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Significance of borderline hemoglobin A2 values in an Italian population with a high prevalence of β-thalassemia

¹ U.O. Ematologia II con Talassemia, Ospedale Vincenzo Cervello, Palermo
² Centro di riferimento Aziendale per la Prevenzione delle Talassemie, ASL 6 Palermo, Bagheria, Italy

Correspondence: Aurelio Maggio, U.O.C. Ematologia II con Talassemia, Azienda Ospedaliera Vincenzo Cervello, via Trabucco 180, Palermo, Italy. E-mail:aureliomaggio{at}virgilio.it

	ABSTRACT

TOP ABSTRACT Introduction Design and Methods Results and Discussion References

 
We report a retrospective analysis carried out on 23,485 subjects submitted to a screening program from 2000 to 2006. Of these subjects, 3,934 had borderline HbA₂ values from 3.1 to 3.9%; 410 samples, analyzed previously using PCR methods and sequencing because all of these were partners of a carrier of classical β-thalassemia, were selected for statistical analysis. Of 410 subjects, 94 (22.9%) were positive for a molecular defect in the β-, - or -globin genes. The most prevalent molecular defects were β IVS1 nt 6 (HBB c.92+6T C), co-inheritance of severe β thalassemia and mutations, β-promoter mutations and triplication of genes were detected; -thalassemia and Hb-variants were also evident. Borderline HbA₂ is not a rare event in a population with a high prevalence of β-thalassemia carriers. These data support the necessity to investigate these cases at a molecular level, particularly if the partner is a carrier of β-thalassemia.

Key words: HbA₂ borderline, β thalassemia, carrier screening.

	Introduction

TOP ABSTRACT Introduction Design and Methods Results and Discussion References

 
In a country with a high prevalence of β-thalassemia, the detection of borderline HbA₂ subjects should be addressed to avoid missing at risk couples. In Sicily it has been reported that there is a 6% prevalence of β-thalassemia carriers with an expected 1/270 probability of at risk couples.¹ In fact, while the presence of a single β-thalassemia allele is usually associated with hypocromic microcytic red cells and an increase in HbA₂ levels, in some cases, the effect of the β-thalassemia genotype or the interaction of this genotype with other molecular defects (-, -thalassemia) may render this allele completely silent with normal or borderline hematologic and HbA₂ levels.

Due to these factors, some individuals with β-globin gene silent mutations^2,3 or with triplication of -globin genotypes⁴ may be missed during screening programs for β-thalassemia, and may only be detected following the birth of an affected offspring. These genotypes must be considered at risk for having children with β-thalassemia if their partner is a carrier of the classical β-thalassemia mutation.⁵ In this paper, we report the results of the molecular analysis of 410 subjects with normal or β-thalassemia carrier-like phenotypes, without iron deficiency, and with HbA₂ levels between 3.1 and 3.9%. The main objective of the study was to evaluate the prevalence and the significance of borderline HbA₂ values for subjects in our population. The secondary aim was to perform a genotype-phenotype correlation within the sub-group of subjects with β or molecular defects.

	Design and Methods

TOP ABSTRACT Introduction Design and Methods Results and Discussion References

 
A previous study on borderline HbA₂ phenotype occurrence in areas with high prevalence of β-thalassemia,⁶ using HPLC procedures for HbA₂ determination, defined values of HbA₂ between 3.3 and 3.7% as borderline. However, because of the high heterogeneity of molecular defects^7,8 evident in our population, with also a prevalence of defects causing β⁺- or β⁺⁺-thalassemia, we defined HbA₂ levels as borderline if they were between 3.1 and 3.9%.

A retrospective analysis was carried out on 23,485 samples obtained during a program for β-thalassemia carrier screening in the Sicilian population from 2000 to 2006. We identified 3,934/23,485 (16.75%) samples showing borderline HbA₂ levels; of these, 726 were partners of carriers of β-thalassemia and all were submitted to molecular analysis; from these we selected only 410 samples, without iron deficiency anemia or hemoglobin variants, for statistical analysis. Figure 1 shows the profile of study performed in this work.

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Figure 1. Profile of study used to evaluate the genotypes β-thal or -thal presented in samples with HbA2 between 3.1 % and 3.9%.

This study was approved by the Ethical Committee of A.O. "V .Cervello" Hospital, and informed consent was obtained from all subjects.

	Results and Discussion

TOP ABSTRACT Introduction Design and Methods Results and Discussion References

 
Among 410 subjects with borderline HbA₂ values, 94 (22.9%) were positive for a molecular defect in the β-, - or -globin genes. No molecular defects were found in the remaining 316 individuals (Figure 1).

Among the positive samples, 55 had MCV < 80 fl (group A) and 39 had MCV 80 fl (group B). Table 1 shows the hematologic findings of the positive samples.

View this table: [in this window] [in a new window] [Download PPT slide]   Table 1. Hematologic parameter mean values and Standard Deviation (SD). (A) parameters of the genotype group found in sample with MCV<80 FL. Among double heterozygotes for severe β- and -thalassemia, 5 subjects showed β IVSI nt110 (HBB c.93-21G A), 3 had an association with HbA2-Yialousa (HBD c.82G T) and 2 with IVSII nt 897(HBD c.316-2 A G), 2 subjects a β IVSI nt1 (HBB c.92+1 G A) and HbA2-Yialousa, 3 subjects had a β codon 39 (HBB c.118C T) with HbA2-Yialousa and the last individual showed a double heterozygosis for β IVSII nt745 (HBB c.316-106C G) and HbA2-Yialousa. (B) Parameters of the genotype group found in sample with MCV 80 FL.

Six samples (10.90%) were heterozygotes for -101(HBB c.-151C T),² and -92 (HBB c.-142 C T)³ β-globin gene promoter mutations (Figure 1, Table 1A). Furthermore, 2 of these cases were also carriers of the -^3.7 deletion (Z84721.1:g.34164_37964del3801)¹⁰ and showed lower HbA₂ levels (3.4% and 3.5%).

Three (7.69%) subjects were carriers of hemoglobin variants, both and β (Figure 1, Table 1A). The hemoglobin variants detected were Hb Acharnes β-Cod 53 (HBB c.160G A),¹³ Hb Bernalda ₁-Cod 119 (HbA1 c.358C T)¹⁴ and Hb Ernz β-Cod 123 (HBB c.371C A),¹⁵ respectively. Moreover, the carrier of Hb Ernz (HBB c.371C A) also showed the -^3.7 deletion (Z84721.1:g.34164_37964del3801) with a greater reduction of MCV (69.7 fL) and MCH (23.4 pg) and a higher HbA₂ level (3.6%), without polycythemia. One sample was positive for the -globin gene triplication ( ^anti3.7)⁴ (Figure 1, Table 1A).

Group B
Two genotypes showed the -globin gene triplication ( ^anti3.7)⁴ and the β-globin gene promoter mutation, -101 (HBB c.-151C T)² and -92 (HBB c.-142 C T),³ accounted for the 71.8% of these molecular globin gene defects (Figure 1, Table 1B).

An undefined Single Nucleotide Polymorphism (SNP) in the β-globin gene was shown in 6 cases (15.4%) (Figure 1, Table 1A). Among these 5 unrelated samples, there was a T C substitution at 12 nts 5' to the poly A site or +1570 from the CAP site (HBB c.*+96T>C). This final substitution was described previously as a β thalassemia mutation¹⁶ and recently as a polymorphism.¹⁷ A point nucleotide substitution, not previously described, was also found in one sample at position β-54 G A (HBB c.-104G C) (M. Vinciguerra, personal communication, 2006).

Three samples (7.7%) presented an Hb Variant of the β-globin gene (Figure 1, Table 1B): 2 subjects with Hb Ernz (HBB c.371C A)¹⁵ and one with Hb Kokomo (HBB c.223G A) (M. Gallivan, personal communication, 2005). Two samples (5.1%) showed the -^3.7 deletion (Z84721.1:g.34164_37964del3801) (Figure 1, Table 1B).

The importance of detecting all β-thalassemia carriers is very relevant for a prevention screening program aimed at the identification of at risk couples. Moreover, although borderline HbA₂ values were previously described during a β-thalassemia screening program in a high risk population,⁶ so far, we do not have any accurate data on their prevalence and clinical significance.

The results of this retrospective analysis, although limited by the selection of samples, suggest both that this event is not rare in our population and that it may be associated with at risk β-thalassemia genotypes.

The most severe β molecular gene defects were found in Group A, and included samples with borderline HbA₂ values and MCV <80 fL (Figure 1). In fact, if we select the four main genotypes found in the A and B groups for a cut-off MCV value of 80 fL (Figure 2), we find that in the MCV 80 range it is possible to detect β-globin gene promoter mutations and triplication of the globin gene, while the most severe genotypes at the IVSI nt 6 (HBB c.92+6T C) and the co-inheritance of severe-β and thalassemia mutations were detected only in the MCV <80 range (Table 1, Figure 2).

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Figure 2. Distribution of HbA2 and MCV values of the four genotypes most presented in the group A and B, among the selected borderline HbA2 levels.

These findings suggest that, according to the evaluation of both MCV and HbA₂, it is possible to differentiate mild mutations from more severe β-globin gene defects. Moreover, this suggests that genotypes previously described (mutations of β-promoter and globin gene triplication) to be linked with a risk for mild or intermediate thalassemia phenotypes, if the partner is a carrier of a classical β thalassemia mutation,¹⁸ were present only in the group with borderline HbA₂ values and MCV 80 fL. A ROC analysis was performed considering each single HbA₂ value from 3.1 to 3.9% as a cut-off point. At the 3.5% HbA₂ cut-off value, sensitivity and specificity were 77.81% and 67.90% respectively. Using the 3.5% HbA₂ value as a cut-off, we correctly classified the 75.85% of cases with a Likelihood Ratio + of 3.06.

The ⁺ thalassemia genotype was found among samples from Group A and B (Figure 1, Table 1). In Group A, ⁺ thalassemia showed classical hematologic findings associated with an anomalous slight increase in HbA₂ level (Table 1A). Similar results were reported by Galanello¹⁹ during screening programs in Sardinia. Regulation factors may play a role in the increase in HbA₂ levels, although so far there is no plausible explanation.

Hemoglobin variants were also detected among samples from Group A and B (Figure 1, Table 1). Among these, three Hb variants, Hb Acharnes (HBB c.160G A),¹³ Hb Bernalda (HbA1 c.358C T)¹⁴ and Hb Ernz (HBB c.371C A),¹⁵ previously described in Italians, Greeks and in a family of Moroccan origin, were detected in Group A, while in Group B one case with Hb Kokomo (HBB c.223G>A) (M. Gallivan, personal communication, 2005) and 2 cases with Hb Ernz (HBB c.371C A)¹⁵ were found (Figure 1, Table 1). Probably, the β-globin gene variants, detected in Group A and B, caused a mild reduction in the expression of mutated alleles, allowing the carriers to present a normal hematologic profile with a slight increase in HbA₂ level.

The possible interaction of ⁺ thalassemia or of these Hb variants with a heterozygote for a classical β thalassemia mutation does not change the carrier phenotype^15,20 except for Hb Acharnes (HBB c.160G A). As reported in a previous study, a subject with intermediate thalassemia resulted from the association of Hb Acharnes with β IVSI nt1 (HBB c.92+1 G A) mutation.¹³ Finally, other genotypes detected only among Group B were an undefined Single Nucleotide Polymorphism (SNP) in the β-globin gene (Figure 1, Table 1B). These last samples were difficult to evaluate and it was necessary to incorporate family history to better understand their potential influence on the phenotype. However, so far there is no evidence regarding their possible role as at risk β-thalassemia genotypes.

Concerning the 316 negative samples with border-line HbA₂ levels (Figure 1), we may only speculate as to some possible explanations. In fact, while samples with MCV < 80 fl could be due to some rare and as yet unexplored molecular defects such as -^5.3 (Z84721.1:g.28684_33930del5246),²¹ or to nucleotide sequence changes in LCR or Enhancer regions of the β-globin gene,²² those with MCV 80 fL could be explained by different factors: increase of -globin gene expression, use of drugs like zidovudine (AZT),²³ presence of hyperthyroidism²⁴ or Pseudoxanthoma Elasticum (PXE)²⁵ or it is also possible to speculate that these phenotypes could be due to mutations in regulatory genes involved in the synthesis of specific protein factors. However, further studies are necessary to clarify this issue. For both groups the method used for HbA₂ determination (electrophoresis, HPLC) and interpretation of results must be considered. Paleari²⁶ evaluated the inter-laboratory variation and accuracy in the HbA₂ assay among 48 Italian laboratories routinely measuring HbA₂ HPLC analyzers; during this study unacceptable results were demonstrated from 17% to 31.9% and the worse results were obtained using a borderline HbA₂ sample. In conclusion, borderline HbA₂ levels are not a rare event in a population with a high prevalence of β-thalassemia carriers, with the most severe genotypes associated with microcytosis. These data support the necessity to investigate these cases at a molecular level, particularly if the partner is a carrier of β-thalassemia.

	Acknowledgments

 
we thank Prof Andrea Mosca for his continuous and valuable advices and the Foundation "Franco e Piera Cutino" for their continous support. Manuscript received February 4, 2008. Revised version arrived on May 10, 2008. Manuscript accepted May 14, 2008.

	Footnotes

 
Authorship and Disclosures

Both AG and CP were mainly responsible for the study. They contributed to designing the study, establishing the research plan, performed molecular analysis on and globin genes, analyzed the data, conducted the statistical analysis and drafted the article; MV and RL collected some of the patients for this study and performed hemoglobin and molecular analysis for β globin gene; PT, MA, GR collected part of the samples and data, and performed hemoglobin analysis; DR assisted in data analysis and interpretation; AM conceived the project, assisted in data interpretation, and checked and revised the final version of manuscript.

The authors reported no potential conflicts of interest.

Some of the data of this study were presented in part at the 41^st Congress of the Italian Society of Hematology, Bologna, Italy, 2007.

	References

TOP ABSTRACT Introduction Design and Methods Results and Discussion References

 

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