Genetic screening of patients with aplastic anemia by targeting sequencing

The pathophysiology of bone marrow failure (BMF) can be immune, as in acquired aplastic anemia (AA), or constitutional, due to germline mutations in genes critical for DNA repair and telomere maintenance. The genetic screening of patients with constitutional AA is performed to detect germline mutations that are etiologic in patients\' disease. That is critical for treatment decisions and to identify a donor for a bone marrow transplant. In acquired AA, the genetic screening has been used to detect somatic mutations that can predict patients\' outcomes after treatment, as the role of germline mutations in this disease is yet not clear. To investigate the role of germline variants in AA, we screened two independent cohorts with two different targeting sequencing panels; a first cohort composed by 13 patients with acquired AA that was screened using a panel with 165 genes related to BMF, hematologic malignancies, DNA repair, telomere maintenance, and immune response pathways. A second cohort composed of 59 patients suspected to have a constitutional disease screened by a commercial Inherited Bone Marrow Failure Sequencing panel. In our first cohort, while patients without functional relevant germline variants responded to immunosuppression treatment (n=8), three out of 5 nonresponder patients were identified with variants in telomere biology genes. We found patients carrying TERT and DHX36 variants. In our constitutional AA cohort, we identified 8 patients carrying variants in the RTEL1 gene, a helicase critical to telomere maintenance. RTEL1 variants associated with both patients\' overall telomere shortening and single-stranded 3\' overhang erosion independent of telomere length. Also, 3\' overhang erosion was associated with patients\' predisposition to clonal evolution. In this context, the variants identified in the helicases genes DHX36 and RTEL1 were both associated with patients\' normal telomere length and poor outcomes. Also, telomere length measurement alone was insufficient to identify all primary telomere defects. The platforms of next-generation sequencing decreased the cost and time for the genetic screening of patients with BMF. In our study, acquired AA patients did not display a clear genetic pattern associated with their immunosuppressive treatment response. In contrast, the sequencing of the cohort selected based on their suspicion to have an inherited diseaseidentified a molecular defect that might be pathogenic in up to 40% of patients, including the RTEL1 variants. Pathogenicity assessment of genetic variants requires a combination of clinical, in silico, and functional data required to avoid misinterpretation of common variants. (AU)