Project description:Here we present complete genomic and biochemical annotations of the signals required for RNA degradation by the dsRNA specific ribonuclease III (Rnt1p) and examine its impact on transcriptome stability. Rnt1p cleavage signals are randomly distributed in the yeast genome and encompass wide variety of sequence indicating that transcriptome stability is not determined by the recurrence of a fixed cleavage motif. Instead, RNA reactivity is defined by the sequence and structural context in which the cleavage sites are located. Reactive signals are often associated with transiently expressed genes and their impact on RNA expression is linked to growth conditions. Together the data suggest that stability of the yeast transcriptome is regulated by malleable RNA degradation signals that permit dynamic response to changes in growth conditions. WT, rnt1 delta and rrp6 delta strains where grown independently and analyzed by Affymetrix yeast tiling microarray analysis

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:Here we present complete genomic and biochemical annotations of the signals required for RNA degradation by the dsRNA specific ribonuclease III (Rnt1p) and examine its impact on transcriptome stability. Rnt1p cleavage signals are randomly distributed in the yeast genome and encompass wide variety of sequence indicating that transcriptome stability is not determined by the recurrence of a fixed cleavage motif. Instead, RNA reactivity is defined by the sequence and structural context in which the cleavage sites are located. Reactive signals are often associated with transiently expressed genes and their impact on RNA expression is linked to growth conditions. Together the data suggest that stability of the yeast transcriptome is regulated by malleable RNA degradation signals that permit dynamic response to changes in growth conditions. Total RNA from rnt1d strain was divided in two samples. One sample was treated with purified Rnt1p. The other was only incubated with buffer. The two samples were then enriched for small RNA.

Project description:Here we present complete genomic and biochemical annotations of the signals required for RNA degradation by the dsRNA specific ribonuclease III (Rnt1p) and examine its impact on transcriptome expression. Rnt1p cleavage signals are randomly distributed in the yeast genome and encompass wide variety of sequence indicating that transcriptome stability is not determined by the recurrence of a fixed cleavage motif. Instead, RNA reactivity is defined by the sequence and structural context in which the cleavage sites are located. Reactive signals are often associated with transiently expressed genes and their impact on RNA expression is linked to growth conditions. Together the data suggest that Rnt1p reactivity is triggered by malleable RNA degradation signals that permit dynamic response to changes in growth conditions.

Project description:Here we present complete genomic and biochemical annotations of the signals required for RNA degradation by the dsRNA specific ribonuclease III (Rnt1p) and examine its impact on transcriptome stability. Rnt1p cleavage signals are randomly distributed in the yeast genome and encompass wide variety of sequence indicating that transcriptome stability is not determined by the recurrence of a fixed cleavage motif. Instead, RNA reactivity is defined by the sequence and structural context in which the cleavage sites are located. Reactive signals are often associated with transiently expressed genes and their impact on RNA expression is linked to growth conditions. Together the data suggest that stability of the yeast transcriptome is regulated by malleable RNA degradation signals that permit dynamic response to changes in growth conditions.

Project description:Here we present complete genomic and biochemical annotations of the signals required for RNA degradation by the dsRNA specific ribonuclease III (Rnt1p) and examine its impact on transcriptome stability. Rnt1p cleavage signals are randomly distributed in the yeast genome and encompass wide variety of sequence indicating that transcriptome stability is not determined by the recurrence of a fixed cleavage motif. Instead, RNA reactivity is defined by the sequence and structural context in which the cleavage sites are located. Reactive signals are often associated with transiently expressed genes and their impact on RNA expression is linked to growth conditions. Together the data suggest that stability of the yeast transcriptome is regulated by malleable RNA degradation signals that permit dynamic response to changes in growth conditions.

Project description:Adult mammalian cardiomyocytes (CM) are differentiated post-mitotic cells that lack significant proliferative potential through their inability to reactivate the cell cycle postnatally. In the week after birth, the mammalian heart goes through distinct stages of cell cycle progression and differentiation that govern the development of the mature adult CM phenotype. By establishing the fundamental framework of the molecular signals governing these early events after birth, a potential treatment strategy that restores the heart’s ability to proliferate, and in theory, undergo ‘repair’ after injury could be developed. At 0 days (d), 1d, 3d, 5d, 7d, 10d, and 15d after birth, hearts from C57BL/6J wild-type mice were excised and processed for total RNA isolation. Samples were analyzed by genome-wide messenger RNA (mRNA) microarray profiling. All experiments were performed on age- and sex-matched mice, with equal ratio of male to female mice.

Project description:In Saccharomyces cerevisiae, the maturation of both pre-rRNA and pre-small nucleolar RNAs (pre-snoRNAs) involves common factors, thereby providing a potential mechanism for the coregulation of snoRNA and rRNA synthesis. In this study, we examined the global impact of the double-stranded-RNA-specific RNase Rnt1p, which is required for pre-rRNA processing, on the maturation of all known snoRNAs. In silico searches for Rnt1p cleavage signals, and genome-wide analysis of the Rnt1p-dependent expression profile, identified seven new Rnt1p substrates. Interestingly, two of the newly identified Rnt1p-dependent snoRNAs, snR39 and snR59, are located in the introns of the ribosomal protein genes RPL7A and RPL7B. In vitro and in vivo experiments indicated that snR39 is normally processed from the lariat of RPL7A, suggesting that the expressions of RPL7A and snR39 are linked. In contrast, snR59 is produced by a direct cleavage of the RPL7B pre-mRNA, indicating that a single pre-mRNA transcript cannot be spliced to produce a mature RPL7B mRNA and processed by Rnt1p to produce a mature snR59 simultaneously. The results presented here reveal a new role of yeast RNase III in the processing of intron-encoded snoRNAs that permits independent regulation of the host mRNA and its associated snoRNA. RNA from wild type, rnt1d and rnt1ts grown at 26 C and 37 C on rich media

Project description:Transcriptome Wide Annotation of Eukaryotic RNase III Reactivity and Degradation Signals

Project description:Shigella is an intracellular bacterial pathogen known to activate numerous innate immunity and inflammatory signaling pathways. Many of these pathways are also involved in mTOR signaling. We used HEK293T cell cultures and sought to understand how Shigella infection and rapamycin treatment affect the transcriptome and in particular whether there were commonly affected pathways in the two experimental conditions. 8 samples were used - 2 control that were uninfected/untreated -- 1 sample lost due to RNA degradation, 3 infected with Shigella for 4 hours, and 3 treated with Rapamycin (50 ug/mL) for 4 hours. All samples were from independent experiments. We used the program AltAnalyze to perform pairwise comparisons between Uninfected with Infected, and Uninfected with Rapamycin using default parameters.