Site-specific covalent metalation of DNA oligonucleotides with phosphorescent platinum(ii) complexes

Luminescent N^C^N Pincer Ni(II), Pd(II), and Pt(II) Complexes with a Pendant Coumarin Group: The Role of Auxiliary Ligands and Environments

Square-planar d8-configured metal complexes and their excited states play a key role in photocatalysis, sensing, and optoelectronic devices. However, metal-to-ligand charge-transfer (MLCT) excited states involving transition metals, particularly those with a 3d8 electronic configuration, present challenges due to rapid nonradiative relaxation via low-lying metal-centered (MC) states. In this work, an isoelectronic and isostructural series of cyclometalated complexes [MX(dpb)] with M = Ni(II), Pd(II), and Pt(II), dpb = 1,3-di(2-pyridyl)phenide, and auxiliary ligand X = chlorido, azido, and triazolato were studied by UV/vis absorption, steady-state, and time-resolved photoluminescence spectroscopy in solution and frozen glassy matrix at 77 K, along with DFT calculations. Consistently, the Pd(II) and Pt(II) complexes exhibited a characteristic emission from their triplet ligand-centered (3LC) excited states. In contrast, Ni(II) complexes with auxiliary chlorido, azido, and triazolatoCOOCH3,COOCH3 ligands were nonemissive at low and room temperatures, due to the presence of low-lying MC-type ligand-field excited states. On the other hand, [Ni(triazolatoCoumarin,COOCH3)(dpb)] showed phosphorescence from the T5 state in a frozen glassy matrix at 77 K, since the restrictive environment limits structural relaxation, while at room temperature, the primary emission is due to singlet LC excited states from the coumarin moiety of the free ligand.

Highly phosphorescent N^C^N platinum(II)-peptide nucleic acid conjugates: synthesis, photophysical studies and hybridization behaviour

The synthesis of novel highly phosphorescent N^C^N tridentate platinum(II)-complex-peptide nucleic acid (PNA) bioconjugates was accomplished through the solid-phase approach. Melting temperature measurements and circular dichroism spectroscopy studies demonstrated that these conjugates maintain the PNA ability to recognize complementary ssDNA and ssRNA, though the length of the spacer between the metal center and the PNA sequence affects their hybridization properties. Noteworthy, the conjugation of PNA to this family of Pt(II) complexes significantly enhanced the luminescent features of the organometallic moiety, leading to increased quantum yields (82.8%, 10-5 M), even in the presence of oxygen (48.6%, 10-5 M). An in vitro cytotoxicity study of Pt(II)-PNA conjugates on HeLa cells showed no significative effect on cell growth in the dark (1 μM for 72 h).

Chemistry of organometallic nucleic acid components: personal perspectives and prospects for the future

Organometallic modifications of biologically important compounds such as drugs, secondary natural products, peptides, and nucleic acids, to name just a few, represent a well-established strategy for the development of new anticancer and antimicrobial agents. Supported by these reasons, over 12 years ago, we initiated a research program into organometallic modifications of nucleic acid components. This account summarizes key results regarding the synthetic chemistry and biological activities of the obtained compounds. As synthetic chemists, our main goal over the last 12 years has been to develop new strategies that allow for the exploration of the chemical space of organometallic nucleic acid components. Accordingly, we have developed a Michael addition reaction-based methodology that enabled the synthesis of an entirely new class of glycol nucleic acid (GNA) constituents. Concerning GNA chemistry, we also reported the synthesis of the first-ever ferrocenyl GNA-RNA "mixed" dinucleoside phosphate analog. Recently, we developed a Cu(I)-catalyzed Huisgen azide-alkyne 1,3-dipolar cycloaddition reaction-based approach for the synthesis of novel 1,2,3-triazole-linked ("click") nucleosides. The high value of this approach is because it allows for the introduction of functional (e.g., luminescent and redox-active) groups that protrude from the main oligomer sequence. With respect to biological activity studies, we identified several promising anticancer and antimicrobial compounds. Furthermore, we found that simple ferrocenyl-nucleobase conjugates have potential as modulators of Aβ21-40 amyloid aggregation. The final section of this article serves as a guide for future studies, as it presents some challenging goals yet to be achieved within the rapidly growing field of nucleic acid chemistry.

Antiprotozoal Pt(II) Complexes as Luminophores Bearing Monodentate P/As/Sb-Based Donors: An X-ray Diffractometric, Photoluminescence, and 121Sb-Mössbauer Spectroscopic Study with TD-DFT-Guided Interpretation and Predictive Extrapolation toward Bi

In this study, it is demonstrated that the radiative rate constant of phosphorescent metal complexes can be substantially enhanced using monodentate ancillary ligands containing heavy donor atoms. Thus, the chlorido coligand from a Pt(II) complex bearing a monoanionic tridentate C^N*N luminophore ([PtLCl]) was replaced by triphenylphosphane (PPh3) and its heavier pnictogen congeners (i.e., PnPh3 to yield [PtL(PnPh3)]). Due to the high tridentate-ligand-centered character of the excited states, the P-related radiative rate is rather low while showing a significant boost upon replacement of the P donor by heavier As- and Sb-based units. The syntheses of the three complexes containing PPh3, AsPh3, and SbPh3 were completed by unambiguous characterization of the clean products using exact mass spectrometry, X-ray diffractometry, bidimensional NMR, and 121Sb-Mössbauer spectroscopy (for [PtL(SbPh3)]) as well as steady state and time-resolved photoluminescence spectroscopies. Hence, it was shown that the hybridization defects of the Vth main-group atoms can be overcome by complexation with the Pt center. Notably, the enhancement of the radiative rate constants mediated by heavier coligands was achieved without significantly influencing the character of the excited states. A rationalization of the results was achieved by TD-DFT. Even though the Bi-based homologue was not accessible due to phenylation side reactions, the experimental data allowed a reasonable extrapolation of the structural features whereas the hybridization defects and the excited state properties related to the Bi-species and its phosphorescence rate can be predicted by theory. The three complexes showed an interesting antiprotozoal activity, which was unexpectedly notorious for the P-containing complex. This work could pave the road toward new efficient materials for optoelectronics and novel antiparasitic drugs.

Organometallic modification confers oligonucleotides new functionalities

To improve their properties or to introduce entirely new functionalities, the intriguing scaffolds of nucleic acids have been decorated with various modifications, most recently also organometallic ones. While challenging to introduce, organometallic modifications offer the potential of expanding the field of application of metal-dependent functionalities to metal-deficient conditions, notably those of biological media. So far, organometallic moieties have been utilized as probes, labels and catalysts. This Feature Article summarizes recent efforts and predicts likely future developments in each of these lines of research.

6-Pyrazolylpurine and its deaza derivatives as nucleobases for silver(I)-mediated base pairing with pyrimidines

The artificial nucleobase 6-pyrazolylpurine (6PP) and its deaza derivatives 1-deaza-6-pyrazolylpurine (1D6PP), 7-deaza-6-pyrazolylpurine (7D6PP), and 1,7-dideaza-6-pyrazolylpurine (1,7D6PP) were investigated with respect to their ability to differentiate between the canonical nucleobases cytosine and thymine by means of silver(I)-mediated base pairing. As shown by temperature-dependent UV spectroscopy and by circular dichroism spectroscopy, 6PP and (to a lesser extent) 7D6PP form stable silver(I)-mediated base pairs with cytosine, but not with thymine. 1D6PP and 1,7D6PP do not engage in the formation of stabilizing silver(I)-mediated base pairs with cytosine or thymine. The different behavior of 1D6PP, 7D6PP, and 1,7D6PP indicates that silver(I) binding occurs via the N1 position of the purine derivative, i.e. via the Watson-Crick face. The data show that 6PP is capable of differentiating between cytosine and thymine, which is potentially relevant in the context of detecting single-nucleotide polymorphisms.