| Literature DB >> 34199109 |
Ismael Henarejos-Castillo1,2, Alejandro Aleman1, Begoña Martinez-Montoro3, Francisco Javier Gracia-Aznárez4, Patricia Sebastian-Leon1,3, Monica Romeu5, Jose Remohi2,6, Ana Patiño-Garcia4,7, Pedro Royo3, Gorka Alkorta-Aranburu4, Patricia Diaz-Gimeno1,3.
Abstract
Ovarian failure (OF) is a common cause of infertility usually diagnosed as idiopathic, with genetic causes accounting for 10-25% of cases. Whole-exome sequencing (WES) may enable identifying contributing genes and variant profiles to stratify the population into subtypes of OF. This study sought to identify a blood-based gene variant profile using accumulation of rare variants to promote precision medicine in fertility preservation programs. A case-control (n = 118, n = 32, respectively) WES study was performed in which only non-synonymous rare variants <5% minor allele frequency (MAF; in the IGSR) and coverage ≥ 100× were considered. A profile of 66 variants of uncertain significance was used for training an unsupervised machine learning model to separate cases from controls (97.2% sensitivity, 99.2% specificity) and stratify the population into two subtypes of OF (A and B) (93.31% sensitivity, 96.67% specificity). Model testing within the IGSR female population predicted 0.5% of women as subtype A and 2.4% as subtype B. This is the first study linking OF to the accumulation of rare variants and generates a new potential taxonomy supporting application of this approach for precision medicine in fertility preservation.Entities:
Keywords: genome variant profile; genomic taxonomy; infertility; ovarian failure; ovary; personalized medicine; precision medicine; prediction model; single nucleotide variant; whole exome sequencing
Year: 2021 PMID: 34199109 DOI: 10.3390/jpm11070609
Source DB: PubMed Journal: J Pers Med ISSN: 2075-4426