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1. A multi-tissue gene expression dataset for hibernating brown bears

   Perry, Blair W.; Saxton, Michael W.; Jansen, Heiko T.; Quackenbush, Corey R.; Evans Hutzenbiler, Brandon D.; Robbins, Charles T.; Kelley, Joanna L.; Cornejo, Omar E. (June 2023, BMC genomic data)

   Objectives Complex physiological adaptations often involve the coordination of molecular responses across multiple tissues. Establishing transcriptomic resources for non-traditional model organisms with phenotypes of interest can provide a foundation for understanding the genomic basis of these phenotypes, and the degree to which these resemble, or contrast, those of traditional model organisms. Here, we present a one-of-a-kind gene expression dataset generated from multiple tissues of two hibernating brown bears (Ursus arctos). Data description This dataset is comprised of 26 samples collected from 13 tissues of two hibernating brown bears. These samples were collected opportunistically and are typically not possible to attain, resulting in a highly unique and valuable gene expression dataset. In combination with previously published datasets, this new transcriptomic resource will facilitate detailed investigation of hibernation physiology in bears, and the potential to translate aspects of this biology to treat human disease. 

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2. Feeding during hibernation shifts gene expression toward active season levels in brown bears (Ursus arctos)

   https://doi.org/10.1152/physiolgenomics.00030.2023  

   Perry, Blair W.; McDonald, Anna L.; Trojahn, Shawn; Saxton, Michael W.; Vincent, Ellery P.; Lowry, Courtney; Evans Hutzenbiler, Brandon D.; Cornejo, Omar E.; Robbins, Charles T.; Jansen, Heiko T.; et al (August 2023, Physiological genomics)

   Hibernation in bears involves a suite of metabolical and physiological changes, including the onset of insulin resistance, that are driven in part by sweeping changes in gene expression in multiple tissues. Feeding bears glucose during hibernation partially restores active season physiological phenotypes, including partial resensitization to insulin, but the molecular mechanisms underlying this transition remain poorly understood. Here, we analyze tissue-level gene expression in adipose, liver, and muscle to identify genes that respond to midhibernation glucose feeding and thus potentially drive postfeeding metabolical and physiological shifts. We show that midhibernation feeding stimulates differential expression in all analyzed tissues of hibernating bears and that a subset of these genes responds specifically by shifting expression toward levels typical of the active season. Inferences of upstream regulatory molecules potentially driving these postfeeding responses implicate peroxisome proliferator-activated receptor gamma (PPARG) and other known regulators of insulin sensitivity, providing new insight into high-level regulatory mechanisms involved in shifting metabolic phenotypes between hibernation and active states. 

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3. Temporal Analysis of Gene Expression and Isoform Switching in Brown Bears ( Ursus arctos )

   https://doi.org/10.1093/icb/icac093  

   Perry, Blair W.; Armstrong, Ellie E.; Robbins, Charles T.; Jansen, Heiko T.; Kelley, Joanna L. (June 2022, Integrative And Comparative Biology)

   Abstract Hibernation in brown bears is an annual process involving multiple physiologically distinct seasons—hibernation, active, and hyperphagia. While recent studies have characterized broad patterns of differential gene regulation and isoform usage between hibernation and active seasons, patterns of gene and isoform expression during hyperphagia remain relatively poorly understood. The hyperphagia stage occurs between active and hibernation seasons and involves the accumulation of large fat reserves in preparation for hibernation. Here, we use time-series analyses of gene expression and isoform usage to interrogate transcriptomic regulation associated with all three seasons. We identify a large number of genes with significant differential isoform usage (DIU) across seasons and show that these patterns of isoform usage are largely tissue-specific. We also show that DIU and differential gene-level expression responses are generally non-overlapping, with only a small subset of multi-isoform genes showing evidence of both gene-level expression changes and changes in isoform usage across seasons. Additionally, we investigate nuanced regulation of candidate genes involved in the insulin signaling pathway and find evidence of hyperphagia-specific gene expression and isoform regulation that may enhance fat accumulation during hyperphagia. Our findings highlight the value of using temporal analyses of both gene- and isoform-level gene expression when interrogating complex physiological phenotypes and provide new insight into the mechanisms underlying seasonal changes in bear physiology. 

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4. Expanded application to plant reproductive tissues of a branched DNA probe‐based in situ hybridization method

   https://doi.org/10.1002/aps3.70020  

   Anaya, Brooklyn M; Nguyen, Austin T; Matsunaga, Kelly_K S; Hileman, Lena C (August 2025, Applications in Plant Sciences)

   Abstract PremiseDetecting clear tissue‐ and organ‐specific patterns of gene expression is key to understanding the genetic mechanisms that control plant development. In situ hybridization (ISH) of mRNA is one of the most precise, yet most challenging approaches to gene expression assays. Methods and ResultsDetection of histone H4 expression in reproductive tissues ofMimulus lewisii, a model angiosperm, was optimized using the RNAscope ISH assay. The optimized protocol was used to detect histone H4 expression in reproductive tissues of two gymnosperm species,Taxodium distichumandJuniperus virginiana, without further need for species‐specific optimization. Additionally, the optimized protocol was used to detect expression ofCYCLOIDEAtranscription factors inM. lewisiireproductive tissues without further optimization and with results similar to those previously reported. ConclusionsThe RNAscope assay can quickly and sensitively generate high‐quality ISH results in reproductive tissues across a breadth of plant species. 

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5. Transcriptional profiling of human cartilage endplate cells identifies novel genes and cell clusters underlying degenerated and non-degenerated phenotypes

   https://doi.org/10.1186/s13075-023-03220-6  

   Kuchynsky, Kyle; Stevens, Patrick; Hite, Amy; Xie, William; Diop, Khady; Tang, Shirley; Pietrzak, Maciej; Khan, Safdar; Walter, Benjamin; Purmessur, Devina (December 2024, Arthritis Research & Therapy)

   Abstract BackgroundLow back pain is a leading cause of disability worldwide and is frequently attributed to intervertebral disc (IVD) degeneration. Though the contributions of the adjacent cartilage endplates (CEP) to IVD degeneration are well documented, the phenotype and functions of the resident CEP cells are critically understudied. To better characterize CEP cell phenotype and possible mechanisms of CEP degeneration, bulk and single-cell RNA sequencing of non-degenerated and degenerated CEP cells were performed. MethodsHuman lumbar CEP cells from degenerated (Thompson grade ≥ 4) and non-degenerated (Thompson grade ≤ 2) discs were expanded for bulk (N=4 non-degenerated,N=4 degenerated) and single-cell (N=1 non-degenerated,N=1 degenerated) RNA sequencing. Genes identified from bulk RNA sequencing were categorized by function and their expression in non-degenerated and degenerated CEP cells were compared. A PubMed literature review was also performed to determine which genes were previously identified and studied in the CEP, IVD, and other cartilaginous tissues. For single-cell RNA sequencing, different cell clusters were resolved using unsupervised clustering and functional annotation. Differential gene expression analysis and Gene Ontology, respectively, were used to compare gene expression and functional enrichment between cell clusters, as well as between non-degenerated and degenerated CEP samples. ResultsBulk RNA sequencing revealed 38 genes were significantly upregulated and 15 genes were significantly downregulated in degenerated CEP cells relative to non-degenerated cells (|fold change| ≥ 1.5). Of these, only 2 genes were previously studied in CEP cells, and 31 were previously studied in the IVD and other cartilaginous tissues. Single-cell RNA sequencing revealed 11 unique cell clusters, including multiple chondrocyte and progenitor subpopulations with distinct gene expression and functional profiles. Analysis of genes in the bulk RNA sequencing dataset showed that progenitor cell clusters from both samples were enriched in “non-degenerated” genes but not “degenerated” genes. For both bulk- and single-cell analyses, gene expression and pathway enrichment analyses highlighted several pathways that may regulate CEP degeneration, including transcriptional regulation, translational regulation, intracellular transport, and mitochondrial dysfunction. ConclusionsThis thorough analysis using RNA sequencing methods highlighted numerous differences between non-degenerated and degenerated CEP cells, the phenotypic heterogeneity of CEP cells, and several pathways of interest that may be relevant in CEP degeneration. 

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