Targeted Next Generation Sequencing and Diagnosis of Congenital Hemolytic Anemias: A Three Years Experience Monocentric Study

Fermo, Elisa; Vercellati, Cristina; Marcello, Anna Paola; Keskin, Ebru Yılmaz; Perrotta, Silverio; Zaninoni, Anna; Brancaleoni, Valentina; Zanella, Alberto; Giannotta, Juri Alessandro; Barcellini, Wilma; Bianchi, Paola

doi:10.3389/fphys.2021.684569

Cited by 22 publications

(23 citation statements)

References 47 publications

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“…In recent years, new discoveries have been made using targeted NGS technology 19–21 . Compared with Sanger sequencing, NGS with a preselected gene panel has higher diagnostic efficiency and can quickly conduct comprehensive gene analysis for patients suspected as having an erythrocyte membrane disease 22–24 . Diagnosis of HS is based on clinical data, family history, and phenotypic testing.…”

Section: Introductionmentioning

confidence: 99%

“…[19][20][21] Compared with Sanger sequencing, NGS with a preselected gene panel has higher diagnostic efficiency and can quickly conduct comprehensive gene analysis for patients suspected as having an erythrocyte membrane disease. [22][23][24] Diagnosis of HS is based on clinical data, family history, and phenotypic testing. Taken together, NGS comes across as a reliable supplement to the previous experimental diagnostic methods.…”

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confidence: 99%

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Identification of variants in 94 Chinese patients with hereditary spherocytosis by next‐generation sequencing

et al. 2022

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Hereditary spherocytosis (HS) is the most common type of hereditary erythrocyte membrane disease and has varied phenotypic features and genetic patterns. We herein performed a retrospective study of 94 patients with HS and aimed to investigate the genetic variations and genotype–phenotype correlations using targeted next‐generation sequencing. In 79/94 (84%) patients, 83 HS variants including 67 novel variants were identified. Pathogenic variants of SPTB, ANK1, SLC4A1, SPTA1, and EPB42 were found in 32/79(41%), 22/79(28%), 15/79 (19%), 8/79 (9%), and 3/79 (4%) of the patients respectively, revealing that SPTB is the most frequently mutated HS gene in Eastern China. Most SPTB and ANK1 gene variations were nonsense and frameshift variations. Missense variants were the main variant type of SLC4A1, SPTA1, and EPB42 genes. Interestingly, one SPTA1 variant (p. Arg1757Cys) showed an autosomal dominant inheritance pattern and one EPB42 variant (p. Gln377His) was apparent as a hotspot variation. Furthermore, genotype–phenotype analysis was performed among the five mutated gene groups. Besides the finding that patients with the SLC4A1 variant had the highest mean corpuscular hemoglobin levels, no clear correlations between genotype and phenotype were observed.

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Section: Introductionmentioning

confidence: 99%

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confidence: 99%

Identification of variants in 94 Chinese patients with hereditary spherocytosis by next‐generation sequencing

et al. 2022

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“…The DNA samples were analysed on an NGS-targeted panel containing 43 genes associated with congenital hemolytic anemia (Supplemetary Table S1) (Fermo et al, 2021b). Libraries were obtained by HaloPlexHS Target Enrichment System Kit (Agilent Technologies, Santa Clara, United States) and sequenced on a MiSeq platform (Illumina, San Diego, United States).…”

Section: Next Generation Sequencing Analysismentioning

confidence: 99%

“…The defective RBC membrane proteins identified by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE), have been considered for many years a confirmatory test for membrane defects in HS; however, it is known that a in about 10% of the patients, the protein deficiency remains unclassified by this technique (Mariani et al, 2008;Bianchi et al, 2012). The development of next generation sequencing (NGS) techniques and targeted-NGS panels may be useful to unravel complex cases, since the genes encoding for RBC membrane proteins are now usually included in the targeted panels specifically designed for the diagnosis of hereditary hemolytic anemias; this resulted in a rapidly growing knowledge of the molecular basis of HS and of the genotype phenotype correlation (He et al, 2017;Russo et al, 2018;van Vuren et al, 2019;Xue et al, 2019;Bianchi et al, 2020;Qin et al, 2020;Fermo et al, 2021b;Vives-Corrons et al, 2021). However, few data are available regarding the direct consequences of the various genetic defects on the assembly and dynamic interactions of the RBC cytoskeleton.…”

Section: Introductionmentioning

confidence: 99%

Effect of primary lesions in cytoskeleton proteins on red cell membrane stability in patients with hereditary spherocytosis

et al. 2022

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We investigated by targeted next generation sequencing the genetic bases of hereditary spherocytosis in 25 patients and compared the molecular results with the biochemical lesion of RBC membrane obtained by SDS-PAGE analysis. The HS diagnosis was based on available guidelines for diagnosis of congenital hemolytic anemia, and patients were selected because of atypical clinical presentation or intra-family variability, or because presented discrepancies between laboratory investigation and biochemical findings. In all patients but 5 we identified pathogenic variants in SPTA1, SPTB, ANK1, SLC4A1, EPB42 genes able to justify the clinical phenotype. Interestingly, a correspondence between the biochemical lesion and the molecular defect was identified in only 11/25 cases, mostly with band 3 deficiency due to SLC4A1 mutations. Most of the mutations in SPTB and ANK1 gene didn’t hesitate in abnormalities of RBC membrane protein; conversely, in two cases the molecular lesion didn’t correspond to the biochemical defect, suggesting that a mutation in a specific cytoskeleton protein may result in a more complex RBC membrane damage or suffering. Finally, in two cases the HS diagnosis was maintained despite absence of both protein defect and molecular lesion, basing on clinical and family history, and on presence of clear laboratory markers of HS. The study revealed complex relationships between the primary molecular lesion and the final effect in the RBC membrane cytoskeleton, and further underlines the concept that there is not a unique approach to the diagnosis of HS.

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“…To facilitate HS diagnosis, targeted next‐generation sequencing (tNGS) is used to detect germline mutations in genes encoding for RBC cytoskeleton proteins [ 11 , 12 , 13 , 14 , 15 , 16 , 17 , 18 , 19 , 20 , 21 ]. tNGS is less time consuming than traditional sequencing techniques, but the technique is associated with high costs and long turnaround.…”

Section: Introductionmentioning

confidence: 99%

Facilitating EMA binding test performance using fluorescent beads combined with next‐generation sequencing

Glenthøj

Brieghel

Nardo‐Marino

et al. 2021

eJHaem

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The eosin‐5′‐maleimide (EMA) binding test is widely used as diagnostic test for hereditary spherocytosis (HS), one of the most common haemolytic disorders in Caucasian populations. We recently described the advantages of replacing the use of healthy control blood samples with fluorescent beads in a modified EMA binding assay. In this study we further explore this novel approach. We performed targeted next‐generation sequencing, modified EMA binding test and osmotic gradient ektacytometry on consecutive individuals referred to our laboratory on the suspicion of HS. In total, 33 of 95 carried a (likely) pathogenic variant, and 24 had variants of uncertain significance (VUS). We identified a total 79 different (likely) pathogenic variants and VUS, including 43 novel mutations. Discarding VUS and recessive mutations in STPA1, we used the occurrence of (likely) pathogenic variants to generate a diagnostic threshold for our modified EMA binding test. Twenty‐one of 23 individuals with non‐SPTA1 (likely) pathogenic variants had EMA ≥ 43.6 AU, which was the optimal threshold in receiver operating characteristic (ROC) analysis. Accuracy was excellent at 93.4% and close to that of osmotic gradient ektacytometry (98.7%). In conclusion, we were able to simplify the EMA‐binding test by using rainbow beads as reference and (likely) pathogenic variants to define an accurate cut‐off value.

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Targeted Next Generation Sequencing and Diagnosis of Congenital Hemolytic Anemias: A Three Years Experience Monocentric Study

Cited by 22 publications

References 47 publications

Identification of variants in 94 Chinese patients with hereditary spherocytosis by next‐generation sequencing

Identification of variants in 94 Chinese patients with hereditary spherocytosis by next‐generation sequencing

Effect of primary lesions in cytoskeleton proteins on red cell membrane stability in patients with hereditary spherocytosis

Facilitating EMA binding test performance using fluorescent beads combined with next‐generation sequencing

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