Abstract
An erythrocytosis is present when the red blood cell mass is increased, demonstrated as elevated hemoglobin and hematocrit in the laboratory evaluation. Congenital predispositions for erythrocytosis are rare, with germline variants in several genes involved in oxygen sensing (VHL, EGLN1, and EPAS1), signaling for hematopoietic cell maturation (EPOR and EPO), and oxygen transfer (HBB, HBA1, HBA2, and BPGM) that were already associated with the eight congenital types (ECYT1–8). Screening for variants in known congenital erythrocytosis genes with classical sequencing approach gives a correct diagnosis for only up to one-third of the patients. The genetic background of erythrocytosis is more heterogeneous, and additional genes involved in erythropoiesis and iron metabolism could have a putative effect on the development of erythrocytosis. This study aimed to detect variants in patients with yet unexplained erythrocytosis using the next-generation sequencing (NGS) approach, targeting genes associated with erythrocytosis and increased iron uptake and implementing the diagnostics of congenital erythrocytosis in Slovenia. Selected 25 patients with high hemoglobin, high hematocrit, and no acquired causes were screened for variants in the 39 candidate genes. We identified one pathogenic variant in EPAS1 gene and three novel variants with yet unknown significance in genes EPAS1, JAK2, and SH2B3. Interestingly, a high proportion of patients were heterozygous carriers for two variants in HFE gene, otherwise pathogenic for the condition of iron overload. The association between the HFE variants and the development of erythrocytosis is not clearly understood. With a targeted NGS approach, we determined an actual genetic cause for the erythrocytosis in one patient and contributed to better management of the disease for the patient and his family. The effect of variants of unknown significance on the enhanced production of red blood cells needs to be further explored with functional analysis. This study is of great significance for the improvement of diagnosis of Slovenian patients with unexplained erythrocytosis and future research on the etiology of this rare hematological disorder.
Highlights
Erythrocytes or red blood cells are the most abundant cells in the blood with the main function of tissue oxygen delivery (Lee and Percy, 2011)
We examined the patients with suspected congenital erythrocytosis for the first time with the established targeted next-generation sequencing (NGS) in the Slovenian clinical setting
We showed that targeted NGS was useful to explore variants in cases with suspected congenital erythrocytosis; in only approximately 15% of the patients, clinically interesting variants were identified
Summary
Erythrocytes or red blood cells are the most abundant cells in the blood with the main function of tissue oxygen delivery (Lee and Percy, 2011). I.e., somatic erythrocytosis (OMIM ID: 133100), is the consequence of somatic genetic variants in Janus kinase 2 (JAK2) gene and SH2B adaptor protein 3 (SH2B3) gene, which lead to constant activation of EPO signaling pathway (McMullin and Cario, 2016; Maslah et al, 2017; Bento, 2018). ECYT6–8 (OMIM IDs: 617980, 617981, and 222800) are developed due to variants in hemoglobin genes HBB, HBA1, and HBA2 and biphosphoglycerate mutase (BPGM), which lead to increased oxygen affinity of hemoglobin (Figure 1; McMullin, 2016; Bento, 2018). Besides the above-mentioned genes, other genes are included in the pathways of red blood cell production but were not yet associated with the clinical outcome of erythrocytosis (Gaspersic et al, 2020)
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