Benchmarking kinship estimation tools for ancient genomes using pedigree simulations

Aktürk, Şevval; Mapelli, Igor; Güler, Merve N.; Gürün, Kanat; Katırcıoğlu, Büşra; Vural, Kıvılcım Başak; Sağlıcan, Ekin; Çetin, Mehmet; Yaka, Reyhan; Sürer, Elif; Atağ, Gözde; Çokoğlu, Sevim Seda; Sevkar, Arda; Altınışık, N. Ezgi; Koptekin, Dilek; Somel, Mehmet

doi:10.1111/1755-0998.13960

Cited by 3 publications

References 67 publications

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Inferring Distant Relationships From Dense SNP Data Utilizing Two Genealogy Algorithms

Lin,

Han,

Zhang

et al. 2024

Electrophoresis

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A highly esteemed method known as investigative genetic genealogy (IGG) has been developed to identify DNA samples from forensic crime scenes and human remains of disaster victims. With the advent of next‐generation sequencing, it is now feasible to access information on millions of SNPs typed in a single sequencing run that fulfill the requirements for kinship inference. However, challenges such as the poor quality of forensic samples, the high cost associated with sequencing technology, and privacy concerns regarding large‐scale genetic databases remain unresolved in this field. In the present study, we validated the identification of relationships up to the seventh degree using two genealogy algorithms (IBIS and KING) under various parameter settings. This was accomplished through whole genome sequencing data derived from two southern Chinese Han pedigrees during an initial phase, while also exploring workflows adapted for low‐quality samples. To achieve this objective, low‐coverage whole genome sequencing data were downsampled from high‐coverage original datasets; additionally, mimic SNP array data—containing less information but offering greater accessibility—were prepared as reference samples. Through a series of experimental analyses, we not only validate the applicability of selected processing procedures and inference tools for low‐coverage samples but also proposed that a meticulously crafted site filtering strategy can significantly improve the accuracy of kinship identification. This acknowledges the necessity for further systematic evidence in future research endeavors.

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Inferring Distant Relationships From Dense SNP Data Utilizing Two Genealogy Algorithms

Lin,

Han,

Zhang

et al. 2024

Electrophoresis

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DeepKin: Predicting relatedness from low-coverage genomes and paleogenomes with convolutional neural networks

Güler,

Yılmaz,

Katırcıoğlu

et al. 2024

Preprint

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DeepKinis a novel tool designed to predict relatedness from genomic data using convolutional neural networks (CNNs). Traditional methods for estimating relatedness often struggle when genomic data is limited, as with paleogenomes and degraded forensic samples.DeepKinaddresses this challenge by leveraging two CNN models trained on simulated genomic data to classify relatedness up to the third-degree and to identify parent-offspring and sibling pairs. Our benchmarking showsDeepKinperforms comparably or better than the widely used toolREADv2.We validatedDeepKinon empirical paleogenomes from two paleological sites, demonstrating its robustness and adaptability across different genetic backgrounds, with accuracy >90% above 10K shared SNPs. By capturing information across genomic segments,DeepKinoffers a new methodological path for relatedness estimation in settings with highly degraded samples, with applications in ancient DNA, as well as forensic and conservation genetics.

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READv2: advanced and user-friendly detection of biological relatedness in archaeogenomics

Alaçamlı,

Naidoo,

Güler

et al. 2024

Genome Biol

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The advent of genome-wide ancient DNA analysis has revolutionized our understanding of prehistoric societies. However, studying biological relatedness in these groups requires tailored approaches due to the challenges of analyzing ancient DNA. READv2, an optimized Python3 implementation of the most widely used tool for this purpose, addresses these challenges while surpassing its predecessor in speed and accuracy. For sufficient amounts of data, it can classify up to third-degree relatedness and differentiate between the two types of first-degree relatedness, full siblings and parent-offspring. READv2 enables user-friendly, efficient, and nuanced analysis of biological relatedness, facilitating a deeper understanding of past social structures.

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Benchmarking kinship estimation tools for ancient genomes using pedigree simulations

Cited by 3 publications

References 67 publications

Inferring Distant Relationships From Dense SNP Data Utilizing Two Genealogy Algorithms

Inferring Distant Relationships From Dense SNP Data Utilizing Two Genealogy Algorithms

DeepKin: Predicting relatedness from low-coverage genomes and paleogenomes with convolutional neural networks

READv2: advanced and user-friendly detection of biological relatedness in archaeogenomics

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