Factor VIII/genetics* ; Gene Duplication ; Humans ; Male ; Thrombosis/genetics*

FVIII is synthesized as a single chain precursor of approximately 280 kD with the domain structure of A1-A2-B-A3-C1-C2 and it circulates as a series of metal ion-linked heterodimers that result from cleavages at B-A3 junction as well as additional cleavages within B domain. Factor VIII is converted to its active form, factor VIIIa, upon proteolytic cleavages by thrombin and is a heterotrimer composed of the A1, A2, and A3-C1-C2 subunits. A1 subunits of factor VIIIa terminates with 36 residue segment (Met337-Arg372) rich in acidic residues. This segment is removed after cleavages at Arg336 by activated protein C, which results in inactivation of the cofactor. In the present study, site-directed mutagenesis of FVIII at Arg336 to Gln336 was performed in order to produce an inactivation resistant mutant rFVIII (rFVIIIm) with an extended physiological stability. A recombinant mutant heavy chain of FVIII (rFVIII-Hm; Arg336 to Gln336) and wild-type light chain of FVIII (rFVIII-L) were expressed in Baculovirus-insect cell (Sf9) system, and a biologically active recombinant mutant FVIII (rFVIIIm) was reconstituted from rFVIII-Hm and rFVIII-L in the FVIII-depleted human plasma containing 40 mM CaCl2. The rFVIIIm exhibited cofactor activity of FVIIIa (2.85 x 10(-2) units/mg protein) that sustained the high level activity during in vitro incubation at 37 degrees C for 24 h, while the cofactor activity of normal plasma was declined steadily for the period. These results indicate that rFVIIIm (Arg336 to Gln336) expressed in Baculovirus-insect cell system is inactivation resistant in the plasma coagulation milieu and may be useful for the treatment of hemophilia A.
Animal ; Baculoviridae/genetics ; Blotting, Western ; Cell Line ; Factor VIII/metabolism* ; Factor VIII/genetics ; Factor VIII/chemistry ; Factor VIII/biosynthesis ; Genetic Vectors ; Human ; Mutagenesis, Site-Directed ; Recombinant Proteins/metabolism ; Recombinant Proteins/genetics ; Recombinant Proteins/chemistry ; Recombinant Proteins/biosynthesis ; Spodoptera

OBJECTIVETo investigate the binding mechanisms of FVIII Trp1707Ser mutation-associated inhibitor.

METHODSThe APPT, PT, TT, Fg and FVIII:C were detected to make phenotypic diagnosis of haemophilia A. Inhibitors titer were measured by Bethesda method. Long distance-PCR (LD-PCR) and sequence-specific PCR were adopted for screening the intron 22 and intron 1 inversions respectively. FVIII coding and boundary sequences were analyzed by direct DNA sequencing. Inhibitor was reacted with different segments of FVIII, including heavy chain and its components A1 and A2, light chain and its components A3, C1 and C2. Corrected test was used to measure the remaining F VIII:C (% ) by adding pooled normal plasmas. After labeling purified inhibitors with biotin, western blot was performed to further confirm the binding reactions between inhibitors and segments.

RESULTSThe haemophilia A patient had mild deficiency of FVIII:C (1.1%) and had high FVIII inhibitor titer of 18.4 BU. A mutation c.97223C>G in exon 14 of F8 gene resulted to p.Trp1707Ser was identified by DNA sequencing. Corrected test showed that the remaining F VIII:C was increased when inhibitors reacted with heavy chain and light chain, especially with heavy chain. The remaining FVIII:C was also increased in the A2 and C2 domain reactions. No significant differences were seen in the A1, A3 and C1 domain reactions. Antigen-antibody reaction bands were confirmed by western blots when degenerated B-domain deleted recombinant FVIII, A2 and C2 were used as antigens.

CONCLUSIONThe binding sites of FVIIITrp1707Ser mutation inhibitor were the A2 domain of heavy chain and C2 domain of light chain. The binding reaction with heavy chain was more intense.

Binding Sites ; genetics ; Exons ; Factor VIII ; antagonists & inhibitors ; genetics ; Hemophilia A ; genetics ; Humans ; Male ; Mutation ; Young Adult

OBJECTIVETo detect potential mutation of F8 gene in a family affected with hemophilia type A.

METHODSInverse-shifting PCR (IS-PCR), next-generation sequencing (NGS), multiplex ligation-dependent probe amplification (MLPA), and short tandem repeat (STR) assays were used.

RESULTSIS-PCR showed that no inversion of F8 gene has occurred in the family. NGS detected no point mutation or small InDel in the proband, but suggested that the exon 2 of the F8 gene may be deleted. MLPA also showed that exon 2 of the F8 gene was absent in the proband, while the carriers were heterozygous for the deletion, though STR analysis yielded a paradoxical result.

CONCLUSIONNGS analysis has identified a large deletion of exon 2 of the F8 gene in a family affected with hemophilia A. Discretion is required when STR analysis was used for carrier screening and antenatal diagnosis. Combination of multiple methods can improve the accuracy for the detection of F8 gene mutations.

Child ; Exons ; genetics ; Factor VIII ; genetics ; Genetic Testing ; methods ; Hemophilia A ; Humans ; Male ; Pedigree ; Sequence Deletion ; genetics

OBJECTIVETo investigate the molecular mechanism of a Chinese hemophilia A patient in whom there was a discrepancy between the clinical bleeding symptoms and laboratory assay of FVIII activity (FVIII: C).

METHODSFVIII: C was detected by chromogenic and one-stage methods, and FVIII: Ag by ELISA. The APTT corrected test was used to screen the FVIII inhibitor and PCR amplification to analyze all the exons and flanking sequences of F8 gene of the proband, PCR products were purified and sequenced directly. The corresponding gene sites of family members were detected according to the gene mutation sites. Two B domain deleted human FVIII mutant expression plasmids His99Arg and His99Ala (pRC/RS V - BDhFVIIIcDNA) were constructed and transfected into HEK293T transiently. FVIII: Ag and FVIII: C of the expression products were assayed.

RESULTSThe proband APTT was prolonged, FVIII: Ag was 120% but FVIII: C <1% and no FVIII inhibitor in plasma. The results of anticoagulation and fibrinolytic functions were normal. The cross reacting material positive (CRM+) hemophilia A was diagnosed. Gene analysis revealed a A28828G substitution in exon 3 resulted in a H (His) to R (Arg) missense mutation and the same heterozygous was identified in his mother. In vitro expression of FVIII: Ag and FVIII: C of His99Arg were 180.0% and 5.8% , respectively, while FVIII: Ag and FVIII: C of His99Ala were 45.0% and 20.0% of that of wild type, respectively. His99Arg and His99Ala were diagnosed as CRM+ and CRM- mutations, respectively.

CONCLUSIONBoth the two F VIII mutations could express FVIII protein. However, CRM His99Arg mutant protein has little FVIII procoagulant activity and His99Ala has reduced FVIII function by routine methods.

Adult ; DNA Mutational Analysis ; Factor VIII ; genetics ; Genotype ; Hemophilia A ; etiology ; genetics ; Humans ; Male ; Mutation, Missense

OBJECTIVEInversions of intron 1 (Inv1) or intron 22 (Inv22) of the coagulation factor VIII gene (F8) may be found in 40%-50% of patients with severe hemophilia A. Such inversions cannot be detected by conventional sequencing. Due to homologous recombination, family-based linkage analysis may yield false positive or false negative results. In this study, Inverse-shifting PCR (IS-PCR) was used to detect potential inversions in two families affected with hemophilia A.

METHODSPeripheral venous blood, fetal amniotic fluid and fetal chorionic cells were harvested for genome DNA extraction. IS-PCR was used to detect Inv1 or Inv22 detection or its subtypes.

RESULTSIS-PCR has accurately detected Inv22 and Inv1 in both families and verified the subtypes of Inv22.

CONCLUSIONCarriers of Inv22 or Inv1 may be precisely detected with IS-PCR. The results have provided valuable information for genetic counseling and prenatal diagnosis for the affected families.

Child ; Chromosome Inversion ; Factor VIII ; genetics ; Genetic Counseling ; Hemophilia A ; diagnosis ; genetics ; Humans ; Introns ; Male ; Prenatal Diagnosis

OBJECTIVETo construct a recombinant lentiviral vector (pXZ208-BDDhFVIII) mediating B-domain-deleted human coagulation factor VIII (BDDhFVIII) gene and investigate its expression in HLF, Chang-Liver and MSC cells.

METHODSBDDhFVIII gene fragment was separated by endonuclease digestion and was cloned into the multiple cloning sites of pXZ208 to construct a recombinant lentiviral vector pXZ208-BDDhFVIII. Viral particles were prepared by means of three-plasmid cotransfection of 293T package cells by calcium phosphate precipitation. After infection, the coagulant activity of human FVIII in the culture medium of 293T, HLF, Chang-Liver and MSC cells was assayed by one-stage method. The gene transduction efficiency was assayed by flow cytometry (FCM). Furthermore, PCR was performed to test the integration of BDDhFVIII.

RESULTSThe infection rates of HLF, Chang-Liver and MSC were (74.52 +/- 7.57)%, (27.24 +/- 6.53)% and (42.34 +/- 5.84)% respectively. The activities of FVIII in supernatants of HLF, Chang-Liver and MSC were (54.1 +/- 5.6)%, (22.5 +/- 2.9)% and (12.5 +/- 2.7)% respectively. BDDhFVIII gene integration was detected in all the infected cells.

CONCLUSIONThe recombinant lentiviral vector pXZ208-BDDhFVIII was successfully constructed and efficiently integrated into target cells to express human FVIII activity in vitro.

Cell Line ; Factor VIII ; biosynthesis ; genetics ; metabolism ; Gene Expression ; Genetic Vectors ; Humans ; Lentivirus ; genetics ; Plasmids ; Transfection

OBJECTIVETo analyze intron 1 and 22 inversions in factor VIII (FVIII) gene in hemophilia A (HA) patients and and their families and to investigate the correlation between intron inversion and FVIII antibody.

METHODSAll patients were detected FVIII: C and FVIII antibody. In addition, 81 unrelated HA patients were directly detected by multiplex PCR and long-distance PCR for intron 1 and 22 inversions in FVIII gene. Pedigree investigation for some patients were conducted.

RESULTSIn 81 unrelated HA patients, 3 severe cases were found intron 1 inversion which accounted for 4.6% of total 65 severe cases. Of the 3 cases, one was FVIII antibody positive. Two female family members of a intron 1 inversion patient were identified as one carrier and one non-carrier. Twenty five of 65 (38.5%) severe cases were found intron 22 inversion. Of the 25 cases 1 was FVIII antibody positive. Nine female members in 5 HA families which had patients with intron 22 inversion were identified as 7 carries and 2 non-carriers.

CONCLUSIONBesides intron 22 inversion, intron 1 inversion was another important molecular defect in resulting in severe HA. Intron inversion analysis can also be used for deviation rectification of experiment grouping in HA patients. Intron 1 and 22 inversions may be one of the higher risk factors for resulting in FVIII antibodies.

Chromosome Inversion ; Chromosomes, Human, X ; Factor VIII ; genetics ; Female ; Hemophilia A ; genetics ; Humans ; Introns ; Male

OBJECTIVETo explore the immune tolerance induction (ITI) in a severe hemophilia A patient with inhibitor, and to improve the therapeutic efficacy for patient.

METHODSThe FVIII:C was assayed by one-stage method and FVIII antibody by Bethesda method. Mutation screening of FVIII gene intron 22 inversion was performed using LD-PCR.

RESULTSFVIII gene intron 22 inversion was detected in this patient. Clinical tolerance to FVIII was successfully induced after administration of the ITI regimen combined with immunosuppression. A fall of inhibitor titer from 8 BU to 0 BU after treatment for 3 months, and in vivo FVIII recovery (> 66%) was normalized. The patient had no bleeding episode in the following 6 months.

CONCLUSIONThis is the first case report on successful immune tolerance induction therapy in Chinese hemophilia A patient. ITI is the most effective therapy for hemophilia A with inhibitor.

Autoantibodies ; immunology ; Factor VIII ; genetics ; Hemophilia A ; genetics ; Humans ; Immune Tolerance ; drug effects ; Immunosuppression

The intron 22 inversion is caused by intrachromosomal homologous recombination of the Int22h (intron 22 homologous region) repeats in opposite orientation, accounting for almost 45%-50% of all cases of severe hemophilia A. By contrast, recombinations between similarly oriented int22h repeats in the same chromosome, homologous chromosomes or chromatids may cause deletion or duplication of the intermediate region between the two int22h copies, resulting in false-positive or false-negative possibility that obscure the characterization of intron 22 inversion. The modified long distance PCR(LD-PCR) and inverse shifting PCR(IS-PCR) would distinguish all the possible int22h-mediated rearrangements.
Factor VIII ; genetics ; Genotype ; Hemophilia A ; genetics ; Humans ; Introns ; Polymerase Chain Reaction ; methods ; Recombination, Genetic