Chemically Modified Oligonucleotides: Synthesis, Physicochemical and Biochemical Properties of their Duplexes with DNA and RNA

Pradeepkumar, Pushpangadan Indira

January 2004

<p>This thesis is based on 9 papers dealing with the synthesis, physicochemical and biochemical properties of two types of chemically modified oligonucleotides which have the potential to down-regulate gene expression: (i) The first set is comprised of antisense oligonucleotides (AONs) conjugated with different chromophores of varying size, charge and π-electron density. Conjugation of the chromophores at the 3'- or 5'-end enhanced the target RNA binding affinity and RNase H recruitment capabilities compared to the native counterpart without changing the global helical conformation of their AON/RNA hybrid duplexes. The 3'-dipyridophenazine (DPPZ) has emerged as the most promising non-toxic chromophore in this series. (ii) The second set encompasses a new class of AONs containing <i>North</i>-<i>East</i> conformationally constrained 1',2'-oxetane-nucleosides. The introduction of oxetane-<b>T</b> and -<b>C</b> units imparts lowering of the T_m by ~ 6º and ~ 3 ºC/modification, respectively, of the AON/RNA hybrids, whereas the incorporation of the corresponding oxetane-<b>A</b> and-<b>G</b> units into AONs did not alter the thermostability in comparison with that of the native hybrid duplex. The oxetane-modified AONs have been found to possess enhanced serum stability compared to that of the native, whereas oxetane-<b>T</b> and -<b>C</b> containing AONs were more endonuclease-resistant than oxetane-<b>A</b> and-<b>G</b> modified AONs. All oxetane-modified mixmer AON/ RNA hybrid duplexes were, however, found to be excellent substrates for RNase H cleavage, which has been analyzed by Michaelis-Menten kinetics. The oxetane-modified mixmer AONs have shown effective down-regulation of the proto-oncogene c-myb mRNA in the K562 human leukemia cells, which was analyzed by QRT-PCR and Western Blot. Based on the amount of AON uptake after delivery, determined by slot blot, it was apparent that the oxetane-modified AONs are 5-6 times more effective antisense agents than the corresponding isosequential phosphorothioate analogues. The electrochemical assay based on sensitive nucleic acid mediated charge transport (CT) has revealed that the presence of oxetane-<b>T</b> unit causes more stacking perturbations in a DNA/DNA duplex than in a DNA/RNA duplex. </p>

Bioorganic chemistry

Antisense oligonucleotides

Dipyridophenazine

Oxetane

RNase H

Gene down-regulation

DNase 1

Charge transport

Bioorganisk kemi

Bioorganic chemistry

Bioorganisk kemi

Chemically Modified Oligonucleotides: Synthesis, Physicochemical and Biochemical Properties of their Duplexes with DNA and RNA

Pradeepkumar, Pushpangadan Indira

January 2004

This thesis is based on 9 papers dealing with the synthesis, physicochemical and biochemical properties of two types of chemically modified oligonucleotides which have the potential to down-regulate gene expression: (i) The first set is comprised of antisense oligonucleotides (AONs) conjugated with different chromophores of varying size, charge and π-electron density. Conjugation of the chromophores at the 3'- or 5'-end enhanced the target RNA binding affinity and RNase H recruitment capabilities compared to the native counterpart without changing the global helical conformation of their AON/RNA hybrid duplexes. The 3'-dipyridophenazine (DPPZ) has emerged as the most promising non-toxic chromophore in this series. (ii) The second set encompasses a new class of AONs containing North-East conformationally constrained 1',2'-oxetane-nucleosides. The introduction of oxetane-<b>T</b> and -<b>C</b> units imparts lowering of the Tm by ~ 6º and ~ 3 ºC/modification, respectively, of the AON/RNA hybrids, whereas the incorporation of the corresponding oxetane-<b>A</b> and-<b>G</b> units into AONs did not alter the thermostability in comparison with that of the native hybrid duplex. The oxetane-modified AONs have been found to possess enhanced serum stability compared to that of the native, whereas oxetane-<b>T</b> and -<b>C</b> containing AONs were more endonuclease-resistant than oxetane-<b>A</b> and-<b>G</b> modified AONs. All oxetane-modified mixmer AON/ RNA hybrid duplexes were, however, found to be excellent substrates for RNase H cleavage, which has been analyzed by Michaelis-Menten kinetics. The oxetane-modified mixmer AONs have shown effective down-regulation of the proto-oncogene c-myb mRNA in the K562 human leukemia cells, which was analyzed by QRT-PCR and Western Blot. Based on the amount of AON uptake after delivery, determined by slot blot, it was apparent that the oxetane-modified AONs are 5-6 times more effective antisense agents than the corresponding isosequential phosphorothioate analogues. The electrochemical assay based on sensitive nucleic acid mediated charge transport (CT) has revealed that the presence of oxetane-<b>T</b> unit causes more stacking perturbations in a DNA/DNA duplex than in a DNA/RNA duplex.

Bioorganic chemistry

Antisense oligonucleotides

Dipyridophenazine

Oxetane

RNase H

Gene down-regulation

DNase 1

Charge transport

Bioorganisk kemi

Bioorganic chemistry

Bioorganisk kemi

Studies on Photocytotoxic Iron(III) and Cobalt(III) Complexes Showing Structure-Activity Relationship

Saha, Sounik

January 2010

Photodynamic therapy(PDT) has recently emerged as a promising new non-invasive treatment modality for a large number of neoplastic and non-neoplastic lesions. Photoexcitation of a photosensitizing drug in the tumor tissue causes generation of reactive oxygen species which results in cell death. The current porphyrinic photosensitizers suffer a wide range of drawbacks leading to the development of the chemistry of alternative photosensitizing agents in PDT. Among them, the 4d and 5d transition metal-based photosensitizers have been explored extensively with the exception of the 3d metal complexes. The objective of this thesis work is to design and synthesize photoactive iron(III) abd cobalt(III) complexes and evalutate their photonuclease and photocytotoxic potential. Bioessential 3d metal ions provide an excellent platform for metal-based PDT drug designing as because of its varied spectral, magnetic and redox properties, with its complexes possessing rich photochemical behavior in aqueous and non-aqueous media. We have synthesized binary iron(III) complexes as netropsin mimics using amino acid Schiff bases derived from salicylaldehyde/napthaldehyde and arginine/lysine. The complexes were found to be good AT selective DNA binders and exhibited significant DNA photocleavage activity. To enhance the photodynamic potential, we further synthesized iron(III) complexes of phenolate-based ligand and planar phenanthroline bases. The DNA photocleavage activity of these complexes and their photocytotoxic potential in cancer models were studied. ROS generated by these complexes were found to induce apoptotic cell death. Ternary cobalt(III) complexes were synthesized to study the effect of the central metal atom. The diamagnetic cobalt(III) complexes were structurally dissimilar to their iron(III) analogues. Although the Co(III)/Co(II) redox couple is chemically and photochemically accessible but the Co(III)-dppz complex, unlike its iron(III)-dppz analogue, exhibited selective damage to hTSHR expressing cells but not in HeLa cells. A structure-activity relationship study on iron(III) phenolates having modified dppz ligands was carried out and it was found that electron donating group on the phenazine unit and an increase of the aromatic surface area largely improved the PDT efficiency. Finally, SMVT targeted iron(III) complexes with biotin as targeting moiety were synthesized and the in vitro efficacy of the complexes was tested in HepG2 cells over-expressing SMVTs and compared to HeLa amd HEK293 cells. The complexes exhibited higher phytocytotoxicity in HepG2 than in HeLa and cells and HEK293 cells. An endocytotic mode of uptake took place in HepG2 cells whereas in HEK293 cells, uptake is purely by diffusion. This is expected to reduce the side-effects and have less effect on cells with relatively less SMVTs. In summary, the present research work opens up novel strategies for the design and development of primarily iron-based photosensitizers for their potential applications in PDT with various targeting moieties.

Iron Complexes

Cancer Research

Malignant Tumour

Cobalt Complexes

DNA Cleavage

DNA Binding

Photocytotoxicity

Dipyridophenazine

Cobalt(III) Complexes

Iron(III) Complexes

Photodynamic Therapy (PDT)

Phenanthroline Bases

Bichemistry

Chemistry Of Ferrocene Conjugates Showing DNA Cleavage And Photocytotoxic Activity

Maity, Basudev

07 1900

Ferrocene is an important molecule in the field of chemical biology due to its stability, unique redox property and significant lipophilicity for better cellular delivery. The medicinal importance of ferrocene is well recognized after its successful incorporation into breast cancer drug tamoxifen and antimalarial drug chloroquin. Designing ferrocene conjugated transition metal complexes is an interesting area of research in the field of photodynamic therapy, a new modality of light activated cancer treatment. The objective of the present thesis work is to develop photoactive ferrocene conjugates showing DNA photocleavage and photocytotoxic activity. We have synthesized the ferrocene conjugated imidazophenanthroline derivative which exhibits visible light induced DNA photocleavage activity and photocytotoxicity in HeLa cell line. The corresponding phenyl analogue is found to be inactive. Polypyridyl platinum(II) complexes of ferrocenyl as well as phenyl moiety are prepared and studied their interactions with calf thymus DNA. The cytotoxicity of the complexes enhance significantly upon irradiation of UV-A light of 365 nm. To enhance the photodynamic potential and to understand the role of organometallic ferrocenyl moiety, ferrocene conjugated terpyridyl copper(II) complexes having planar phenanthroline bases are prepared. The interaction of these complexes with duplex DNA and their photo-induced DNA cleavage and anticancer activity in HeLa cancer cells are studied. The complexes are able to generate ROS in the presence of visible light which causes DNA damage as well as cell death. The importance of ferrocenyl moiety is evidenced from the less activity of the corresponding phenyl analogues complex. We have prepared copper(II) complexes of ferrocenyl methyl dipicolylamine ligand to understand the role of terpyridyl moiety. These complexes lacking any conjugation between the copper(II) and the ferrocenyl moiety are found to be less active compared to the terpyridyl conjugated system. The copper(II) complexes are found to show undesirable dark cytotoxicity in the presence of cellular thiols like GSH. To overcome the dark toxicity problem and to understand the mechanistic aspects of DNA photocleavage and photocytotoxicity, a series of binary ferrocene conjugated terpyridyl complexes of Fe(II), Co(II), Cu(II) and Zn(II) are prepared and their DNA photocleavage and anticancer activity studied. The zinc(II) complex having redox-active ferrocenyl moiety and redox-inactive zinc(II) center exhibits significant PDT effect with low dark toxicity compared to its copper(II) analogue. The ferrocenyl moiety plays an important role towards showing photocytotoxic activity since its phenyl analogue is inactive in nature. Finally, the present thesis work opens up a new strategy for designing and developing new ferrocene based metal complexes as novel photosensitizers for PDT applications.

Ferrocene

DNA Cleavage

Photocytotoxicity

Biochemistry

Ferrocene Conjugates

DNA Photocleavage

Terpyridyl Copper(II) Complexes

Platinum(II) Complexes

Ferrocenyl Terpyridine Complexes

Copper(II) Dipyridophenazine Complex

Toxicology