Solution structure of a nitrous acid induced DNA interstrand cross-link.

Nitrous acid is a mutagenic agent. It can induce interstrand cross-links in duplex DNA, preferentially at d(CpG) steps: two guanines on opposite strands are linked via a single shared exocyclic imino group. Recent synthetic advances have led to the production of large quantities of such structurally homogenous cross-linked duplex DNA. Here we present the high resolution solution structure of the cross-linked dodecamer [d(GCATCCGGATGC)]2 (the cross-linked guanines are underlined), determined by 2D NMR spectroscopy, distance geometry, restrained molecular dynamics and iterative NOE refinement. The cross-linked guanines form a nearly planar covalently linked 'G:G base pair' with only minor propeller twisting, while the cytidine bases of their normal base pairing partners have been flipped out of the helix and adopt well defined extrahelical positions in the minor groove. On the 5'-side of the cross-link, the minor groove is widened to accommodate these extrahelical bases, and the major groove becomes quite narrow at the cross-link. The cross-linked 'G:G base pair' is well stacked on the spatially adjacent C:G base pairs, particularly on the 3'-side guanines. In addition to providing the first structure of a nitrous acid cross-link in DNA, these studies could be of major importance to the understanding of the mechanisms of nitrous acid cross-linking and mutagenicity, as well as the mechanisms responsible for its repair in intracellular environments. It is also the shortest DNA cross-link structure to be described.

Sequence context effect on the structure of nitrous acid induced DNA interstrand cross-links.

In the preceding paper in this journal, we described the solution structure of the nitrous acid cross-linked dodecamer duplex [d(GCATCCGGATGC)]2 (the cross-linked guanines are underlined). The structure revealed that the cross-linked guanines form a nearly planar covalently linked 'G:G base pair', with the complementary partner cytidines flipped out of the helix. Here we explore the flanking sequence context effect on the structure of nitrous acid cross-links in [d(CG)]2 and the factors allowing the extrahelical cytidines to adopt such fixed positions in the minor groove. We have used NMR spectroscopy to determine the solution structure of a second cross-linked dodecamer duplex, [d(CGCTACGTAGCG)]2, which shows that the identity of the flanking base pairs significantly alters the stacking patterns and phosphate backbone conformations. The cross-linked guanines are now stacked well on adenines preceding the extrahelical cytidines, illustrating the importance of purine- purine base stacking. Observation of an imino proton resonance at 15.6 p.p.m. provides evidence for hydrogen bonding between the two cross-linked guanines. Preliminary structural studies on the cross-linked duplex [d(CGCGACGTCGCG)]2 show that the extrahelical cytidines are very mobile in this sequence context. We suggest that favorable van der Waals interactions between the cytidine and the adenine 2 bp away from the cross-link localize the cytidines in the previous cross-linked structures.

Potent, novel in vitro inhibitors of the Pseudomonas aeruginosa deacetylase LpxC.

Deacetylation of uridyldiphospho-3-O-(R-hydroxydecanoyl)-N-acetylglucosamine by LpxC is the first committed step in the Pseudomonas aeruginosa biosynthetic pathway to lipid A; homologous enzymes are found widely among Gram-negative bacteria. As an essential enzyme for which no inhibitors have yet been reported, the P. aeruginosa LpxC represents a highly attractive target for a novel antibacterial drug. We synthesized several focused small-molecule libraries, each composed of a variable aromatic ring, one of four heterocyclic/spacer moieties, and a hydroxamic acid and evaluated the LpxC inhibition of these compounds against purified P. aeruginosa enzyme. To ensure that the in vitro assay would be as physiologically relevant as possible, we synthesized a tritiated form of the specific P. aeruginosa glycolipid substrate and measured directly the enzymatically released acetate. Several of our novel compounds, predominantly those having fluorinated substituents on the aromatic ring and an oxazoline as the heterocyclic moiety, demonstrated in vitro IC(50) values less than 1 microM. We now report the synthesis and in vitro evaluation of these P. aeruginosa LpxC inhibitors.

Phosphate backbone neutralization increases duplex DNA flexibility: a model for protein binding.

An important component of protein-DNA recognition is the charge neutralization of DNA backbone phosphates and subsequent protein-induced DNA bending. Replacement of phosphates by neutral methylphosphonates has previously been shown to be a model for protein-induced bending. In addition to bending, the neutralization process may change the inherent flexibility of the DNA--a feature never before tested. We have developed a method to measure the differential flexibility of duplex DNA when methylphosphonate substitutions are made and find that the local flexibility is increased up to 40%. These results imply that backbone-neutralization-dependent DNA flexibility augments DNA-binding motifs in protein-DNA recognition processes.