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COMBINATORIAL BIOSYNTHETIC DERIVATIZATION OF THE ANTITUMORAL AGENT GILVOCARCIN VShepherd, Micah Douglas 01 January 2011 (has links)
Gilvocarcin V (GV), the principal product of Streptomyces griseoflavus Gö 3592 and other Streptomyces spp., is the most prominent member of a distinct class of antitumor antibiotics that share a polyketide derived coumarin-based aromatic core. GV and other members of this class including polycarcin V from Streptomyces polyformus, often referred to as gilvocarcin-like aryl C-glycosides, are particularly interesting because of their potent bactericidal, virucidal and antitumor activities at low concentrations while maintaining low in vivo toxicity. Although the precise molecular mechanism of GV bioactivity is unknown, gilvocarcin V has been shown to undergo a photoactivated [2+2] cycloaddition of its vinyl side chain with thymine residues of DNA in near-UV or visible blue light. In addition, GV was shown to selectively crosslink histone H3 with DNA, thereby effectively disrupting normal cellular processes such as transcription. Furthermore, GVs ability to inhibit topoisomerase II has also been attributed as a mechanism of action for gilvocarcin V activity. The excellent antitumor activity, as well as an unprecedented structural architecture, has made GV an ideal candidate for biosynthetic studies toward the development of novel analogues with improved pharmacological properties. Previous biosynthetic research has identified several candidate genes responsible for key steps during the biosynthesis of gilvocarcin V including an oxygenase cascade leading to C-C bond cleavage, methylations, lactone formation, C-glycosylation and vinyl side chain formation.
In this study, we further examined two critical biosynthetic transformations essential for the bioactivity of gilvocarcin V, namely starter unit incorporation and C-glycosylation, through the following specific aims: 1) creation of functional chimeric C-glycosyltransferases through domain swapping of gilvocarcin-like glycosyltransferases and identification and evaluation of the donor substrate flexibility of PlcGT, the polycarcin V pathway specific C-glycosyltransferase; 2) creation of a library of O-methylated-L-rhamnose analogues of polycarcin V for structure activity relationship studies; 3) identification of the role of GilP and GilQ in starter unit specificity during gilvocarcin V biosynthesis; and 4) creation of a plasmid based approach in which selective gilvocarcin biosynthetic genes were utilized to produce important gilvocarcin intermediates for further in vivo and in vitro experimentation.
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Chemoenzymatic Studies to Enhance the Chemical Space of Natural ProductsChen, Jhong-Min 01 January 2015 (has links)
Natural products provide some of the most potent anticancer agents and offer a template for new drug design or improvement with the advantage of an enormous chemical space. The overall goal of this thesis research is to enhance the chemical space of two natural products in order to generate novel drugs with better in vivo bioactivities than the original natural products.
Polycarcin V (PV) is a gilvocarcin-type antitumor agent with similar structure and comparable bioactivity with the principle compound of this group, gilvocarcin V (GV). Modest modifications of the polyketide-derived tetracyclic core of GV had been accomplished, but the most challenging part was to modify the sugar moiety. In order to solve this problem, PV was used as an alternative lead-structure for modification because its sugar moiety offered the possibility of enzymatic O-methylation. We produced four PV derivatives with different methylation patterns for cytotoxicity assays and provided important structure-activity-relationship information.
Mithramycin (MTM) is the most prominent member of the aureolic acid type anticancer agents. Previous work in our laboratory generated three MTM analogues, MTM SA, MTM SK, and MTM SDK by inactivating the mtmW gene. We developed new MTM analogues by coupling many natural and unnatural amino acids to the C-3 side chain of MTM SA via chemical semi-synthesis and successfully made some compounds with both improved bioactivity and in vivo tolerance than MTM. Some of them were consequently identified as promising lead-structures against Ewing’s sarcoma.
The potential of selectively generating novel MTM analogues led us to focus on a key enzyme in the biosynthetic pathway of mithramycin, MtmC. This protein is a bifunctional enzyme involved in the biosynthesis of TDP-D-olivose and TDP-D-mycarose. We clarified its enzymatic mechanisms by X-ray diffraction of several crystal complexes of MtmC with its biologically relevant ligands. Two more important post-PKS tailoring enzymes involved in the biosynthesis of the MTM side chains, MtmW and MtmGIV, are currently under investigation. This would not only give us insight into this biosynthetic pathway but also pave the way to develop potentially useful MTM analogues by engineered enzymes.
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