The FACT histone chaperone guides histone H4 into its nucleosomal conformation in Saccharomyces cerevisiae.

The pob3-Q308K mutation alters the small subunit of the Saccharomyces cerevisiae histone/nucleosome chaperone Facilitates Chromatin Transactions (FACT), causing defects in both transcription and DNA replication. We describe histone mutations that suppress some of these defects, providing new insight into the mechanism of FACT activity in vivo. FACT is primarily known for its ability to promote reorganization of nucleosomes into a more open form, but neither the pob3-Q308K mutation nor the compensating histone mutations affect this activity. Instead, purified mutant FACT complexes fail to release from nucleosomes efficiently, and the histone mutations correct this flaw. We confirm that pob3-T252E also suppresses pob3-Q308K and show that combining two suppressor mutations can be detrimental, further demonstrating the importance of balance between association and dissociation for efficient FACT:nucleosome interactions. To explain our results, we propose that histone H4 can adopt multiple conformations, most of which are incompatible with nucleosome assembly. FACT guides H4 to adopt appropriate conformations, and this activity can be enhanced or diminished by mutations in Pob3 or histones. FACT can therefore destabilize nucleosomes by favoring the reorganized state, but it can also promote assembly by tethering histones and DNA together and maintaining them in conformations that promote canonical nucleosome formation.

Fetal and postnatal lung defects reveal a novel and required role for Fgf8 in lung development.

The fibroblast growth factor, FGF8, has been shown to be essential for vertebrate cardiovascular, craniofacial, brain and limb development. Here we report that Fgf8 function is required for normal progression through the late fetal stages of lung development that culminate in alveolar formation. Budding, lobation and branching morphogenesis are unaffected in early stage Fgf8 hypomorphic and conditional mutant lungs. Excess proliferation during fetal development disrupts distal airspace formation, mesenchymal and vascular remodeling, and Type I epithelial cell differentiation resulting in postnatal respiratory failure and death. Our findings reveal a previously unknown, critical role for Fgf8 function in fetal lung development and suggest that this factor may also contribute to postnatal alveologenesis. Given the high number of premature infants with alveolar dysgenesis and lung dysplasia, and the accumulating evidence that short-term benefits of available therapies may be outweighed by long-term detrimental effects on postnatal alveologenesis, the therapeutic implications of identifying a factor or pathway that can be targeted to stimulate normal alveolar development are profound.

Nuclear localization is required for induction of apoptotic cell death by the Rb-associated p84N5 death domain protein.

The mechanisms utilized to transduce apoptotic signals that originate from within the nucleus, in response to DNA damage for example, are not well understood. Identifying these mechanisms is important for predicting how tumor cells will respond to genotoxic radiation or chemotherapy. The Rb tumor suppressor protein can inhibit apoptosis triggered by DNA damage, but how it does so is unclear. We have previously characterized a death domain protein, p84N5, that specifically associates with an amino-terminal domain of Rb protein. The p84N5 death domain is required for its ability to trigger apoptotic cell death. Association with Rb protein inhibits p84N5-induced apoptosis suggesting that it may be a mediator of Rb's effects on apoptosis. Unlike other death domain-containing apoptotic signaling proteins, however, p84N5 is localized predominantly within the nucleus of interphase cells. Here we test whether p84N5 requires nuclear localization in order to trigger apoptosis. We identify the p84N5 nuclear localization signal and demonstrate that nuclear localization is required for p84N5-induced apoptosis. To our knowledge, this identifies p84N5 as the first death-domain containing apoptotic signaling protein that functions within the nucleus. By analogy to other death domain containing proteins, p84N5 may play some role in apoptotic signaling within the nucleus. Further, p84N5 is a potential mediator of Rb protein's effects on DNA damage induced apoptosis.