Metal-Modified Nucleobase Sextet: Joining Four Linear Metal Fragments (trans-a2PtII) and Six Model Nucleobases to an Exceedingly Stable Entity

Sigel, Roland K. O.; Thompson, Susan; Freisinger, Eva; Glahé, Frank; Lippert, Bernhard

doi:10.1002/1521-3765(20010504)7:9<1968::aid-chem1968>3.0.co;2-b

Cited by 52 publications

(35 citation statements)

References 88 publications

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“…Thus, Scheme 2a is an example for the involvement of a second nucleobase (X ϭ guanine) in self-association (v in Scheme 4), as are compounds V (14) and VI (15) tion (vii in Scheme 4). This pair by far exceeds the normal G,C Watson-Crick pair in strength (47)(48)(49)(50).…”

Section: Discussionmentioning

confidence: 99%

Canonical and unconventional pairing schemes between bis(nucleobase) complexes oftrans-a₂Pt^II: Artificial nucleobase quartets and C—H…N bonds

Freisinger

Rother

Lüth

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

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If two nucleobases are crosslinked by trans-a2Pt II , self-association via H bonding may take place either through individual bases or jointly through both bases. Due to the blockage of an acceptor site by the metal, the number of feasible pairing patterns can be reduced, and the preferred ones altered. If the metalated base pair as a whole undergoes association, base quartets can form. Various scenarios resulting from the application of guanine, hypoxanthine, and cytosine model nucleobases are discussed. Unconventional COH. . .N hydrogen bonding has been observed in several instances.H bonding ͉ platinum T he existence of cyclic guanine (G) quartets and the association of poly(G) and poly(I) into four-stranded structures have been known for quite some time (1, 2). Proof of the formation of G quartets in telomere sequences (3) and their existence in human cells (4), new insights on the structure of human telomeric DNA (5, 6), and, above all, implications that G quartets are potential drug targets for the chemotherapy of cancer, on the one hand, and can play a dysfunctional role, on the other (7), have made the field of DNA quadruplex structures a booming area. From an inorganic chemistry point of view, the involvement of metal ions in the formation and stabilization of G 4 structural elements is of particular interest. That these cations, K ϩ and Na ϩ under physiological conditions and many other cations under nonphysiological conditions, are absolutely essential for maintaining the G 4 structure elements has been recognized at an early stage. Moreover, it is now clear that a stem of G 4 quartets stabilizes other quartet structures, including those between dimers of Watson-Crick pairs, e.g., [GC] 2 (C, cytosine) (8).Small molecules that bind specifically to quadruplex DNA, thereby interfering with the enzyme telomerase or inhibiting expression of a crucial gene, are believed to be useful for chemotherapeutic applications. Among these, cationic porphyrins such as tetra-(N-methyl-4-pyridyl)porphine are particularly promising (4, 9, 10). Our interest in this area stems from our experience with metal-nucleobase complexes representing artificial base quartets that are cationic and flat and that have dimensions compatible with the natural base quartets. Because of their shape and charge, these compounds can be expected to have a natural affinity for tetra-stranded DNA in general and telomere sequences in particular. The use of metal ions (M) displaying linear coordination geometries and the fact that purine nucleobases, on simultaneous metal binding to N1 and N7, provide 90°angles between their M-N vectors and hence represent angular building blocks of squares and rectangles have enabled the construction of a variety of artificial M-base quartets (11-16). Examples are given in Scheme 1. Depending on the metal ions applied and the degree of crosslinking, these quartets can be kinetically labile or robust, also occasionally assembled by remarkably strong H bonds, even in solution. It will be our ultimate goal to probe t...

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Section: Discussionmentioning

confidence: 99%

Canonical and unconventional pairing schemes between bis(nucleobase) complexes oftrans-a₂Pt^II: Artificial nucleobase quartets and C—H…N bonds

Freisinger

Rother

Lüth

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

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“…Similarly, the strength of the pair between Pt-CH and 1-MeC exceeds that of the regular G/C pair, even though it does not reach the record value recently observed for the hemideprotonated pair of N7-platinated guanine. [8] Our findings have led us to pursue the idea of creating artificial oligonucleotide analogues that consist of a backbone of metal ions and bridging ligands, with nucleobases attached either through N1 (unsubstituted pyrimidine bases), through N9 (unsubstituted purine bases), or through N7 (N9-substituted purine bases) to the metal centers. These coordination polymers might be considered relatives of purely organic neutral [9] and cationic [10] oligonucleotide analogues.…”

mentioning

confidence: 99%

PtII Binding to N1 of Cytosine: Strengthening the Watson-Crick Pair with Guanine and yet Confining Its pH Existence Range

Brüning

Sigel

Freisinger

et al. 2001

Angew. Chem. Int. Ed.

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“…Three principal arrangements of two hemi-deprotonated adenine ligands in head-head orientation and cross-linked by linear metal ions (M = trans-a 2 Pt II ): N1-Pt-N1, N1-Pt-N7, and N7-Pt-N7 (top to bottom). [73][74][75][76][77][78][79][80][81]. Even with a single purine base applied, e.g., 9MeA [82], yet more so in combinations with a second, different purine base [54], the number of linkage isomers becomes large.…”

Section: Types Of Pt II Complexes Studiedmentioning

confidence: 99%

“…Typically G-H8 resonances undergo upfield shifts of 0.2-0.25 ppm during N1H deprotonation, whereas A-H8 and A-H2 shift by ca. 0.6 ppm or even more [78,80,[90][91][92]. Changes in nucleobase rotamer states may modify these values further.…”

Section: Revisiting Complexes 4a and 4bmentioning

confidence: 99%

Connectivity patterns and rotamer states of nucleobases determine acid–base properties of metalated purine quartets

Lüth

Freisinger

Kampf

et al. 2015

Journal of Inorganic Biochemistry

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Metal-Modified Nucleobase Sextet: Joining Four Linear Metal Fragments (trans-a2PtII) and Six Model Nucleobases to an Exceedingly Stable Entity

Cited by 52 publications

References 88 publications

Canonical and unconventional pairing schemes between bis(nucleobase) complexes oftrans-a₂Pt^II: Artificial nucleobase quartets and C—H…N bonds

Canonical and unconventional pairing schemes between bis(nucleobase) complexes oftrans-a₂Pt^II: Artificial nucleobase quartets and C—H…N bonds

PtII Binding to N1 of Cytosine: Strengthening the Watson-Crick Pair with Guanine and yet Confining Its pH Existence Range

Connectivity patterns and rotamer states of nucleobases determine acid–base properties of metalated purine quartets

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Metal-Modified Nucleobase Sextet: Joining Four Linear Metal Fragments (trans-a2PtII) and Six Model Nucleobases to an Exceedingly Stable Entity

Cited by 52 publications

References 88 publications

Canonical and unconventional pairing schemes between bis(nucleobase) complexes oftrans-a2PtII: Artificial nucleobase quartets and C—H…N bonds

Canonical and unconventional pairing schemes between bis(nucleobase) complexes oftrans-a2PtII: Artificial nucleobase quartets and C—H…N bonds

PtII Binding to N1 of Cytosine: Strengthening the Watson-Crick Pair with Guanine and yet Confining Its pH Existence Range

Connectivity patterns and rotamer states of nucleobases determine acid–base properties of metalated purine quartets

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Canonical and unconventional pairing schemes between bis(nucleobase) complexes oftrans-a₂Pt^II: Artificial nucleobase quartets and C—H…N bonds

Canonical and unconventional pairing schemes between bis(nucleobase) complexes oftrans-a₂Pt^II: Artificial nucleobase quartets and C—H…N bonds