Project description:The molecular mechanisms that enable memories to persist over long time-scales from days to weeks and months are still poorly understood. To develop insights, we created a behavioral task where by varying the frequency of learned associations, mice formed multiple memories, but only consolidated some while forgetting others, over the span of weeks. We then monitored circuit-specific molecular programs that diverge between consolidated and forgotten memories. We identified multiple distinct waves of transcription, i.e., cellular macrostates, specifically in the thalamo-cortical circuit, that defined memory persistence. Notably, a small set of transcriptional regulators appeared sufficient to orchestrate broad molecular programs that enabled entry into these macrostates. Targeted CRISPR-manipulations of these transcriptional regulators revealed that while they had no effects on memory formation, they had prominent, causal, and strikingly time-dependent roles in memory stabilization. In particular, the calmodulin-dependent transcription factor Camta1 was required for initial memory maintenance over days, while Tcf4 and the histone methyl-transferase Ash1L were required later to maintain memory over weeks. These results identify a critical Camta1-Tcf4-Ash1L thalamo-cortical transcriptional cascade required for memory stabilization, and puts forth a model where the sequential, multi-step, recruitment of circuit-specific transcriptional programs enable memory maintenance over progressively longer time-scales.

Project description:The molecular mechanisms that enable memories to persist over long time-scales from days to weeks and months are still poorly understood. To develop insights, we created a behavioral task where by varying the frequency of learned associations, mice formed multiple memories, but only consolidated some while forgetting others, over the span of weeks. We then monitored circuit-specific molecular programs that diverge between consolidated and forgotten memories. We identified multiple distinct waves of transcription, i.e., cellular macrostates, specifically in the thalamo-cortical circuit, that defined memory persistence. Notably, a small set of transcriptional regulators appeared sufficient to orchestrate broad molecular programs that enabled entry into these macrostates. Targeted CRISPR-manipulations of these transcriptional regulators revealed that while they had no effects on memory formation, they had prominent, causal, and strikingly time-dependent roles in memory stabilization. In particular, the calmodulin-dependent transcription factor Camta1 was required for initial memory maintenance over days, while Tcf4 and the histone methyl-transferase Ash1L were required later to maintain memory over weeks. These results identify a critical Camta1-Tcf4-Ash1L thalamo-cortical transcriptional cascade required for memory stabilization, and puts forth a model where the sequential, multi-step, recruitment of circuit-specific transcriptional programs enable memory maintenance over progressively longer time-scales.

Project description:Novel taste memories, critical for animal survival, are consolidated to form long term memories which are dependent on translation regulation in the gustatory cortex We used microarray for identification of genes involved in novel taste learning at two time points- 1 and 3 hours following memory formation for novel taste

Project description:Novel taste memories, critical for animal survival, are consolidated to form long term memories which are dependent on translation regulation in the gustatory cortex We used microarray for identification of genes involved in novel taste learning at two time points- 1 and 3 hours following memory formation for novel taste Adult rats were separated into two groups- novel tatse (0.1% sacchain) and water, two time points were used 1, 3 hours following learnin. Rna was extracted and hybridized on Affymetrix microarray

Project description:The expression profiles of circRNAs in Jurkats cells, co-cultured with and without ionomycin, were analyzed by next-generation sequencing and validated using real-time polymerase chain reaction. The identified Ca2+ influx-regulated circRNAs were further examined in T cells from 42 patients with SLE and 23 healthy controls. The biological function of specific circRNAs was investigated using transfection and RNA pull-down assay. After validation, we confirmed that the expression levels of circ-ERCC4, circ-NFATC2, circ-MYH10, circ-CAMTA1, circ-ASH1L, circ-SOCS7, and circ-ASAP1 were consistently increased in Jurkat cells following Ca2+ influx. The expression levels of circ-CAMTA1, circ-ASH1L, and circ-ASAP1 were significantly lower in T cells from patients with SLE, with even lower levels observed in those with higher disease activity. Interferon (IFN)-α was found to suppress the expression of circ-CAMTA1. Circ-CAMTA1 bound to pyruvate carboxylase and inhibited its biologic activity. Overexpression of circ-CAMTA1, but not its linear form, significantly decreased extracellular glucose levels. Furthermore, increased expression of circ-CAMTA1, but not its linear form, enhanced IL-2 secretion and the protein expression of NFAT1.

Project description:Sequential transcriptional gates in the thalamo-cortical circuit coordinate memory stabilization

Project description:Sequential transcriptional gates in the thalamo-cortical circuit support memory stabilization [ATAC]

Project description:Single cell RNA-seq characterization of stem cell derived organoids resembling the parts of human cortico-striatal-thalamo-cortical circuit

Project description:Sequential transcriptional gates in the thalamo-cortical circuit support memory stabilization [ChIP-seq]

Project description:Social communication guides decision making that is essential for survival. Social transmission of food preference (STFP) is an ecologically relevant memory paradigm in which an animal learns a desirable food odor from other animals in a social context. How food-preference memory is acquired, consolidated, and stored is unclear. Here, we identify a circuit involving the posteromedial nucleus of the cortical amygdala (COApm) as a computational center that integrates social and sensory olfactory inputs for long-term STFP memory consolidation. Blocking synaptic signaling by the COApm circuit selectively abolished STFP memory consolidation without impairing memory acquisition, storage, or recall. STFP memory consolidation by the COApm depends on synaptic inputs from the accessory olfactory bulb and on synaptic outputs to the anterior olfactory nucleus and requires protein synthesis, suggesting a gene expression mechanism. Deep single-cell and spatial transcriptomics revealed robust but distinct gene expression signatures induced by STFP memory formation in the COApm consistent with synapse restructuring. Our data thus define a neural circuit for consolidation of a socially communicated long-term memory, thereby mechanistically distinguishing protein synthesis-dependent memory consolidation from memory acquisition, storage, or retrieval.