毕赤酵母液滴微流控高通量筛选方法的建立与应用

巴斯德毕赤酵母是当前应用最为方便和广泛的外源蛋白表达系统之一,为了进一步提高其表达外源蛋白的能力,文中建立了基于液滴微流控的毕赤酵母高通量筛选方法,并以木聚糖酶融合荧光蛋白为例,筛选获得木聚糖酶表达和分泌能力提高的突变株。通过PCR扩增得到木聚糖酶xyn5基因和绿色荧光蛋白gfp基因融合片段,并克隆到毕赤酵母表达载体pPIC9K中构建出木聚糖酶融合绿色荧光蛋白的质粒pPIC9K-xyn5-gfp,电转化至毕赤酵母GS115中得到表达木聚糖酶和绿色荧光蛋白的毕赤酵母SG菌株。该菌株经过常压室温等离子体诱变后进行单细胞液滴包埋,液滴培养24h后进行微流控筛选,获得高表达木聚糖酶的突变菌株,进而用于下一轮的诱变突变库构建和筛选。以此类推,经过5轮液滴微流控筛选,获得一株高产菌株SG-m5,其木聚糖酶活为149.17U/mg,较出发菌株提升300%,分泌外源蛋白的能力较出发菌株提高160%。文中建立的毕赤酵母单细胞液滴微流控高通量筛选方法能达到每小时10万菌株的筛选通量,筛选百万级别的菌株库仅需10h,消耗荧光试剂体积100μL,对比传统的微孔板筛选方法降低试剂成本近百万倍,为高效、低成本筛选获得表达和分泌外源蛋白能力提高的毕赤酵母提供了一条新途径。     

A high-throughput expression and screening platform for applications-driven PETase engineering

The environmental consequences of plastic waste have impacted all kingdoms of life in terrestrial and aquatic ecosystems. However, as the burden of plastic pollution has increased, microbes have evolved to utilize anthropogenic polymers as nutrient sources. Of depolymerase enzymes, the best characterized is PETase, which hydrolyzes aromatic polyesters. PETase engineering has made impressive progress in recent years; however, further optimization of engineered PETase toward industrial application has been limited by lower throughput techniques used in protein purification and activity detection. Here, we address these deficiencies through development of a higher-throughput PETase engineering platform. Secretory expression via YebF tagging eliminates lysis and purification steps, facilitating production of large mutant libraries. Fluorescent detection of degradation products permits rapid screening of depolymerase activity in microplates as opposed to serial chromatographic methods. This approach enabled development of more stable PETase, semi-rational (SR) PETase variant containing previously unpublished mutations. SR-PETase releases 1.9-fold more degradation products and has up to 7.4-fold higher activity than wild-type PETase over 10 days at 40°C. These methods can be adapted to a variety of chemical environments, enabling screening of PETase mutants in applications-relevant conditions. Overall, this work promises to facilitate advancements in PETase engineering toward industrial depolymerization of plastic waste.     

A high-throughput, low-cost method for the preparation of "sequencing-ready" phage DNA template

We have developed a simple and efficient protocol for the isolation of good-quality recombinant phage DNA useful for all downstream processing, including automated sequencing. The overnight-grown phage particles were effectively precipitated (without any contaminating Escherichia coli DNA and other culture media components) by adjusting the pH of the culture medium to 5.2 with sodium acetate, followed by addition of ethanol to 25%. The phage DNA was selectively precipitated with ethanol in the presence of guanidinium thiocyanate under alkaline pH, resulting in uniform quality and quantity of phage DNA. The quality of the phage DNA preparation was demonstrated by DNA sequencing that provided an average read length of >700 bases (PHRED20 quality). This protocol for plating, picking, growing, and subsequent DNA purification of individual phage clones can be completely automated using any standard robotic platform. This protocol does not require any commercial kits and can be completed within 2 h.     

宏基因组学技术的研究与挑战

宏基因组学研究作为研究微生物种群生态分布、群体遗传特征和基因相互作用的新兴学科领域,在很大程度上促进了环境微生物资源,特别是未培养微生物资源的开发利用,在土壤、海洋、人体医学、药物等各个领域的应用中取得了突破性的进展,为发现新的生物活性物质提供了新的有效途径。就宏基因组学研究进展进行综述,并重点介绍了宏基因组学研究中的机遇及挑战。     

畜禽微生物耐药组研究进展

目前,绝大部分抗生素用于给人类提供肉奶蛋等食品的畜禽,由此产生的抗生素耐药性对全球公众健康造成了巨大威胁。为了降低畜禽生产环节抗生素耐药性向人类的传播,首先需要明确畜禽消化道或产品微生物携带哪些耐药基因。耐药组指的是某个环境微生物群落全部耐药基因的总和,近年来对于畜禽生产过程中耐药组分析成为研究热点之一。本文综述了基于测序技术研究畜禽(猪、鸡、反刍动物)消化道以及乳中微生物耐药组组成及其影响因素的最新进展,并提出了未来研究方向,包括耐药组研究方法的标准化、基于宏转录组的耐药组基因表达研究,以及可移动遗传元件所携带的耐药基因等,旨在为调控畜禽养殖过程中耐药基因提供思路。     

Open resource metagenomics: a model for sharing metagenomic libraries

Both sequence-based and activity-based exploitation of environmental DNA have provided unprecedented access to the genomic content of cultivated and uncultivated microorganisms. Although researchers deposit microbial strains in culture collections and DNA sequences in databases, activity-based metagenomic studies typically only publish sequences from the hits retrieved from specific screens. Physical metagenomic libraries, conceptually similar to entire sequence datasets, are usually not straightforward to obtain by interested parties subsequent to publication. In order to facilitate unrestricted distribution of metagenomic libraries, we propose the adoption of open resource metagenomics, in line with the trend towards open access publishing, and similar to culture- and mutant-strain collections that have been the backbone of traditional microbiology and microbial genetics. The concept of open resource metagenomics includes preparation of physical DNA libraries, preferably in versatile vectors that facilitate screening in a diversity of host organisms, and pooling of clones so that single aliquots containing complete libraries can be easily distributed upon request. Database deposition of associated metadata and sequence data for each library provides researchers with information to select the most appropriate libraries for further research projects. As a starting point, we have established the Canadian MetaMicroBiome Library (CM²BL [1]). The CM²BL is a publicly accessible collection of cosmid libraries containing environmental DNA from soils collected from across Canada, spanning multiple biomes. The libraries were constructed such that the cloned DNA can be easily transferred to Gateway® compliant vectors, facilitating functional screening in virtually any surrogate microbial host for which there are available plasmid vectors. The libraries, which we are placing in the public domain, will be distributed upon request without restriction to members of both the academic research community and industry. This article invites the scientific community to adopt this philosophy of open resource metagenomics to extend the utility of functional metagenomics beyond initial publication, circumventing the need to start from scratch with each new research project.     

Continuous perfusion microfluidic cell culture array for high-throughput cell-based assays

We present for the first time a microfluidic cell culture array for long-term cellular monitoring. The 10 x 10 array could potentially assay 100 different cell-based experiments in parallel. The device was designed to integrate the processes used in typical cell culture experiments on a single self-contained microfluidic system. Major functions include repeated cell growth/passage cycles, reagent introduction, and real-time optical analysis. The single unit of the array consists of a circular microfluidic chamber, multiple narrow perfusion channels surrounding the main chamber, and four ports for fluidic access. Human carcinoma (HeLa) cells were cultured inside the device with continuous perfusion of medium at 37 degrees C. The observed doubling time was 1.4 +/- 0.1 days with a peak cell density of approximately 2.5*10(5) cells/cm(2). Cell assay was demonstrated by monitoring the fluorescence localization of calcein AM from 1 min to 10 days after reagent introduction. Confluent cell cultures were passaged within the microfluidic chambers using trypsin and successfully regrown, suggesting a stable culture environment suitable for continuous operation. The cell culture array could offer a platform for a wide range of assays with applications in drug screening, bioinformatics, and quantitative cell biology.     

高通量自动化微生物微液滴进化培养与筛选技术及其装备化

液滴微流控由于可以快速生成大量微液滴,并实现单个液滴独立的控制,每个液滴都可以作为独立的单元进行微生物培养,因此在微生物的高通量培养方面具有独特的应用优势.然而现有研究多停留在实验室搭建和使用阶段,存在操作要求高、影响因素多、缺乏自动化集成技术等关键问题,制约了液滴微流控技术在微生物研究中的应用.文中以解决液滴微流控技...     

高通量分析技术在资源微生物及功能基因发掘中的应用

随着新的微生物资源不断被发现以及微生物基因组测序数据的积累和完善,目前研究重点和难点是如何从大量数据中快速发现和鉴定与微生物重要表型相关的功能基因,这就需要高通量的分析研究手段,主要涉及建库和筛选两个主要技术单元。其中,建库是指构建能够覆盖微生物全基因组的突变或干扰文库,所涉及的技术包括宏基因组、转座子插入突变、RNA干扰(RNA interference,RNAi)、反转录子文库重组工程(retron library recombineering,RLR)、CRISPR抑制(CRISPRi)和CRISPR激活(CRISPRa)等。筛选则是通过某种胁迫压力来促使文库菌群的差异化生长,并结合高通量测序全面发掘与特定表型相关的功能基因,从而为后续研究提供有效信息。本文对功能基因组学研究中现有的高通量分析技术进行了梳理、总结和展望,以期为这类技术方法的拓展、优化以及应用提供参考。     

Automated, high-throughput platform for protein solubility screening using a split-GFP system

Overproduction of soluble and stable proteins for functional and structural studies is a major bottleneck for structural genomics programs and traditional biochemistry laboratories. Many high-payoff proteins that are important in various biological processes are “difficult to handle” as protein reagents in their native form. We have recently made several advances in enabling biochemical technologies for improving protein stability (), allowing stratagems for efficient protein domain trapping, solubility-improving mutations, and finding protein folding partners. In particular split-GFP protein tags are a very powerful tool for detection of stable protein domains. Soluble, stable proteins tagged with the 15 amino acid GFP fragment (amino acids 216–228) can be detected in vivo and in vitro using the engineered GFP 1–10 “detector” fragment (amino acids 1–215). If the small tag is accessible, the detector fragment spontaneously binds resulting in fluorescence. Here, we describe our current and on-going efforts to move this process from the bench (manual sample manipulation) to an automated, high-throughput, liquid-handling platform. We discuss optimization and validation of bacterial culture growth, lysis protocols, protein extraction, and assays of soluble and insoluble protein in multiple 96 well plate format. The optimized liquid-handling protocol can be used for rapid determination of the optimal, compact domains from single ORFS, collections of ORFS, or cDNA libraries.     

宏基因组学挖掘新型生物催化剂的研究进展

微生物蕴藏着大量具有工业应用潜力的生物催化剂。然而,传统培养方法只能从环境中获得不到1%的微生物。宏基因组学是通过提取某一特定环境中的所有微生物基因组DNA、构建基因组文库并对文库进行筛选,寻找和发现新的功能基因的一种方法。它绕过了微生物分离培养过程,成为研究环境样品中不可培养微生物的有力手段。因此,从宏基因组中挖掘新型生物催化剂一直倍受生物学家的关注。以下主要对宏基因组文库的样品来源、DNA提取方法、文库的构建和筛选策略的选择这4个方面的研究状况进行了综述,列举了近年来利用宏基因组技术所获得的新型生物催化剂,并对其今后的研究方向提出了展望。     

A high-throughput screening platform for inhibitors of the riboflavin biosynthesis pathway

3,4-Dihydroxy-2-butanone 4-phosphate synthase, 6,7-dimethyl-8-ribityllumazine synthase, and riboflavin synthase of the riboflavin biosynthetic pathway are potential targets for novel antiinfective drugs. This article describes a platform for high-throughput screening for inhibitors of these enzymes. The assays can be monitored photometrically and have been shown to be robust, as indicated by Z factors 0.87. A (13)C NMR assay for hit verification of 3,4-dihydroxy-2-butanone 4-phosphate synthase inhibitors is also reported.     

A surface display yeast two-hybrid screening system for high-throughput protein interactome mapping

Despite the wide acceptance of yeast two-hybrid (Y2H) system for protein-protein interaction analysis and discovery, conventional Y2H assays are not well suited for high-throughput screening of the protein interaction network (“interactome”) on a genomic scale due to several limitations, including labor-intensive agar plating and colony selection methods associated with the use of nutrient selection markers, complicated reporter analysis methods associated with the use of LacZ enzyme reporters, and incompatibility of the liquid handling robots. We recently reported a robust liquid culture Y2H system based on quantitative analysis of yeast-enhanced green fluorescent protein (yEGFP) reporters that greatly increased the analysis throughput and compatibility with liquid handling robots. To further advance its utility in high-throughput complementary DNA (cDNA) library screening, we report the development of a novel surface display Y2H (sdY2H) library screening system with uniquely integrated surface display hemagglutination (sdHA) antigen and yEGFP reporters. By introduction of a surface reporter sdHA into the yEGFP-based Y2H system, positive Y2H targets are quickly isolated from library cells by a simple magnetic separation without a large plating effort. Moreover, the simultaneous scoring of multiple reporters, including sdHA, yEGFP, and conventional nutrient markers, greatly increased the specificity of the Y2H assay. The feasibility of the sdY2H assay on large cDNA library screening was demonstrated by the successful recovery of positive P53/T interaction pairs at a target-to-background ratio of 1:1,000,000. Together with the massive parallel DNA sequencing technology, it may provide a powerful proteomic tool for high-throughput interactome mapping on a genomic scale.     

A low-cost microfluidic chip for rapid genotyping of malaria-transmitting mosquitoes

Background

Vector control is one of the most effective measures to prevent the transmission of malaria, a disease that causes over 600,000 deaths annually. Around 30–40 Anopheles mosquito species are natural vectors of malaria parasites. Some of these species cannot be morphologically distinguished, but have behavioral and ecological differences. Emblematic of this is the Anopheles gambiae species complex. The correct identification of vector species is fundamental to the development of control strategies and epidemiological studies of disease transmission.

Methodology/Principal Findings

An inexpensive, disposable, field-deployable, sample-to-answer, microfluidic chip was designed, constructed, and tested for rapid molecular identification of Anopheles gambiae and Anopheles arabiensis. The chip contains three isothermal amplification reactors. One test reactor operates with specific primers to amplify Anopheles gambiae DNA, another with specific primers for Anopheles arabiensis DNA, and the third serves as a negative control. A mosquito leg was crushed on an isolation membrane. Two discs, laden with mosquito tissue, were punched out of the membrane and inserted into the two test chambers. The isolated, disc-bound DNA served as a template in the amplification processes. The amplification products were detected with intercalating fluorescent dye that was excited with a blue light-emitting diode. The emitted light was observed by eye and recorded with a cell-phone camera. When the target consisted of Anopheles gambiae, the reactor containing primers specific to An. gambiae lit up while the other two reactors remained dark. When the target consisted of Anopheles arabiensis, the reactor containing primers specific to An. arabiensis lit up while the other two reactors remained dark.

Conclusions/Significance

The microfluidic chip provides a means to identify mosquito type through molecular analysis. It is suitable for field work, allowing one to track the geographical distribution of mosquito populations and community structure alterations due to environmental changes and malaria intervention measures.     

基于CRISPR/Cas9技术的高通量筛选平台:发掘病毒复制相关宿主分子的新途径

病毒作为严格的细胞内寄生生物,需要多种宿主蛋白辅助其完成生命周期。寻找与病毒复制相关的宿主因子并揭示其作用机制,将有助于阐明病毒的感染机制,为疫病的防治提供新靶标。与RNA干扰技术相比,近年来兴起的CRISPR/Cas9技术能更特异、高效、准确地实现基因组编辑,因而在功能基因研究中得到更广泛应用。而基于CRISPR/Cas9系统的宿主全基因组sgRNA文库高通量筛选技术平台,可快速发现参与病毒侵入、复制等生物学过程的关键宿主因子,通过明确病毒-宿主分子相互作用进而揭示病毒的生命周期,为分子病毒学和免疫学提供了强大的研究工具。本文主要总结了基于CRISPR/Cas9技术的高通量筛选平台的具体筛选流程,归纳和讨论了该平台在筛选调控病毒复制相关宿主因子中的应用现状和发展前景。     

Separation of phospholipids in microfluidic chip device: application to high-throughput screening assays for lipid-modifying enzymes

Phospholipid molecules such as ceramide and phosphoinositides play crucial roles in signal transduction pathways. Lipid-modifying enzymes including sphingomyelinase and phosphoinositide kinases regulate the generation and degradation of these lipid-signaling molecules and are important therapeutic targets in drug discovery. We now report a sensitive and convenient method to separate these lipids using microfluidic chip-based technology. The method takes advantage of the high-separation power of the microchips that separate lipids based on micellar electrokinetic capillary chromatography (MEKC) and the high sensitivity of fluorescence detection. We further exploited the method to develop a homogenous assay to monitor activities of lipid-modifying enzymes. The assay format consists of two steps: an on-plate enzymatic reaction using fluorescently labeled substrates followed by an on-chip MEKC separation of the reaction products from the substrates. The utility of the assay format for high-throughput screening (HTS) is demonstrated using phospholipase A(2) on the Caliper 250 HTS system: throughput of 80min per 384-well plate can be achieved with unattended running time of 5.4h. This enabling technology for assaying lipid-modifying enzymes is ideal for HTS because it avoids the use of radioactive substrates and complicated separation/washing steps and detects both substrate and product simultaneously.     

A three-dimensional in vitro ovarian cancer coculture model using a high-throughput cell patterning platform

In vitro 3D cancer models that provide a more accurate representation of disease in vivo are urgently needed to improve our understanding of cancer pathology and to develop better cancer therapies. However, development of 3D models that are based on manual ejection of cells from micropipettes suffer from inherent limitations such as poor control over cell density, limited repeatability, low throughput, and, in the case of coculture models, lack of reproducible control over spatial distance between cell types (e.g., cancer and stromal cells). In this study, we build on a recently introduced 3D model in which human ovarian cancer (OVCAR-5) cells overlaid on Matrigel^™ spontaneously form multicellular acini. We introduce a high-throughput automated cell printing system to bioprint a 3D coculture model using cancer cells and normal fi broblasts micropatterned on Matrigel^™. Two cell types were patterned within a spatially controlled microenvironment (e.g., cell density, cell-cell distance) in a high-throughput and reproducible manner; both cell types remained viable during printing and continued to proliferate following patterning. This approach enables the miniaturization of an established macro-scale 3D culture model and would allow systematic investigation into the multiple unknown regulatory feedback mechanisms between tumor and stromal cells and provide a tool for high-throughput drug screening.