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Trends Genet,
2001]
Gene silencing can occur either through repression of transcription, termed transcriptional gene silencing (TGS), or through mRNA degradation, termed post-transcriptional gene silencing (PTGS). Initially, TGS was associated with the regulation of transposons through DNA methylation in the nucleus, whereas PTGS was shown to regulate virus infection through double-stranded RNA in the cytoplasm. However, several breakthroughs in the field have been reported recently that blur this neat distinction. First, in plants TGS and DNA methylation can be induced by either dsRNA or viral infection. Second, a mutation in the plant MOM gene reverses TGS without affecting DNA methylation. Third, in Caenorhabditis elegans mutation of several genes that control RNA interference, a form of PTGS, also affect the regulation of transposons. TGS and PTGS, therefore, appear to form two alternative pathways to control incoming, redundant and/or mobile nucleic acids.
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WormBook,
2005]
Evolutionary innovation requires genetic raw materials upon which selection can act. The duplication of genes is of fundamental importance in providing such raw materials. Gene duplications are very widespread in C. elegans and appear to arise more frequently than in either Drosophila or yeast. It has been proposed that the rate of duplication of a gene is of the same order of magnitude as the rate of mutation per nucleotide site, emphasising the enormous potential that gene duplication has for generating substrates for evolutionary change. The fate of duplicated genes is discussed. Complete functional redundancy seems unstable in the long term. Most models require that equality amongst duplicated genes must be disrupted if they are to be preserved. There are various ways of achieving inequality, involving either the nonfunctionalization of one copy, or one copy acquiring some novel, beneficial function, or both copies becoming partially compromised so that both copies are required to provide the overall function that was previously provided by the single ancestral gene. Examples of C. elegans gene duplications that appear to have followed each of these pathways are considered.
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Science,
2003]
Small RNAs, including microRNAs (miRNAs) and short interfering RNAs (siRNAs), are key components of an evolutionarily conserved system of RNA-based gene regulation in eukaryotes. They are involved in many molecular interactions, including defense against viruses and regulation of gene expression during development. miRNAs interfere with expression of messenger RNAs encoding factors that control developmental timing, stem cell maintenance, and other developmental and physiological processes in plants and animals. miRNAs are negative regulators that function as specificity determinants, or guides, within complexes that inhibit protein synthesis (animals) or promote degradation (plants) of mRNA targets.
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Mol Cell Endocrinol,
2011]
Nuclear receptors (NRs) belong to a large protein superfamily that are important transcriptional modulators in metazoans. Parasitic helminths include parasitic worms from the Lophotrochozoa (Platyhelminths) and Ecdysozoa (Nematoda). NRs in parasitic helminths diverged into two different evolutionary lineages. NRs in parasitic Platyhelminths have orthologues in Deuterostomes, in arthropods or both with a feature of extensive gene loss and gene duplication within different gene groups. NRs in parasitic Nematoda follow the nematode evolutionary lineage with a feature of multiple duplication of SupNRs and gene loss.
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Methods Cell Biol,
1995]
Geneticists like to point out that the ultimate test of a proposed function for a gene and its encoded product (or products) in a living organism involves making a mutant and analyzing its phenotype. This is the goal of reverse genetics: a gene is cloned and sequenced, its transcripts and protein coding sequence are analyzed, and a function may be proposed; one must then introduce a mutation in the gene in a living organism to see what the functional consequences are. The analysis of genetic mosaics takes this philosophy a step further. In mosaics, some cells of an individual are genotypically mutant and other cells are genotypically wild type. One then asks what the phenotypic consequences are for the living organism. This is not the same as asking what cells transcribe the gene or in what cells the protein product of the gene is to be found, but rather it is asking in what cells the wild-type gene is needed for a given function...
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Parasitol Today,
2000]
Gene discovery programs centred around expressed sequence tag (EST) and genome sequencing projects have predictably led to an exponential surge in the number of parasite gene sequences deposited in public databases. To take advantage of this wealth of sequence information, it is essential to develop rapid methods for elucidating the biological function or mode of action of individual genes. Here, Patricia Kuwabara and Alan Coulson discuss the virtues of a powerful epigenetic gene disruption technique, RNA-mediated interference (RNAi), which was originally developed for the nematode Caenorhabditis elegans. It is anticipated that this technique will not only provide insights into gene function, but also help investigators to mine the genome for candidate drug intervention or vaccine development targets, some of which may not be readily apparent on the basis of sequence information alone.
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Trends in Biochemical Sciences,
2004]
Over the past few years, microRNAs (miRNAs) have emerged as abundant regulators of gene expression. Like many transcription factors (TFs), miRNAs are important determinants of cellular fate specification. Here I provide a conceptual framework for miRNA action in the context of creating cellular diversity in a developing organism, and emphasize the conceptual similarity of TF- and miRNA-mediated control of gene expression. Both TFs and miRNAs are trans-acting factors that exert their activity through composite cis-regulatory elements that are 'hard-wired' into DNA or RNA. TFs and miRNAs act in a largely combinatorial manner - that is, many different TFs or miRNAs control one gene - and they act cooperatively on their targets - that is, there are several cis-regulatory elements for a single TF or miRNA species in a target gene. Just as the set of TFs in a given cell type has been proposed to constitute a 'code' that specifies cellular differentiation, so 'miRNA codes' are likely to have conceptually similar roles in the specification of cell types.
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FEBS Lett,
2005]
RNA interference (RNAi) is a form of gene silencing induced by double stranded RNA (dsRNA) that is processed into short interfering RNAs (siRNAs). RNAi can induce both post-transcriptional and transcriptional gene silencing. In Caenorhabditis elegans, there are several distinct pathways where post-transcriptional or/and transcriptional RNAi mechanisms are involved. RNAi in C. elegans is also systemic and heritable. This review will discuss RNAi related pathways, features of RNAi in C. elegans and possibilities of endogenous gene regulation by RNAi.
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Methods Cell Biol,
2011]
The Caenorhabditis elegans hermaphrodite is a complex multicellular animal that is composed of 959 somatic cells. The C. elegans genome contains 20,000 protein-coding genes, 940 of which encode regulatory transcription factors (TFs). In addition, the worm genome encodes more than 100 microRNAs and many other regulatory RNA and protein molecules. Most C. elegans genes are subject to regulatory control, most likely by multiple regulators, and combined, this dictates the activation or repression of the gene and corresponding protein in the relevant cells and under the appropriate conditions. A major goal in C. elegans research is to determine the spatiotemporal expression pattern of each gene throughout development and in response to different signals, and to determine how this expression pattern is accomplished. Gene regulatory networks describe physical and/or functional interactions between genes and their regulators that result in specific spatiotemporal gene expression. Such regulators can act at transcriptional or post-transcriptional levels. Here, I will discuss the methods that can be used to delineate gene regulatory networks in C. elegans. I will mostly focus on gene-centered yeast one-hybrid (Y1H) assays that are used to map interactions between non-coding genic regions, such as promoters, and regulatory TFs. The approaches discussed here are not only relevant to C. elegans biology, but can also be applied to other model organisms and humans.
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Mol Cell,
2003]
RNA interference (RNAi) describes the ability of double-stranded RNA (dsRNA) to inhibit homologous gene expression at the RNA or DNA level. In a recent paper, Feinberg and Hunter report that a single transmembrane dsRNA transport protein may enable RNAi to spread systemically from one cell to another.