BackgroundSELEX is an iterative process in which highly diverse synthetic nucleic acid libraries are selected over many rounds to finally identify aptamers with desired properties. However, little is understood as how binders are enriched during the selection course. Next-generation sequencing offers the opportunity to open the black box and observe a large part of the population dynamics during the selection process.MethodologyWe have performed a semi-automated SELEX procedure on the model target streptavidin starting with a synthetic DNA oligonucleotide library and compared results obtained by the conventional analysis via cloning and Sanger sequencing with next-generation sequencing. In order to follow the population dynamics during the selection, pools from all selection rounds were barcoded and sequenced in parallel.ConclusionsHigh affinity aptamers can be readily identified simply by copy number enrichment in the first selection rounds. Based on our results, we suggest a new selection scheme that avoids a high number of iterative selection rounds while reducing time, PCR bias, and artifacts.
The need for simple and effective assays for detecting nucleic acids by isothermal amplification reactions has led to a great variety of end point and real-time monitoring methods. Here we tested direct and indirect methods to visualize the amplification of potato spindle tuber viroid (PSTVd) by loop-mediated isothermal amplification (LAMP) and compared features important for one-pot in-field applications. We compared the performance of magnesium pyrophosphate, hydroxynaphthol blue (HNB), calcein, SYBR Green I, EvaGreen, and berberine. All assays could be used to distinguish between positive and negative samples in visible or UV light. Precipitation of magnesium-pyrophosphate resulted in a turbid reaction solution. The use of HNB resulted in a color change from violet to blue, whereas calcein induced a change from orange to yellow-green. We also investigated berberine as a nucleic acid-specific dye that emits a fluorescence signal under UV light after a positive LAMP reaction. It has a comparable sensitivity to SYBR Green I and EvaGreen. Based on our results, an optimal detection method can be chosen easily for isothermal real-time or end point screening applications.
DNA sequencing continues to evolve quickly even after > 30 years. Many new platforms suddenly appeared and former established systems have vanished in almost the same manner. Since establishment of next-generation sequencing devices, this progress gains momentum due to the continually growing demand for higher throughput, lower costs and better quality of data. In consequence of this rapid development, standardized procedures and data formats as well as comprehensive quality management considerations are still scarce. Here, we listed and summarized current standardization efforts and quality management initiatives from companies, organizations and societies in form of published studies and ongoing projects. These comprise on the one hand quality documentation issues like technical notes, accreditation checklists and guidelines for validation of sequencing workflows. On the other hand, general standard proposals and quality metrics are developed and applied to the sequencing workflow steps with the main focus on upstream processes. Finally, certain standard developments for downstream pipeline data handling, processing and storage are discussed in brief. These standardization approaches represent a first basis for continuing work in order to prospectively implement next-generation sequencing in important areas such as clinical diagnostics, where reliable results and fast processing is crucial. Additionally, these efforts will exert a decisive influence on traceability and reproducibility of sequence data.
Due to the success of DNA microarrays and the growing numbers of available protein expression clones, protein microarrays have become more and more popular for the high throughput screening of protein interactions. However, the widespread applicability of protein microarrays is currently hampered by the large effort associated with their production. Apart from the requirement for a protein expression library, expression and purification of the proteins themselves and the lacking stability of many proteins remain the bottleneck. Here we present an approach that allows the generation of high density protein microarrays from unbound DNA template molecules on the chip. It is based on the multiple spotting technique and comprises the deposition of a DNA template in a first spotting step and the transfer of a cell-free transcription and translation mixture on top of the same spot in a second spotting step. Using wild-type green fluorescent protein as a model protein, we demonstrated the time and template dependence of this coupled transcription and translation and showed that enough protein was produced to yield signals that were comparable to 300 g/ml spotted protein. Plasmids as well as unpurified PCR products can be used as templates, and as little as 35 fg of PCR product (ϳ22,500 molecules) were sufficient for the detectable expression of full-length wild-type green fluorescent protein in subnanoliter volumes. We showed that both aminopropyltrimethoxysilane and nickel chelate surfaces can be used for capture of the newly synthesized proteins. Surprisingly we observed that nickel chelate-coated slides were binding the newly synthesized proteins in an unspecific manner. Finally we adapted the system to the high throughput expression of libraries by designing a single primer pair for the introduction of the required T7 promoter and demonstrated the in situ expression using 384 randomly chosen clones. Molecular & Cellular Proteomics 5:1658 -1666, 2006.The understanding of complex cellular networks necessitates tools that are amenable to the analysis of different parameters in a highly parallel manner (1). Although in the last years DNA microarrays were the technology of choice to monitor the abundance of several thousands of mRNA transcripts at a time, such studies provide us with little information on the proteins that are encoded by these transcripts (2, 3). However, because proteins rather than DNA carry out cellular functions, there is large interest to analyze proteins and their entirety, the proteome, in a manner comparable to DNA microarrays. One technology that is envisaged to meet the demands of high throughput protein interaction and modification screening is protein microarray technology (4 -8).Protein microarrays have been applied in different areas of application, such as the analysis of protein-protein interactions (9 -11), the identification of substrates for protein kinases (12-14), or the elucidation of potential diagnostic markers in bacterial or autoimmune diseases (15-18). All of them share the bas...
The enzyme-linked immunosorbent assay (ELISA) is typically applied in the format of microtiter plates. To increase throughput and reduce consumption of precious samples, efforts have been made to transfer ELISA to the microchip format using conventional microarrays, microfluidic systems, and chips bearing microwells. However, all three formats lack the possibility to screen several analytes on several immobilized binders at a time or require complicated liquid handling, surface modifications, and additional equipment. Here, we describe an immunoassay performed on a standard microscope slide without the requirement for wells or tubes to separate the samples using standard surfaces and machinery already available for microarray technology. The new multiple spotting technique (MIST) comprises immobilization of a binder onto a surface and subsequent spotting of the second compound on the same spot, on top of the immobilized binder. We show that the analytes bind their ligands immediately within the confined space of separate droplets on the chip surface, thereby eliminating the need for extra incubation time. We illustrate the feasibility of the new technique by spotting dilution rows of proteins or monoclonal and polyclonal antibodies on top of their immobilized binders. Moreover, we demonstrate specificity by applying a mixture of antibodies in a multiplex format and demonstrate that the technique is compatible with conventional microarray protocols, such as total incubation. Finally, we indicate that the technique is capable of quantifying as little as 400 zmol (240,000 molecules) of analyte.
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