Development of 4,4'-dibromobinaphthalene analogues with potent photo-inducible DNA cross-linking capability and cytotoxicity towards breast MDA-MB 468 cancer cells.

Photoinduced DNA cross-linking process showed advantages of high spatio-temporal resolution and control. We have designed, synthesized, and characterized several 4,4'-dibromo binaphthalene analogues (1a-f) that can be activated by 350 nm irradiation to induce various DNA damage, including DNA interstrand cross-links (ICL) formation, strand cleavages, and alkaline labile DNA lesions. The degree and types of DNA damage induced by these compounds depend on the leaving groups of the substrates, pH value of the buffer solution, and DNA sequences. The DNA ICL products were produced from the carbocations formed via the oxidation of free radicals photo-generated from 1a-f. Most of these compounds alone exhibited minimum cytotoxicity towards cancer cells while 350 nm irradiation greatly improved their anticancer effects (up to 40-fold enhancement) because of photo-induced cellular DNA damage. This work provides guidance for further design of photo-inducible DNA cross-linking agents as potent photo-activated anticancer prodrugs with good control over toxicity and selectivity.

Photo-Reactivity of Binaphthalene Triphenylphosphonium Salts: DNA Interstrand Cross-Link Formation and Substituent Effects.

Five novel 1,1'-binaphthalene analogues 1a-1e with triphenylphosphonium (TPP+) salts as a leaving group have been synthesized and characterized as photo-activatable DNA alkylating agents. Phototriggered release of the TPP+ group from 1a-1e generated naphthalenylmethyl-free radicals that were spontaneously transformed to the corresponding cations directly producing DNA interstrand cross-link (ICL) formation via alkylation. The substituents at position 4 not only affect the efficiency of ICL formation but also influence the reaction rate for DNA cross-linking. Groups with small or medium size favor ICL formation, while a bulky substituent (e.g., phenyl group) prevents DNA interstrand cross-linking. DNA alkylation by the naphthalenylmethyl cations photo-generated from 1a-1e occurs at dG, dC, and dA, while interstrand cross-linking took place with dG/dC base pairs. The TPP+ salts (1a-1e) are cations with both lipophilic and hydrophilic properties, which have great potential for biological applications.

Design, Synthesis, and Characterization of Binaphthalene Precursors as Photoactivated DNA Interstrand Cross-Linkers.

Most recently, alkylation via photogenerated carbocations has been identified as a novel mechanism for photoinduced DNA interstrand cross-link (ICL) formation by bifunctional aryl compounds. However, most compounds showed a low efficiency for DNA cross-linking. Here, we have developed a series of new 1,1'-binaphthalene analogues that efficiently form DNA ICLs upon 350 nm irradiation via generated 2-naphthalenylmethyl cations. The DNA cross-linking efficiency depends on the substituents at position 4 of the naphthalene moiety as well as the leaving groups. Compounds with NO2, Ph, H, Br, or OMe substituents led to 2-4 times higher DNA ICL yields than those with a boronate ester group. Compounds with trimethylammonium salt as a leaving group showed slightly better cross-linking efficiency than those with bromo as a leaving group. Some of these compounds showed a better cross-linking efficiency than that of traditional alkylating agents, such as nitrogen mustard analogues or quinone methide precursors. These highly efficient photoactivated carbocation precursors allow determination and characterization of the adducts formed between the photogenerated naphthalenyl cations and four natural nucleosides, indicating that the alkylation sites for these naphthalene analogues are dG, dA, and dC.

Photoinduced DNA Interstrand Cross-Link Formation by Naphthalene Boronates via a Carbocation.

Most photoinduced DNA cross-link formation by a bifunctional aryl derivative is through a bisquinone methide. DNA cross-linking via a bisarylcarbocation remains a less explored area. We designed and synthesized a series of naphthalene boronates that produce DNA interstrand cross-links via a carbocation upon UV irradiation. A free radical was generated from the naphthalene boronates with 350 nm irradiation and further converted to a carbocation by electron transfer. The activation mechanism was determined using the orthogonal traps, 2,2,6,6-tetramethylpiperidin-1-oxyl (TEMPO) and methoxyamine that react with either the free radical or the carbocation but not both. This represents a novel example of photoinduced DNA cross-link formation via carbocations generated from a bisaryl derivative. This work provides information useful for the design of novel photoactivated DNA cross-linking agents.

Chiral surfactant-type catalyst: enantioselective reduction of long-chain aliphatic ketoesters in water.

A series of amphiphilic ligands were designed and synthesized. The rhodium complexes with the ligands were applied to the asymmetric transfer hydrogenation of broad range of long-chained aliphatic ketoesters in neat water. Quantitative conversion and excellent enantioselectivity (up to 99% ee) was observed for α-, ß-, γ-, δ- and ε-ketoesters as well as for α- and ß-acyloxyketone using chiral surfactant-type catalyst 2. The CH/π interaction and the strong hydrophobic interaction of long aliphatic chains between the catalyst and the substrate in the metallomicelle core played a key role in the catalytic transition state. Synergistic effects between the metal-catalyzed site and the hydrophobic microenvironment of the core in the micelle contributed to high stereoselectivity.

Hydrogen peroxide activated quinone methide precursors with enhanced DNA cross-linking capability and cytotoxicity towards cancer cells.

Quinone methide (QM) formation induced by endogenously generated H2O2 is attractive for biological and biomedical applications. To overcome current limitations due to low biological activity of H2O2-activated QM precursors, we are introducing herein several new arylboronates with electron donating substituents at different positions of benzene ring and/or different neutral leaving groups. The reaction rate of the arylboronate esters with H2O2 and subsequent bisquinone methides formation and DNA cross-linking was accelerated with the application of Br as a leaving group instead of acetoxy groups. Additionally, a donating group placed meta to the nascent exo-methylene group of the quinone methide greatly improves H2O2-induced DNA interstrand cross-link formation as well as enhances the cellular activity. Multiple donating groups decrease the stability and DNA cross-linking capability, which lead to low cellular activity. A cell-based screen demonstrated that compounds 2a and 5a with a OMe or OH group dramatically inhibited the growth of various tissue-derived cancer cells while normal cells were less affected. Induction of H2AX phosphorylation by these compounds in CLL lymphocytes provide evidence for a correlation between cell death and DNA damage. The compounds presented herein showed potent anticancer activities and selectivity, which represent a novel scaffold for anticancer drug development.

Photochemical Generation of Benzyl Cations That Selectively Cross-Link Guanine and Cytosine in DNA.

UV irradiation of several aryl boronates efficiently produced bifunctional benzyl cations that selectively form guanine-cytosine cross-links in DNA. Photoinduced homolysis of the C-Br bond took place with the aryl boronate bromides 3a and 4a, generating free radicals that were oxidized to benzyl cations via electron transfer. However, photoirradiation of the quaternary ammonium salts 3b and 4b led to heterolysis of C-N bond, directly producing benzyl cations. The electron-donating group in the aromatic ring greatly enhanced cross-linking efficiency.