Comparative binding studies on the interaction of the indoloquinoline alkaloid cryptolepine with the B and the non-canonical protonated form of DNA: A spectroscopic insight

Sequence-Specific Dual DNA Binding Modes and Cytotoxicities of N-6-Functionalized Norcryptotackieine Alkaloids

Norcryptotackieine (1a) belongs to the indoloquinoline class of alkaloids isolated from Cryptolepis sanguinolenta, a plant species that has been traditionally used as an antimalarial agent. Additional structural modifications of 1a can potentially enhance its therapeutic potency. Indoloquinolines such as cryptolepine, neocryptolepine, isocryptolepine, and neoisocryptolepine show restricted clinical applications owing to their cytotoxicity deriving from interactions with DNA. Here, we examined the effect of substitutions at the N-6 position of norcryptotackieine on the cytotoxicity, as well as structure-activity relationship studies pertaining to sequence specific DNA-binding affinities. The representative compound 6d binds DNA in a nonintercalative/pseudointercalative fashion, in addition to nonspecific stacking on DNA, in a sequence selective manner. The DNA-binding studies clearly establish the mechanism of DNA binding by N-6-substituted norcryptotackieines and neocryptolepine. The synthesized norcryptotackieines 6c,d and known indoloquinolines were screened on different cell lines (HEK293, OVCAR3, SKOV3, B16F10, and HeLa) to assess their cytotoxicity. Norcryptotackieine 6d (IC50 value of 3.1 μM) showed 2-fold less potency when compared to the natural indoloquinoline cryptolepine 1c (IC50 value of 1.64 μM) in OVCAR3 (ovarian adenocarcinoma) cell lines.

Targeting genomic DNAs and oligonucleotide on base specificity: A comparative spectroscopic, computational and in vitro study

Drug discovery in targeted nucleic acid therapeutics encompass several stages and rigorous challenges owing to less specificity of the DNA binders and high failure rate in different stages of clinical trials. In this perspective, we report newly synthesized ethyl 4-(pyrrolo[1,2-a]quinolin-4-yl)benzoate (PQN) with minor groove A-T base pair binding selectivity and encouraging in cell results. This pyrrolo quinolin derivative has shown excellent groove binding ability with three of our inspected genomic DNAs (cpDNA 73 % AT, ctDNA58% AT and mlDNA 28 % AT) with varying A-T and G-C content. Notably in spite of similar binding patterns PQN have strong binding preference with A-T rich groove of genomic cpDNA over the ctDNA and mlDNA. Spectroscopic experiments like steady state absorption and emission results have established the relative binding strengths (K_abs = 6.3 × 10⁵ M^-1, 5.6 × 10⁴ M^-1, 4.3 × 10⁴ M^-1 and K_emiss = 6.1 × 10⁵ M^-1, 5.7 × 10⁴ M^-1 and 3.5 × 10⁴ M^-1 for PQN-cpDNA, PQN-ctDNA and PQN-mlDNA respectively) whereas circular dichroism and thermal melting studies have unveiled the groove binding mechanism. Specific A-T base pair attachment with van der Waals interaction and quantitative hydrogen bonding assessment were characterized by computational modeling. In addition to genomic DNAs, preferential A-T base pair binding in minor groove was also observed with our designed and synthesized deca-nucleotide (primer sequences 5^/-GCGAATTCGC-3^/ and 3^/-CGCTTAAGCG-5^/). Cell viability assays (86.13 % in 6.58 μM and 84.01 % in 9.88 μM concentrations) and confocal microscopy revealed low cytotoxicity (IC₅₀ 25.86 μM) and efficient perinuclear localization of PQN. We propose PQN with excellent DNA-minor groove binding capacity and intracellular permeation properties, as a lead for further studies encompassing nucleic acid therapeutics.

Highly Antiproliferative Latonduine and Indolo[2,3-c]quinoline Derivatives: Complex Formation with Copper(II) Markedly Changes the Kinase Inhibitory Profile

A series of latonduine and indoloquinoline derivatives HL¹–HL⁸ and their copper(II) complexes (1–8) were synthesized and comprehensively characterized. The structures of five compounds (HL⁶, [CuCl(L¹)(DMF)]·DMF, [CuCl(L²)(CH₃OH)], [CuCl(L³)]·0.5H₂O, and [CuCl₂(H₂L⁵)]Cl·2DMF) were elucidated by single crystal X-ray diffraction. The copper(II) complexes revealed low micro- to sub-micromolar IC₅₀ values with promising selectivity toward human colon adenocarcinoma multidrug-resistant Colo320 cancer cells as compared to the doxorubicin-sensitive Colo205 cell line. The lead compounds HL⁴ and 4 as well as HL⁸ and 8 induced apoptosis efficiently in Colo320 cells. In addition, the copper(II) complexes had higher affinity to DNA than their metal-free ligands. HL⁸ showed selective inhibition for the PIM-1 enzyme, while 8 revealed strong inhibition of five other enzymes, i.e., SGK-1, PKA, CaMK-1, GSK3β, and MSK1, from a panel of 50 kinases. Furthermore, molecular modeling of the ligands and complexes showed a good fit to the binding pockets of these targets.