Deglycobleomycin A6 analogues modified in the methylvalerate moiety

Previous studies have indicated that the methylvalerate subunit of bleomycin (BLM) plays an important role in facilitating DNA cleavage by BLM and deglycoBLM. Eleven methylvalerate analogues have been synthesized and incorporated into deglycoBLM congeners by the use of solid-phase synthesis. The effect of the valerate moiety in the deglycoBLM analogues has been studied by comparison with the parent deglycoBLM A(5) using supercoiled DNA relaxation and sequence-selective DNA cleavage assays. All of the deglycoBLM analogues were found to effect the relaxation of the plasmid DNA. Those analogues having aromatic C4-substituents exhibited cleavage efficiency comparable to that of deglycoBLM A(5). Some, but not all, of the deglycoBLM analogues were also capable of mediating sequence-selective DNA cleavage.     

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.     

Development of new simple molecular probes of DNA bulged structures

NCSi-gb is a neocarzinostatin chromophore (NCS-chrom) metabolite which binds strongly to certain two-base DNA bulges. Compared with previously reported NCSi-gb analogues, a new analogue with a different aminoglycoside position was synthesized, and it showed strong fluorescence and improved binding and sequence selectivity to DNA bulges. The N-dimethylated form of this analogue had a similar binding pattern, and it competitively inhibited bulge-specific cleavage by NCS-chrom.     

Structural characterization of beta-cardiac myosin subfragment 1 in solution

beta-cardiac myosin subfragment 1 (betaS1) tertiary structure and dynamics were characterized with proteolytic digestion, nucleotide analogue trapping kinetics, and intrinsic fluorescence changes accompanying nucleotide binding. Proteolysis of betaS1 produces the 25, 50, and 20 kDa fragments and a new cut within the 50-kDa fragment at Arg369. F-actin inhibits cleavage of the 50-kDa fragment and fails to inhibit cleavage at the 50/20 kDa junction, suggesting betaS1 presents an actoS1 conformation fundamentally different from skeletal S1. Time-dependent changes in Mg(2+)-ATPase accompanying proteolysis identifies cleavage points that lie within the energy transduction pathway. The nucleotide analogue trapping kinetics reveal the presence of a reversible weakly actin attached state. Comparison of nucleotide analogue induced betaS1 structures with the transient structures occurring during ATPase indicates analogue induced and transient structures are in a one-to-one correspondence. Tryptophan fluorescence enhancement accompanies the binding or trapping of nucleotide or nucleotide analogues. Isolation of Trp508 fluorescence shows it is an ATP-sensitive tryptophan and that its vicinity changes conformation sequentially with the transient intermediates accompanying ATPase. These studies elucidate energy transduction and suggest how mutations of betaS1 implicated in disease might undermine function, stability, or efficiency.     

Synthesis of a dA-dT base pair analogue and its effects on DNA-ligand binding

Two nucleoside derivatives containing the base analogues 3-deazaadenine and 3-methyl-2-pyridone have been prepared as analogues of dA and dT, respectively. After conversion into the appropriately protected phosphoramidites, DNA sequences were prepared with site-specifically placed analogues. When present in a duplex DNA sequence, the analogues result in the deletion of one or both of the hydrogen bonding functional groups (the N3-nitrogen of dA and the O2-carbonyl of dT) present in the minor groove. Binding by two ligands, 4',6-diamidine-2-phenyl indole (DAPI) and Hoechst 33258 in the minor groove has been probed using a variety of DNA sequences. These sequences contain a d(GAATTC)2 core with analogue nucleosides substituted for one or more of the dA and dT residues. DAPI bound strongly to any sequence that contained both O2-carbonyls of the central two dT residues. The presence of a dc3A residue did in some cases enhance binding. With one of the central O2-carbonyls deleted, the binding was noticeably reduced, and with both absent, no significant binding could be detected. Similar although less dramatic results were observed with Hoechst 33258 binding to analogue sequences.     

Heparin enhances the furin cleavage of HIV-1 gp160 peptides

Infectious HIV-1 requires gp160 cleavage by furin at the REKR511 downward arrow motif (site1) into the gp120/gp41 complex, whereas the KAKR503 (site2) sequence remains uncleaved. We synthesized 41mer and 51mer peptides, comprising site1 and site2, to study their conformation and in vitro furin processing. We found that, while the previously reported 19mer and 13mer analogues represent excellent in vitro furin substrates, the present extended sequences require heparin for optimal processing. Our data support the hypothesis of a direct binding of heparin with site1 and site2, allowing selective exposure/accessibility of the REKR sequence, which is only then optimally cleaved by furin.     

Inhibition of eukaryotic translation by analogues of messenger RNA 5'-cap: chemical and biological consequences of 5'-phosphate modifications of 7-methylguanosine 5'-monophosphate

New analogues of 7-methylguanosine 5'-monophosphate (m7GMP) were synthesized with modified 5'-phosphate moieties by replacement of -O with -H, -CH3, or -NH2. Additional analogues were synthesized with 8-methyl- or 8-aminoguanine base substitutions or ring-opened ribose (2',3'-diol). These compounds were analyzed by 1H and 31P NMR for solution conformation. In addition, they were also analyzed for biological activity as analogues of mRNA 5'-caps by competition as inhibitors of translation in reticulocyte lysate. Substitution of oxygen on the 5'-monophosphate moiety by -H and -CH3 diminished the activity of the cap analogue as a competitive inhibitor; however, replacement by -NH2 did not diminish the activity of the analogue as an inhibitor. It was inferred from this result that cap binding proteins require a hydrogen bond acceptor as opposed to having an exclusive requirement for a second anionic group on the alpha-phosphate moiety. Inhibition results obtained with C8-substituted m7GMP analogues indicated that the 8-amino derivative was a better inhibitor than the 8-methyl derivative of m7GMP. The former is primarily anti whereas the latter is primarily syn with respect to glycosidic bond conformation. This result further supports the model that the anti conformation is the preferred form of the cap structure for interaction with cap binding proteins. The 2',3'-diol derivative of m7GMP was inactive as an inhibitor of translation.     

Solution structure of a novel ETB receptor selective agonist ET1-21 [Cys(Acm)1,15, Aib3,11, Leu7] by nuclear magnetic resonance spectroscopy and molecular modelling.

The solution structure of a biologically active modified linear endothelin-1 analogue, ET1-21[Cys(Acm)1,15, Aib3,11, Leu7], has been determined for the first time by two-dimensional nuclear magnetic resonance spectroscopy in a methanol-d3/water solvent mixture. Out of approximately one hundred linear peptide analogues tested by biological assay, this peptide, together with a dozen others, showed significant ETB selective agonist activity. Here we report the solution structure of an ETB selective agonist of a full-length, synthetic linear endothelin analogue. The calculated structures indicate that the peptide adopts an alpha-helical conformation between residues Ser5-His16, whilst both N- and C-termini show no preferred conformation. These results suggest that the disulphide bridges normally associated with endothelin and sarafotoxin peptides may not necessarily be important for either ETB receptor binding activity or the formation of a helical conformation in solution.     

Photoactivated DNA cleavage by compounds structurally related to the bithiazole moiety of bleomycin.

The syntheses of several novel halogenated bithiazoles structurally related to the bithiazole moiety of bleomycin A(5) are described. Also described is the ability of these compounds to mediate photoactivated DNA cleavage. Chlorinated bithiazole analogues were shown to be much more active than an analogous brominated derivative. DNA strand scission activity was strictly light dependent and was accompanied by dechlorination of the bithiazole nucleus, apparently in a stoichiometric fashion. Inhibition of DNA cleavage in the presence of DMSO, as well as photoaddition to 1-octene by both brominated and chlorinated bithiazole derivatives, suggest strongly that the initial step in photoactivated DNA cleavage involves homolysis of the thiazole carbon-halogen bond. The chlorinated bithiazoles were found to mediate sequence selective cleavage of a (32)P-end labeled DNA, although the selectivity observed was not the same as that of bleomycin itself. The implications of this observation are discussed.     

Ultraviolet light-induced cleavage of DNA in the presence of iodoHoechst 33258: the sequence specificity of the reaction.

IodoHoechst 33258 sensitizes DNA to cleavage by near ultraviolet light (UV-A). Following an earlier study which showed that the UV-induced cleavage is at discrete locations corresponding to the ligand binding sites, this paper reports a more extensive analysis of the sequence specificity of cleavage. The experiments involved use of double-stranded DNA synthesised on primed M13 templates. Analysis of cleavage in a 280bp sequence in M13mp18 and a 310bp sequence in three M13mp9 clones ('alpha-32', 'alpha-82' and 'alpha-22') derived from human alpha-DNA, showed that for all of the twenty-nine strong and very strong damage sites, cleavage was at the 3' end of a run of three or more consecutive AT base pairs. The extent of cleavage was higher for sites with consecutive Ts than for consecutive As, and greatest for the sequence cTTTTca. Comparison of three closely-related alpha-DNA clones enabled assessment of single bp changes and essentially confirmed the results of detailed analysis of binding cleavage sites in mp18 and alpha-32. Decreasing the input ratio of iodoHoechst/per bp DNA from 0.13 to 0.013 altered the sequence specificity, and sites possessing only three consecutive AT bps were generally not cleaved. The contributions of both the strength of ligand binding and the efficiency of photolytic cleavage to the overall extent of cleavage by UV/iodoHoechst are discussed, in view of the potential utility of the ligand as a probe of DNA conformation.     

DNA sequence recognition by under-methylated analogues of triostin A.

Two new analogues of TANDEM (des-N-tetramethyl triostin A) have been synthesised in an effort to elucidate the molecular basis of DNA nucleotide sequence recognition in this series of compounds. Their binding preferences have been investigated by DNAase I footprinting and differential inhibition of restriction nuclease attack. The presence of a single N-methyl group on only one valine residue (in [N-MeVal4] TANDEM) abolishes the ability to recognise DNA, presumably because this antibiotic analogue has suffered an unfavourable conformational change in the depsipeptide ring. A bis-methylated analogue, [N-MeCys3, N-MeCys7]TANDEM, was found to interact quite strongly with DNA and afforded binding sites, rich in AT residues, identical to those of TANDEM. Footprinting with various DNA fragments of known sequence showed that this analogue recognises sequences containing the dinucleotide TpA, although we cannot exclude the possibility that it binds to ApT as well. [N-MeCys3, N-MeCys7]TANDEM inhibits cutting by RsaI, a restriction enzyme that recognises GTAC but not by Sau3AI which recognises GATC. This provides further supportive evidence that the ligand (and, by extension, TANDEM itself) prefers binding to sequences containing the dinucleotide step TpA.     

Sequence-specific base pair mimics are efficient topoisomerase IB inhibitors

Topoisomerase IB controls DNA topology by cleaving DNA transiently. This property is used by inhibitors, such as camptothecin, that stabilize, by inhibiting the religation step, the cleavage complex, in which the enzyme is covalently attached to the 3'-phosphate of the cleaved DNA strand. These drugs are used in clinics as antitumor agents. Because three-dimensional structural studies have shown that camptothecin derivatives act as base pair mimics and intercalate between two base pairs in the ternary DNA-topoisomerase-inhibitor complex, we hypothesized that base pairs mimics could act like campthotecin and inhibit the religation reaction after the formation of the topoisomerase I-DNA cleavage complex. We show here that three base pair mimics, nucleobases analogues of the aminophenyl-thiazole family, once targeted specifically to a DNA sequence were potent topoisomerase IB inhibitors. The targeting was achieved through covalent linkage to a sequence-specific DNA ligand, a triplex-forming oligonucleotide, and was necessary to position and keep the nucleobase analogue in the cleavage complex. In the absence of triplex formation, only a weak binding to the DNA and topoisomerase I-mediated DNA cleavage was observed. The three compounds were equally active once conjugated, implying that the intercalation of the nucleobase upon triplex formation is the essential feature for the inhibition activity.     

Intercalative and nonintercalative binding of large cationic porphyrin ligands to calf thymus DNA

The large meso-substituted porphine, meso-tetra(4-N-methylpyridyl)porphine has been identified as a DNA-interactive ligand with a capacity for intercalation (1,2). Subsequently, the 2-N-methyl, 3-N-methyl and N-trimethylanilinium analogues of this porphyrin intercalator have been obtained for physico-chemical analyses (absorption spectroscopy, viscometry, circular dichroism, unwinding of supercoiled DNA). In this paper we discuss the factors affecting the character of porphyrin binding (intercalative, as is the case for the 4-N-methyl and 3-N-methyl porphines, versus non-intercalative, as is the case for the 2-N-methyl and N-trimethylanilinium porphines) and the impact that porphyrins' binding has upon the structure of DNA. The molecular conformation of the porphyrin ligand varies slightly within this series so that the ability of a given porphyrin to intercalate may be correlated with the arrangement of charged groups, the planarity of the porphine ring and the effective width of the individual molecules. The results from these studies indicate that sequence selective binding occurs within a small aperture of solution conditions.     

DNA recognition of base analogue and chemically modified substrates by the TaqI restriction endonuclease.

It has been proposed that protein-DNA recognition is mediated via specific hydrogen bond, hydrophobic, and/or electrostatic interactions between the protein and DNA surfaces. We have attempted to map and quantitate the energies of these interactions for the TaqI endonuclease by constructing substrates substituted with base or phosphate analogues that either remove or sterically obstruct particular functional groups in the canonical TCGA sequence. The DNA backbone was also modified using a chemical approach (phosphate ethylation) which identified several phosphates in the recognition sequence essential for cleavage. The base analogues, N6-methyl-A, N7-deaza-A, N7-deaza-G, inosine, N4-methyl-C, 5-methyl-C, uracil, 5-bromo-U, and the phosphate analogues, alpha-thio-A, alpha-thio-G, alpha-thio-T, alpha-thio-A, were substituted for their corresponding unmodified counterpart in one strand of the TCGA duplex. The effects of these analogues were monitored by measuring the steady state (Km, kcat) and single-turnover (kst) kinetic constants. Only the N6-methyl-A-substituted DNA, which mimics in vivo methylation, was unreactive while the remaining analogue substitutions exhibited Michaelis-Menten kinetics. In general, the Km was either unchanged or lowered by the analogue substitutions. In contrast, many of the analogues severely reduced kcat, suggesting the modified functional groups served mainly to destabilize the transition state. Single-turnover measurements paralleled the kcat results, pointing to the N7 and N6 of A, the N7 of G, and one of the nonbridging oxygens 3' to T as putative contacts made in achieving the transition state. Substrates with double substitutions displayed simple additivity of delta delta G" implying that these changes behaved independently. The unmodified strand in 10 out of 12 hemisubstituted substrates had a normal kst value suggesting that a particular cleavage center is controlled predominantly by recognition of determinants on the same strand as the scissile bond. These results are discussed in relation to base analogue work from the EcoRI, RsrI, and EcoRV restriction endonucleases.     

Recognition of single-stranded nucleic acids by small-molecule splicing modulators

Risdiplam is the first approved small-molecule splicing modulator for the treatment of spinal muscular atrophy (SMA). Previous studies demonstrated that risdiplam analogues have two separate binding sites in exon 7 of the SMN2 pre-mRNA: (i) the 5′-splice site and (ii) an upstream purine (GA)-rich binding site. Importantly, the sequence of this GA-rich binding site significantly enhanced the potency of risdiplam analogues. In this report, we unambiguously determined that a known risdiplam analogue, SMN-C2, binds to single-stranded GA-rich RNA in a sequence-specific manner. The minimum required binding sequence for SMN-C2 was identified as GAAGGAAGG. We performed all-atom simulations using a robust Gaussian accelerated molecular dynamics (GaMD) method, which captured spontaneous binding of a risdiplam analogue to the target nucleic acids. We uncovered, for the first time, a ligand-binding pocket formed by two sequential GAAG loop-like structures. The simulation findings were highly consistent with experimental data obtained from saturation transfer difference (STD) NMR and structure-affinity-relationship studies of the risdiplam analogues. Together, these studies illuminate us to understand the molecular basis of single-stranded purine-rich RNA recognition by small-molecule splicing modulators with an unprecedented binding mode.     

The genome-wide sequence specificity of DNA cleavage by bleomycin analogues in human cells

Bleomycin (BLM) is a cancer chemotherapeutic agent that cleaves cellular DNA at specific sequences. Using next-generation Illumina sequencing, the genome-wide sequence specificity of DNA cleavage by two BLM analogues, 6′-deoxy-BLM Z and zorbamycin (ZBM), was determined in human HeLa cells and compared with BLM. Over 200 million double-strand breaks were examined for each sample, and the 50,000 highest intensity cleavage sites were analysed. It was found that the DNA sequence specificity of the BLM analogues in human cells was different to BLM, especially at the cleavage site (position “0”) and the “+1” position. In human cells, the 6′-deoxy-BLM Z had a preference for 5′-GTGY*MC (where * is the cleavage site, Y is C or T, M is A or C); it was 5′-GTGY*MCA for ZBM; and 5′-GTGT*AC for BLM. With cellular DNA, the highest ranked tetranucleotides were 5′-TGC*C and 5′-TGT*A for 6′-deoxy-BLM Z; 5′-TGC*C, 5′-TGT*A and 5′-TGC*A for ZBM; and 5′-TGT*A for BLM. In purified human genomic DNA, the DNA sequence preference was 5′-TGT*A for 6′-deoxy-BLM, 5′-RTGY*AYR (where R is G or A) for ZBM, and 5′-TGT*A for BLM. Thus, the sequence specificity of the BLM analogue, 6′-deoxy-BLM Z, was similar to BLM in purified human DNA, while ZBM was different.     

Zorbamycin has a different DNA sequence selectivity compared with bleomycin and analogues

Bleomycin (BLM) is used clinically in combination with a number of other agents for the treatment of several types of tumours. Members of the BLM family of drugs include zorbamycin (ZBM), phleomycin D1, BLM A2 and BLM B2. By manipulating the BLM biosynthetic machinery, we have produced two new BLM analogues, BLM Z and 6′-deoxy-BLM Z, with the latter exhibiting significantly improved DNA cleavage activity. Here we determined the DNA sequence specificity of BLM Z, 6′-deoxy-BLM Z and ZBM, in comparison with BLM, with high precision using purified plasmid DNA and our recently developed technique. It was found that ZBM had a different DNA sequence specificity compared with BLM and the BLM analogues. While BLM and the BLM analogues showed a similar DNA sequence specificity, with TGTA sequences as the main site of cleavage, ZBM exhibited a distinct DNA sequence specificity, with both TGTA and TGTG as the predominant cleavage sites. These differences in DNA sequence specificity are discussed in relation to the structures of ZBM, BLM and the BLM analogues. Our findings support the strategy of manipulating the BLM biosynthetic machinery for the production of novel BLM analogues, difficult to prepare by total synthesis; some of which could have beneficial cancer chemotherapeutic properties.     

Modeling active RNA structures using the intersection of conformational space: application to the lead-activated ribozyme.

The Pb2+ cleavage of a specific phosphodiester bond in yeast tRNA(Phe) is the classical model of metal-assisted RNA catalysis. In vitro selection experiments have identified a tRNA(Phe) variant, the leadzyme, that is very active in cleavage by Pb2+. We present here a three-dimensional modeling protocol that was used to propose a structure for this ribozyme, and is based on the computation of the intersection of conformational space of sequence variants and the use of chemical modification data. Sequence and secondary structure data were used in a first round of computer modeling that allowed identification of conformations compatible with all known leadzyme variants. Common conformations were then tested experimentally by evaluating the activity of analogues containing modified nucleotides in the catalytic core. These experiments led to a new structural hypothesis that was tested in a second round of computer modeling. The resulting proposal for the active conformation of the leadzyme is consistent with all known structural data. The final model suggests an in-line SN2 attack mechanism and predicts two Pb2+ binding sites. The protocol presented here is generally applicable in modeling RNAs whenever the catalytic or binding activity of structural analogues is known.     

In vitro preferential topoisomerization of bent DNA.

The steps of the topoisomerization reaction by calf thymus DNA topoisomerase I on a DNA domain containing an intrinsically bent DNA sequence have been analyzed. High preferentiality of binding, cleavage and topoisomerization on the bent segment relative to the rest of the DNA domain was observed. These studies show the importance of the local DNA conformation in the reaction of eukaryotic DNA topoisomerase I and the interest of the use of this enzyme as a tool for the analysis of DNA conformation and DNA dynamics.     

RecA protein-promoted cleavage of LexA repressor in the presence of ADP and structural analogues of inorganic phosphate, the fluoride complexes of aluminum and beryllium

Complexes formed from A13+ or Be2+ and fluoride inhibit the single-stranded DNA-dependent ATPase activity of RecA protein. In contrast, poly(dT)-RecA-ADP complexes, which are inactive for cleavage of LexA protein, become fully active in the presence of AlF4- or BeF3- ions. These data suggest that fluoride complexes of aluminum and beryllium (called herein X) convert RecA-ADP complexes, which bind weakly to single-stranded DNA, into RecA-ADP-X complexes, which bind tightly to single-stranded DNA, the ADP-X moiety behaving as a nonhydrolyzable analogue of ATP. We propose that AlF4- and BeF3- ions act as analogues of inorganic phosphate by binding to the site of the gamma-phosphate of ATP on RecA-ADP complexes, hence mimicking the single-stranded DNA-RecA-ADP-Pi transition state. We conclude that the elementary reaction that switches RecA protein from a high affinity single-stranded DNA binding state to a low affinity single-stranded DNA binding state is not ATP hydrolysis per se but Pi release.