The C. elegans SNAPc component SNPC-4 coats piRNA domains and is globally required for piRNA abundance.

The Piwi/Piwi-interacting RNA (piRNA) pathway protects the germline from the activity of foreign sequences such as transposons. Remarkably, tens of thousands of piRNAs arise from a minimal number of discrete genomic regions. The extent to which clustering of these small RNA genes contributes to their coordinated expression remains unclear.

Insulin/IGF1 signaling inhibits age-dependent axon regeneration.

The ability of injured axons to regenerate declines with age, yet the mechanisms that regulate axon regeneration in response to age are not known. Here we show that axon regeneration in aging C. elegans motor neurons is inhibited by the conserved insulin/IGF1 receptor DAF-2.

Homeland security in the C. elegans germ line: insights into the biogenesis and function of piRNAs.

While most eukaryotic genomes contain transposable elements that can provide select evolutionary advantages to a given organism, failure to tightly control the mobility of such transposable elements can result in compromised genomic integrity of both parental and subsequent generations. Together with the Piwi subfamily of Argonaute proteins, small, non-coding Piwi-interacting RNAs (piRNAs) primarily function in the germ line to defend the genome against the potentially deleterious effects that can be caused by transposition. Here, we describe recent discoveries concerning the biogenesis and function of piRNAs in the nematode Caenorhabditis elegans, illuminating how the faithful production of these mature species can impart a robust defense mechanism for the germ line to counteract problems caused by foreign genetic elements across successive generations by contributing to the epigenetic memory of non-self vs.

Operating on chromatin, a colorful language where context matters.

Histones, the fundamental packaging elements of eukaryotic DNA, are highly decorated with a diverse set of post-translational modifications (PTMs) that are recognized to govern the structure and function of chromatin. Ten years ago, we put forward the histone code hypothesis, which provided a model to explain how single and/or combinatorial PTMs on histones regulate the diverse activities associated with chromatin (e.g.

Identification of lysine 37 of histone H2B as a novel site of methylation.

Recent technological advancements have allowed for highly-sophisticated mass spectrometry-based studies of the histone code, which predicts that combinations of post-translational modifications (PTMs) on histone proteins result in defined biological outcomes mediated by effector proteins that recognize such marks. While significant progress has been made in the identification and characterization of histone PTMs, a full appreciation of the complexity of the histone code will require a complete understanding of all the modifications that putatively contribute to it. Here, using the top-down mass spectrometry approach for identifying PTMs on full-length histones, we report that lysine 37 of histone H2B is dimethylated in the budding yeast Saccharomyces cerevisiae.

Histone H2BK123 monoubiquitination is the critical determinant for H3K4 and H3K79 trimethylation by COMPASS and Dot1.

Histone H2B monoubiquitination by Rad6/Bre1 is required for the trimethylation of both histone H3K4 and H3K79 by COMPASS and Dot1 methyltransferases, respectively. The dependency of methylation at H3K4 and H3K79 on the monoubiquitination of H2BK123 was recently challenged, and extragenic mutations in the strain background used for previous studies or epitope-tagged proteins were suggested to be the sources of this discrepancy. In this study, we show that H3K4 and H3K79 methylation is solely dependent on H2B monoubiquitination regardless of any additional alteration to the H2B sequence or genome.

Demethylation of histone H3K36 and H3K9 by Rph1: a vestige of an H3K9 methylation system in Saccharomyces cerevisiae?

Histone methylation is an important posttranslational modification that contributes to chromatin-based processes including transcriptional regulation, DNA repair, and epigenetic inheritance. In the budding yeast Saccharomyces cerevisiae, histone lysine methylation occurs on histone H3 lysines 4, 36, and 79, and its deposition is coupled mainly to transcription. Until recently, histone methylation was considered to be irreversible, but the identification of histone demethylase enzymes has revealed that this modification can be dynamically regulated.

Yeast Jhd2p is a histone H3 Lys4 trimethyl demethylase.

Histone methylation is important in regulating chromatin structure and function. In budding yeast, methylation of histone H3 at Lys4 (H3-K4) is associated with active transcription and is enriched at the 5' regions of transcribed genes. Here we identify a novel budding yeast JmjC domain-containing H3-K4 demethylase, Jhd2p, that antagonizes the trimethyl modification state and contributes to regulation of telomeric silencing.

Mechanistic insight into the Cdc28-related protein kinase Ime2 through analysis of replication protein A phosphorylation.

In budding yeast, the meiosis-specific protein kinase Ime2 is required for normal meiotic progression. Current evidence suggests that Ime2 is functionally related to Cdc28, the major cyclin-dependent kinase in yeast that is essential for both cell cycle and meiosis. We have previously reported that a natural target of Ime2 activity is replication protein A (RPA), the cellular single-stranded DNA-binding protein that performs critical functions during DNA replication, repair and recombination.