Eaf1 (for Esa1-associated factor 1) and Eaf2 have been identified as stable subunits of NuA4, a yeast histone H4/H2A acetyltransferase complex implicated in gene regulation and DNA repair. While both SWI3-ADA2-N-CoR-TF IIIB domain-containing proteins are required for normal cell cycle progression, their depletion does not affect the global Esa1-dependent acetylation of histones. In contrast to all other subunits, Eaf1 is found exclusively associated with the NuA4 complex in vivo. It serves as a platform that coordinates the assembly of functional groups of subunits into the native NuA4 complex. Eaf1 shows structural similarities with human p400/Domino, a subunit of the NuA4-related TIP60 complex. On the other hand, p400 also possesses an SWI2/SNF2 family ATPase domain that is absent from the yeast NuA4 complex. This domain is highly related to the yeast Swr1 protein, which is responsible for the incorporation of histone variant H2AZ in chromatin. Since all of the components of the TIP60 complex are homologous to SWR1 or NuA4 subunits, we proposed that the human complex corresponds to a physical merge of two yeast complexes. Chromatin is a very dynamic structure, and it plays an intricate regulatory role in DNA replication, transcription, and repair. Two major types of activities regulating chromatin structure and function have been studied extensively over the past few years and have been functionally linked together in diverse nuclear processes (65). ATP-dependent chromatin-remodeling complexes of the SWI2/SNF2 family disrupt DNAhistone contacts within nucleosomes, increasing DNA accessibility and nucleosome mobility (25). Histone-modifying complexes target specific residues on histones for acetylation, methylation, phosphorylation, and ubiquitinylation. These modifications can affect the level of DNA compaction but also serve as markers identifying the chromatin state of specific genomic loci. Different histone modifications influence each other and create a specific local signature that can be recognized by protein domains present in various regulators, e.g., bromodomains for acetylated lysines and chromodomains for methylated lysines. These posttranslational modifications are reversible and highly dynamic during cell growth (36). Diverse ATP-dependent remodelers and histone modifiers have been shown to be recruited to specific loci through direct interactions with DNA-bound factors. For example, histone acetyltransferase (HAT) and histone deacetylase (HDAC) complexes are recruited to specific promoter regions by transcriptional activators or repressors (61). The local incorporation of specific histone variants is an additional mechanism that regulates chromatin function. Activities responsible for these incorporations recently have been identified, and a specific class of ATP-dependent remodelers has been implicated in this process (31,40).Nucleosome acetyltransferase of H4 (NuA4) is a multisubunit HAT complex that is highly conserved in eukaryotes and plays important roles in transcription and DNA repair (2...
NuA4 is an essential histone H4/H2A acetyltransferase complex that interacts with activators and stimulates transcription in vitro. We have identified three novel NuA4 subunits: Act3/Arp4, an actin-related protein implicated in epigenetic control of transcription, Act1, and Epl1, a protein homologous to Drosophila Enhancer of Polycomb. Act3/Arp4 binds nucleosomes in vitro and is required for NuA4 integrity in vivo. Mutations in ACT3 and acetyltransferase-encoding ESA1 cause gene-specific transcription defects. Accordingly, NuA4 is localized in precise loci within the nucleus and does not overlap with the silent chromatin marker Sir3. These data along with the known epigenetic roles of Act3/Arp4 and homologs of Epl1 and Esa1 strongly support an essential role for chromatin structure modification by NuA4 in transcription regulation in vivo.
The alpha1-fetoprotein (AFP) gene is located between the albumin and alpha-albumin genes and is activated by transcription factor FTF (fetoprotein transcription factor), presumed to transduce early developmental signals to the albumin gene cluster. We have identified FTF as an orphan nuclear receptor of the Drosophila FTZ-F1 family. FTF recognizes the DNA sequence 5'-TCAAGGTCA-3', the canonical recognition motif for FTZ-F1 receptors. cDNA sequence homologies indicate that rat FTF is the ortholog of mouse LRH-1 and Xenopus xFF1rA. Rodent FTF is encoded by a single-copy gene, related to the gene encoding steroidogenic factor 1 (SF-1). The 5.2-kb FTF transcript is translated from several in-frame initiator codons into FTF isoforms (54 to 64 kDa) which appear to bind DNA as monomers, with no need for a specific ligand, similar KdS (approximately equal 3 x 10(-10) M), and similar transcriptional effects. FTF activates the AFP promoter without the use of an amino-terminal activation domain; carboxy-terminus-truncated FTF exerts strong dominant negative effects. In the AFP promoter, FTF recruits an accessory trans-activator which imparts glucocorticoid reactivity upon the AFP gene. FTF binding sites are found in the promoters of other liver-expressed genes, some encoding liver transcription factors; FTF, liver alpha1-antitrypsin promoter factor LFB2, and HNF-3beta promoter factor UF2-H3beta are probably the same factor. FTF is also abundantly expressed in the pancreas and may exert differentiation functions in endodermal sublineages, similar to SF-1 in steroidogenic tissues. HepG2 hepatoma cells seem to express a mutated form of FTF.
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