CASK is a scaffold protein that functions in trafficking and targeting of synaptic proteins in the central nervous system. Emerging literature suggests that CASK localizes inside nucleus and might regulate transcription by interacting with TBR1, a transcription factor essential for brain development. However, these regulatory mechanisms are not well established. We hypothesize that CASK is involved in neuronal activity‐regulated transcription. To test our hypothesis, we used primary cultures of mouse cortical neurons stimulated with KCL depolarization buffer, which is known to activate a robust CREB‐dependent gene expression program and to induce the activation of distal enhancer elements. To measure gene expression genome‐wide, we performed RNAseq in unstimulated or KCL‐treated neurons after knock‐down of CASK expression using specific shRNA. Our results show that CASK knock‐down strongly reduces the number of genes that are regulated by depolarization. These results indicate that CASK is required for gene expression regulation in neuronal cells. To gain further insights in the mechanisms by which CASK regulate transcription, we used RNA in situ hybridization (RNAscope) to test the hypothesis that CASK is not only required for the transcription of coding genes, but also of non‐coding RNAs, termed ‘enhancer RNAs (eRNAs), in proximity of KCL‐regulated genes. We showed that RNAscope is a valid method to measure eRNAs induction after KCl treatment. Ongoing experiments in the lab are assessing the effect of CASK knock‐down on eRNA transcription. Interestingly, we observed by immunoprecipitation that nuclear CASK dimerizes, and that the stability of this homodimer is dependent on the presence of RNA. Finally, we used biochemical fractionation to study CASK localization in the nucleus in both mouse neuronal cultures and brain tissues. These results shed light on how CASK functions in neurons. This study is relevant to human disease because mutations in CASK gene are linked to microcephaly and X‐linked intellectual disability. Support or Funding Information This project has been supported by CABRI Undergraduate Research Fellowship
Biofouling on polymeric membranes poses a significant challenge in protein production and separation processes. We report here on the use of zwitterionic peptides composed of alternating lysine (K) and glutamic acid (E) residues to reduce biomolecular fouling on gold substrates and polymeric membranes within a protein production-mimicking environment. Our findings demonstrate that both gold chips and polymeric membranes functionalized with longer sequence zwitterionic peptides, along with a hydrophilic linker, exhibit superior antifouling performance across various protein-rich environments. Furthermore, increasing the grafting density of these peptides on substrates enhances their antifouling properties. We believe that this work sheds light on the antifouling capabilities of zwitterionic peptides in cell culture environments, advancing our understanding and paving the way for the development of zwitterionic peptide-based antifouling materials for polymeric membranes.
The ability to rapidly change gene expression patterns is essential for differentiation, development, and functioning of the brain. Throughout development, or in response to environmental stimuli, gene expression patterns are tightly regulated by the dynamic interplay between transcription activators and repressors. Nuclear receptor corepressor 1 (NCoR1) and silencing mediator for retinoid or thyroid-hormone receptors (SMRT) are the best characterized transcriptional co-repressors from a molecular point of view. They mediate epigenetic silencing of gene expression in a wide range of developmental and homeostatic processes in many tissues, including the brain. For instance, NCoR1 and SMRT regulate neuronal stem cell proliferation and differentiation during brain development and they have been implicated in learning and memory. However, we still have a limited understanding of their regional and cell type-specific expression in the brain. In this study, we used fluorescent immunohistochemistry to map their expression patterns throughout the adult mouse brain. Our findings reveal that NCoR1 and SMRT share an overall neuroanatomical distribution, and are detected in both excitatory and inhibitory neurons. However, we observed striking differences in their cell type-specific expression in glial cells. Specifically, all oligodendrocytes express NCoR1, but only a subset express SMRT. In addition, NCoR1, but not SMRT, was detected in a subset of astrocytes and in the microglia. These novel observations are corroborated by single cell transcriptomics and emphasize how NCoR1 and SMRT may contribute to distinct biological functions, suggesting an exclusive role of NCoR1 in innate immune responses in the brain.
'/%3e%3cpath fill='%23fff' d='m8.751-17.959 10.11 11.373L3.997-9.844l13.94-6.1-7.692 13.129z'/%3e%3c/svg%3e)
'/%3e%3cuse xlink:href='%23a' transform='rotate(23.036 .093 25.536)'/%3e%3cuse xlink:href='%23a' transform='rotate(45.87 1.273 16.18)'/%3e%3cuse xlink:href='%23a' transform='rotate(69.945 .996 12.078)'/%3e%3cuse xlink:href='%23a' transform='rotate(20.66 -19.689 31.932)'/%3e%3c/svg%3e)