Function of the Trypanosome Argonaute 1 protein in RNA interference requires the N-terminal RGG domain and arginine 735 in the Piwi domain

Argonaute proteins are central components of RNA interference (RNAi) and related phenomena in a wide variety of eukaryotes, including the early diverging protozoan Trypanosoma brucei. The single T. brucei Argonaute protein (TbAGO1) is in a complex with small interfering RNAs (siRNAs), and a fraction of this ribonucleoprotein particle is associated with polyribosomes. In this study, we generated a panel of insertion, deletion, and single point mutants of TbAGO1 and assayed them in vivo for their function in RNAi. In addition to the signature domains of Argonaute proteins, PAZ and Piwi, TbAGO1 has an N-terminal domain with a high abundance of RGG repeats. Deletion of the N-terminal domain blocked association of AGO1 with polyribosomes and severely affected mRNA cleavage. Nevertheless, the mutant protein was in a complex with siRNAs. In contrast, deletion of the Piwi domain led to a loss of siRNAs but did not abolish polyribosome association. Site-directed mutagenesis of conserved amino acids in the Piwi domain identified arginine 735 as essential for RNAi. Although the R735A mutant bound siRNAs and associated with polyribosomes, it displayed a severe defect in the cleavage of target mRNA.     

An unusual Dicer-like1 protein fuels the RNA interference pathway in Trypanosoma brucei

RNA interference (RNAi) is an evolutionarily conserved gene-silencing pathway that is triggered by double-stranded RNA (dsRNA). Central to this pathway are two ribonucleases: Dicer, a multidomain RNase III family enzyme that initiates RNAi by generating small interfering RNAs (siRNAs), and Argonaute or Slicer, an RNase H signature enzyme that affects cleavage of mRNA. Previous studies in the early diverging protozoan Trypanosoma brucei have established a key role for Argonaute 1 in RNAi. However, the identity of Dicer has not been resolved. Here, we report the identification and functional characterization of a T. brucei Dicer-like enzyme (TbDcl1). Using genetic and biochemical approaches, we provide evidence that TbDcl1 is required for the generation of siRNA-size molecules and for RNAi. Whereas Dicer and Dicer-like proteins are endowed with two adjacent RNase III domains at the carboxyl terminus (RNase IIIa and RNase IIIb), the arrangement of these two domains is unusual in TbDcl1. RNase IIIa is close to the amino terminus, and RNase IIIb is located approximately in the center of the molecule. This domain organization is specific to trypanosomatids and further illustrates the variable structures of protozoan Dicer-like proteins as compared to fungal and metazoan Dicer.     

Functional replacement of Trypanosoma brucei Argonaute by the human slicer Argonaute2

RNA interference (RNAi) is widespread throughout the eukaryotic lineage, from protozoa to man. Central to all RNAi phenomena is a member of the Argonaute protein family, and, in the case of dsRNA-triggered mRNA cleavage, the Ago protein functions as the RNAi endonuclease or slicer. However, at present there is no definite experimental evidence that slicer Argonautes can be interchanged between distantly related organisms. Here, we show that the human slicer Argonaute2 (HsAgo2), but not HsAgo1, functions in RNAi in the early divergent protozoan Trypanosoma brucei, thus mimicking the situation in mammalian cells. This finding indicates that the basic features of the RNAi mechanism are conserved from T. brucei to man.     

Argonautes confront new small RNAs

Argonaute is at the heart of all effector complexes in RNA interference. In the classical RNAi pathway Argonaute functions as the Slicer enzyme that cleaves an mRNA target directed by a complementary siRNA. Two recently described Argonaute protein subfamilies mediate distinct functions in RNAi. The Piwi subfamily functions in the germline through a novel class of small RNAs that are longer than Argonaute-specific siRNAs and miRNAs. Piwi-interacting RNAs (piRNAs) carry a 2'-O-methylation on their 3' end and appear to be synthesized by a Piwi Slicer dependent mechanism. Piwi/piRNA complexes in mammals and flies are directly linked to the control of transposable elements during germline development. Amplified RNAi in C. elegans is mediated by secondary siRNAs selectively bound to secondary Argonautes (SAGOs) that belong to a worm-specific Argonaute subfamily (WAGO). Secondary siRNAs are 5' triphosphorylated that may allow specific loading into SAGO complexes that are rate limiting for RNAi in C. elegans. Interestingly, SAGOs lack conserved Slicer amino acid residues and probably act in a Slicer-independent fashion.     

piRNAs can trigger a multigenerational epigenetic memory in the germline of C. elegans

Transgenerational effects have wide-ranging implications for human health, biological adaptation, and evolution; however, their mechanisms and biology remain poorly understood. Here, we demonstrate that a germline nuclear small RNA/chromatin pathway can maintain stable inheritance for many generations when triggered by a piRNA-dependent foreign RNA response in C. elegans. Using forward genetic screens and candidate approaches, we find that a core set of nuclear RNAi and chromatin factors is required for multigenerational inheritance of environmental RNAi and piRNA silencing. These include a germline-specific nuclear Argonaute HRDE1/WAGO-9, a HP1 ortholog HPL-2, and two putative histone methyltransferases, SET-25 and SET-32. piRNAs can trigger highly stable long-term silencing lasting at least 20 generations. Once established, this long-term memory becomes independent of the piRNA trigger but remains dependent on the nuclear RNAi/chromatin pathway. Our data present a multigenerational epigenetic inheritance mechanism induced by piRNAs.     

Structural features of small RNA precursors determine Argonaute loading in Caenorhabditis elegans

In C. elegans, DCR-1 is required for the maturation of both short interfering RNAs (siRNAs) and microRNAs (miRNAs), which are subsequently loaded into different Argonaute proteins to mediate silencing via distinct mechanisms. We used in vivo analyses to show that precursors of small RNAs contain structural features that direct the small RNAs into the RNA interference (RNAi) pathway or the miRNA-processing pathway. Nucleotide changes in the pre-let-7 miRNA precursor that make its stem fully complementary cause the resulting small RNA to be recognized as siRNA and induce binding to RDE-1, which leads to RNAi. Mismatches of 1 to 3 nucleotides at various positions in the stem of the precursor restore direction into the miRNA pathway, as the largest portion of such small RNA variants is associated with ALG-1. The Argonaute proteins to which the small RNAs are bound determine the silencing mode, and no functional overlap between RDE-1 and ALG-1 was detected.     

The RNA interference pathway: a new target for autoimmunity

Many intracellular macromolecular complexes that are involved in the production or degradation of RNAs are targeted by autoantibodies in systemic autoimmune diseases. RNA interference (RNAi) is a recently characterized gene silencing pathway by which specific mRNAs are either degraded or translationally suppressed. In a recent issue of Arthritis Research and Therapy, Andrew Jakymiw and colleagues reported that the enigmatic Su autoantigen complex contains key components of the RNAi machinery. Anti-Su autoantibodies from both human patients with rheumatic diseases and a mouse model of autoimmunity recognize the endonucleolytic Argonaute and Dicer proteins, both crucial enzymes of the RNAi pathway. These data raise the question of how the anti-Su response is triggered. So far, it is unknown whether molecular modifications may be involved, as has been proposed for other intracellular autoantigens. The implication of RNAi in anti-viral defence may suggest a role for virus infection in this process.     

Glycolysis modulates trypanosome glycoprotein expression as revealed by an RNAi library

RNA interference (RNAi) is a powerful tool for identifying gene function in Trypanosoma brucei. We generated an RNAi library, the first of its kind in any organism, by ligation of genomic fragments into the vector pZJMbeta. After transfection at approximately 5-fold genome coverage, trypanosomes were induced to express double-stranded RNA and screened for reduced con canavalin A (conA) binding. Since this lectin binds the surface glycoprotein EP-procyclin, we predicted that cells would lose affinity to conA if RNAi silenced genes affecting EP-procyclin expression or modification. We found a cell line in which RNAi switches expression from glycosylated EP-procyclins to the unglycosylated GPEET-procyclin. This switch results from silencing a hexokinase gene. The relationship between procyclin expression and glycolysis was supported by silencing other genes in the glycolytic pathway, and confirmed by observation of a similar upregulation of GPEET- procyclin when parental cells were grown in medium depleted of glucose. These data suggest that T.brucei 'senses' changes in glucose level and modulates procyclin expression accordingly.     

Characterization of Argonaute cDNA from Penaeus monodon and implication of its role in RNA interference

RNA interference (RNAi) has recently become a promising strategy for therapeutic of several viral diseases including those in the black tiger shrimp Penaeus monodon. However, the protein components that play role in RNAi in P. monodon have not yet been identified. Here, we report the cloning and functional characterization of a cDNA encoding Argonaute, a principal constituent of RNAi pathway in P. monodon. P. monodon’s Argonaute (Pem-AGO) exhibited the two signature domains, PAZ and PIWI. Substantial level of Pem-ago expression could be suppressed by double-stranded RNA (dsRNA) that targeted PAZ coding sequence in shrimp primary culture of Oka cells. The Pem-ago depleted cells showed impaired RNAi as the expression of an endogenous gene was rescued from the dsRNA-mediated silencing in these cells. Our results imply that Pem-ago is required for effective RNAi in P. monodon and thus identify the first protein constituent of RNAi machinery in penaeid shrimp.     

Enhanced susceptibility of Ago1/3 double-null mice to influenza A virus infection

RNA interference (RNAi) is a critical component of many cellular antiviral responses in plants, invertebrates, and mammals. However, its in vivo role in host protection from the negative-sense RNA virus influenza virus type A (flu) is unclear. Here we have examined the role of RNAi in host defense to flu by analyzing Argonaute 1 and 3 double-knockout mice deficient in components of the RNA-induced silencing complex. Compared to littermate controls, flu-infected double-knockout mice exhibited increased mortality, consistent with more severe alveolitis and pneumonitis. These data indicate that optimal resistance to flu requires Argonaute 1 and/or 3. Enhanced mortality of double-knockout mice was not associated either with increased viral replication or with differential pulmonary recruitment or function of innate and adaptive immune cells. Given the absence of detectable immune defects, our results support the notion that the enhanced flu susceptibility of double-knockout mice arises from an intrinsic impairment in the ability of lung cells to tolerate flu-elicited inflammation.     

Requirement for acetyl-CoA carboxylase in Trypanosoma brucei is dependent upon the growth environment

Trypanosoma brucei, the causative agent of human African trypanosomiasis, possesses two fatty acid synthesis pathways: a major de novo synthesis pathway in the ER and a mitochondrial pathway. The 2-carbon donor for both pathways is malonyl-CoA, which is synthesized from acetyl-CoA by Acetyl-CoA carboxylase (ACC). Here, we show that T. brucei ACC shares the same enzyme architecture and moderate ～ 30% identity with yeast and human ACCs. ACC is cytoplasmic and appears to be distributed throughout the cell in numerous puncta distinct from glycosomes and other organelles. ACC is active in both bloodstream and procyclic forms. Reduction of ACC activity by RNA interference (RNAi) resulted in a stage-specific phenotype. In procyclic forms, ACC RNAi resulted in 50-75% reduction in fatty acid elongation and a 64% reduction in growth in low-lipid media. In bloodstream forms, ACC RNAi resulted in a minor 15% decrease in fatty acid elongation and no growth defect in culture, even in low-lipid media. However, ACC RNAi did attenuate virulence in a mouse model of infection. Thus the requirement for ACC in T. brucei is dependent upon the growth environment in two different life cycle stages.