Engineering of the erythromycin-producing polyketide synthase

Wiesmann, Kristen E. H.

January 1995

No description available.

572.8

Antibiotic biosynthesis genes

Analysis of the regulation and expression of novobiocin resistance in the producer organism Streptomyces niveus 19793

Hoggarth, Jennifer Heather

January 1993

No description available.

579

Antibiotic biosynthesis

Glycopeptide Antibiotic Biosynthesis and Resistance in Streptomyces toyocaensis

Marshall, Christopher G

10 1900

Genetic and biochemical studies were conducted on S. toyocaensis NRRL 15009, a gram-positive spomlating filamentous bacterium, and producer of the glycopeptide antibiotic A47934. This compound is structurally similar to the clinically important antibiotic vancomycin, and the recent spread of vancomycin-resistant enterococci (VRE) in North American hospitals has driven the need for new glycopeptides with enhanced activities. Studies were aimed at developing an understanding of the mechanism of A47934 biosynthesis inS. toyocaensis NRRL 15009, as well as the mechanism of resistance employed by this organism. Two cosmid clones, containing a partial A47934 biosynthesis gene cluster on a total of65 kilobases of S. toyocaensis NRRL 15009 chromosomal DNA, were isolated for study. Preliminary sequencing indicates the presence of several genes predicted in glycopeptide assembly, such as peptide synthetases and glycosyltransfe~ases. Furthermore, using a oligonucleotide probe designed to identify D-alanine-D-alanine ligases, an 8.1 kilobase chromosomal fragment was isolated from S. toyocaensis NRRL 15009 and found to contain genes very similar to VRE vanH, vanA and vanX. Phylogenetic analysis of the predicted products of these genes showed them to be more similar to the VRE enzymes than any other in each enzyme class. These genes were also found in the vancomycin producer A. orienta/is C329.2 and several other glycopeptide antibiotic producing organisms. Not only does this imply that these organisms employ a mechanism of resistance similar to clinical VRE, it also suggests that these organisms may have been the source of the VRE genes. The enzymes VanHst and DdlN were studied in some detail and found to have biochemical properties similar to their corresponding VRE enzymes VanH and VanA, respectively. Given that the latter group of enzymes has physical properties that have impeded detailed analysis of enzyme mechanism, these new enzymes could find use as model systems in drug development programs. / Thesis / Doctor of Philosophy (PhD)

Precursor Supply and Polyketide Antibiotic Biosynthesis in Oil-based Industrial Fermentations of Streptomyces Cinnamonensis

Li, Chaoxuan

01 January 2007

Polyketides are a group of bioactive natural products synthesized by bacteria, fungi and plants with various acyl-CoA precursors, such as malonyl-CoA, methylmalonyl-CoA and ethylmalonyl-CoA. A sufficient supply of these precursors is a prerequisite for the high level production of polyketide products. A thorough understanding of relative roles of various metabolic pathways involved in precursor supply makes increased production by genetical manipulation, and thus rational strain improvement, a reality. Monensin A is a polyketide antibiotic assembled from one ethylmalonyl-CoA, seven methylmalonyl-CoA and five malonyl-CoA molecules by Streptomyces cinnamonensis. In the present work, the origin of these biosynthetic precursors was investigated using an industrially mutagenized monensin producer and industrial fermentation conditions. A hitherto disregarded metabolic pathway was discovered to play a significant role in providing methylmalonyl-CoA for monensin biosynthesis by gene disruption, isotope-labeling of monensin and analysis of in vivo acyl-CoA pools. This pathway starts from biosynthesis of butyryl-CoA from two molecules of acetyl-CoA, and goes through the intermediate of isobutyryl-CoA, and finally produces methylmalonyl-CoA by direct oxidation of the pro-S methyl group of isobutyryl-CoA.Industrial fermentation of the industrially mutagenized monensin producer yields significantly more monensin than the routine laboratory fermentation. This suggested the presence of abundant in vivo malonyl-CoA and methylmalonyl-CoA in this process and presented an opportunity to utilize it as a biological system for the high-titer production of heterologous polyketides derived from malonyl-CoA and/or methylmalonyl-CoA. The tetracenomycin C polyketide synthase (PKS) synthesizes tetracenomycin C, a polyketide with ten molecules of malonyl-CoA. In this work, the tetracenomycin C PKS gene cluster was introduced into two industrially mutagenized strains of Streptomyces cinnamonensis. Unprecedented multi-gram/liter of tetracenomycin production was observed in the resulting two strains, indicating the high potential of industrially mutagenized monensin production strains as efficient hosts for the production of malonyl-CoA-derived polyketides. For additional improvement in tetracenomycin yield, we attempted to increase malonyl-CoA supply to tetracenomycin C PKS by genetically manipulating metabolic pathways affecting production of malonyl-CoA and eliminating competition from monensin PKS for malonyl-CoA. However, only decreased tetracenomycin production was observed, demonstrating that the regulation of malonyl-CoA-related metabolic pathways is a complex process.

polyketide

antibiotic biosynthesis

fermentation

precursor supply

Chemicals and Drugs

Medicine and Health Sciences

Cloning And Characterization Of Streptomyces Clavuligerus Meso-diaminopimelate Decarboxylase (lysa) Gene

Yagcioglu, Cigdem

01 September 2004

In Streptomyces clavuligerus, the route to the biosynthesis of &amp / #945 / -aminoadipic acid (&amp / #945 / -AAA) represents an important primary metabolic pathway providing carbon flux to the synthetases of antibiotic formation. This carbon flow comes through the lysine-specific branch of the aspartate pathway and is rate limiting in the formation of cephamycin C, a second generation cephalosporin produced by this organism. In this study, the lysA gene which encodes for an important key enzyme of aspartate pathway / meso-diaminopimelic acid (DAP) decarboxylase (E.C.4.1.1.20) catalyzing the conversion of diaminopimelate to lysine was cloned and characterized for the first time from S. clavuligerus NRRL 3585. The attempts to clone the gene by constructing libraries of S. clavuligerus genomic DNA and screening of the libraries either by homologous probing or complementation approach gave no positive results. Then, PCR-based cloning was taken as the approach and the gene was amplified with PCR using the primers derived from the conserved sequences of lysA genes in two fragments (620 and 983 bp) which had overlapping regions. Fragments were then cloned and nucleotide sequencing revealed a complete open reading frame (ORF) encoding a protein of 463 aa (Mr 49, 907). The GC content of the gene was identified as 70.98 %. The gene sequence showed 83 % identity to the sequence of S. coelicolor lysA gene and 81 % identity to S. avermitilis lysA gene. By comparing the amino acid sequence of this protein to those available in database, the sites of the enzyme important for catalysis were identified.

QR Bacteria 75-99.5

Streptomyces clavuligerus

Gene cloning

DAP decarboxylase

Cephamycin C, antibiotic biosynthesis.

Cephamycin C Production By Streptomyces Clavuligerus Mutants Impaired In Regulation Of Aspartokinase

Zeyniyev, Araz

01 September 2006

Aspartokinase is the first enzyme of the aspartate family amino acids biosynthetic pathway. Cephamycin C is a &amp / #946 / -lactam antibiotic produced as a secondary metabolite via the enzymatic reactions in the lysine branch of this pathway in Streptomyces clavuligerus. The aspartokinase activity of S. clavuligerus is under concerted feedback inhibition by two of the end product amino acids, lysine plus threonine. It is also known that carbon flow through the lysine branch of the aspartate pathway is rate limiting step in the formation of cephamycin C. Therefore, genetic alterations in the regulatory regions of the aspartokinase enzyme are expected to lead to an increased cephamycin C production. The aim of this study was to obtain S. clavuligerus mutants that possess aspartokinase enzyme insensitive to feedback inhibition by lysine and threonine, identification of the mutation(s) accounting for the resistance being the ultimate goal. For this aim, chemical mutagenesis was employed to increase random mutation rate and a population of lysine anti-metabolite resistant S. clavuligerus mutants that can grow in the presence of S-(2-aminoethyl)-L-cysteine was obtained. The mutants were screened for their aspartokinase insensitivity via enzyme assays and one mutant exhibiting the highest level of deregulation was assessed for its cephamycin C production. The results revealed a 2-fold increase in specific production of the antibiotic. As a member of &amp / #946 / -lactam class antibiotics, cephamycin C has an importance in medicine. Therefore, the mutant strain obtained might be a candidate for industrial production of the compound.

QR Microbiology 1-502