Adapting chromophore-assisted laser inactivation for high throughput functional proteomics.

Recent advances in genomics and proteomics have generated a change in emphasis from hypothesis-based to discovery-based investigations. Genomic and proteomic studies based on differential expression microarrays or comparative proteomics often provide many potential candidates for functionally important roles in normal and diseased cells. High throughput technologies to address protein and gene function in situ are still necessary to exploit these emerging advances in gene and protein discovery in order to validate these identified targets. The pharmaceutical industry is particularly interested in target validation, and has identified it as the critical early step in drug discovery. An especially powerful approach to target validation is a direct protein knockdown strategy called chromophore-assisted laser inactivation (CALI) which is a means of testing the role of specific proteins in particular cellular processes. Recent developments in CALI allow for its high throughput application to address many proteins in tandem. Thus, CALI may have applications for high throughput hypothesis testing, target validation or proteome-wide screening.     

蛋白质组研究中分离新技术与新方法

对于蛋白质组的研究离不开分析技术的支撑。由于样品及其基质的复杂性,为了实现蛋白质的高通量、高灵敏度、快速分析鉴定,必须发展与之匹配的新技术与新方法。多维高效液相色谱/毛细管电泳技术,部分弥补了传统2D PAGE的不足,近年来,在蛋白质分离鉴定方面取得了最令人瞩目的成绩。本文分别从多维液相色谱分离技术、多维毛细管电泳蛋白质分离平台、微柱液相-毛细管电泳联用技术、极端pH蛋白质的分离分析和蛋白质的在线富集技术等方面对蛋白质组学研究中在新技术与新方法方面近期取得的成果加以系统阐述。     

Current two-dimensional electrophoresis technology for proteomics

Two-dimensional gel electrophoresis (2-DE) with immobilized pH gradients (IPGs) combined with protein identification by mass spectrometry (MS) is currently the workhorse for proteomics. In spite of promising alternative or complementary technologies (e.g. multidimensional protein identification technology, stable isotope labelling, protein or antibody arrays) that have emerged recently, 2-DE is currently the only technique that can be routinely applied for parallel quantitative expression profiling of large sets of complex protein mixtures such as whole cell lysates. 2-DE enables the separaration of complex mixtures of proteins according to isoelectric point (pI), molecular mass (M_r), solubility, and relative abundance. Furthermore, it delivers a map of intact proteins, which reflects changes in protein expression level, isoforms or post-translational modifications. This is in contrast to liquid chromatography-tandem mass spectrometry based methods, which perform analysis on peptides, where M_r and pI information is lost, and where stable isotope labelling is required for quantitative analysis. Today's 2-DE technology with IPGs (Görg et al., Electrophoresis 2000, 21, 1037–1053), has overcome the former limitations of carrier ampholyte based 2-DE (O'Farrell, J. Biol. Chem. 1975, 250, 4007–4021) with respect to reproducibility, handling, resolution, and separation of very acidic and/or basic proteins. The development of IPGs between pH 2.5–12 has enabled the analysis of very alkaline proteins and the construction of the corresponding databases. Narrow-overlapping IPGs provide increased resolution (δpI = 0.001) and, in combination with prefractionation methods, the detection of low abundance proteins. Depending on the gel size and pH gradient used, 2-DE can resolve more than 5000 proteins simultaneously (˜2000 proteins routinely), and detect and quantify < 1 ng of protein per spot. In this article we describe the current 2-DE/MS workflow including the following topics: sample preparation, protein solubilization, and prefractionation; protein separation by 2-DE with IPGs; protein detection and quantitation; computer assisted analysis of 2-DE patterns; protein identification and characterization by MS; two-dimensional protein databases.     

Antibody suspension bead arrays within serum proteomics

Antibody microarrays offer a powerful tool to screen for target proteins in complex samples. Here, we describe an approach for systematic analysis of serum, based on antibodies and using color-coded beads for the creation of antibody arrays in suspension. This method, adapted from planar antibody arrays, offers a fast, flexible, and multiplexed procedure to screen larger numbers of serum samples, and no purification steps are required to remove excess labeling substance. The assay system detected proteins down to lower picomolar levels with dynamic ranges over 3 orders of magnitude. The feasibility of this workflow was shown in a study with more than 200 clinical serum samples tested for 20 serum proteins.     

蛋白质组学研究中的双向电泳技术

蛋白质组学研究已经成为后基因组时代的研究热点,其两大支柱是双向凝胶电泳技术和生物质谱技术。尽管双向电泳技术近几年已经取得了突破性进展,是当前蛋白质分离的最常用技术,但其本身还有一些难以克服的问题。随着质谱技术的快速发展,双向电泳逐渐成为蛋白质组学研究的瓶颈。本综述双向电泳主要技术步骤的现状、存在问题及其改进方向。     

Ligation-based molecular tools for lab-on-a-chip devices

Molecular diagnostics can offer early detection of disease, improved diagnostic accuracy, and qualified follow-up. Moreover, the use of microfluidic devices can in principle render these analyses quickly and user-friendly, placing them within the reach of the general practitioner and maybe even in households. However, the progress launching such devices has been limited so far. We propose that an important limiting factor has been the difficulty of establishing molecular assays suitable for microfabricated formats. The assays should be capable of monitoring a wide range of molecules, including genomic DNA, RNA and proteins with secondary modifications and interaction partners, and they must exhibit excellent sensitivity and specificity. We discuss these problems and describe a series of molecular tools that may present new opportunities for lab-on-a-chip devices at the point-of-care.     

All about DIGE: quantification technology for differential-display 2D-gel proteomics

2D polyacrylamide gel electrophoresis has been the traditional workhorse of proteomics, allowing for the resolution of several thousand proteins in a single gel. Difference gel electrophoresis is an emerging technology that allows for accurate quantification with statistical confidence while controlling for nonbiologic variation, and also increases the dynamic range and sensitivity of traditional 2D polyacrylamide gel electrophoresis. With inclusion of an internal standard formed from equal amounts of every sample in an experiment, difference gel electrophoresis technology also allows for repetitive measurements and multivariable analyses to be quantitatively analyzed in one co-ordinated experiment, yielding statistically-significant changes in protein expression related to many disease states. This technique promises to be an important tool in clinical proteomics and the study of the mechanism of disease, investigating diagnostic biomarkers and pinpointing novel therapeutic targets.     

All about DIGE: quantification technology for differential-display 2D-gel proteomics

2D polyacrylamide gel electrophoresis has been the traditional workhorse of proteomics, allowing for the resolution of several thousand proteins in a single gel. Difference gel electrophoresis is an emerging technology that allows for accurate quantification with statistical confidence while controlling for nonbiologic variation, and also increases the dynamic range and sensitivity of traditional 2D polyacrylamide gel electrophoresis. With inclusion of an internal standard formed from equal amounts of every sample in an experiment, difference gel electrophoresis technology also allows for repetitive measurements and multivariable analyses to be quantitatively analyzed in one co-ordinated experiment, yielding statistically-significant changes in protein expression related to many disease states. This technique promises to be an important tool in clinical proteomics and the study of the mechanism of disease, investigating diagnostic biomarkers and pinpointing novel therapeutic targets.     

A new application of microwave technology to proteomics

Two-dimensional electrophoresis (2-DE) combined with mass spectrometry has significantly improved the possibilities of large-scale identification of proteins. However, 2-DE is limited by its inability to speed up the in-gel digestion process. We have developed a new approach to speed up the protein identification process utilizing microwave technology. Proteins excised from gels are subjected to in-gel digestion with endoprotease trypsin by microwave irradiation, which rapidly produces peptide fragments. The peptide fragments were further analyzed by matrix-assisted laser desorption/ionization technique for protein identification. The efficacy of this technique for protein mapping was demonstrated by the mass spectral analyses of the peptide fragmentation of several proteins, including lysozyme, albumin, conalbumin, and ribonuclease A. The method reduced the required time for in-gel digestion of proteins from 16 hours to as little as five minutes. This new application of microwave technology to protein identification will be an important advancement in biotechnology and proteome research.     

New perspective for phage display as an efficient and versatile technology of functional proteomics

Phage display with antibody libraries has been widely used with versatile applications. However, phage display with cDNA libraries is rare and inefficient. Because of uncontrollable reading frames and stop codons in cDNA repertoires, high percentage of phage clones identified from conventional cDNA libraries are non-open reading frames (non-ORFs) encoding unnatural short peptides with minimal implications in protein networks. Consequently, phage display has not been used as a technology of functional proteomics to elucidate protein–protein interactions like yeast two-hybrid system and mass spectrometry-based technologies. Several strategies, including C-terminal display and ORF cDNA libraries, have been explored to circumvent the technical problem. The accumulative endeavors eventually led to the efficient elucidation of a large number of tubby- and phosphatidylserine-binding proteins in recent studies by ORF phage display with minimal reading frame issue. ORF phage display inherits all the versatile applications of antibody phage display, but enables efficient identification of real endogenous proteins with efficiency, sensitivity, and accuracy comparable to other technologies of functional proteomics. Its ELISA-like procedure can be conveniently adapted by individual laboratories or fully automated for high-throughput screening. Thus, ORF phage display is an efficient, sensitive, versatile, and convenient technology of functional proteomics for elucidation of global and pathway-specific protein–protein interactions, disease mechanisms, or therapeutic targets.     

Microfluidic lab-on-a-chip for microbial identification on a DNA microarray

A lab-on-a-chip for the rapid identification of microbial species has been developed for a water monitoring system. We employed highly parallel DNA microarrays for the direct profiling of microbial populations in a sample. For the integration and minimization of the DNA microarray protocols for bacterial identification, rRNA was selected as a target nucleotide for probe:target hybridization. In order to hybridize target rRNA onto the probe oligonucleotide, intact rRNA extracted fromE. coli rRNA was fragmented via chemical techniques in the lab-on-a-chip platform. The size of fragmented rRNA was less than 400 base pairs, which was confirmed by polyacrylamide gel electrophoresis. The fragmented rRNA was also labeled using fluorescent chemicals. The lab-on-a-chip for fragmentation and labeling includes a PDMS chaotic mixer for efficient mixing, operated by flow pressure. In addition, the fragmented rRNA was hybridized successfully on a DNA microarray with sample recirculation on a microfluidic platform. Our fragmentation and labeling technique will have far-reaching applications, which require rapid but complicated chemical genetic material processing on a lab-on-a-chip platform.     

Development of low-cost microfluidic systems for lab-on-a-chip biosensor applications

In this work, we develop low-cost microfluidic systems based on polydimethylsiloxane (PDMS) for lab-on-a-chip applications. PDMS microfluidic structures have been fabricated by micromolding, PDMS casting, and plasma bonding processes. The micromolding technique is used to fabricate PDMS slabs with micro-sized grooves, and the complete microchannel is formed by bonding PDMS slab with glass or PDMS substrate. The molding procedure using SU-8 photoresist patterning on silicon wafer, PDMS microchannel fabrication, and PDMS surface treatment using oxygen plasma and TiO₂ coating, are discussed. The various parameters for oxygen plasma treatment including RF power and treatment time are studied in order to obtain conditions for good bonding with the glass substrate. The best condition for plasma treatment is found to be the low RF power (8 W) with 5 min treatment time. In addition, TiO₂ coating with oxygen plasma treatment has been applied to make PDMS surface more hydrophilic to improve aqueous solution compatilbility. The microfluidic channels for various applications, including sample injection cross channel, micropump channel, T and Y sample mixers, PCR thermocyling chamber and channel, capillary electrophoresis flow channel, and conductimetric systems have been fabricated. Finally, a typical application of the PDMS chip in a flow injection conductimetric system for sodium chloride detection has been demonstrated.