Synthesis of Hemiprotonic Phenanthroline-Phenanthroline+ Compounds with both Antitumor and Antimicrobial Activity

Hemiprotonic ph-ph+ with two targets inhibits metastatic breast cancer and concurrent candidiasis

Concurrent infection in breast cancer patients is the direct cause of the high mortality rate of the disease. However, there is no available method to increase the survival rate until now. To address the problem, we propose one drug with two target strategy to treat the refractory disease. A small chemical, ph-ph+, was attempted to be used in the study to explore the feasibility of the approach in anticancer and antifungus at the same time. The results showed that ph-ph+ could prevent the proliferation and metastasis of breast cancer cells, and kill C. albicans simultaneously. The molecular mechanism was associated with the activation of an evolutionarily conserved protease CLpP in the cancer and C. albicans cells. Also, the signaling pathway mediated by PLAGL2 that highly expressed in cancer cells participated in preventing cell metastasis and inducing apoptosis of ph-ph+. The one drug with dual targets inhibited the growth and metastasis of the cancer cells, and meanwhile eliminated C. albicans in tissues in the experimental animals. The results suggested that ph-ph+ with dual targets of CLpP and PLAGL2 would be a feasible approach to prolong the survival rate in patients with metastatic breast cancer and pathogenic infection.

Discovery of the Effects of the Hemiprotonic Phenanthroline-Phenanthroline+ against Trichophyton rubrum by Inducing Fungal Apoptosis

Trichophyton rubrum (T. rubrum) is the most common causative agent of dermatophytosis worldwide. The development of antifungal drugs will contribute to treating the disease. In this study, we suggest that a hemiprotonic compound phenanthroline-phenanthroline+ (ph-ph+) is active in inhibiting the growth and reproduction of T. rubrum, and the minimum inhibitory concentration and minimum fungicidal concentration values were 2 μg/ml and 8 μg/ml, respectively. In an in vitro onychomycosis model, ph-ph+ killed T. rubrum by inducing apoptosis, which was evaluated by transmission electron microscopy and Annexin V-FITC/propidium iodide staining. Transcriptomic analysis and biochemical assay showed that ph-ph+ elevated iron ion content in T. rubrum cells and reduced glutathione antioxidant system level, leading to an increase in the contents of ROS and malondialdehyde. Therefore, the antifungal mechanism of ph-ph+ would be associated with iron ion-induced cell apoptosis, which is different from other known antifungal drugs. Furthermore, ph-ph+ was prepared into gel for application in guinea pigs with dermatophytosis caused by T. rubrum. The results showed that the ph-ph+ gel eliminated the fungus in the animals without causing skin irritation or other adverse reactions. The study would not only provide a potential compound to treat dermatophytosis, but also suggest that iron ion-induced cell apoptosis might be a new approach to killing fungi.

Emerging roles of i-motif in gene expression and disease treatment

As non-canonical nucleic acid secondary structures consisting of cytosine-rich nucleic acids, i-motifs can form under certain conditions. Several i-motif sequences have been identified in the human genome and play important roles in biological regulatory functions. Due to their physicochemical properties, these i-motif structures have attracted attention and are new targets for drug development. Herein, we reviewed the characteristics and mechanisms of i-motifs located in gene promoters (including c-myc, Bcl-2, VEGF, and telomeres), summarized various small molecule ligands that interact with them, and the possible binding modes between ligands and i-motifs, and described their effects on gene expression. Furthermore, we discussed diseases closely associated with i-motifs. Among these, cancer is closely associated with i-motifs since i-motifs can form in some regions of most oncogenes. Finally, we introduced recent advances in the applications of i-motifs in multiple areas.