PIP[subscript 3] Regulates Spinule Formation in Dendritic Spines during Structural Long-Term Potentiation

Dendritic spines are small, highly motile structures on dendritic shafts that provide flexibility to neuronal networks. Spinules are small protrusions that project from spines. The number and the length of spinules increase in response to activity including theta burst stimulation and glutamate application. However, what function spinules exert and how their formation is regulated still remains unclear. Phosphatidylinositol-3,4,5-trisphosphate (PIP[subscript 3]) plays important roles in cell motility such as filopodia and lamellipodia by recruiting downstream proteins such as Akt and WAVE to the membrane, respectively. Here we reveal that PIP[subscript 3] regulates spinule formation during structural long-term potentiation (sLTP) of single spines in CA1 pyramidal neurons of hippocampal slices from rats. Since the local distribution of PIP[subscript 3] is important to exert its functions, the subcellular distribution of PIP[subscript 3] was investigated using a fluorescence lifetime-based PIP[subscript 3] probe. PIP[subscript 3] accumulates to a greater extent in spines than in dendritic shafts, which is regulated by the subcellular activity pattern of proteins that produce and degrade PIP[subscript 3]. Subspine imaging revealed that when sLTP was induced in a single spine, PIP[subscript 3] accumulates in the spinule whereas PIP[subscript 3] concentration in the spine decreased.National Institutes of Health (U.S.) (Grant R01DA17310

Application of FRET probes in the analysis of neuronal plasticity

Breakthroughs in imaging techniques and optical probes in recent years have revolutionized the field of life sciences in ways that traditional methods could never match. The spatial and temporal regulation of molecular events can now be studied with great precision. There have been several key discoveries that have made this possible. Since green fluorescent protein (GFP) was cloned in 1992, it has become the dominant tracer of proteins in living cells. Then the evolution of color variants of GFP opened the door to the application of Förster resonance energy transfer (FRET), which is now widely recognized as a powerful tool to study complicated signal transduction events and interactions between molecules. Employment of fluorescent lifetime imaging microscopy (FLIM) allows the precise detection of FRET in small subcellular structures such as dendritic spines. In this review, we provide an overview of the basic and practical aspects of FRET imaging and discuss how different FRET probes have revealed insights into the molecular mechanisms of synaptic plasticity and enabled visualization of neuronal network activity both in vitro and in vivo.National Science Foundation (U.S.) (Grant R01DA17310

Protocol for screening cellular outputs activated by optogenetically controlled temporal PI3K signaling activation patterns

Summary: PI3K signaling elicits distinct outputs in response to different patterns of extracellular stimulation. Here, we present a protocol for screening cellular outputs activated by optogenetically controlled temporal PI3K signaling activation patterns in 96-well plates. We describe steps for establishing PPAP2-stable cells, probe expression, and blue light irradiation. We then detail procedures for analysis of translation activity. This protocol can be applied for purposes, such as examining the effect of PI3K signaling on the efficacy of anticancer drugs.For complete details on the use and execution of this protocol, please refer to Ueda et al. (2022).1 : Publisher’s note: Undertaking any experimental protocol requires adherence to local institutional guidelines for laboratory safety and ethics

Comparative Analysis of Biological Sphingolipids with Glycerophospholipids and Diacylglycerol by LC-MS/MS

Liquid chromatography-electrospray ionization mass spectrometry (LC-MS) is an effective and popular technique used in lipid metabolomic studies. Although many LC-MS methods enabling the determination of sphingolipid molecular species have been reported, they do not cover a broad range of sphingolipid metabolites with expanding glycerophospholipids (GPLs) and diacylglycerol (DAG). In this study, we developed an approach for the comprehensive analysis of sphingolipids, GPLs and DAG molecular species in a biological sample, without alkaline hydrolysis. After validating the reliability of this approach, we analyzed tissue lipids of sphingomyelin synthase 2-knockout mice and found that changes in sphingolipid metabolism in the liver affect the level of docosahexaenoic acid-containing GPLs. Our method analyzes GPLs and DAG, as well as sphingolipids within biological samples and, thus, will facilitate more comprehensive studies of sphingolipid metabolism in pathology and diagnostics

Assembly Domain-Based Optogenetic System for the Efficient Control of Cellular Signaling

We previously developed the Magnet system, which consists of two distinct Vivid protein variants, one positively and one negatively charged, designated the positive Magnet (pMag) and negative Magnet (nMag), respectively. These two proteins bind to each other through electrostatic interactions, preventing unwanted homodimerization and providing selective light-induced heterodimerization. The Magnet system enables the manipulation of cellular functions such as protein–protein interactions and genome editing, although the system could be improved further. To enhance the ability of pMagFast2 (a pMag variant with fast kinetics) to bind nMag, we introduced several pMagFast2 modules in tandem into a single construct, pMagFast2(3×). However, the expression level of this construct decreased drastically with increasing number of pMagFast2 molecules integrated into a single construct. In the present study, we applied a new approach to improve the Magnet system based on an assembly domain (AD). Among several ADs, the Ca²⁺/calmodulin-dependent protein kinase IIα association domain (CAD) most enhanced the Magnet system. The present CAD-Magnet system overcame a trade-off issue between the expression level and binding affinity. The CAD-converged 12 pMag photoswitches exhibited a stronger interaction with nMag after blue light irradiation compared with monomeric pMag. Additionally, the CAD played a key role in converging effector proteins as well in a single complex. Owing to these substantial improvements, the CAD-Magnet system combined with Tiam1 allowed us to robustly induce localized formation of vertical ruffles on the apical plasma membrane. The CAD-Magnet system combined with 4D imaging was instrumental in revealing the dynamics of ruffle formation

Assembly Domain-Based Optogenetic System for the Efficient Control of Cellular Signaling

We previously developed the Magnet system, which consists of two distinct Vivid protein variants, one positively and one negatively charged, designated the positive Magnet (pMag) and negative Magnet (nMag), respectively. These two proteins bind to each other through electrostatic interactions, preventing unwanted homodimerization and providing selective light-induced heterodimerization. The Magnet system enables the manipulation of cellular functions such as protein–protein interactions and genome editing, although the system could be improved further. To enhance the ability of pMagFast2 (a pMag variant with fast kinetics) to bind nMag, we introduced several pMagFast2 modules in tandem into a single construct, pMagFast2(3×). However, the expression level of this construct decreased drastically with increasing number of pMagFast2 molecules integrated into a single construct. In the present study, we applied a new approach to improve the Magnet system based on an assembly domain (AD). Among several ADs, the Ca²⁺/calmodulin-dependent protein kinase IIα association domain (CAD) most enhanced the Magnet system. The present CAD-Magnet system overcame a trade-off issue between the expression level and binding affinity. The CAD-converged 12 pMag photoswitches exhibited a stronger interaction with nMag after blue light irradiation compared with monomeric pMag. Additionally, the CAD played a key role in converging effector proteins as well in a single complex. Owing to these substantial improvements, the CAD-Magnet system combined with Tiam1 allowed us to robustly induce localized formation of vertical ruffles on the apical plasma membrane. The CAD-Magnet system combined with 4D imaging was instrumental in revealing the dynamics of ruffle formation

Assembly Domain-Based Optogenetic System for the Efficient Control of Cellular Signaling

We previously developed the Magnet system, which consists of two distinct Vivid protein variants, one positively and one negatively charged, designated the positive Magnet (pMag) and negative Magnet (nMag), respectively. These two proteins bind to each other through electrostatic interactions, preventing unwanted homodimerization and providing selective light-induced heterodimerization. The Magnet system enables the manipulation of cellular functions such as protein–protein interactions and genome editing, although the system could be improved further. To enhance the ability of pMagFast2 (a pMag variant with fast kinetics) to bind nMag, we introduced several pMagFast2 modules in tandem into a single construct, pMagFast2(3×). However, the expression level of this construct decreased drastically with increasing number of pMagFast2 molecules integrated into a single construct. In the present study, we applied a new approach to improve the Magnet system based on an assembly domain (AD). Among several ADs, the Ca²⁺/calmodulin-dependent protein kinase IIα association domain (CAD) most enhanced the Magnet system. The present CAD-Magnet system overcame a trade-off issue between the expression level and binding affinity. The CAD-converged 12 pMag photoswitches exhibited a stronger interaction with nMag after blue light irradiation compared with monomeric pMag. Additionally, the CAD played a key role in converging effector proteins as well in a single complex. Owing to these substantial improvements, the CAD-Magnet system combined with Tiam1 allowed us to robustly induce localized formation of vertical ruffles on the apical plasma membrane. The CAD-Magnet system combined with 4D imaging was instrumental in revealing the dynamics of ruffle formation