Your search keyword '"Gross TE"' showing total 15 results

1. Development and validation of the VISAGE AmpliSeq basic tool to predict appearance and ancestry from DNA

Author

Xavier, C, de La Puente, M, Mosquera-Miguel, A, Freire-Aradas, A, Kalamara, Vivian, Vidaki, Athina, Gross, TE, Revoir, A, Pospiech, E, Kartasinska, E, Spolnicka, M, Branicki, W, Ames, CE, Schneider, PM, Hohoff, C, Kayser, Manfred, Phillips, C, Parson, W, Xavier, C, de La Puente, M, Mosquera-Miguel, A, Freire-Aradas, A, Kalamara, Vivian, Vidaki, Athina, Gross, TE, Revoir, A, Pospiech, E, Kartasinska, E, Spolnicka, M, Branicki, W, Ames, CE, Schneider, PM, Hohoff, C, Kayser, Manfred, Phillips, C, and Parson, W

Published

2020

2. Forensic ancestry analysis with two capillary electrophoresis ancestry informative marker (AIM) panels: Results of a collaborative EDNAP exercise

Author

Santos, C, Fondevila, M, Ballard, D, Banemann, R, Bento, AM, Børsting, C, Branicki, W, BRISIGHELLI, FRANCESCA, Burrington, M, Capal, T, Chaitanya, L, Daniel, R, Decroyer, V, England, R, Gettings, KB, Gross, TE, Haas, C, Harteveld, J, Hoff-Olsen, P, Hoffmann, A, Kayser, M, Kohler, P, Linacre, A, Mayr-Eduardoff, M, McGovern, C, Morling, N, O'Donnell, G, Parson, W, Pascali, VL, Porto, MJ, Roseth, A, Schneider, PM, Sijen, T, Stenzl, V, Court, DS, Templeton, JE, Turanska, M, Vallone, PM, van Oorschot, RAH, Zatkalikova, L, Carracedo, Á, Phillips, C, Santos, C, Fondevila, M, Ballard, D, Banemann, R, Bento, AM, Børsting, C, Branicki, W, BRISIGHELLI, FRANCESCA, Burrington, M, Capal, T, Chaitanya, L, Daniel, R, Decroyer, V, England, R, Gettings, KB, Gross, TE, Haas, C, Harteveld, J, Hoff-Olsen, P, Hoffmann, A, Kayser, M, Kohler, P, Linacre, A, Mayr-Eduardoff, M, McGovern, C, Morling, N, O'Donnell, G, Parson, W, Pascali, VL, Porto, MJ, Roseth, A, Schneider, PM, Sijen, T, Stenzl, V, Court, DS, Templeton, JE, Turanska, M, Vallone, PM, van Oorschot, RAH, Zatkalikova, L, Carracedo, Á, and Phillips, C

Published

2015

3. Collaborative EDNAP exercise on the IrisPlex system for DNA-based prediction of human eye colour

Author

Chaitanya, L, Walsh, S, Andersen, Jd, Ansell, R, Ballantyne, K, Ballard, D, Banemann, R, Bauer, Cm, Bento, Am, Brisighelli, Francesca, Capal, T, Clarisse, L, Gross, Te, Haas, C, Hoff Olsen, P, Hollard, C, Keyser, C, Kiesler, Km, Kohler, P, Kupiec, T, Linacre, A, Minawi, A, Morling, N, Nilsson, H, Norén, L, Ottens, R, Palo, Ju, Parson, W, Pascali, Vincenzo Lorenzo, Phillips, C, Porto, Mj, Sajantila, A, Schneider, Pm, Sijen, T, Söchtig, J, Syndercombe Court, D, Tillmar, A, Turanska, M, Vallone, Pm, Zatkalíková, L, Zidkova, A, Branicki, W, Kayser, M., Brisighelli, Francesca (ORCID:0000-0001-5469-4413), Pascali, Vincenzo Lorenzo (ORCID:0000-0001-6520-5224), Chaitanya, L, Walsh, S, Andersen, Jd, Ansell, R, Ballantyne, K, Ballard, D, Banemann, R, Bauer, Cm, Bento, Am, Brisighelli, Francesca, Capal, T, Clarisse, L, Gross, Te, Haas, C, Hoff Olsen, P, Hollard, C, Keyser, C, Kiesler, Km, Kohler, P, Kupiec, T, Linacre, A, Minawi, A, Morling, N, Nilsson, H, Norén, L, Ottens, R, Palo, Ju, Parson, W, Pascali, Vincenzo Lorenzo, Phillips, C, Porto, Mj, Sajantila, A, Schneider, Pm, Sijen, T, Söchtig, J, Syndercombe Court, D, Tillmar, A, Turanska, M, Vallone, Pm, Zatkalíková, L, Zidkova, A, Branicki, W, Kayser, M., Brisighelli, Francesca (ORCID:0000-0001-5469-4413), and Pascali, Vincenzo Lorenzo (ORCID:0000-0001-6520-5224)

Abstract

The IrisPlex system is a DNA-based test system for the prediction of human eye colour from biological samples and consists of a single forensically validated multiplex genotyping assay together with a statistical prediction model that is based on genotypes and phenotypes from thousands of individuals. IrisPlex predicts blue and brown human eye colour with, on average, >94% precision accuracy using six of the currently most eye colour informative single nucleotide polymorphisms (HERC2 rs12913832, OCA2 rs1800407, SLC24A4 rs12896399, SLC45A2 (MATP) rs16891982, TYR rs1393350, and IRF4 rs12203592) according to a previous study, while the accuracy in predicting non-blue and non-brown eye colours is considerably lower. In an effort to vigorously assess the IrisPlex system at the international level, testing was performed by 21 laboratories in the context of a collaborative exercise divided into three tasks and organised by the European DNA Profiling (EDNAP) Group of the International Society of Forensic Genetics (ISFG). Task 1 involved the assessment of 10 blood and saliva samples provided on FTA cards by the organising laboratory together with eye colour phenotypes; 99.4% of the genotypes were correctly reported and 99% of the eye colour phenotypes were correctly predicted. Task 2 involved the assessment of 5 DNA samples extracted by the host laboratory from simulated casework samples, artificially degraded, and provided to the participants in varying DNA concentrations. For this task, 98.7% of the genotypes were correctly determined and 96.2% of eye colour phenotypes were correctly inferred. For Tasks 1 and 2 together, 99.2% (1875) of the 1890 genotypes were correctly generated and of the 15 (0.8%) incorrect genotype calls, only 2 (0.1%) resulted in incorrect eye colour phenotypes. The voluntary Task 3 involved participants choosing their own test subjects for IrisPlex genotyping and eye colour phenotype inference, while eye photographs were provided to the organising la

Published

2014

4. Development and evaluations of the ancestry informative markers of the VISAGE Enhanced Tool for Appearance and Ancestry.

Author

Ruiz-Ramírez J, de la Puente M, Xavier C, Ambroa-Conde A, Álvarez-Dios J, Freire-Aradas A, Mosquera-Miguel A, Ralf A, Amory C, Katsara MA, Khellaf T, Nothnagel M, Cheung EYY, Gross TE, Schneider PM, Uacyisrael J, Oliveira S, Klautau-Guimarães MDN, Carvalho-Gontijo C, Pośpiech E, Branicki W, Parson W, Kayser M, Carracedo A, Lareu MV, and Phillips C

Subjects

Humans, Male, Genotype, Haplotypes, Middle East, Polymorphism, Single Nucleotide, High-Throughput Nucleotide Sequencing, Genetics, Population, Gene Frequency, DNA, DNA Fingerprinting

Abstract

The VISAGE Enhanced Tool for Appearance and Ancestry (ET) has been designed to combine markers for the prediction of bio-geographical ancestry plus a range of externally visible characteristics into a single massively parallel sequencing (MPS) assay. We describe the development of the ancestry panel markers used in ET, and the enhanced analyses they provide compared to previous MPS-based forensic ancestry assays. As well as established autosomal single nucleotide polymorphisms (SNPs) that differentiate sub-Saharan African, European, East Asian, South Asian, Native American, and Oceanian populations, ET includes autosomal SNPs able to efficiently differentiate populations from Middle East regions. The ability of the ET autosomal ancestry SNPs to distinguish Middle East populations from other continentally defined population groups is such that characteristic patterns for this region can be discerned in genetic cluster analysis using STRUCTURE. Joint cluster membership estimates showing individual co-ancestry that signals North African or East African origins were detected, or cluster patterns were seen that indicate origins from central and Eastern regions of the Middle East. In addition to an augmented panel of autosomal SNPs, ET includes panels of 85 Y-SNPs, 16 X-SNPs and 21 autosomal Microhaplotypes. The Y- and X-SNPs provide a distinct method for obtaining extra detail about co-ancestry patterns identified in males with admixed backgrounds. This study used the 1000 Genomes admixed African and admixed American sample sets to fully explore these enhancements to the analysis of individual co-ancestry. Samples from urban and rural Brazil with contrasting distributions of African, European, and Native American co-ancestry were also studied to gauge the efficiency of combining Y- and X-SNP data for this purpose. The small panel of Microhaplotypes incorporated in ET were selected because they showed the highest levels of haplotype diversity amongst the seven population groups we sought to differentiate. Microhaplotype data was not formally combined with single-site SNP genotypes to analyse ancestry. However, the haplotype sequence reads obtained with ET from these loci creates an effective system for de-convoluting two-contributor mixed DNA. We made simple mixture experiments to demonstrate that when the contributors have different ancestries and the mixture ratios are imbalanced (i.e., not 1:1 mixtures) the ET Microhaplotype panel is an informative system to infer ancestry when this differs between the contributors., (Copyright © 2023 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2023

5. Development and inter-laboratory evaluation of the VISAGE Enhanced Tool for Appearance and Ancestry inference from DNA.

Author

Xavier C, de la Puente M, Mosquera-Miguel A, Freire-Aradas A, Kalamara V, Ralf A, Revoir A, Gross TE, Schneider PM, Ames C, Hohoff C, Phillips C, Kayser M, and Parson W

Subjects

Humans, Male, Genetic Markers, Reproducibility of Results, Phenotype, DNA genetics, Polymorphism, Single Nucleotide

Abstract

Responding to the growing scientific and practical interest in forensic DNA phenotyping, the VISible Attributes through GEnomics (VISAGE) Consortium was founded in 2017 with the main goal of developing and validating new and reliable molecular and statistical tools to predict appearance, ancestry and age from DNA. Here, we describe the development and inter-laboratory evaluation and validation of the VISAGE Enhanced Tool for Appearance and Ancestry inference from DNA. The VISAGE Enhanced Tool for Appearance and Ancestry is the first forensic-driven genetic laboratory tool that comprises well-established markers for eye, hair and skin color with more recently discovered DNA markers for eyebrow color, freckling, hair shape and male pattern baldness and bio-geographic ancestry informative DNA markers. The bio-geographic ancestry markers include autosomal SNPs (bi- and tri-allelic SNPs), X-SNPs, Y-SNPs and autosomal Microhaplotypes. In total, primers targeting 524 SNPs (representing a 97.6% assay conversion rate) were successfully designed using AmpliSeq into a single primer pool (i.e., one multiplex assay) and sequenced with the Ion S5. In a collaborative framework, five VISAGE laboratories tested the VISAGE Enhanced Tool for Appearance and Ancestry on reproducibility, sensitivity, genotyping concordance, mixtures, species specificity and performance in relevant forensic conditions, including inhibitor-spiked, mock casework and artificially degraded samples. Based on our results, the VISAGE Enhanced Tool for Appearance and Ancestry is a robust, reproducible, and - for the large SNP number - fairly sensitive MPS assay with high concordance rates. With the VISAGE Enhanced Tool for Appearance and Ancestry introduced here, the VISAGE Consortium delivers the first single DNA-test for combined appearance prediction based on seven traits together with bio-geographic ancestry inference based on major continental regions for separated bi-parental and paternal ancestry, which represents the most comprehensive validated laboratory tool currently available for Forensic DNA Phenotyping., Competing Interests: Conflict of interest statement The authors declare no conflicts of interest., (Copyright © 2022 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2022

6. Variant interpretation in molecular autopsy: a useful dilemma.

Author

Scheiper-Welling S, Tabunscik M, Gross TE, Jenewein T, Beckmann BM, Niess C, Gradhand E, Wunder C, Schneider PM, Rothschild MA, Verhoff MA, and Kauferstein S

Subjects

Adolescent, Autopsy, Cohort Studies, High-Throughput Nucleotide Sequencing, Humans, Young Adult, Death, Sudden, Cardiac etiology, Genetic Testing

Abstract

Sudden cardiac death (SCD) in adolescents and young adults may be the first manifestation of an inherited arrhythmic syndrome. Thus identification of a genetic origin in sudden death cases deemed inconclusive after a comprehensive autopsy and may help to reduce the risk of lethal episodes in the remaining family. Using next-generation sequencing (NGS), a large number of variants of unknown significance (VUS) are detected. In the majority of cases, there is insufficient evidence of pathogenicity, representing a huge dilemma in current genetic investigations. Misinterpretation of such variants may lead to inaccurate genetic diagnoses and/or the adoption of unnecessary and/or inappropriate therapeutic approaches. In our study, we applied current (ACMG) recommendations for variant classification in post-mortem genetic screening of a cohort of 56 SCD victims. We identified a total 53 rare protein-altering variants (MAF < 0.2%) classified as VUS or worse. Twelve percent of the cases exhibited a clinically actionable variant (pathogenic, likely pathogenic or VUS - potentially pathogenic) that would warrant cascade genetic screening in relatives. Most of the variants detected by means of the post-mortem genetic investigations were VUS. Thus, genetic testing by itself might be fairly meaningless without supporting background data. This data reinforces the need for an experienced multidisciplinary team for obtaining reliable and accountable interpretations of variant significance for elucidating potential causes for SCDs in the young. This enables the early identification of relatives at risk or excludes family members as genetic carriers. Also, development of adequate forensic guidelines to enable appropriate interpretation of rare genetic variants is fundamental., (© 2021. The Author(s).)

Published

2022

7. Development and Evaluation of the Ancestry Informative Marker Panel of the VISAGE Basic Tool.

Author

de la Puente M, Ruiz-Ramírez J, Ambroa-Conde A, Xavier C, Pardo-Seco J, Álvarez-Dios J, Freire-Aradas A, Mosquera-Miguel A, Gross TE, Cheung EYY, Branicki W, Nothnagel M, Parson W, Schneider PM, Kayser M, Carracedo Á, Lareu MV, Phillips C, and On Behalf Of The Visage Consortium

Subjects

Africa, Americas, Europe, Female, Gene Frequency, Genotype, High-Throughput Nucleotide Sequencing, Humans, Male, Oceania, Polymorphism, Single Nucleotide genetics, Ethnicity genetics, Forensic Genetics, Genetics, Population, Racial Groups genetics

Abstract

We detail the development of the ancestry informative single nucleotide polymorphisms (SNPs) panel forming part of the VISAGE Basic Tool (BT), which combines 41 appearance predictive SNPs and 112 ancestry predictive SNPs (three SNPs shared between sets) in one massively parallel sequencing (MPS) multiplex, whereas blood-based age analysis using methylation markers is run in a parallel MPS analysis pipeline. The selection of SNPs for the BT ancestry panel focused on established forensic markers that already have a proven track record of good sequencing performance in MPS, and the overall SNP multiplex scale closely matched that of existing forensic MPS assays. SNPs were chosen to differentiate individuals from the five main continental population groups of Africa, Europe, East Asia, America, and Oceania, extended to include differentiation of individuals from South Asia. From analysis of 1000 Genomes and HGDP-CEPH samples from these six population groups, the BT ancestry panel was shown to have no classification error using the Bayes likelihood calculators of the Snipper online analysis portal. The differentiation power of the component ancestry SNPs of BT was balanced as far as possible to avoid bias in the estimation of co-ancestry proportions in individuals with admixed backgrounds. The balancing process led to very similar cumulative population-specific divergence values for Africa, Europe, America, and Oceania, with East Asia being slightly below average, and South Asia an outlier from the other groups. Comparisons were made of the African, European, and Native American estimated co-ancestry proportions in the six admixed 1000 Genomes populations, using the BT ancestry panel SNPs and 572,000 Affymetrix Human Origins array SNPs. Very similar co-ancestry proportions were observed down to a minimum value of 10%, below which, low-level co-ancestry was not always reliably detected by BT SNPs. The Snipper analysis portal provides a comprehensive population dataset for the BT ancestry panel SNPs, comprising a 520-sample standardised reference dataset; 3445 additional samples from 1000 Genomes, HGDP-CEPH, Simons Foundation and Estonian Biocentre genome diversity projects; and 167 samples of six populations from in-house genotyping of individuals from Middle East, North and East African regions complementing those of the sampling regimes of the other diversity projects.

Published

2021

8. Progress in the implementation of massively parallel sequencing for forensic genetics: results of a European-wide survey among professional users.

Author

Gross TE, Fleckhaus J, and Schneider PM

Subjects

Europe, Forensic Genetics education, Humans, Laboratories organization & administration, Surveys and Questionnaires, DNA Fingerprinting methods, Forensic Genetics methods, High-Throughput Nucleotide Sequencing, Sequence Analysis, DNA

Abstract

A European-wide online survey was conducted to generate an overview on the state-of-the-art using massively parallel sequencing (MPS) platforms for forensic DNA analysis and DNA phenotyping among forensic practitioners in Europe. The survey was part of the dissemination activities of the "VISible Attributes through GEnomics - VISAGE" Horizon 2020 funded European research project [30], in preparation of a series of educational training activities. A total of 105 replies from 32 European countries representing participants from police, governmental, academic, and private laboratories providing professional services in the field of forensic genetics were included in the final analysis. Of these, 73% already own an MPS platform or are planning to acquire one within the next 1-2 years. One-third of the participants have already carried out MPS-based STR sequencing, identity, or ancestry SNP typing. A total of 23-40% of participants are planning to explore all FDP applications showing the overall very high interest in using MPS for the whole range of forensic MPS markers and applications. About 50% of the participants have previously gathered experience using forensic DNA phenotyping (FDP) markers based on conventional (i.e., not MPS-based) DNA typing methods. A total of 55% of the participants have attended training on the general use of MPS technology, but 36% have received no training whatsoever. Accordingly, 90% have expressed high or medium interest to attend training on the analysis and interpretation of DNA phenotyping data for predicting appearance, ancestry, and age. The results of our survey will provide valuable information for organizing relevant training workshops on all aspects of MPS-based DNA phenotyping for the forensic genetics scientific community.

Published

2021

9. Towards broadening Forensic DNA Phenotyping beyond pigmentation: Improving the prediction of head hair shape from DNA.

Author

Pośpiech E, Chen Y, Kukla-Bartoszek M, Breslin K, Aliferi A, Andersen JD, Ballard D, Chaitanya L, Freire-Aradas A, van der Gaag KJ, Girón-Santamaría L, Gross TE, Gysi M, Huber G, Mosquera-Miguel A, Muralidharan C, Skowron M, Carracedo Á, Haas C, Morling N, Parson W, Phillips C, Schneider PM, Sijen T, Syndercombe-Court D, Vennemann M, Wu S, Xu S, Jin L, Wang S, Zhu G, Martin NG, Medland SE, Branicki W, Walsh S, Liu F, and Kayser M

Subjects

Adult, Genome-Wide Association Study, Genotyping Techniques instrumentation, High-Throughput Nucleotide Sequencing, Humans, Logistic Models, Models, Genetic, Sequence Analysis, DNA, DNA genetics, Hair, Phenotype, Polymorphism, Single Nucleotide

Abstract

Human head hair shape, commonly classified as straight, wavy, curly or frizzy, is an attractive target for Forensic DNA Phenotyping and other applications of human appearance prediction from DNA such as in paleogenetics. The genetic knowledge underlying head hair shape variation was recently improved by the outcome of a series of genome-wide association and replication studies in a total of 26,964 subjects, highlighting 12 loci of which 8 were novel and introducing a prediction model for Europeans based on 14 SNPs. In the present study, we evaluated the capacity of DNA-based head hair shape prediction by investigating an extended set of candidate SNP predictors and by using an independent set of samples for model validation. Prediction model building was carried out in 9674 subjects (6068 from Europe, 2899 from Asia and 707 of admixed European and Asian ancestries), used previously, by considering a novel list of 90 candidate SNPs. For model validation, genotype and phenotype data were newly collected in 2415 independent subjects (2138 Europeans and 277 non-Europeans) by applying two targeted massively parallel sequencing platforms, Ion Torrent PGM and MiSeq, or the MassARRAY platform. A binomial model was developed to predict straight vs. non-straight hair based on 32 SNPs from 26 genetic loci we identified as significantly contributing to the model. This model achieved prediction accuracies, expressed as AUC, of 0.664 in Europeans and 0.789 in non-Europeans; the statistically significant difference was explained mostly by the effect of one EDAR SNP in non-Europeans. Considering sex and age, in addition to the SNPs, slightly and insignificantly increased the prediction accuracies (AUC of 0.680 and 0.800, respectively). Based on the sample size and candidate DNA markers investigated, this study provides the most robust, validated, and accurate statistical prediction models and SNP predictor marker sets currently available for predicting head hair shape from DNA, providing the next step towards broadening Forensic DNA Phenotyping beyond pigmentation traits., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

10. Body fluid identification using a targeted mRNA massively parallel sequencing approach - results of a EUROFORGEN/EDNAP collaborative exercise.

Author

Ingold S, Dørum G, Hanson E, Berti A, Branicki W, Brito P, Elsmore P, Gettings KB, Giangasparo F, Gross TE, Hansen S, Hanssen EN, Kampmann ML, Kayser M, Laurent FX, Morling N, Mosquera-Miguel A, Parson W, Phillips C, Porto MJ, Pośpiech E, Roeder AD, Schneider PM, Schulze Johann K, Steffen CR, Syndercombe-Court D, Trautmann M, van den Berge M, van der Gaag KJ, Vannier J, Verdoliva V, Vidaki A, Xavier C, Ballantyne J, and Haas C

Subjects

Blood Chemical Analysis, Cervix Mucus chemistry, Female, Genetic Markers, Humans, Laboratories, Least-Squares Analysis, Male, Menstruation, Saliva chemistry, Semen chemistry, Skin chemistry, High-Throughput Nucleotide Sequencing, RNA, Messenger metabolism

Abstract

In a previous study we presented an assay for targeted mRNA sequencing for the identification of human body fluids, optimised for the Illumina MiSeq/FGx MPS platform. This assay, together with an additional in-house designed assay for the Ion Torrent PGM/S5 platform, was the basis for a collaborative exercise within 17 EUROFORGEN and EDNAP laboratories, in order to test the efficacy of targeted mRNA sequencing to identify body fluids. The task was to analyse the supplied dried body fluid stains and, optionally, participants' own bona fide or mock casework samples of human origin, according to specified protocols. The provided primer pools for the Illumina MiSeq/FGx and the Ion Torrent PGM/S5 platforms included 33 and 29 body fluid specific targets, respectively, to identify blood, saliva, semen, vaginal secretion, menstrual blood and skin. The results demonstrated moderate to high count values in the body fluid or tissue of interest with little to no counts in non-target body fluids. There was some inter-laboratory variability in read counts, but overall the results of the laboratories were comparable in that highly expressed markers showed high read counts and less expressed markers showed lower counts. We performed a partial least squares (PLS) analysis on the data, where blood, menstrual blood, saliva and semen markers and samples clustered well. The results of this collaborative mRNA massively parallel sequencing (MPS) exercise support targeted mRNA sequencing as a reliable body fluid identification method that could be added to the repertoire of forensic MPS panels., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

11. A GHEP-ISFG collaborative study on the genetic variation of 38 autosomal indels for human identification in different continental populations.

Author

Pereira R, Alves C, Aler M, Amorim A, Arévalo C, Betancor E, Braganholi D, Bravo ML, Brito P, Builes JJ, Burgos G, Carvalho EF, Castillo A, Catanesi CI, Cicarelli RMB, Coufalova P, Dario P, D'Amato ME, Davison S, Ferragut J, Fondevila M, Furfuro S, García O, Gaviria A, Gomes I, González E, Gonzalez-Liñan A, Gross TE, Hernández A, Huang Q, Jiménez S, Jobim LF, López-Parra AM, Marino M, Marques S, Martínez-Cortés G, Masciovecchio V, Parra D, Penacino G, Pinheiro MF, Porto MJ, Posada Y, Restrepo C, Ribeiro T, Rubio L, Sala A, Santurtún A, Solís LS, Souto L, Streitemberger E, Torres A, Vilela-Lamego C, Yunis JJ, Yurrebaso I, and Gusmão L

Subjects

DNA Fingerprinting, Databases, Nucleic Acid, Ethnicity genetics, Gene Frequency, Genotype, Humans, Laboratories statistics & numerical data, Microsatellite Repeats, Genetics, Population, INDEL Mutation, Polymorphism, Single Nucleotide, Racial Groups genetics

Abstract

A collaborative effort was carried out by the Spanish and Portuguese Speaking Working Group of the International Society for Forensic Genetics (GHEP-ISFG) to promote knowledge exchange between associate laboratories interested in the implementation of indel-based methodologies and build allele frequency databases of 38 indels for forensic applications. These databases include populations from different countries that are relevant for identification and kinship investigations undertaken by the participating laboratories. Before compiling population data, participants were asked to type the 38 indels in blind samples from annual GHEP-ISFG proficiency tests, using an amplification protocol previously described. Only laboratories that reported correct results contributed with population data to this study. A total of 5839 samples were genotyped from 45 different populations from Africa, America, East Asia, Europe and Middle East. Population differentiation analysis showed significant differences between most populations studied from Africa and America, as well as between two Asian populations from China and East Timor. Low F ST values were detected among most European populations. Overall diversities and parameters of forensic efficiency were high in populations from all continents., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2018

12. Inter-laboratory evaluation of the EUROFORGEN Global ancestry-informative SNP panel by massively parallel sequencing using the Ion PGM™.

Author

Eduardoff M, Gross TE, Santos C, de la Puente M, Ballard D, Strobl C, Børsting C, Morling N, Fusco L, Hussing C, Egyed B, Souto L, Uacyisrael J, Syndercombe Court D, Carracedo Á, Lareu MV, Schneider PM, Parson W, Phillips C, Parson W, and Phillips C

Subjects

DNA Degradation, Necrotic, DNA Fingerprinting, DNA Primers, Databases, Genetic, Gene Frequency, Genetic Markers, Genotype, Humans, Polymerase Chain Reaction, Genetics, Population, High-Throughput Nucleotide Sequencing instrumentation, Polymorphism, Single Nucleotide, Racial Groups genetics

Abstract

The EUROFORGEN Global ancestry-informative SNP (AIM-SNPs) panel is a forensic multiplex of 128 markers designed to differentiate an individual's ancestry from amongst the five continental population groups of Africa, Europe, East Asia, Native America, and Oceania. A custom multiplex of AmpliSeq™ PCR primers was designed for the Global AIM-SNPs to perform massively parallel sequencing using the Ion PGM™ system. This study assessed individual SNP genotyping precision using the Ion PGM™, the forensic sensitivity of the multiplex using dilution series, degraded DNA plus simple mixtures, and the ancestry differentiation power of the final panel design, which required substitution of three original ancestry-informative SNPs with alternatives. Fourteen populations that had not been previously analyzed were genotyped using the custom multiplex and these studies allowed assessment of genotyping performance by comparison of data across five laboratories. Results indicate a low level of genotyping error can still occur from sequence misalignment caused by homopolymeric tracts close to the target SNP, despite careful scrutiny of candidate SNPs at the design stage. Such sequence misalignment required the exclusion of component SNP rs2080161 from the Global AIM-SNPs panel. However, the overall genotyping precision and sensitivity of this custom multiplex indicates the Ion PGM™ assay for the Global AIM-SNPs is highly suitable for forensic ancestry analysis with massively parallel sequencing., (Copyright © 2016 Elsevier Ireland Ltd. All rights reserved.)

Published

2016

13. Forensic ancestry analysis with two capillary electrophoresis ancestry informative marker (AIM) panels: Results of a collaborative EDNAP exercise.

Author

Santos C, Fondevila M, Ballard D, Banemann R, Bento AM, Børsting C, Branicki W, Brisighelli F, Burrington M, Capal T, Chaitanya L, Daniel R, Decroyer V, England R, Gettings KB, Gross TE, Haas C, Harteveld J, Hoff-Olsen P, Hoffmann A, Kayser M, Kohler P, Linacre A, Mayr-Eduardoff M, McGovern C, Morling N, O'Donnell G, Parson W, Pascali VL, Porto MJ, Roseth A, Schneider PM, Sijen T, Stenzl V, Court DS, Templeton JE, Turanska M, Vallone PM, Oorschot RAHV, Zatkalikova L, Carracedo Á, and Phillips C

Subjects

DNA genetics, Genotype, Humans, Polymorphism, Single Nucleotide, Electrophoresis, Capillary methods, Forensic Genetics, Genetic Markers

Abstract

There is increasing interest in forensic ancestry tests, which are part of a growing number of DNA analyses that can enhance routine profiling by obtaining additional genetic information about unidentified DNA donors. Nearly all ancestry tests use single nucleotide polymorphisms (SNPs), but these currently rely on SNaPshot single base extension chemistry that can fail to detect mixed DNA. Insertion-deletion polymorphism (Indel) tests have been developed using dye-labeled primers that allow direct capillary electrophoresis detection of PCR products (PCR-to-CE). PCR-to-CE maintains the direct relationship between input DNA and signal strength as each marker is detected with a single dye, so mixed DNA is more reliably detected. We report the results of a collaborative inter-laboratory exercise of 19 participants (15 from the EDNAP European DNA Profiling group) that assessed a 34-plex SNP test using SNaPshot and a 46-plex Indel test using PCR-to-CE. Laboratories were asked to type five samples with different ancestries and detect an additional mixed DNA sample. Statistical inference of ancestry was made by participants using the Snipper online Bayes analysis portal plus an optional PCA module that analyzes the genotype data alongside calculation of Bayes likelihood ratios. Exercise results indicated consistent genotyping performance from both tests, reaching a particularly high level of reliability for the Indel test. SNP genotyping gave 93.5% concordance (compared to the organizing laboratory's data) that rose to 97.3% excluding one laboratory with a large number of miscalled genotypes. Indel genotyping gave a higher concordance rate of 99.8% and a reduced no-call rate compared to SNP analysis. All participants detected the mixture from their Indel peak height data and successfully assigned the correct ancestry to the other samples using Snipper, with the exception of one laboratory with SNP miscalls that incorrectly assigned ancestry of two samples and did not obtain informative likelihood ratios for a third. Therefore, successful ancestry assignments were achieved by participants in 92 of 95 Snipper analyses. This exercise demonstrates that ancestry inference tests based on binary marker sets can be readily adopted by laboratories that already have well-established CE regimes in place. The Indel test proved to be easy to use and allowed all exercise participants to detect the DNA mixture as well as achieving complete and concordant profiles in nearly all cases. Lastly, two participants successfully ran parallel next-generation sequencing analyses (each using different systems) and achieved high levels of genotyping concordance using the exercise PCR primer mixes unmodified., (Copyright © 2015 Elsevier Ireland Ltd. All rights reserved.)

Published

2015

14. Inter-laboratory evaluation of SNP-based forensic identification by massively parallel sequencing using the Ion PGM™.

Author

Eduardoff M, Santos C, de la Puente M, Gross TE, Fondevila M, Strobl C, Sobrino B, Ballard D, Schneider PM, Carracedo Á, Lareu MV, Parson W, and Phillips C

Subjects

DNA analysis, DNA genetics, Female, Humans, Male, Reproducibility of Results, Sequence Analysis, DNA, Forensic Genetics methods, Genotyping Techniques methods, High-Throughput Nucleotide Sequencing methods, Polymorphism, Single Nucleotide

Abstract

Next generation sequencing (NGS) offers the opportunity to analyse forensic DNA samples and obtain massively parallel coverage of targeted short sequences with the variants they carry. We evaluated the levels of sequence coverage, genotyping precision, sensitivity and mixed DNA patterns of a prototype version of the first commercial forensic NGS kit: the HID-Ion AmpliSeq™ Identity Panel with 169-markers designed for the Ion PGM™ system. Evaluations were made between three laboratories following closely matched Ion PGM™ protocols and a simple validation framework of shared DNA controls. The sequence coverage obtained was extensive for the bulk of SNPs targeted by the HID-Ion AmpliSeq™ Identity Panel. Sensitivity studies showed 90-95% of SNP genotypes could be obtained from 25 to 100pg of input DNA. Genotyping concordance tests included Coriell cell-line control DNA analyses checked against whole-genome sequencing data from 1000 Genomes and Complete Genomics, indicating a very high concordance rate of 99.8%. Discordant genotypes detected in rs1979255, rs1004357, rs938283, rs2032597 and rs2399332 indicate these loci should be excluded from the panel. Therefore, the HID-Ion AmpliSeq™ Identity Panel and Ion PGM™ system provide a sensitive and accurate forensic SNP genotyping assay. However, low-level DNA produced much more varied sequence coverage and in forensic use the Ion PGM™ system will require careful calibration of the total samples loaded per chip to preserve the genotyping reliability seen in routine forensic DNA. Furthermore, assessments of mixed DNA indicate the user's control of sequence analysis parameter settings is necessary to ensure mixtures are detected robustly. Given the sensitivity of Ion PGM™, this aspect of forensic genotyping requires further optimisation before massively parallel sequencing is applied to routine casework., (Copyright © 2015 Elsevier Ireland Ltd. All rights reserved.)

Published

2015

15. Collaborative EDNAP exercise on the IrisPlex system for DNA-based prediction of human eye colour.

Author

Chaitanya L, Walsh S, Andersen JD, Ansell R, Ballantyne K, Ballard D, Banemann R, Bauer CM, Bento AM, Brisighelli F, Capal T, Clarisse L, Gross TE, Haas C, Hoff-Olsen P, Hollard C, Keyser C, Kiesler KM, Kohler P, Kupiec T, Linacre A, Minawi A, Morling N, Nilsson H, Norén L, Ottens R, Palo JU, Parson W, Pascali VL, Phillips C, Porto MJ, Sajantila A, Schneider PM, Sijen T, Söchtig J, Syndercombe-Court D, Tillmar A, Turanska M, Vallone PM, Zatkalíková L, Zidkova A, Branicki W, and Kayser M

Subjects

Humans, DNA genetics, Eye Color genetics

Abstract

The IrisPlex system is a DNA-based test system for the prediction of human eye colour from biological samples and consists of a single forensically validated multiplex genotyping assay together with a statistical prediction model that is based on genotypes and phenotypes from thousands of individuals. IrisPlex predicts blue and brown human eye colour with, on average, >94% precision accuracy using six of the currently most eye colour informative single nucleotide polymorphisms (HERC2 rs12913832, OCA2 rs1800407, SLC24A4 rs12896399, SLC45A2 (MATP) rs16891982, TYR rs1393350, and IRF4 rs12203592) according to a previous study, while the accuracy in predicting non-blue and non-brown eye colours is considerably lower. In an effort to vigorously assess the IrisPlex system at the international level, testing was performed by 21 laboratories in the context of a collaborative exercise divided into three tasks and organised by the European DNA Profiling (EDNAP) Group of the International Society of Forensic Genetics (ISFG). Task 1 involved the assessment of 10 blood and saliva samples provided on FTA cards by the organising laboratory together with eye colour phenotypes; 99.4% of the genotypes were correctly reported and 99% of the eye colour phenotypes were correctly predicted. Task 2 involved the assessment of 5 DNA samples extracted by the host laboratory from simulated casework samples, artificially degraded, and provided to the participants in varying DNA concentrations. For this task, 98.7% of the genotypes were correctly determined and 96.2% of eye colour phenotypes were correctly inferred. For Tasks 1 and 2 together, 99.2% (1875) of the 1890 genotypes were correctly generated and of the 15 (0.8%) incorrect genotype calls, only 2 (0.1%) resulted in incorrect eye colour phenotypes. The voluntary Task 3 involved participants choosing their own test subjects for IrisPlex genotyping and eye colour phenotype inference, while eye photographs were provided to the organising laboratory and judged; 96% of the eye colour phenotypes were inferred correctly across 100 samples and 19 laboratories. The high success rates in genotyping and eye colour phenotyping clearly demonstrate the reproducibility and the robustness of the IrisPlex assay as well as the accuracy of the IrisPlex model to predict blue and brown eye colour from DNA. Additionally, this study demonstrates the ease with which the IrisPlex system is implementable and applicable across forensic laboratories around the world with varying pre-existing experiences., (Copyright © 2014 Elsevier Ireland Ltd. All rights reserved.)

Published

2014