As a route to accessing the potential chemical diversity of uncultivable microbes from the soil, combinatorial biosynthetic libraries were constructed by cloning large fragments of DNA isolated from soil into a Streptomyces lividans host. Four novel compounds, terragines A (1), B (2), C (3), and D (4), were isolated from recombinant 436-s4-5b1, and another novel compound, terragine E (5), was isolated from 446-s3-102g1. The structures were determined by a combination of spectroscopic techniques, primarily 2D NMR.
Molecular phylogenetic surveys based on the characterization of 16S rRNA genes have revealed that soil is an environment particularly rich in microbial diversity. A clade of crenarchaeota (archaea) has frequently been detected among many other novel lineages of uncultivated bacteria. In this study we have initiated a genomic approach for the characterization of uncultivated microorganisms from soil. We have developed a procedure based on a two-phase electrophoresis technique that allows the fast and reliable purification of concentrated and clonable, high molecular weight DNA. From this DNA we have constructed complex large-insert genomic libraries. Using archaea-specific 16S rRNA probes we have isolated a 34 kbp fragment from a 900 Mbp fosmid library of soil DNA. The clone contained a complete 16S/23S rRNA operon and 17 genes encoding putative proteins. Phylogenetic analyses of the rRNA genes and of several protein encoding genes (e.g. DNA polymerase, FixAB, glycosyl transferase) confirmed the specific affiliation of the genomic fragment with the non-thermophilic clade of the crenarchaeota. Content and structure of the genomic fragment indicated that the archaea from soil differ significantly from their previously studied uncultivated marine relatives. The protein encoding genes gave the first insights into the physiological potential of these organisms and can serve as a basis for future genomic and functional genomic studies.
To examine as randomly as possible the role of the -ketoacyl and acyl carrier protein (ACP) components of bacterial type II polyketide synthases (PKSs), homologs of the chain-length-factor (CLF) genes were cloned from the environmental community of microorganisms. With PCR primers derived from conserved regions of known ketosynthase (KS ␣ ) and ACP genes specifying the formation of 16-to 24-carbon polyketides, two CLF (KS  ) genes were cloned from unclassified streptomycetes isolated from the soil, and two were cloned from soil DNA without the prior isolation of the parent microorganism. The sequence and deduced product of each gene were distinct from those of known KS  genes and, by phylogenetic analysis, belonged to antibiotic-producing PKS gene clusters. Hybrid PKS gene cassettes were constructed with each novel KS  gene substituted for the actI-ORF2 or tcmL KS  subunit genes, along with the respective actI-ORF1 or tcmK KS ␣ , tcmM ACP, and tcmN cyclase genes, and were found to produce an octaketide or decaketide product characteristic of the ones known to be made by the heterologous KS ␣ gene partner. Since substantially less than 1% of the microorganisms present in soil are thought to be cultivatable by standard methods, this work demonstrates a potential way to gain access to a more extensive range of microbial molecular diversity and to biosynthetic pathways whose products can be tested for biological applications.The polyketide metabolites are a large group of structurally complex and diverse natural products, many of which are clinically valuable antibiotics or chemotherapeutic agents or have other useful pharmacological activities (48). Polyketides are synthesized by polyketide synthases (PKSs) which, like the related fatty acid synthases, are multifunctional enzyme assemblies that catalyze repeated decarboxylative condensations between enzyme-bound acylthioesters (52). The structural diversity of polyketides is a result of the different numbers and types of acyl units involved, coupled with various possibilities for enzyme-mediated reduction, dehydration, cyclization, and aromatization of the initial -ketoacyl condensation products (52). Manipulation of the sequence or specificity of the PKS enzymes can lead to the production of novel secondary metabolites (28,29,33). The key to further exploitation of this approach to molecular diversity lies in an increased understanding of the genetics and biochemistry of the various PKS systems.Recent progress in the cloning and sequencing of microbial PKS genes has led to the identification of at least two architecturally different types of PKSs (28, 33). Modular type I PKSs, represented by erythromycin A (11, 17), avermectin (41), rapamycin (58), and soraphen (57), are discrete multifunctional enzymes sporting numerous unique active site domains. The domains are grouped into distinct modules that in turn control the sequential addition of acylthioester units to the growing polyketide chain and the subsequent modification of the respective condensation prod...
BackgroundThe large surplus of crude glycerol, as main low-value waste stream in biodiesel production, has led to the investigation of new possibilities for the production of value-added chemicals from this feedstock. New and efficient (bio-) catalysts are needed that are able to convert glycerol to versatile chemical building blocks. This would contribute to further develop away from a mainly petroleum based, to a sustainable, bio-based industry. One promising group of discussed building block chemicals are dicarbonic acids.ResultsHere, we report the efficient synthesis of malate from glycerol using Ustilago trichophora RK089, which was identified in a screening of 74 Ustilaginaceae. For economically feasible production that can compete with existing processes, a high productivity is required. By adaptive laboratory evolution, the growth and production rate were increased by 2.5- and 6.6-fold, respectively. Further medium optimization increased the final titer, yield, and overall production rate to 196 g L−1, 0.82 gmal ggly−1, and 0.39 g L−1 h−1, respectively.ConclusionsThis titer is the highest reported for microbial malate production, making U. trichophora TZ1 a promising microbial production host for malate from crude glycerol, especially since it is not genetically engineered. Since this production process starts from an industrial waste stream as substrate and yields an interesting platform chemical, which can be used to replace petro-chemicals, it greatly contributes to a sustainable bio-economy.
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