Ultra long dna sequencing kit

Manufactured by Oxford Nanopore

Sourced in United Kingdom

The Ultra-Long DNA Sequencing kit is a laboratory instrument designed for the sequencing of long DNA molecules. It utilizes Oxford Nanopore's proprietary technology to provide long-read sequencing capabilities. The core function of this kit is to enable the analysis and study of complex genetic samples.

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Lab products found in correlation

Rapid sequencing kit, by Oxford Nanopore (1 mentions) Rapid barcoding kit, by Oxford Nanopore (1 mentions) Sqk rad004, by Oxford Nanopore (1 mentions) Minion r9.4 flow cells, by Oxford Nanopore (1 mentions) Sqk rbk004, by Oxford Nanopore (1 mentions) Paired end 150 bp sequencing pe150, by Illumina (1 mentions)

2 protocols using ultra long dna sequencing kit

Targeted Sequencing of HPV16 in Cell Lines

Cited 2 times

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For ligation sequencing 1 ug of cell line DNA was sheared to 8–20 kb with a G-tube (Covaris) or used unsheared with the LSK-109 kit. Targeted sequencing of HPV16 was carried out in CaSki and SiHa cells using CRISPR probes to HPV16 probes (Supplementary Table S1). For transposase sequencing of cell lines, 1 ug was used with the Rapid Sequencing kit (SQK-RAD004, Oxford Nanopore). CaSki and SNU-1000 DNA was also prepared using the Ultra-Long protocol of Circulomics and the Ultra-Long DNA Sequencing kit (SQK-ULK001, Oxford Nanopore) with and without adaptive sampling (35 (link),36 (link)) using a combined human HG38/high-risk HPV FASTA file selecting for cancer genes, integration loci, and HPV.
Tumor DNAs (0.3 ug) were sequenced using the Rapid Barcoding kit (SQK-RBK004, Oxford Nanopore). A total of 30–50 fM of DNA was loaded onto MinIon R9.4 flow cells (Oxford Nanopore).

Lin M.H., Nguyen H.T., Dybala C, & Storti R.V. (1996). Myocyte-specific enhancer factor 2 acts cooperatively with a muscle activator region to regulate Drosophila tropomyosin gene muscle expression.. Proceedings of the National Academy of Sciences of the United States of America, 93(10), 4623-4628.

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Genome sequencing of Spiroplasma strain sHm

Cited 3 times

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For genome sequencing of strain sHm, high molecular weight DNA was extracted from the egg masses of S+ line moths using Nanobind Tissue Big DNA Kit (Circulomics Inc., MD, USA) and used for library construction using Ultra-Long DNA Sequencing Kit (Oxford Nanopore Technologies, Oxford, UK) following the manufacture’s protocol. The constructed libraries were sequenced using ONT MinION flow cell (R 9.4.1) (Oxford Nanopore Technologies). The obtained reads were mapped to the H. magnanima reference genome (Jouraku et al., in preparation) with minimap2 (Li, 2018 (link)), and the non-mapped reads containing Spiroplasma reads were extracted with SAMtools v.1.9 (Li et al., 2009 (link)) and assembled using Canu 1.6 (Koren et al., 2017 (link)). The draft Spiroplasma genome (a circular main chromosome and plasmids) was annotated via BLASTn (NCBI nr database). The extracted DNA was also subjected to Illumina paired-end 150 bp sequencing (PE-150) at Novogene (Beijing, China). The Illumina data were used to polish the draft genome using minimap2 (Li, 2018 (link)) and Pilon v. 1.23 (Walker et al., 2014 (link)). Since no sequence changes were observed after the second polishing, the polished genome was considered as the complete genome of strain sHm. The circularity of the sHm genome was confirmed by BLASTn search, followed by manual deletion of overlapping sequence.

Arai H., Inoue M.N, & Kageyama D. (2022). Male-killing mechanisms vary between Spiroplasma species. Frontiers in Microbiology, 13, 1075199.

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