Heteroduplex screening for molecular defects in factor IX genes from haemophilia B families

F9 missense mutations impairing factor IX activation are associated with pleiotropic plasma phenotypes

BACKGROUND

Circulating dysfunctional factor IX (FIX) might modulate distribution of infused FIX in hemophilia B (HB) patients. Recurrent substitutions at FIX activation sites (R191-R226, >300 patients) are associated with variable FIX activity and antigen (FIXag) levels.

OBJECTIVES

To investigate the (1) expression of a complete panel of missense mutations at FIX activation sites and (2) contribution of F9 genotypes on the FIX pharmacokinetics (PK).

METHODS

We checked FIX activity and antigen and activity assays in plasma and after recombinant expression of FIX variants and performed an analysis of infused FIX PK parameters in patients (n = 30), mostly enrolled in the F9 Genotype and PK HB Italian Study (GePKHIS; EudraCT ID2017-003902-42).

RESULTS

The variable FIXag amounts and good relation between biosynthesis and activity of multiple R191 variants results in graded moderate-to-mild severity of the R191C>L>P>H substitutions. Recombinant expression may predict the absence in the HB mutation database of the benign R191Q/W/K and R226K substitutions. Equivalent changes at R191/R226 produced higher FIXag levels for R226Q/W/P substitutions, as also observed in p.R226W female carrier plasma. Pharmacokinetics analysis in patients suggested that infused FIX Alpha distribution and Beta elimination phases positively correlated with endogenous FIXag levels. Mean residence time was particularly prolonged (79.4 h, 95% confidence interval 44.3-114.5) in patients (n = 7) with the R191/R226 substitutions, which in regression analysis were independent predictors (β coefficient 0.699, P = .004) of Beta half-life, potentially prolonged by the increasing over time ratio between endogenous and infused FIX.

CONCLUSIONS

FIX activity and antigen levels and specific features of the dysfunctional R191/R226 variants may exert pleiotropic effects both on HB patients' phenotypes and substitutive treatment.

Pathological mechanism and antisense oligonucleotide-mediated rescue of a non-coding variant suppressing factor 9 RNA biogenesis leading to hemophilia B

Loss-of-function mutations in the human coagulation factor 9 (F9) gene lead to hemophilia B. Here, we dissected the consequences and the pathomechanism of a non-coding mutation (c.2545A>G) in the F9 3’ untranslated region. Using wild type and mutant factor IX (FIX) minigenes we revealed that the mutation leads to reduced F9 mRNA and FIX protein levels and to lower coagulation activity of cell culture supernatants. The phenotype could not be compensated by increased transcription. The pathomechanism comprises the de novo creation of a binding site for the spliceosomal component U1snRNP, which is able to suppress the nearby F9 poly(A) site. This second, splicing-independent function of U1snRNP was discovered previously and blockade of U1snRNP restored mutant F9 mRNA expression. In addition, we explored the vice versa approach and masked the mutation by antisense oligonucleotides resulting in significantly increased F9 mRNA expression and coagulation activity. This treatment may transform the moderate/severe hemophilia B into a mild or subclinical form in the patients. This antisense based strategy is applicable to other mutations in untranslated regions creating deleterious binding sites for cellular proteins.

The elucidation of the pathomechanisms of non-coding variants yields important insights into diseases as well as cellular processes causing the defect. Although these variants may account for the majority of phenotypic variation, only a minority of them can be explained mechanistically. The human coagulation factor 9 3’ UTR variant described here converts a non-essential sequence motif into a U1snRNP-binding site with deleterious effects on RNA 3’ end processing at the nearby poly(A) site. Poly(A) site suppression by U1snRNP was described before and it normally protects cellular mRNAs from premature termination. However, if misled by creation of a U1 site close the authentic poly(A) site as in the F9 3’ UTR, this nuclear surveillance mechanism results in the opposite. Since recognition by U1snRNP depends on sequence complementarity we were able to use antisense oligonucleotides to mask the mutant site and partially restored F9 mRNA levels. This antisense based strategy may be applicable to other variants in untranslated regions, which create deleterious binding sites for cellular proteins.

A novel gene expression system: non-viral gene transfer for hemophilia as model systems

It is highly desirable to generate tissue-specific and persistently high-level transgene expression per genomic copy from gene therapy vectors. Such vectors can reduce the cost and preparation of the vectors and reduce possible host immune responses to the vector and potential toxicity. Many gene therapy vectors have failed to produce therapeutic levels of transgene because of inefficient promoters, loss of vector or gene expression from episomal vectors, or a silencing effect of integration sites on integrating vectors. Using in vivo screening of vectors incorporating many different combinations of gene regulatory sequences, liver-specific, high-expressing vectors to accommodate factor IX, factor VIII, and other genes for effective gene transfer have been established. Persistent and high levels of factor IX and factor VIII gene expression for treating hemophilia B and A, respectively, were achieved in mouse livers using hydrodynamics-based gene transfer of naked plasmid DNA incorporating these novel gene expression systems. Some other systems to prolong or stabilize the gene expression following gene transfer are also discussed.

Rapid and robust screening of the Menkes disease/occipital horn syndrome gene

Menkes disease and occipital horn syndrome (OHS) are allelic neurogenetic disorders of copper transport associated with mutations in an X-linked gene, ATP7A. This gene encodes a copper-transporting P-type ATPase. The spectrum of mutations at the Menkes/OHS locus is estimated to include 1% chromosomal rearrangements and 15-20% large deletions, with the remaining defects involving small alterations. There is a compelling need for a rapid and reliable molecular diagnostic approach for patients and families impacted by these conditions. In addition to testing suspected affected males, carrier screening of females in Menkes/OHS families and prenatal evaluation of at-risk pregnancies will be enhanced by the wider availability of robust mutation analysis for this large (23-exon) locus. Here we describe a stepwise approach to mutation screening for these disorders that successfully identified molecular alterations in over 95% of our patient population (n = 49). This genomic DNA-based technique employs multiplex PCR, heteroduplex analysis, and direct sequencing, in a serial fashion. This approach should find application in molecular diagnostic laboratories in the United States and other countries. Currently, only a single European center provides commercial testing for unknown mutations in Menkes/OHS patients, even though these disorders occur worldwide.

Hemophilic factor VIII C1- and C2-domain missense mutations and their modeling to the 1.5-angstrom human C2-domain crystal structure

Factor VIII C domains contain key binding sites for von Willebrand factor (vWF) and phospholipid membranes. Hemophilic patients were screened for factor VIII C-domain mutations to provide a well-characterized series. Mutated residues were localized to the high-resolution C2 structure and to a homology model of C1. Of 30 families found with mutations in the C domains, there were 14 missense changes, and 9 of these were novel. Of the missense mutations, 10 were associated with reduced vWF binding and 8 were at residues with surface-exposed side chains. Six of the 10 mutants had nearly equivalent factor VIII clotting activity and antigen level, suggesting that reduced vWF binding could cause hemophilia by reducing factor VIII stability in circulation. When the present series was combined with previously described mutations from an online international database, 11 C1 and C2 mutations in patients with mild or moderately severe hemophilia A were associated with antibody-inhibitor development in at least one affected individual. Of these substitutions, 6 occurred at surface-exposed residues. As further details of the C1 structure and its interface with C2 become available, and as binding studies are performed on the plasma of more patients with hemophilic C-domain mutations, prediction of surface binding sites should improve, allowing confirmation by site-specific mutagenesis of surface-exposed residues.

Hemophilic factor VIII C1- and C2-domain missense mutations and their modeling to the 1.5-angstrom human C2-domain crystal structure

Factor VIII C domains contain key binding sites for von Willebrand factor (vWF) and phospholipid membranes. Hemophilic patients were screened for factor VIII C-domain mutations to provide a well-characterized series. Mutated residues were localized to the high-resolution C2 structure and to a homology model of C1. Of 30 families found with mutations in the C domains, there were 14 missense changes, and 9 of these were novel. Of the missense mutations, 10 were associated with reduced vWF binding and 8 were at residues with surface-exposed side chains. Six of the 10 mutants had nearly equivalent factor VIII clotting activity and antigen level, suggesting that reduced vWF binding could cause hemophilia by reducing factor VIII stability in circulation. When the present series was combined with previously described mutations from an online international database, 11 C1 and C2 mutations in patients with mild or moderately severe hemophilia A were associated with antibody-inhibitor development in at least one affected individual. Of these substitutions, 6 occurred at surface-exposed residues. As further details of the C1 structure and its interface with C2 become available, and as binding studies are performed on the plasma of more patients with hemophilic C-domain mutations, prediction of surface binding sites should improve, allowing confirmation by site-specific mutagenesis of surface-exposed residues.

Inclusion of the hepatic locus control region, an intron, and untranslated region increases and stabilizes hepatic factor IX gene expression in vivo but not in vitro

We systematically compared human factor IX gene expression from a variety of plasmids containing different cis-regulatory sequences after transfection into different hepatocyte cell lines, or in vivo, after their injection into the livers of mice. Although there was a 1.5- to 2.0-fold variation in gene expression from cultured cells, a 65-fold variation was observed in the in vivo studies. We found that a plasmid containing the apolipoprotein E locus control region (HCR), human alpha1-antitrypsin (hAAT) promoter, hFIX minigene (hFIXmg) sequence including a portion of the first intron (intron A), 3'-untranslated region (3'-UTR), and a bovine growth hormone polyadenylation signal (bpA) produced the highest serum level of human factor IX, reaching 18 microg/ml (normal = 5 microg/ml) 1 day after injection. Although most of the plasmid DNAs resulted in transient gene expression, inclusion of an intron, a polyadenylation signal from either the 1.7-kb 3'-UTR or the 0.3-kb bpA, and the HCR resulted in persistent and therapeutic levels of hFIX gene expression, ranging from 0.5 to 2 microg/ml (10 to 40% of normal) for 225 days (length of experiment). These data underscore the importance of cis sequences for enhancing in vivo hepatic gene expression and reemphasize the lack of correlation of gene expression in tissue culture and in vivo studies.

A domain mutations in 65 haemophilia A families and molecular modelling of dysfunctional factor VIII proteins

A variety of mutations are found in haemophilia A families. Those with circulating, dysfunctional protein can provide insights into structural determinants of factor VIII function. A molecular model based upon the crystal structure of the homologous A domains in caeruloplasmin enables predictions of molecular consequences of mutations. To identify haemophilic mutations in coding regions for three A domains of factor VIII and predict amino acid substitutions important for coagulant cofactor function, amplified DNA fragments from 188 unrelated haemophilia A families were screened for heteroduplex formation. Exons 1-19 were examined. 65 families were positive for 58 distinct mutations (39 novel) on DNA sequencing. 12 were non-missense mutations. 38 missense mutations were found in patients that circulate or potentially circulate dysfunctional factor VIII protein and are in an A domain molecular model. Of these 38, 12 have identical residues among all known species of factors V, VIII and caeruloplasmin. These 38 mutations have been localized onto a factor VIII A domain molecular model. Of these, 19 are in coiled, 15 in beta-pleated sheet, and two each in turns and alpha-helical structures. 15 substituted residues are on the surface, nine are partially on the surface and 14 are buried within the model structure. Mutant side-chain substitutions were inserted to predict changes in surface groups or, for buried residues, potential surface areas whose structure is probably disrupted by the substitution.

Genetic Counseling by Analysis of Intron 22 Inversions of the Factor VIII Gene

Ten patients with severe hemophilia A and 10 with moderate and mild hemophilia A were studied. Five of 10 unrelated patients with severe hemophilia A had the distal telo meric int22h sequence, none had the proximal sequence, and one had a unique variant factor VIII gene rearrangement. Car rier detection was done in these six families. All mothers and two daughters of the patients were to be carriers. Six of the 15 at-risk female relatives were heterozygous for the rearranged and normal allele and were carriers. These results indicate that the rearrangement assay is very useful for carrier detection in families with severe hemophilia A. Key Words: Hemophilia A—Factor VIII gene rearrangement—Genetic counseling.

Consequences of factor IX mutations in 26 families with haemophilia B

Haemophilia B is due to a variety of mutations within the factor IX gene. In the Seattle series, 26 additional unrelated families have had a mutation identified within the past 2 years. Of these, 11 were common recurrent point mutations identifiable by rapid restriction digest screening; eight of these probably represent founder mutations. 15 others were identified by sequencing amplified coding region fragments; eight are novel. Two each had frameshift and donor splice mutations and 11 had missense mutations. Five of these mutations associated with normal levels of circulating dysfunctional factor IX were computer modelled into coordinates for factor IXa.

Mutation scanning methods for the analysis of parasite genes

Molecular variation is widespread in parasite populations, and its analysis has important implications for studying aspects relating to the function and organisation of genes, and the taxonomy, phylogeny and population genetics of parasites. This article reviews some PCR-based mutation scanning techniques that have advantages over currently used DNA methods for the analysis of genetic variation in parasites. The review is technical and describes briefly the principles of relevant techniques, examines some of their advantages and disadvantages and gives several examples for possible applications.

The factor IX gene as a model for analysis of human germline mutations: an update

The variation generated by germline mutation is essential for evolution, but individuals pay a steep price in the form of Mendelian disease and genetic predisposition to complex disease. Indeed, the health of a species is determined ultimately by the rate of germline mutation. Analysis of the factor IX gene in patients with hemophilia B has provided insights into the human germline mutational process. Herein, seven topics will be reviewed with emphasis on recent advances: (i) proposed mechanisms of deletions, inversions, and insertions; (ii) discordant sex ratios of mutation and associated age effects; (iii) somatic mosaicism; (iv) founder effects; (v) mutation rates; (vi) the factor IX gene as a germline mutagen test; and (vii) cancer as a possible mechanism for maintaining a constant rate of germline mutation.

Heteroduplex analysis in hemophilia B: detection of two novel factor IX gene mutations

Heteroduplex analysis of polymerase chain reaction (PCR)-amplified factor IX (FIX) sequences in eight hemophilia B pedigrees localized the causative hemophilia mutation to a single exon in each case. Subsequent PCR-based direct DNA sequence analysis identified two novel FIX mutations and six recurrent mutations. Three of the eight pedigrees represent sporadic hemophilia B, and direct mutation analysis facilitated hemophilia carrier diagnosis in each case.

Clinical correlates among 49 families with hemophilia A and factor VIII gene inversions

Inversions between a gene A copy within intron 22 of the factor VIII gene and additional copies outside the factor VIII gene were found in 49 families with hemophilia A. Inversion patterns were that of recombination with a distal gene A copy in 34, a proximal copy in 14, and a third (variant) copy in one. Baseline factor VIII clotting levels were <1% of normal in 43 and 1% in 6. No inversion was detected in 61 other families whose affected members had < or = 1% activity levels nor in 42 families with moderately severe hemophilia A and 2-5% baseline levels. Both high titer and low level alloantibody inhibitors were found in patients with of without an inversion. Of 13 high titer inhibitors, 8 were persistent and 1 of these patients had an inversion. Of 5 that responded to daily factor VIII infusions, 4 were in patients with gene inversions. Of the 49 families with an inversion, the occurrence of hemophilia was isolated in 30 and the mother was a carrier in the 25 in which additional family members were informative. In three of these families with isolated occurrence, the maternal grandmother was a carrier whereas in three others a de novo mutation occurred in the maternal grandfather's factor VIII gene. Screening for gene inversions in patients with severe (or "borderline" severe) hemophilia A provides a direct marker of the mutation in 45% of families. It is useful even if there is no living affected member and in predicting the likely severity of an infant in which there are no reliable baseline clotting activities, including 70% of families with isolated occurrences of hemophilia A.

Haemophilia B (sixth edition): a database of point mutations and short additions and deletions

The sixth edition of the haemophilia B database lists in easily accessible form all known factor IX mutations due to small changes (base substitutions and short additions and/or deletions of <30 bp) identified in haemophilia B patients. The 1380 patient entries are ordered by the nucleotide number of their mutation. Where known, details are given on factor IX activity, factor IX antigen in circulation and origin of mutation. References to published mutations are given and the laboratories generating the data are indicated.