Your search keyword '"Bredeweg EL"' showing total 2 results

1. Strain Construction for Intracellular Metabolic Pathway Localization in Y. lipolytica.

Author

Bredeweg EL and Baker SE

Subjects

DNA End-Joining Repair, Metabolic Networks and Pathways, Plasmids genetics, Yarrowia genetics, Fungal Proteins genetics, Transformation, Genetic, Yarrowia growth & development

Abstract

Pathway localization by fluorophore or epitope tagging can be accomplished through a multi-staged DNA construct and confirmation process, to generate a series of successfully tagged protein targets. Prerequisite conditions for this process in Y. lipolytica are auxotrophic selection (leu2 or ura3), impaired non-homologous end joining by deletion or impairment of ku70, and plasmids or gene pieces for epitope-selection cassette construction. The general approach for gene tagging can work for C- or N-terminal tags. Gene overexpression from an episomal plasmid can be accomplished through transcript amplification and cloning. C-terminal tagging allows expression of a gene-GFP fusion to be regulated from the endogenous promoter. The epitope-selection cassette also includes a constitutive or highly expressed promoter driving the auxotrophic or other selectable marker gene such as one conferring antifungal or antibiotic resistance. Strains for pathway localization utilize overlap PCR, PEG-based transformation, and a fast DNA preparation for rapid colony screening. Successful transformants can be used for pathway localization and condition-specific response analysis.

Published

2021

2. Library preparation and data analysis packages for rapid genome sequencing.

Author

Pomraning KR, Smith KM, Bredeweg EL, Connolly LR, Phatale PA, and Freitag M

Subjects

Chromatin Immunoprecipitation, DNA genetics, DNA Repair, Gene Expression Profiling, INDEL Mutation genetics, Polymorphism, Single Nucleotide genetics, Software, Sonication, Time Factors, Gene Library, Genomics methods, High-Throughput Nucleotide Sequencing methods, Sequence Analysis, DNA methods, Statistics as Topic methods

Abstract

High-throughput sequencing (HTS) has quickly become a valuable tool for comparative genetics and genomics and is now regularly carried out in laboratories that are not connected to large sequencing centers. Here we describe an updated version of our protocol for constructing single- and paired-end Illumina sequencing libraries, beginning with purified genomic DNA. The present protocol can also be used for "multiplexing," i.e. the analysis of several samples in a single flowcell lane by generating "barcoded" or "indexed" Illumina sequencing libraries in a way that is independent from Illumina-supported methods. To analyze sequencing results, we suggest several independent approaches but end users should be aware that this is a quickly evolving field and that currently many alignment (or "mapping") and counting algorithms are being developed and tested.

Published

2012