RESUMEN
Hydrogen peroxide (H(2)O(2)) acts as a signaling messenger by oxidatively modifying distinct cysteinyl thiols in distinct target proteins. However, it remains unclear how redox-regulated proteins, which often have low intrinsic reactivity towards H(2)O(2) (k(app) â¼1-10 M(-1) s(-1)), can be specifically and efficiently oxidized by H(2)O(2). Moreover, cellular thiol peroxidases, which are highly abundant and efficient H(2)O(2) scavengers, should effectively eliminate virtually all of the H(2)O(2) produced in the cell. Here, we show that the thiol peroxidase peroxiredoxin-2 (Prx2), one of the most H(2)O(2)-reactive proteins in the cell (k(app) â¼10(7)-10(8) M(-1) s(-1)), acts as a H(2)O(2) signal receptor and transmitter in transcription factor redox regulation. Prx2 forms a redox relay with the transcription factor STAT3 in which oxidative equivalents flow from Prx2 to STAT3. The redox relay generates disulfide-linked STAT3 oligomers with attenuated transcriptional activity. Cytokine-induced STAT3 signaling is accompanied by Prx2 and STAT3 oxidation and is modulated by Prx2 expression levels.
Asunto(s)
Peróxido de Hidrógeno/farmacología , Peroxirredoxinas/metabolismo , Factor de Transcripción STAT3/metabolismo , Transducción de Señal/efectos de los fármacos , Antioxidantes/farmacología , ADN/metabolismo , Células HEK293 , Humanos , Interleucina-6/farmacología , Oxidación-ReducciónRESUMEN
Budding yeast Spc110, a member of γ-tubulin complex receptor family (γ-TuCR), recruits γ-tubulin complexes to microtubule (MT) organizing centers (MTOCs). Biochemical studies suggest that Spc110 facilitates higher-order γ-tubulin complex assembly (Kollman et al., 2010). Nevertheless the molecular basis for this activity and the regulation are unclear. Here we show that Spc110 phosphorylated by Mps1 and Cdk1 activates γ-TuSC oligomerization and MT nucleation in a cell cycle dependent manner. Interaction between the N-terminus of the γ-TuSC subunit Spc98 and Spc110 is important for this activity. Besides the conserved CM1 motif in γ-TuCRs (Sawin et al., 2004), a second motif that we named Spc110/Pcp1 motif (SPM) is also important for MT nucleation. The activating Mps1 and Cdk1 sites lie between SPM and CM1 motifs. Most organisms have both SPM-CM1 (Spc110/Pcp1/PCNT) and CM1-only (Spc72/Mto1/Cnn/CDK5RAP2/myomegalin) types of γ-TuCRs. The two types of γ-TuCRs contain distinct but conserved C-terminal MTOC targeting domains.DOI: http://dx.doi.org/10.7554/eLife.02208.001.
Asunto(s)
Antígenos/fisiología , Ciclo Celular , Microtúbulos/fisiología , Tubulina (Proteína)/fisiología , Secuencia de Aminoácidos , Biopolímeros/metabolismo , Datos de Secuencia Molecular , Fosforilación , Homología de Secuencia de Aminoácido , Tubulina (Proteína)/químicaRESUMEN
Histone modifications play an important role in the formation of an epigenetic memory system that maintains cellular identity. Their complex patterns have been suggested to constitute a histone code, which encodes for specific forms of chromatin. According to the histone code hypothesis these specific patterns are passed on from one cell generation to the next. This enables cells to keep a specific gene expression pattern even in absence of the specific transcription factors that initiated the expression of lineage determining genes. The methylation of specific lysine residues within the histone tails plays a particularly important role in defining the histone modification pattern as mutations of the enzymes that catalyze the formation or the removal of methyl groups have severe effects on cellular physiology. Lysines can get mono-, di- or trimethylated, but the molecular function of the different modification states is still not fully understood. In the following review we will highlight recent data that try to tackle this question and discuss their potential impact for our understanding of the role of histone methylation in epigenetic inheritance.
Asunto(s)
Metilación de ADN/genética , Animales , Cromatina/metabolismo , Metilación de ADN/fisiología , Epigénesis Genética/genética , Epigénesis Genética/fisiología , Histonas/metabolismo , HumanosRESUMEN
To restore chromatin on new DNA during replication, recycling of histones evicted ahead of the fork is combined with new histone deposition. The Asf1 histone chaperone, which buffers excess histones under stress, is a key player in this process. Yet how histones handled by human Asf1 are modified remains unclear. Here we identify marks on histones H3-H4 bound to Asf1 and changes induced upon replication stress. In S phase, distinct cytosolic and nuclear Asf1b complexes show ubiquitous H4K5K12diAc and heterogeneous H3 marks, including K9me1, K14ac, K18ac, and K56ac. Upon acute replication arrest, the predeposition mark H3K9me1 and modifications typical of chromatin accumulate in Asf1 complexes. In parallel, ssDNA is generated at replication sites, consistent with evicted histones being trapped with Asf1. During recovery, histones stored with Asf1 are rapidly used as replication resumes. This shows that replication stress interferes with predeposition marking and histone recycling with potential impact on epigenetic stability.
Asunto(s)
Proteínas de Ciclo Celular/metabolismo , Ensamble y Desensamble de Cromatina , Replicación del ADN , ADN de Cadena Simple/biosíntesis , Histonas/metabolismo , Estrés Fisiológico/genética , Acetilación , Western Blotting , Proteínas de Ciclo Celular/genética , Núcleo Celular/metabolismo , Citosol/metabolismo , Células HeLa , Humanos , Metilación , Chaperonas Moleculares , Proteínas Nucleares/metabolismo , Nucleosomas/metabolismo , Unión Proteica , Procesamiento Proteico-Postraduccional , Fase S , Espectrometría de Masas en Tándem , Factores de Tiempo , TransfecciónRESUMEN
Every cell has to duplicate its entire genome during S-phase of the cell cycle. After replication, the newly synthesized DNA is rapidly assembled into chromatin. The newly assembled chromatin 'matures' and adopts a variety of different conformations. This differential packaging of DNA plays an important role for the maintenance of gene expression patterns and has to be reliably copied in each cell division. Posttranslational histone modifications are prime candidates for the regulation of the chromatin structure. In order to understand the maintenance of chromatin structures, it is crucial to understand the replication of histone modification patterns. To study the kinetics of histone modifications in vivo, we have pulse-labeled synchronized cells with an isotopically labeled arginine ((15)N(4)) that is 4 Da heavier than the naturally occurring (14)N(4) isoform. As most of the histone synthesis is coupled with replication, the cells were arrested at the G1/S boundary, released into S-phase and simultaneously incubated in the medium containing heavy arginine, thus labeling all newly synthesized proteins. This method allows a comparison of modification patterns on parental versus newly deposited histones. Experiments using various pulse/chase times show that particular modifications have considerably different kinetics until they have acquired a modification pattern indistinguishable from the parental histones.
Asunto(s)
Ensamble y Desensamble de Cromatina , Histonas/metabolismo , Procesamiento Proteico-Postraduccional , Acetilación , Ciclo Celular , Células HeLa , Histonas/biosíntesis , Humanos , Cinética , MetilaciónRESUMEN
Histone modifications play an important role in shaping chromatin structure. Here, we describe the use of an in vitro chromatin assembly system from Drosophila embryo extracts to investigate the dynamic changes of histone modifications subsequent to histone deposition. In accordance with what has been observed in vivo, we find a deacetylation of the initially diacetylated isoform of histone H4, which is dependent on chromatin assembly. Immediately after deposition of the histones onto DNA, H4 is monomethylated at K20, which is required for an efficient deacetylation of the H4 molecule. H4K20 methylation-dependent dl(3)MBT association with chromatin and the identification of a dl(3)MBT-dRPD3 complex suggest that a deacetylase is specifically recruited to the monomethylated substrate through interaction with dl(3)MBT. Our data demonstrate that histone modifications are added and removed during chromatin assembly in a highly regulated manner.
Asunto(s)
Cromatina/metabolismo , Drosophila melanogaster/metabolismo , Histonas/metabolismo , Lisina/metabolismo , Acetilación/efectos de los fármacos , Animales , Extractos Celulares , Cromatina/efectos de los fármacos , Ensamble y Desensamble de Cromatina/efectos de los fármacos , Proteínas de Drosophila/metabolismo , Drosophila melanogaster/enzimología , N-Metiltransferasa de Histona-Lisina/metabolismo , Metilación/efectos de los fármacos , Nucleosomas/efectos de los fármacos , Nucleosomas/metabolismo , Péptidos/metabolismo , Unión Proteica/efectos de los fármacos , S-Adenosilhomocisteína/farmacología , Especificidad por Sustrato/efectos de los fármacosRESUMEN
Post-translational modifications of histones are involved in transcript initiation and elongation. Methylation of lysine 36 of histone H3 (H3K36me) resides promoter distal at transcribed regions in Saccharomyces cerevisiae and is thought to prevent spurious initiation through recruitment of histone-deacetylase activity. Here, we report surprising complexity in distribution, regulation and readout of H3K36me in Drosophila involving two histone methyltransferases (HMTases). Dimethylation of H3K36 peaks adjacent to promoters and requires dMes-4, whereas trimethylation accumulates toward the 3' end of genes and relies on dHypb. Reduction of H3K36me3 is lethal in Drosophila larvae and leads to elevated levels of acetylation, specifically at lysine 16 of histone H4 (H4K16ac). In contrast, reduction of both di- and trimethylation decreases lysine 16 acetylation. Thus di- and trimethylation of H3K36 have opposite effects on H4K16 acetylation, which we propose enable dynamic changes in chromatin compaction during transcript elongation.