Genetic profiling of Vietnamese population from large-scale genomic analysis of non-invasive prenatal testing data

Tran, Ngoc Hieu; Vo, Thanh Binh; Nguyen, Van Thong; Tran, Nhat Thang; Trinh, Thu-Huong Nhat; Pham, Hong-Anh Thi; Dao, Hong Thuy; Nguyễn, Như Gia; Van, Yen-Linh Thi; Tran, Vu Uyen; Vu, Hoang Giang; Bui, Quynh-Tram Nguyen; Vo, Phuong-Anh Ngoc; Nguyen, Huu Nguyen; Nguyen, Quynh-Tho Thi; Do, Thanh-Thuy Thi; Ngoc, Phuong Cao Thi; Truong, Dinh Kiet; Nguyen, Hoai-Nghia; Giang, Hoa; Phan, Minh-Duy

doi:10.1101/868588

Cited by 6 publications

(10 citation statements)

References 27 publications

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“…The use of dense genotyping arrays followed by imputation to a haplotype reference panel has enabled population-scale genome wide associations studies to become routine in characterizing the genetic architecture of complex traits and disease. An alternative technology is low-pass whole genome sequencing followed by imputation, which has successfully used for a number of problems in statistical and population genetics (Tran et al, 2020;Pasaniuc et al, 2012;Gilly et al, 2019), and which was recently shown to recapitulate comparable disease risk stratification performance using a handful of polygenic risk scores derived from imputed array data from an independent cohort (Homburger et al, 2019). We introduced the notion of effective coverage, a quantity which describes the coverage of a sequenced sample under an ideal sampling process and which is more predictive of imputation accuracy than nominal coverage.…”

Section: Discussionmentioning

confidence: 99%

“…As genome sequencing costs have decreased over the past decade, sequencing-based alternatives to genotyping arrays have been the subject of growing interest (Wetterstrand, 2019). Specifically, low-coverage shotgun whole genome sequencing followed by imputation has been utilized for a number of problems in statistical and population genetics, from providing the backbone for graphbased pangenomes in sorghum to trait mapping in human pharmacogenetics (Tran et al, 2020;Gilly et al, 2019;Rubinacci et al, 2020;Homburger et al, 2019;Wasik et al, 2019;Jensen et al, 2020;Cai et al, 2015a;Liu et al, 2018). As an intuition for why this approach is useful, a sample sequenced at a target coverage of 0.5× is expected to have at least one read on 33 million of the 85 million sites in the 1000 Genomes Phase 3 release, whereas a genotyping array will probe a number of variants which is one to two orders of magnitude fewer, albeit with higher average accuracy (Consortium et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…As an intuition for why this approach is useful, a sample sequenced at a target coverage of 0.5× is expected to have at least one read on 33 million of the 85 million sites in the 1000 Genomes Phase 3 release, whereas a genotyping array will probe a number of variants which is one to two orders of magnitude fewer, albeit with higher average accuracy (Consortium et al, 2015). For many use cases, there are a number of advantages to low-pass sequencing (lps) over genotyping arrays; for example, (1) there is a lack of ascertainment bias with regard to which variants/sites on the genome are assayed, (2) sequence data can be used to discover novel variation both at the sample or population level (such as in Tran et al (2020); Liu et al (2018)), (3) massively parallel low-pass sequencing can be achieved by multiplexing large numbers of samples to reduce cost, and (4) the fact that the average expected accuracy of a sample's imputed genotypes can be fine-tuned by adjusting the target coverage for the sample, something which is useful when designing experiments within real-world logistical or budgeting constraints (see Pasaniuc et al (2012) for a detailed simulation-based cost-benefit analysis of low-pass sequencing compared to genotyping arrays for GWAS study designs).…”

Section: Introductionmentioning

confidence: 99%

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Low-pass sequencing increases the power of GWAS and decreases measurement error of polygenic risk scores compared to genotyping arrays

Mazur

Berisa

et al. 2020

Preprint

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Low-pass sequencing (sequencing a genome to an average depth less than 1x coverage) combined with genotype imputation has been proposed as an alternative to genotyping arrays for trait mapping and calculation of polygenic scores; however, the current literature is largely limited to simulation-and downsampling-based approaches. To empirically assess the relative performance of these technologies for different applications, we performed low-pass sequencing (targeting coverage levels of 0.5x and 1x) and array genotyping (using the Illumina Global Screening Array) on 120 DNA samples derived from African and European-ancestry individuals that are part of the 1000 Genomes Project. We then imputed both the sequencing data and the genotyping array data to the 1000 Genomes Phase 3 haplotype reference panel using a leaveone-out design. First, we evaluated overall imputation accuracy from these different assays as measured by genotype concordance; we introduce the concept of effective coverage that accounts for evenness of sequencing and show that this metric is a better predictor of imputation accuracy than nominal mapped coverage for low-pass sequencing data. Next, we evaluated overall power for genome-wide association studies (GWAS) as measured by the squared correlation between imputed and true genotypes. In the African individuals, at common variants (> 5% minor allele frequency), imputation r 2 averaged 0.83 for the array data and ranged from 0.89 to 0.95 for the low-pass sequencing data, corresponding to an effective 7 − 15% increase in GWAS discovery power. For the same variants in the European individuals, imputation r 2 averaged 0.91 for the array data and ranged from 0.92-0.96 for the low-pass sequencing data, corresponding to an effective 1-6% increase in GWAS discovery power. Finally, we computed polygenic risk scores for breast cancer and coronary artery disease from the different assays. We observed consistently lower measurement error for risk scores computed from low-pass sequencing data above an effective coverage of ∼ 0.5x. The mean squared error of the array-based estimates was three to four times that of the estimates from samples sequenced at an effective coverage of ∼ 1.2x for coronary artery disease, with qualitatively similar results for breast cancer. We conclude that low-pass sequencing plus imputation, in addition to providing a substantial increase in statistical power for genome wide association studies, provides increased accuracy for polygenic risk prediction at effective coverages of ∼ 0.5x and higher.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Low-pass sequencing increases the power of GWAS and decreases measurement error of polygenic risk scores compared to genotyping arrays

Mazur

Berisa

et al. 2020

Preprint

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“…(1 in 20) of the Vietnamese population. populations, had been reported previously in [9]. Two other autosomal recessive diseases were found with relatively high carrier frequencies, including hemochromatosis type 1 (HFE, 9.4% or syndrome is a multisystem disorder characterized by many clinical features, including developmental delay, intellectual disability and facial dysmorphis.…”

Section: Carrier Frequencies Of Genetic Diseases In the Vietnamese Pomentioning

confidence: 93%

“…Gurdasani et al found that nearly 78% of the participants in genetic studies had European ancestries, whereas the two major populations, Asian and African, only accounted for 11% and 2.4%, respectively [6]. Indeed, genetic research on the Vietnamese population still lags behind other Western and Asian populations, despite recent efforts of genome sequencing projects in the country [8, 9]. There has been no research to study the prevalence of inherited disorders in the Vietnamese population.…”

Section: Introductionmentioning

confidence: 99%

Genetic landscape of recessive diseases in the Vietnamese population from large-scale clinical exome sequencing

Tran

Thi²,

Tang³

et al. 2020

Preprint

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Purpose: Accurate profiling of population-specific recessive diseases is essential for the design of cost-effective carrier screening programs. However, minority populations and ethnic groups, including Vietnamese, are still under-represented in existing genetic studies. Here we reported the first comprehensive study of recessive diseases in the Vietnamese population. Methods: Clinical exome sequencing (CES) data of 4,503 disease-associated genes obtained from a cohort of 985 Vietnamese individuals was analyzed to identify pathogenic variants, associated diseases and their carrier frequencies in the population. Results: Eighty-five recessive diseases were identified in the Vietnamese population, among which seventeen diseases had carrier frequencies of at least 1% (1 in 100 individuals). Three diseases were especially prevalent in the Vietnamese population with carrier frequencies of 2-12 times higher than in other East Asia or the world populations, including Beta-thalassemia (1 in 25), citrin deficiency (1 in 33) and phenylketonuria (1 in 40). Seven novel pathogenic and three likely pathogenic variants associated with nine recessive diseases were also discovered. Conclusions: The comprehensive profile of recessive diseases identified in this study shall enable the design of cost-effective carrier screening programs specific to the Vietnamese population. The newly discovered pathogenic variants may also exist in other populations at extremely low frequencies, thus representing a valuable resource for future research. Our study has demonstrated the advantage of population-specific genetic studies to advance the knowledge and practice of medical genetics. Keywords: carrier frequency; carrier screening; recessive diseases.

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Genetic landscape of recessive diseases in the Vietnamese population from large‐scale clinical exome sequencing

Tran

Thi²,

Tang

et al. 2021

Human Mutation

Self Cite

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Accurate profiling of population‐specific recessive diseases is essential for the design of cost‐effective carrier screening programs. However, minority populations and ethnic groups, including Vietnamese, are still underrepresented in existing genetic studies. Here, we reported the first comprehensive study of recessive diseases in the Vietnamese population. Clinical exome sequencing data of 4503 disease‐associated genes obtained from a cohort of 985 Vietnamese individuals was analyzed to identify pathogenic variants, associated diseases and their carrier frequencies in the population. A total of 118 recessive diseases associated with 164 pathogenic or likely pathogenic variants were identified, among which 28 diseases had carrier frequencies of at least 1% (1 in 100 individuals). Three diseases were prevalent in the Vietnamese population with carrier frequencies of 2–12 times higher than in the world populations, including beta‐thalassemia (1 in 23), citrin deficiency (1 in 31), and phenylketonuria (1 in 40). Seven novel pathogenic and two likely pathogenic variants associated with nine recessive diseases were discovered. The comprehensive profile of recessive diseases identified in this study enables the design of cost‐effective carrier screening programs specific to the Vietnamese population.

show abstract

Genetic profiling of Vietnamese population from large-scale genomic analysis of non-invasive prenatal testing data

Cited by 6 publications

References 27 publications

Low-pass sequencing increases the power of GWAS and decreases measurement error of polygenic risk scores compared to genotyping arrays

Low-pass sequencing increases the power of GWAS and decreases measurement error of polygenic risk scores compared to genotyping arrays

Genetic landscape of recessive diseases in the Vietnamese population from large-scale clinical exome sequencing

Genetic landscape of recessive diseases in the Vietnamese population from large‐scale clinical exome sequencing

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