Atomic force microscopy with carbon nanotube probe resolves the subunit organization of protein complexes.

Among many scanning probe microscopies, atomic force microscopy (AFM) is a useful technique to analyse the structure of biological materials because of its applicability to non-conductors in physiological conditions with high resolution. However, the resolution has been limited to an inherent property of the technique; tip effect associated with a large radius of the scanning probe. To overcome this problem, we developed a carbon nanotube probe by attaching a carbon nanotube to a conventional scanning probe under a well-controlled process. Because of the constant and small radius of the tip (2.5-10 nm) and the high aspect ratio (1:100) of the carbon nanotube, the lateral resolution has been much improved judging from the apparent widths of DNA and nucleosomes. The carbon nanotube probes also possessed a higher durability than the conventional probes. We further evaluated the quality of carbon nanotube probes by three parameters to find out the best condition for AFM imaging: the angle to the tip axis; the length; and the tight fixation to the conventional tip. These carbon nanotube probes, with high vertical resolution, enabled us to clearly visualize the subunit organization of multi-subunit proteins and to propose structural models for proliferating cell nuclear antigen and replication factor C. This success in the application of carbon nanotube probes provides the current AFM technology with an additional power for the analyses of the detailed structure of biological materials and the relationship between the structure and function of proteins.

Atomic force microscopy sees nucleosome positioning and histone H1-induced compaction in reconstituted chromatin.

We addressed the question of how nuclear histones and DNA interact and form a nucleosome structure by applying atomic force microscopy to an in vitro reconstituted chromatin system. The molecular images obtained by atomic force microscopy demonstrated that oligonucleosomes reconstituted with purified core histones and DNA yielded a 'beads on a string' structure with each nucleosome trapping 158 +/- 27 bp DNA. When dinucleosomes were assembled on a DNA fragment containing two tandem repeats of the positioning sequence of the Xenopus 5S RNA gene, two nucleosomes were located around each positioning sequence. The spacing of the nucleosomes fluctuated in the absence of salt and the nucleosomes were stabilized around the range of the positioning signals in the presence of 50 mM NaCl. An addition of histone H1 to the system resulted in a tight compaction of the dinucleosomal structure.

Long range interaction of cis-DNA elements mediated by architectural transcription factor Bach1.

BACKGROUND: A central question in vertebrate transcriptional regulation is how cis-regulatory modules, including enhancers, silencers and promoters, communicate with each other over long distances to mandate proper gene expression. In order to address this question we analysed protein/DNA interactions in the human beta-globin locus control region (LCR). One of the many proteins that are potentially implicated in LCR function is Bach1. Bach1 possesses a basic leucine zipper (bZip) domain, as well as a BTB/POZ domain that has been shown to be involved in the regulation of chromatin structure. Bach1 forms heterodimers with small Maf proteins through its leucine zipper and binds to Maf recognition elements (MARE). RESULTS: Using atomic force microscopy we visualized large looped DNA structures between MAREs located in different regulatory elements within the human beta-globin LCR that were mediated by Bach1/MafK heterodimers. The formation of these DNA loops required the Bach1 BTB/POZ protein interaction domain. Furthermore, in transfection studies we found that Bach1 repressed the enhancer activity of the LCR in a BTB/POZ domain-dependent manner. CONCLUSION: Our results suggest that Bach1 and other BTB/POZ transcription factors may represent a class of nuclear architectural proteins that mediate long range interactions between cis-regulatory elements in order to regulate gene expression.