Mogens Trier Hansen scite author profile

Animals and higher plants express endogenous peptide antibiotics called defensins. These small cysteine-rich peptides are active against bacteria, fungi and viruses. Here we describe plectasin-the first defensin to be isolated from a fungus, the saprophytic ascomycete Pseudoplectania nigrella. Plectasin has primary, secondary and tertiary structures that closely resemble those of defensins found in spiders, scorpions, dragonflies and mussels. Recombinant plectasin was produced at a very high, and commercially viable, yield and purity. In vitro, the recombinant peptide was especially active against Streptococcus pneumoniae, including strains resistant to conventional antibiotics. Plectasin showed extremely low toxicity in mice, and cured them of experimental peritonitis and pneumonia caused by S. pneumoniae as efficaciously as vancomycin and penicillin. These findings identify fungi as a novel source of antimicrobial defensins, and show the therapeutic potential of plectasin. They also suggest that the defensins of insects, molluscs and fungi arose from a common ancestral gene.

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Monomeric insulins obtained by protein engineering and their medical implications

Brange

Ribel

Hansen

et al. 1988

Nature

486

323

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The use of insulin as an injected therapeutic agent for the treatment of diabetes has been one of the outstanding successes of modern medicine. The therapy has, however, had its associated problems, not least because injection of insulin does not lead to normal diurnal concentrations of insulin in the blood. This is especially true at meal times when absorption from subcutaneous tissue is too slow to mimic the normal rapid increments of insulin in the blood. In the neutral solutions used for therapy, insulin is mostly assembled as zinc-containing hexamers and this self-association, which under normal physiological circumstances functions to facilitate proinsulin transport, conversion and intracellular storage, may limit the rate of absorption. We now report that it is possible, by single amino-acid substitutions, to make insulins which are essentially monomeric at pharmaceutical concentrations (0.6 mM) and which have largely preserved their biological activity. These monomeric insulins are absorbed two to three times faster after subcutaneous injection than the present rapid-acting insulins. They are therefore capable of giving diabetic patients a more physiological plasma insulin profile at the time of meal consumption.

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High Level Expression of Recombinant Genes in Aspergillus Oryzae

et al. 1988

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A novel aspartyl protease allowing KEX2‐independent MFα propheromone processing in yeast

Egel-Mitani

Flygenring

Hansen

1990

Yeast

136

116

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Mutants of Saccharomyces cerevisiae which lack the KEX2-encoded endopeptidase are unable to process proteolytically the mating factor alpha (MF alpha) propheromone produced from the chromosomal MF alpha 1 and MF alpha 2 genes (Julius et al., 1983). Overproduction of pheromone precursor from multiple, plasmid-borne MF alpha genes did, however, lead to the production of active MF alpha peptides in the absence of the KEX2 gene product. S. cerevisiae therefore must possess an alternative processing enzyme. The cleavage site of this enzyme appeared identical to that of the KEX2-encoded endopeptidase. To identify the gene responsible for the alternative processing, we have isolated clones which allowed production of mature MF alpha in a kex2-disrupted strain even from the chromosomal MF alpha genes. The gene isolated in this way was shown also to be essential for the KEX2-independent processing of propheromone overproduced from plasmid-borne MF alpha 1. The amino acid sequence deduced from the gene shows extensive homology to a number of aspartyl proteases including the PEP4 and BAR1 gene products from S. cerevisiae. In contrast to the BAR1 gene product, the novel aspartyl protease (YAP3 for Yeast Aspartyl Protease 3) contains a C-terminal serine/threonine-rich sequence and potential transmembrane domain similar to those found in the KEX2 gene product. The corresponding gene YAP3 was located to chromosome XII. The normal physiological role of the YAP3 gene product is not known. Strains disrupted in YAP3 are both viable and able to process the mating factor a precursor.

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