The impact of the Turkish (TK) population variome on the genomic architecture of rare disease traits

Abstract: We investigated the influences of admixture and consanguinity on the genetic architecture of disease by generating a database of variants derived from exome sequencing (ES) of 853 unrelated Turkish (TK) individuals with different disease phenotypes. We observed that TK genomes are more similar to Europeans with 69.3% of the unique variants (N = 356,613) not present in the Greater Middle Eastern variome.We found higher inbreeding coefficient values in the TK cohort correlating with a larger median span of long-… Show more

“…It is expected that all patients with biallelic disease variants fall into three categories (1) HMZ: those affected with homozygous small variants possibly from a close-or distant-consanguineous relationship, (2) SNV+SNV: those affected with compound heterozygous small variants, and (3) NAHR+SNV: those affected with a large deletion in trans with a small variant. We anticipate that category #1-HMZ accounts for a substantial proportion, demonstrating the well-established robustness of autozygosity mapping as a method for allelic and new recessive gene discovery (as populational rare alleles can be escalated to much higher clan allele frequency) (Coban-Akdemir et al 2020). In outbred pedigrees and populations corresponding to categories #2-SNV+SNV and #3-NAHR+SNV, our modeling from the NIRD hypothesis is that #3-NAHR+SNV should account for a higher fraction.…”

“…We anticipate that category #1 accounts for a substantial proportion, demonstrating the robustness of the autozygosity mapping method in new recessive gene discovery (as populational rare alleles can be escalated to much higher clan allele frequency). 5 In outbred populations corresponding to categories #2 and #3, the working hypothesis is that #3 should account for a much higher fraction. Otherwise, the opposing trend may suggest that our current disease gene/allele discovery efforts are not exploiting the large deletion allele to the fullest extent that a ‘human haploid genetics’ approach might allow.…”

“…4 ; 5 Thus, the probability of ascertaining patients with the recessive disorder increases exponentially, even when all existing alleles are ultra-rare in sampling the general population. 6…”

“…In this circumstance, the allele pool shrinks to the Clan of the patient's extended family, which dramatically escalates the effective disease-allele frequency (Gonzaga-Jauregui et al 2020;Alkuraya 2021). Thus, the probability of ascertaining patients with the recessive trait disorder increases exponentially, even when all existing alleles are ultra-rare in sampling the general population (Coban-Akdemir et al 2020).…”

“…In this circumstance, the allele pool shrinks to the Clan of the patient's extended family, which dramatically escalates the effective disease-allele frequency compared to the baseline allele frequency in the general population (Gonzaga-Jauregui et al 2020;Alkuraya 2021). Thus, the probability of ascertaining patients with a recessive trait disorder increases exponentially, because the sampling of the second allele occurs within the Clan rather than the general population (Coban-Akdemir et al 2020). Similarly, focusing on a specific geographic or ethnic population is another effective strategy, often attributed to available founder mutation alleles in the population studied (Gonzaga-Jauregui et al 2020); the Puerto Rican founder allele, and specifically the COL27A1 founder in a geographic isolation bottleneck and Steel syndrome on the island of Puerto Rico, was informative.…”

Sequencing individual genomes with recurrent genomic disorder deletions: an approach to characterize genes for autosomal recessive rare disease traits

“…It is expected that all patients with biallelic disease variants fall into three categories (1) HMZ: those affected with homozygous small variants possibly from a close-or distant-consanguineous relationship, (2) SNV+SNV: those affected with compound heterozygous small variants, and (3) NAHR+SNV: those affected with a large deletion in trans with a small variant. We anticipate that category #1-HMZ accounts for a substantial proportion, demonstrating the well-established robustness of autozygosity mapping as a method for allelic and new recessive gene discovery (as populational rare alleles can be escalated to much higher clan allele frequency) (Coban-Akdemir et al 2020). In outbred pedigrees and populations corresponding to categories #2-SNV+SNV and #3-NAHR+SNV, our modeling from the NIRD hypothesis is that #3-NAHR+SNV should account for a higher fraction.…”

“…We anticipate that category #1 accounts for a substantial proportion, demonstrating the robustness of the autozygosity mapping method in new recessive gene discovery (as populational rare alleles can be escalated to much higher clan allele frequency). 5 In outbred populations corresponding to categories #2 and #3, the working hypothesis is that #3 should account for a much higher fraction. Otherwise, the opposing trend may suggest that our current disease gene/allele discovery efforts are not exploiting the large deletion allele to the fullest extent that a ‘human haploid genetics’ approach might allow.…”

“…4 ; 5 Thus, the probability of ascertaining patients with the recessive disorder increases exponentially, even when all existing alleles are ultra-rare in sampling the general population. 6…”

“…In this circumstance, the allele pool shrinks to the Clan of the patient's extended family, which dramatically escalates the effective disease-allele frequency (Gonzaga-Jauregui et al 2020;Alkuraya 2021). Thus, the probability of ascertaining patients with the recessive trait disorder increases exponentially, even when all existing alleles are ultra-rare in sampling the general population (Coban-Akdemir et al 2020).…”

“…In this circumstance, the allele pool shrinks to the Clan of the patient's extended family, which dramatically escalates the effective disease-allele frequency compared to the baseline allele frequency in the general population (Gonzaga-Jauregui et al 2020;Alkuraya 2021). Thus, the probability of ascertaining patients with a recessive trait disorder increases exponentially, because the sampling of the second allele occurs within the Clan rather than the general population (Coban-Akdemir et al 2020). Similarly, focusing on a specific geographic or ethnic population is another effective strategy, often attributed to available founder mutation alleles in the population studied (Gonzaga-Jauregui et al 2020); the Puerto Rican founder allele, and specifically the COL27A1 founder in a geographic isolation bottleneck and Steel syndrome on the island of Puerto Rico, was informative.…”

Sequencing individual genomes with recurrent genomic disorder deletions: an approach to characterize genes for autosomal recessive rare disease traits

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