Translation initiation factor 2 (eIF2) is a heterotrimeric protein that transfers methionyl-initiator tRNAMet to the small ribosomal subunit in a ternary complex with GTP. The eIF2 phosphorylated on serine 51 of its ␣ subunit [eIF2(␣P)] acts as competitive inhibitor of its guanine nucleotide exchange factor, eIF2B, impairing formation of the ternary complex and thereby inhibiting translation initiation. eIF2B is comprised of catalytic and regulatory subcomplexes harboring independent eIF2 binding sites; however, it was unknown whether the ␣ subunit of eIF2 directly contacts any eIF2B subunits or whether this interaction is modulated by phosphorylation. We found that recombinant eIF2␣ (glutathione S-transferase [GST]-SUI2) bound to the eIF2B regulatory subcomplex in vitro, in a manner stimulated by Ser-51 phosphorylation. Genetic data suggest that this direct interaction also occurred in vivo, allowing overexpressed SUI2 to compete with eIF2(␣P) holoprotein for binding to the eIF2B regulatory subcomplex. Mutations in SUI2 and in the eIF2B regulatory subunit GCD7 that eliminated inhibition of eIF2B by eIF2(␣P) also impaired binding of phosphorylated GST-SUI2 to the eIF2B regulatory subunits. These findings provide strong evidence that tight binding of phosphorylated SUI2 to the eIF2B regulatory subcomplex is crucial for the inhibition of eIF2B and attendant downregulation of protein synthesis exerted by eIF2(␣P). We propose that this regulatory interaction prevents association of the eIF2B catalytic subcomplex with the  and ␥ subunits of eIF2 in the manner required for GDP-GTP exchange.
Sporulation in Saccharomyces cerevisiae is a highly regulated process wherein a diploid cell gives rise to four haploid gametes. In this study we show that histone H4 Ser1 is phosphorylated (H4 S1ph) during sporulation, starting from mid-sporulation and persisting to germination, and is temporally distinct from earlier meiosis-linked H3 S10ph involved in chromosome condensation. A histone H4 S1A substitution mutant forms aberrant spores and has reduced sporulation efficiency. Deletion of sporulation-specific yeast Sps1, a member of the Ste20 family of kinases, nearly abolishes the sporulation-associated H4 S1ph modification. H4 S1ph may promote chromatin compaction, since deletion of SPS1 increases accessibility to antibody immunoprecipitation; furthermore, either deletion of Sps1 or an H4 S1A substitution results in increased DNA volume in nuclei within spores. We find H4 S1ph present during Drosophila melanogaster and mouse spermatogenesis, and similar to yeast, this modification extends late into sperm differentiation relative to H3 S10ph. Thus, H4 S1ph may be an evolutionarily ancient histone modification to mark the genome for gamete-associated packaging.[Keywords: Saccharomyces cerevisiae; fly and mouse spermatogenesis; genome compaction; histone H4 phosphorylation; kinase; yeast sporulation] Genetic and epigenetic information is transferred to a new cell generation through the gametogenesis process. Dramatic changes in chromatin structure occur during both metazoan spermatogenesis and yeast sporulation involving DNA compaction. In addition, spermatogenesis requires removal of most canonical histones and substitution with histone variants and histone replacement proteins (Govin et al. 2004; Kimmins and SassoneCorsi 2005).The nucleosome is the fundamental repeating unit of chromatin and harbors an octamer of basic histone proteins (two copies of dimeric H3/H4 and H2A/H2B) wrapped by ∼147 base pairs (bp) of DNA (Luger et al. 1997). Nucleosomes pack into higher-order chromatin structures, whose precise architectures are not understood. Post-translational modifications (PTMs) of histones (including acetylation, phosphorylation, methylation, and ubiquitylation) regulate chromatin function and contribute to its folding. PTMs occur in distinct patterns and in diverse cellular pathways. For example, H3 S10ph correlates with both mitotic/meiotic chromosome condensation and transcriptional activation (Nowak and Corces 2004). Chromosome condensation includes a large number of possibly redundant histone phosphorylation marks, including S10 (Hendzel et al. 1997), T3 (Polioudaki et al. 2004), T11 (Preuss et al. 2003, S28 (Goto et al. 1999S28 (Goto et al. , 2002 within H3, S1 within H4 (Barber et al. 2004), S1 within H2A (Barber et al. 2004), and S10 in H2B (Ahn et al. 2005b). Phosphorylation at H3 S10 has been causally linked to mitotic
Distinct patterns of posttranslational histone modifications can regulate DNA-templated events such as mitosis, transcription, replication, apoptosis, and DNA damage, suggesting the presence of a "histone code" in these nuclear processes. Phosphorylation of histone H2A S129 at sites of DNA double-strand breaks (DSBs) has been implicated in damage repair in yeast. Here, we describe another phosphorylation event on serine 1 (S1) of histone H4; this event is also associated with MMS- or phleomycin-induced DSBs but not with UV-induced DNA damage. Chromatin-immunoprecipitation (ChIP) studies of an HO-endonuclease-inducible strain show that S1 phosphorylation is specifically enhanced 20- to 25-fold in nucleosomes proximal to the DSB. In addition, we show that casein kinase II (CK2) can phosphorylate H4 S1 in vitro and that null or temperature-sensitive CK2 yeast mutants are defective for induction of H4 S1 phosphorylation upon DNA damage in vivo. Furthermore, H4 S1 phosphorylation and CK2 play a role in DSB re-joining as indicated by a nonhomologous end-joining (NHEJ) plasmid assay. CK2 has been implicated in regulating a DNA-damage response; our data suggest that histone H4 S1 is one of its physiological substrates. These data suggest that this modification is a part of the DNA-repair histone code.
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