The nature of the nucleosomal barrier to transcription: direct observation of paused intermediates by electron cryomicroscopy.

Transcribing SP6 RNA polymerase was arrested at unique positions in the nucleosome core, and the complexes were analyzed using biochemical methods and electron cryomicroscopy. As the polymerase enters the nucleosome, it disrupts DNA-histone interactions behind and up to approximately 20 bp ahead of the elongation complex. After the polymerase proceeds 30-40 bp into the nucleosome, two intermediates are observed. In one, only the DNA ahead of the polymerase reassociates with the octamer. In the other, DNA both ahead of and behind the enzyme reassociates. These intermediates present a barrier to elongation. When the polymerase approaches the nucleosome dyad, it displaces the octamer, which is transferred to promoter-proximal DNA.     

Structure-function relationships in nucleosomal arrays containing linker histone H5

To study the structural and functional changes accompanying the integration of histone H5 into the nucleosome structure, linear DNA species have been employed with a terminal promoter for bacteriophage T7 RNA polymerase followed by tandem repeats of a 207-bp nucleosome positioning sequence. The oligonucleosomes assembled from 12-repeat DNA and saturating amounts of core histone octamer plus histone H5 are compacted, in the presence of 1 mM free magnesium ions, to the level of the 30-nm fiber. Under these ionic conditions the efficiency in RNA synthesis and the size distribution of RNA chains obtained with this template are the same as those corresponding to the template without H5, indicating that the 30-nm fiber stabilized by H5 does not impair RNA elongation. Therefore, under our experimental conditions, incorporation of one molecule of histone H5 per nucleosome does not affect elongation of RNA even when a folded structure is produced. However, elongation is inhibited by binding of an excess of H5.     

Purification and properties of RNA polymerase of phage KB1

Bacteriophage KB1 belongs to group C of Bradely's classification After infection a bacteriophage specific RNA polymerase is induced in infected cells. KB1 RNA polymerase is a stable enzyme and is easily purified to homogeneity in good overall yield. The activity resides in a single polypeptide chain of molecular weight about 90,000. Synthesis of RNA by KB1 RNA polymerase requires a DNA template and Mg++ and like SP6 RNA polymerase, is strongly stimulated by either bovine serum albumin or spermidine. Thiol reactive reagents inhibit the enzyme, suggesting the presence of essential sulfhydryl residues. The enzyme possess a stringent promoter specificity. The KB1 RNA polymerase is also highly active in synthesis of poly(rG) with poly(dI).(dC) as template. My experiments suggest that the catalytic portion of the polymerase can be separated from the RNA polymerase holoenzyme.