Project description:The subcellular localization and translation of messenger RNA (mRNA) supports functional differentiation between cellular compartments. In neuronal dendrites, local translation of mRNA provides a rapid and specific mechanism for synaptic plasticity and memory formation, and might be involved in the pathophysiology of certain brain disorders. Despite the importance of dendritic mRNA translation, little is known about which mRNAs can be translated in dendrites in vivo and when their translation occurs. Here we collect ribosome-bound mRNA from the dendrites of CA1 pyramidal neurons in the adult mouse hippocampus. We find that dendritic mRNA rapidly associates with ribosomes following a novel experience consisting of a contextual fear conditioning trial. High throughput RNA sequencing followed by machine learning classification reveals an unexpected breadth of ribosome-bound dendritic mRNAs, including mRNAs expected to be entirely somatic. Our findings are in agreement with a mechanism of synaptic plasticity that engages the acute local translation of functionally diverse dendritic mRNAs.

Project description:Comparing WT mice to a mouse model of mental retardation, this work identifies genes which display differences in ribosome-bound mRNAs, in hippocampus CA1 pyramidal cells. These genes products are potent functional components of neuronal plasticity and hippocampus-dependent memory.

Project description:Learning and memory require activity-induced changes in mRNA translation within dendrites, but which mRNAs are involved and how they are regulated remain unclear. We combined proximity labeling with ribosome profiling and CLIP to monitor how depolarization impacts dendritic translation. For a functionally coherent set of transcripts highly enriched in mitochondrial genes, depolarization leads to enhanced uORF translation, eIF4G2 binding, and increased translation. Engineered reporters demonstrate that activity-dependent translational control is conferred by the 5’UTRs and that dendritic localization, eIF4G2 binding, and uORF translation are necessary and sufficient to mediate this regulation. Downstream, this drives activity-dependent changes in dendritic mitochondrial function. Our studies uncover an unanticipated mechanism by which activity-dependent uORF translational control by eIF4G2 enables the coupling of synaptic activity to local remodeling of dendrites.

Project description:Learning and memory require activity-induced changes in mRNA translation within dendrites, but which mRNAs are involved and how they are regulated remain unclear. We combined proximity labeling with ribosome profiling and CLIP to monitor how depolarization impacts dendritic translation. For a functionally coherent set of transcripts highly enriched in mitochondrial genes, depolarization leads to enhanced uORF translation, eIF4G2 binding, and increased translation. Engineered reporters demonstrate that activity-dependent translational control is conferred by the 5’UTRs and that dendritic localization, eIF4G2 binding, and uORF translation are necessary and sufficient to mediate this regulation. Downstream, this drives activity-dependent changes in dendritic mitochondrial function. Our studies uncover an unanticipated mechanism by which activity-dependent uORF translational control by eIF4G2 enables the coupling of synaptic activity to local remodeling of dendrites.

Project description:Background: mRNA localization and translation in neuronal dendrites are the basis for long-term synaptic plasticity and memory formation. RNA granules, membrane-less macromolecular assemblies in which dendritic mRNAs are recruited, are thought to contribute to these processes. RNG105/caprin1 is an RNA granule assembly factor involved in mRNA transport. Results: Genome-wide profiling of mRNA distribution in distinct hippocampal layers revealed dendritically and somatically enriched mRNAs, and demonstrated marked reduction in the differential somato-dendritic localization of the mRNAs in RNG105 cKO mice. Conclusion: RNG105 is an essential factor for the localization of many, but particularly for specific mRNAs localized to dendrites.

Project description:Rett syndrome is caused by mutations in the gene encoding methyl-CpG binding protein 2 (MECP2), an epigenetic regulator of mRNA transcription. Here we report a test of the hypothesis of shared pathophysiology of Rett syndrome and fragile X, another monogenic cause of autism and intellectual disability. In fragile X, the loss of the mRNA translational repressor FMRP leads to exaggerated protein synthesis downstream of metabotropic glutamate receptor 5 (mGluR5). We found that mGluR5- and protein synthesis-dependent synaptic plasticity is similarly altered in area CA1 of Mecp2 KO mice. CA1 pyramidal cell-type-specific, genome-wide profiling of ribosome-bound mRNAs was performed in wild-type and Mecp2 KO hippocampal CA1 neurons to reveal the MeCP2-regulated ‘translatome’. We found significant overlap between ribosome-bound transcripts overexpressed in the Mecp2 KO and FMRP mRNA targets. These tended to encode long genes that are functionally related to either cytoskeleton organization or the development of neuronal connectivity. In the Fmr1 KO mouse, chronic treatment with mGluR5 negative allosteric modulators (NAMs) has been shown to ameliorate many mutant phenotypes by correcting excessive protein synthesis. In the Mecp2 KO mice we found that mGluR5 NAM treatment significantly reduces the level of overexpressed ribosome-associated transcripts, particularly those that are also FMRP targets. Some Rett phenotypes were also ameliorated by treatment, most notably hippocampal cell size and life span. Together, these results suggest a potential mechanistic link between MeCP2-mediated transcription regulation and mGluR5/FMRP-mediated protein translation regulation through co-regulation of a subset of genes relevant to synaptic functions.

Project description:We studied the transcriptomes of mouse CA1 inhibitory cells. Novel clustering methods identified all 23 previously described CA1 inhibitory types, while also suggesting 6 new inhibitory classes. Latent‐factor analysis revealed a common continuum of expression of many genes within and between classes, which we hypothesized correlates with a continuum from faster‐spiking cells that proximally target pyramidal cells, to slower active cells targeting pyramidal distal dendrites or interneurons.

Project description:Mammalian target of rapamycin (mTOR) is implicated in synaptic plasticity and local translation in dendrites. Here we found that the mTOR inhibitor, rapamycin, increased the Kv1.1 voltage-gated potassium channel protein in hippocampal neurons and promoted Kv1.1 surface expression on dendrites without altering its axonal expression. Moreover, endogenous Kv1.1 mRNA was detected in dendrites. Using Kv1.1 fused to the photo-convertible fluorescence protein Kaede as a reporter for local synthesis, we observed Kv1.1 synthesis in dendrites upon inhibition of mTOR or the N-methyl-D-aspartate (NMDA) glutamate receptor. Thus, synaptic excitation may cause local suppression of dendritic Kv1 channels by reducing their local synthesis. Experiment Overall Design: mRNA isoloated from the synaptosomes of the hippocampus is compared to mRNA isolated from the total hippocampus to identify mRNAs that are enriched at the synapse

Project description:Previous work demonstrated that the developmental pruning of dendritic spines requires autophagy. This developmental process is facilitated by long-term depression (LTD)-like mechanisms, inviting the speculation that LTD, a fundamental form of plasticity, itself requires autophagy. Here, we show that LTD-inducing activation of NMDA receptors or metabotropic glutamate receptors triggers the rapid initiation of autophagy in postsynaptic dendrites. Dendritic autophagic vesicles (AVs) act in parallel with the endocytic machinery to remove AMPAR subunits from the surface and rapidly degrade them and their scaffold PSD95. Moreover, during NMDAR-LTD, key postsynaptic proteins are sequestered for autophagic degradation, as revealed by quantitative proteomic profiling of purified AVs. In turn, pharmacological inhibition of AV biogenesis, or conditional ablation of atg5 in pyramidal neurons abolishes LTD and instead triggers sustained potentiation in the hippocampus. These deficits in synaptic plasticity are recapitulated by knockdown of atg5 specifically in postsynaptic pyramidal neurons in the CA1 area. Conducive to the role of synaptic plasticity in behavioral flexibility, mice with autophagy deficiency in excitatory neurons exhibit altered response in reversal learning. Therefore, local assembly of the autophagic machinery in dendrites ensures the degradation of postsynaptic components and facilitates LTD expression.

Project description:Dysregulated protein synthesis is a core pathogenic mechanism in Fragile X Syndrome (FX). The mGluR Theory of FX predicts that pathological synaptic changes arise from the excessive translation of mRNAs downstream of mGlu1/5 activation. Here, we use a combination of CA1 pyramidal neuron-specific Translating Ribosome Affinity Purification and RNA-seq (TRAP-seq) and proteomics to identify the overtranslating mRNAs supporting exaggerated mGlu1/5 -induced long-term synaptic depression (mGluR-LTD) in the FX mouse model (Fmr1-/y). Our results identify a robust translation of ribosomal proteins (RPs) upon mGlu1/5 stimulation that coincides with a reduced translation of long mRNAs encoding synaptic proteins. These changes are mimicked and occluded in Fmr1-/y neurons. In addition, proteomics analyses identify increased degradation of multiple proteins at hippocampal synapses, many of which are underexpressed at steady-state.