Recombinant alpha 1-antitrypsin Pittsburgh (Met 358----Arg) is a potent inhibitor of plasma kallikrein and activated factor XII fragment.

In normal plasma, the serine protease inhibitor alpha 1-antitrypsin (alpha 1-AT) plays little or no role in the control of plasma kallikrein or activated Factor XII fragment (Factor XIIf), this function being performed by Cl-inhibitor. Recently, an alpha 1-AT variant was described with a Met----Arg mutation at the reactive center P1 residue (position 358) which altered the specificity of inhibition from the Met- or Val-specific protease neutrophil elastase to thrombin, an Arg-specific protease. We have now examined the inhibition of plasma kallikrein and Factor XIIf, both Arg-specific enzymes, with recombinant alpha 1-AT(Met358----Arg) produced by an Escherichia coli strain carrying a mutated human alpha 1-AT gene. The engineered protein was a very efficient inhibitor of both enzymes. It was more effective than Cl-inhibitor by a factor of 4.1 for kallikrein and 11.5 for Factor XIIf. These results suggest that recombinant alpha 1-AT(Met358----Arg) has therapeutic potential for disease states where activation of the plasma kinin-forming system is observed, for example in hereditary angioedema or septic shock.

Protection by recombinant alpha 1-antitrypsin Ala357 Arg358 against arterial hypotension induced by factor XII fragment.

The specificity of serpin superfamily protease inhibitors such as alpha 1-antitrypsin or C1 inhibitor is determined by the amino acid residues of the inhibitor reactive center. To obtain an inhibitor that would be specific for the plasma kallikrein-kinin system enzymes, we have constructed an antitrypsin mutant having Arg at the reactive center P1 residue (position 358) and Ala at residue P2 (position 357). These modifications were made because C1 inhibitor, the major natural inhibitor of kallikrein and Factor XIIa, contains Arg at P1 and Ala at P2. In vitro, the novel inhibitor, alpha 1-antitrypsin Ala357 Arg358, was more efficient than C1 inhibitor for inhibiting kallikrein. Furthermore, Wistar rats pretreated with alpha 1-antitrypsin Ala357 Arg358 were partially protected from the circulatory collapse caused by the administration of beta-Factor XIIa.

Oxidants spontaneously released by alveolar macrophages of cigarette smokers can inactivate the active site of alpha 1-antitrypsin, rendering it ineffective as an inhibitor of neutrophil elastase.

Current concepts relating to the pathogenesis of emphysema associated with cigarette smoking is that an imbalance exists within the lower respiratory tract between neutrophil elastase and the local anti-neutrophil elastase screen, enabling uninhibited neutrophil elastase to destroy the alveolar structures over time. The possible role of alveolar macrophages in contributing to this imbalance was investigated by evaluating the ability of cigarette smokers' alveolar macrophages to inactivate alpha 1-antitrypsin (alpha 1AT), the major anti-neutrophil elastase of the human lower respiratory tract. In vitro, alveolar macrophages of smokers spontaneously released 2.5-fold more superoxide anion and eightfold more H2O2 than macrophages of nonsmokers (P less than 0.01, both comparisons). Using a model system that reproduced the relative amounts of alveolar macrophages and alpha 1AT found in the epithelial lining fluid of the lower respiratory tract, we observed that smokers' macrophages caused a 60 +/- 5% reduction in the ability of alpha 1AT to inhibit neutrophil elastase. In marked contrast, under the same conditions, nonsmokers' macrophages had no effect upon the anti-neutrophil elastase function of alpha 1AT. Addition of superoxide dismutase, catalase, mannitol, and methionine prevented inactivation of alpha 1AT by smokers' macrophages, implying that the release of oxidants mediated the inactivation of alpha 1AT. In addition, by utilizing a recombinant DNA produced modified form of alpha 1AT containing an active site substitution (met358----val), the inactivation of alpha 1AT by smokers' alveolar macrophages was prevented, suggesting that the smokers' macrophages inactivate alpha 1AT by oxidizing the active site of the alpha 1AT molecule. These results suggest that in cigarette smokers, the alveolar macrophage can modulate the activity of alpha 1AT as an inhibitor of neutrophil elastase and thus play a role in the pathogenesis of emphysema associated with cigarette smoking.

RNA structural elements for expression in Escherichia coli. Alpha 1-antitrypsin synthesis using translation control elements based on the cII ribosome-binding site of phage lambda.

Analysis of a series of lambda cII::alpha 1-antitrypsin (alpha 1AT) gene fusions of different sizes showed that increased alpha 1AT expression correlated with the stabilisation of a particular computer-predicted RNA secondary structure. Moreover, significant synthesis of unfused alpha 1AT was achieved by reconstruction of this conformation to permit interaction between the upstream region of the ribosome-binding site and the first part of the alpha 1AT coding sequence. This high-level expression was dependent upon certain silent point mutations in the coding sequence, indicating that RNA primary and secondary structure determinants can operate in concert to dictate the efficiency of protein synthesis.

cDNA cloning and expression of a hamster alpha-thrombin receptor coupled to Ca2+ mobilization.

The serine protease alpha-thrombin (thrombin) potently stimulates G-protein-coupled signaling pathways and DNA synthesis in CCL39 hamster lung fibroblasts. To clone a thrombin receptor cDNA, selective amplification of mRNA sequences displaying homology to the transmembrane domains of G-protein-coupled receptor genes was performed by polymerase chain reaction. Using reverse transcribed poly(A)+ RNA from CCL39 cells and degenerate primers corresponding to conserved regions of several phospholipase C-coupled receptors, three novel putative receptor sequences were identified. One corresponds to an mRNA transcript of 3.4 kb in CCL39 cells and a relatively abundant cDNA. Microinjection of RNA transcribed in vitro from this cDNA in Xenopus oocytes leads to the expression of a functional thrombin receptor. The hamster thrombin receptor consists of 427 amino acid residues with 8 hydrophobic domains, including one at the extreme N-terminus that is likely to represent a signal peptide. A thrombin consensus cleavage site is present in the N-terminal extracellular region of the receptor sequence followed by a negatively charged cluster of residues present in a number of proteins that interact with the anion-binding exosite of thrombin.

Sulphation of hirudin in BHK cells.

Hirudin, a thrombin inhibitor of the leech, was expressed in BHK cells; the alpha 1-antitrypsin signal peptide was used to direct secretion into the culture medium. The recombinant hirudin so produced inhibited thrombin and was shown by labelling experiments with [35S]sulphate to have been posttranslationally modified.

Use of synthetic oligonucleotides in gene isolation and manipulation.

Great progress has occurred in the techniques of synthesis of DNA molecules of defined sequences in terms of speed, length of the obtained oligonucleotides, and automation of the processes. Corresponding progress also occurred in the ways of using synthetic DNA in molecular biology and recombinant DNA research. Screening of cloned DNA sequence banks with long, unique oligonucleotides, provided a new approach to isolate the genes for proteins which are present in very small quantity. This technique can present considerable advantages over the more classical use of mixtures of oligonucleotides, in reducing the number of potentially positive clones on a primary screen, and enabling cloning with a minimum of amino acid sequence data. Synthetic oligonucleotides also provide the basis of a set of techniques for site-directed mutagenesis of DNA sequences. This allows the possibility of engineering the structure of particular proteins, and the properties of new variants can be tested by expressing the protein in a heterologous host. An example of this approach is the production of variants of human alpha 1-antitrypsin. A variant where valine replaces the methionine at the active site is equally active as an antielastase, but no longer susceptible to oxidative inactivation. A second variant, where arginine replaces the methionine, now functions as an antithrombin, but no longer inhibits elastase. Total gene synthesis is now feasible for larger and larger genes, and some of the recent strategies of whole gene synthesis are presented.

Antiprotease targeting: altered specificity of alpha 1-antitrypsin by amino acid replacement at the reactive centre.

Alpha-1 antitrypsin (alpha 1AT) is an efficient inhibitor of the human neutrophil proteases, elastase and cathepsin G. The reactive centre P1 residue (Met358) of alpha 1AT is important in defining the specificity of inhibition; furthermore, oxidation of this residue results in a loss of inhibitor activity. There is evidence that oxidative inactivation of alpha 1AT may be involved in the pathogenesis of pulmonary emphysema associated with cigarette smoking. We have studied the effect of a series of amino acid replacements at the active centre on the inhibition properties of alpha 1AT. The mutant proteins were produced in E. coli following in vitro mutagenesis of the alpha 1AT cDNA. Alpha-1-AT (Ile358), (Ala358) and (Val358) were efficient inhibitors of both neutrophil and pancreatic elastase, but not cathepsin G. Alpha-1-AT (Ala356, Val358) and alpha 1AT (Phe358) were specific for pancreatic elastase and cathepsin G respectively. Alpha-1-AT (Leu358) inhibited both neutrophil elastase and cathepsin G. These data show that, for effective inhibition, a potential cleavage site for the protease must be displayed at the alpha 1AT active centre. In each case, replacement of Met358 led to resistance to oxidative inactivation. Since alpha 1AT (Leu358) inhibits both neutrophil proteases and is resistant to oxidation, this variant may be of increased potential for the therapy of destructive lung disorders.

Characterization of recombinant human factor IX expressed in transgenic mice and in derived trans-immortalized hepatic cell lines.

Transgenic mice were generated in which 5 kb of the 5' flanking promoter region of the human Factor IX (FIX) gene fused to various FIX constructs (gene, minigene and cDNA) were stably integrated in the germ line. Several transgenic mouse lines expressed high circulating levels of active and correctly processed recombinant human FIX. The presence of at least one FIX intron had a positive effect on the expression. The FIX transgenes were expressed in a tissue-specific manner in the liver of transgenic mice. By crossing transgenic mice synthesizing FIX with others prone to develop hepatoma, progeny which co-express the transgenes in hepatocytes were obtained. Hepatoma-derived cell lines were shown to have a differentiated phenotype and secrete active human FIX for many generations.

Synthesis in E. coli of alpha 1-antitrypsin variants of therapeutic potential for emphysema and thrombosis.

The primary function of alpha 1-antitrypsin (alpha 1-AT), an antiprotease produced by the liver, is the inhibition of neutrophil elastase, a protease capable of hydrolysing most connective tissue components. The importance of alpha 1-AT is demonstrated by the high incidence of early-onset emphysema in individuals with hereditary alpha 1-AT deficiency (Type PiZZ), in whom serum levels of alpha 1-AT are 10-20% of normal. Oxidants in tobacco smoke can inactivate alpha 1-AT in vitro, and studies have shown that alpha 1-AT from the lungs of individuals who smoke cigarettes may also be partially inactivated, perhaps explaining the high incidence of emphysema associated with cigarette smoking. Oxidative inactivation is probably due to modification of the Met residue (Met358) at the P1 subsite position of the elastase binding site of the protein. To study the possibility of modulating the biological properties of alpha 1-AT, we have introduced selected sequence modifications at the reactive site by in vitro mutation of a cloned alpha 1-AT complementary DNA. We describe here the characterization of two alpha 1-AT analogues produced in Escherichia coli. The first, alpha 1-AT(Met385----Val), is not only fully active as an elastase inhibitor but is also resistant to oxidative inactivation. The other, alpha 1-AT(Met358----Arg), no longer inhibits elastase but is an efficient thrombin inhibitor. The active site of the latter is identical to that of the alpha 1-AT (Pittsburgh) variant, which was associated with a fatal bleeding disorder.

Altered specificities of genetically engineered alpha 1 antitrypsin variants.

Seven active site variants of human alpha 1-antitrypsin (alpha 1AT) were produced in Escherichia coli following site-specific mutagenesis of the alpha 1AT complementary DNA. alpha 1AT (Ala358), alpha 1AT (Ile358) and alpha 1AT (Val358) were efficient inhibitors of both neutrophil and pancreatic elastases, but not of cathepsin G. alpha 1AT (Ala356, Val358) and alpha 1AT (Phe358) specifically inhibited pancreatic elastase and cathepsin G respectively. The most potent inhibitor of neutrophil elastase was alpha 1AT (Leu358), which also proved to be effective against cathepsin G. The alpha 1AT (Arg358) variant inactivated thrombin with kinetics similar to antithrombin III in the presence of heparin. Electrophoretic analysis showed that SDS-stable high mol. wt complexes were formed between the mutant inhibitors and the cognate proteases in each case. These data indicate that effective inhibition occurs when the alpha 1AT P1 residue (position 358) corresponds to the primary specificity of the target protease. Moreover, alteration of the P3 residue (position 356) can further modify the reactivity of the inhibitor. Two of the variants have therapeutic potential: alpha 1AT (Leu358) may be more useful than plasma alpha 1AT in the treatment of destructive lung disorders and alpha 1AT (Arg358) could be effective in the control of thrombosis.

Altered chloride ion channel kinetics associated with the delta F508 cystic fibrosis mutation.

Cystic fibrosis is associated with a defect in epithelial chloride ion transport which is caused by mutations in a membrane protein called CFTR (cystic fibrosis transmembrane conductance regulator). Heterologous expression of CFTR produces cyclicAMP-sensitive Cl(-)-channel activity. Deletion of phenylalanine at amino-acid position 508 in CFTR (delta F508 CFTR) is the most common mutation in cystic fibrosis. It has been proposed that this mutation prevents glycoprotein maturation and its transport to its normal cellular location. We have expressed both CFTR and delta F508 CFTR in Vero cells using recombinant vaccinia virus. Although far less delta F508 CFTR reached the plasma membrane than normal CFTR, sufficient delta F508 CFTR was expressed at the plasma membrane to permit functional analysis. delta F508 CFTR expression induced a reduced activity of the cAMP-activated Cl- channel, with conductance, anion selectivity and open-time kinetics similar to those of CFTR, but with much greater closed times, resulting in a large decrease of open probability. The delta F508 mutation thus seems to have two major consequences, an abnormal translocation of the CFTR protein which limits membrane insertion, and an abnormal function in mediating Cl- transport.

Variable deletion of exon 9 coding sequences in cystic fibrosis transmembrane conductance regulator gene mRNA transcripts in normal bronchial epithelium.

The predicted protein domains coded by exons 9-12 and 19-23 of the 27 exon cystic fibrosis transmembrane conductance regulator (CFTR) gene contain two putative nucleotide-binding fold regions. Analysis of CFTR mRNA transcripts in freshly isolated bronchial epithelium from 12 normal adult individuals demonstrated that all had some CFTR mRNA transcripts with exon 9 completely deleted (exon 9- mRNA transcripts). In most (9 of 12), the exon 9- transcripts represented less than or equal to 25% of the total CFTR transcripts. However, in three individuals, the exon 9- transcripts were more abundant, comprising 39, 62 and 66% of all CFTR transcripts. Re-evaluation of the same individuals 2-4 months later showed the same proportions of exon 9- transcripts. Of the 24 CFTR alleles in the 12 individuals, the sequences of the exon-intron junctions relevant to exon 9 deletion (exon 8-intron 8, intron 8-exon 9, exon 9-intron 9, and intron 9-exon 10) were identical except for the intron 8-exon 9 region sequences. Several individuals had varying lengths of a TG repeat in the region between splice branch and splice acceptor consensus sites. Interestingly, one allele in each of the two individuals with 62 and 66% exon 9- transcripts had a TT deletion in the splice acceptor site for exon 9. These observations suggest either the unlikely possibility that sequences in exon 9 are not critical for the functioning of the CFTR or that only a minority of the CFTR mRNA transcripts need to contain exon 9 sequences to produce sufficient amounts of a normal CFTR to maintain a normal clinical phenotype.