A novel missense mutation, p.Phe360Cys, in FIX gene results in haemophilia B in a female patient with skewed X-inactivation

Molecular pathogenesis of a novel Met394Thr variant causing hemophilia B

BACKGROUND

Hemophilia B (HB), a rare bleeding disorder, shows X-linked recessive inheritance and is caused by heterogeneous variants in the FIX gene (F9) encoding coagulation factor IX (FIX). This study aimed to investigate the molecular pathogenesis of a novel Met394Thr variant causing HB.

METHODS

We used Sanger sequencing to analyze F9 sequence variants in members of a Chinese family with moderate HB. Subsequently, we performed in vitro experiments on the identified novel FIX-Met394Thr variant. In addition, we performed bioinformatics analysis of the novel variant.

RESULTS

We identified a novel missense variant (c.1181T>C, p.Met394Thr) in a Chinese family with moderate HB in the proband. The proband's mother and grandmother were carriers for the variant. The identified FIX-Met394Thr variant did not affect the transcription of F9 and the synthesis and secretion of FIX protein. The variant may, therefore, affect the physiological function of FIX protein by disrupting its spatial conformation. In addition, another variant (c.88+75A>G) in intron 1 of F9 was identified in the grandmother, which may also affect FIX protein function.

CONCLUSION

We identified FIX-Met394Thr as a novel causative variant of HB. Further understanding of the molecular pathogenesis underlying FIX deficiency may guide novel strategies for precision HB therapy.

A Case of Acquired Hemophilia A and Congenital Hemophilia B

Congenital hemophilia B is a rare, inherited X-linked bleeding disorder caused by a deficiency of factor IX (FIX). Acquired hemophilia A is a rare, acquired bleeding disorder which presents as new onset bleeding in older adults due to the development of autoantibodies against factor VIII (FVIII). This report describes the management of a patient with congenital hemophilia B and acquired hemophilia A. We highlight the limitations in maintaining FVIII levels using factor replacement alone and the need for escalating treatment such as rituximab and prednisone in patients with acquired hemophilia A. This case demonstrates the importance of continuing to pursue alternative diagnoses when existing ones do not explain the full clinical picture and laboratory data is inconclusive.

Skewed X-Chromosome Inactivation and Parental Gonadal Mosaicism Are Implicated in X-Linked Recessive Female Hemophilia Patients

Background: Hemophilia A (HA) and B (HB) are X-linked recessive disorders that mainly affect males born from a mother carrier. Females are rarely affected but a number of mechanisms have been suggested in symptomatic females, such as skewed X-chromosome inactivation (XCI), chromosomal rearrangements, and hermaphrodites. Different methodologies are required to elucidate the underlying causes of such diseases in female patients. Methods: Three families with female hemophilia patients, including two HA and one HB, were enrolled for genetic analyses. Cytogenetics, molecular examinations on F8 and F9 genes, XCI assay, and linkage analysis were performed. Results: All three female patients are demonstrated to be heterozygous for an F8, or F9 mutation: one patient is inherited from her unaffected mother and the other two are sporadic cases. All three patients exhibit skewed XCI. The inherited patient is found to be unmethylated in the maternal X chromosome, which increases the potential for the expression of the mutant allele. The two sporadic cases are hypomethylated or unmethylated in the paternal X chromosome, suggesting that paternal gonadal mosaicism may exist in these families. Conclusions: In addition to screening for coagulation function, different genetic analyses are mandatory to explore the nature of mechanisms responsible for the X-linked recessive disorders in female patients as shown in this study. Our results confirm that skewed XCI is responsible for hemophilia in heterozygous female patients. Likewise, our results implicate that parental gonadal mosaicism, followed by skewed XCI, contributes to hemophilia in “sporadic” female patients.

X‑linked adrenoleukodystrophy caused by maternal ABCD1 mutation and paternal X chromosome inactivation

X-linked adrenoleukodystrophy (X-ALD) is the most common peroxisomal disorder. It is caused by defects in the ATP-binding cassette subfamily D member 1 (ABCD1) gene, resulting in impaired peroxisomal β-oxidation of very-long-chain fatty acids (VLCFAs). As an X-linked recessive disease, female X-ALD carriers are typically asymptomatic. In the present study, a 7-year-old girl was diagnosed with cerebral ALD. Brain magnetic resonance imaging revealed asymmetric demyelination of bilateral white matter. Plasma VLCFAs level showed a substantial increase. Whole exome and Sanger sequencing revealed an ABCD1 c.919C>T (p.Q307X) heterozygous pathogenic mutation, which was inherited from the asymptomatic mother. X chromosome inactivation (XCI) analysis revealed that the normal paternal X chromosome was almost completely inactivated. Thus, the maternal ABCD1 mutation and paternal XCI were responsible for causing the disease in the patient. XCI may be one reason female X-ALD carriers can be symptomatic.