High-throughput profiling of caenorhabditis elegans starvation-responsive microRNAs

MicroRNAs (miRNAs) are non-coding RNAs of ~22 nucleotides in length that regulate gene expression by interfering with the stability and translation of mRNAs. Their expression is regulated during development, under a wide variety of stress conditions and in several pathological processes. In nature, animals often face feast or famine conditions. We observed that subjecting early L4 larvae from Caenorhabditis elegans to a 12-hr starvation period produced worms that are thinner and shorter than well-fed animals, with a decreased lipid accumulation, diminished progeny, reduced gonad size, and an increased lifespan. Our objective was to identify which of the 302 known miRNAs of C. elegans changed their expression under starvation conditions as compared to well-fed worms by means of deep sequencing in early L4 larvae. Our results indicate that 13 miRNAs (miR-34-3p, the family of miR-35-3p to miR-41-3p, miR-39-5p, miR-41-5p, miR-240-5p, miR-246-3p and miR-4813-5p) were upregulated, while 2 miRNAs (let-7-3p and miR-85-5p) were downregulated in 12-hr starved vs. well-fed early L4 larvae. Some of the predicted targets of the miRNAs that changed their expression in starvation conditions are involved in metabolic or developmental process. In particular, miRNAs of the miR-35 family were upregulated 6-20 fold upon starvation. Additionally, we showed that the expression of gld-1, important in oogenesis, a validated target of miR-35-3p, was downregulated when the expression of miR-35-3p was upregulated. The expression of another reported target, the cell cycle regulator lin-23, was unchanged during starvation. This study represents a starting point for a more comprehensive understanding of the role of miRNAs during starvation in C. elegans

Subcellular specialization of multifaceted 3'end modifying nucleotidyltransferases.

While canonical 3'end modifications of mRNAs or tRNAs are well established, recent technological advances in RNA analysis have given us a glimpse of how widespread other types of distinctive 3'end modifications appear to be. Next to alternative nuclear or cytoplasmic polyadenylation mechanisms, evidence accumulated for a variety of 3'end mono-nucleotide and oligo-nucleotide additions of primarily adenosines or uracils on a variety of RNA species. Enzymes responsible for such non-templated additions are non-canonical RNA nucleotidyltransferases, which possess surprising flexibility in RNA substrate selection and enzymatic activity. We will highlight recent findings supporting the view that RNA nucleotidyltransferase activity, RNA target selection and sub-compartimentalization are spatially, temporally and physiologically regulated by dedicated co-factors. Along with the diversification of non-coding RNA classes, the evolutionary conservation of these multifaceted RNA modifiers underscores the prevalence and importance of diverse 3'end formation mechanisms

MEL-47, a novel protein required for early cell divisions in the nematode Caenorhabditis elegans

In the early Caenorhabditis elegans embryo, a rapid succession of cell divisions, many of them asymmetric, form blastomeres that differ in size, cell cycle duration and developmental potential. These early cell cycles are highly regulated and controlled by maternally contributed products. We describe here a novel gene, mel-47, that is required maternally for the proper execution of the early cell cycles. mel-47(yt2) mutants arrest as completely disorganized embryos with 50-80 cells of variable size. The earliest defects we found are changes in the absolute and relative duration of the very early embryonic cell cycles. In particular, the posterior cell of the two-cell embryo divides late compared with its anterior sister. Frequently the daughter cells remain connected through chromatin bridges after the early cleavage divisions indicating that the chromosomes do not segregate properly. The cell cycle delay can be suppressed by knocking down a DNA replication check point. Therefore we propose that mel-47 is required for proper DNA replication in the early embryo

Increased sensitivity and accuracy of a single-stranded DNA splint-mediated ligation assay (sPAT) reveals poly(A) tail length dynamics of developmentally regulated mRNAs.

Poly(A) tail length is a readout of an mRNA's translatability and stability, especially in developmental systems. PolyAdenylation Test (PAT) assays attempt to quickly measure the average poly(A) tail length of RNAs of experimental interest. Here we present sPAT, splint-mediated PAT, a procedure that uses a DNA splint to aid in the ligation of an RNA-tag to the poly(A) tail of an mRNA. In comparison to other PAT methodologies, including ePAT, sPAT is highly sensitive to low-abundance mRNAs, gives a more accurate profile of the poly(A) tail distribution, and requires little starting material. To demonstrate its strength, we calibrated sPAT on defined poly(A) tails of synthetic mRNAs, reassessed developmentally regulated poly(A) tail-length changes of known mRNAs from established model organisms, and extended it to the emerging evolutionary developmental nematode model Pristionchus pacificus. Lastly, we used sPAT to analyze the contribution of the two cytoplasmic poly(A) polymerases GLD-2 and GLD-4, and the deadenylase CCR-4, onto Caenorhabditis elegans gld-1 mRNA that encodes a translationally controlled tumor suppressor whose poly(A) tail length measurement proved elusive

GLD-4-Mediated Translational Activation Regulates the Size of the Proliferative Germ Cell Pool in the Adult C. elegans Germ Line.

To avoid organ dysfunction as a consequence of tissue diminution or tumorous growth, a tight balance between cell proliferation and differentiation is maintained in metazoans. However, cell-intrinsic gene expression mechanisms controlling adult tissue homeostasis remain poorly understood. By focusing on the adult Caenorhabditis elegans reproductive tissue, we show that translational activation of mRNAs is a fundamental mechanism to maintain tissue homeostasis. Our genetic experiments identified the Trf4/5-type cytoplasmic poly(A) polymerase (cytoPAP) GLD-4 and its enzymatic activator GLS-1 to perform a dual role in regulating the size of the proliferative zone. Consistent with a ubiquitous expression of GLD-4 cytoPAP in proliferative germ cells, its genetic activity is required to maintain a robust proliferative adult germ cell pool, presumably by regulating many mRNA targets encoding proliferation-promoting factors. Based on translational reporters and endogenous protein expression analyses, we found that gld-4 activity promotes GLP-1/Notch receptor expression, an essential factor of continued germ cell proliferation. RNA-protein interaction assays documented also a physical association of the GLD-4/GLS-1 cytoPAP complex with glp-1 mRNA, and ribosomal fractionation studies established that GLD-4 cytoPAP activity facilitates translational efficiency of glp-1 mRNA. Moreover, we found that in proliferative cells the differentiation-promoting factor, GLD-2 cytoPAP, is translationally repressed by the stem cell factor and PUF-type RNA-binding protein, FBF. This suggests that cytoPAP-mediated translational activation of proliferation-promoting factors, paired with PUF-mediated translational repression of differentiation factors, forms a translational control circuit that expands the proliferative germ cell pool. Our additional genetic experiments uncovered that the GLD-4/GLS-1 cytoPAP complex promotes also differentiation, forming a redundant translational circuit with GLD-2 cytoPAP and the translational repressor GLD-1 to restrict proliferation. Together with previous findings, our combined data reveals two interconnected translational activation/repression circuitries of broadly conserved RNA regulators that maintain the balance between adult germ cell proliferation and differentiation

The nematode Pristionchus pacificus (Nematoda: Diplogastridae) is associated with the oriental beetle Exomala orientalis (Coleoptera: Scarabaeidae) in Japan

Pristionchus pacificus has been developed as a nematode satellite organism in evolutionary developmental biology. Detailed studies of vulva development revealed multiple differences in genetic and molecular control in P. pacificus compared to the model organism Caenorhabditis elegans. To place evolutionary developmental biology in a comprehensive evolutionary context, such studies have to be complemented with ecology. In recent field studies in western Europe and eastern North America we found 11 Pristionchus species that are closely associated with scarab beetles and the Colorado potato beetle. However, P. pacificus was not commonly found in association with scarab beetles in these studies. Here, we describe the results of a similar survey of scarab beetles in Japan. Pristionchus pacificus was the most common Pristionchus species on scarab beetles in Japan, with 40 out of 43 (93%) isolates. The other Pristionchus isolates represent three novel species, which we refer to as Pristionchus sp. 11, Pristionchus sp. 14, and Pristionchus sp. 15. Thirty-seven of the established P. pacificus strains were found on the oriental beetle Exomala orientalis. Laboratory studies with the sex pheromone (Z)-7-tetradecen-2-one of the oriental beetle revealed that P. pacificus shows strong olfactory attraction to the beetle's sex pheromone, which provides a potential mechanism for the recognition and interaction of P. pacificus and E. orientalis. Together, this study identifies P. pacificus as the most common Pristionchus nematode in field studies in Japan, identifies E. orientalis as an important host species, and provides the basis for the ecology of P. pacificus

GLD-4-Mediated Translational Activation Regulates the Size of the Proliferative Germ Cell Pool in the Adult <i>C. elegans</i> Germ Line

<div><p>To avoid organ dysfunction as a consequence of tissue diminution or tumorous growth, a tight balance between cell proliferation and differentiation is maintained in metazoans. However, cell-intrinsic gene expression mechanisms controlling adult tissue homeostasis remain poorly understood. By focusing on the adult <i>Caenorhabditis elegans</i> reproductive tissue, we show that translational activation of mRNAs is a fundamental mechanism to maintain tissue homeostasis. Our genetic experiments identified the Trf4/5-type cytoplasmic poly(A) polymerase (cytoPAP) GLD-4 and its enzymatic activator GLS-1 to perform a dual role in regulating the size of the proliferative zone. Consistent with a ubiquitous expression of GLD-4 cytoPAP in proliferative germ cells, its genetic activity is required to maintain a robust proliferative adult germ cell pool, presumably by regulating many mRNA targets encoding proliferation-promoting factors. Based on translational reporters and endogenous protein expression analyses, we found that <i>gld-4</i> activity promotes GLP-1/Notch receptor expression, an essential factor of continued germ cell proliferation. RNA-protein interaction assays documented also a physical association of the GLD-4/GLS-1 cytoPAP complex with <i>glp-1</i> mRNA, and ribosomal fractionation studies established that GLD-4 cytoPAP activity facilitates translational efficiency of <i>glp-1</i> mRNA. Moreover, we found that in proliferative cells the differentiation-promoting factor, GLD-2 cytoPAP, is translationally repressed by the stem cell factor and PUF-type RNA-binding protein, FBF. This suggests that cytoPAP-mediated translational activation of proliferation-promoting factors, paired with PUF-mediated translational repression of differentiation factors, forms a translational control circuit that expands the proliferative germ cell pool. Our additional genetic experiments uncovered that the GLD-4/GLS-1 cytoPAP complex promotes also differentiation, forming a redundant translational circuit with GLD-2 cytoPAP and the translational repressor GLD-1 to restrict proliferation. Together with previous findings, our combined data reveals two interconnected translational activation/repression circuitries of broadly conserved RNA regulators that maintain the balance between adult germ cell proliferation and differentiation.</p></div

<i>glp-1</i> mRNA associates with GLD-4 and is a likely target of poly(A) tail extension and translational activation.

<p>(A,B) RNA-coimmunoprecipitation experiments (RIPs) of GLD-4 and GLS-1 proteins specifically enrich <i>glp-1</i> mRNA and the positive control <i>gld-1</i> mRNA. <i>eft-3</i> and <i>rpl-11.1</i> mRNA served as negative controls. (A) A representative ethidium bromide-stained agarose gel of semiquantitative RT-PCR products from three independent biological replicates. (B) Quantitative RT-PCR measurements of three additional RIPs. Error bars are SEM. ***, p<0.001; **, p<0.01; n.s., not significant (Student's t-test). (C,D) Translational efficiency of <i>glp-1</i> mRNA depends on <i>gld-4</i> activity. The data are representative of three independent biological experiments. (C) Polysome gradient. Top is to the right; grey peaks represent optical density read of 258 nm; the peaks of the large ribosomal subunit (60S), monosomes (80S), and polysomes are indicated. Relative <i>glp-1</i> mRNA levels are lower in polysome fractions of <i>gld-4</i>(RNAi) as measured by RT-qPCR. (D) Quantification and comparison of <i>glp-1</i> mRNA in pooled polysomal (polys.) and non-polysomal (non-polys.) fractions. Each measurement was normalized to an internal spike-in control (see <a href="http://www.plosgenetics.org/article/info:doi/10.1371/journal.pgen.1004647#s4" target="_blank">Materials and Methods</a>). Error bars are SEM. *, p<0.05; n.s., not significant (Student's t-test). (E,F) poly(A) tails of <i>glp-1</i> mRNA are reduced upon <i>gld-4</i>(RNAi). (E) Representative PAT assay (n = 2) of the <i>glp-1</i> mRNA material from (C) and the gradient input material. Nucleotide size marker to the left. Lane 7 reflects a 3′UTR with a strongly reduced poly(A) tail (pA) after RNAase H and oligo dT treatment (H/dT). (F) Line scans of PAT assay from (E).</p