Nonactin biosynthesis: unexpected patterns of label incorporation from 4,6-dioxoheptanoate show evidence of a degradation pathway for levulinate through propionate in Streptomyces griseus.

The polyketide nonactin, a polyketide possessing antitumor and antibacterial activity, is produced by an unusual biosynthesis pathway in Streptomyces griseus that uses both enantiomers of the nonactin precursor, nonactic acid. Despite many studies with labeled precursors, much of the biosynthesis pathway remains unconfirmed, particularly the identity of the last achiral intermediate in the pathway, which is believed to be 4,6-diketoheptanoyl-CoA. We set out to confirm the latter hypothesis with feeding studies employing [4,5-(13)C(2)]-, [5,6-(13)C(2)]-, and [6,7-(13)C(2)]-4,6-diketoheptanoate thioester derivatives. In each case the isotopic label was incorporated efficiently into nonactin; however, at positions inconsistent with the currently accepted biosynthesis pathway. To resolve the discrepancy, we conducted additional feeding studies with a [3,4-(13)C(2)]levulinate thioester derivative and again observed efficient label incorporation. The latter result was intriguing, as levulinate is not an obvious precursor to nonactin. Levulinate, however, is known to be efficiently degraded into propionate even though the pathway for the conversion is not known. On the basis of both our levulinate and diketoheptanoate isotope incorporation data we can now postulate a pathway from levulinate to propionate that can also account for the conversion of 4,6-diketoheptanoate into levulinate in S. griseus.

Natural product derivatives with bactericidal activity against Gram-positive pathogens including methicillin-resistant Staphylococcus aureus and vancomycin-resistant Enterococcus faecalis.

We have shown that the intentional engineering of a natural product biosynthesis pathway is a useful way to generate stereochemically complex scaffolds for use in the generation of combinatorial libraries that capture the structural features of both natural products and synthetic compounds. Analysis of a prototype library based upon nonactic acid lead to the discovery of triazole-containing nonactic acid analogs, a new structural class of antibiotic that exhibits bactericidal activity against drug resistant, Gram-positive pathogens including Staphylococcus aureus and Enterococcus faecalis.

Alternating pattern of stereochemistry in the nonactin macrocycle is required for antibacterial activity and efficient ion binding.

Nonactin is a polyketide antibiotic produced by Streptomyces griseus ETH A7796 and is an ionophore that is selective for K(+) ions. It is a cyclic tetraester generated from two monomers of (+)-nonactic acid and two of (-)-nonactic acid, arranged (+)-(-)-(+)-(-) so that nonactin has S4 symmetry and is achiral. To understand why achiral nonactin is the naturally generated diastereoisomer, we generated two alternate diastereoisomers of nonactin, one prepared solely from (+)-nonactic acid and one prepared solely from (-)-nonactic acid, referred to here as 'all-(+)-nonactin' and 'all-(-)-nonactin', respectively. Both non-natural diastereoisomers were 500-fold less active against gram positive organisms than nonactin confirming that the natural stereochemistry is necessary for biological activity. We used isothermal calorimetry to obtain the K(a), DeltaG, DeltaH, and DeltaS of formation for the K(+), Na(+), and NH(4)(+) complexes of nonactin and all-(-)-nonactin; the natural diastereoisomer bound K(+) 880-fold better than all-(-)-nonactin. A picrate partitioning assay confirmed that all-(-)-nonactin, unlike nonactin, could not partition K(+) ions into organic solvent. To complement the thermodynamic data we used a simple model system to show that K(+) transport was facilitated by nonactin but not by all-(-)-nonactin. Modeling of the K(+) complexes of nonactin and all-(-)-nonactin suggested that poor steric interactions in the latter complex precluded tight binding to K(+). Overall, the data show that both enantiomers of nonactic acid are needed for the formation of a nonactin diastereoisomer that can act as an ionophore and has antibacterial activity.

Nonactin biosynthesis: setting limits on what can be achieved with precursor-directed biosynthesis.

Nonactin, produced by Streptomyces griseus ETH A7796, is a macrotetrolide assembled from nonactic acid. It is an effective inhibitor of drug efflux in multidrug resistant erythroleukemia K562 cells at sub-toxic concentrations and has been shown to possess both antibacterial and antitumor activity. As total synthesis is impractical for the generation of nonactin analogs we have studied precursor-directed biosynthesis as an alternative as it is known that nonactic acid can serve as a nonactin precursor in vivo. To determine the scope of the approach we prepared and evaluated a furan-based nonactic acid derivative, 11. Although no new nonactin analogs were detected when 11 was administered to S. griseus fermentative cultures, a significant inhibition of nonactin biosynthesis was noted (IC(50) approximately 100 microM). Cell mass, nonactic acid production and the generation of other secondary metabolites in the culture were unaffected by 11 demonstrating that 11 selectively inhibited the assembly of nonactin from nonactic acid. While we were unable to generate new nonactin analogs we have discovered, however, a useful inhibitor that we can use to probe the mechanism of nonactin assembly with the ultimate goal of developing more successful precursor-directed biosynthesis transformations.

Natural products in parallel synthesis: triazole libraries of nonactic acid.

The synthesis of a library of nonactic acid-derived triazoloamide derivatives and their evaluation as antimicrobial agents is described.