Nucleosome organization at promoter regions plays an important role in regulating gene activity. Genome-wide studies in yeast, flies, worms, mammalian embryonic stem cells and transformed cell lines have found well-positioned nucleosomes flanking a nucleosome depleted region (NDR) at transcription start sites. This nucleosome arrangement depends on DNA sequence (cis-elements) as well as DNA binding factors and ATP-dependent chromatin modifiers (trans-factors). However, little is understood about how the nascent embryonic genome positions nucleosomes during development. This is particularly intriguing since the embryonic genome must undergo a broad reprogramming event upon fusion of sperm and oocyte. Using four stages of early embryonic zebrafish development, we map nucleosome positions at the promoter region of 37 zebrafish hox genes. We find that nucleosome arrangement at the hox promoters is a progressive process that takes place over several stages. At stages immediately after fertilization, nucleosomes appear to be largely disordered at hox promoter regions. At stages after activation of the embryonic genome, nucleosomes are detectable at hox promoters, with positions becoming more uniform and more highly occupied. Since the genomic sequence is invariant during embryogenesis, this progressive change in nucleosome arrangement suggests that trans-factors play an important role in organizing nucleosomes during embryogenesis. Separating hox genes into expressed and non-expressed groups shows that expressed promoters have better positioned and occupied nucleosomes, as well as distinct NDRs, than non-expressed promoters. Finally, by blocking the retinoic acid-signaling pathway, we disrupt early hox gene transcription, but observe no effect on nucleosome positions, suggesting that active hox transcription is not a driving force behind the arrangement of nucleosomes at the promoters of hox genes during early development.

Hox genes encode a conserved family of homeodomain containing transcription factors essential for metazoan development. The establishment of overlapping Hox expression domains specifies tissue identities along the anterior-posterior axis during early embryogenesis and is regulated by chromatin architecture and retinoic acid (RA). Here we present the role nucleosome positioning plays in hox activation during embryogenesis. Using four stages of early embryo development, we map nucleosome positions at 37 zebrafish hox promoters. We find nucleosome arrangement to be progressive, taking place over several stages independent of RA. This progressive change in nucleosome arrangement on invariant sequence suggests that trans-factors play an important role in organizing nucleosomes. To further test the role of trans-factors, we created hoxb1b and hoxb1a mutants to determine if the loss of either protein effected nucleosome positions at the promoter of a known target, hoxb1a. Characterization of these mutations identified hindbrain segmentation defects similar to targeted deletions of mouse orthologs Hoxa1 and Hoxb1 and zebrafish hoxb1b and hoxb1a morpholino (MO) loss-of-function experiments. However, we also identified differences in hindbrain segmentation as well as phenotypes in facial motor neuron migration and reticulospinal neuron formation not previously observed in the MO experiments. Finally, we find that nucleosomes at the hoxb1a promoter are positioned differently in hoxb1b-/- embryos compared to wild-type. Together, our data provides new insight into the roles of hoxb1b and hoxb1a in zebrafish hindbrain segmentation and reticulospinal neuron formation and indicates that nucleosome positioning at hox promoters is dynamic, depending on sequence specific factors such as Hox proteins.

Polyhomeotic (Ph), which forms complexes with other Polycomb-group (PcG) proteins, is widely required for maintenance of cell identity by ensuring differential gene expression patterns in distinct types of cells. Genetic mosaic screens in adult fly brains allow for recovery of a mutation that simultaneously disrupts the tandemly duplicated Drosophila ph transcriptional units. Distinct clones of neurons normally acquire different characteristic projection patterns and can be differentially labeled using various subtype-specific drivers in mosaic brains. Such neuronal diversity is lost without Ph. In response to ecdysone, ph mutant neurons are transformed into cells with unidentifiable projection patterns and indistinguishable gene expression profiles during early metamorphosis. Some subtype-specific neuronal drivers become constitutively activated, while others are constantly suppressed. By contrast, loss of other PcG proteins, including Pc and E(z), causes different neuronal developmental defects; and, consistent with these phenomena, distinct Hox genes are differentially misexpressed in different PcG mutant clones. Taken together, Drosophila Ph is essential for governing neuronal diversity, especially during steroid hormone signaling.