Markus Beier scite author profile

Small noncoding RNAs (sncRNAs) have moved from oddity to recognized important players in gene regulation. Next generation sequencing approaches discover more and more such molecules from a variety of different groups, but flexible tools translating this sequence information into affordable high-throughput assays are missing. Here we describe a microfluidic primer extension assay (MPEA) for the detection of sncRNAs on highly flexible microfluidic microarrays which combines several beneficial parameters: it can effortless incorporate any new sequence information; it is sensitive enough to work with as little as 20ng of total RNA and has a high level of specificity owing to a combination of a conventional hybridization assay and an enzymatic elongation step. Importantly, no labeling step is needed before hybridization and - because of its high sensitivity - no amplification is required. Both aspects ensure that no bias is introduced by such processes. Although the assay is exemplified with miRNAs, the flexibility of the technology platform allows the analysis of any type of sncRNA, such as piRNAs.

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Targeted next-generation sequencing by specific capture of multiple genomic loci using low-volume microfluidic DNA arrays

Bau¹,

Schracke²,

Kränzle³

et al. 2008

Anal Bioanal Chem

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We report a flexible method for selective capture of sequence fragments from complex, eukaryotic genome libraries for next-generation sequencing based on hybridization to DNA microarrays. Using microfluidic array architecture and integrated hardware, the process is amenable to complete automation and does not introduce amplification steps into the standard library preparation workflow, thereby avoiding bias of sequence distribution and fragment lengths. We captured a discontiguous human genomic target region of 185 kb using a tiling design with 50mer probes. Analysis by high-throughput sequencing using an Illumina/Solexa 1G Genome Analyzer revealed 2150-fold enrichment with mean per base coverage between 4.6 and 107.5-fold for the individual target regions. This method represents a flexible and cost-effective approach for large-scale resequencing of complex genomes.

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Microarray-based multicycle-enrichment of genomic subsets for targeted next-generation sequencing

Summerer¹,

Wu²,

Haase³

et al. 2009

Genome Res.

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The lack of efficient high-throughput methods for enrichment of specific sequences from genomic DNA represents a key bottleneck in exploiting the enormous potential of next-generation sequencers. Such methods would allow for a systematic and targeted analysis of relevant genomic regions. Recent studies reported sequence enrichment using a hybridization step to specific DNA capture probes as a possible solution to the problem. However, so far no method has provided sufficient depths of coverage for reliable base calling over the entire target regions. We report a strategy to multiply the enrichment performance and consequently improve depth and breadth of coverage for desired target sequences by applying two iterative cycles of hybridization with microfluidic Geniom biochips. Using this strategy, we enriched and then sequenced the cancer-related genes BRCA1 and TP53 and a set of 1000 individual dbSNP regions of 500 bp using Illumina technology. We achieved overall enrichment factors of up to 1062-fold and average coverage depths of 470-fold. Combined with high coverage uniformity, this resulted in nearly complete consensus coverages with >86% of target region covered at 20-fold or higher. Analysis of SNP calling accuracies after enrichment revealed excellent concordance, with the reference sequence closely mirroring the previously reported performance of Illumina sequencing conducted without sequence enrichment.

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Nucleotides, Part LXII, Pyridinium Salts - An Effective Class of Catalysts for Oligonucleotide Synthesis

Beier

Pfleiderer

1999

HCA

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Synthesis of Photolabile 5′-O-Phosphoramidites for the Photolithographic Production of Microarrays of Inversely Oriented Oligonucleotides

Beier

Stephan

Hoheisel³

2001

HCA

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The photolabile 3′‐O‐{[2‐(2‐nitrophenyl)propoxy]carbonyl}‐protected 5′‐phosphoramidites (16 – 18) were synthesized (see Scheme) for an alternative mode of light‐directed production of oligonucleotide arrays. Because of the characteristics of these monomeric building blocks, photolithographic in situ DNA synthesis occurred in 5′→3′ direction, in agreement with the orientation of enzymatic synthesis. Synthesis yields were as good as those of conventional reactions. The resulting oligonucleotides are attached to the surface via their 5′‐termini, while the 3′‐hydroxy groups are available as substrates for enzymatic reactions such as primer extension upon hybridization of a DNA template (see Fig. 2). The production of such oligonucleotide chips adds new procedural avenues to the growing number of applications of DNA microarrays.

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Nucleotides, Part LXI, Phthaloyl Strategy: A New Concept of Oligonucleotide Synthesis

Beier

Pfleiderer

1999

HCA

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Geniom® Technology—The Benchtop Array Facility

Güimil¹,

Beier²,

Scheffler³

et al. 2003

Nucleosides, Nucleotides and Nucleic Acids

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Phthaloyl Strategy—A New Approach Towards Oligodeoxyribonucleotide Synthesis

Beier

Pfleiderer

1997

Nucleosides and Nucleotides

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Markus Beier

Microfluidic-based enzymatic on-chip labeling of miRNAs

Targeted next-generation sequencing by specific capture of multiple genomic loci using low-volume microfluidic DNA arrays

Microarray-based multicycle-enrichment of genomic subsets for targeted next-generation sequencing

Nucleotides, Part LXII, Pyridinium Salts - An Effective Class of Catalysts for Oligonucleotide Synthesis

Synthesis of Photolabile 5′-O-Phosphoramidites for the Photolithographic Production of Microarrays of Inversely Oriented Oligonucleotides

Nucleotides, Part LXI, Phthaloyl Strategy: A New Concept of Oligonucleotide Synthesis

Geniom® Technology—The Benchtop Array Facility

Phthaloyl Strategy—A New Approach Towards Oligodeoxyribonucleotide Synthesis

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