SPR蛋白质芯片在输入性疟疾筛查中的应用

输入性疟疾已是我国疟疾防控的主要危险因素,如何对入境人员进行疟疾快速筛查是急需解决的难题。蛋白质芯片已被广泛应用于高通量筛选和诊断,本研究尝试构建了表面等离子共振技术 (Surface plasmon resonance,SPR) 蛋白芯片用于恶性疟疾的快速检测。采用聚乙二醇高分子处理的特异性吸附表面,以恶性疟疾特异性抗原富组氨酸蛋白Ⅱ (Histidine-rich protein Ⅱ,HRP2) 作为捕获探针,建立疟疾的微阵列芯片,并对芯片的最佳抗原固定浓度,检测的灵敏性和特异性,以及抗干扰能力进行了分析。该芯片可成功应用于恶性疟疾的筛查,具有无标记、即时快速的特点,与荧光定量PCR法相比,两种方法在敏感度和特异性方面无统计学差异。研究结果为一步研制疟疾分型鉴定蛋白质芯片奠定了基础,有利于对入境人员进行疟疾快速筛查。     

Rapid identification of potential drought tolerance genes from Solanum tuberosum by using a yeast functional screening method

Identification of major stress tolerance genes of a crop plant is important for the rapid development of its stress-tolerant cultivar. Here, we used a yeast functional screen method to identify potential drought-tolerance genes from a potato plant. A cDNA expression library was constructed from hyperosmotic stressed potato plants. The yeast transformants expressing different cDNAs were selected for their ability to survive in hyperosmotic stress conditions. The relative tolerances of the selected yeast transformants to multiple abiotic stresses were also studied. Specific potato cDNAs expressed in the tolerant yeast transformants were identified. Sixty-nine genes were found capable of enhancing hyperosmotic stress tolerance of yeast. Based on the relative tolerance data generated, 12 genes were selected, which could be most effective in imparting higher drought tolerance to potato with better survival in salt and high-temperature stresses. Orthologues of few genes identified here are previously known to increase osmotic stress tolerance of yeast and plants; however, specific studies are needed to confirm their role in the osmotic stress tolerance of potato.     

用于药物筛选的微流控细胞阵列芯片

细胞区域分布培养以及如何有效地对微流体进行操控是微流控阵列芯片在细胞药物研究中的关键技术。本研究介绍了一种利用SU-8负性光刻胶模具和PDMS制作双层结构的微流控细胞阵列芯片的方法,该芯片通过C型的坝结构将进样细胞拦截在芯片的细胞培养的固定区域,键合双层PDMS构成阀控制层,阀网络的开关作用成功实现了芯片通道内微流体的操控,同时芯片设计了药物浓度梯度网络,产生6个不同浓度的药物刺激细胞。通过对芯片3种共培养细胞活性的检测和药物伊立替康(CTP-11)对肝癌细胞的浓度梯度刺激等实验结果验证该芯片在细胞研究和药物筛选等方面的可行性。     

A generic approach to engineer antibody pH-switches using combinatorial histidine scanning libraries and yeast display

There is growing interest in the fast and robust engineering of protein pH-sensitivity that aims to reduce binding at acidic pH, compared to neutral pH. Here, we describe a novel strategy for the incorporation of pH-sensitive antigen binding functions into antibody variable domains using combinatorial histidine scanning libraries and yeast surface display. The strategy allows simultaneous screening for both, high affinity binding at pH 7.4 and pH-sensitivity, and excludes conventional negative selection steps. As proof of concept, we applied this strategy to incorporate pH-dependent antigen binding into the complementary-determining regions of adalimumab. After 3 consecutive rounds of separate heavy and light chain library screening, pH-sensitive variants could be isolated. Heavy and light chain mutations were combined, resulting in 3 full-length antibody variants that revealed sharp, reversible pH-dependent binding profiles. Dissociation rate constants at pH 6.0 increased 230- to 780-fold, while high affinity binding at pH 7.4 in the sub-nanomolar range was retained. Furthermore, binding to huFcRn and thermal stability were not affected by histidine substitutions. Overall, this study emphasizes a generalizable strategy for engineering pH-switch functions potentially applicable to a variety of antibodies and further proteins-based therapeutics.     

A generic approach to engineer antibody pH-switches using combinatorial histidine scanning libraries and yeast display

There is growing interest in the fast and robust engineering of protein pH-sensitivity that aims to reduce binding at acidic pH, compared to neutral pH. Here, we describe a novel strategy for the incorporation of pH-sensitive antigen binding functions into antibody variable domains using combinatorial histidine scanning libraries and yeast surface display. The strategy allows simultaneous screening for both, high affinity binding at pH 7.4 and pH-sensitivity, and excludes conventional negative selection steps. As proof of concept, we applied this strategy to incorporate pH-dependent antigen binding into the complementary-determining regions of adalimumab. After 3 consecutive rounds of separate heavy and light chain library screening, pH-sensitive variants could be isolated. Heavy and light chain mutations were combined, resulting in 3 full-length antibody variants that revealed sharp, reversible pH-dependent binding profiles. Dissociation rate constants at pH 6.0 increased 230- to 780-fold, while high affinity binding at pH 7.4 in the sub-nanomolar range was retained. Furthermore, binding to huFcRn and thermal stability were not affected by histidine substitutions. Overall, this study emphasizes a generalizable strategy for engineering pH-switch functions potentially applicable to a variety of antibodies and further proteins-based therapeutics.     

Identification of interacting proteins for calcium-dependent protein kinase 8 by a novel screening system based on bimolecular fluorescence complementation

Protein kinases are key regulators of cell function that constitute one of the largest and most functionally diverse gene families. We developed a novel assay system, based on the bimolecular fluorescence complementation (BiFC) technique in Escherichia coli, for detecting transient interactions such as those between kinases and their substrates. This system detected the interaction between OsMEK1 and its direct target OsMAP1. By contrast, BiFC fluorescence was not observed when OsMAP2 or OsMAP3, which are not substrates of OsMEK1, were used as prey proteins. We also screened for interacting proteins of calcium-dependent protein kinase 8 (OsCPK8), a regulator of plant immune responses, and identified three proteins as interacting molecules of OsCPK8. The interaction between OsCPK8 and two of these proteins (ARF-GEF and peptidyl prolyl isomerase) was confirmed in rice cells by means of BiFC technology. These results indicate that our new assay system has the potential to screen for protein kinase target molecules.     

Organophosphorus compound detection on a cell chip with yeast coexpressing hydrolase and eGFP

Organophosphorus compounds (OPs) such as pesticides, fungicides, and herbicides are highly toxic but are nevertheless extensively used worldwide. To detect OPs, we constructed a yeast strain that co-displays organophosphorus hydrolase (OPH) and enhanced green fluorescent protein (EGFP) on the cell surface using a Flo1p anchor system. OP degradation releases protons and causes a change in pH. This pH change results in structural deformation of EGFP, which triggers quenching of its fluorescence, thereby making this cell useful for visual detection of OPs. Fluorescence microscopy confirmed the high-intensity fluorescence displayed by EGFP on the cell surface. The yeast strain possessed sufficient OPH hydrolytic activities for degrading OPs, as measured by incubation with 1 mM paraoxon for 24 h at 30°C. In addition, with 20 mM paraoxon at 30°C, fluorescence quenching of EGFP on the single yeast cell was observed within 40 s in a microchamber chip. These observations suggest that engineered yeast cells are suitable for simultaneous degradation and visual detection of OPs.     

High-throughput and automation advances for accelerating single-cell cloning,monoclonality and early phase clone screening steps in mammalian cell line development for biologics production

Mammalian cell line development is a multistep process wherein timelines for developing clonal cells to be used as manufacturing cell lines for biologics production can commonly extend to 9 months when no automation or modern molecular technologies are involved in the workflow. Steps in the cell line development workflow involving single-cell cloning, monoclonality assurance, productivity and stability screening are labor, time and resource intensive when performed manually. Introduction of automation and miniaturization in these steps has reduced the required manual labor, shortened timelines from months to weeks, and decreased the resources needed to develop manufacturing cell lines. This review summarizes the advances, benefits, comparisons and shortcomings of different automation platforms available in the market for rapid isolation of desired clonal cell lines for biologics production.     

Construction and characterization of a pseudo-immune human antibody library using yeast surface display

Lymphocytes from eight individuals out of 60 healthy donors, whose plasmas showed relatively higher antibody titer for a target antigen of death receptor 5 (DR5), were selected for the source of antibody genes to construct so called an anti-DR5 pseudo-immune human single-chain fragment variable (scFv) library on the yeast cell surface (approximately 2x10(6) diversity). Compared with a large nonimmune human scFv library (approximately 1x10(9) diversity), the repertoire of the pseudo-immune scFv library was significantly biased toward the target antigen, which facilitated rapid enrichments of the target-specific high affinity scFvs during selections by fluorescence activated cell sortings. Isolated scFvs, HW5 and HW6, from the pseudo-immune library showed much higher specificity and affinity for the targeted antigen than those from the nonimmune library. Our results suggest that a pseudo-immune antibody library is very efficient to isolate target-specific high affinity antibody from a relatively small sized library.     

快速筛选高效表达重组蛋白毕赤酵母菌株新方法的建立及评价

毕赤酵母是当前应用最为广泛的重组蛋白表达系统之一,文中建立了一种快速筛选高效表达重组蛋白的毕赤酵母菌株的新方法.首先,对内质网转膜蛋白Sec63融合表达增强型绿色荧光蛋白EGFP的改造菌株GS115-E表达重组蛋白的能力进行检测;之后将携带不同拷贝数的植酸酶phy基因或木聚糖酶xyn基因的质粒转化进入GS115-E中,...     

神经元蛋白3.1结合蛋白酵母双杂交筛选体系的建立

神经元蛋白3.1(P311)是肺泡发育的上游调节因子。以pEGFP-P311重组质粒为模板,利用PCR方法扩增P311基因编码序列。通过Nde I和BamH I位点插入诱饵载体pGBKT7,构建重组诱饵载体pGBKT7-P311。重组体转化酵母菌AH109进行自激活和毒性检测,结果 DNA-BD-P311融合蛋白无单独激活报告基因作用,对酵母菌亦无毒性。以出生11 d小鼠肺组织为材料,提取总RNA。逆转录产生单链cDNA,通过长距离PCR进行扩增。扩增产物ds cDNA电泳后可见大小为0.2～3.0 kb间的弥散状分布条带,说明文库cDNA可满足筛选要求。诱饵载体pGBKT7-P311的构建及相应小鼠肺组织cDNA文库的建立,为进一步利用酵母双杂交技术探讨P311功能奠定了基础。     

构建葡萄糖二酸指示系统筛选肌醇加氧酶突变株

葡萄糖二酸是一种高附加值天然有机酸,已经广泛应用于疾病防治、生产聚合物材料等领域。在葡萄糖二酸的合成途径中,肌醇加氧酶MIOX所催化的肌醇转换为葡萄糖醛酸的过程是整个途径的限速步骤。通过应用将葡萄糖二酸浓度与绿色荧光蛋白荧光强度相结合的筛选系统,从突变体文库中筛选出3株有潜力的肌醇加氧酶突变体(K59V/R60A、R171S和D276A),使MIOX活性得到提高。重组菌株Escherichia coli BL21(DE3)/MU-R171S的葡萄糖二酸产量相比于未突变菌株提高了36.5%。     

A microfluidic cell chip for virus isolation via rapid screening for permissive cells

Virus identification is a prerequisite not only for the early diagnosis of viral infectious diseases but also for the effective prevention of epidemics. Successful cultivation is the gold standard for identifying a virus, according to the Koch postulates. However, this requires screening for a permissive cell line, which is traditionally time-, reagent- and labor-intensive. Here, a simple and easy-to-operate microfluidic chip, formed by seeding a variety of cell lines and culturing them in parallel, is reported for use in virus cultivation and virus-permissive host-cell screening. The chip was tested by infection with two known viruses, enterovirus 71 (EV71) and influenza virus H1N1. Infection with EV71 and H1N1 caused significant cytopathic effects (CPE) in RD and MDCK cells, respectively, demonstrating that virus cultivation based on this microfluidic cell chip can be used as a substitute for the traditional plate-based culture method and reproduce the typical CPE caused by virus infection. Using this microfluidic cell chip method for virus cultivation could make it possible to identify an emerging virus in a high-throughput, automatic, and unprecedentedly fast way.     

Identification of novel ASK1 inhibitors using virtual screening

Apoptosis signal-regulating kinase 1 (ASK1, also called MAP3K5) is a mitogen-activated protein kinase kinase kinase (MAP3K) that plays important roles in stress-induced cell death and inflammation, and is expected as a new therapeutic target for cancer, cardiovascular diseases, and neurodegenerative diseases. We identified novel ASK1 inhibitors by virtual screening from the public chemical library collected by Chemical Biology Research Initiative (CBRI) at the University of Tokyo.     

Creation of a novel peptide endowing yeasts with acid tolerance using yeast cell-surface engineering

The cell wall of Saccharomyces cerevisiae plays an essential role in the biophysical characteristics of the cell surface. The modification of the cell wall property is an important factor for cellular adaptation to a stressful environment. In this study, we randomly modified the cell wall by displaying combinatorial random peptides on the yeast cell surface, and by screening, we successfully obtained a novel peptide, Scr35, that endowed yeasts with acid tolerance. The yeast, surface-modified by Scr35, was able to grow well under acidic condition and low glucose condition and showed high glucose uptake activity. However, the growth of the modified yeast became inferior as extracellular pH became higher. This inferiority was rescued by decreasing glucose concentration in a medium. Our results suggest that the optimum pH of a medium becomes low when the newly created Scr35 affects glucose uptake activity through cell-surface modification. Therefore, such artificial modification of the cell surface has a great potential as a useful tool for breeding acid-tolerant yeasts for industrial applications of S. cerevisiae as a biocatalyst.     

Construction of a cultivation system of a yeast single cell in a cell chip microchamber

A novel single cell screening system was constructed using a yeast cell chip in combination with the yeast cell surface engineering [NanoBiotechnology 2005, 1, 105-111]. Enzymes or functional proteins displayed on a yeast cell surface can be used as a protein cluster. To achieve high-throughput screening of protein libraries on the cell surface, a catalytic reaction by a single cell-surface-engineered yeast cell was successfully carried out in the microchamber on the yeast cell chip. After screening, to replicate a target cell for use in measuring of activity, DNA sequencing, and preservation, a novel single cell cultivation system in the yeast cell chip was constructed. To avoid damage of the rapid dry up of medium in the microchamber array, the yeast cell chip was modified with a protection sheet, so that the modified chip was like a micro-culture tank constructed on the yeast cell chip microchamber. As a result, single yeast cell cultivation in the yeast cell chip microchamber was observed, and the modified yeast cell chip was evaluated to be good for a single cell selection. The improvement showed that the single cell screening system coupled with the single cell cultivation using the modified yeast cell chip may be superior to that by a cell sorter for the isolation of a target cell and its practical use.     

The establishment of mouse embryonic stem cell cultures on 96-well plates for high-throughput screening

Embryonic stem (ES) cells can be valuable for monitoring differentiation processes and for improving applications in basic developmental biology. The application of ES cells can be a useful tool for drug discovery and toxicology. Therefore, we suggest the high-throughput screening (HTS) system based on ES cells in this study. Firstly, we optimized the feeder-free condition and seeding cell number which can maintained for at least 7 days without over-confluency. We analyzed the system by cell viability, proliferation activity, RT-PCR and morphologic/immunohistochemical evaluations. The optimal cell seeding number was 30/well that was maintained the typical colonial morphology over 9 d with 1,000 U/ml LIF in the limited space. The cell in optimized condition expressed ALP, SSEA-1, Oct 4 and Nanog and the genetic expressions showed similar to protein expressions. The cell lineage marker expressions showed faint or none. The cell viability and proliferation activity were increased in time-dependent manner in our optimized HTS system. In conclusion, the novel HTS system using ES cells can by useful for developing models for drug discovery as well as toxicological screening in the near future.