The Movement of Coiled Bodies Visualized in Living Plant Cells by the Green Fluorescent Protein

Boudonck, Kurt; Dolan, Liam; Shaw, Peter

doi:10.1091/mbc.10.7.2297

Cited by 132 publications

(135 citation statements)

References 58 publications

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“…These findings indicate that the nucleolar subdomain where AGO4 colocalizes with RDR2, DCL3, NRPD1b, and various siRNAs are Cajal bodies, or related entities. The fact that these AGO4 bodies can be found inside the nucleolus, or on the outer edge of the nucleolus, is consistent with other observations of the dynamic nature of Cajal bodies (Boudonck et al 1999;Cioce and Lamond 2005). Previously described associations of Cajal bodies with chromatin, such as histone genes and telomeres, to deliver histone mRNA processing or telomerase RNPs, respectively, suggest that the trafficking of RISCs to heterochromatic loci via Cajal body intermediates is plausible.…”

Section: A Connection Between the Nuclearsupporting

confidence: 88%

Cell Biology of the Arabidopsis Nuclear siRNA Pathway for RNA-directed Chromatin Modification

Pikaard¹

2006

Cold Spring Harbor Symposia on Quantitative Biology

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473In diverse eukaryotes, small RNAs have important roles in viral defense, centromere maintenance, or transcriptional silencing of transposons and repeated DNA elements. These RNA-mediated gene silencing phenomena can occur posttranscriptionally, due to inactivation of homologous target RNAs, or transcriptionally, by specifying repressive heterochromatin formation at DNA sequences that match the small RNAs (Baulcombe 2004;Grewal and Rice 2004;Lippman and Martienssen 2004;Almeida and Allshire 2005;Brodersen and Voinnet 2006). The various forms of RNA silencing have in common the involvement of 21-25-nucleotide RNAs, known as siRNAs or microRNAs (miRNAs), that are generated from double-stranded RNA (dsRNA) precursors by RNase-III-like endonucleases known as Dicers (Bernstein et al. 2001;Hannon 2002). Following unwinding of dicer-generated 20-25-bp duplexes, singlestranded siRNAs or miRNAs are loaded into RISCs that participate in subsequent steps, such as mRNA inactivation or heterochromatin modification. A defining component of RISC RNP complexes is an Argonaute (AGO) protein, a family of proteins that is conserved from fission yeast to humans and gets its name from its founding member in Arabidopsis (Carmell et al. 2002;Hunter et al. 2003;Sasaki et al. 2003;Sontheimer and Carthew 2004).In addition to Dicer and Argonaute proteins, Neurospora, plants, Schizosaccharomyces pombe, and Caenorhabditis elegans make use of RNA-dependent RNA polymerases (RdRPs) for RNA silencing (Wassenegger and Krczal 2006). Neurospora and tomato RdRPs have been shown to synthesize dsRNA, in a primer-independent fashion, from a single-stranded RNA template in vitro (Schiebel et al. 1993;Makeyev and Bamford 2002). The Neurospora RdRP also has been shown to be capable of using short RNA primers for dsRNA synthesis (Makeyev and Bamford 2002), suggesting that siRNAs might prime dsRNA synthesis by RdRP, leading to dicing and amplification of siRNAs as long as the target RNA continues to be produced (Baulcombe 2004).Plants possess a diversified tool kit for conducting RNA silencing, including four Dicers (DCL1-DCL4), ten Argonautes (AGO1-AGO10), and six RdRPs The ten Arabidopsis Argonaute proteins also have specialized functions. For instance, AGO1 is involved in miRNA-and siRNA-dependent mRNA degradation pathways , whereas AGO4 functions in the pathway for siRNA-directed DNA methylation and chromatin modification Vaucheret et al. 2004). Likewise, the six RdRPs appear to have different roles in the cell, with RDR6 required for viral, transgene, and trans-acting siRNA production and RDR2 specializing in the siRNA-directed DNA methylation and chromatin modification pathway (Baulcombe 2004;Peragine et al. 2004;Vazquez et al. 2004;Xie et al. 2004;Allen et al. 2005). This paper focuses on the siRNA-directed DNA methylation and chromatin modification pathway that, in addition to DCL3, RDR2, and AGO4 introduced above, In Arabidopsis thaliana, the pathway for transcriptional silencing via RNA-directed DNA methylation and chromatin modification involv...

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Section: A Connection Between the Nuclearsupporting

confidence: 88%

Cell Biology of the Arabidopsis Nuclear siRNA Pathway for RNA-directed Chromatin Modification

Pikaard¹

2006

Cold Spring Harbor Symposia on Quantitative Biology

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“…Differences in the HYL1 protein level affect miRNA metabolism and mRNA stability but not dsRNA-mediated PTGS. HYL1 is predominantly a nuclear protein and is detected in nuclear bodies and ring-like structures reminiscent of Cajal or coiled bodies, known to be involved in nuclear RNA processing in association with the nucleolus (45,46). One-third to one-half of the HYL1 protein in crude extracts is in the form of an Ϸ300-kDa complex.…”

Section: Dsrna-mediated Ptgs Is Not Compromised In the Hyl1 Mutantmentioning

confidence: 99%

The Arabidopsis double-stranded RNA-binding protein HYL1 plays a role in microRNA-mediated gene regulation

Han

Goud

Song

et al. 2004

Proc. Natl. Acad. Sci. U.S.A.

479

387

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The Arabidopsis HYL1 gene encodes a nuclear double-stranded RNA-binding protein. A knockout mutation of the hyl1 gene is recessive and pleiotropic, causing developmental abnormalities, increasing sensitivity to abscisic acid, and reducing sensitivity to auxin and cytokinin. We report that levels of several microRNAs (miRNAs; miR159, -167, and -171) are reduced in homozygous mutant plants, and levels of two of three tested target mRNAs are elevated. Conversely, the miRNA levels are elevated in plants expressing a HYL1 cDNA from a strong promoter, and the corresponding target RNAs are reduced. These changes result from alterations in the stability of the target RNAs. However, doublestranded RNA-induced posttranscriptional gene silencing is unaffected by the hyl1 mutation. One-third to one-half of the cellular HYL1 protein is in a macromolecular complex, and a GFP-HYL1 fusion protein is found predominantly in the nucleus, although it is observed in both nucleus and cytoplasm in some cells. Within nuclei, HYL1 is associated with subnuclear bodies and ring-like structures. These observations provide evidence that the HYL1 protein is part of a nuclear macromolecular complex that is involved in miRNA-mediated gene regulation. Because hyl1 mutants show marked abnormalities in hormone responses, these results further suggest that miRNA-mediated changes in mRNA stability play a vital role in plant hormone signaling.

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“…Recent studies have shown that CB components reside for relatively short times in CBs, suggesting that molecular events occur in CBs in the context of a dynamic exchange of factors with the surrounding nucleoplasm (Handwerger et al, 2003;Dundr et al, 2004). In addition, CBs themselves are highly dynamic, in that they move, split, and fuse during the lifetime of the cell (Andrade et al, 1993;Boudonck et al, 1999;Platani et al, 2000); moreover, their structure is dependent on active transcription and metabolic activity, suggesting that a constant supply of substrates is required to maintain CB integrity (Carmo-Fonseca et al, 1992;Boudonck et al, 1998;Shpargel and Matera, 2005;Lemm et al, 2006). Although it is formally possible that the occurrence of CBs in nuclei is an indirect outcome of physiological state, speculation has focused in recent years on the possibility that concentration of components facilitates key steps in gene expression.…”

Section: Introductionmentioning

confidence: 99%

Enhancement of U4/U6 Small Nuclear Ribonucleoprotein Particle Association in Cajal Bodies Predicted by Mathematical Modeling

Klingauf

Staněk

Neugebauer

2006

MBoC

100

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Spliceosomal small nuclear ribonucleoprotein particles (snRNPs) undergo specific assembly steps in Cajal bodies (CBs), nonmembrane-bound compartments within cell nuclei. An example is the U4/U6 di-snRNP, assembled from U4 and U6 monomers. These snRNPs can also assemble in the nucleoplasm when cells lack CBs. Here, we address the hypothesis that snRNP concentration in CBs facilitates assembly, by comparing the predicted rates of U4 and U6 snRNP association in nuclei with and without CBs. This was accomplished by a random walk-and-capture simulation applied to a three-dimensional model of the HeLa cell nucleus, derived from measurements of living cells. Results of the simulations indicated that snRNP capture is optimal when nuclei contain three to four CBs. Interestingly, this is the observed number of CBs in most cells. Microinjection experiments showed that U4 snRNA targeting to CBs was U6 snRNP independent and that snRNA concentration in CBs is ϳ20-fold higher than in nucleoplasm. Finally, combination of the simulation with calculated association rates predicted that the presence of CBs enhances U4 and U6 snRNP association by up to 11-fold, largely owing to this concentration difference. This provides a chemical foundation for the proposal that these and other cellular compartments promote molecular interactions, by increasing the local concentration of individual components.

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The Movement of Coiled Bodies Visualized in Living Plant Cells by the Green Fluorescent Protein

Cited by 132 publications

References 58 publications

Cell Biology of the Arabidopsis Nuclear siRNA Pathway for RNA-directed Chromatin Modification

Cell Biology of the Arabidopsis Nuclear siRNA Pathway for RNA-directed Chromatin Modification

The Arabidopsis double-stranded RNA-binding protein HYL1 plays a role in microRNA-mediated gene regulation

Enhancement of U4/U6 Small Nuclear Ribonucleoprotein Particle Association in Cajal Bodies Predicted by Mathematical Modeling

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