On the role of individual bleomycin thiazoles in oxygen activation and DNA cleavage

HFIP-Mediated Multicomponent Reactions: Synthesis of Pyrazole-Linked Thiazole Derivatives

The development of one-pot, atom, and step-economic new methods avoiding metal, harsh reaction conditions, and toxic reagents for the synthesis of medicinally important hybrid molecules bearing more than one bioactive moieties is currently one of the hot topics in organic synthesis. Herein, we report a green and efficient room temperature multicomponent reaction for the synthesis of novel pyrazole-linked thiazoles involving a one-pot C-C, C-N, and C-S bond-forming process from the reaction of aryl glyoxal, aryl thioamide, and pyrazolones in 1,1,1,3,3,3-hexafluoroisopropanol, a hydrogen bond donating reaction medium. A set of diverse hybrid molecules bearing thiazole and pyrazole moieties were prepared in good to excellent yields by using this method. This methodology can also be extended to prepare thiazole-linked barbiturates as well as imidazole-linked pyrazoles. All the products were fully characterized by spectroscopic techniques. The notable features of this protocol are room temperature, metal as well as additive-free reaction conditions, use of recyclable solvent, water as the byproduct, wide substrate scope, operational simplicity, easy purification, applicability for gram-scale synthesis, high atom economy, and the presence of two bioactive pyrazole and thiazole moieties in the products.

Transport of Molecular Cargo by Interaction with Virus-Like Particle RNA

Virus-like particles (VLPs) derived from Leviviridae virions contain substantial amounts of cellular and plasmid-derived RNA. This encapsidated polynucleotide serves as a reservoir for the efficient binding of the intercalating dye thiazole orange (TO). Polyethylene glycol (PEG) molecules and oligopeptides of varying length, end-functionalized with TO, were loaded into VLPs up to approximately 50 % of the mass of the capsid protein (hundreds to thousands of cargo molecules per particle, depending on size). The kinetics of TO-PEG binding included a significant entropic cost for the reptation of long chains through the capsid pores. Cargo molecules were released over periods of 20-120 hours following simple reversible first-order kinetics in most cases. These observations define a simple general method for the noncovalent packaging, and subsequent release, of functional molecules inside nucleoprotein nanocages in a manner independent of modifications to the capsid protein.

Investigation of Indigoidine Synthetase Reveals a Conserved Active-Site Base Residue of Nonribosomal Peptide Synthetase Oxidases

Nonribosomal peptide synthetase (NRPS) oxidase (Ox) domains oxidize protein-bound intermediates to install crucial structural motifs in bioactive natural products. The mechanism of this domain remains elusive. Here, by studying indigoidine synthetase, a single-module NRPS involved in the biosynthesis of indigoidine and several other bacterial secondary metabolites, we demonstrate that its Ox domain utilizes an active-site base residue, tyrosine 665, to deprotonate a protein-bound l-glutaminyl residue. We further validate the generality of this active-site residue among NRPS Ox domains. These findings not only resolve the biosynthetic pathway mediated by indigoidine synthetase but enable mechanistic insight into NRPS Ox domains.

Biochemical evaluation of a 108-member deglycobleomycin library: viability of a selection strategy for identifying bleomycin analogues with altered properties

The bleomycins (BLMs) are clinically used glycopeptide antitumor antibiotics that have been shown to mediate the sequence-selective oxidative damage of both DNA and RNA. Previously, we described the solid-phase synthesis of a library of 108 unique analogues of deglycoBLM A6, a congener that cleaves DNA analogously to BLM itself. Each member of the library was assayed for its ability to effect single- and double-strand nicking of duplex DNA, sequence-selective DNA cleavage, and RNA cleavage in the presence and absence of a metal ion cofactor. All of the analogues tested were found to mediate concentration-dependent plasmid DNA relaxation to some extent, and a number exhibited double-strand cleavage with an efficiency comparable to or greater than deglycoBLM A6. Further, some analogues having altered linker and metal-binding domains mediated altered sequence-selective cleavage, and a few were found to cleave a tRNA3Lys transcript both in the presence and in the absence of a metal cofactor. The results provide insights into structural elements within BLM that control DNA and RNA cleavage. The present study also permits inferences to be drawn regarding the practicality of a selection strategy for the solid-phase construction and evaluation of large libraries of BLM analogues having altered properties.

Conformationally Constrained Aliphatic−Aromatic Amino-Acid-Conjugated Hybrid Foldamers with Periodic β-Turn Motifs

In this note, we describe the design, synthesis, and structural studies of novel hybrid foldamers derived from Aib-Pro-Adb building blocks that display repeat beta-turn structure motif. The foldamer having a conformationally constrained aliphatic-aromatic amino acid conjugate adopts a well-defined, compact, three-dimensional structure, governed by a combined conformational restriction imposed by the individual amino acids with which it is made of. Conformational investigations by single-crystal X-ray and solution-state NMR studies were undertaken to investigate the conformational preference of these foldamers with a hetero-backbone. Our findings suggest that constrained aliphatic-aromatic amino acid conjugates would offer new avenues for the de novo design of hybrid foldamers with distinctive structural architectures.

Mid-Infrared Spectroscopy of Protected Peptides in the Gas Phase: A Probe of the Backbone Conformation

Infrared/UV hole-burning spectroscopy is performed on individual conformers of the protected dipeptide Z-Aib-Pro-NHMe. The extended IR range probed in this study allows one to elucidate both the H-bonding motif (5-7 microm) as well as the backbone structure (7-10 microm). Comparison with DFT calculations shows that the backbone is locally constrained to an alpha-conformation by Aib and to a gamma-turn by Pro. The gamma-turn motif observed here is intriguing since the condensed phase structure is known to be a beta-turn. This is the first actual observation of such a discrepancy, and it emphasizes the subtle balance between intra- and intermolecular forces, which is responsible for the relative stability of the different secondary structure motifs.

Excision of the epothilone synthetase B cyclization domain and demonstration of in trans condensation/cyclodehydration activity

The epothilones are potent anticancer natural products produced by a polyketide synthase (PKS)-nonribosomal peptide synthetase (NRPS) hybrid involving proteins EpoA-F. The single NRPS module of the epothilone assembly line, EpoB, is a distinct subunit of approximately 160 kDa and consists of four successive domains: cyclization, adenylation, oxidation, and peptidyl carrier protein (Cy-A-Ox-PCP). The cyclization domain is responsible for introduction of the thiazoline heterocycle into the growing polyketide/nonribosomal peptide chain from the precursors malonyl-CoA and cysteine through the multiple steps of condensation, cyclization, and dehydration. This enzyme-bound thiazoline intermediate is subsequently oxidized to a thiazole by the EpoB Ox domain. The EpoB module was dissected to provide 57 kDa EpoB(Cy) and 102 kDa EpoB(A-Ox-PCP) as subunit fragments to evaluate Cy as a free-standing domain. EpoB was reconstituted by these fragments in trans to generate the methylthiazole product. Using this system, apparent kinetic constants for the upstream acyl donor EpoA(ACP) and EpoB(Cy) were determined, providing a measure of affinity for the naturally occurring interface of the amino terminus of EpoB and the EpoA carboxy terminus. Site-directed mutants in excised EpoB(Cy) were prepared and used to examine residues involved in condensation and heterocycle formation. This work demonstrates the ability to define a functional Cy domain by excision from its native NRPS module, and examine both its protein-protein interactions and mechanism of activity.

Portability of oxidase domains in nonribosomal peptide synthetase modules

Oxazole and thiazole rings are present in numerous nonribosomal peptide natural products. Oxidase domains are responsible for catalyzing the oxidation of thiazolines and oxazolines to yield fully aromatic heterocycles. Unlike most domains, the placement of oxidase domains within assembly line modules varies. Noting this tolerance, we investigated the portability of an oxidase domain to a heterologous assembly line. The epimerase domain of PchE, involved in pyochelin biosynthesis, was replaced with the oxidase domain from MtaD, involved in myxothiazol biosynthesis. The chimeric module was expressed in soluble form as a flavin mononucleotide-containing flavoprotein. The functionality of the inserted oxidase domain was assayed within PchE and in transfer of the growing siderophore acyl chain from PchE to the next downstream module. While pyochelin-like product release was not observed downstream, the robust activity of the transplanted oxidase domain and the ability of the chimeric module to produce an advanced intermediate bound to the synthetase underscore the possibility of future engineering within nonribosomal peptide synthetase pathways using oxidase domains.

Conformationally constrained analogues of bleomycin A5

The bleomycin (BLM) group antitumor antibiotics are glycopeptide-derived natural products shown to cause sequence selective lesions in DNA. Prior studies have indicated that the linker region, composed of the methylvalerate and threonine residues, may be responsible for a conformational bend in the agent required for efficient DNA cleavage. We have synthesized a number of conformationally constrained methylvalerate analogues and incorporated them into deglycobleomycin A(5) congeners using our recently reported procedure for the solid phase construction of (deglyco)bleomycin and its analogues. These analogues were designed to probe the effects of conformational constraint of the native valerate moiety. Initial experiments indicated that the constrained molecules, none of which mimic the conformation proposed for the natural valerate linker, possessed DNA cleavage activity, albeit with potencies less than that of (deglyco)BLM and lacking sequence selectivity. Further experiments demonstrated that these analogues failed to produce alkali-labile lesions in DNA or sequence selective oxidative damage in RNA. However, two of the conformationally constrained deglycoBLM analogues were shown to mediate RNA cleavage in the absence of added Fe(2+). The ability of the analogues to mediate the oxygenation of small molecules was also assayed, and it was shown that they were as competent in the transfer of oxygen to low molecular weight substrates as the parent compound.

Oxidase domains in epothilone and bleomycin biosynthesis: thiazoline to thiazole oxidation during chain elongation

The natural products epothilone and bleomycin are assembled by hybrid polyketide/nonribosomal peptide synthetases. Of note in these assembly lines is the conversion of internal cysteine residues into thiazolines and their subsequent oxidation to heteroaromatic thiazole rings. We have excised the EpoB oxidase domain, EpoB-Ox, proposed to be responsible for thiazoline to thiazole oxidation in epothilone biosynthesis, and expressed it in soluble form in Escherichia coli. The purified domain is an FMN-containing flavoprotein that demonstrates thiazoline to thiazole oxidase activity when incubated with thioester substrate mimics. Kinetic parameters were determined for both thiazoline and oxazoline substrates, with k(cat) values ranging between 48.8 and 0.55 min(-1). While the physiological electron acceptor is not yet known, molecular oxygen is needed in these in vitro assays to mediate reoxidation of reduced FMN. Additionally, the oxidase domain-containing BlmIII from the bleomycin assembly line was heterologously expressed and purified. BlmIII is also an FMN-containing protein with activity similar to EpoB-Ox. This work marks the first direct characterization of nonribosomal peptide synthetase oxidase domain activity and will lead to further exploration of these flavoproteins.

Total synthesis of exochelin MN and analogues

The first total synthesis of exochelin MN is described along with rationally designed analogues. The required L-threo-beta-hydroxyamino acid components were constructed using either Sharpless asymmetric aminohydroxylation reactions or an aldol reaction of imidazolidinone 19. A new concise procedure for the preparation of the constituent six-membered cyclic hydroxamate was developed. In addition, a plausible mechanism for exochelin MN-mediated iron(III) transport was proposed. Biological studies of these compounds will be used to evaluate this hypothesis.

Solid-phase synthesis of deglycobleomycins: a C-terminal tetraamine linker that permits direct evaluation of resin-bound bleomycins

Deglycobleomycin analogues having different length polyamine side chains at the C-terminus were synthesized using a novel solid-phase synthesis strategy that produces fully deprotected deglycobleomycin congeners attached to the resin. Detailed studies of DNA cleavage by these compounds and their resin-bound counterparts using supercoiled plasmid DNAs and DNA restriction fragments as substrates revealed that (i) the length of the polyamine side chain of free deglycoBLM had limited effect on its DNA cleavage potency or sequence selectivity, and (ii) the nature of the linker moiety between the resin and attached deglycobleomycin had a more substantial effect on the potency of DNA cleavage, but no effect on sequence selectivity of resin-bound deglycoBLMs. Resin-bound 4 exhibited efficient DNA cleavage, indicating that its tetraamine linker moiety could be used for the elaboration and direct evaluation of bleomycin congeners attached to resins.

Chemical and structural characterization of the interaction of bleomycin A2 with d(CGCGAATTCGCG)2. efficient, double-strand DNA cleavage accessible without structural reorganization

A detailed description of the interaction between Fe(II).bleomycin A2 and the Dickerson-Drew dodecamer d(CGCGAATTCGCG)2 is presented. The reaction between bleomycin and this substrate leads to DNA cleavage at two major sites, adenosine5 and cytidine11, and two minor sites, cytidine3 and thymidine8. The pattern and relative intensities of cleavage at these sites was not entirely consistent with what would be predicted based on the preference of the drug for cleavage at the pyrimidines of 5'-GC-3' and 5'-GT-3' sites. Insight into the origins of the apparent alteration of selectivity was provided by examination of the structure of the duplex which had been determined by X-ray crystallography. This indicated that the C4' hydrogens of the two nucleotides located at the strongest cleavage sites, C11 on one strand and A5 on the other, were oriented toward each other in the minor groove. Two-dimensional NMR measurements and molecular dynamics modeling indicated that a metalloBLM could bind to the duplex in an orientation that positioned the metal center roughly equally close to each of these hydrogen atoms. On the basis of this observation, it was proposed that these two residues represented a double-stranded BLM cleavage site. This hypothesis was tested through the study of the BLM-mediated cleavage of the related decamer duplex, d(CGCGAATTCG).d(CGAATTCGCG), as well as the hairpin sequence d(CGCGAATTCGIIIITTTTCCCCCGAATTCGCG). By the use of the hairpin oligonucleotide 32P-labeled alternately at the 5' and 3'-ends, unequivocal evidence was obtained for BLM-mediated double-strand cleavage. Quantitative analysis of the proportion of damage involving double-strand cleavage was effected by the use of the hairpin substrate; for damage initiated at the predominant cleavage site (cytidine31, analogous to cytidine11 in the dodecanucleotide), it is estimated that 43% of all damage leads to double-stranded lesions. The exceptional efficiency of double-strand cleavage observed in this system must reflect the spatial proximity and orientation of the two sugar H's whose abstraction is required to produce double-stranded lesions.

Solid-phase synthesis of bleomycin group antibiotics. Elaboration of deglycobleomycin A(5)

The solid-phase syntheses of two deglycobleomycin A(5) analogues were achieved using a commercially available polystyrene resin containing triphenylmethyl-linked spermidine. The final products were deblocked and released from the resin, analyzed, and purified by C(18) reversed phase HPLC and characterized by high-field (1)H NMR spectroscopy and mass spectrometry. The purified products relaxed supercoiled plasmid DNA in a concentration-dependent fashion and to the same extent as authentic material derived from natural BLM A(5).

Synthesis, hydroxyl radical production and cytotoxicity of analogues of bleomycin

Two pyridine analogues of the metal complexing region of the anticancer drug bleomycin and two related but deactivated prodrugs have been linked to a 2,6-diphenylpyridine derivative as a DNA binding unit. The 2,6-diphenylpyridine system is structurally related to known amplifiers of the cytotoxicity of bleomycin. The conjugates were found to bind to DNA more strongly than bleomycin-A2 and were more cytotoxic than the corresponding compounds lacking the DNA binding unit. On exposure of a mixture of cells and prodrugs to hypoxia and then air, the prodrug containing the nitrohistidine unit was not bioreductively activated but the prodrug having an N-oxide group was bioreductively activated. This result represents a novel approach to the improvement of the therapeutic ratio of bleomycin analogues.

New Robust Bleomycin Analogues: Synthesis, Spectroscopy, and Crystal Structures of the Copper(II) Complexes

Two new bleomycin analogues, 2-[((2-(4-imidazolyl)ethyl)amino)carbonyl]-6-[((2-amino-2-methylpropyl)amino)methyl]pyridine = L(3)() and 2-[((2-(4-imidazolyl)ethyl)amino)carbonyl]-6-[((2-amino-1,1,2-trimethylpropyl)amino)methyl]pyridine = L(4)(), were synthesized in order to create air-stable ligands of their Cu(I) (and Fe(II)) complexes. The protonation constants (log K(n)()) of the ligands at 25 degrees C and I = 0.1 M NaNO(3) were 9.9, 6.9, and 5.2 for L(3)() and 10.0, 6.7, and 3.9 for L(4)(). The complexation of the triprotonated L(3)() and L(4)() with Cu(II) started at pH < 5 to yield 4-coordinate [Cu(II)(H(-)(1)L).H(+)](2+) complexes, 4 and 6, respectively, followed by formation of square-pyramidal [Cu(II)(H(-)(1)L)](+) complexes, 5 and 7, with pK(a) values of 5.6 for 5 and 5.9 for 7. The complexation constants, log K(Cu)()II(H)()-1(L), were 8.9 for [Cu(II)(H(-)(1)L(3))](+), 5, and 8.6 for [Cu(II)(H(-)(1)L(4))](+), 7, respectively. The structures of [Cu(II)(H(-)(1)L(3))]ClO(4) (5.ClO(4)) and [Cu(II)(H(-)(1)L(4))]BF(4) (7.BF(4)) were determined by X-ray crystallography. Crystal data for 5.ClO(4): monoclinic, space group P2(1)/n (No. 14), a = 13.978(6) Å, b = 8.103(3) Å, c = 18.037(5) Å, beta = 98.61(3) degrees, V = 2019(1) Å(3), Z = 4, R = 0.053, and R(w) = 0.044 for 2996 [I > 3sigma(I)] reflections. Crystal data for 7.BF(4): monoclinic, space group P2(1)/n (No. 14), a = 16.092 (4) Å, b = 7.974(4) Å, c = 16.819(2) Å, beta = 99.64(1) degrees, V = 2127(1) Å(3), Z = 4, R = 0.040, and R(w) = 0.025 for 1633 [I > 4sigma(I)] reflections. The coordination geometry around the copper was a distorted square-pyramid in 5, while that of 7 was the intermediate between a trigonal-bipyramid and a square-pyramid. The distortion is influenced strongly by the number of the methyl group. The EPR spectral data for both copper(II) complexes were consistent with the retention of the solid-state structure in frozen DMF/MeOH (1:1) solution at 77 K. The visible absorption spectra of 10% DMF/aqueous solutions (pH 9.5) of 5 and 7 at I = 0.1 M NaNO(3) showed absorption maxima at 646 nm with a shoulder at ca. 900 nm for 5 and at 658 and 888 nm for 7. The red-shift of 7 by ca. 12 nm relative to 5 reflects the distortion toward the trigonal-bipyramidal geometry of 7 in solution. Both complexes displayed irreversible redox behavior in DMF at I = 0.1 M tetra(n-butyl)ammonium tetrafluoroborate. The anodic and cathodic peak potentials obtained by cyclic voltammetry for 5 and 7 were -0.14 and -0.76 V for 5 and -0.17 and -0.80 for 7 vs Ag/AgCl. The cathodic potentials of copper(II) complexes were shifted toward the anodic direction by ca. 20-60 mV compared to the nonsubstituted 5-coordinate, [Cu(II)(H(-)(1)L(1))](+) complex, 16 (-0.82 V vs Ag/AgCl). The Cu(I) complexes (9and 10) are air-oxidized to the corresponding Cu(II) complexes, 5 and 7, respectively.

N-methyl threonine analogues of deglycobleomycin A2: synthesis and evaluation

The synthesis of 5 and its D-allo-threonine epimer 6 and the comparison of their DNA cleavage efficiency and selectivity with that of deglycobleomycin A2 (3) are detailed. The studies illustrate that N-methylation of the L-threonine subunit within deglycobleomycin A2 dramatically reduces the DNA cleavage efficiency (10-15-fold), weakens and nearly abolishes the inherent DNA cleavage selectivity, but has little effect on the inherent oxidation capabilities of the activated Fe(III) complexes. The results are consistent with a previously unrecognized prominent role for the threonine NH and the potential importance of a hydrogen bond to the Fe(III) hydroperoxide complex of bleomycin or a subsequent activated complex implicated in recent structural models.

Mechanism of site-selective DNA nicking by the hydrodioxyl (perhydroxyl) radical

In previous studies, the ability of the hydrodioxyl (perhydroxyl) radical [HOO., the conjugate acid of superoxide (O2.-] to "nick" DNA under biomimetic conditions was demonstrated, and a sequence selectivity was observed. A background level of nonspecific nicking also was noted. This paper provides support for 5'-hydrogen atom abstraction from the deoxyribose ring as the initial event in the sequence-selective nicking by 02.-/HOO.. Two experiments support the proposed mechanism. First, using a defined sequence 5'-32P-labeled restriction fragment as the DNA substrate, only free (unalkylated) 3'-phosphate is produced at the site of nicking. Second, using poly (dA).poly (T) as the substrate, furfural is formed in the reaction from deoxyribose ring breakdown. Both results are consistent with 5'-hydrogen atom abstraction for initiation of the site-selective nicking. Hydrogen atom abstraction at other sites of the deoxyribose ring and/or base oxidation and loss followed by strand scission likely are responsible for the nonspecific nicking. The 5'-abstraction mechanism contrasts to those elicited by other 02-derived and metal-associated oxidants, which may provide a biomarker for the reactivity of HOO. in vivo.

Synthesis and evaluation of deglycobleomycin A2 analogues containing a tertiary N-methyl amide and simple ester replacement for the L-histidine secondary amide: direct functional characterization of the requirement for secondary amide metal complexation

The synthesis and comparative examination of 3-5, analogues of deglycobleomycin A2 (2) which address the inferred importance of the L-histidine secondary amide directly, are detailed. The agent 3 lacks only the L-histidine beta-hydroxy group of deglycobleomycin A2 and the corresponding agents 4 and 5 incorporate a tertiary N-methyl amide and simple ester in place of the L-histidine secondary amide. The DNA cleavage properties of 3 proved essentially indistinguishable from those of deglycobleomycin A2 (2) confirming that the distinctions between bleomycin A2 (1) and deglycobleomycin (2) are due to the removal of the disaccharide and not the introduction of the L-histidine free beta-hydroxy group. The agents 4 and 5 containing a tertiary N-methyl amide and ester in place of the L-histidine secondary amide were found to cleave duplex DNA but to do so in a nonsequence selective fashion with a substantially reduced efficiency and a diminished double to single strand cleavage ratio that are only slightly greater than that of free iron itself. These latter observations establish the functional requirement for the L-histidine secondary amide and are consistent with the proposals that the L-histidine deprotonated secondary amide is required for functional metal chelation and activity.

Synthesis and evaluation of potential N pi and N sigma metal chelation sites within the beta-hydroxy-L-histidine subunit of bleomycin A2: functional characterization of imidazole N pi metal complexation

The synthesis and evaluation of 4 and 5, fully functionalized deglycobleomycin A2 (2) analogues incorporating an oxazole and a pyrrole in place of the beta-hydroxy-L-histidine imidazole, are detailed. The oxazole agent is only capable of Npi metal complexation through a form related to the N1-H imidazole tautomer of bleomycin A2 (1) while the pyrrole agent may potentially mimic the Nsigma metal complexation capabilities of the imidazole N3-H tautomer. Metal complexes (Fe-II, Fe-III) of 4 and 5 were found to cleave duplex DNA in the presence of O2 (Fe-II) or H2O2 (Fe-III). The oxazole agent 4 which is incapable of Nsigma metal chelation was found to behave analogous to, albeit slightly less effectively than, deglycobleomycin A2 resulting in the characteristic 5'-GC/5'-GT sequence selective cleavage of duplex DNA directly confirming that imidazole/oxazole Npi metal chelation is sufficient for functional reactivity. Importantly, the effective substitution of the oxazole O-1 for the histidine N-1 further illustrates that this group does not require deprotonation upon metal complexation, oxygen activation, or the ensuing oxidation reactions, that the functional bleomycin A2 tautomer is the imidazole N'-H tautomer, and that the imidazole N'-H functionality is not contributing to the polynucleotide recognition through H-bonding to the phosphate backbone or nucleotide bases. In contrast, the pyrrole agent 5 which is incapable of Npi metal chelation, but possesses the capabilities of functioning as a Nsigma metal donor was also found to cleave duplex DNA, but does so in a nonsequence selective fashion with a significantly reduced efficiency and a diminished double to single strand cleavage ratio both only slightly above that of background iron itself. These observations are analogous to those made with 3 which lacks the imidazole altogether and further support the observations that Nsigma coordination, not Npi coordination, of the imidazole is required for the functional activity of bleomycin A2.

Post-translational heterocyclic backbone modifications in the 43-peptide antibiotic microcin B17. Structure elucidation and NMR study of a 13C,15N-labelled gyrase inhibitor

Microcin B17 (McB17), the first known gyrase inhibitor of peptidic nature, is produced by ribosomal synthesis and post-translational modification of the 69-residue precursor protein by an Escherichia coli strain. To elucidate the chemical structure of the mature 43-residue peptide antibiotic, fermentation and purification protocols were established and optimized which allowed the isolation and purification of substantial amounts of highly pure McB17 (non-labelled, 15N-labelled and 13C/15N-labelled peptide. By ultraviolet-absorption spectroscopy. HPLC-electrospray mass spectrometry and GC-mass spectrometry, amino acid analysis, protein sequencing, and, in particular, multidimensional NMR, we could demonstrate and unequivocally prove that the enzymic modification of the precursor backbone at Gly-Cys and Gly-Ser segments leads to the formation of 2-aminomethylthiazole-4-carboxylic acid and 2-aminomethyloxazole-4-carboxylic acid, respectively. In addition, two bicyclic modifications 2-(2-aminomethyloxazolyl)thiazole-4-carboxylic acid and 2-(2-aminomethylthiazolyl)oxazole-4-carboxylic acid were found that consist of directly linked thiazole and oxazole rings derived from one Gly-Ser-Cys and one Gly-Cys-Ser segment. Analogous to the thiazole and oxazole rings found in antitumor peptides of microbial and marine origin, these heteroaromatic ring systems of McB17 presumably play an important role in its gyrase-inhibiting activity, e.g. interacting with the DNA to trap the covalent protein-DNA intermediate of the breakage-reunion reaction of the gyrase.

Analogue versus digital recognition of DNA by bleomycin: an effect of the carbohydrate moiety

We have sought to determine the influence of the carbohydrate moiety of the antitumour antibiotic bleomycin on the sequence-specific cleavage of DNA. Both bleomycin A2 and deglycobleomycin A2 produce different cleavage patterns with DNA in which the 2-amino group has been removed from guanine, added to adenine, or both, as well as on a designed DNA fragment containing a few defined cleavage sites. Although each drug cleaves DNA primarily at GpT and GpC sites, the cleavage at these sites is frequently found to be stronger with deglycobleomycin compared with bleomycin A2. Conversely, in most cases the cleavage at secondary sites, in particular at ApT steps, is significantly reduced or even abolished with deglycobleomycin. The results indicate that the gulose-mannose moiety of bleomycin A2 plays a significant role in the recognition of preferred nucleotide sequences and confirm the view that both secondary structure and interaction with guanine are involved in determining sequence-specific cleavage of DNA by bleomycin.

Synthesis of key analogs of bleomycin A2 that permit a systematic evaluation of the linker region: identification of an exceptionally prominent role for the L-threonine substituent

The synthesis of a full series of analogs 2b-k of deglycobleomycin A2 (2a) containing systematic variations in the linker domain of bleomycin A2 (1) is described. The agents 2b-k, which are not accessible through structural modification of 1 or 2a, constitute key substructure analogs incorporating deep-seated structural modifications in the linker domain capable of delineating the contribution of the individual backbone substituents to the DNA cleavage efficiency, characteristic DNA cleavage selectivity, and double strand to single strand DNA cleavage ratio. The comparative examination of the DNA cleavage properties of the Fe(II) and Fe(III) complexes of 2a-k upon activation by O2-thiol or H2O2, respectively, revealed several characteristic features and trends. First, none of the substituents affect the characteristic 5'-GC, 5'-GT > 5'-GA DNA cleavage selectivity of bleomycin A2. In contrast, an exceptionally prominent role for the L-threonine substituent and an important role for the C4-methyl substituent of the (2S,3S,4R)-4-amino-3-hydroxy-2-methylpentanoic acid subunit were observed on the DNA cleavage efficiency of the agents. Similarly, the L-threonine substituent was found to substantially increase the ratio of double strand to single strand DNA cleavage events (2-3 times). In a w794 DNA cleavage assay, shortening the linker region by two carbons resulted in an exceptionally large reduction in DNA cleavage efficiency (125 times) and provided an agent that was only 1.3 times more effective than Fe(III) indicating that this deep-seated modification essentially destroys the DNA cleavage capabilities of the agent. The L-threonine substituent contributes in an exceptional manner, and its removal resulted in a 25 times reduction in DNA cleavage efficiency. A substantial contribution was observed for the C4-methyl group on the 4-aminobutanoic acid subunit and its removal resulted in a 7 times reduction in DNA cleavage efficiency. Little effect for the C3-hydroxyl and C2-methyl substituents on the 4- aminobutanoic acid subunit was observed (0-2.5 times) and even their inversion of stereochemistry had little impact on DNA cleavage efficiency or selectivity. Notably, the magnitude of the previously unappreciated L-threonine substituent contribution to the DNA cleavage efficiency and on the ratio of double to single strand DNA cleavage events is the largest effect observed to date including the well recognized disaccharide potentiation (6 times) of the DNA cleavage properties. Consequently, the past role and relative importance of the L-threonine subunit and substituent has been underestimated. Moreover, the cumulative effect of the two important linker chain substituents clearly illustrate that the functional role of this domain is much more important than its simply serving as a linker.

Reactions of oxyl radicals with DNA

The importance of radical-induced damage to DNA is apparent from the ever-increasing number of publications in this area. This review focuses on the damage caused to DNA by reactive oxygen-centred radicals, however formed. These may be hydroxyl radicals, which arise either from the radiolysis of water by ionizing radiation (gamma-rays or X-rays), or from a purely chemical source. Alternatively, metal-bound oxyl radicals (M-O.) are also active intermediates in DNA-cleaving reactions and may be formed from synthetic compounds or from natural products such as bleomycin (BLM). Chemical mechanisms leading to the observed degradation products are covered in detail. The biological effects of some of the DNA base lesions formed are touched upon, concentrating on the molecular mechanisms behind the initial events that lead to mutagenesis.

Design, synthesis and sequence selective DNA cleavage of functional models of bleomycin--II. 1,2-trans-disubstituted cyclopropane units as novel linkers

The design and syntheses of functional models for bleomycin in which AMPHIS, a simplified model of the metal-chelating subunit of bleomycin is connected to distamycin analogs with a series of linkers, are described. Kinetic studies and DNA cleavage assay show that 1,2-trans-disubstituted cyclopropane units are the best linkers within this series. Study of selective DNA cleavage on high resolution polyacrylamide sequencing gels indicates that the linker modified hybrids generally cleave selectively at the 5' end of poly T sites and at the 3' end of poly A sites. Cleavage activity is enhanced for most of the compounds related to those with shorter linkers, previously reported, (Huang, L.; Quada, Jr J. C.; Lown, J. W. Bioconjugate Chem. 1995, 6, 21, Ref. 1) probably as a result of the linker allowing the active complex to approach the target deoxyribose more closely and efficiently. Certain of the compounds, ones containing a (S)-methyl in the linker and the (S,S)-cyclopropyl linker, exhibit unique cleavage sites, indicating that these linkers allow the hybrids to locate novel, individual DNA binding sites.