The antimalarial and cytotoxic drug cryptolepine intercalates into DNA at cytosine-cytosine sites.

Lisgarten, J.N., Coll, M., Portugal, J., Wright, Colin W., Aymami, J.

January 2001

No / Cryptolepine, a naturally occurring indoloquinoline alkaloid used as an antimalarial drug in Central and Western Africa, has been found to bind to DNA in a formerly unknown intercalation mode. Evidence from competition dialysis assays demonstrates that cryptolepine is able to bind CG-rich sequences containing nonalternating CC sites. Here we show that cryptolepine interacts with the CC sites of the DNA fragment d(CCTAGG)2 in a base-stacking intercalation mode.

Cryptolepine

Indoloquinoline alkaloid

Antimalarial drugs

DNA intercalation

X-ray crystallographic structure of the potent antiplasmodial compound 2,7-dibromocryptolepine acetic acid solvate.

Potter, B.S., Lisgarten, J.N., Pitts, J.E., Palmer, R.A., Wright, Colin W.

January 2008

No / The structure of 2,7-dibromocryptolepine acetic acid solvate, C16H11N2Br2 [1.5(C2H4O2)][C2H3O2 -] [0.5H2O], Mr = 460.17, has been determined from X-ray diffraction data. The crystals are monoclinic, space group P21/c with Z = 4 molecules per unit cell and a = 7.3243(3), b = 18.7804(6), c = 15.8306(7) A ° , b = 94.279(1) , Vc = 2171.5(2) A ° , crystal density Dc = 1.667 g/cm3. The structure was determined using direct methods and refined by full-matrix least-squares to a conventional R-index of 0.0496 for 4,908 reflections and 258 parameters. The cryptolepine nucleus of the 2,7-dibromocryptolepine molecule is highly planar and the two Br atoms are in this plane within 0.06 and 0.01 A ° , respectively. The crystal structure is maintained via hydrogen bonding between N(10) in the cryptolepine nucleus and the oxygen of one of the three solvated acetic acid molecules. The acetic acid molecules also form hydrogen bonded chains. Acetic acid B is deprotonated and its two C¿O bond lengths are equivalent, unlike those in A and C. Acetic acid C lies very close to a crystallographic centre of symmetry. To avoid overlap the two repeats cannot exist together and are subject to 50% statistical disorder. O(1C) of this methanol is furthest from the two-fold axis and its occupancy refines to a value of 1.0 and is assumed to exist alternately as a water oxygen hydrogen bonding to methanol O(1C) across the two-fold axis at a distance of 2.775 A ° .

Cryptolepine

Malaria

DNA intercalation

Crystal structure

Antiplasmodial

Low Temperature X-Ray Crystallographic Structure of the Antiplasmodial Compound 5-N-Hydroxyethanequindoline Hydrochloride 0.5CH3OH.

Hampson, Hannah C., Ho, Chung Y., Palmer, R.A., Potter, B.S., Helliwell, M., Wright, Colin W.

January 2011

No / The structure of 5-N-hydroxyethanequindoline hydrochloride methanolate, C17H15ON2 Cl·½CH3OH, M r = 314.78, has been determined from X-ray diffraction data. The crystals are monoclinic, space group C2/c, with Z = 8 molecules per unit cell and a = 18.179(11), b = 7.317(5), c = 24.125(15) Å, β = 110.155(10)°, V c = 3012(3) Å3, crystal density D c = 1.388 Mg m−3. The structure was solved by direct methods, and the asymmetric unit comprises the 5-N-hydroxyethanequindoline hydrochloride and ½CH3OH moiety. The methanol is unusually disordered over a twofold axis with the C atom slightly removed from the twofold axis. Restraints were applied to the bond lengths of the two components of the disordered CH3OH, and to the anisotropic thermal displacement parameters of the disordered CH3OH carbon atom. The heterocyclic quindoline ring system and the first C atom of the hydroxyethane side chain are planar within 0.02 Å, with the terminal C–OH atoms of the side chain significantly out of the plane. The crystal structure is maintained via three hydrogen bonds all involving the chlorine atom an oxygen in the hydroxyethane side chain, a nitrogen in the quindoline moiety and the methanol oxygen.

Antiplasmodial

Crystal structure

Cryptolepine

NMR

DNA intercalation

Binding studies of a sequence specific threading NDI intercalator

Holman, Garen Gilman

22 September 2011

A series of studies from our lab have investigated the threading polyintercalator approach to sequence specific DNA binding using a 1,4,5,8-naphthalene tetracarboxylic diimide (NDI) intercalating unit connected by flexible peptide linkers. Herein is a report of the sequence specificity, as well as a detailed kinetic analysis, of a threading NDI tetraintercalator. DNase I footprinting using two ~500 base pair DNA fragments containing one designed binding site for the tetraintercalator confirmed highly sequence specific binding. Kinetic analyses include 1H NMR, gel mobility-shift assays, and stopped-flow UV measurements to reveal a polyintercalation binding mode that demonstrates significant similarities between association rate profiles and rate constants for the tetraintercalator binding to its preferred versus a random oligonucleotide sequence. Sequence specificity was found to derive almost entirely from large differences in dissociation rates from the preferred versus random oligonucleotide sequences. Interestingly, the dissociation rate constant of the tetraintercalator complex dissociating from its preferred binding site was extremely slow, corresponding to a 16 day half-life at a benchmark 100 mM [Na+]. This dissociation result for the tetraintercalator is one of the longest bound half-lives yet measured, and to the best of our knowledge, the longest for a DNA binding small molecule. Such a long-lived complex raises the possibility of using threading polyintercalators to disrupt biological processes for extended periods. Current focus is given to deciphering a mechanism for the molecular recognition of the tetraintercalator preferred binding site within a long sequence of DNA. Initial DNase I footprinting results on an approximate 500mer DNA sequence containing three sequential preferred binding sites reveal that the tetraintercalator likely locates its designed binding site by a macro- or microscopic dissociation/re-association type of mechanism. Cooperativity is a possible ally to binding, leaving future studies to distinguish the mechanism for molecular recognition in a manner that is capable of circumventing cooperative binding. Taken together, the threading polyintercalation binding mode presents an interesting topology to sequence specific DNA binding. Extraordinarily long dissociation rates from preferred binding sites offers many future possibilities to disrupt biological processes in vivo. / text

DNA intercalation

Dissociation half-lives

Novel Acridine-Based Compounds That Exhibit an Anti-Pancreatic Cancer Activity Are Catalytic Inhibitors of Human Topoisomerase II

Oppegard, Lisa M., Ougolkov, Andrei V., Luchini, Doris N., Schoon, Renee A., Goodell, John R., Kaur, Harneet, Billadeau, Daniel D., Ferguson, David M., Hiasa, Hiroshi

14 January 2009

We have identified a small library of novel substituted 9-aminoacridine derivatives that inhibit cell proliferation of pancreatic cancer cell lines by inducing apoptosis [Goodell, J.R. et al., 2008. J. Med. Chem. 51, 179-182.]. To further investigate their antiproliferative activities, we have assessed the antiproliferative activity of these acridine-based compounds against several pancreatic cancer cell lines. All four compounds used in this study inhibited the proliferation of pancreatic cancer cell lines in vitro. In addition, we have employed a xenograft tumor model and found that these compounds also inhibit the proliferation of pancreatic cancer in vivo. In light of the potential importance of the anticancer activity of these acridine-based compounds, we have conducted a series of biochemical assays to determine the effect of these compounds on human topoisomerase II. Unlike amsacrine, these compounds do not poison topoisomerase II. Similar to amsacrine, however, these compounds intercalate into DNA in a way that they would alter the apparent topology of the DNA substrate. Thus, inhibition of the relaxation activity of topoisomerase II by these compounds has been reexamined using a DNA strand passage assay. We have found that these compounds, indeed, inhibit the catalytic activity of topoisomerase II. Thus, these novel acridine-based compounds with anti-pancreatic cancer activity are catalytic inhibitors, not poisons, of human topoisomerase II.

acridine derivative

anticancer drug

cancer

catalytic inhibitor

DNA intercalation

topoisomerase

Studies of Photoinduced DNA Damage by Phenanthrene Dihydrodioxin and Light-driven Electron Delocalization in Pyridinium Molecules

Tikhomirova, Anastasiia

06 August 2019

No description available.

Chemistry

Biochemistry

Physical Chemistry

Organic Chemistry

DNA damage

DNA binding

DNA intercalation

Reactive Oxygen Species

ROS

Photolysis

geminal diol

cyanine dye

pyridinium salts

pimerization

aerobic oxidation

photochemistry

organic chemistry

spectroscopy