Substitution-inert Polynuclear Platinum Research Articles

Substitution-inert polynuclear platinum complexes and Glycosaminoglycans: A molecular dynamics study of its non-covalent interactions

An impressive class of formally substitution-inert polynuclear platinum complexes known as Substitution-inert Polynuclear Platinum (II) Complexes (SI-PPCs) present an attractive approach for medicinal inorganic chemistry through high-affinity non-covalent interactions with biomolecules, such as DNA and Glycosaminoglycans (GAGs). This interaction occurs through the formation of non-covalent cyclic structures called clamps and forks with the phosphate and sulfate groups present in these biomolecules. This work shows several analyses of the non-covalent interactions formed between heparin (PDB code: 1HPN) and SI-PPCs obtained through molecular dynamics (MD) simulations. Root Mean Square Deviation (RMSD) results showed that the “non-covalent” di-nuclear platinum compound, DiplatinNC ([{trans-Pt(NH3)2(NH2(CH2)6NH3+)}2-μ-NH2(CH2)6NH2]6+) and AH44 ([{Pt(NH3)3}2{(μ-(H2N(CH2)6NH2)2-(trans-Pt(NH3)2}]6+, 0,0,0/t,t,t,) complexes, which are both 6+ charged complexes, were the most rigid. On the other hand, the Root Mean Square Fluctuation (RMSF) showed that there is a reduction in the atomic fluctuation of atoms in the central region of the heparin molecule; the solvent accessible surface area (SASA) analysis also indicates a reduction in the accessible area by the heparin when interacting with SI-PPCs. The evaluation of H-Bond data confirms the formation of the non-covalent interactions, which may suggest a decrease in the action of 1HPN by preventing the action of enzymes on this substrate. In addition, thermodynamic results indicate that this interaction is spontaneous, considering the negative variations in the Gibbs free energy presented by the studied systems.

Platinum complexes act as shielding agents against virus infection.

We determine that the substitution-inert polynuclear platinum complex (PPC) TriplatinNC is an antiviral agent and protects cells from enterovirus 71 and human metapneumovirus infection. This protection occurs through the formation of adducts with cell-surface glycosaminoglycans. Our detailed mechanistic investigation demonstrates that TriplatinNC blocks viral entry by shielding cells from virus attack, opening new directions for metalloshielding antiviral drug development.

Conformational Modulation of Iduronic Acid-Containing Sulfated Glycosaminoglycans by a Polynuclear Platinum Compound and Implications for Development of Antimetastatic Platinum Drugs.

1 H NMR spectroscopic studies on the 1:1 adduct of the pentasaccharide Fondaparinux (FPX) and the substitution-inert polynuclear platinum complex TriplatinNC show significant modulation of geometry around the glycosidic linkages of the FPX constituent monosaccharides. FPX is a valid model for the highly sulfated cell signalling molecule heparan sulfate (HS). The conformational ratio of the 1 C4 :2 S0 forms of the FPX residue IdoA(2S) is altered from ca. 35:65 (free FPX) to ca. 75:25 in the adduct; the first demonstration of a small molecule affecting conformational changes on a HS oligosaccharide. Functional consequences of such binding are suggested to be inhibition of HS cleavage in MDA-MB-231 triple-negative breast cancer (TNBC) cells. We further describe inhibition of metastasis by TriplatinNC in the TNBC 4T1 syngeneic tumour model. Our work provides insight into a novel approach for design of platinum drugs (and coordination compounds in general) with intrinsic anti-metastatic potential.

Substitution-inert polynuclear platinum compounds inhibit human cytomegalovirus attachment and entry

Human cytomegalovirus (HCMV) infects up to 90–100% of the world population. Although HCMV infection is not a concern for immunocompetent patients, it can be life threatening for immunocompromised individuals. Additionally, congenital HCMV infections can cause serious neurological deficits in neonates. Since viral resistance mutations arise for all current treatments, new treatments targeting novel processes are needed. A well-defined target for HCMV is heparan sulfate, a highly sulfated glycosaminoglycan (GAG) necessary for virion/host cell attachment. In this study, we investigated as possible antiviral agents substitution-inert cationic polynuclear platinum complexes (PPCs) that demonstrate charge-dependent high affinity for GAGs (Katner et al., 2018; Peterson et al., 2017). Certain PPCs had anti-HCMV activities in low micromolar concentrations and antiviral activity correlated with their GAG-binding affinity. Time of addition, removal, and mechanistic studies were consistent with PPCs binding to cells and blocking HCMV virion attachment; however, evidence also suggested that PPC/virion interactions could inhibit fibroblast but not epithelial cell infection. We hypothesize that the PPC-heparan sulfate interaction described here is a general approach to inhibition of virion/host cell attachment and viral entry mediated by other anionic GAGs and sialic acids on the cell surface. Through metalloshielding of the critical sulfate receptors, PPCs offer an attractive alternative to current antiviral compounds, with the potential to target a broad spectrum of viruses that utilize GAGs for attachment and entry.

Substitution-Inert Polynuclear Platinum Complexes Inhibit Reverse Transcription Preferentially in RNA Triplex-Forming Templates.

RNA triplexes are significant tertiary structure motifs that are found in many functional RNAs. Hence, small molecules capable of recognition, binding, and stabilization of the triple-helical RNA structures are emerging as attractive potential molecular biology tools and therapeutic agents. Here, we utilize methods of molecular biology and biophysics to study the interactions of a series of antitumor substitution-inert polynuclear platinum complexes (SI-PPCs) with triple-helical RNA structures. We show that SI-PPCs recognize and stabilize RNA triplexes and inhibit reverse transcription preferentially in the RNA template prone to the triplex formation. These so far unexplored properties of SI-PPCs suggest that the targeting of triple-stranded regions in RNA might contribute to the biological effects of SI-PPCs.

Molecular dynamics simulation of non-covalent interactions between polynuclear platinum(II) complexes and DNA.

Several studies with substitution-inert polynuclear platinum(II) complexes (SI-PPC) have been carried out in recent years due to the form of DNA binding presented by these compounds. This form of bonding is achieved by molecular recognition through the formation of non-covalent structures, commonly called phosphate clamps and forks, which generate small extensions of the major and minor grooves. In this work, we use molecular dynamics simulations (MD) to study the formation of these cyclical structures between six different SI-PPCs and a double DNA dodecamer, here called 24_bp_DNA. The results showed the influence of the complex expressed on the number of phosphate clamps and forks formed. Based on the conformational characterization of the DNA fragment, we show that the studied SI-PPCs interact preferentially in the minor groove, causing groove spanning, except for two of them, Monoplatin and AH44. The phosphates of C-G pairs are the main sites for such non-covalent interactions. The Gibbs interaction energy of solvated species points out to AH78P, AH78H, and TriplatinNC as the most probable ones when coupled with DNA. As far as we know, this work is the very first one related to SI-PPCs which brings MD simulations and a complete analysis of the non-covalent interactions with a double DNA dodecamer.

Substitution-Inert Polynuclear Platinum Complexes with Dangling Amines: Condensation/Aggregation of Nucleic Acids and Inhibition of DNA-Related Enzymatic Activities.

The substitution-inert polynuclear platinum complexes (SI-PPCs) are now recognized as a distinct subclass of platinum anticancer drugs with high DNA binding affinity. Here, we investigate the effects of SI-PPCs containing dangling amine groups in place of NH3 as ligands to increase the length of the molecule and therefore overall charge and its distribution. The results obtained with the aid of biophysical techniques, such as total intensity light scattering, gel electrophoresis, and atomic force microscopy, show that addition of dangling amine groups considerably augments the ability of SI-PPCs to condense/aggregate nucleic acids. Moreover, this enhanced capability of SI-PPCs correlates with their heightened efficiency to inhibit DNA-related enzymatic activities, such as those connected with DNA transcription, catalysis of DNA relaxation by DNA topoisomerase I, and DNA synthesis catalyzed by Taq DNA polymerase. Thus, the addition of the dangling amine groups resulting in structures of SI-PPCs, which differ so markedly from the derivatives of cisplatin used in the clinic, appears to contribute to the overall biological activity of these molecules.

Substitution-Inert Polynuclear Platinum Complexes Act as Potent Inducers of Condensation/Aggregation of Short Single- and Double-Stranded DNA and RNA Oligonucleotides.

Compounds condensing DNA and RNA molecules can essentially affect important biological processes including DNA replication and transcription. Here, this work shows with the aid of total intensity light scattering, gel electrophoresis, and atomic force microscopy (AFM) that the substitution-inert polynuclear platinum complexes (SI-PPCs), particularly [{trans-Pt(NH3 )2 (NH2 (CH2 )6 - NH3 + )}2 -μ-{trans-Pt(NH3 )2 (NH2 (CH2 )6 NH2 )2 }]8+ (Triplatin NC), exhibit an unprecedented high potency to condense/aggregate fragments of DNA and RNA as short as 20 base pairs. SI-PPCs condensates are distinctive from those generated by the naturally occurring polyamines (commonly used DNA compacting/condensing agents). Collectively, the results further confirm that SI-PPCs are very efficient inducers of condensation of DNA and RNA, including their short fragments that might have potential in gene therapy, biotechnology, and bionanotechnology. Moreover, the data confirm the structural advantages of the phosphate clamp, with a well-defined rigid DNA recognition motif in initiating condensation and aggregation phenomena on oligonucleotides.

Substitution-Inert Polynuclear Platinum Complexes That Inhibit the Activity of DNA Polymerase in Triplex-Forming Templates.

The formation of triple-helical DNA is implicated in the regulation of gene expression. The triplexes are, however, unstable under physiological conditions so that effective stabilizers for the triplex formation are needed. Herein, we describe a new strategy for the stabilization of such triplexes that is based on antitumor substitution-inert polynuclear platinum complexes (SI-PPCs). These compounds were previously shown to bind to DNA through the phosphate clamp-a discrete mode of DNA-ligand recognition distinct from the canonical intercalation and minor-groove binding. We have found that SI-PPCs efficiently inhibit DNA synthesis by DNA polymerase in sequences prone to the formation of pyrimidine- and purine-motif triplex DNAs. Moreover, the results suggest that SI-PPCs are able to induce the formation of triple-helical DNA between duplexes and strands that are not completely complementary to each other. Collectively, these data provide evidence that SI-PPCs are very efficient stabilizers of triple-stranded DNA that might exert their action by stabilizing higher-order structures such as triple-helical DNA.

The phosphate clamp as recognition motif in platinum–DNA interactions

This review summarizes studies on substitution-inert polynuclear platinum complexes (PPCs) which bind to DNA through the phosphate clamp – a discrete mode of DNA–ligand recognition distinct from the canonical intercalation and minor-groove binding. Especially, this review concentrates on comparing the binding and conformational changes induced by trinuclear platinum complexes with dinuclear spermine-linked complexes. The protonated central polyamine –+NH2–(CH2)4–N+H2– of spermine allows direct comparison with the central Pt(tetraamine) moiety of the trinuclear complexes. The weight of the evidence suggests that while overall charge on the small molecule determines binding affinity, the presence of minor groove spanning from the phosphate clamp is important in conformational changes and in sequence selectivity.

Multi-platinum anti-cancer agents. Substitution-inert compounds for tumor selectivity and new targets.

This tutorial review summarizes chemical, biophysical and cellular biological properties of formally substitution-inert "non-covalent" polynuclear platinum complexes (PPCs). We demonstrate how modulation of the pharmacological factors affecting platinum compound cytotoxicity such as cellular accumulation, reactivity toward extracellular and intracellular sulfur-ligand nucleophiles and consequences of DNA binding is achieved to afford a profile of biological activity distinct from that of covalently-binding agents. The DNA binding of substitution-inert complexes is achieved by molecular recognition through minor groove spanning and backbone tracking of the phosphate clamp. In this situation, the square-planar tetra-am(m)ine Pt(ii) coordination units hydrogen bond to phosphate oxygen OP atoms to form bidentate N-O-N motifs. The modular nature of the polynuclear compounds results in high-affinity binding to DNA and very efficient nuclear condensation. These combined effects distinguish the phosphate clamp as a third mode of ligand-DNA binding, discrete from intercalation and minor-groove binding. The cellular consequences mirror those of the biophysical studies and a significant portion of nuclear DNA is compacted, a unique effect different from mitosis, senescence or apoptosis. Substitution-inert PPCs display cytotoxicity similar to cisplatin in a wide range of cell lines, and sensitivity is indifferent to p53 status. Cellular accumulation is mediated through binding to heparan sulfate proteoglycans (HSPG) allowing for possibilities of tumor selectivity as well as disruption of HSPG function, opening new targets for platinum antitumor agents. The combined properties show that covalently-binding chemotypes are not the unique arbiters of cytotoxicity and antitumor activity and meaningful antitumor profiles can be achieved even in the absence of Pt-DNA bond formation. These dual properties make the substitution-inert compounds a unique class of inherently dual-action anti-cancer agents.

The phosphate clamp: sequence selective nucleic acid binding profiles and conformational induction of endonuclease inhibition by cationic Triplatin complexes.

The substitution-inert polynuclear platinum(II) complex (PPC) series, [{trans-Pt(NH3)2(NH2(CH2)nNH3)}2-μ-(trans-Pt(NH3)2(NH2(CH2)nNH2)2}](NO3)8, where n = 5 (AH78P), 6 (AH78 TriplatinNC) and 7 (AH78H), are potent non-covalent DNA binding agents where nucleic acid recognition is achieved through use of the ‘phosphate clamp' where the square-planar tetra-am(m)ine Pt(II) coordination units all form bidentate N–O–N complexes through hydrogen bonding with phosphate oxygens. The modular nature of PPC–DNA interactions results in high affinity for calf thymus DNA (Kapp ∼5 × 107 M−1). The phosphate clamp–DNA interactions result in condensation of superhelical and B-DNA, displacement of intercalated ethidium bromide and facilitate cooperative binding of Hoechst 33258 at the minor groove. The effect of linker chain length on DNA conformational changes was examined and the pentane-bridged complex, AH78P, was optimal for condensing DNA with results in the nanomolar region. Analysis of binding affinity and conformational changes for sequence-specific oligonucleotides by ITC, dialysis, ICP-MS, CD and 2D-1H NMR experiments indicate that two limiting modes of phosphate clamp binding can be distinguished through their conformational changes and strongly suggest that DNA condensation is driven by minor-groove spanning. Triplatin-DNA binding prevents endonuclease activity by type II restriction enzymes BamHI, EcoRI and SalI, and inhibition was confirmed through the development of an on-chip microfluidic protocol.