Sequence specificity, reactivity, and antitumor activity of DNA-alkylating pyrrole-imidazole diamides.

Three conjugates of imidazole (Im)-pyrrole (Py) diamide and a DNA-alkylating moiety derived from the antibiotic duocarmycin A were synthesized, and their sequence specificity, reactivity, and antitumor activity comparatively examined. Sequencing gel analysis indicated that ImPyDu (1) alkylates DNA at the 3' end of AT-rich sequences at micromolar concentration. ImPyDu86 (2) reacts with DNA at AT-rich sites together with dialkylation sites at micromolar concentration. ImPyLDu86 (3) efficiently alkylates dialkylation sites at nanomolar concentration. Average values of log IC(50) against a 39 cancer cell line panel of 1-3 were -4.59, -5.95, and -8.25, respectively. The differential growth inhibition pattern of 1-3 varied with relatively low correlation coefficients. Array-based gene expression monitoring was performed for 3 in a human lung cancer cell line. Substantial downregulation of expression was seen for genes involved in DNA damage response, transcription, and signal transduction.

Efficient DNA alkylation by a pyrrole-imidazole CBI conjugate with an indole linker: sequence-specific alkylation with nine-base-pair recognition.

Conjugates 7, 8, and 10 of N-methylpyrrole (Py)-N-methylimidazole (Im) polyamides and 1,2,9,9a-tetrahydrocyclopropa[1,2-c]benz[1,2-e]indol-4-one (CBI) with a 5-amino-1H-indole-2-carbonyl linker were synthesized by Fmoc solid-phase synthesis and a subsequent liquid-phase coupling procedure. The DNA alkylating abilities of conjugates 7, 8, 6b, and 10 were examined using Texas Red-labeled PCR fragments and high-resolution denaturing gel electrophoresis. CBI conjugates 7 and 8 exhibited highly efficient sequence-specific DNA alkylation comparable with previous CBI conjugates with a vinyl linker. In particular, conjugate 10, with a 10-ringed hairpin Py-Im polyamide, alkylated at the adenine of 5'-ACAAATCCA-3'. Introduction of an indole linker greatly facilitated the synthesis of sequence-specific alkylating Py-Im polyamides.

Specific adenine alkylation by pyrrole-imidazole CBI conjugates.

We examined DNA alkylation by pyrrole (Py)-imidazole (Im) hairpin polyamides, which possess 1,2,9,9a-tetrahydrocyclopropa[1,2-c]benz[1,2-e]indol-4-one (CBI) or cyclopropapyrroloindole (CPI) as DNA alkylating moieties. High-resolution denaturing gel electrophoresis revealed that alkylation by CBI conjugates 2 and 4 occurred specifically at adenines (A) in matched sequences, whereas CPI conjugates 1 and 3 alkylated both A and guanines (G) in matched sequences. The origin of the different reactivity of CBI and CPI conjugates is discussed in relation to the electrophilicity of the cyclopropane moiety. The high selectivity of the CBI conjugate gives additional sequence specificity relative to CPI conjugates that would be useful for the biological applications.

Molecular design of hairpin pyrrole-imidazole polyamides possessing sequence specific DNA alkylating moiety.

By conjugating pyrrole (Py)/imidazole (Im) hairpin polyamides with CBI, a stable alkylating moiety, we have developed a new type of DNA-sequence-specific alkylating agent. The sequence specificity and alkylation efficiency of the CBI conjugates were analyzed with high-resolution denaturing gel electrophoresis using linear 450- and 1000-bp DNA. The results demonstrate that CBI conjugates selectively alkylate adenine in specific sequences, whereas the previous type of alkylating polyamide, which contains segment A of DU-86, alkylates both adenine and guanine.

Molecular design of hairpin polyamide possessing sequence-specific alkylation activity.

A novel type of sequence specific hairpin polyamide alkylating agents were synthesized and their alkylation activities were evaluated on linear 450 bp DNA fragment. To optimize the design of hairpin polyamide CPI-conjugates, several structural analogues were prepared. Analysis using high resolution denaturing gel electrophoresis suggests that such subtle structural differences effect the sequence specificity of the polyamides.

Molecular design of alkylating pyrrole-imidazole polyamides with indole linker.

A series of novel DNA alkylating polyamide possessing indole linker was synthesized. The reactivities and specificities of these polyamides with double strand DNA were investigated by using high-resolution gel electrophoresis. The results revealed that the indole linker linked Py-Im polyamides have the high alkylating activities and sequence specificities comparable to vinyl linker linked Py-Im polyamides.

Molecular design of a pyrrole-imidazole hairpin polyamides for effective DNA alkylation.

New hairpin polyamide-CPI (CPI = cyclopropylpyrroloindole) conjugates, compounds 12-14, were synthesized and their DNA-alkylating activities compared with the previously prepared hairpin polyamide, compound 1, by high-resolution denaturing gel electrophoresis with 450 base pair (bp) DNA fragments and by HPLC product analysis of the synthetic decanucleotide. In accord with our previous results, alkylation by compound 1 occurred predominantly at the G moiety of the sequence 5'-AGTCAG-3' (site 3). However, compound 12, in which the structure of the alkylating moiety of compound 1 is replaced with segment A of duocarmycin A DU-86 (CPI), did not show any DNA alkylating activity. In clear contrast, the hairpin CPI conjugate 13, which differs from compound 1 in that it lacks one Py unit and possesses a vinyl linker, alkylated the A of 5'-AGTCAG-3' (site 3) efficiently at nanomolar concentrations. Alkylation by compound 14, which has a vinyl linker, occurred at the A of 5'-AGTCCA-3' (site 6) and at several minor alkylation sites, including mismatch alkylation at A of 5'-TCACAA-3' (site 2). The significantly different reactivity of the alkylating hairpin polyamides 1, 12, 13, and 14 was further confirmed by HPLC product analysis by using a synthetic decanucleotide. The results suggest that hairpin polyamide--CPI conjugate 13 alkylates effectively according to Dervan's pairing rule, and with a new mode of recognition in which the Im-vinyl linker (L) pair targets G-C base pairs. These results demonstrate that incorporation of the vinyl-linker pairing with Im dramatically improves the reactivity of hairpin polyamide--CPI conjugates.

Highly efficient sequence-specific DNA interstrand cross-linking by pyrrole/imidazole CPI conjugates.

We have developed a novel type of DNA interstrand cross-linking agent by synthesizing dimers of a pyrrole (Py)/imidazole (Im)-diamide-CPI conjugate, ImPyLDu86 (1), connected using seven different linkers. The tetramethylene linker compound, 7b, efficiently produces DNA interstrand cross-links at the nine-base-pair sequence, 5'-PyGGC(T/A)GCCPu-3', only in the presence of a partner triamide, ImImPy. For efficient cross-linking by 7b with ImImPy, one A.T base pair between two recognition sites was required to accommodate the linker region. Elimination of the A.T base pair and insertion of an additional A.T base pair and substitution with a G.C base pair significantly reduced the degree of cross-linking. The sequence specificity of the interstrand cross-linking by 7b was also examined in the presence of various triamides. The presence of ImImIm slightly reduced the formation of a cross-linked product compared to ImImPy. The mismatch partners, ImPyPy and PyImPy, did not produce an interstrand cross-link product with 7b, whereas ImPyPy and PyImPy induced efficient alkylation at their matching site with 7b. The interstrand cross-linking abilities of 7b were further examined using denaturing polyacrylamide gel electrophoresis with 5'-Texas Red-labeled 400- and 67-bp DNA fragments. The sequencing gel analysis of the 400-bp DNA fragment with ImImPy demonstrated that 7b alkylates several sites on the top and bottom strands, including one interstrand cross-linking match site, 5'-PyGGC(T/A)GCCPu-3'. To obtain direct evidence of interstrand cross-linkages on longer DNA fragments, a simple method using biotin-labeled complementary strands was developed, which produced a band corresponding to the interstrand cross-linked site on both top and bottom strands. Densitometric analysis indicated that the contribution of the interstrand cross-link in the observed alkylation bands was approximately 40%. This compound efficiently cross-linked both strands at the target sequence. The present system consisted of a 1:2 complex of the alkylating agent and its partner ImImPy and caused an interstrand cross-linking in a sequence-specific fashion according to the base-pair recognition rule of Py-Im polyamides.

C-H to N substitution dramatically alters the sequence-specific DNA alkylation, cytotoxicity, and expression of human cancer cell lines.

We designed and synthesized sequence-specific alkylating conjugates 1 and 2, which selectively alkylate matched sequences at nanomolar concentrations. Conjugates 1 and 2 differ only in that the C-H is substituted by an N in the second ring, which precisely recognizes and effectively alkylates DNA according to the recognition rule of Py-Im polyamides. We investigated sequence-specific DNA alkylation, cytotoxicity in 39 human cancer cell lines, and the effect on expression levels in cancer cell lines by Py-Im conjugates 1 and 2. The COMPARE analysis of the mean graphs showed that conjugates 1 and 2 did not correlate well with each other (r = 0.65) despite having a common DNA alkylating mechanism (purine N3 alkylation). Array-based gene expression analysis demonstrated that there are several oppositely regulated genes. The results suggest the intriguing possibility that DNA alkylating agents recognizing longer base-pair sequences may provide a promising approach for developing new types of antigene agents.

Sequence-specific gene silencing in mammalian cells by alkylating pyrrole-imidazole polyamides.

Gene silencing was examined by sequence-specific alkylation of DNA by N-methylpyrrole (Py)-N-methylimidazole (Im) hairpin polyamides. Polyamides ImImPyPygammaImImPyLDu86 (A) and ImImPyPygammaImPyPyLDu86 (B) selectively alkylated the coding regions of the renilla and firefly luciferases, respectively, according to the base pair recognition rule of Py-Im polyamides. Two different plasmids, encoding renilla luciferase and firefly luciferase, were used as vectors to examine the effect of alkylation on gene silencing. Transfection of the alkylated luciferase vectors-by polyamide A or B-into HeLa, 293, and NIH3T3 cells demonstrated that these sequence-specific DNA alkylations lead to selective silencing of gene expression. Next, the vectors were cotransfected into HeLa cells and the cells were treated with polyamide A or B. Selective reduction of luciferase activities was caused by both polyamides. On the basis of this sequence-specific alkylation and gene silencing activity, these alkylating Py-Im polyamides thus have potential as antitumor drugs to target specific gene expression in human cells.

Inhibition of transcription at a coding sequence by alkylating polyamide.

Transcription from DNA sequence-specifically alkylated by a hairpin polyamide (ImPyPy-gamma-ImPyLDu86, 1) was investigated. High-resolution polyacrylamide gel electrophoresis demonstrated that conjugate 1 alkylated a 993-bp DNA fragment, in accordance with the Py-Im recognition rule, predominantly at the one match site on the GFP-encoding strand and at four sites (I'-IV') on the noncoding strand. Alkylation of DNA inhibited the formation of full-length mRNA and caused the transcription of truncated mRNA. Polyacrylamide gel electrophoresis demonstrated that the length of the truncated mRNA was consistent with the alkylated site on the coding strand. Complete inhibition of full-length mRNA synthesis was observed in the presence of 50 nM 1. In clear contrast, the hydrolyzed derivative of 1, designated 2, produced no truncated mRNA, nor did it significantly retard transcription: >80% transcription of full-length mRNA was observed at 50 nM. These results clearly indicate that inhibition of transcription can be achieved with alkylating Py-Im polyamide even in the coding regions of genes.

Enantioselective DNA alkylation by a pyrrole-imidazole S-CBI conjugate.

Conjugates 12S and 12R of N-methylpyrrole (Py)-N-methylimidazole (Im) seven-ringed hairpin polyamide with both enantiomers of 1,2,9,9a-tetrahydrocyclopropa[1,2-c]benz[1,2-e]indol-4-one (CBI) were synthesized, and their DNA alkylating activity was examined. High-resolution denaturing gel electrophoresis revealed that 12S selectively and efficiently alkylated at one match sequence, 5'-TGACCA-3', in 450-bp DNA fragments. The selectivity and efficiency of the DNA alkylation by 12S were higher than those of the corresponding cyclopropapyrroloindole (CPI) conjugate, 11. In sharp contrast, another enantiomer, 12R, showed very weak DNA alkylating activity. Product analysis of the synthetic decanucleotide confirmed that the alkylating activity of 12S was comparable with 11 and that 12S had a significantly higher reactivity than 12R. The enantioselective reactivity of 12S and 12R is assumed to be due to the location of the alkylating cyclopropane ring of the CBI unit in the minor groove of the DNA duplex. Since the CBI unit can be synthesized from commercially available 1,3-naphthalenediol, the present results open up the possibility of large-scale synthesis of alkylating Py-Im polyamides for facilitating their use in future animal studies.

Regulation of gene expression by sequence-specific alkylating polyamide.

In order to investigate the inhibition of gene expression by a new type of hairpin polyamide-CPI conjugate 1, its ability to inhibit transcription in cell free system was investigated. Sequence-selective alkylation of double-stranded DNA by 1 was investigated by denaturing gel electrophoresis using 1000 bp DNA fragment which codes for green fluorescence protein (GFP) under the control of T7 promoter. Analysis of DNA sequence indicated that 1 alkylated predominantly at the site of 5'-AGTCA-3' in coding region of GFP. The transcript by T7 RNA polymerase using the alkylated DNA as a template was analyzed by PAGE. The results clearly indicate that 1 inhibits transcription by alkylation of coding region at a nanomolar concentration.