Midecamycin Is Inactivated by Several Different Sugar Moieties at Its Inactivation Site.

Glycosylation inactivation is one of the important macrolide resistance mechanisms. The accumulated evidences attributed glycosylation inactivation to a glucosylation modification at the inactivation sites of macrolides. Whether other glycosylation modifications lead to macrolides inactivation is unclear. Herein, we demonstrated that varied glycosylation modifications could cause inactivation of midecamycin, a 16-membered macrolide antibiotic used clinically and agriculturally. Specifically, an actinomycetic glycosyltransferase (GT) OleD was selected for its glycodiversification capacity towards midecamycin. OleD was demonstrated to recognize UDP-D-glucose, UDP-D-xylose, UDP-galactose, UDP-rhamnose and UDP-N-acetylglucosamine to yield corresponding midecamycin 2'-O-glycosides, most of which displayed low yields. Protein engineering of OleD was thus performed to improve its conversions towards sugar donors. Q327F was the most favorable variant with seven times the conversion enhancement towards UDP-N-acetylglucosamine. Likewise, Q327A exhibited 30% conversion enhancement towards UDP-D-xylose. Potent biocatalysts for midecamycin glycosylation were thus obtained through protein engineering. Wild OleD, Q327F and Q327A were used as biocatalysts for scale-up preparation of midecamycin 2'-O-glucopyranoside, midecamycin 2'-O-GlcNAc and midecamycin 2'-O-xylopyranoside. In contrast to midecamycin, these midecamycin 2'-O-glycosides displayed no antimicrobial activities. These evidences suggested that besides glucosylation, other glycosylation patterns also could inactivate midecamycin, providing a new inactivation mechanism for midecamycin resistance. Cumulatively, glycosylation inactivation of midecamycin was independent of the type of attached sugar moieties at its inactivation site.

Bifunctional Nitrone-Conjugated Secondary Metabolite Targeting the Ribosome.

Many microorganisms possess the capacity for producing multiple antibiotic secondary metabolites. In a few notable cases, combinations of secondary metabolites produced by the same organism are used in important combination therapies for treatment of drug-resistant bacterial infections. However, examples of conjoined roles of bioactive metabolites produced by the same organism remain uncommon. During our genetic functional analysis of oxidase-encoding genes in the everninomicin producer Micromonospora carbonacea var. aurantiaca, we discovered previously uncharacterized antibiotics everninomicin N and O, comprised of an everninomicin fragment conjugated to the macrolide rosamicin via a rare nitrone moiety. These metabolites were determined to be hydrolysis products of everninomicin P, a nitrone-linked conjugate likely the result of nonenzymatic condensation of the rosamicin aldehyde and the octasaccharide everninomicin F, possessing a hydroxylamino sugar moiety. Rosamicin binds the erythromycin macrolide binding site approximately 60 Å from the orthosomycin binding site of everninomicins. However, while individual ribosomal binding sites for each functional half of everninomicin P are too distant for bidentate binding, ligand displacement studies demonstrated that everninomicin P competes with rosamicin for ribosomal binding. Chemical protection studies and structural analysis of everninomicin P revealed that everninomicin P occupies both the macrolide- and orthosomycin-binding sites on the 70S ribosome. Moreover, resistance mutations within each binding site were overcome by the inhibition of the opposite functional antibiotic moiety binding site. These data together demonstrate a strategy for coupling orthogonal antibiotic pharmacophores, a surprising tolerance for substantial covalent modification of each antibiotic, and a potential beneficial strategy to combat antibiotic resistance.

Cytochrome P450 enzyme RosC catalyzes a multistep oxidation reaction to form the non-active compound 20-carboxyrosamicin.

The cytochrome P450 enzyme RosC catalyzes a two-step, hydroxylation and alcohol oxidation, oxidation reaction to form the C-20 formyl group in the biosynthesis of a 16-membered macrolide antibiotic rosamicin produced by Micromonospora rosaria IFO13697. RosC is presumed to be involved in the formation of 20-carboxyrosamicin because it has been isolated from the culture broth of M. rosaria. Here, we confirmed that RosC has catalytic activity, with E. coli expressing RosC converting rosamicin into 20-carboxyrosamicin. Therefore, it was revealed that RosC is a multifunctional P450 that catalyzes a three-step oxidation reaction that leads to the formation of the hydroxyl group, formyl group and carboxyl group at C-20 on the macrolactone ring in the rosamicin biosynthetic pathway. Moreover, the cytochrome P450 enzyme TylI, which is involved in formation of the formyl group of a 16-membered macrolide antibiotic tylosin produced by Streptomyces fradiae ATCC 19609, also converted rosamicin into 20-carboxyrosamicin.

Characterization of the Two Methylation Steps Involved in the Biosynthesis of Mycinose in Tylosin.

The S-adenosyl-l-methionine-dependent O-methyltransferases TylE and TylF catalyze the last two methylation reactions in the tylosin biosynthetic pathway of Streptomyces fradiae. It has long been known that the TylE-catalyzed C2‴-O-methylation of the 6-deoxy-d-allose bound to demethylmacrocin or demethyllactenocin precedes the TylF-catalyzed C3‴-O-methylation of the d-javose (C2‴-O-methylated 6-deoxy-d-allose) attached to macrocin or lactenocin. This study reveals the unexpected substrate promiscuity of TylE and TylF responsible for the biosynthesis of d-mycinose (C3‴-O-methylated d-javose) in tylosin through the identification of a new minor intermediate 2‴-O-demethyldesmycosin (2; 3‴-methyl-demethyllactenocin), which lacks a 2‴-O-methyl group on the mycinose moiety of desmycosin, along with 2‴-O-demethyltylosin (1; 3‴-methyl-demethylmacrocin) that was previously detected from the S. fradiae mutant containing a mutation in the tylE gene. These results unveil the unique substrate flexibility of TylE and TylF and demonstrate their potential for the engineered biosynthesis of novel glycosylated macrolide derivatives.

Salinipyrone and Pacificanone Are Biosynthetic By-products of the Rosamicin Polyketide Synthase.

Salinipyrones and pacificanones are structurally related polyketides from Salinispora pacifica CNS-237 that are proposed to arise from the same modular polyketide synthase (PKS) assembly line. Genome sequencing revealed a large macrolide PKS gene cluster that codes for the biosynthesis of rosamicin A and a series of new macrolide antibiotics. Mutagenesis experiments unexpectedly correlated salinipyrone and pacificanone biosynthesis to the rosamicin octamodule Spr PKS. Remarkably, this bifurcated polyketide pathway illuminates a series of enzymatic domain- and module-skipping reactions that give rise to natural polyketide product diversity. Our findings enlarge the growing knowledge of polyketide biochemistry and illuminate potential challenges in PKS bioengineering.

Biotransformation of rosamicin antibiotic into 10,11-dihydrorosamicin with enhanced in vitro antibacterial activity against MRSA.

A biotransformation approach using microbes as biocatalysts can be an efficient tool for the targeted modification of existing antibiotic chemical scaffolds to create previously uncharacterized therapeutic agents. By employing a recombinant Streptomyces venezuelae strain as a microbial catalyst, a reduced macrolide, 10,11-dihydrorosamicin, was created from rosamicin macrolide. Its chemical structure was spectroscopically elucidated, and the new rosamicin analog showed 2-4-fold higher antibacterial activity against two strains of methicillin-resistant Staphylococcus aureus compared with its parent rosamicin. This kind of biocatalytic approach is able to expand existing antibiotic entities and can also provide more diverse therapeutic resources.

Production of rosamicin derivatives in Micromonospora rosaria by introduction of D-mycinose biosynthetic gene with PhiC31-derived integration vector pSET152.

Some of the polyketide-derived bioactive compounds contain sugars attached to the aglycone core, and these sugars often impart specific biological activity to the molecule or enhance this activity. Mycinamicin II, a 16-member macrolide antibiotic produced by Micromonospora griseorubida A11725, contains a branched lactone and two different deoxyhexose sugars, D-desosamine and D-mycinose, at the C-5 and C-21 positions, respectively. The D-mycinose biosynthesis genes, mycCI, mycCII, mycD, mycE, mycF, mydH, and mydI, present in the M. griseorubida A11725 chromosome were introduced into pSET152 under the regulation of the promoter of the apramycin-resistance gene aac(3)IV. The resulting plasmid pSETmycinose was introduced into Micromonospora rosaria IFO13697 cells, which produce the 16-membered macrolide antibiotic rosamicin containing a branched lactone and D-desosamine at the C-5 position. Although the M. rosaria TPMA0001 transconjugant exhibited low rosamicin productivity, two new compounds, IZI and IZII, were detected in the ethylacetate extract from the culture broth. IZI was identified as a mycinosyl rosamicin derivative, 23-O-mycinosyl-20-deoxo-20-dihydro-12,13-deepoxyrosamicin (MW 741), which has previously been synthesized by a bioconversion technique. This is the first report on production of mycinosyl rosamicin-derivatives by a engineered biosynthesis approach. The integration site PhiC31attB was identified on M. rosaria IFO13697 chromosome, and the site lay within an ORF coding a pirin homolog protein. The pSETmycinose could be useful for stimulating the production of "unnatural" natural mycinosyl compounds by various actinomycete strains using the bacteriophage PhiC31 att/int system.

Substituent effects within the DNA binding subunit of CBI analogues of the duocarmycins and CC-1065.

A series of CBI analogues of the duocarmycins and CC-1065 exploring substituent effects within the first indole DNA binding subunit are detailed. Substitution at the indole C5 position led to cytotoxic potency enhancements that are > or =1000-fold, providing simplified analogues containing a single DNA binding subunit that are more potent (IC(50)=2-3 pM) than CBI-TMI, duocarmycin SA, or CC-1065.

Recent developments in sequence selective minor groove DNA effectors.

DNA is a well characterized intracellular target but its large size and sequential nature make it an elusive target for selective drug action. Binding of low molecular weight ligands to DNA causes a wide variety of potential biological responses. In this respect the main consideration is given to recent developments in DNA sequence selective binding agents bearing conjugated effectors because of their potential application in diagnosis and treatment of cancers as well as in molecular biology. Recent progress in the development of cross linked lexitropsin oligopeptides and hairpins, which bind selectively to the minor groove of duplex DNA, is discussed. Bis-distamycins and related lexitropsins show inhibitory activity against HIV-1 and HIV-2 integrases at low nanomolar concentrations. Benzoyl nitrogen mustard analogs of lexitropsins are active against a variety of tumor models. Certain of the bis-benzimidazoles show altered DNA sequence preference and bind to DNA at 5'CG and TG sequences rather than at the preferred AT sites of the parent drug. A comparison of bifunctional bizelesin with monoalkylating adozelesin shows that it appears to have an increased sequence selectivity such that monoalkylating compounds react at more than one site but bizelesin reacts only at sites where there are two suitably positioned alkylation sites. Adozelesin, bizelesin and carzelesin are far more potent as cytotoxic agents than cisplatin or doxorubicin. A new class of 1,2,9,9a-tetrahydrocyclo-propa[c]benz[e]indole-4-one (CBI) analogs i.e., CBI-lexitropsin conjugates arising from the latter leads are also discussed.A number of cyclopropylpyrroloindole (CPI) and CBI-lexitropsin conjugates related to CC-1065 alkylate at the N3 position of adenine in the minor groove of DNA in a sequence specific manner, and also show cytotoxicities in the femtomolar range. The cross linking efficiency of PBD dimers is much greater than that of other cross linkers including cisplatin, and melphalan. A new class of PBD-lexitropsin conjugates is also discussed. Certain functional models of the bleomycins (BLMs) show outstanding DNA cleavage activity comparable with that of and positionally distinct from natural BLM.

Sequence specific recognition of ligand-DNA complexes studied by NMR.

The last few years have represented an accelerated accumulation in detailed information about ligand-DNA interactions. A collected view of literature information is essential for advancing our understanding of the principles of ligand-DNA recognition, utilizing this valuable information for construction of a modeling database, and eventually the rational design of DNA-binding ligands possessing desired properties. This review is concentrated on structure-based information on ligand-oligodeoxyribonucleotide (DON) complexes published since 1995, especially focusing on the results obtained from NMR structure elucidation. The discussions emphasize the sequence specific recognition of novel binding motifs or binding modules of ligand molecules rather than specific atomic details. A comprehensive list of DNA binding ligands are discussed in the text and are also summarized in a table. The DNA sequences that are recognized by specific ligand molecules as studied by NMR are annotated in a figure to provide a clear view of target selection. This review also briefly describes NMR methods for characterization and structure elucidation of ligand-DNA complexes.

Highly selective glycosylated prodrugs of cytostatic CC-1065 analogues for antibody-directed enzyme tumor therapy.

Novel prodrugs of the cytotoxic antibiotic CC-1065 for an antibody-directed enzyme prodrug therapy (ADEPT) were prepared that show an excellent selectivity with a high toxicity of the corresponding drug. In particular, the seco-CBI analogue of CC-1065, 1-chloromethyl-5-hydroxy-1,2-dihydro-3H-benz[e]indole, as well as the novel methyl-seco-CBI analogue 1-(1'-chloroethyl)-5-hydroxy-1,2-dihydro-3H-benz[e]indole, were synthesized and transformed into their galactosides 10 a and 10 b, respectively. These galactosides can be cleaved with beta-D-galactosidase to give the free cytotoxic compounds. They were tested in in vitro cytotoxicity assays by using human bronchial carcinoma cells of line A549 in the presence and in the absence of beta-D-galactosidase. While the seco-CBI prodrugs revealed only modest selectivity, prodrugs of the methyl-seco-CBI analogue bearing an anti orientation of the substituents at the two stereogenic centers of the N-heterocycle displayed an excellent selectivity with an ED(50) quotient of about 750. The cytotoxicity of the corresponding phenol was rather high, with an ED(50) of 1.3 nM. The diastereomer with a syn orientation at the stereogenic centers was much less toxic.

Inhibition of the ribosomal peptidyl transferase reaction by the mycarose moiety of the antibiotics carbomycin, spiramycin and tylosin.

Many antibiotics, including the macrolides, inhibit protein synthesis by binding to ribosomes. Only some of the macrolides affect the peptidyl transferase reaction. The 16-member ring macrolide antibiotics carbomycin, spiramycin, and tylosin inhibit peptidyl transferase. All these have a disaccharide at position 5 in the lactone ring with a mycarose moiety. We have investigated the functional role of this mycarose moiety. The 14-member ring macrolide erythromycin and the 16-member ring macrolides desmycosin and chalcomycin do not inhibit the peptidyl transferase reaction. These drugs have a monosaccharide at position 5 in the lactone ring. The presence of mycarose was correlated with inhibition of peptidyl transferase, footprints on 23 S rRNA and whether the macrolide can compete with binding of hygromycin A to the ribosome. The binding sites of the macrolides to Escherichia coli ribosomes were investigated by chemical probing of domains II and V of 23 S rRNA. The common binding site is around position A2058, while effects on U2506 depend on the presence of the mycarose sugar. Also, protection at position A752 indicates that a mycinose moiety at position 14 in 16-member ring macrolides interact with hairpin 35 in domain II. Competitive footprinting of ribosomal binding of hygromycin A and macrolides showed that tylosin and spiramycin reduce the hygromycin A protections of nucleotides in 23 S rRNA and that carbomycin abolishes its binding. In contrast, the macrolides that do not inhibit the peptidyl transferase reaction bind to the ribosomes concurrently with hygromycin A. Data are presented to argue that a disaccharide at position 5 in the lactone ring of macrolides is essential for inhibition of peptide bond formation and that the mycarose moiety is placed near the conserved U2506 in the central loop region of domain V 23 S rRNA.

Characterization of a duocarmycin-DNA adduct-recognizing protein in cancer cells.

Duocarmycins have been reported to derive their potent antitumor activity through a sequence-selective minor groove alkylation of N3 adenine in double-stranded DNA. We have used gel mobility shift assays to detect proteins that bind to DNA treated in vitro with duocarmycin SA and identified a protein, named duocarmycin-DNA adduct recognizing protein (DARP), which binds with increased affinity to duocarmycin-damaged DNA. Examination with partially purified DARP revealed that the protein recognized not only the DNA adduct of structurally related drug, CC-1065, but unexpectedly, the protein also recognized the DNA adduct of another chemotype of minor groove binder, anthramycin. These results demonstrate that DARP recognizes the structural alteration of DNA induced by these potent DNA-alkylating drugs, suggesting the possibility that the protein might modulate the antitumor activity of these drugs.

Stability and DNA alkylation rates of the simplest functional analogues of CC-1065, para-hydroxy and para-amino phenethyl bromides.

We have recently synthesised a series of compounds based on the simplest functional unit of CC-1065 containing a para substituted phenethyl halide moiety. These compounds alkylate N3 of adenines in a similar fashion to CC-1065, as well as N7 of guanines to a limited extent. In this work we compared the para amino substituted derivative (2) with the published hydroxyl compound (1) in terms of stability, DNA reactivity and pH dependence using gel electrophoresis techniques. The results show that 2 has a shorter lifetime and is at least 2.5 times more reactive with DNA than 1. It is completely hydrolysed between 30 and 60 min in buffer and its reaction with DNA is complete within 5 min. In contrast, only a fraction of 1 is hydrolysed after 60 min and retains reactivity towards DNA even after 3 h. The reactivities of both 1 and 2 with DNA are pH dependent and reaction rates rapidly decrease in the range pH 5.8-8.8. Preliminary molecular modelling studies suggest that the p-amino group on 2 enables the drug to bind to the AT-rich minor groove more effectively, thus stabilising the orientation of the substrate in the groove such that the reactive cyclopropyl ring is located close to the nucleophilic centre N3 of adenine. A possible mechanism of action of these drugs is presented based on these findings.

CC-1065/duocarmycin and bleomycin A2 hybrid agents: lack of enhancement of DNA alkylation by attachment to noncomplementary DNA binding subunits.

Hybrid agents 5-11 containing the C-terminus DNA binding domain of bleomycin A2 linked to the CBI analogue of the CC-1065 and duocarmycin DNA alkylation subunits were prepared and evaluated. The agents exhibited little or no enhancement of the DNA alkylation efficiency and in some cases the linkage resulted in diminished properties relative to the simple alkylation subunit itself. Moreover, the DNA alkylation selectivity (5'-AA > 5'-TA) of the resulting agents proved identical to that of simple derivatives of the CBI alkylation subunit, e.g. N-BOC-CBI. Thus, the linkage to the DNA binding domain of bleomycin A2 did not alter this inherent DNA alkylation selectivity to reflect a DNA binding or cleavage selectivity of bleomycin A2, nor did it reflect the greater 5- or 3.5-base-pair AT-rich selectivities observed with CC-1065 or the duocarmycins, respectively. Consistent with these observations, the cytotoxic properties of 5-11 were diminished relative to those of even simple derivatives of the CC-1065/duocarmycin alkylation subunits, e.g. N-BOC-CBI.

Catalysis of the CC-1065 and duocarmycin DNA alkylation reaction: DNA binding induced conformational change in the agent results in activation.

A number of indirect observations are summarized that suggest the rate acceleration for the CC-1065 and duocarmycin. DNA alkylation reaction is derived in part from a DNA binding-induced conformational change in the agents which substantially increases their inherent reactivity. This ground-state destabilization of the agent, which we suggest results from a binding-induced twist in the linking N2 amide and requires a rigid extended N2 amide substituent, disrupts the vinylogous amide stabilization and activates the agents for DNA alkylation.

In vitro and in vivo binding of a CC-1065 analogue to human gene sequences: a polymerase-chain reaction study.

In this paper we analyse the in vitro sequence selectivity of the CC-1065 analogue 2-[[5-[(1H-indol-2-yl]carbonyl)-1H-indol-2-yl] carbonyl]-7-methyl-1,2,8,8a-tetrahydrocyclopropa [c]-pyrrolo-[3,2-e]-indol-4-one (U-71184) employing the polymerase-chain reaction (PCR). In addition, we determined whether alteration of PCR by U-71184 is detected when DNA is isolated from cells cultured in the presence of this drug. As molecular model systems we employed the human estrogen receptor gene, the Ha-ras oncogene and the chromosome X-linked, (CGG)-rich fragile X mental retardation-1 gene. The first conclusion that can be drawn from the experiments reported in our paper is that U-71184 inhibits PCR in a sequence-dependent manner. A second conclusion of our experiments is that PCR performed on DNA from U-71184-treated cells is inhibited when the primers amplifying the estrogen receptor gene region are used. This approach might bring important information on both in vivo uptake of the drug by target cells and binding to DNA.

Demonstration and definition of the noncovalent binding selectivity of agents related to CC-1065 by an affinity cleavage agent: noncovalent binding coincidental with alkylation.

A study of the DNA cleavage efficiency and selectivity of CDPI3-EDTA (4), an affinity cleavage agent based on the structure of CC-1065, is described. The studies with 4 provide direct evidence of AT-rich noncovalent binding coincidental with all DNA alkylation sites observed with (+)- or ent-(-)-CC-1065.

Specific targeting of protein-DNA complexes by DNA-reactive drugs (+)-CC-1065 and pluramycins.

To gain insight into the interactions between transcriptional factor proteins and DNA, the DNA-reactive drugs (+)-CC-1065 and pluramycin were used to target specific protein-DNA complexes. The structural features of the complex between the transcriptional activator Sp1 and the 21-base-pair repeat of the early promoter region of SV40 DNA were examined using hydroxyl-radical footprinting; (+)-CC-1065, a sequence-specific minor groove bending probe; and circularization experiments. The results show that the 21-base-pair repeat region has an intrinsically in-phase bent structure that is stabilized upon saturation Sp1 binding by protein-DNA and protein-protein interactions to produce a looping structure. The intercalating drug pluramycin was used to probe the structural details of the interaction between the TATA binding protein (TBP) and the TATA box DNA sequence. TBP, which directs initiation of RNA transcription, exhibits two-fold symmetry and apparently interacts with the TATA box in a symmetrical fashion. However, the interaction results in an asymmetric effect, in that transcription is initiated only in the downstream direction. Using pluramycin as a probe, it was determined that TBP binding to the human myoglobin TATA sequences enhances pluramycin reactivity at a site immediately downstream of the TATA box. The implications on transcriptional control of ternary complexes comprised of transcriptional factors, DNA, and DNA-reactive compounds will be presented.