Characterization of two novel Alu element-mediated α-globin gene cluster deletions causing α0-thalassemia by targeted next-generation sequencing

Thalassemia genetic screening of pregnant women with anemia in Northern China through comprehensive analysis of thalassemia alleles (CATSA)

Thalassemia is an inherited blood disorder and traditionally considered more prevalent in Southern China. However, with increased migration and intermarriage, more and more thalassemia carriers had been reported in Northern China. The lack of screening for thalassemia carriers may also result in missed diagnosis in Northern China. Additionally, thalassemia carriers are usually asymptomatic or mild anemia, but their anemia can get worse during pregnancy. Iron deficiency anemia (IDA) is also one of the causes of anemia during pregnancy. In particular, both IDA and thalassemia are characterized by microcytic hypochromic anemia. The overlap of symptoms and the presence of thalassemia carriers with IDA may lead to misdiagnosis. In this study, long-read sequencing based approach termed comprehensive analysis of thalassemia alleles (CATSA) had been performed for 244 pregnant women in Northern China whose results of routine blood examinations were abnormal. As a result, 16.39 % (40/244) of the anemic pregnant women carried at least one mutation of thalassemia. One Hb H patient and a rare α-globin gene triplication combined with β-thalassemia were also identified. Of the 44 thalassemia variants detected, the -α3.7, -SEA and HBB:c.316-197C > T were the most common variants. CATSA is of great significance for determining exact genotype of 22.50 % (9/40) thalassemia carriers because 8 variants they carried were outside the detection range of routine genetic tests. It is noted that 2 novel deletions of HBA gene were identified, expanding the genotype spectrum of α-thalassemia. Our findings demonstrate the importance of thalassemia screening in Northern China. Future research should focus on expanding screening to include more diverse populations.

Hotspots and status of Fetal Alpha-Thalassemia from 2009 to 2023: a bibliometric analysis

Objective

to evaluate the research status and development hotspots of fetal α-thalassemia by quantitatively analyzing the diagnostic status, key areas, related management measures and prospects of the disease by bibliometrics.

Methods

The global literature on fetal α-thalassemia and severe α-thalassemia from 2009-2023 in the Web of Science Core Collection (WOSCC) was visually analyzed by VOSviewer and CiteSpace.

Results

(1) The examination of the quantity of publications concerning fetal α-thalassemia indicates a rising tendency prior to 2018, followed by a decrease after 2018. (2)The United States, China, Italy, Thailand have published more papers, and the United States has more collaborating countries such as Italy and China. (3) Chiang Mai University and Harvard University are the top two institutions with the highest contribution. However, Chiang Mai University's H index (12) and citation frequency per article (8.05) are relatively low and the NC (6,342), H index (33) and citations per article (75.42) of Harvard University are higher than those of the other institutions. (4) Tongsong T, Gambari R and Fucharoen S are the top three prolific authors. Fucharoen S emerges as the most frequently cited author with 738 citations, excluding self-citations. (5) HEMOGLOBIN leading with 87 published papers (NC:601,IF: 0.82, H-index: 13), followed by BLOOD(58 papers, Nc: 3755, IF: 25.48, H-index: 40) and BLOOD CELLS MOLECULES AND DISEASES(39 papers, Nc: 729, IF: 2.37, H-index: 16). (6) The most cited article was published in science and the second and third cited articles were featured in the Proceedings of the National Academy of Sciences; the top 3 clusters of co-cited literature are "gene editing", "polymorphisms", "hydroxyurea". (7) Keywords analysis showe that the top two categories of keyword cluster focus on the prenatal diagnosis and the current treatment strategy of the disease, which remain the research hotspots.

Conclusions

Recent research on this topic has primarily focused on prenatal diagnosis and treatment strategies. A particular area of interest is the ongoing research on gene therapy.The advances in non-invasive diagnosis and therapeutic methods will change the current management approaches for fetal severe α-thalassemia in the future.

Detection of 13 Novel Variants and Investigation of Mutation Distribution by Next Generation Sequencing in Hemoglobinopathies: A Single Center Experience

Hemoglobinopathies are the most common monogenic disorders in the world. Traditional diagnostic algorithms generated by conventional methods for thalassemia can be labor-intensive and time-consuming due to the complexities of the genes involved and the variability in disease-causing mutations. With the advantages of next-generation sequencing (NGS) technology, molecular analysis of highly complex diseases such as hemoglobinopathies has become easier. Next-generation sequencing is a highly sensitive and effective method due to its capacity to sequence many gene regions simultaneously while allowing good read depths. In this study, single nucleotide changes, small deletions and copy number variations in HBA1, HBA2 and HBB in 914 patients with suspected hemoglobinopathy were analysed with NGS. At least one HBA1, HBA2, HBB or HBD variant was detected in 483 (52.8%) patients. Ten novel variants were detected in HBA1 and HBA2, three in HBB, and one in HBD. From these variants, c.*76T > A, c.301-24 G > A, c.301-24G > C c.-41C > G, c.-37-40C > G, c.-9G > C, c. 95 + 9C > T, c.95 + 26C > A, c.95 + 38C > T and c.*18C > G variants were located in α-globin genes, c.-25T > C, c.*103T > C and c92 + 39A > G variants were located in β-globin genes, and c.-43C > A was located in HBD. This is the first comprehensive study using NGS for the molecular diagnosis of hemoglobinopathies in Turkey. Accurate molecular diagnosis is of critical importance in hemoglobinopathies which are a public health problem due to their increased prevalence, high burden to society, and lack of curative treatment. Currently, NGS appears to be an advanced option over conventional methods to detect all variants occurring by molecular mechanisms and simultaneously analyse many genomic sequences.

Identification of a novel 91.5 kb-deletion (αα)FJ in the α-globin gene cluster using single-molecule real-time (SMRT) sequencing

OBJECTIVES

To present a novel 91.5-kb deletion of the α-globin gene cluster (αα)FJ identified by genetic assay and prenatal diagnosis in a Chinese family.

SUBJECTS AND METHODS

The proband was a 34-year-old G3P1 (Gravida 3, Para 1) female at the gestational age of 21+ weeks with a history of an edematous fetus. A routine genetic assay (reverse dot blot hybridization, RDB) was performed to detect common thalassemia mutations. Multiplex ligation-dependent probe amplification (MLPA) and single-molecule real-time technology (SMRT) were used to detect rare thalassemia mutations.

RESULTS

The hematological phenotypes of the proband, her mother, elder sister, husband, daughter, and nephew were consistent with the phenotype of α-thalassemia trait. No mutations were found in these family members by RDB, except for the proband's husband who carried an α-globin gene deletion --SEA/αα. MLPA results showed that the proband and other α-thalassemia-suspected relatives had heterozygous deletions around the POLR3K-3-463nt, HS40-178nt, and HBA-HS40-382nt probes. The 5'-breakpoint was out of probe scope and could not be determined. SMRT was performed and a 91.5-kb deletion (NC_000016.10: g.39268_130758del) in the α-globin gene cluster (αα)FJ was identified in the proband and other suspected relatives, which could explain their phenotypes. At the proband's gestational age of 22+ weeks, an amniotic fluid sample was collected and analyzed. As only the 91.5-kb deletion (αα)FJ was identified in the fetus with RDB, MLPA, and SMRT. The proband was suggested to continue the pregnancy.

CONCLUSION

We first reported a 91.5-kb deletion (NC_000016.10: g.hg38-chr16:39268-_130758del) of the HS-40 region in the α-globin gene cluster (αα)FJ identified in a Chinese family. Since the HS-40 loss of heterozygosity in combination with the heterozygous deletion --SEA might result in Hb Bart's hydrops fetalis, routine genetic assay, and SMRT were recommended to individuals at risk for prenatal diagnosis.

Molecular characterization of a novel 83.9-kb deletion of the α-globin upstream regulatory elements by long-read sequencing

Inherited deletions of upstream regulatory elements of α-globin genes give rise to α-thalassemia, which is an autosomal recessive monogenic disease. However, conventional thalassemia target diagnosis often fails to identify these rare deletions. Here we reported a family with two previous pregnancies of Hb Bart's hydrops fetalis and was seeking for prenatal diagnosis during the third pregnancy. Both parents had low level of Hemoglobin A2 indicating α-thalassemia. Conventional Gap-PCR and PCR-reverse dot blot showed the father carried -SEA deletion but did not identify any variants in the mother. Multiplex ligation-dependent probe amplification identified a deletion containing two HS-40 probes but could not determine the exact region. Finally, a long-read sequencing (LRS)-based approach directly identified that the exact deletion region was chr16: 48,642-132,584, which was located in the α-globin upstream regulatory elements and named (αα)JM after the Jiangmen city. Gap-PCR and Sanger sequencing confirmed the breakpoint. Both the mother and fetus from the third pregnancy carried heterozygous (αα)JM, and the fetus was normally delivered at gestational age of 39 weeks. This study demonstrated that LRS technology had great advantages over conventional target diagnosis methods for identifying rare thalassemia variants and assisted better carrier screening and prenatal diagnosis of thalassemia.

Two large novel alpha-globin gene cluster deletions causing alpha(0)-thalassemia in two Chinese families

INTRODUCTION

Monosomy of terminal 16p13.3 is a relatively common subtelomeric abnormality, most affected individuals presented α-thalassemia, some also have mental retardation, developmental abnormalities and/or speech delay and facial dysmorphism, which is termed ATR-16 syndrome. Here, we reported two novel 16p13.3 deletions involving the α-globin gene cluster and multispecies conserved sequences (MCSs), causing only a phenotype of α-thalassemia.

METHODS

Samples were collected from members of the two families and were subjected to haematological and comprehensive genetic analysis.

RESULTS

The novel 108 Kb deletion in family A extends from the non-protein coding RNA gene (WASIR2) to the NPRL3 gene, removing MCS-R1 to R3. This deletion should arise de novo because it wasn't detected in both parents. The novel 336 Kb deletion in family B should extend from telomere to ∼ chr16:336000, removing the entire α-globin gene cluster. Carriers of these two deletions presented with microcytosis and hypochromic red cells, in accordance with a phenotype of α⁰-thalassemia carrier.

CONCLUSION

Our study increases the mutation spectrum of α-thalassemia. MCSs deletion should be considered in clinical practice of thalassemia screening and diagnosis.

Third-generation sequencing: A novel tool detects complex variants in the α-thalassemia gene

OBJECTIVE

Thalassemia is a monogenic disorder with a high carrier rate in the southern region of China. Most laboratories currently follow the protocol of testing hematologic indicators in individuals with positive hematologic indicators and then using the hot-spot mutation test kit. A novel thalassemia gene test is performed if there is a mismatch between the hematology and hot-spot mutation test results. However, due to the large population in southern China, some individuals carry complex α-globin gene cluster (CAGC) variants in NG_000006.1, which are difficult to detect using conventional thalassemia genetic analysis protocols, leading to missed or false genetic test results for individuals carrying these complex α-globin gene cluster variants. When an individual carries a complex α-thalassemia gene variant, and an individual carries a β- thalassemia gene variant, there may be clinical symptoms that might complicate clinical consultation and prenatal diagnosis if not accurately detected. Third-generation sequencing (TGS) enables long-read single-molecule sequencing with high detection accuracy, and long-length DNA chain reads in high-fidelity reads mode. TGS can be used to analyze high homology and rich GC DNA sequences.

RESULTS

Four samples that showed abnormalities in the thalassemia genetic test were studied using TGS, revealing that they carried genotypes with complex α-globin gene cluster variants, one of which was a complex variant αα anti3.7 α anti3.7 α 17.2.

CONCLUSIONS

TGS detects complex α-globin gene cluster variants. This study may provide a reference protocol for the use of TGS for the detection of complex α-globin gene cluster variants. TGS can reveal individuals with complex α-thalassemia genotypes in the population and improve the accuracy of genetic counseling and prenatal diagnosis.

Characterization of a Novel 71.8 kb α0-Thalassemia Deletion and Subsequent Summary of a Practical Procedure for Thalassemia Molecular Diagnosis

Thalassemia is the most common monogenic disorder around the world. Based on the principle of genotype-phenotype correlation, identification of thalassemia mutations is the essential prerequisite for clinical diagnosis and management. Because only common mutations are routinely detected, the identification of rare or undetermined mutations is a challenge for clinical laboratories. Herein, a proband presenting with inconsistent phenotype-genotype correlation after routine molecular screening was investigated by multiplex ligation-dependent probe amplification (MLPA), targeted-next generation sequencing (targeted-NGS), gap-polymerase chain reaction (gap-PCR) and Sanger sequencing. Eventually, a novel 71.8 kb deletion (- -^71.8) was identified and characterized, which included HBZ (ζ), HBA2 (α2), and HBA1 (α1) genes and was causing α⁰-thalassemia (α⁰-thal). Furthermore, we summarized a practical procedure based on accumulated experience in studies and clinical practice, which can be a guide for molecular screening and clinical diagnosis of thalassemia, especially for identification of undetermined or novel mutations.

Update in Laboratory Diagnosis of Thalassemia

Alpha- and β-thalassemias and abnormal hemoglobin (Hb) are common in tropical countries. These abnormal globin genes in different combinations lead to many thalassemic diseases including three severe thalassemia diseases, i.e., homozygous β-thalassemia, β-thalassemia/Hb E, and Hb Bart’s hydrops fetalis. Laboratory diagnosis of thalassemia requires a number of tests including red blood cell indices and Hb and DNA analyses. Thalassemic red blood cell analysis with an automated hematology analyzer is a primary screening for thalassemia since microcytosis and decreased Hb content of red blood cells are hallmarks of all thalassemic red blood cells. However, these two red blood cell indices cannot discriminate between thalassemia trait and iron deficiency or between α- and β-thalassemic conditions. Today, Hb analysis may be carried out by either automatic high-performance liquid chromatography (HPLC) or capillary zone electrophoresis (CE) system. These two systems give both qualitative and quantitative analysis of Hb components and help to do thalassemia prenatal and postnatal diagnoses within a short period. Both systems have a good correlation, but the interpretation under the CE system should be done with caution because Hb A2 is clearly separated from Hb E. In case of α-thalassemia gene interaction, it can affect the amount of Hb A2/E. Thalassemia genotypes can be characterized by the intensities between alpha-/beta-globin chains or alpha-/beta-mRNA ratios. However, those are presumptive diagnoses. Only DNA analysis can be made for specific thalassemia mutation diagnosis. Various molecular techniques have been used for point mutation detection in β-thalassemia and large-deletion detection in α-thalassemia. All of these techniques have some advantages and disadvantages. Recently, screening for both α- and β-thalassemia genes by next-generation sequencing (NGS) has been introduced. This technique gives an accurate diagnosis of thalassemia that may be misdiagnosed by other conventional techniques. The major limitation for using NGS in the screening of thalassemia is its cost which is still expensive. All service labs highly recommend to select the technique(s) they are most familiar and most economic one for their routine use.