Structural and initial biological analysis of synthetic arylomycin A(2)

The growing threat of untreatable bacterial infections has refocused efforts to identify new antibiotics, especially those acting by novel mechanisms. While the inhibition of pathogen proteases has proven to be a successful strategy for drug development, such inhibitors are often limited by toxicity...

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Bibliographic Details
Published inJournal of the American Chemical Society Vol. 129; no. 51; pp. 15830 - 15838
Main Authors Roberts, Tucker C., Smith, Peter A., Cirz, Ryan T., Romesberg, Floyd E.
Format Journal Article
LanguageEnglish
Published WASHINGTON Amer Chemical Soc 26.12.2007
Subjects
Chemistry
Chemistry, Multidisciplinary
Physical Sciences
Science & Technology
BACTERIAL SIGNAL PEPTIDASE
STREPTOMYCES SP TU-6075
AMINO-ACID
VANCOMYCIN AGLYCON
ESCHERICHIA-COLI
LEADER PEPTIDASE
CATALYTIC MECHANISM
PROTEASOME INHIBITORS
TEICHOMYCETICUS-NOV-SP
BIPHENOMYCIN-B
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Summary:The growing threat of untreatable bacterial infections has refocused efforts to identify new antibiotics, especially those acting by novel mechanisms. While the inhibition of pathogen proteases has proven to be a successful strategy for drug development, such inhibitors are often limited by toxicity due to their promiscuous inhibition of homologous and mechanistically related human enzymes. Unlike many protease inhibitors, inhibitors of the essential type I bacterial signal peptidase (SPase) may be more specific and thus less toxic due to the enzyme's unique structure and catalytic mechanism. Recently, the arylomycins and related lipoglycopeptide natural products were isolated and shown to inhibit SPase. The core structure of the arylomycins and lipoglycopeptides consists of a biaryl-linked, N-methylated peptide macrocycle attached to a lipopeptide tail, and in the case of the lipoglycopeptides, a deoxymannose moiety. Herein, we report the first total synthesis of a member of this group of antibiotics, arylomycin A(2). The synthesis relies on Suzuki-Miyaura-mediated biaryl coupling, which model studies suggested would be more efficient than a lactamization-based route. Biological studies demonstrate that these compounds are promising antibiotics, especially against Gram-positive pathogens, with activity against S. epidermidis that equals that of the, currently prescribed antibiotics. Structural and biological studies suggest that both N-methylation and lipidation may contribute to antibiotic activity, whereas glycosylation appears to be generally less critical. Thus, these studies help identify the determinants of the biological activity of arylomycin A(2) and should aid in the design of analogs to further explore and develop this novel class of antibiotic.
ISSN:0002-7863
1520-5126
DOI:10.1021/ja073340u