Genome-wide screen identifies signaling pathways that regulate autophagy during Caenorhabditis elegans development.

The mechanisms that coordinate the regulation of autophagy with developmental signaling during multicellular organism development remain largely unknown. Here, we show that impaired function of ribosomal protein RPL-43 causes an accumulation of SQST-1 aggregates in the larval intestine, which are removed upon autophagy induction. Using this model to screen for autophagy regulators, we identify 139 genes that promote autophagy activity upon inactivation. Various signaling pathways, including Sma/Mab TGF-ß signaling, lin-35/Rb signaling, the XBP-1-mediated ER stress response, and the ATFS-1-mediated mitochondrial stress response, regulate the expression of autophagy genes independently of the TFEB homolog HLH-30. Our study thus provides a framework for understanding the role of signaling pathways in regulating autophagy under physiological conditions.

A genome-wide RNAi screen identifies genes regulating the formation of P bodies in C. elegans and their functions in NMD and RNAi.

Cytoplasmic processing bodies, termed P bodies, are involved in diverse post-transcriptional processes including mRNA decay, nonsense-mediated RNA decay (NMD), RNAi, miRNA-mediated translational repression and storage of translationally silenced mRNAs. Regulation of the formation of P bodies in the context of multicellular organisms is poorly understood. Here we describe a systematic RNAi screen in C. elegans that identified 224 genes with diverse cellular functions whose inactivations result in a dramatic increase in the number of P bodies. 83 of these genes form a complex functional interaction network regulating NMD. We demonstrate that NMD interfaces with many cellular processes including translation, ubiquitin-mediated protein degradation, intracellular trafficking and cytoskeleton structure.We also uncover an extensive link between translation and RNAi, with different steps in protein synthesis appearing to have distinct effects on RNAi efficiency. Moreover, the intracellular vesicular trafficking network plays an important role in the regulation of RNAi. A subset of genes enhancing P body formation also regulate the formation of stress granules in C. elegans. Our study offers insights into the cellular mechanisms that regulate the formation of P bodies and also provides a framework for system-level understanding of NMD and RNAi in the context of the development of multicellular organisms.

A piggyBac transposon-based mutagenesis system for the fission yeast Schizosaccharomyces pombe.

The TTAA-specific transposon piggyBac (PB), originally isolated from the cabbage looper moth, Trichoplusia ni, has been utilized as an insertional mutagenesis tool in various eukaryotic organisms. Here, we show that PB transposes in the fission yeast Schizosaccharomyces pombe and leaves almost no footprints. We developed a PB-based mutagenesis system for S. pombe by constructing a strain with a selectable transposon excision marker and an integrated transposase gene. PB transposition in this strain has low chromosomal distribution bias as shown by deep sequencing-based insertion site mapping. Using this system, we obtained loss-of-function alleles of klp5 and klp6, and a gain-of-function allele of dam1 from a screen for mutants resistant to the microtubule-destabilizing drug thiabendazole. From another screen for cdc25-22 suppressors, we obtained multiple alleles of wee1 as expected. The success of these two screens demonstrated the usefulness of this PB-mediated mutagenesis tool for fission yeast.

Strand compositional asymmetries in vertebrate large genes.

Both transcription-associated and replication-associated strand compositional asymmetries have recently been shown in vertebrate genomes. In this paper, we illustrate that transcription-associated strand compositional asymmetries and replication-associated ones coexist in most vertebrate large genes, although in most case the former conceals the latter. Furthermore, we found that the transcription-associated strand compositional asymmetries of housekeeping genes are stronger than those of somatic cell expressed genes. Together with other evidence, we suggest that germline transcription-associated strand asymmetric mutations may be the main cause of the transcription-associated strand compositional asymmetries.

Transcription factor NFY globally represses the expression of the C. elegans Hox gene Abdominal-B homolog egl-5.

The C. elegans Hox gene egl-5 (ortholog of Drosophila Abdominal-B) is expressed in multiple tissues in the tail region and is involved in tail patterning. In this study, we identify and clone the corresponding C. elegans orthologs of the components of the heterotrimeric transcription factor NFY, nfya-1, nfyb-1 and nfyc-1 and demonstrate that mutations in these components result in the ectopic expression of egl-5 outside of its normal expression domains. The NFYA-1 protein forms a complex with NFYB-1 and NFYC-1, specifically recognizing the CCAAT box. Mutating a CCAAT box in the proximal promoter of egl-5 also leads to the derepression of egl-5, suggesting a direct role for the NFY complex in the regulation of egl-5. In addition, we show that the NFY complex interacts with the MES-2/MES-6 PcG complex in Hox gene regulation. Thus, our studies unravel a physiological function of NFY in establishing the spatially restricted expression pattern of egl-5.

Replication-associated strand asymmetries in vertebrate genomes and implications for replicon size, DNA replication origin, and termination.

Strand compositional asymmetry has been observed in prokaryotes and used in predicting prokaryotic DNA replication origins and termini. However, it was not found in eukaryotic genomes by the same methods. We propose that transcription-associated strand asymmetries mask the replication-associated ones. By analyzing the nucleotide composition of intergenic sequences larger than 50 kb by cumulative skew diagrams (CSD), we found replication-associated strand asymmetry in vertebrate genomes. Furthermore, we found that the most common replicon sizes in vertebrates are 50-100 kb, and show evidence that the replication origin and termination regions of vertebrate genomes range from a discrete site to a broad zone.

mRNA-mediated intron losses: evidence from extraordinarily large exons.

Multicellular eukaryotes that have high intron density have their introns almost evenly distributed within genes, but unicellular eukaryotes that are generally intron poor have their introns asymmetrically distributed toward the 5' ends of genes. This was explained by homologous recombination of genomic DNA with the cDNA reverse transcribed from the 3' polyadenylated tail of spliced mRNA. This paper is to study whether mRNA-mediated intron losses have ever occurred in multicellular eukaryotes. If intron losses were mRNA-mediated, adjacent introns should be commonly lost together. A direct result is fusion of several previously adjacent exons and producing a large exon. We found that extraordinarily large exons (ELEs) are common not only in unicellular eukaryotes but also in multicellular eukaryotes. The percentage of genes having ELEs is negatively correlated with intron abundance. In addition, the number of lost introns estimated from the relative lengths of ELEs is negatively correlated with the number of extant introns. These results support mRNA-mediated intron losses in all eukaryotes. Moreover, we found that the ELEs of intron-common eukaryotes (with more than 0.5 intron per gene on average) are not only located at 3' ends but also at 5' ends and the middle of genes. This is contrary to what would be expected if the involved cDNAs were reverse transcribed from the 3' polyadenosine ends. A remarkable difference in intron distribution was revealed between intron-rare eukaryotes and intron-common eukaryotes. The intron-rare eukaryotes show very strong 5'-biased intron distribution, whereas the intron-common eukaryotes display even intron distribution or only weak 5'-biased distribution. We suspected that intron losses from 3' end of genes may be limited in intron-rare eukaryotes. The intron losses from intron-common eukaryotes should have other priming mechanism, like self-primed reverse transcription.