Association of an α-Globin Gene Cluster Duplication and Heterozygous β-Thalassemia in a Patient with a Severe Thalassemia Syndrome

Beta-thalassemia intermedia due to a complex alpha-globin rearrangement and a heterozygous beta thalassemia mutation

The alpha-thalassaemia alleles are very frequent in the world's population. The main molecular mechanism is a large deletion with the loss of one or two alpha genes. Another type of rarer abnormality exists: the gain of alpha genes. The consequence of a gain is an overproduction of alpha-globin chains, which aggravates a beta-thalassaemia trait into an intermedia phenotype (non-transfusion-dependent thalassaemia, NTDT). Here, we report the case of a young girl referred for a beta-NTDT with a combination never described in the literature: a heterozygous beta-thalassaemia mutation associated with a copy number gain of the alpha-globin locus and -alpha 3.7 deletion on the same allele.

Next-Generation Sequencing (NGS) and Third-Generation Sequencing (TGS) for the Diagnosis of Thalassemia

Thalassemia is one of the most heterogeneous diseases, with more than a thousand mutation types recorded worldwide. Molecular diagnosis of thalassemia by conventional PCR-based DNA analysis is time- and resource-consuming owing to the phenotype variability, disease complexity, and molecular diagnostic test limitations. Moreover, genetic counseling must be backed-up by an extensive diagnosis of the thalassemia-causing phenotype and the possible genetic modifiers. Data coming from advanced molecular techniques such as targeted sequencing by next-generation sequencing (NGS) and third-generation sequencing (TGS) are more appropriate and valuable for DNA analysis of thalassemia. While NGS is superior at variant calling to TGS thanks to its lower error rates, the longer reads nature of the TGS permits haplotype-phasing that is superior for variant discovery on the homologous genes and CNV calling. The emergence of many cutting-edge machine learning-based bioinformatics tools has improved the accuracy of variant and CNV calling. Constant improvement of these sequencing and bioinformatics will enable precise thalassemia detections, especially for the CNV and the homologous HBA and HBG genes. In conclusion, laboratory transiting from conventional DNA analysis to NGS or TGS and following the guidelines towards a single assay will contribute to a better diagnostics approach of thalassemia.

The hemoglobinopathies, molecular disease mechanisms and diagnostics

Hemoglobinopathies are the most common monogenic disorders in the world with an ever increasing global disease burden each year. As most hemoglobinopathies show recessive inheritance carriers are usually clinically silent. Programmes for preconception and antenatal carrier screening, with the option of prenatal diagnosis are considered beneficial in many endemic countries. With the development of genetic tools such as Array analysis and Next Generation Sequencing in addition to state of the art screening at the hematologic, biochemic and genetic level, have contributed to the discovery of an increasing number of rare rearrangements and novel factors influencing the disease severity over the recent years. This review summarizes the basic requirements for adequate carrier screening analysis, the importance of genotype–phenotype correlation and how this may lead to the unrevealing exceptional interactions causing a clinically more severe phenotype in otherwise asymptomatic carriers. A special group of patients are β‐thalassemia carriers presenting with features of β‐thalassemia intermedia of various clinical severity. The disease mechanisms may involve duplicated α‐globin genes, mosaic partial Uniparental Isodisomy of chromosome 11p15.4 where the HBB gene is located or haplo‐insufficiency of a non‐linked gene SUPT5H on chromosome 19q, first described in two Dutch families with β‐thalassemia trait without variants in the HBB gene.

Borderline HbA2 levels: Dilemma in diagnosis of beta-thalassemia carriers

There is inconsistency in the exact definition of diagnostic levels of HbA₂ for β thalassemia trait. While many laboratories consider HbA₂ ≥4.0 % diagnostic, still others consider HbA₂ ≥3.3 % or HbA₂ ≥3.5 % as the cut-off for establishing β thalassemia carrier diagnosis. This is because, over the years, studies have described β thalassemia carriers showing HbA₂ levels that lie above the normal range of HbA₂ but below the typical carrier range of β thalassemia. These, "borderline HbA₂ levels", though not detrimental to health, are significant in β thalassemia carrier diagnosis because they can lead to misinterpretation of results. In this review, we have evaluated the prevalence of borderline HbA₂ levels and discussed the causes of borderline HbA₂ values. We have also compiled an extensive catalogue of β globin gene defects associated with borderline HbA₂ levels and have discussed strategies to avoid misdiagnosing borderline HbA₂ β thalassemia carriers. Our analysis of studies that have delineated the cause of borderline HbA₂ levels in different populations shows that 35.4 % [626/1766] of all individuals with borderline HbA₂ levels carry a molecular defect. Among the positive samples, 17 % [299/1766] show β globin gene defects, 7.7 % [137/1766] show α thalassemia defects, 2.7 % [49/1766] show KLF1 gene mutations, 2.3 % [41/1766] show the co-inheritance of β and α thalassemia, 2.0 % [37/1766] show the co-inheritance of β and δ thalassemia and 1.8 % [32/1766] show α globin gene triplication. It appears that a comprehensive molecular work up of the β globin gene is the only definite method to detect borderline HbA₂ β thalassemia carriers, especially in populations with a high prevalence of the disease. The presence of associated genetic or acquired determinants may subsequently be assessed to identify the cause of borderline HbA₂.

Whole-exome sequencing identifies an α-globin cluster triplication resulting in increased clinical severity of β-thalassemia

Whole-exome sequencing (WES) has been increasingly useful for the diagnosis of patients with rare causes of anemia, particularly when there is an atypical clinical presentation or targeted genotyping approaches are inconclusive. Here, we describe a 20-yr-old man with a lifelong moderate-to-severe anemia with accompanying splenomegaly who lacked a definitive diagnosis. After a thorough clinical workup and targeted genetic sequencing, we identified a paternally inherited β-globin mutation (HBB:c.93-21G>A, IVS-I-110:G>A), a known cause of β-thalassemia minor. As this mutation alone was inconsistent with the severity of the anemia, we performed WES. Although we could not identify any relevant pathogenic single-nucleotide variants (SNVs) or small indels, copy-number variant (CNV) analyses revealed a likely triplication of the entire α-globin cluster, which was subsequently confirmed by multiplex ligation-dependent probe amplification. Treatment and follow-up was redefined according to the diagnosis of β-thalassemia intermedia resulting from a single β-thalassemia mutation in combination with an α-globin cluster triplication. Thus, we describe a case where the typical WES-based analysis of SNVs and small indels was unrevealing, but WES-based CNV analysis resulted in a definitive diagnosis that informed clinical decision-making. More generally, this case illustrates the value of performing CNV analysis when WES is otherwise unable to elucidate a clear genetic diagnosis.

Next-generation sequencing as a tool for breakpoint analysis in rearrangements of the globin gene clusters

INTRODUCTION

Next-generation sequencing (NGS), now embedded within genomic laboratories, is well suited to the detection of small sequence changes but is less well adapt for detecting structural variants (SV), mainly due to the relatively short sequence reads. Of the available target enrichment methods, bait capture or whole-genome sequencing appears better suited to detecting SV as there is less PCR amplification and is therefore more representative of the genome being sequenced.

MATERIAL AND METHODS

In 2015, we described the first inversion/deletion causing εγδβ- thalassemia using an NGS approach, with base-pair resolution. Bioinformatic processing of the sequencing data was manual and time-consuming. The methodology relied on detecting the presence or absence of the SV by assessing sequence coverage and then mapping the deletion by capturing and sequencing breakpoint spanning reads (split reads). In the period between developing more automated analytical methods, we identified the first duplication of the entire beta globin cluster.

RESULTS

Detecting the presence of the SV is reliable but capturing the breakpoint spanning reads is challenging. Confirmation by Sanger sequencing a breakpoint spanning amplicon has confirmed the NGS results in all cases.

CONCLUSIONS

We have now streamlined and automated the bioinformatic approach using Exome Depth to assess sequence coverage and Delly to detect split and discordant reads. The combined NGS and bioinformatic strategy has proven to be highly successful and applicable to routine diagnostics.

Thalassemia Intermedia Caused by 16p13.3 Sectional Duplication in a β-Thalassemia Heterozygous Child

Thalassemia intermedia is an inherited hemoglobin disorder characterized by a significant genetic and clinical heterogeneity. A wide spectrum of different genotypes-homozygous, heterozygous, and compound heterozygous-have been found to be responsible for it. The authors describe a Chinese child of β-thalassemia heterozygote with the mutation IVS2-654 (C→T) (HBB:c.316-197C→T) presenting with severe thalassemia intermedia. Multiplex ligation-dependent probe amplification (MLPA) and array comparative genomic hybridization (CGH) analyses of the α gene cluster revealed an approximate 146-kb duplication at 16p13.3 including the complete α gene cluster. The duplicated allele and the normal allele in trans result in a total of 6 active α genes. The severe clinical phenotype seemed to be related to the considerable excess of the α-globin and the β-globin deficit caused by the presence of the β-thalassemia. The α gene duplication should be considered in patients heterozygous for β-thalassemia who show a more severe phenotype than β-thalassemia trait.

Two novel copy number variations involving the α-globin gene cluster on chromosome 16 cause thalassemia in two Chinese families

Copy number variations (CNVs) can cause many genetic disorders and the structure analysis of unknown CNVs is important for clinical diagnosis. The human α-globin gene cluster lies close to the telomere of the short arm on chromosome 16. Copy number variations of this region produce excessive or insufficient α-globin chains which imbalances the β-globin chains, resulting in thalassemia. However, these CNVs usually cannot be precisely defined by traditional methods. Here, we designed a technique strategy and applied it to identify two CNVs involving the α-globin gene cluster causing thalassemia in two Chinese families. A novel 282 kb duplication (αααα(282)) was identified in family A and a novel 235 kb deletion (--(235)) in family B. Proband A is a coinheritance of β(CD41-42) and αααα(282) and showed severe β-thalassemia intermedia phenotype. Proband B is a compound heterozygote of --(235)/α(CS)α genotype and was diagnosed with hemoglobin H disease. The clinical phenotypic features of the CNVs carriers were described, together with a complete picture of molecular structure of these rearrangements. Two CNVs are novel rearrangements in α-globin clusters and the αααα(282) is the first to identify the exact insert position of a duplication region from the telomere on chromosome 16. In a conclusion, successful identification and characterization of these two novel CNVs not only demonstrates the precision and effectiveness of our strategy in analyzing the structure of unknown CNVs, but also extended the spectrum of thalassemia and provide new examples for studying genomic recombination.