Detection of in vivo protein-DNA interactions using DamID in mammalian cells

Understanding gene regulatory networks in mammalian cells requires detailed knowledge of protein-DNA interactions. Commonly used methods for genome-wide mapping of these interactions are based on chromatin immunoprecipitation. However, these methods have some drawbacks, such as the use of crosslinking reagents, the need for highly specific antibodies and relatively large amounts of starting material. We present DamID, an alternative technique to map genome-wide occupancy of interaction sites in vivo, that bypasses these limitations. DamID is based on the expression of a fusion protein consisting of a protein of interest and DNA adenine methyltransferase (Dam). This leads to methylation of adenines near sites where the protein of interest interacts with the DNA. These methylated sequences are subsequently amplified by a methylation-specific PCR protocol and identified by hybridization to microarrays. Using DamID, genome-wide maps of the binding of DNA-interacting proteins in mammalian cells can be constructed efficiently. Depending on the strategy used for expression of the Dam-fusion proteins, genome-wide binding maps can be obtained in as little as 2 weeks.     

In situ detection of protein-DNA interactions in filamentous fungi by in vivo footprinting.

The method described here allows the detection of protein-DNA interactions in vivo in filamentous fungi. We outline culture conditions and conditions of in vivo methylation that permit uniform modification of all cells in an apically growing, non-uniform organism, and subsequent visualization of protected areas by ligation-mediated PCR.     

In vitro protein-DNA interactions at the human lamin B2 replication origin

The complexity of mammalian origins of DNA replication has prevented, so far, the in vitro studies of the modalities of initiator protein binding and origin selection. We approached this problem by utilizing the human lamin B2 origin, wherein the precise start sites of replication initiation have been identified and known to be bound in vivo by the origin recognition complex (ORC). In order to analyze the in vitro interactions occurring at this origin, we have compared the DNA binding requirements and patterns of the human recombinant Orc4 with those of preparations of HeLa nuclear proteins containing the ORC complex. Here we show that both HsOrc4 alone and HeLa nuclear proteins recognize multiple sites within a 241-bp DNA sequence encompassing the lamin B2 origin. The DNA binding activity of HeLa cells requires the presence of ORC and can be reproduced in the absence of all the other proteins known to be recruited to origins by ORC. Both HsOrc4 alone and HeLa nuclear proteins exhibit cooperative and ATP-independent binding. This binding covers nucleotides 3853-3953 and then spreads outward. Because this region contains the start sites of DNA synthesis as well as the area protected in vivo and preserves protein binding capacity in vitro after removal of a fraction of the protected region, we suggest that it could contain the primary binding site. Thus the in vitro approach points to the sequence requirements for ORC binding as a key element for origin recognition.