Project description:Determining the pattern of activity of individual connections within a neural circuit could provide insights into the computational processes that underlie brain function. Here, we develop new strategies to label active synapses by trans-synaptic fluorescence complementation in Drosophila. First, we demonstrate that a synaptobrevin-GRASP chimera functions as a powerful activity-dependent marker for synapses in vivo. Next, we create cyan and yellow variants, achieving activity-dependent, multi-colour fluorescence reconstitution across synapses (X-RASP). Our system allows for the first time retrospective labelling of synapses (rather than whole neurons) based on their activity, in multiple colours, in the same animal. As individual synapses often act as computational units in the brain, our method will promote the design of experiments that are not possible using existing techniques. Moreover, our strategies are easily adaptable to circuit mapping in any genetic system.

Project description:We have established a new screening system for identifying interacting proteins by combining biomolecular fluorescence complementation (BiFC) and a transposon gene trap system. This system requires creation of a bait strain that stably expresses a fusion product of part of the fluorescent monomeric Kusabira-Green (mKG) protein to a protein of interest. A PiggyBac transposon vector is then introduced into this strain, and a sequence encoding the remainder of mKG is inserted into the genome and fused randomly with endogenous genes. The binding partner can be identified by isolating cells that fluoresce when BiFC occurs. Using this system, we screened for interactors of p65 (also known as RELA), an NF-κB subunit, and isolated a number of mKG-positive clones. 5'- or 3'-RACE to produce cDNAs encoding mKG-fragment fusion genes and subsequent reconstitution assay identified PKM, HSP90AB1, ANXA2, HSPA8, and CACYBP as p65 interactors. All of these, with the exception of CACYBP, are known regulators of NF-κB. Immunoprecipitation assay confirmed endogenously expressed CACYBP and p65 formed a complex. A reporter assay revealed that CACYBP enhanced 3κB reporter activation under TNFα stimulation. This screening system therefore represents a valuable method for identifying interacting factors that have not been identified by other methods.

Project description:Synaptic vesicles are recycled locally within presynaptic specializations. We examined how vesicles are reused after endocytosis, using transgenic mice expressing the genetically encoded fluorescent indicator synaptopHluorin in subsets of neurons. At both excitatory and inhibitory synapses in cultured hippocampal neurons, newly endocytosed vesicles did not preferentially enter the releasable pool of vesicles. Rather, they entered the reserve pool first and subsequently the readily releasable pool over a period of several minutes. All vesicles in the recycling pool could be accessed by spaced stimuli, arguing against preferential local reuse of the readily releasable vesicles. Interestingly, nearly half the vesicles at excitatory synapses, and a third at inhibitory synapses, could not be recruited for release even by sustained stimuli. We conclude that, at presynaptic terminals in the hippocampus, most vesicles vacate release sites after exocytosis and are replaced by existing vesicles from the reserve pool, placing constraints on kiss-and-run recycling.

Project description:The GDI1 gene encodes ?GDI, which retrieves inactive GDP-bound RAB from membranes to form a cytosolic pool awaiting vesicular release. Mutations in GDI1 are responsible for X-linked Intellectual Disability. Characterization of the Gdi1-null mice has revealed alterations in the total number and distribution of hippocampal and cortical synaptic vesicles, hippocampal short-term synaptic plasticity and specific short-term memory deficits in adult mice, which are possibly caused by alterations of different synaptic vesicle recycling pathways controlled by several RAB GTPases. However, interpretation of these studies is complicated by the complete ablation of Gdi1 in all cells in the brain throughout development. In this study, we generated conditionally gene-targeted mice in which the knockout of Gdi1 is restricted to the forebrain, hippocampus, cortex and amygdala and occurs only during postnatal development. Adult mutant mice reproduce the short-term memory deficit previously reported in Gdi1-null mice. Surprisingly, the delayed ablation of Gdi1 worsens the pre-synaptic phenotype at cortico-amygdala synaptic connections compared to Gdi1-null mice. These results suggest a pivotal role of ?GDI via specific RAB GTPases acting specifically in forebrain regions at the pre-synaptic sites involved in memory formation.

Project description:Kinase-substrate networks are the main components of many signal transduction pathways. Although proteome-wide studies have been successful in elucidating many important biological events including the cataloging of thousands of sites of protein phosphorylation, there is a lack of a universal method to identify the direct upstream kinases responsible for many of these modifications. We have introduced Fluorescence ComplementatiKinase-substrate networks are the main components of many signal transduction pathways. Although proteome-wide studies have been successful in elucidating many important biological events including the cataloging of thousands of sites of protein phosphorylation, there is a lack of a universal method to identify the direct upstream kinases responsible for many of these modifications. We have introduced Fluorescence Complementation Mass Spectrometry (FCMS) as the first proteomic approach that identifies direct upstream kinases in living cells by stabilizing and capturing the kinase-substrate pairs. Using FCMS, we have identified both known and novel direct kinases of cAMP response element-binding protein (CREB). on Mass Spectrometry (FCMS) as the first proteomic approach that identifies direct upstream kinases in living cells by stabilizing and capturing the kinase-substrate pairs. Using FCMS, we have identified both known and novel direct kinases of cAMP response element-binding protein (CREB).

Project description:SLC25A46 is an outer mitochondrial protein, member of the mitochondrial carrier family (SLC25), whereas mutations result in mitochondrial structure abnormalities leading to a wide spectrum of neurological disorders. SLC25A46 is known to interact with members of the MICOS (Mitochondrial Contact Site) complex involved in mitochondrial cristae organization, and components of the endoplasmic reticulum membrane. In the present work, our aim was to identify the interactome of SLC25A46 in cerebrum, cerebellum, heart and thymus from TgSLC25A46-FLAG transgenic mice through immunoprecipitation with anti-FLAG beads and proteomic analysis with LC-MS/MS.

Project description:SLC25A46 is an outer mitochondrial protein, member of the mitochondrial carrier family (SLC25), whereas mutations result in mitochondrial structure abnormalities leading to a wide spectrum of neurological disorders. SLC25A46 is known to interact with members of the MICOS (Mitochondrial Contact Site) complex involved in mitochondrial cristae organization, and components of the endoplasmic reticulum membrane. In the present work, our aim was to identify the interactome of SLC25A46 in cerebrum, cerebellum, heart and thymus from TgSLC25A46-FLAG transgenic mice through immunoprecipitation with anti-FLAG beads and proteomic analysis with LC-MS/MS.

Project description:SLC25A46 is an outer mitochondrial protein, member of the mitochondrial carrier family (SLC25), whereas mutations result in mitochondrial structure abnormalities leading to a wide spectrum of neurological disorders. SLC25A46 is known to interact with members of the MICOS (Mitochondrial Contact Site) complex involved in mitochondrial cristae organization, and components of the endoplasmic reticulum membrane. In the present work, our aim was to identify the interactome of SLC25A46 in cerebrum from TgSLC25A46-FLAG transgenic mice through immunoprecipitation with anti-FLAG beads and proteomic analysis with LC-MS/MS.

Project description:SLC25A46 is an outer mitochondrial protein, member of the mitochondrial carrier family (SLC25), whereas mutations result in mitochondrial structure abnormalities leading to a wide spectrum of neurological disorders. SLC25A46 is known to interact with members of the MICOS (Mitochondrial Contact Site) complex involved in mitochondrial cristae organization, and components of the endoplasmic reticulum membrane. In the present work, our aim was to identify the interactome of SLC25A46 in cerebrum, cerebellum, heart and thymus from TgSLC25A46-FLAG transgenic mice through immunoprecipitation with anti-FLAG beads and proteomic analysis with LC-MS/MS.

Project description:The testing of pathological biomarkers of Alzheimer's disease (AD), such as amyloid beta and tau, is time-consuming, expensive, and invasive. Here, we used 3xTg-AD mice to identify and validate putative novel blood transcriptome biomarkers of AD that can potentially be identified in the blood of patients. mRNA was extracted from the blood and hippocampus of 3xTg-AD and control mice at different ages and used for microarray analysis. Network and functional analyses revealed that the differentially expressed genes between AD and control mice modulated the immune and neuroinflammation systems. Five novel gene transcripts (Cdkn2a, Apobec3, Magi2, Parp3, and Cass4) showed significant increases with age, and their expression in the blood was collated with that in the hippocampus only in AD mice. We further assessed previously identified candidate biomarker genes. The expression of Trem1 and Trem2 in both the blood and brain was significantly increased with age. Decreased Tomm40 and increased Pink1 mRNA levels were observed in the mouse blood. The changes in the expression of Snca and Apoe mRNA in the mouse blood and brain were similar to those found in human AD blood. Our results demonstrated that the immune and neuroinflammatory system is involved in the pathophysiologies of aging and AD and that the blood transcriptome might be useful as a biomarker of AD.