Abstract
BackgroundLigation-mediated PCR protocols have diverse uses including the identification of integration sites of insertional mutagens, integrating vectors and naturally occurring mobile genetic elements. For approaches that employ NGS sequencing, the relative abundance of integrations within a complex mixture is typically determined through the use of read counts or unique fragment lengths from a ligation of sheared DNA; however, these estimates may be skewed by PCR amplification biases and saturation of sequencing coverage.ResultsHere we describe a modification of our previous splinkerette based ligation-mediated PCR using a novel Illumina-compatible adapter design that prevents amplification of non-target DNA and incorporates unique molecular identifiers. This design reduces the number of PCR cycles required and improves relative quantitation of integration abundance for saturating sequencing coverage. By inverting the forked adapter strands from a standard orientation, the integration-genome junction can be sequenced without affecting the sequence diversity required for cluster generation on the flow cell. Replicate libraries of murine leukemia virus-infected spleen samples yielded highly reproducible quantitation of clonal integrations as well as a deep coverage of subclonal integrations. A dilution series of DNAs bearing integrations of MuLV or piggyBac transposon shows linearity of the quantitation over a range of concentrations.ConclusionsMerging ligation and library generation steps can reduce total PCR amplification cycles without sacrificing coverage or fidelity. The protocol is robust enough for use in a 96 well format using an automated liquid handler and we include programs for use of a Beckman Biomek liquid handling workstation. We also include an informatics pipeline that maps reads, builds integration contigs and quantitates integration abundance using both fragment lengths and unique molecular identifiers. Suggestions for optimizing the protocol to other target DNA sequences are included. The reproducible distinction of clonal and subclonal integration sites from each other allows for analysis of populations of cells undergoing selection, such as those found in insertional mutagenesis screens.
Highlights
Ligation-mediated Polymerase chain reaction (PCR) protocols have diverse uses including the identification of integration sites of insertional mutagens, integrating vectors and naturally occurring mobile genetic elements
Unlike standard Illumina adapters, the PCR primers have no template to bind until after the first strand has been synthesized, similar to the approach used for vectorette/ splinkerette PCR protocols [4, 5]
The secondary PCR primer against the long terminal repeat (LTR) sequence incorporates a sequence that is capable of binding the flow cell
Summary
Ligation-mediated PCR protocols have diverse uses including the identification of integration sites of insertional mutagens, integrating vectors and naturally occurring mobile genetic elements. Ligation-mediated PCR methods have diverse applications in identifying the integration sites of a known DNA sequence at an unknown locus. In many protocols the use of non-complementary forked or bubble adapters, such as vectorette and splinkerette, limits the first round of DNA synthesis to the target sequence primer [4, 5]. After this has occurred can the adapter primer bind to a template and give rise to exponential amplification of target regions. Chemical blocking of a shortened lower strand adapter 3′ terminus can be incorporated such that it is unable to act as a primer for template extension [6]
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