Novel hirudin variants from the leech Hirudinaria manillensis. Amino acid sequence, cDNA cloning and genomic organization.

Novel hirudin variants isolated from the leech Hirudinaria manillensis, a leech more specialized for mammalian parasitism, are described. Isolation of antithrombin polypeptides was performed by ion-exchange chromatographies followed by an affinity chromatography step on immobilized thrombin. The major active component, antithrombin polypeptide peak 2 (HM2) and a second polypeptide, named HM1, were purified to homogeneity and their complete amino acid sequences were determined. The protein structure of the two hirudin variants include 64 amino acids with 6 cysteine residues at highly conserved positions. Comparison of the amino acid sequences of HM1 and HM2 with other known hirudins shows differences mainly in the central part and in the C-terminal region of the polypeptides. Particularly significant is the lack of a sulfated tyrosine residue in the C-terminal portion of the molecule which is replaced by aspartic acid. Polymerase chain reaction cloning techniques were used to isolate and characterize the cDNAs and determine the genomic structures of these hirudin-like polypeptides. The cDNA clones coding for the two variants indicate the expression of pre-hirudins of 84 amino acids where the first 20 residues constitute the signal peptide required for extracellular secretion. The leader sequence appears to be highly conserved for both isoforms and shares a complete similarity with the partial hirudin variant 2 (HV2) signal peptide sequence previously reported. The HM1 and HM2 gene fragments show the presence of four exons: the first one corresponding to a 20-amino-acid signal peptide while the other three exons share the full primary structure of the antithrombin polypeptides. HM2 was also efficiently produced in recombinant Escherichia coli by expressing a periplasmic construction containing the synthetic gene.

Secretion of biologically active leech hirudin from baculovirus-infected insect cells.

The thrombin inhibitor, hirudin, from the leech Hirudo Medicinalis, is the most powerful natural anticoagulant known. It has been characterized as a polypeptide of 65 amino acids which exhibits its anticoagulant properties by binding tightly and specifically to alpha-thrombin. The potency and specificity of hirudin have generated interest on its possible use in the treatment or prophylaxis of various thrombotic diseases. We have used the baculovirus expression system to efficiently produce active hirudins in insect cells. The Autographa californica nuclear polyhedrosis virus has proved useful as a helper-independent viral expression vector for high-level production of recombinant proteins in cultured insect cells. Hirudin variants (HV1 and HV2) were produced in infected insect cells as secreted proteins by joining their coding sequences to the leader peptide sequence of the vescicular stomatitis virus G protein. The recombinant products were biologically active and, interestingly, N-terminal sequencing of HV1 revealed that the heterologous leader peptide is correctly removed.

Production of the HV1 variant of hirudin by recombinant DNA methodology.

Recombinant DNA technologies now allow the preparation of virtually any polypeptide sequence. Very efficient expression systems for prokaryotic and eukaryotic cells have been developed which may yield large quantities of the desired protein. Bacterial systems are still the most widely used while alternative organisms are often considered when post-translational modifications could influence the biological behaviour of the product. For hirudin or its analogues, two important molecular characteristics should be taken into account. First, it is necessary that no extra amino acid residue, such as the initial methionine, is present on the NH2 end of the recombinant polypeptide. It is known that a free N-terminal sequence is crucial for the thrombin inhibitory activity. Second, a sulphate group on tyrosine at position 63 is found in natural hirudin extracted from leeches. Such post-translational modification has never been observed for all the recombinant hirudin preparations reported to date even though the importance of the sulphate group on the in vitro and in vivo activity of hirudin has not yet been clarified. Finally, the recombinant DNA methodology of choice for the commercial development of hirudin must also take into consideration yield and cost factors which ultimately will affect the widespread use of this product particularly if it has to compete with heparin. We will review our work on the preparation of recombinant hirudin describing bacterial and insect cell expression systems and addressing some of the questions mentioned above.

Genetic mapping of the Saccharomyces cerevisiae DNA polymerase I gene and characterization of a pol1 temperature-sensitive mutant altered in DNA primase-polymerase complex stability.

The cloned DNA polymerase I gene has been used to map the POL1 locus on the left arm of chromosome XIV, between MET4 and TOP2. Temperature-sensitive mutants in POL1 have been obtained by in vitro mutagenesis of the cloned gene and in vivo replacement of the wild-type allele with the mutated copy. Physiological and biochemical characterization of one temperature-sensitive mutant (pol1-1) shows that cells shifted to the non-permissive temperature can complete one round of cell division and DNA replication before they arrest. Analysis of DNA polymerase I in crude extracts and in partially purified preparations indicates that the pol1-1 mutation results in a conformational change and affects the stability of the DNA primase-polymerase complex.