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Long noncoding RNAs (lncRNAs) are pervasively transcribed in the eukaryotic genome [1] and are important for the control of master regulatory genes that are involved in cell differentiation and development [2, 3]. Here, we show that a 5' UTR-overlapping lncRNA regulates the male-specific expression of the DM-domain gene doublesex1 (dsx1) in the crustacean Daphnia magna, which produces males in response to environmental stimuli. This lncRNA, named doublesex1 alpha promoter-associated long RNA (DAPALR), is transcribed upstream the transcription start site (TSS) in a sense orientation and subjected to 5' end capping and 3' end processing at a stem-loop structure before the dsx1 coding exon. Similar to dsx1, its expression is only activated in males by the juvenile hormone (JH) and basic-leucine zipper (bZIP) transcription factor Vrille (Vri) and is maintained during embryogenesis. Knockdown of DAPALR in males silenced dsx1 and led to feminization, including egg production, whereas ectopic expression of DAPALR in dsx1-silenced females resulted in the de-repression of dsx1. We further demonstrate that the DAPALR transcript overlaps the dsx1 5'-UTR, and this overlapping region is required for dsx1 activation. Our results suggest that DAPALR can transactivate and possibly maintain dsx1 expression. This might be important for converting transient environmental signals into stable male development, controlled by the continuous expression of dsx1.
Loading of small RNAs into Argonaute, the core protein in RNA silencing, requires the Hsp70/Hsp90 chaperone machinery. This machinery also activates many other clients, including steroid hormone receptors and kinases, but how their structures change during chaperone-dependent activation remains unclear. Here, we utilized single-molecule Förster resonance energy transfer (smFRET) to probe the conformational changes of Drosophila Ago2 mediated by the chaperone machinery. We found that empty Ago2 exists in various closed conformations. The Hsp70 system (Hsp40 and Hsp70) and the Hsp90 system (Hop, Hsp90, and p23) together render Ago2 into an open, active form. The Hsp70 system, but not the Hsp90 system alone, is sufficient for Ago2 to partially populate the open form. Instead, the Hsp90 system is required to extend the dwell time of Ago2 in the open state, which must be transiently primed by the Hsp70 system. Our data uncover distinct and coordinated actions of the chaperone machinery, where the Hsp70 system expands the structural ensembles of Ago2 and the Hsp90 system captures and stabilizes the active form.
The functional coherence between microRNAs (miRNAs) and their host genes remains enigmatic. As host genes and its intronic miRNAs are transcribed as cistronic units, their functional coherence could be beneficial for the organism. However, it is not clear how broad the coherence takes place in the organisms. In this study, we focused on the functions of a miRNA miR-140 and its host gene Wwp2, both of which are reported to be important for the craniofacial development in mouse (Miyaki et al. Gene Dev. 2010, Zou et al. Nat. Cell Biol. 2011). Using CRISPR/Cas9 system, we generated single and double knockout mice for miR-140 and Wwp2 to explore the possible coherence in their functions. Unexpectedly, we found that the miRNA, but not the protein coding gene, is involved in the craniofacial development. Further analysis with compound heterozygous mice suggested that the gene-trap cassette used in the original report of Wwp2 knockout mouse (Zou et al. Nat. Cell Biol. 2011) unintendedly downregulated the expression of miR-140, which lies downstream of the insertion site, and this caused the craniofacial phenotype. Our results dissected the role of a microRNA and its host gene by CRISPR/Cas9 system, and raised a caution for the phenotypic evaluation of knockout mice generated by gene-trap or similar strategy.
Tropomyosin, one of major actin-filament binding proteins, regulates actin-myosin interaction and actin filament stability. Multicellular organisms express a number of tropomyosin isoforms, but understanding of isoform-specific tropomyosin functions is incomplete. The nematode Caenorhabditis elegans has a single tropomyosin gene, lev-11, which has been reported to express four isoforms by using two separate promoters and alternative splicing. Here, we report a fifth tropomyosin isoform, LEV-11O, which is produced by alternative splicing which includes a newly identified seventh exon, exon 7a. By visualizing specific splicing events in vivo, we find that exon 7a is predominantly selected in a subset of the body wall muscles in the head, while exon 7b, which is alternative to exon 7a, is utilized in the rest of the body. Point mutations in exon 7a and exon 7b cause resistance to levamisole-induced muscle contraction specifically in the head and the main body, respectively. Overexpression of LEV-11O, but not LEV-11A, in the main body results in weak levamisole resistance. These results demonstrate that specific tropomyosin isoforms are expressed in the head and body regions of the muscles and differentially contribute to the regulation of muscle contractility.
The nervous system of higher eukaryotes is composed of numerous types of neurons and glia that together orchestrate complex neuronal responses. However, this complex pool of cells typically poses analytical challenges in investigating gene expression profiles and their epigenetic basis for specific cell types. Here, we developed a novel method that enables cell type-specific analyses of epigenetic modifications using tandem chromatin immunoprecipitation sequencing (tChIP-Seq). FLAG-tagged histone H2B, a constitutive chromatin component, was first expressed in Camk2a-positive pyramidal cortical neurons and used to purify chromatin in a cell type-specific manner. Subsequent chromatin immunoprecipitation using antibodies against H3K4me3-a chromatin modification mainly associated with active promoters-allowed us to survey the histone modifications in Camk2a-positive neurons. Indeed, tChIP-Seq identified hundreds of H3K4me3 modifications in promoter regions located upstream of genes associated with neuronal functions and genes with unknown functions in cortical neurons. tChIP-Seq provides a versatile approach to investigating the epigenetic modifications of particular cell types in vivo.
Long noncoding RNA (lncRNA) molecules are some of the newest and least understood players in gene regulation. Hence, we need good model systems with well-defined RNA and protein components. One such system is paraspeckles - protein-rich nuclear organelles built around a specific lncRNA scaffold. New discoveries show how paraspeckles are formed through multiple RNA-protein and protein-protein interactions, some of which involve extensive polymerization, and others with multivalent interactions driving phase separation. Once formed, paraspeckles influence gene regulation through sequestration of component proteins and RNAs, with subsequent depletion in other compartments. Here we focus on the dual aspects of paraspeckle structure and function, revealing an emerging role for these dynamic bodies in a multitude of cellular settings.
The epigenetic phenomenon called X chromosome inactivation plays critical roles in female development in eutherian mammals, and has attracted attention in the fields of developmental biology and regenerative biology in efforts to understand the pluripotency of stem cells. X chromosome inactivation is routinely studied after cell fixation, but live imaging is increasingly being required to improve our understanding of the dynamics and kinetics of X chromosome inactivation and reactivation processes. Here, we describe our live imaging method to monitor the epigenetic status of X chromosomes using a gene knock-in mouse strain named "Momiji" and give an overview of the application of this strain as a resource for biological and stem cell research.
It has been 8 years since the concept of naïve and primed pluripotent stem cell states was first proposed. Both are states of pluripotency, but exhibit slightly different properties. The naïve state represents the cellular state of the preimplantation mouse blastocyst inner cell mass, while the primed state is representative of the post-implantation epiblast cells. These two cell types exhibit clearly distinct developmental potential, as evidenced by the fact that naïve cells are able to contribute to blastocyst chimeras, while primed cells cannot. However, the epigenetic differences that underlie the distinct developmental potential of these cell types remain unclear, which is rather surprising given the large amount of active investigation over the years. Elucidating such epigenetic differences should lead to a better understanding of the fundamental properties of these states of pluripotency and the means by which the naïve-to-primed transition occurs, which may provide insights into the essence of stem cell commitment.
The CRISPR-associated endonuclease Cas9 binds to a guide RNA and cleaves doublestranded DNA with a sequence complementary to the RNA guide. The Cas9–RNA system has been harnessed for numerous applications, such as genome editing. Here we use high-speed atomic force microscopy (HS-AFM) to visualize the real-space and real-time dynamics of CRISPR-Cas9 in action. HS-AFM movies indicate that, whereas apo-Cas9 adopts unexpected flexible conformations, Cas9–RNA forms a stable bilobed structure and interrogates target sites on the DNA by three-dimensional diffusion. These movies also provide real-time visualization of the Cas9-mediated DNA cleavage process. Notably, the Cas9 HNH nuclease domain fluctuates upon DNA binding, and subsequently adopts an active conformation, where the HNH active site is docked at the cleavage site in the target DNA. Collectively, our HS-AFM data extend our understanding of the action mechanism of CRISPR-Cas9.
X inactive-specific transcript (Xist) is a long noncoding RNA that plays an essential role in X chromosome inactivation. Although Xist RNA, like common protein-coding mRNAs, is transcribed by RNA polymerase II, spliced and polyadenylated, it is retained in the nucleus and associates with the X chromosome it originates from. It has been assumed that Xist RNA recruits proteins involved in epigenetic modifications and chromatin compaction to the X chromosome. One of the major proteins constituting the nuclear matrix, hnRNP U, has been shown to be required for the association of Xist RNA with the inactive X chromosome (Xi). In this study, we found that the first 950-nt sequence of Xist RNA had the potential to associate with chromatin in a manner independent of hnRNP U. Furthermore, its chromatin association is apparently dependent on the presence of an intact A-repeat sequence, which is one of the repeats in Xist/XIST RNA conserved among many mammalian species, and has been shown to be important for Xist RNA-mediated silencing. Taking this unexpected finding and a previous study demonstrating the effect of Xist RNA lacking the A-repeat on the formation of the silent heterochromatin domain together, we suggest that the A-repeat captures chromatin near the initial loading site of Xist RNA and relocates it into the core of the heterochromatin domain.