Your search keyword '"Sylvia Clausing"' showing total 4 results

1. The Helicase-Like Domains of Type III Restriction Enzymes Trigger Long-Range Diffusion Along DNA

Author

Júlia Tóth, Ralf Seidel, Guanshen Cui, Mark D. Szczelkun, Sylvia Clausing, Friedrich W. Schwarz, and Kara van Aelst

Subjects

DNA polymerase, DNA polymerase II, Article, 03 medical and health sciences, Adenosine Triphosphate, 0302 clinical medicine, DNA Cleavage, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, DNA ligase, Multidisciplinary, DNA clamp, biology, Hydrolysis, DNA Helicases, Helicase, DNA, Protein Structure, Tertiary, DNA binding site, Microscopy, Fluorescence, Biochemistry, chemistry, biology.protein, Nucleic Acid Conformation, DNA supercoil, Primase, Deoxyribonucleases, Type III Site-Specific, 030217 neurology & neurosurgery

Abstract

Sliding Restriction Helicase enzymes access the genetic information stored in double-helical DNA and RNA by opening the individual strands. Pseudo-helicases, including bacterial Type III restriction enzymes, use adenosine triphosphate (ATP) hydrolysis to communicate between two distant restriction sites on the same DNA and excise it only if the DNA is sensed as “foreign.” Schwarz et al. (p. 353 ) show that the bacterial Type III restriction enzyme, EcoP15I, undergoes an ATP-dependent conformational switch that promotes sliding along the DNA to allow the enzyme to localize to its target.

Published

2013

2. Phased full Length SMRT sequencing of HLA-DPB1

Author

Sylke Winkler, Christoph König, Carolin Zweiniger, Irina Boehme, Kathrin Lang, Nicola Gscheidel, Maarten T. Penning, Gerhard Schöfl, Erik H. Rozemuller, Alexander H. Schmidt, Yannick Duport, Sylvia Clausing, and Vinzenz Lange

Subjects

Genetics, HLA-DPB1, Sequence analysis, Immunology, Genotype, Consensus sequence, Immunology and Allergy, Locus (genetics), General Medicine, Biology, Amplicon, Genotyping, Single molecule real time sequencing

Abstract

Aim In contrast to exon-based HLA-typing approaches, whole gene genotyping crucially depends on full-length sequences submitted to the IMGT/HLA Database. Currently, full-length sequences are provided for only 7 out of 520 HLA-DPB1 alleles. Therefore, we developed a fully phased whole-gene sequencing approach for DPB1, to facilitate further exploration of the allelic structure at this locus. Methods Primers were developed flanking the UTR-regions of DPB1 resulting in a 12 kb amplicon. Using a 4-primer approach, secondary primers containing barcodes were combined with the gene-specific primers to obtain barcoded full-gene amplicons in a single amplification step. Amplicons were pooled, purified, and ligated to SMRT bells (i.e. annealing points for sequencing primers) following standard protocols from Pacific Biosciences. Taking advantage of the SMRT chemistry, pools of 48 amplicons were sequenced full length in single runs on a Pacific Biosciences RSII instrument. Demultiplexing was performed using the SMRT portal. Sequence analysis was performed using the NGSengine software (GenDx). Results We analyzed a set of 48 randomly picked samples. With 3 exceptions due to PCR failure, all genotype assignments conformed to standard genotyping results based on exons 2 and 3. Allelic proportions for heterozygous positions were evenly distributed (range 0.4–0.6) for all samples, suggesting unbiased amplifications. Despite the high per-read raw error rates typical for SMRT sequencing ( ∼ 15%) the consensus sequence proved highly reliable. All consensus sequences for exons 2 and 3 were in full accordance with their MiSeq-derived sequences. We describe novel intronic sequence variation of the 7 so far genomically defined alleles, as well as 7 whole-length DPB1 alleles with hitherto unknown intronic regions. One of these alleles (HLA-DPB1∗131:01) is classified as rare. Conclusion Here we present a whole gene amplification and sequencing workflow for DPB1 alleles utilizing single molecule real-time (SMRT) sequencing from Pacific Biosciences. Validation of consensus sequences against known exonic sequences highlights the reliability of this technology. This workflow will facilitate amending the IMGT/HLA Database for DPB1.

Published

2015

3. Full length phased sequencing of HLA class I samples reveals deeper insight in sequence variety

Author

Christoph König, Gerhard Schöfl, Andreas Dahl, Vinzenz Lange, Bianca Schoene, Yannick Duport, Kathrin Lang, Carolin Zweiniger, Alexander R. Schmidt, Irina Boehme, Nicola Gscheidel, Ines Wagner, Sylvia Clausing, and Juergen Sauter

Subjects

Genetics, Sequence analysis, Immunology, Haplotype, Consensus sequence, Immunology and Allergy, General Medicine, Biology, Amplicon, DNA sequencing, Exome sequencing, Deep sequencing, Single molecule real time sequencing

Abstract

Aim The vast majority of donor typing relies on sequencing exons 2 and 3 of HLA class I genes (HLA-A, -B, -C). With such an approach certain allele combinations do not result in the anticipated “high resolution” (G-code) typing, due to the lack of exon-phasing information. To resolve ambiguous typing results for a haplotype frequency project, we established a whole gene sequencing approach for HLA class I, facilitating also an estimation of the degree of sequence variability outside the commonly sequenced exons. Methods Primers were developed flanking the UTR regions resulting in similar amplicon lengths of 4.2–4.4 kb. Using a 4-primer approach, secondary primers containing barcodes were combined with the gene specific primers to obtain barcoded full-gene amplicons in a single amplification step. Amplicons were pooled, purified, and ligated to SMRT bells (i.e. annealing points for sequencing primers) following standard protocols from Pacific Biosciences. Taking advantage of the SMRT chemistry, pools of 48–72 amplicons were sequenced full length and phased in single runs on a Pacific Biosciences RSII instrument. Demultiplexing was achieved using the SMRT portal. Sequence analysis was performed using NGSengine software (GenDx). Results We successfully performed full-length gene sequencing of 1003 samples, harboring ambiguous typings of either HLA-A (n = 46), HLA-B (n = 304) or HLA-C (n = 653). Despite the high per-read raw error rates typical for SMRT sequencing ( ∼ 15%) the consensus sequence proved highly reliable. All consensus sequences for exons 2 and 3 were in full accordance with their MiSeq-derived sequences. Unambiguous allelic resolution was achieved for all samples. We observed novel intronic, exonic as well as UTR sequence variations for many of the alleles covered by our data set. This included sequences of 600 individuals with HLA-C∗07:01/C∗07:02 genotype revealing the extent of sequence variation outside the exons 2 and 3. Conclusion Here we present a whole gene amplification and sequencing approach for HLA class I genes. The maturity of this approach was demonstrated by sequencing more than 1000 samples, achieving fully phased allelic sequences. Extensive sequencing of one common allele combination hints at the yet to discover diversity of the HLA system outside the commonly analyzed exons.

Published

2015

4. Efficient preparation of internally modified single-molecule constructs using nicking enzymes

Author

Ralf Seidel, Sylvia Clausing, Friedrich W. Schwarz, Nicholas Luzzietti, Wolfgang Staroske, Daniel Klaue, and Hergen Brutzer

Subjects

chemistry.chemical_classification, Endodeoxyribonucleases, Base Sequence, Modified dna, DNA, Single-Stranded, DNA, Biology, Microscopy, Atomic Force, DNA metabolism, chemistry.chemical_compound, Enzyme, chemistry, Biochemistry, Genetics, Biophysics, Nucleic acid, biology.protein, Methods Online, Molecule, Ligation

Abstract

Investigations of enzymes involved in DNA metabolism have strongly benefited from the establishment of single molecule techniques. These experiments frequently require elaborate DNA substrates, which carry chemical labels or nucleic acid tertiary structures. Preparing such constructs often represents a technical challenge: long modified DNA molecules are usually produced via multi-step processes, involving low efficiency intermolecular ligations of several fragments. Here, we show how long stretches of DNA (>50 bp) can be modified using nicking enzymes to produce complex DNA constructs. Multiple different chemical and structural modifications can be placed internally along DNA, in a specific and precise manner. Furthermore, the nicks created can be resealed efficiently yielding intact molecules, whose mechanical properties are preserved. Additionally, the same strategy is applied to obtain long single-strand overhangs subsequently used for efficient ligation of ss- to dsDNA molecules. This technique offers promise for a wide range of applications, in particular single-molecule experiments, where frequently multiple internal DNA modifications are required.

Published

2010