Chlorambucil labelled with the phenosafranin scaffold as a new chemotherapeutic for imaging and cancer treatment

Liposomal Encapsulation of Chlorambucil with a Terpyridine-Based, Glutathione-Targeted Optical Probe Facilitates Cell Entry and Cancer Cell Death

The nitrogen mustard alkylating agent chlorambucil (CBL) is a critical component of chemotherapeutic regimens used in the treatment of chronic lymphocytic leukemia. The cancer cell-killing actions of CBL are limited by glutathione (GSH) conjugation, a process catalyzed by the GSH transferase hGSTA1-1 that triggers CBL efflux from cells. In the cancer cell microenvironment, intracellular GSH levels are elevated to counterbalance oxidative stress generated due to the high glycolytic demand. As many chemotherapeutic drugs trigger cell death through mechanisms that depend on reactive oxygen species (ROS), antioxidant capacity in cancer cells also represents a barrier to anticancer therapies. Here, we demonstrate that a heightened GSH content in cancer cells can also be exploited for cell-selective drug delivery. We successfully synthesized a malononitrile conjugate terpyridine-based derivative L1, which specifically reacts with GSH in the presence of other biologically relevant amino acids including cysteine (Cys) and homocysteine (Hcy). The significant change in the electronic spectra of L1 in the presence of GSH confirmed GSH detection, which was further corroborated by density functional theory calculations. We next encapsulated CBL into L1-containing, anthracene-functionalized, and 10,12-pentacosadiynoic acid (PCDA)- and 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC)-based liposomes (Lip-CBL-L1). We established successful CBL encapsulation and release from L1-containing liposomes in GSH-enriched cancer cells in vitro. Both Lip-CBL-L1 and the L1-lacking Lip-CBL control displayed cell-killing activity. However, human triple-negative breast cancer cells MDAMB231, human lung cancer cells A549, and murine leukemic WEHI cells were more sensitive to the cytotoxic effects of Lip-CBL-L1 compared to the nonmalignant cells (AC16 and HEK293). Indeed, in these cancer cell lines, Lip-CBL-L1 induced greater ROS generation compared to that of Lip-CBL. Together, our results provide initial evidence of the feasibility of exploiting the unique oxidant environment of cancer cells for optimized drug delivery.

Selective nitrogen insertion into aryl alkanes

Molecular structure-editing through nitrogen insertion offers more efficient and ingenious pathways for the synthesis of nitrogen-containing compounds, which could benefit the development of synthetic chemistry, pharmaceutical research, and materials science. Substituted amines, especially nitrogen-containing alkyl heterocyclic compounds, are widely found in nature products and drugs. Generally, accessing these compounds requires multiple steps, which could result in low efficiency. In this work, a molecular editing strategy is used to realize the synthesis of nitrogen-containing compounds using aryl alkanes as starting materials. Using derivatives of O-tosylhydroxylamine as the nitrogen source, this method enables precise nitrogen insertion into the Csp2-Csp3 bond of aryl alkanes. Notably, further synthetic applications demonstrate that this method could be used to prepare bioactive molecules with good efficiency and modify the molecular skeleton of drugs. Furthermore, a plausible reaction mechanism involving the transformation of carbocation and imine intermediates has been proposed based on the results of control experiments.

Chlorambucil-Bearing Hybrid Molecules in the Development of Potential Anticancer Agents

Increasing cases of cancer have been a primary concern in recent decades. Developing new chemotherapeutics is challenging and has been faced with limitations, such as multidrug resistance, poor specificity, selectivity, and toxicity. The aforementioned factors contribute to treatment failure. Hybrid compounds have features that can overcome the limitations mentioned above. Chlorambucil, an anticancer drug that is used to treat prostate and breast cancer, suffers from poor aqueous solubility and specificity, a short half-life, and severe side effects, including anaemia and bone marrow suppression. It compromises the immune system, resulting in treatment failure. Hence, its combination with other pharmacophores has been reported to result in effective anticancer agents with fewer side effects and high therapeutic outcomes. Furthermore, this review gives an update (2010 to date) on the developments of chlorambucil hybrid compounds with anticancer activity, and the structure-activity relationship (SAR), and also highlights future strategies for developing novel anticancer agents.

Biotin-phenosafranin as a new photosensitive conjugate for targeted therapy and imaging

A biotinylated phenazine compound as a phenosafranin conjugate (Biot-PSF) was synthesized and reported for the first time.

Selective modification of sulfamidate-containing peptides

Hybrid peptides whose N-terminal residues are activated in the form of α-methylisoserine-derived cyclic sulfamidates exhibit rich reactivity as electrophiles, allowing site- and stereoselective modifications at different backbone and side chain positions. The unique properties of this scaffold allow the stereocontrolled late-stage functionalization of the peptide backbone by nucleophilic ring opening with fluorescent probes, thiocarbohydrates and tags for strain-promoted azide-alkyne cycloaddition as well as by installing labile N-terminal affinity tags (biotin) and cytotoxic drugs (chlorambucil) for pH-controlled release. Finally, an unexpected base-promoted acyl group migration from the sulfamidate N-terminus allows fast and quantitative intramolecular modification of nucleophilic side chains on the fully unprotected peptides.