Paul S. Kingma

Topoisomerase II·Etoposide Interactions Direct the Formation of Drug-induced Enzyme-DNA Cleavage Complexes

Topoisomerase II is the target for several highly active anticancer drugs that induce cell death by enhancing enzyme-mediated DNA scission. Although these agents dramatically increase levels of nucleic acid cleavage in a site-specific fashion, little is understood regarding the mechanism by which they alter the DNA site selectivity of topoisomerase II. Therefore, a series of kinetic and binding experiments were carried out to determine the mechanistic basis by which the anticancer drug, etoposide, enhances cleavage complex formation at 22 specific nucleic acid sequences. In general, maximal levels of DNA scission (i.e. Cmax) varied over a considerably larger range than did the apparent affinity of etoposide (i.e. Km) for these sites, and there was no correlation between these two kinetic parameters. Furthermore, enzyme·drug binding and order of addition experiments indicated that etoposide and topoisomerase II form a kinetically competent complex in the absence of DNA. These findings suggest that etoposide· topoisomerase II (rather than etoposide·DNA) interactions mediate cleavage complex formation. Finally, rates of religation at specific sites correlated inversely with Cmax values, indicating that maximal levels of etoposide-induced scission reflect the ability of the drug to inhibit religation at specific sequences rather than the affinity of the drug for site-specific enzyme-DNA complexes.

Apurinic Sites Are Position-specific Topoisomerase II Poisons

Many anticancer drugs “poison” topoisomerase II by enhancing its double-stranded DNA cleavage activity. To determine whether DNA lesions act as endogenous topoisomerase II poisons, we characterized the effects of position-specific apurinic sites on enzyme activity. Lesions located within the 4-base overhang generated by enzyme-mediated DNA scission stimulated cleavage ∼10-18-fold without altering the specificity of topoisomerase II. DNA breaks were double-stranded in nature, protein-linked, and readily reversible. In contrast, apurinic sites located immediately outside the cleavage overhang were inhibitory. Thus, apurinic sites, which are the most commonly formed lesion in DNA, are position-specific topoisomerase II poisons. A model is proposed that encompasses the actions of endogenous and exogenous topoisomerase II poisons and provides a pre-existing pathway for the cellular actions of topoisomerase II-targeted anticancer drugs.

THE RESPONSE OF EUKARYOTIC TOPOISOMERASES TO DNA DAMAGE

Beyond the known mutagenic properties of DNA lesions, recent evidence indicates that several forms of genomic damage dramatically influence the catalytic activities of DNA topoisomerases. Apurinic sites, apyrimidinic sites, base mismatches, and ultraviolet photoproducts all enhance topoisomerase I-mediated DNA cleavage when they are located in close proximity to the point of scission. Furthermore, when located between the points of scission of a topoisomerase II cleavage site, these same lesions (with the exception of ultraviolet photoproducts) greatly stimulate the cleavage activity of the type II enzyme. Thus, as found for anticancer drugs, lesions have the capacity to convert topoisomerases from essential cellular enzymes to potent DNA toxins. These findings raise exciting new questions regarding the mechanism of anticancer drugs, the physiological functions of topoisomerases, and the processing of DNA damage in the cell.

Abasic Sites Stimulate Double-stranded DNA Cleavage Mediated by Topoisomerase II DNA LESIONS AS ENDOGENOUS TOPOISOMERASE II POISONS

Several clinically relevant anticancer drugs induce genomic mutations and cell death by increasing topoisomerase II-mediated DNA breakage. To determine whether endogenous DNA damage also affects this cleavage event, the effects of abasic sites (the most commonly formed spontaneous DNA lesion) on topoisomerase II activity were investigated. The presence of 3 abasic sites/plasmid stimulated enzyme-mediated DNA breakage >6-fold, primarily by enhancing the forward rate of cleavage. This corresponds to a potency that is >2000-fold higher than that of the anticancer drug, etoposide. These findings suggest that abasic sites represent endogenous topoisomerase II poisons and imply that anticancer drugs mimic the cleavage-enhancing actions of naturally occurring DNA lesions.

Spontaneous DNA Damage Stimulates Topoisomerase II-mediated DNA Cleavage

Apurinic sites are position-specific poisons of topoisomerase II and stimulate DNA scission ∼10-18-fold when they are located within the 4-base overhang generated by enzyme-mediated cleavage (Kingma, P. S., and Osheroff, N. (1997) J. Biol. Chem. 272, 1148-1155). To determine whether other major forms of spontaneous DNA damage also act as topoisomerase II poisons, the effects of position-specific apyrimidinic sites and deaminated cytosines (i.e. uracil:guanine mismatches) on the type II enzyme were determined. Both of these lesions stimulated topoisomerase II-mediated DNA scission with the same positional specificity as apurinic sites but were less efficacious. Moreover, apurinic sites dominated the effects of apyrimidinic sites in substrates that contained multiple lesions. The differential ability of spontaneous lesions to enhance DNA cleavage did not correlate with either a decreased stability of the double helix or the size of the gap formed by base loss. Rather, it appears to be due (at least in part) to increased rates of religation for substrates containing apyrimidinic sites or deaminated cytosines. These results suggest that several forms of spontaneous DNA damage are capable of acting as endogenous poisons of topoisomerase II.

Correction of pulmonary abnormalities in Sftpd-/- mice requires the collagenous domain of surfactant protein D.

Surfactant protein D (SP-D) is a member of the collectin family of innate defense proteins. Members of this family share four distinct structural domains: an N-terminal cross-linking domain, a collagenous domain, a neck region, and a carbohydrate recognition domain. In this study, the function of the collagenous domain was evaluated by expressing a SP-D collagen deletion mutant protein (rSftpdCDM) in wild type and SP-D null mice (Sftpd-/-). rSftpdCDM formed disulfide-linked trimers that further oligomerized into higher order structures. The mutant protein effectively bound carbohydrate and aggregated bacteria in vitro. Whereas rSftpdCDM did not disrupt pulmonary morphology or surfactant phospholipid levels in wild type mice, the mutant protein failed to rescue the emphysema or enlarged foamy macrophages that are characteristic of Sftpd-/- mice. Moreover, rSftpdCDM partitioned with small aggregate surfactant in a manner similar to SP-D, but rSftpdCDM did not correct the abnormal surfactant ultrastructure or phospholipid levels observed in Sftpd-/- mice. In contrast, rSftpdCDM completely corrected viral clearance and the abnormal inflammatory response that occurs following pulmonary influenza A challenge in Sftpd-/- mice. Our findings indicate that the collagen domain of SP-D is not required for assembly of disulfide-stabilized oligomers or the innate immune response to viral pathogens. The collagen domain of SP-D is required for the regulation of pulmonary macrophage activation, airspace remodeling, and surfactant lipid homeostasis.

Topoisomerase II-mediated DNA cleavage and religation in the absence of base pairing. Abasic lesions as a tool to dissect enzyme mechanism.

The interaction of topoisomerase II with its DNA cleavage site is critical to the physiological functions of the enzyme. Despite this importance, the specific enzyme-DNA interactions that drive topoisomerase II-mediated DNA cleavage and religation are poorly understood. Therefore, to dissect interactions between the enzyme and its cleavage site, abasic DNA lesions were incorporated into a bilaterally symmetrical and identical cleavage site. Results indicate that topoisomerase II has unique interactions with each position of the 4-base overhang generated by enzyme-mediated DNA cleavage. Lesions located 2 bases 3′ to the point of scission stimulated cleavage the most, whereas those 3 bases from the point of scission stimulated cleavage the least. Moreover, an additive and in some cases synergistic cleavage enhancement was observed in oligonucleotides that contained multiple DNA lesions, with levels reaching >60-fold higher than the wild-type substrate. Finally, topoisomerase II efficiently cleaved and religated a DNA substrate in which apyrimidinic sites were simultaneously incorporated at every position on one strand of the 4-base overhang. Therefore, unlike classical DNA ligases in which base pairing is the driving force behind closure of the DNA break, it appears that for topoisomerase II, the enzyme is responsible for the spatial orientation of the DNA termini for ligation.