Structural Determinants of p53-Independence in Anticancer Ruthenium-Arene Schiff-Base Complexes.

p53 is a key tumor suppressor gene involved in key cellular processes and implicated in cancer therapy. However, it is inactivated in more than 50% of all cancers due to mutation or overexpression of its negative regulators. This leads to drug resistance and poor chemotherapeutic outcome as most clinical drugs act via a p53-dependent mechanism of action.

Platinum(IV) Carboxylate Prodrug Complexes as Versatile Platforms for Targeted Chemotherapy.

Kinetically-inert Pt(IV) carboxylate complexes have emerged in recent years as candidates for the development of next-generation platinum anticancer drugs. Being native prodrugs of clinically-important Pt(II) chemotherapeutic agents, the Pt(IV) scaffold can be exploited to incorporate additional functionalities while keeping the Pt(II) pharmacophore intact. This mini-review examines recent work performed to illuminate the mechanism of Pt(IV) prodrug activation and their use as versatile platforms for targeted chemotherapy.

Induction of targeted necrosis with HER2-targeted platinum(iv) anticancer prodrugs.

It is well-recognized that the failure of many chemotherapeutics arises due to an inability to induce apoptosis. Most cancers acquire a myriad of pro-survival adaptations, and the vast heterogeneity and accumulation of multiple often unrelated anti-apoptotic signaling pathways have been a major stumbling block towards the development of conventional chemotherapeutics, which can overcome drug resistance. We have developed highly potent and selective HER2-targeted Pt(iv) prodrugs bearing anti-HER2/neu peptides that induce as a novel strategy to circumvent apoptosis-resistance.

Induction of immunogenic cell death by chemotherapeutic platinum complexes.

There is compelling evidence suggesting that the immune-modulating effects of many conventional chemotherapeutics, including platinum-based agents, play a crucial role in achieving clinical response. One way in which chemotherapeutics can engage a tumor-specific immune response is by triggering an immunogenic mode of tumor cell death (ICD), which then acts as an "anticancer vaccine". In spite of being a mainstay of chemotherapy, there has not been a systematic attempt to screen both existing and upcoming Pt agents for their ICD ability.

Discovery and investigation of anticancer ruthenium-arene Schiff-base complexes via water-promoted combinatorial three-component assembly.

The structural diversity of metal scaffolds makes them a viable alternative to traditional organic scaffolds for drug design. Combinatorial chemistry and multicomponent reactions, coupled with high-throughput screening, are useful techniques in drug discovery, but they are rarely used in metal-based drug design. We report the optimization and validation of a new combinatorial, metal-based, three-component assembly reaction for the synthesis of a library of 442 Ru-arene Schiff-base (RAS) complexes.

Immuno-chemotherapeutic platinum(IV) prodrugs of cisplatin as multimodal anticancer agents.

There is growing consensus that the clinical therapeutic efficacy of some chemotherapeutic agents depends on their off-target immune-modulating effects. Pt anticancer drugs have previously been identified to be potent immunomodulators of both the innate and the adaptive immune system. Nevertheless, there has been little development in the rational design of Pt-based chemotherapeutic agents to exploit their immune-activating capabilities.

Harnessing chemoselective imine ligation for tethering bioactive molecules to platinum(IV) prodrugs.

Platinum(II) anticancer drugs are among the most effective and often used chemotherapeutic drugs. In recent years, there has been increasing interest in exploiting inert platinum(IV) scaffolds as a prodrug strategy to mitigate the limitations of platinum(II) anticancer complexes. In this prodrug strategy, the axial ligands are released concomitantly upon intracellular reduction to the active platinum(II) congener, offering the possibility of conjugating bioactive co-drugs which may synergistically enhance cytotoxicity on cancer cells.

Anticancer platinum (IV) prodrugs with novel modes of activity.

Over the past four decades, the search for improved platinum drugs based on the classical platinum (II)-diam(m)ine pharmacophore has yielded only a handful of successful candidates. New methodologies centred on platinum (IV) complexes, with better stability and expanded coordination spheres, offer the possibility of overcoming limitations inherent to platinum (II) drugs. In this review, novel strategies of targeting and killing cancer cells using platinum (IV) constructs are discussed.