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The structure of a tetragonal crystal form of thiostrepton has been solved using the anomalous dispersive effects of five S atoms from high-redundancy data collected to 1.33 A resolution at the Cu Kalpha wavelength. Data measured to 1.02 A resolution with a synchrotron source were used for refinement. Details of the molecular structure, intramolecular and intermolecular interactions are given.

The first phase of the total synthesis of thiostrepton (1), a highly complex thiopeptide antibiotic, is described. After a brief introduction to the target molecule and its structural motifs, it is shown that retrosynthetic analysis of thiostrepton reveals compounds 23, 24, 26, 28, and 29 as potential key building blocks for the projected total synthesis. Concise and stereoselective constructions of all these intermediates are then described. The synthesis of the dehydropiperidine core 28 was based on a biosynthetically inspired aza-Diels-Alder dimerization of an appropriate azadiene system, an approach that was initially plagued with several problems which were, however, resolved satisfactorily by systematic investigations. The quinaldic acid fragment 24 and the thiazoline-thiazole segment 26 were synthesized by a series of reactions that included asymmetric and other stereoselective processes. The dehydroalanine tail precursor 23 and the alanine equivalent 29 were also prepared from the appropriate amino acids. Finally, a method was developed for the direct coupling of the labile dehydropiperidine key building block 28 to the more advanced and stable peptide intermediate 27 through capture with the highly reactive alanine equivalent 67 under conditions that avoided the initially encountered destructive ring contraction process.

The completion of the total synthesis of thiostrepton (1) is described. The synthesis proceeded from key building blocks 2-5, which were assembled into a growing substrate that finally led to the target molecule. Thus, the dehydropiperidine peptide core 2 was, after appropriate manipulation, coupled to the thiazoline-thiazole fragment 3, and the resulting product was advanced to intermediate 11 possessing the thiazoline-thiazole macrocycle. The bis-dehydroalanine tail equivalent 4 and the quinaldic acid fragment 5 were then sequentially incorporated, and the products so obtained were further elaborated to forge the second macrocycle of the molecule. Several roadblocks encountered along the way were systematically investigated and overcome, finally opening the way, through intermediates 20, 32, 44, 45, and 46, to the targeted natural product, 1.

The x-ray crystal structure of the thiostrepton resistance RNA methyltransferase (Tsr).S-adenosyl-L-methionine (AdoMet) complex was determined at 2.45-A resolution. Tsr is definitively confirmed as a Class IV methyltransferase of the SpoU family with an N-terminal "L30-like" putative target recognition domain. The structure and our in vitro analysis of the interaction of Tsr with its target domain from 23 S ribosomal RNA (rRNA) demonstrate that the active biological unit is a Tsr homodimer. In vitro methylation assays show that Tsr activity is optimal against a 29-nucleotide hairpin rRNA though the full 58-nucleotide L11-binding domain and intact 23 S rRNA are also effective substrates. Molecular docking experiments predict that Tsr.rRNA binding is dictated entirely by the sequence and structure of the rRNA hairpin containing the A1067 target nucleotide and is most likely driven primarily by large complementary electrostatic surfaces. One L30-like domain is predicted to bind the target loop and the other is near an internal loop more distant from the target site where a nucleotide change (U1061 to A) also decreases methylation by Tsr. Furthermore, a predicted interaction with this internal loop by Tsr amino acid Phe-88 was confirmed by mutagenesis and RNA binding experiments. We therefore propose that Tsr achieves its absolute target specificity using the N-terminal domains of each monomer in combination to recognize the two distinct structural elements of the target rRNA hairpin such that both Tsr subunits contribute directly to the positioning of the target nucleotide on the enzyme.

We identified the thiomuracins, a novel family of thiopeptides produced by a rare-actinomycete bacterium typed as a Nonomuraea species, via a screen for inhibition of growth of the bacterial pathogen Staphylococcus aureus. Thiopeptides are a class of macrocyclic, highly modified peptides that are decorated by thiazoles and defined by a central six-membered heterocyclic ring system. Mining the genomes of thiopeptide-producing strains revealed the elusive biosynthetic route for this class of antibiotics. The thiopeptides are chromosomally encoded, ribosomally synthesized proteins, and isolation of gene clusters for production of thiomuracin and the related thiopeptide GE2270A revealed the post-translational machinery required for maturation. The target of the thiomuracins was identified as bacterial Elongation Factor Tu (EF-Tu). In addition to potently inhibiting a target that is unexploited by marketed human therapeutics, the thiomuracins have a low propensity for selecting for antibiotic resistance and confer no measurable cross-resistance to antibiotics in clinical use.

Nuclease S1 protection experiments indicated that the thiostrepton resistance gene (tsr) of Streptomyces azureus is transcribed from tandem promoters, tsrp1 and tsrp2, that initiate transcription 45 and 173 nucleotides, respectively, upstream of the presumptive translational start codon. The -10 regions of both promoters show similarity to the consensus sequence for the major class of prokaryotic promoters, but the -35 regions do not, although they show some similarity to each other. Replacement of sequences upstream of position -22 relative to the tsrp2 start site with two different DNA segments affected the levels of the tsrp2 transcript but did not alter the tsrp2 initiation site. In vitro transcription assays using RNA polymerase from Streptomyces coelicolor A3(2) also confirmed the location of tsrp2 and identified additional start sites near tsrp2 that were barely detectable with in vivo synthesised RNA. Transcripts corresponding to initiation in vitro at trsp1 could not be detected, suggesting that additional factors are required for utilisation of this promoter.

Specifically 13C-labeled quinoline-2-carboxylate derivatives were synthesized from quinoline and used to study the biosynthesis of thiostrepton in a strain of Streptomyces laurentii. 13C NMR analysis of thiostrepton recovered after feeding methyl (RS)-[11-13C]-4-(1-hydroxyethyl)quinoline-2-carboxylate or methyl [11-13C]-4-acetylquinoline-2-carboxylate showed conclusively that these compounds are specifically and efficiently incorporated into thiostrepton. Both compounds were also detected in cultures of the producing organism by isotope dilution analysis. The significance of the relative endogenous concentrations of the two compounds and of the relative extent of the incorporation of exogenously added labeled material into thiostrepton are discussed in terms of the biosynthetic pathway linking tryptophan and 4-(1-hydroxyethyl)quinoline-2-carboxylate in S. laurentii. A highly specific enzyme activity was detected in cell-free extracts of S. laurentii that was capable of adenylating (12S)-4-(1-hydroxyethyl)quinoline-2-carboxylic acid. Partial purification of the enzyme was achieved. The enzyme was found to be specific for the enantiomer of the substrate which has the same absolute configuration as found in the natural antibiotic structure. The presence of one specific enzyme catalysing the adenylation process in S. laurentii was shown by photoaffinity labeling with [alpha-32P]-8-azido-ATP and subsequent SDS PAGE analysis of the labeled products. The native molecular weight of the active enzyme, determined by gel permeation chromatography, was found to be approximately 47 kDa, compared with a denatured weight of 50 kDa estimated for the photoaffinity-labeled protein. The enzyme is thus probably monomeric.

A plasmid, pSA1.1, of Streptomyces azureus elicited conjugative pocks and inhibited the sporulation of its host mycelia. pSA1.1 was studied with a kanamycin resistance gene derived from S. kanamyceticus as a selective marker. The deletion analysis and sequencing of the derivative plasmid found an open reading frame (ORF909b) that was involved in the sporulation-inhibitory function of pSA1.1 and in pock formation. The nucleotide sequences of ORF909b were compared with those of the genes registered in GenBank, but no similarity was found. However, the predicted amino acid sequence of ORF909b showed a significantly high similarity with that of the spoIIIE gene of Bacillus subtilis. This detected gene might be a new sporulation-regulatory gene in streptomycetes.

A detailed 13C NMR study of thiostrepton and two series of thiopeptin components is consistent with their proposed structures and allows many unequivocal assignments to be made.

The majority of the 84 protons in the 1H NMR spectrum of thiostrepton at 300 MHz were unambiguously assigned on the basis of double resonance experiments under different conditions of solvent, temperature and 2H-exchange by comparison with the known crystal structure determined by Anderson et al.1) Evidence is presented to suggest that the side chain, the nature of which remained undefined on X-ray analysis, is comprised of two dehydroalanine residues which supports the conclusions reached by Tori et al.2) on the basis of 13C NMR spectroscopy. These two residues are missing in thiostrepton A2, a minor artifact. All available 1H NMR evidence suggests thiostrepton to have a similar conformation in deuterochloroform solution to that found in the crystal form.

A methylase enzyme, responsible for autoimmunity in the thiostrepton producer Streptomyces azureus, renders ribosomes completely resistant to thiostrepton. This RNA-pentose methylase modifies adenosine-1067 of Escherichia coli 23 S rRNA.

Promoter-probe plasmid vectors were used to isolate putative promoter-containing DNA fragments of three Streptomyces antibiotic resistance genes, the rRNA methylase (tsr) gene of S. azureus, the aminoglycoside phosphotransferase (aph) gene of S. fradiae, and the viomycin phosphotransferase (vph) gene of S. vinaceus. DNA sequence analysis was carried out for all three of the fragments and for the protein-coding regions of the tsr and vph genes. No sequences resembling typical E. coli promoters or Bacillus vegetatively-expressed promoters were identified. Furthermore, none of the three DNA fragments found to be transcriptionally active in Streptomyces could initiate transcription when introduced into E. coli. An extremely biased codon usage pattern that reflects the high G + C composition of Streptomyces DNA was observed for the protein-coding regions of the tsr and vph genes, and of the previously sequenced aph gene. This pattern enabled delineation of the protein-coding region and identification of the coding strand of the genes.