Harold L. James

The dysfunction of coagulation factor VIIPadua results from substitution of arginine-304 by glutamine

This study addresses whether a mutation in the factor VIIPadua gene could explain the reduced activity of the inherited variant protein. All nine exons of the normal and Padua factor VII gene were amplified using the polymerase chain reaction, cloned into pUC19 and sequenced. A point mutation (G to A at nucleotide position 10828) was found which results in the substitution of a glutamine (CAG) for arginine (CGG) at amino acid position 304. This substitution creates a PvuII restriction site useful in screening for the defect and in demonstrating homozygosity. This substitution involves an arginine residue in the catalytic domain within a Leu*****Pro******Cys motif which occurs in conserved region 5 in up to 16 coagulation and other serine proteinases. On the basis of conformational homology among serine proteinases, it is suggested that the observed amino acid substitution in factor VIIPadua could cause structural changes affecting its activation and/or catalytic activity.

Factor XKetchikan: a variant molecule in which Gly replaces a Gla residue at position 14 in the light chain

To seek the possible molecular defect in a patient with deficient factor X plasma procoagulant activity, factor X gene exons and splice junctions were subjected to heteroduplex analyses and sequencing. A mutation in exon 2 was confirmed as substitution of A by G at nucleotide position 206, coding for Gly instead of a Glu which is a normal precursor for γ-carboxylated glutamic acid (Gla) at amino acid position 14. An abolished TaqI restriction site was used to indicate homozygosity of the defect, but occurrence of a gene deletion with attendant heterozygosity could not be excluded. The deletion of a Gla residue could affect the Ca2+-binding properties of factor X or confer a flexibility interfering with the interactive properties of the light chain. The defect could explain the decreased functional activity of circulating factor X and the mild bleeding tendency of the propositus.

Factors XWenatchee I and II: compound heterozygosity involving two variant proteins.

Variant factor X in an individual with a mild bleeding tendency was suspected based on deficient procoagulant activity (10-20% of normal) and antigen (30-35% of normal) levels of plasma factor X. Heteroduplex analysis of factor X gene exons indicated heterozygosity for mutations in both exons 6 and 4, confirmed by direct sequencing of the amplified exons. Substitution of C by T at nucleotide position 13,984 (Arg-139 to Cys) was found in the factor X gene exon 6 of the propositus. This mutation creates a BsmI site and the patient tested heterozygous for the BsmI cleavage involved, as did one of his two daughters. In addition, exon 4 was found to have the normal A and a novel C (Asn-57 to Thr) at nucleotide position 9338. The exon 4 mutation creates a BsaJI site, detectable after amplification mismatch to remove an existing BsaJI site. Both the patient and the second of his two daughters were heterozygous for this cleavage. The two variant proteins are called factors XWenatchee I (Arg-139 to Cys) and II (Asn-57 to Thr). A mixed variant isolate derived from the plasma of the propositus exhibited heavy/light chains of normal size, as well as an apparent single-chain molecule not dissociable by reducing agent. A single-chain molecule would be predicted for form I, if the mutation blocks processing cleavages that normally remove a tripeptide interposed between the heavy and light chains. A Western blot of partially purified factor X from the daughter who inherited the form I defect revealed a component migrating the same as the putative single-chain species. Based upon the factor X activity vs. antigen ratios for the propositus and both daughters, both forms I and II are probably dysfunctional molecules.

Expression of human factor X with normal biological activity in human embryonic kidney cells

SummaryHuman embryonic kidney cells (293) were transfected with a construct containing human factor X cDNA and selected for G418 resistance. The level of expression of recombinant factor X in serum-free medium was 4 to 5 μg/ml. Purified recombinant factor X had a molecular size identical to that of normal plasma factor X. Amino-terminal sequencing revealed normal processing cleavages. The γ-carboxy Glu and β-OH Asp content of the recombinant factor X was close to 90% of the expected levels of these post-translational residues. The specific activity of recombinant factor X was about 95% of that of plasma factor X in three plasma-based clotting assays. This report demonstrates that 293 cells can produce a high level of biologically active factor X and describes a visual criterion for verifying the transfection process.

Differences between human and rabbit coagulation factor X-implications for in vivo models of thrombosis.

The activation of factor X (fX) to factor Xa (fXa) marks the penultimate step in the coagulation cascade and modulating fXa activity may be effective for antithrombotic therapy. Even though fXa inhibitors are screened using in vitro inhibition of human fXa (HfXa) while subsequent evaluation uses in vivo rabbit models, there is limited knowledge of species differences between the coagulation proteins. When comparing amino acid sequences for the human (HfX) and rabbit (RafX) protein, differences are found in the activation peptide and active site regions. In order to study the relative functional characteristics of HfX and RafX, we asked (1) whether fX from the two species is immunologically related, (2) whether the two proteins are activated to fXa in a similar manner, (3) whether HfXa and rabbit factor Xa (RafXa) have similar catalytic activities toward tripeptide substrates. To answer (1), we expressed RafX-glutathione S-transferase (RafX-GST) fusion protein in bacteria and purified the protein for use as an antigen. The resulting monoclonal antibodies were suitable for affinity purification of plasma RafX and for effective anticoagulation in rabbit plasma clotting assays. We found two antibodies (mAb 214 and mAb 290) that anticoagulated rabbit plasma in a dose responsive manner but did not cross-react with human plasma. At a concentration of 500 nM, mAb 214 attained a two-fold extension of rabbit plasma activated partial thromboplastin time (aPTT). To answer (2), we purified plasma RafX and compared the activation of HfX and RafX with Russells viper venom (RVV-X). Under equivalent reaction conditions, conversion was 30% slower for the rabbit protein. To answer (3), amidolytic activity of HfXa and RafXa were assayed by cleavage of three para-nitroanilide (pNA) substrates (S2222 [Bz-Ile-Glu(gamma-OR)-Gly-Arg-pNA.HCl], S2765 [Z-D-Arg-Gly-Arg-pNA.HCl] and Spectrozyme Xa [MeO-CO-D-CHG-Gly-Arg-pNA.AcOH]). Michaelis constants (K(m)) for the rabbit protein were 187, 72 and 69 microM, respectively, and for the human analog, 255, 63 and 135 microM, respectively. Comparing the extent of substrate turnover (V(max)) for HfXa and RafXa, the latter was shown to cleave all three substrates at a reduced rate. Based on these observations, it can be speculated that the relative antithrombotic potency of active site directed fXa inhibitors might be different between the two species. Predicted human therapeutic doses derived from in vivo results in rabbit models should therefore take species variation into consideration.

CHARACTERIZATION OF A FULL-LENGTH cDNA FOR RABBIT FACTOR X

A 300 bp probe generated by the PCR was derived from rabbit genomic DNA using primers from a highly conserved region of the DNA for human factor X (HFX). The probe was used in northern blot analysis of liver RNA to demonstrate an mRNA species of 1.6 kb for the rabbit factor X and subsequently for isolation and characterization of the cDNA for rabbit factor X (RFX) from a lambda Zap II cDNA library generated from rabbit liver mRNA. The cDNA contains 22 bases upstream from the 5-translation initiation codon, 1470 nucleotides of open reading frame, a stop codon and a 3 poly (A) tail. The cDNA codes for a 40-residue signal/propeptide region, followed by a 447-residue mature protein. The deduced amino acid sequence shows a high degree of homology with the sequence of HFX. Inhibitory peptides derived from interactive sites of HFX for activators, cofactor and substrate exerted degrees of inhibition of RFX activation which showed a dependence on extent of homology with the corresponding regions of RFX.