Project description:MicroRNAs (miRNAs) together with Argonaute (AGO) proteins form the core of the RNA-induced silencing complex (RISC) to regulate gene expression of their target RNAs post-transcriptionally. Argonaute proteins are subjected to intensive regulation via various post-translational modifications that can affect their stability, silencing efficacy and specificity for targeted gene regulation. We report here that in C. elegans, two conserved serine/threonine kinases - Casein Kinase 1 alpha 1 (CK1A1) and Casein Kinase 2 (CK2) - regulate a highly conserved phosphorylation cluster of 4 Serine residues (S988:S998) on the miRNA-specific AGO protein ALG-1. We show that CK1A1 phosphorylates ALG-1 at sites S992 and S995, while CK2 phosphorylates ALG-1 at sites S988 and S998. Furthermore, we demonstrate that phospho-mimicking mutants of the entire S988:S998 cluster rescue the various developmental defects observed upon depleting CK1A1 and CK2. In humans, we show that CK1A1 also acts as a priming kinase of this cluster on AGO2. Altogether, our data suggest that phosphorylation of AGO within the cluster by CK1A1 and CK2 is required for efficient miRISC-target RNA binding and silencing

Project description:MicroRNAs (miRNA) associate with Argonaute proteins and negatively regulate gene expression by base pairing with complementary sequences in the 3’ UTRs of target genes. De novo coding variants in the human Argonaute gene AGO1 were reported to cause neurodevelopmental disorder (NDD) with intellectual disability (ID). Most of the altered amino acids are conserved between the miRNA associated Argonautes in H. sapiens and C. elegans, suggesting that the human AGO1 mutations could disrupt evolutionarily conserved functions in miRNA biogenesis or target repression. We genetically modeled four human AGO1 mutations in C. elegans by introducing identical mutations into the C. elegans AGO1 homolog, ALG-1. These alg-1 NDD mutations caused phenotypes in C. elegans indicative of disrupted miRNA processing, miRISC formation, and/or target repression. We show that the alg-1 NDD mutations are antimorphic as they cause developmental and molecular phenotypes stronger than those exhibited by the alg-1 null mutants, likely by sequestrating functional miRNA silencing complex (miRISC) components into non-functional complexes that fail to confer robust gene repression. The alg-1 NDD mutations cause allele-specific disruptions in mature miRNA profiles, both in overall abundances and ALG-1 NDD association, accompanied by perturbation of downstream gene expression, including altered translational efficiency and/or mRNA abundance. The perturbed genes include those with human orthologs whose dysfunction is associated with NDD. These cross-clade genetic studies illuminate fundamental Argonaute functions and provide insights into the conservation of miRNA-mediated post-transcriptional regulatory mechanisms.

Project description:MicroRNAs (miRNA) associate with Argonaute proteins and negatively regulate gene expression by base pairing with complementary sequences in the 3’ UTRs of target genes. De novo coding variants in the human Argonaute gene AGO1 were reported to cause neurodevelopmental disorder (NDD) with intellectual disability (ID). Most of the altered amino acids are conserved between the miRNA associated Argonautes in H. sapiens and C. elegans, suggesting that the human AGO1 mutations could disrupt evolutionarily conserved functions in miRNA biogenesis or target repression. We genetically modeled four human AGO1 mutations in C. elegans by introducing identical mutations into the C. elegans AGO1 homolog, ALG-1. These alg-1 NDD mutations caused phenotypes in C. elegans indicative of disrupted miRNA processing, miRISC formation, and/or target repression. We show that the alg-1 NDD mutations are antimorphic as they cause developmental and molecular phenotypes stronger than those exhibited by the alg-1 null mutants, likely by sequestrating functional miRNA silencing complex (miRISC) components into non-functional complexes that fail to confer robust gene repression. The alg-1 NDD mutations cause allele-specific disruptions in mature miRNA profiles, both in overall abundances and ALG-1 NDD association, accompanied by perturbation of downstream gene expression, including altered translational efficiency and/or mRNA abundance. The perturbed genes include those with human orthologs whose dysfunction is associated with NDD. These cross-clade genetic studies illuminate fundamental Argonaute functions and provide insights into the conservation of miRNA-mediated post-transcriptional regulatory mechanisms.

Project description:MicroRNAs (miRNA) associate with Argonaute proteins and negatively regulate gene expression by base pairing with complementary sequences in the 3’ UTRs of target genes. De novo coding variants in the human Argonaute gene AGO1 were reported to cause neurodevelopmental disorder (NDD) with intellectual disability (ID). Most of the altered amino acids are conserved between the miRNA associated Argonautes in H. sapiens and C. elegans, suggesting that the human AGO1 mutations could disrupt evolutionarily conserved functions in miRNA biogenesis or target repression. We genetically modeled four human AGO1 mutations in C. elegans by introducing identical mutations into the C. elegans AGO1 homolog, ALG-1. These alg-1 NDD mutations caused phenotypes in C. elegans indicative of disrupted miRNA processing, miRISC formation, and/or target repression. We show that the alg-1 NDD mutations are antimorphic as they cause developmental and molecular phenotypes stronger than those exhibited by the alg-1 null mutants, likely by sequestrating functional miRNA silencing complex (miRISC) components into non-functional complexes that fail to confer robust gene repression. The alg-1 NDD mutations cause allele-specific disruptions in mature miRNA profiles, both in overall abundances and ALG-1 NDD association, accompanied by perturbation of downstream gene expression, including altered translational efficiency and/or mRNA abundance. The perturbed genes include those with human orthologs whose dysfunction is associated with NDD. These cross-clade genetic studies illuminate fundamental Argonaute functions and provide insights into the conservation of miRNA-mediated post-transcriptional regulatory mechanisms.

Project description:Background: Metazoan embryos undergo a maternal-to-zygotic transition (MZT) during which a subset of maternal gene products is eliminated and the zygotic genome becomes transcriptionally active. RNA-binding proteins (RBPs) and the microRNA-induced silencing complex (miRISC) – of which Argonaute 1 (AGO1) is a key component in Drosophila – target maternal mRNAs for degradation. The Drosophila Smaug, Brain tumor (BRAT) and Pumilio (PUM) RBPs direct the degradation of maternal mRNAs. Here we elucidate Smaug’s roles in regulation of miRNAs and miRISC during the MZT. Results: By global analysis of small RNAs at several stages during the MZT, we show that the vast majority of all miRNA species encoded by the Drosophila genome (85%) are expressed during the MZT. Whereas a subset of these miRNAs is loaded into oocytes by the mother and stays at constant levels during the MZT, dozens of miRNA species are either newly synthesized or re-expressed in the early embryo. Loss of Smaug has a profound effect on miRNAs but little effect on piRNAs or siRNAs. Smaug is required for production of new miRNAs during the MZT; Smaug-bound AGO1 reflects the constellation and abundance of the miRNAs present in early embryos; and Smaug is required for the increase in AGO1 protein levels that occurs during the MZT. As a consequence of low miRISC activity in smaug mutants, maternal mRNAs that are normally targeted for degradation by zygotic miRNAs fail to be cleared. BRAT and PUM share target mRNAs with miRISC during the MZT while the miR-309 miRNA family coregulates targets of BRAT but not PUM. Conclusions: Smaug controls the MZT through direct targeting of a subset of maternal mRNAs for degradation and, indirectly, through production and function of miRNAs and miRISC, which control clearance of a distinct subset of maternal mRNAs. BRAT and/or PUM function together with miRISC during the latter process. With respect to miRISC-dependent transcript degradation, Smaug is required (1) for the synthesis of miRNAs, (2) for synthesis and stabilization of AGO1, and (3) for action of AGO1 in association with its bound miRNAs. In smaug mutants a large number of maternal mRNAs persist and the MZT fails. Examination of miRNA expresssion at different time points in wild type and smuag mutant early embryos .

Project description:MicroRNAs (miRNAs) are essential regulators of several biological processes. To achieve their repressive function, they are loaded onto Argonaute (AGO) proteins, forming the microRNA Induced Silencing Complex (miRISC). Thus, regulating this loading step is essential for miRNA-dependent gene regulation. In this study, we identified the co-chaperone DNJ-12 as a new interactor of ALG-1, one of the two major miRNA-specific AGOs in Caenorhabditis elegans (C. elegans). Importantly, DNJ-12 does not interact with other AGOs, making it a specific regulator of miRNA function. Furthermore, the loss of DNJ-12 leads to developmental phenotypes previously shown to be dependent on miRNA function. Using the Auxin Inducible Degron (AID) system, a powerful tool to study the spatiotemporal effects of DNJ-12 depletion on miRNA function, we show that DNJ-12 depletion hampers ALG-1 interaction with HSP70, a chaperone required for miRISC loading in vitro. Moreover, DNJ-12 depletion leads to a decrease in the levels of several miRNAs and prevents their loading onto ALG-1. This study highlights for the first time the requirement of a co-chaperone for the loading of miRNAs in vivo, provides a potential mechanism explaining AGO differential loading by small RNA, and therefore helps expand our understanding of the miRISC function in animals.

Project description:MicroRNAs are regulators of gene expression whose functions are critical for normal development and physiology. We have previously characterized mutations in a Caenorhabditis elegans microRNA-specific Argonaute ALG-1 (Argonaute-like gene) that are antimorphic [alg-1(anti)]. alg-1(anti) mutants have dramatically stronger microRNA-related phenotypes than animals with a complete loss of ALG-1. ALG-1(anti) miRISC (microRNA induced silencing complex) fails to undergo a functional transition from microRNA processing to target repression. To better understand this transition, we characterized the small RNA population associated with ALG-1(anti) complexes in vivo. alg-1(anti) mutants dramatically overaccumulated microRNA* (passenger) strands, and immunoprecipitated ALG-1(anti) complexes contained nonstoichiometric yields of mature microRNA and microRNA* strands, with some microRNA* strands present in the ALG-1(anti) Argonaute far in excess of the corresponding mature microRNAs. We show complex and microRNA-specific defects in microRNA strand selection and microRNA* strand disposal. For certain microRNAs (for example mir-58), microRNA guide strand selection by ALG-1(anti) appeared normal, but microRNA* strand release was inefficient. For other microRNAs (such as mir-2), both the microRNA and microRNA* strands were selected as guide by ALG-1(anti), indicating a defect in normal specificity of the strand choice. Our results suggest that wild-type ALG-1 complexes recognize structural features of particular microRNAs in the context of conducting the strand selection and microRNA* ejection steps of miRISC maturation. Deep-sequencing was performed on cDNA libraries made from total RNA and RNA immunoprecipitated with ALG-1 from mixed-staged populations of three strains: three biological replicates from wild-type animals and two biological replicates each from alg-1(ma192) and alg-1(ma202) mutant animals. In addition, deep-sequencing was performed on cDNA libraries made from L2-staged total RNA in two biological replicates from wildtype and alg-1(ma202) animals and one biological replicate of alg-1(ma192).

Project description:MicroRNAs are regulators of gene expression whose functions are critical for normal development and physiology. We have previously characterized mutations in a Caenorhabditis elegans microRNA-specific Argonaute ALG-1 (Argonaute-like gene) that are antimorphic [alg-1(anti)]. alg-1(anti) mutants have dramatically stronger microRNA-related phenotypes than animals with a complete loss of ALG-1. ALG-1(anti) miRISC (microRNA induced silencing complex) fails to undergo a functional transition from microRNA processing to target repression. To better understand this transition, we characterized the small RNA population associated with ALG-1(anti) complexes in vivo. alg-1(anti) mutants dramatically overaccumulated microRNA* (passenger) strands, and immunoprecipitated ALG-1(anti) complexes contained nonstoichiometric yields of mature microRNA and microRNA* strands, with some microRNA* strands present in the ALG-1(anti) Argonaute far in excess of the corresponding mature microRNAs. We show complex and microRNA-specific defects in microRNA strand selection and microRNA* strand disposal. For certain microRNAs (for example mir-58), microRNA guide strand selection by ALG-1(anti) appeared normal, but microRNA* strand release was inefficient. For other microRNAs (such as mir-2), both the microRNA and microRNA* strands were selected as guide by ALG-1(anti), indicating a defect in normal specificity of the strand choice. Our results suggest that wild-type ALG-1 complexes recognize structural features of particular microRNAs in the context of conducting the strand selection and microRNA* ejection steps of miRISC maturation.

Project description:MicroRNAs are critical regulators of gene expression in animals. To repress their target mRNAs, these small RNAs are first loaded onto Argonaute proteins to form the silencing complex called miRISC. The complex must then be transported to its target mRNA where it interacts mostly within the 3’UTR through base-pairing. After target repression, the constituents of the miRISC undergo degradation or recycling mediated through their accurate sorting and localization in the cell. While some reports have linked intracellular trafficking to miRNA activity, it is still unclear how these pathways coordinate to allow proper miRNA-mediated gene silencing and turnover. Through a forward genetic screen performed in the nematode Caenorhabditis elegans, we identified the RabGAP tbc-11 as an important factor for the miRNA pathway. We show that TBC-11 is likely a GAP for the small GTPase RAB-6 and that its regulation is required for miRNA function in animals. The absence of functional TBC-11 leads to the persistent activation of RAB-6, which increases the localization of miRNA-unloaded Argonaute ALG-1 on endomembranes. This inactive form of Argonaute accumulates on polysomes, leading to defective miRNA-mediated target mRNA repression. Together, our results establish the importance of intracellular trafficking for miRNA function and demonstrates the involvement of a small GTPase in proper Argonaute localization in vivo.

Project description:Many Argonaute proteins can cleave RNA (“slicing”) as part of the microRNA-induced silencing complex (miRISC), even though miRNA-mediated target repression is generally independent of target cleavage. Here we use C. elegans to examine the role of catalytic residues of miRNA Argonautes in organismal development. In contrast to previous work, mutations in presumed catalytic residues did not interfere with normal development when introduced by CRISPR. We find that unwinding and decay of miRNA star strands is weakly defective in the catalytic residue mutants, with the largest effect observed in embryos. Argonaute-Like Gene 2 (ALG-2) is more dependent on slicing for unwinding than ALG-1. The miRNAs that displayed the greatest (albeit minor) dependence on catalytic residues for unwinding tend to form stable duplexes with their star strand, and in some cases, lowering duplex stability alleviates dependence on catalytic residues. While a few miRNA guide strands are reduced in the mutant background, the basis of this is unclear since changes were not dependent on EBAX-1, an effector of Target-Directed miRNA Degradation (TDMD). Overall, this work defines a role for the catalytic residues of miRNA Argonautes in star strand decay; future work should examine whether this role may contribute to the selection pressure to conserve catalytic activity of miRNA Argonautes across the metazoan phylogeny.