Project description:Ultradian rhythm of gene expression in excised leaf.

Project description:Biological rhythms have important implications for human disease, as evidenced by the effects of disrupting the 24h circadian clock. While circadian rhythms are entrained to the once daily light-dark cycle of the sun, coastal marine organisms are known to exhibit 12h ultradian rhythms, corresponding to the twice daily movement of the tides. Human ancestors emerged from a circa-tidal environment millions of years ago. However, whether 12h ultradian rhythms are conserved in humans remains unknown. Here, we performed prospective, high temporal resolution transcriptome profiling in the peripheral white blood cells of three healthy subjects. Remarkably, all three subjects exhibited a shared transcriptional program demonstrating robust ~12h rhythms. Pathway analysis implicated 12h transcriptional oscillations primarily affected core cellular processes, including RNA and protein metabolism, with strong homology to the 12h gene programs previously identified in cnidarian marine species. These results establish the existence of 12h biological rhythms in humans. Such rhythms appear to have a primordial evolutionary origin dating back at least 700 million years and are likely to have far-reaching implications in human health and disease.

Project description:The eur1-11 which developed by EMS mutation has no ultradian rhythm in excised leaf. This data set was focused on how EUR and eur1-11 effect on de novo root regeneration.

Project description:In the chronobiology field, a fundamental dichotomy exists to explain daily rhythmicity of biological processes: these can be elicited in response to cyclic extrinsic/environmental signals such as light, or driven endogenously by the circadian clock. In mammals, the circadian clock ticks in almost every cell of the body, and functions based on a network of transcription-translation feedback loops. The PI3K-AKT signaling pathway relays environmental information of nutritional/metabolic state to regulate cell size and proliferation. AKT, a Serine/Threonine protein kinase, is activated by phosphorylation, where phospho-serine 473 (pAKT) serves as a hallmark for its activation. Following activation, it proceeds to phosphorylate dozens of target proteins that convey the signal to regulate gene expression and other key cellular functions. Overall, this pathway is widely known to be activated in response to feeding related signals, and previous studies in mice found elevated pAKT levels in correspondence with food ingestion. However, it is still unknown whether this can (also) be driven through intrinsic mechanisms, such as the circadian clock. Here, we inspected daily activation of AKT both in cultured cells and animal models. Unexpectedly, we found, that neither environmental cues nor the circadian clock were necessary for pAKT rhythms, which exhibited ultradian, rather than circadian, cycles of phosphorylation. In addition, hepatic gene expression also exhibited short rhythms in clock disrupted mice, corresponding with AKT related genes/functions. Reciprocally, inhibition of AKT phosphorylation did not affect the rhythmicity of the circadian clock. Overall, our findings uncover temporal regulation of AKT activation and reveal ultradian molecular rhythmicity that cycles independently of the canonical circadian clock.

Project description:Conservation of primordial ~12-hour ultradian gene programs in humans

Project description:Ultradian Molecular Rhythms Emerge in the Absence of a Circadian Clock

Project description:Temporal data on gene expression and context-specific open chromatin states can improve identification of key transcription factors (TFs) and the gene regulatory networks (GRNs) controlling cellular differentiation. However, their integration remains challenging. Here, we delineate a general approach for data-driven and unbiased identification of key TFs and dynamic GRNs, called EPIC-DREM. We generated time-series transcriptomic and epigenomic profiles during differentiation of mouse multipotent bone marrow stromal cells (MSCs) towards adipocytes and osteoblasts. Using our novel approach we constructed time-resolved GRNs for both lineages and identifed the shared TFs involved in both differentiation processes. To take an alternative approach to prioritize the identified shared regulators, we mapped dynamic super-enhancers in both lineages and associated them to target genes with correlated expression profiles. The combination of the two approaches identified aryl hydrocarbon receptor (AHR) and Glis family zinc finger 1 (GLIS1) as mesenchymal key TFs controlled by dynamic MSC-specific super-enhancers that become repressed in both lineages. AHR and GLIS1 control differentiation-induced genes and we propose they function as guardians of mesenchymal multipotency.

Project description:Recent single-cell studies have revealed that yeast stress response involves multiple transcription factors that are temporally activated in pulses. However, it remains largely unclear whether and how these dynamic transcription factors temporally interact to regulate stress survival. Here we show that budding yeast cells can exploit the temporal relationship between paralogous general stress regulators, Msn2 and Msn4, during stress response. We found that individual pulses of Msn2 and Msn4 are largely redundant, and cells can enhance the expression of their shared target genes by increasing their temporal divergence. Thus, functional redundancy between these two paralogs is modulated in a dynamic manner to confer fitness advantages for yeast cells, which might feed back to promote the preservation of their functional redundancy. This evolutionary implication was supported by evidence from Msn2/Msn4 orthologs and analyses of other transcription factor paralogs. Together, we show a cell fate control mechanism through temporal redundancy modulation in yeast, which may represent an evolutionarily important strategy for maintaining functional redundancy between gene duplicates.

Project description:We performed RNAseq with Saccharomyces cerevisiae cells under both transient and steady-state conditions to study the regulation of genes by two pulsatile transcription factors, Msn2 and Mig1. The transient data allowed us to identify combinatorial targets while the steady-state data was used to study target expression dependence on the relative pulse timing between the two TFs.

Project description:Leaf excision evokes an ultradian gene expression rhythm to prime de novo root regeneration