2O/gHb, with a surface density of 0.20 molH2O/A2. The hydration decreased to 0.33 gH2O/gHb and 0.14 molH2O/A2 in the presence of 1.7 molal osmolites. The decreased hydration was compensated by the increased mass (i.e., decreased surface area per unit volume) so that the thickness of the water shell around these proteins remained close to a single layer of water molecules. These findings indicate that the combination of static and dynamic light scattering offer unique means for investigating the relevance of water activity on the structure and function of biological macromolecules. In the case of hemoglobin, the data suggest that the decreased oxygen affinity in the presence of osmolites reported by Colombo et al. (M. F. Colombo, D. C. Rau, and V. A. Parsegian Science, 1992, Vol. 256, pp. 655-659), as due to ligand linked water binding on hemoglobin surface, is part of a complex phenomenon involving the hydration shell of hemoglobin and the formation of low affinity supertetrameric molecules.     

Identification of a human immunodominant B-cell epitope within the GRA1 antigen of Toxoplasma gondii by phage display of cDNA libraries

Excreted secreted antigens of the protozoan parasite Toxoplasma gondii play a key role in stimulating the host immune system during acute and chronic infection. With the aim of identifying the immunodominant epitopes of T. gondii antigens involved in the human B-cell response against the parasite, we employed a novel immunological approach. A library of cDNA fragments from T. gondii tachyzoites was displayed as fusion proteins to the amino-terminus of lambda bacteriophage capsid protein D. The lambdaD-tachyzoite library was then affinity-selected by using a panel of sera of pregnant women, all infected with the parasite. Some of the clones identified through this procedure matched the sequence of the dense granule GRA1 protein (p24), allowing us to identify its antigenic regions. In particular, the analysis of human antibody response against the recombinant GRA1 antigen fragments revealed the existence of an immunodominant epitope (epi-24 peptide).     

Stay‐green: A consequence of the balance between supply and demand for nitrogen during grain filling?

Retention of green leaf area in grain sorghum under post‐anthesis drought, known as stay‐green, is associated with greater biomass production, lodging resistance and yield. The stay‐green phenomenon can be examined at a cell, leaf, or whole plant level. At a cell level, the retention of chloroplast proteins such as LHCP2, OEC33 and Rubisco until late in senescence has been reported in sorghum containing the KS19 source of stay‐green, indicating that photosynthesis may be maintained for longer during senescence in these genotypes. At a leaf level, longevity of photosynthetic apparatus is intimately related to nitrogen (N) status. At a whole plant level, stay‐green can be viewed as a consequence of the balance between N demand by the grain and N supply during grain filling. To examine some of these concepts, nine hybrids varying in the B35 and KS19 sources of stay‐green were grown under a post‐anthesis water deficit. Genotypic variation in delayed onset and reduced rate of leaf senescence were explained by differences in specific leaf nitrogen (SLN) and N uptake during grain filling. Matching N supply from age‐related senescence and N uptake during grain filling with grain N demand found that the shortfall in N supply for grain filling was greater in the senescent than stay‐green hybrids, resulting in more accelerated leaf senescence in the former. We hypothesise that increased N uptake by stay‐green hybrids is a result of greater biomass accumulation during grain filling in response to increased sink demand (higher grain numbers) which, in turn, is the result of increased radiation use efficiency and transpiration efficiency due to higher SLN. Delayed leaf senescence resulting from higher SLN should, in turn, allow more carbon and nitrogen to be allocated to the roots of stay‐green hybrids during grain filling, thereby maintaining a greater capacity to extract N from the soil compared with senescent hybrids.