Project description:Elevation of intracellular Ca2+ ([Ca2+]i) activates Ca2+/calmodulin-dependent kinases (CaMK) and promotes gene transcription. This essential signaling pathway is referred to as excitation-transcription (E-T) coupling. Although vascular myocytes can exhibit E-T coupling, the molecular mechanisms and physiological/pathological roles are unknown. Multiscale analysis spanning from single molecules to whole organisms has revealed essential steps in mouse vascular smooth muscle E-T coupling: (1) Upon depolarizing stimulus Ca2+ influx through voltage-dependent Ca2+ channel Cav1.2 activates CaMKK2, which results in phosphorylation of CaMK1a and CREB in the nucleus. (2) Within caveolae the formation of molecular complex of Cav1.2/CaMKK2/CaMK1a is promoted in the vascular myocytes. (3) Ca2+ influx through Cav1.2 localized to caveolae directly activates CaMKK2. (4) CaMK1a is phosphorylated by CaMKK2 at caveolae and translocated to the nucleus upon membrane depolarization. In addition, RNAseq analysis revealed that sustained depolarization of mesenteric artery preparation selectively induced genes related to chemotaxis, leukocyte adhesion and inflammation, and these changes were reversed by inhibitors of Cav1.2, CaMKK2 and CaMK or disruption of caveolae. In the context of pathophysiology, when mesenteric artery was loaded by high pressure in vivo, we noted CREB phosphorylation in myocytes, macrophage accumulation at adventitia, and increased thickness and cross-sectional area of tunica media. These changes were reduced in caveolin1-KO mice or in mice treated with a CaMKK2 inhibitor STO609. In summary, E-T coupling depend on Cav1.2/CaMKK2/CaMK1a localized to caveolae, and this molecular complex converts [Ca2+]i changes to gene transcription, leading to macrophage accumulation and media remodeling for adaptation to increased circumferential stretch.

Project description:Effect of CaM overexpression on Arabidopsis transcriptome. Unlike animals, plants are immobile and cannot simply move away from unfavourable environments and thus have developed complex mechanisms to respond to and sense biotic and abiotic signals. These stimuli often lead to tightly controlled changes in cytoplasmic free calcium concentration [Ca2+]cyt termed "calcium signatures" which are thought to be, at least partly, responsible for the specificity of plant responses to the environment. However little is known about how exactly these calcium signatures are decoded into specific end-responses. Calmodulin (CaM) is the most well characterised Ca2+ binding protein and is the primary sensor of changing [Ca2+]. Upon binding Ca2+ CaM undergoes a conformational change allowing binding and activation of a wide variety of target proteins. In plants CaM exists in gene families encoding multiple isoforms. The expression of individual CaM genes can be differentially regulated and isoforms may be differentially localised. Furthermore specific isoforms can bind and activate different target proteins. These features of plant CaM allow the possibility of specificity during calcium signalling in response to specific stimuli. The effect of overexpression of four CaM protein isoforms on the Arabidopsis thaliana transcriptome will be investigated. Ten day old transgenic Arabidopsis seedlings (containing estradiol inducible CaM overexpression constructs) were induced for 9hrs in 5uM estradiol with appropriate water (0.025% DMSO) and empty vector controls.

Project description:Toxoplasma gondii is an apicomplexan parasite infecting human and animals, causing huge health concerns and economic losses. Calcium ion, a critical second messenger in cells, can regulate related vital activities, particularly in parasite invasion and escape processes. Calmodulin (CaM) is a short, highly conserved Ca2+ binding protein found in all eukaryotic cells, including apicomplexan parasites. After binding to Ca2+, CaM can be activated to interact with a variety of proteins (such as enzymes). Since direct destruction of CaM is impossible, few studies have been conducted on the function of CaM in T. gondii. We generated the CaM indirect knockout strain (iCaM) using a tetracycline-off system with CaM promoter sequence in T. gondii TATI strain, and compared the transcriptomes of tachyzoites with and without Calmodulin.

Project description:Regulator of G Protein Signaling 14 (RGS14) is a complex scaffolding protein with an unusual domain structure that allows it to integrate G protein and mitogen-activated protein kinase (MAPK) signaling pathways. RGS14 mRNA and protein are enriched in brain tissue of rodents and primates. In the adult mouse brain, RGS14 is predominantly expressed in postsynaptic dendrites and spines of hippocampal CA2 pyramidal neurons where it naturally inhibits synaptic plasticity and hippocampus-dependent learning and memory. However, the signaling proteins that RGS14 natively interacts with in neurons to regulate plasticity are unknown. Here, we show that RGS14 exists as a component of a high molecular weight protein complex in brain. To identify RGS14 neuronal interacting partners, endogenous RGS14 isolated from mouse brain was subjected to mass spectrometry and proteomic analysis. We find that RGS14 interacts with key postsynaptic proteins that regulate neuronal plasticity. Gene ontology analysis reveals that the most enriched RGS14 interacting proteins have functional roles in actin-binding, calmodulin(CaM)-binding, and CaM-dependent protein kinase (CaMK) activity. We validate these proteomics findings using biochemical assays that identify interactions between RGS14 and two previously unknown binding partners: CaM and CaMKII. We report that RGS14 directly interacts with CaM in a calcium-dependent manner and is phosphorylated by CaMKII in vitro. Lastly, we detect that RGS14 associates with CaMKII and with CaM in hippocampal CA2 neurons by proximity ligation assays in mouse brain sections. Taken together, these findings demonstrate that RGS14 is a novel CaM effector and CaMKII phosphorylation substrate thereby providing new insight into cellular mechanisms by which RGS14 controls plasticity in CA2 neurons.

Project description:Cysteine dioxygenase type 1 (Cdo1) is a key enzyme for cysteine catabolism that is enriched in liver, whose role in NAFLD remains poorly understood. Here, we show that exercise induces the expression of hepatic Cdo1 via the cAMP/PKA/CREB signaling pathway. Hepatocyte-specific knockout of Cdo1 (Cdo1LKO) impairs the effect of exercise against NAFLD, whereas hepatocyte-specific overexpression of Cdo1 (Cdo1LTG) and exercise synergistically ameliorates NAFLD in male mice. Mechanistically, Cdo1 facilitates the binding between AMPK and kinase active Camkk2, which activates AMPK signaling. This promotes fatty acid oxidation and mitochondrial biogenesis in hepatocytes to attenuate hepatosteatosis. Therefore, by promoting hepatic Camkk2-AMPK signaling pathway, Cdo1 acts as an important downstream effector of exercise to combat against NAFLD

Project description:Toxoplasma gondii is an apicomplexan parasite infecting human and animals, causing huge health concerns and economic losses. Calcium ion, a critical second messenger in cells, can regulate related vital activities, particularly in parasite invasion and escape processes. Calmodulin (CaM) is a short, highly conserved Ca2+ binding protein found in all eukaryotic cells, including apicomplexan parasites. After binding to Ca2+, CaM can be activated to interact with a variety of proteins (such as enzymes). Nevertheless, CaM-interacting proteins have not been identified in T. gondii. We report here the use of T. gondii strain RH△hxgprt expressing the proximity-labeling enzyme BirA* fused to CaM, in combination with LC-MS/MS to specifically identify CaM-interacting proteins. Our study revealed over three hundred of CaM’s proximal interacting proteins in T. gondii. These CaM partners were broadly dispersed throughout the parasite. The majority of their CRISPR fitness scores were below zero, indicating CaM's essential functions in parasites.

Project description:Ca2+ is a second messenger that regulates a variety of cellular responses in fungi. However, the mechanism behind how Ca2+ signals are transmitted within the cell as they regulate downstream targets remains unclear. We used a fluorescent Ca2+ biosensor to visualize the changes in Ca2+ concentration in the hyphae of the filamentous fungus Aspergillus nidulans in response to thermal stress via infrared laser point irradiation, and then we analyzed the characteristics of the periodic Ca2+ influx in the hyphae. Stress-responsive Ca2+ pulses promoted the reorganization of the actin cytoskeleton and exocytosis, and they controlled the resumption, redirection, or branching of hyphal growth. To clarify how calcium signals are transmitted to downstream targets, we focused on calmodulin (CaM) and calcium/CaM-dependent protein kinases (CaMKs; CmkA, CmkB, and CmkC) by clarifying their localization and studying their interacting proteins by GFP-trap and MS analysis. Analysis of proteins that co-precipitated with CaM or CamKs showed that the calcium signaling pathway is involved in actin cytoskeleton rearrangement, vesicle transport, cell wall synthesis, and the cell wall integrity (CWI) pathway. Our approach enabled us to visualize the actual conduction of Ca2+ in hyphae in response to stress, and it clarified the downstream targets of CaM and CaMKs, thereby connecting the series of events, from input to output that are involved in calcium signaling.

Project description:Purpose: Cardiac hypertrophy is a well-known major risk factor for poor prognosis in patients with cardiovascular diseases. Dysregulation of intracellular Ca2+ is involved in the pathogenesis of cardiac hypertrophy. However, the precise mechanism underlying cardiac hypertrophy remains elusive. Here, we investigated whether pressure-overload induced hypertrophy can be induced by destabilization of cardiac ryanodine receptor (RyR2) through calmodulin (CaM) dissociation and subsequent Ca2+ leakage, and whether it can be genetically rescued by enhancing the binding affinity of CaM to RyR2. Methods: To examine the role of CaM-RyR2 complex in the development of pressure-overload induced cardiac hypertrophy, whole transcriptome analysis using RNA-seq analysis in the hearts from WT and homozygous RyR2V3599K/V3599K (V3599K) mice with or without transverse aortic constriction (TAC) was performed to elucidate the RyR2 signaling pathway in the heart. Results: Gene expression increased in WT (+TAC) hearts compared to WT (-TAC) hearts; however, this increase was not observed in V3599K (+TAC) hearts. Conclusions: Enhanced CaM binding to RyR2 decreased expression of hypertrophy-related genes.

Project description:Indentification of CaMKK2-binding proteins under cystine starvation condition in 293T cells.

Project description:Membrane adenylyl cyclases (ACs) catalyze the conversion of ATP to cAMP, a second messenger involved in different signaling pathways. AC8 is one of the 9 membrane-bound isoforms, present in the brain and implicated in cognitive functions. AC8 is regulated by Ca2+/CaM and different G proteins but structural evidence on its regulation is scarce. We solved the structure of full-length AC8 in complex with Gas and CaM. ACs contain large stretches of disordered/highly flexible domains that cannot be resolved with cryo-EM. To overcome this limitation, we have studied AC8's interaction with CaM, Gas and Gbg using crosslinking mass spectrometry (XL-MS).