Pneumocandins from Zalerion arboricola. II. Modification of product spectrum by mutation and medium manipulation.

@article{Masurekar1992PneumocandinsFZ,
  title={Pneumocandins from Zalerion arboricola. II. Modification of product spectrum by mutation and medium manipulation.},
  author={Prakash S. Masurekar and Jimmy M Fountoulakis and Thomas C. Hallada and Margaret S Sosa and Louis. Kaplan},
  journal={The Journal of antibiotics},
  year={1992},
  volume={45 12},
  pages={
          1867-74
        }
}
Zalerion arboricola ATCC 20868 produces pneumocandin A0 (L-671,329), a cyclic hexapeptide with a dimethylmyristic acid side chain. This compound has anti-candida and anti-pneumocystis activities. We were interested in looking for other related compounds produced by this organism. To facilitate this search, a simple medium (S2) composed of D-mannitol, peptonized milk, lactic acid, glycine, KH2PO4 and trace elements, which supported the production of a number of such compounds, was designed. For… 
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Reclassification of a pneumocandin-producing anamorph, Glarea lozoyensis gen. et sp. nov., previously identified as Zalerion arboricola

The genus Zalerion is artificial; its species bear no phylogenetic relation among themselves, and a new anamorph genus and species is proposed, Glarea lozoyensis, to accommodate ATCC 20868.

Engineering of Glarea lozoyensis for Exclusive Production of the Pneumocandin B0 Precursor of the Antifungal Drug Caspofungin Acetate

Retrospective analysis of the GLOXY4 gene in a previously isolated pneumocandin B0-exclusive mutant indicated that chemical mutagenesis disrupted theGLO XY4 gene function by introducing two amino acid mutations in GLOxy4, suggesting this one-step genetic manipulation can rationally engineer a high-yield production strain.

Improvement in the titer of echinocandin-type antibiotics: A magnesium-limited medium supporting the biphasic production of pneumocandins A0 and B0

A liquid fermentation medium for the submerged culture of the fungus, Zalerion arboricola, which supports the rapid production of an echinocandin-type antibiotic, pneumocand in A0 (formerly L-671, 329), in yields increased at least 4-fold over those reported previously.

Pneumocandins from Zalerion arboricola. I. Discovery and isolation.

HPLC bioautography of the directed biosynthesis of Zalerion arboricola led to the discovery of pneumocandin B0 (L-688,786), a new antifungal and anti-Pneumocystis carinii lipopeptide. Isolation

Acrophiarin (antibiotic S31794/F-1) from Penicillium arenicola shares biosynthetic features with both Aspergillus- and Leotiomycete-type echinocandins.

Inclusion of the acrophiarin gene cluster into a comprehenisve phylogenetic analysis of echinocandin gene clusters indicates the divergent evolutionary lineages of e chinocand in gene clusters are descendents from a common ancestral progenitor.

Genomics-driven discovery of the pneumocandin biosynthetic gene cluster in the fungus Glarea lozoyensis

Characterization of the gene cluster provides a blueprint for engineering new pneumocandin derivatives with improved pharmacological properties and provides yet another example of the huge potential for drug discovery from natural products from the fungal kingdom.

FROMZalerion arboricola V. GLUTAMIC ACID- AND LEUCINE- DERIVED AMINO ACIDS IN PNEUMOCANDIN Ao (L-671,329) AND DISTINCT ORIGINS OF THE SUBSTITUTED PROLINE RESIDUES IN PNEUMOCANDINS Ao AND Bo

A family of pneumocandins produced by the helicosporous fungus, Zalerion arboricola, are described, which are acylated cyclic hexapeptides belonging to the echinocandin group of antifungal antibiotics.

Genetic Manipulation of the Pneumocandin Biosynthetic Pathway for Generation of Analogues and Evaluation of Their Antifungal Activity.

13 new pneumocandin analogues are generated that lack one, two, three, or four hydroxyl groups on 4R,5R-dihydroxy-ornithine and 3S,4S-dHYDroxy-homotyrosine of the parent hexapeptide, and all of these cyclic lipopeptides showed potent antifungal activities.

Pneumocandin D0, a new antifungal agent and potent inhibitor of Pneumocystis carinii.

Pneumocandin D0 (9), a new member of the echinocandin class of antifungal agents, has been isolated as a minor constituent from fermentation broths of the filamentous fungi Zalerion arboricola (ATCC

Reanalysis of the mitochondrial genome of the pneumocandin-producing fungus Glarea lozoyensis

The authentic mitogenome sequence of G. lozoyensis was reported and frequent gene transfer between mitochondrial and nuclear genomes in the fungus was found and it was verified that there existed erroneous sequences in the publishedMitogenome of ATCC 74030.
...

12 References

Pneumocandins from Zalerion arboricola. I. Discovery and isolation.

HPLC bioautography of the directed biosynthesis of Zalerion arboricola led to the discovery of pneumocandin B0 (L-688,786), a new antifungal and anti-Pneumocystis carinii lipopeptide. Isolation

Biosynthesis of L-671,329, an Echinocandin-Type Antibiotic Produced by Zalerion arboricola: Origins of Some of the Unusual Amino Acids and the Dimethylmyristic Acid Side Chain.

The biosynthesis of L-671,329, an antibiotic of the echinocandin class, was studied in Zalerion arboricola by stable isotope tracer techniques and high-field NMR spectroscopy. The organism

Genetics of Industrial Microorganisms

Mutation and the production of secondary metabolites.

  • A. Demain
  • Biology
    Advances in applied microbiology
  • 1973

The effect of inorganic phosphate on the production of avermectin in Streptomyces avermitilis

From the results, it follows that the biosynthesis of avermectin tolerates high concentrations of phosphate in the medium and the production of secondary metabolite is unaffected.

L-671,329, a new antifungal agent. I. Fermentation and isolation.

A new lipopeptide antifungal agent, similar to echinocandin B, has been isolated from Zalerion arboricola and studies indicate that L-671,329 is produced under both solid and liquid fermentation conditions.

Control by phosphate of candicidin production.

ATP and adenylate energy charge during phosphate-mediated control of antibiotic synthesis.

Control of antibiotic synthesis by phosphate

Inhibition by phosphate of the activity of candicidin synthases