Biosynthetic Gene Cluster for the Cladoniamides, Bis-Indoles with a Rearranged Scaffold

The cladoniamides are bis-indole alkaloids isolated from Streptomyces uncialis, a lichen-associated actinomycete strain. The cladoniamides have an unusual, indenotryptoline structure rarely observed among bis-indole alkaloids. I report here the isolation, sequencing, and annotation of the cladoniamide biosynthetic gene cluster and compare it to the recently published gene cluster for BE-54017, a closely related indenotryptoline natural product. The cladoniamide gene cluster differs from the BE-54017 gene cluster in gene organization and in the absence of one N-methyltransferase gene but otherwise contains close homologs to all genes in the BE-54017 cluster. Both gene clusters encode enzymes needed for the construction of an indolocarbazole core, as well as flavin-dependent enzymes putatively involved in generating the indenotryptoline scaffold from an indolocarbazole. These two bis-indolic gene clusters exemplify the diversity of biosynthetic routes that begin from the oxidative dimerization of two molecules of l-tryptophan, highlight enzymes for further study, and provide new opportunities for combinatorial engineering

Identification and Utility of FdmR1 as a Streptomyces Antibiotic Regulatory Protein Activator for Fredericamycin Production in Streptomyces griseus ATCC 49344 and Heterologous Hosts▿ †

The fredericamycin (FDM) A biosynthetic gene cluster, cloned previously from Streptomyces griseus ATCC 49344, contains three putative regulatory genes, fdmR, fdmR1, and fdmR2. Their deduced gene products show high similarity to members of the Streptomyces antibiotic regulatory protein (SARP) family (FdmR1) or to MarR-like regulators (FdmR and FdmR2). Here we provide experimental data supporting FdmR1 as a SARP-type activator. Inactivation of fdmR1 abolished FDM biosynthesis, and FDM production could be restored to the fdmR1::aac(3)IV mutant by expressing fdmR1 in trans. Reverse transcription-PCR transcriptional analyses revealed that up to 26 of the 28 genes within the fdm gene cluster, with the exception of fdmR and fdmT2, were under the positive control of FdmR1, directly or indirectly. Overexpression of fdmR1 in S. griseus improved the FDM titer 5.6-fold (to about 1.36 g/liter) relative to that of wild-type S. griseus. Cloning of the complete fdm cluster into an integrative plasmid and subsequent expression in heterologous hosts revealed that considerable amounts of FDMs could be produced in Streptomyces albus but not in Streptomyces lividans. However, the S. lividans host could be engineered to produce FDMs via constitutive expression of fdmR1; FDM production in S. lividans could be enhanced further by overexpressing fdmC, encoding a putative ketoreductase, concomitantly with fdmR1. Taken together, these studies demonstrate the viability of engineering FDM biosynthesis and improving FDM titers in both the native producer S. griseus and heterologous hosts, such as S. albus and S. lividans. The approach taken capitalizes on FdmR1, a key activator of the FDM biosynthetic machinery

Nucleotide sequence of the tcmII-tcmIV region of the tetracenomycin C biosynthetic gene cluster of Streptomyces glaucescens and evidence that the tcmN gene encodes a multifunctional cyclase-dehydratase-O-methyl transferase.

Mutations in the tcmII-tcmIV region of the Streptomyces glaucescens chromosome block the C-3 and C-8 O-methylations of the polyketide antibiotic tetracenomycin C (Tcm C). The nucleotide sequence of this region reveals the presence of two genes, tcmN and tcmO, whose deduced protein products display similarity to the hydroxyindole O-methyl transferase of the bovine pineal gland, an enzyme that catalyzes a phenolic O-methylation analogous to those required for the biosynthesis of Tcm C. The deduced product of the tcmN gene also has an N-terminal domain that shows similarity to the putative ActVII and WhiE ORFVI proteins of Streptomyces coelicolor. The tcmN N-terminal domain can be separated from the remainder of the tcmN gene product, and when coupled on a plasmid with the Tcm C polyketide synthase genes (tcmKLM), this domain enables high-level production of an early, partially cyclized intermediate of Tcm C in a Tcm C- null mutant or in a heterologous host (Streptomyces lividans). By analogy to fatty acid biosynthesis, the tcmKLM polyketide synthase gene products are probably sufficient to produce the linear decaketide precursor of Tcm C; thus, the tcmN N-terminal domain is most likely responsible for one or more of the early cyclizations and, perhaps, the attendant dehydrations that lead to the partially cyclized intermediate. The tcmN gene therefore appears to encode a multifunctional cyclase-dehydratase-3-O-methyl transferase. The tcmO gene encodes the 8-O-methyl transferase