In eukaryotic cells, genomic DNA is primarily packaged into nucleosomes through sequential ordered binding of the core and linker histone proteins. The acidic proteins termed histone chaperones are known to bind to core histones to neutralize their positive charges, thereby facilitating their proper deposition onto DNA to assemble the core of nucleosomes. For linker histones, however, little has been known about the regulatory mechanism for deposition of linker histones onto the linker DNA. Here we report that, in Xenopus eggs, the linker histone is associated with the Xenopus homologue of nucleosome assembly protein-1 (NAP-1), which is known to be a chaperone for the core histones H2A and Xenopus laevis ͉ chromatosome assembly ͉ cell-free system
SummaryMultiple RNA polymerase II (RNAPII) molecules can transcribe a gene simultaneously, but what happens when such polymerases collide—for example due to polymerase pausing or DNA damage? Here, RNAPII collision was characterized using a reconstituted system for simultaneous transcription by two polymerases. When progression of leading polymerase is obstructed, rear-end collision entails a transient state in which the elongation complexes interact, followed by substantial backtracking of trailing polymerase. Elongation complexes remain stable on DNA, with their activity and the integrity of transcription bubbles remaining intact. Subsequent TFIIS-stimulated transcript cleavage allows resumed forward translocation, resulting in trailing polymerase oscillating at the obstruction. Conversely, if leading polymerase is merely stalled at a pause site, collision and TFIIS cooperate to drive it through. We propose that dynamic interactions between RNAPII elongation complexes help regulate polymerase traffic and that their conformational flexibility buffers the effect of collisions with objects on DNA, thereby maintaining stability in the face of obstacles to transcription.
Complex transitions in chromatin structure produce changes in genome function during development in metazoa. Linker histones, the last component of nucleosomes to be assembled into chromatin, comprise considerably divergent subtypes as compared with core histones. In all metazoa studied, their composition changes dramatically during early embryogenesis concomitant with zygotic gene activation, leading to distinct functional changes that are still poorly understood. Here, we show that early embryonic linker histone B4, which is maternally expressed, is functionally different from somatic histone H1 in influencing chromatin structure and dynamics. We developed a chromatin assembly system with nucleosome assembly protein-1 as a linker histone chaperone. This assay system revealed that maternal histone B4 allows chromatin to be remodeled by ATP-dependent chromatin remodeling factor, whereas somatic histone H1 prevents this remodeling. Structural analysis shows that histone B4 does not significantly restrict the accessibility of linker DNA. These findings define the functional significance of developmental changes in linker histone variants. We propose a model that holds that maternally expressed linker histones are key molecules specifying nuclear dynamics with respect to embryonic totipotency.ATP-dependent chromatin remodeling ͉ linker histone assembly
Transcriptional arrest triggers ubiquitylation of RNA polymerase II (RNAPII). We mapped the yeast RNAPII ubiquitylation sites and found that they play an important role in elongation and the DNA-damage response. One site lies in a protein domain that is unordered in free RNAPII, but ordered in the elongating form, helping explain the preferential ubiquitylation of this form. The other site is >125 Angstroms away, yet mutation of either site affects ubiquitylation of the other, in vitro and in vivo. The basis for this remarkable coupling was uncovered: an Rsp5 (E3) dimer assembled on the RNAPII C-terminal domain (CTD). The ubiquitylation sites bind Ubc5 (E2), which in turn binds Rsp5 to allow modification. Evidence for folding of the CTD compatible with this mechanism of communication between distant sites is provided. These data reveal the specificity and mechanism of RNAPII ubiquitylation and demonstrate that E2s can play a crucial role in substrate recognition.
Transcript elongation by RNA polymerase II is a surprisingly complex process that is affected by a number of different factors. Biochemical analyses of transcription support the idea that transcript elongation involves frequent pausing and even arrest, which has to be overcome in order for overall transcription to be efficient. A defining response to any transcription obstacle is retrograde motion of RNAPII, so‐called backtracking, during which RNAPII looses contact with the 3′‐end of the RNA and often needs the help of general elongation factor TFIIS (also called SII) to recover. However, a large number of factors associate with, and affect the function of elongating RNAPII. In this talk, our recent studies of the basic mechanism of transcript elongation, including the effect of such co‐factors, will be discussed.
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