Drosophila engrailed-1,10-phenanthroline chimeras as probes of homeodomain-DNA complexes

High-resolution digital profiling of the epigenome

The widespread adoption of short-read DNA sequencing as a digital epigenomic readout platform has motivated the development of genome-wide tools that achieve base-pair resolution. New methods for footprinting and affinity purification of nucleosomes, RNA polymerases, chromatin remodellers and transcription factors have increased the resolution of epigenomic profiling by two orders of magnitude, leading to new insights into how the chromatin landscape affects gene regulation. These digital epigenomic tools have also been applied to directly profile both turnover kinetics and transcription in situ. In this Review, we describe how these new genome-wide tools allow interrogation of diverse aspects of the epigenome.

Site-specific DNA cleavage of synthetic NarL sites by an engineered Escherichia coli NarL protein-1,10-phenanthroline cleaving agent

The NarL response regulatory protein of Escherichia coli has been engineered by covalent modification with 1,10-phenanthroline (OP) to create a set of site-specific DNA-cleaving agents. This was accomplished by introducing single cysteine amino acid replacements at selected locations within the carboxy-terminal DNA-binding domain in or nearby the helix 8 to helix 9 region of the NarL protein using site-directed mutagenesis. Of 18 modified NarL-OP proteins made, 13 retained the ability to bind DNA as evidenced by gel mobility assays, whereas 10 of the 1,10-phenanthroline-modified proteins also exhibited specific cleavage activity for a synthetic NarL recognition sequence. These DNA-cleaving agents were divided into two groups based on the location of the cleavage sites. The first class set cleaved the DNA nearby the center of a synthetic 7-2-7 sequence composed of two NarL heptamer sites separated by a 2-bp spacer element. The second class cut the DNA at the periphery of the 7-2-7 sequence. The cleavage data are consistent with the ability of two NarL monomers to recognize and bind to the DNA in a head-to-head orientation. A second set of DNA-cleaving agents was constructed using the carboxy-terminal domain of NarL called NarL(C). Similar cleavage patterns were observed whether full-length NarL or NarL(C) was used. The availability of 1,10-phenanthroline-modified NarL and NarL(C) proteins opens up the possibility to explore the position, orientation, and number of NarL recognition sites at E. coli promoters predicted to contain multiple and complex arrangements of NarL-binding sites.

Probing contacts between the ribonuclease H domain of HIV-1 reverse transcriptase and nucleic acid by site-specific photocross-linking

Cys(38) and Cys(280) of p66/p51 human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) can be converted to Ser without affecting enzyme function. We have exploited this feature to construct and purify "monocysteine" RT derivatives for site-specific modification with the photoactivable cross-linking agent, p-azidophenacyl bromide. Acylation of a unique cysteine residue introduced at the extreme C terminus of the p66 subunit (C(561)) with an azidophenacyl group allowed us to probe contacts between residues C-terminal to alpha-helix E' of the RNase H domain and structurally divergent nucleic acid duplexes. In a binary complex of RT and template-primer, we demonstrate efficient cross-linking to primer nucleotides -21 to -24/-25, and template nucleotides -18 to -21. Cross-linking specificity was confirmed by an analogous evaluation following limited primer extension, where the profile is displaced by the register of DNA synthesis. Finally, contact with a DNA primer hybridized to an isogenic RNA or DNA template indicates subtle alterations in cross-linking specificity, suggesting differences in nucleic acid geometry between duplex DNA and RNA/DNA hybrids at the RNase H domain. These data exemplify how site-specific acylation of HIV-1 RT can be used to provide high resolution structural data to complement crystallographic studies.

The design of protein-based catalysts using semisynthetic methods

The combination of site-directed mutagenesis and chemical modification has resulted in the preparation of protein conjugates with new and useful properties. Proteins modified with metal-chelating groups are proving useful for mapping tertiary and quaternary interactions using the technique of affinity cleavage. The attachment of cofactors, including pyridoxal and pyridoxamine, has resulted in the preparation of semisynthetic transaminases that display enzyme-like properties, including enantioselectivity, substrate specificity and reaction-rate acceleration.

The DNA binding specificity of engrailed homeodomain

The engrailed gene of Drosophila melanogaster is an integral member of the highly complex cascade which results in a fully developed fruitfly. The gene product of engrailed contains a homeodomain which is responsible for DNA binding via a helix-turn-helix motif. The crystal structure of this 60 amino acid residue domain complexed to DNA is analogous to structures of other homeodomain-DNA complexes, consistent with the high degree of sequence conservation within both protein and DNA. Despite the high degree of homology, homeodomains do exhibit distinct preferences for certain DNA sequences. Such specificity may be at least partly responsible for the interactions necessary for normal development. Using the hydroxyl radical as a chemical probe, we have examined complexes of Engrailed homeodomain with several DNA sequences to determine the protein's binding specificity in solution. We find that Engrailed forms a single, specific complex with a unique DNA binding site which is analogous to the complex seen in the co-crystal structure. In contrast, our chemical probe experiments show that the binding site of Engrailed that was determined by in vitro selection and that also was present in the co-crystal structure contains two possible binding sites. Modification of the sequence of this site to yield single binding sites removes the ambiguity, and results in two different, well-behaved Engrailed-DNA complexes. Our results underscore the utility of chemical probe experiments for defining the variety of modes of interaction of proteins with DNA that can occur in solution, but that might not be apparent in a crystal structure.