Automation of the Precision ID NGS System for routine use

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Presentation transcript:

Automation of the Precision ID NGS System for routine use

with the Precision ID NGS System and the Ion Torrent Technology from Collaboration and Aim Collaboration Aim Develop a fully automated procedure for SNP, STR and Sequencing analyses with the Precision ID NGS System and the Ion Torrent Technology from Thermo Fisher Scientific, and with the MicroLab STAR Line from Hamilton

Workflow Partial Digestion of Amplicons Ligation of Barcodes/ Adapters to Libraries Purification Clonal Amplification Beads Enrichment Loading Chip PCR Setup and Librairies Preparation qPCR Setup and Libraries Quantification Libraries Normalization and Pooling Template Preparation Sequencing Data Analysis PCR Setup and Amplification Librairies Preparation qPCR Setup and Libraries Quantification Libraries Normalization and Pooling Template Preparation Sequencing Data Analysis

Semi-automated procedure PCR Setup and Amplification Librairies Preparation qPCR Setup and Libraries Quantification Libraries Normalization and Pooling Template Preparation Sequencing Data Analysis Automatic Automatic Automatic Manual (PCR setup) Manual Manual (PCR setup) Manual

Duration of semi-automated procedure 4 days to analyse 88 samples over a 5 days period 7 days to analyse 166 samples over a 8 days period

Semi-automated procedure PCR Setup and Amplification Librairies Preparation qPCR Setup and Libraries Quantification Libraries Normalization and Pooling Template Preparation Sequencing Data Analysis Many manual steps, no traceability, time-consuming and error risk AUTOMATION

Precision ID panels SNP Panels STR Panel Precision ID Identity Panel, 1 amplification per sample  1 library per sample Precision ID Ancestry Panel, 1 amplification per sample  1 library per sample STR Panel Precision ID GlobalFilerTM NGS STR Panel v2, 1 amplification per sample  1 library per sample Sequencing Panel (HV1/2/3 regions of mtDNA) Precision ID mtDNA Control Region Panel, 2 amplifications per sample  1 or 2 libraries per sample 3 analyses methods: Full : 2 amplifications per sample (20µl)  2 libraries per sample 2in1 : 2 amplifications per sample (20µl), pooling of 10µl of each amplification  1 library per sample Conservative : 2 amplifications per sample (10µl), pooling of these 2 amplifications  1 library per sample

Automation pre-PCR 3 Analyses (SNP, STR, Seq) 1 program Program PCR Setup and Amplification Librairies Preparation qPCR Setup and Libraries Quantification Libraries Normalization and Pooling Template Preparation Sequencing Data Analysis 3 Analyses (SNP, STR, Seq) 1 program Program PCR mix dispensing Samples dispensing 2 plate maps SNP, STR mtDNA (3 methods) From 1 to 88 samples From 1 to 48 samples From 49 to 88 samples Amplification 1 Amplification 2 Amplification 1 Amplification 2

Automation post-PCR Libraries Preparation Libraries qPCR setup PCR Setup and Amplification Librairies Preparation qPCR Setup and Libraries Quantification Libraries Normalization and Pooling Template Preparation Sequencing Data Analysis Libraries Preparation Libraries qPCR setup Libraries Normalization & Pooling

Automation post-PCR mtDNA and SNP libraries can be prepared together PCR Setup and Amplification Librairies Preparation qPCR Setup and Libraries Quantification Libraries Normalization and Pooling Template Preparation Sequencing Data Analysis Samples worklist Adapter/barcode worklist mtDNA and SNP libraries can be prepared together but STR libraries must be prepared separately 4 steps : 1. Pooling of amplicons (mtDNA CR panel) 2. Partial digestion of amplicons 3. Ligation of barcodes/adapters to amplicons 4. Libraries purification 2 worklists generate manually or by a LIMS 1. Samples worklist (.csv file) 2. Barcode/adapter worklist (.csv file)

Automation post-PCR 3 steps : 1. Libraries and standard dilution PCR Setup and Amplification Librairies Preparation qPCR Setup and Libraries Quantification Libraries Normalization and Pooling Template Preparation Sequencing Data Analysis Samples worklist 3 steps : 1. Libraries and standard dilution 2. PCR mix dispensing 3. Libraries and standard dispensing 1 samples worklist (.csv file) Samples file (.txt) for 7500 generate automatically by the program Samples file for 7500

Automation post-PCR 3 steps : 1. Data file import from 7500 and PCR Setup and Amplification Librairies Preparation qPCR Setup and Libraries Quantification Libraries Normalization and Pooling Template Preparation Sequencing Data Analysis 3 steps : 1. Data file import from 7500 and automatic dilution factor determination for each library 2. Libraries dilution 3. Libraries pooling Pool of libraries ready for the run template (pooling of different pools is possible but make sure that there are no two different samples with the same barcode) Data file from 7500

Duration of automated procedure 2 days to analyse 88 samples over a 3 days period (vs 4 days over a 5 days period) 3.5 days to analyse 166 samples over a 4 days period (vs 7 days over a 8 days period)

Automated procedure test 429 hair analysed in mtDNA (Precision ID mtDNA Control Region panel) 200 hair analysed with the semi-automated precedure 229 hair analysed with the automated precedure Lysis and DNA extraction with the Crime PrepAdem kit from Ademetch mtDNA quantification by an inhouse method mtDNA normalization to 50 mtDNA copies/µl All positive samples in mtDNA (QmtDNA ≥ 2.5 copies/µl) have been analysed in MPS with the conservative method (7.5 to 150 mtDNA copies/amplification and 26 PCR cycles) Templates preparation  Ion Chef, and Sequencing  Ion S5 Sequencing data analysis  mtDNA plugin

Results

Conclusion Semi-automated procedure and automated procedure : same performance Automation onto Hamilton STARlet significantly reduces the preparation time of libraries with a full traceability and without error risk Only one automated procedure for SNP, STR and Sequencing analyses Programs flexibility (from 1 to 88 libraries prepared at the same time) Very high success rate with the semi-automated procedure and the automated procedure by using the Precision ID mtDNA Control Region panel and the Ion Torrent technology, higher than with the conventional procedure Validation of the automated procedure in progress for SNP, STR and Sequencing analyses

Acknowledgement Thierry Jurado Chantal Roth Claire Bartholini Matt Phipps Gareth Stead Lionel Ausset Jörg Breitling Fabio Grasso Speaker was provided travel and hotel support by Thermo Fisher Scientific for this presentation, but no remuneration When used for purposes other than Human Identification or Paternity Testing the instruments and software modules cited are for Research Use Only. Not for use in diagnostic procedures. Thermo Fisher Scientific and its affiliates are not endorsing, recommending, or promoting any use or application of Thermo Fisher Scientific products presented by third parties during this seminar. Information and materials presented or provided by third parties are provided as-is and without warranty of any kind, including regarding intellectual property rights and reported results. Parties presenting images, text and material represent they have the rights