A computational study of tetrahedrene: strained alkene or dicarbene?

A computational study of tetrahedrene at the RCCD/cc-pVDZ level led to a singlet-state structure with a lowest energy vibrational mode of 660 cm(-1). The corresponding triplet state was found to be ca. 37 kcal/mol lower in energy than the singlet state. The heat of formation of the singlet state was estimated to be 270 kcal/mol. An isomeric singlet bicyclic dicarbene bis-bicyclo[1.1.0]cyclobutylidene was found to be approximately 94 kcal/mol lower in energy than tetrahedrene.

The 2-norbornyl cation via the fragmentations of exo- and endo-2-norbornyloxychlorocarbenes: distinction without much difference.

exo- and endo-2-norbornyloxychlorocarbenes (7) were generated photochemically from the corresponding diazirines (6). Both carbenes fragmented to [2-norbornyl cation (carbon monoxide) chloride] ion pairs in MeCN or 1,2-dichloroethane solutions. Products included exo-norbornyl chloride (8), endo-norbornyl chloride (9), norbornene (10), and nortricyclene (11). Fragmentation activation energies were very low (< approximately 4 kcal/mol) and, as a result, the (laser flash photolytic) rate constants for fragmentation were essentially identical for exo-7 and endo-7 ( approximately 5 x 10(5) s(-1) in MeCN). Due to chloride return within the ion pairs, product distributions from exo- and endo-7 differed, with more endo-chloride formed from the endo-carbene: the 8/9 product ratio in MeCN was approximately 41 from exo-7, but only 4.6 from endo-7. Norbornene, formed by proton transfer to Cl(-) within the ion pairs, was a major product in both cases (44% from exo-7 and 62% from endo-7). In MeOH/MeCN, up to 28% of exo-2-norbornyl methyl ether formed at the expense of some of the norbornene, but even in 100% MeOH, the norbornyl chloride products of ion pair return still accounted for 46% and 31% of the exo-7 and endo-7 product mixtures (accompanied by 26-32% of norbornene). Electronic structure calculations on the ground states and fragmentation transition states of exo-7 and endo-7 are presented.

Human topoisomerase I poisoning by protoberberines: potential roles for both drug-DNA and drug-enzyme interactions.

Protoberberines represent a structural class of organic cations that induce topoisomerase I-mediated DNA cleavage, a behavior termed topoisomerase I poisoning. We have employed a broad range of biophysical, biochemical, and computer modeling techniques to characterize and cross-correlate the DNA-binding and topoisomerase poisoning properties of four protoberberine analogues that differ with respect to the substituents on their A- and/or D-rings. Our data reveal the following significant features: (i) The binding of the four protoberberines unwinds duplex DNA by approximately 11 degrees, an observation consistent with an intercalative mode of interaction. (ii) Enthalpically favorable interactions, such as stacking interactions between the intercalated ligand and the neighboring base pairs, provide <50% of the thermodynamic driving force for the complexation of the protoberberines to duplex DNA. Computer modeling studies on protoberberine-DNA complexes suggest that only rings C and D intercalate into the host DNA helix, while rings A and B protrude out of the helix interior into the minor groove. (iii) All four protoberberine analogues are topoisomerase I-specific poisons, exhibiting little or no topoisomerase II poisoning activity. (iv) Modifications of the D-ring influence both DNA binding and topoisomerase I poisoning properties. Specifically, transference of a methoxy substituent from the 11- to the 9-position diminishes both DNA binding affinity and topoisomerase I poisoning activity, an observation suggesting that DNA binding is important in the poisoning of topoisomerase I by protoberberines. (v) Modifications of the A-ring have a negligible impact on DNA binding affinity, while exerting a profound influence on topoisomerase I poisoning activity. Specifically, protoberberine analogues containing either 2,3-dimethoxy; 3,4-dimethoxy; or 3, 4-methylenedioxy substituents all bind DNA with a similar affinity. By contrast, these analogues exhibit markedly different topoisomerase I poisoning activities, with these activities following the hierarchy: 3,4-methylenedioxy > 2,3-dimethoxy >> 3, 4-dimethoxy. These differences in topoisomerase I poisoning activity may reflect the differing abilities of the analogues to interact with specific functionalities on the enzyme, thereby stabilizing the enzyme in its cleavable state. In the aggregate, our results are consistent with a mechanistic model in which both ligand-DNA and ligand-enzyme interactions are important for the poisoning of topoisomerase I by protoberberines, with the DNA-directed interactions involving ring D and the enzyme-directed interactions involving ring A. It is reasonable to suggest that the poisoning of topoisomerase I by a broad range of other naturally occurring and synthetic ligands may entail a similar mechanism.

Minor groove-directed and intercalative ligand-DNA interactions in the poisoning of human DNA topoisomerase I by protoberberine analogs.

Spectroscopic, calorimetric, DNA cleavage, electrophoretic, and computer modeling techniques have been employed to characterize the DNA binding and topoisomerase poisoning properties of three protoberberine analogs, 8-desmethylcoralyne (DMC), 5,6-dihydro-8-desmethylcoralyne (DHDMC), and palmatine, which differ in the chemical structures of their B- and/or D-rings. DNA topoisomerase-mediated cleavage assays revealed that these compounds were unable to poison mammalian type II topoisomerase. By contrast, the three protoberberine analogs poisoned human topoisomerase I according to the following hierarchy: DHDMC > DMC > palmatine. DNA binding by all three protoberberine analogs induced negative flow linear dichroism signals as well as unwinding of the host duplex. These two observations are consistent with an intercalative mode of protoberberine binding to duplex DNA. However, a comparison of the DNA binding properties for DMC and DHDMC, which differ only by the state of saturation at the 5,6 positions of the B-ring, revealed that the protoberberine analogs do not "behave" like classic DNA intercalators. Specifically, saturation of the 5-6 double bond in the B-ring of DMC, thereby converting it to the DHDMC molecule, was associated with enhanced DNA unwinding as well as a reversal of DNA binding preference from a DNA duplex with an inaccessible or occluded minor groove {poly[d(G-C)]2} to DNA duplexes with accessible or unobstructed minor grooves {poly[d(A-T)]2 and poly[d(I-C)]2}. In addition, a comparison of the DNA binding properties for DHDMC and palmatine revealed that transferring the 11-methoxy moiety on the D-ring of DHDMC to the 9 position, thereby converting it to palmatine, was associated with a reduction in binding affinity for both duplexes with unobstructed minor grooves as well as for duplexes with occluded minor grooves. These DNA binding properties are consistent with a "mixed-mode" DNA binding model for protoberberines in which a portion of the ligand molecule intercalates into the double helix, while the nonintercalated portion of the ligand molecule protrudes into the minor groove of the host duplex, where it is thereby available for interactions with atoms lining the floor and/or walls of the minor groove. Furthermore, saturation at the 5,6 positions of the B-ring, which causes the A-ring to be tilted relative to the plane formed by rings C and D, appears to stabilize the interaction between the host duplex and the minor groove-directed portion of the protoberberine ligand. Computer modeling studies on the DHDMC-poly[d(A-T)]2 complex suggest that this interaction may involve van der Waals contacts between the ligand A-ring and backbone sugar atoms lining the minor groove of the host duplex. The hierarchy of topoisomerase I poisoning noted above suggests that this minor groove-directed interaction may play an important role in topoisomerase I poisoning by protoberberine analogs. In the aggregate, our results presented here, coupled with the recent demonstration of topoisomerase I poisoning by minor groove-binding terbenzimidazoles [Sun, Q., Gatto, B., Yu, C., Liu, A. , Liu, L. F., & LaVoie, E. J. (1995) J. Med. Chem. 38, 3638-3644], suggest that minor groove-directed ligand-DNA interactions may be of general importance in the poisoning of topoisomerase I.