Project description:Pattern recognition receptors (PRRs) at the plasma membrane promote plant immunity through the detection of conserved microbe-associated molecular patterns (MAMPs). In plants, the PRR for bacterial flagellin (flg22) is encoded by the receptor kinase FLS2. One of the earliest MAMP responses is the rapid and transient increase of cytosolic calcium (Ca2+) ions, which is required for many of the well-described downstream responses, e.g. generation of reactive oxygen species (ROS) and the transcriptional activation of defence-associated genes. Despite its relevance, the molecular components regulating the Ca2+ burst remain largely unknown. Here, we show that the plasma membrane P2B-type Ca2+ ATPase ACA8 forms a dynamic complex with the PRR FLS2. ACA8 and its closest homologue ACA10 are required for immunity against virulent bacteria. Mutant aca8 aca10 plants are reduced in the flg22-induced Ca2+ burst, show reduced ROS production and exhibit altered transcriptional reprogramming. In particular, flg22-induced gene expression is elevated downstream of signalling mitogen-activated protein (MAP) kinases, but reduced downstream of the calcium-dependent protein (CDP) kinase cascade. These results demonstrate that the fine regulation of Ca2+ fluxes in the cytosol is critical for the coordination of the downstream MAMP responses and provide for the first time a link between the FLS2 receptor complex and signalling kinases via the secondary messenger Ca2+. ACA8 also interacted with the BRI1 and CLV1 receptor kinases, which correlated with the developmental phenotypes of aca8 aca10 mutants suggesting a broader role for Ca2+ ATPases in receptor-mediated signalling. We used Affymetrix Arabidopsis Tiling 1.0R Array to compare global transcript levels in 7 days-old sterile grown seedlings. Steady-state mRNA levels in total RNA samples of 7 days old sterile seedlings

Project description:Pattern recognition receptors (PRRs) at the plasma membrane promote plant immunity through the detection of conserved microbe-associated molecular patterns (MAMPs). In plants, the PRR for bacterial flagellin (flg22) is encoded by the receptor kinase FLS2. One of the earliest MAMP responses is the rapid and transient increase of cytosolic calcium (Ca2+) ions, which is required for many of the well-described downstream responses, e.g. generation of reactive oxygen species (ROS) and the transcriptional activation of defence-associated genes. Despite its relevance, the molecular components regulating the Ca2+ burst remain largely unknown. Here, we show that the plasma membrane P2B-type Ca2+ ATPase ACA8 forms a dynamic complex with the PRR FLS2. ACA8 and its closest homologue ACA10 are required for immunity against virulent bacteria. Mutant aca8 aca10 plants are reduced in the flg22-induced Ca2+ burst, show reduced ROS production and exhibit altered transcriptional reprogramming. In particular, flg22-induced gene expression is elevated downstream of signalling mitogen-activated protein (MAP) kinases, but reduced downstream of the calcium-dependent protein (CDP) kinase cascade. These results demonstrate that the fine regulation of Ca2+ fluxes in the cytosol is critical for the coordination of the downstream MAMP responses and provide for the first time a link between the FLS2 receptor complex and signalling kinases via the secondary messenger Ca2+. ACA8 also interacted with the BRI1 and CLV1 receptor kinases, which correlated with the developmental phenotypes of aca8 aca10 mutants suggesting a broader role for Ca2+ ATPases in receptor-mediated signalling. We used Affymetrix Arabidopsis Tiling 1.0R Array to compare global transcript levels in 7 days-old sterile grown seedlings.

Project description:In this work, we set out to identify and characterize the calcium occluded intermediate(s) of the plasma membrane Ca(2+)-ATPase (PMCA) to study the mechanism of calcium transport. To this end, we developed a procedure for measuring the occlusion of Ca(2+) in microsomes containing PMCA. This involves a system for overexpression of the PMCA and the use of a rapid mixing device combined with a filtration chamber, allowing the isolation of the enzyme and quantification of retained calcium. Measurements of retained calcium as a function of the Ca(2+) concentration in steady state showed a hyperbolic dependence with an apparent dissociation constant of 12 ± 2.2 ?M, which agrees with the value found through measurements of PMCA activity in the absence of calmodulin. When enzyme phosphorylation and the retained calcium were studied as a function of time in the presence of La(III) (inducing accumulation of phosphoenzyme in the E(1)P state), we obtained apparent rate constants not significantly different from each other. Quantification of EP and retained calcium in steady state yield a stoichiometry of one mole of occluded calcium per mole of phosphoenzyme. These results demonstrate for the first time that one calcium ion becomes occluded in the E(1)P-phosphorylated intermediate of the PMCA.

Project description:BackgroundMarlin-1 is a microtubule binding protein that associates specifically with the GABAB1 subunit in neurons and with members of the Janus kinase family in lymphoid cells. In addition, it binds the molecular motor kinesin-I and nucleic acids, preferentially single stranded RNA. Marlin-1 is expressed mainly in the central nervous system but little is known regarding its cellular and subcellular distribution in the brain.ResultsHere we have studied the localization of Marlin-1 in the rodent brain and cultured neurons combining immunohistochemistry, immunofluorescence and pre-embedding electron microscopy. We demonstrate that Marlin-1 is enriched in restricted areas of the brain including olfactory bulb, cerebral cortex, hippocampus and cerebellum. Marlin-1 is abundant in dendrites and axons of GABAergic and non-GABAergic hippocampal neurons. At the ultrastructural level, Marlin-1 is present in the cytoplasm and the nucleus of CA1 neurons in the hippocampus. In the cytoplasm it associates to microtubules in the dendritic shaft and occasionally with the Golgi apparatus, the endoplasmic reticulum (ER) and dendritic spines. In the nucleus, clusters of Marlin-1 associate to euchromatin.ConclusionOur results demonstrate that Marlin-1 is expressed in discrete areas of the brain. They also confirm the microtubule association at the ultrastructural level in neurons. Together with the abundance of the protein in dendrites and axons they are consistent with the emerging role of Marlin-1 as an intracellular protein linking the cytoskeleton and transport. Our study constitutes the first detailed description of the cellular and subcellular distribution of Marlin-1 in the brain. As such, it will set the basis for future studies on the functional implications of Marlin-1 in protein trafficking.

Project description:The plasma membrane calcium extrusion mechanism, PMCA (plasma membrane calcium ATPase) isoform 2 is richly expressed in the brain and particularly the cerebellum. Whilst PMCA2 is known to interact with a variety of proteins to participate in important signalling events [Strehler EE, Filoteo AG, Penniston JT, Caride AJ (2007) Plasma-membrane Ca(2+) pumps: structural diversity as the basis for functional versatility. Biochem Soc Trans 35 (Pt 5):919-922], its molecular interactions in brain synapse tissue are not well understood. An initial proteomics screen and a biochemical fractionation approach identified PMCA2 and potential partners at both pre- and post-synaptic sites in synapse-enriched brain tissue from rat. Reciprocal immunoprecipitation and GST pull-down approaches confirmed that PMCA2 interacts with the post-synaptic proteins PSD95 and the NMDA glutamate receptor subunits NR1 and NR2a, via its C-terminal PDZ (PSD95/Dlg/ZO-1) binding domain. Since PSD95 is a well-known partner for the NMDA receptor this raises the exciting possibility that all three interactions occur within the same post-synaptic signalling complex. At the pre-synapse, where PMCA2 was present in the pre-synapse web, reciprocal immunoprecipitation and GST pull-down approaches identified the pre-synaptic membrane protein syntaxin-1A, a member of the SNARE complex, as a potential partner for PMCA2. Both PSD95-PMCA2 and syntaxin-1A-PMCA2 interactions were also detected in the molecular and granule cell layers of rat cerebellar sagittal slices by immunohistochemistry. These specific molecular interactions at cerebellar synapses may allow PMCA2 to closely control local calcium dynamics as part of pre- and post-synaptic signalling complexes.

Project description:GLT1, the predominant glutamate transporter of the forebrain, exists in two splice variant isoforms, i.e., GLT1a and GLT1b. Although GLT1 was originally detected only in astrocytes, we have recently demonstrated that GLT1a protein is expressed by neurons in the hippocampus as well. In the present study, the mRNA distribution patterns for the two isoforms were examined throughout the rat brain by using nonisotopic in situ hybridization and variant-specific RNA probes. Both isoforms were expressed in neuronal subgroups outside the hippocampus, such as in the cerebral cortex layer VI, or the neurons in the olfactory tubercle. As was the case in the hippocampus, GLT1a was the predominant transcript in neurons in these regions as well. Both GLT1 isoforms were widely expressed in astrocytes throughout the brain. GLT1a mRNA expression in astrocytes showed noticeable variation in labeling intensity in subregions of the hippocampus and other areas, whereas GLT1b expression in astrocytes was relatively homogeneous. On the subcellular level, GLT1a mRNA was expressed primarily in astrocyte processes, whereas GLT1b mRNA was more restricted to the astrocyte cell body. The two isoforms showed similar distributions in the subfornical organ and in tanycytes of the third ventricle. However, GLT1 expression in the pineal gland and the retina was due primarily to GLT1b, whereas GLT1a was more strongly expressed in Bergman glia in the cerebellum. These findings suggest that the expression of the two GLT1 isoforms is regulated by different mechanisms. Moreover, the function of the two isoforms may be subject to different regulatory processes.

Project description:The cellular localization of exogenous proteins expressed in transgenic crops not only determines their stability, but also their effects on crop growth and development, including under stressful conditions; however, the underlying molecular mechanisms remain unknown. Here, we determined the cellular distribution of exogenously expressed Cry1Ab/c protein in insect-resistant transgenic rice Huahui-1 (HH1) cells through subcellular localization, immunohistochemistry, immunofluorescence, and western blot analyses. Interaction between the Cry1Ab/c protein and the preliminarily screened endogenous plasma membrane protein Ca2+-ATPase was investigated through yeast two-hybrid, bimolecular fluorescence complementation (BIFC), and co-immunoprecipitation analyses. The potential interaction mechanism was analyzed by comparing the cellular localization and interaction sites between Cry1Ab/c and Ca2+-ATPase. Phenotypic indices and Ca2+-ATPase activity, which may be regulated by the Cry1Ab/c-Ca2+-ATPase interaction, were determined in transgenic HH1 and the parental line Minghui-63 under stress-free and salt-stress conditions. The results showed that Cry1Ab/c was not only distributed in the cytoplasm and nucleus but was also distributed on the plasma membrane, where it interacted with plasma membrane Ca2+-ATPase. This interaction partially retain plasma membrane protein Ca2+-ATPase in the nucleus by a BIFC experiment and thus may affect Ca2+-ATPase activity on the membrane by altering the cellular location of the protein. Consistently, our results confirmed that the presence of Cry1Ab/c in the transgenic HH1 resulted in a reduction in Ca2+-ATPase activity as well as causing detrimental effects on plant phenotype, including significantly reduced plant height and biomass, compared to parental MH63; and that these detrimental effects were more pronounced under salt stress conditions, impacting the salt resistance of the transgenic plants. We suggest that the Cry1Ab/c-Ca2+-ATPase interaction may explain the plasma membrane localization of Cry1Ab/c, which lacks a signal peptide and a transmembrane domain, and the adverse effects of Cry1Ab/c expression on the growth and development of transgenic HH1 plants under salt stress. This information may clarify the molecular mechanisms of these unintended effects and demonstrate the feasibility of evaluating the success and performance of genetic modification of commercially vital crops.

Project description:BACKGROUND:Megalencephalic leukoencephalopathy with subcortical cysts (MLC) is a rare form of infantile-onset leukodystrophy. The disorder is caused primarily by mutations of MLC1 that leads to a series of phenotypic outcomes including vacuolation of myelin and astrocytes, subcortical cysts, brain edema, and macrocephaly. Recent studies have indicated that functional interactions among MLC1, GlialCAM, and ClC-2 channels play key roles in the regulation of neuronal, glial and vascular homeostasis. However, the physiological role of MLC1 in cellular homeostatic communication remains poorly understood. In the present study, we investigated the cellular function of MLC1 and its effects on cell-cell interactions. METHODS:MLC1-dependent cellular morphology and motility were analyzed by using confocal and live cell imaging technique. Biochemical approaches such as immunoblotting, co-immunoprecipitation, and surface biotinylation were conducted to support data. RESULTS:We found that the altered MLC1 expression and localization led to a great alteration in cellular morphology and motility through actin remodeling. MLC1 overexpression induced filopodia formation and suppressed motility. And, MLC1 proteins expressed in patient-derived MLC1 mutants resulted in trapping in the ER although no changes in morphology or motility were observed. Interestingly knockdown of Mlc1 induced Arp3-Cortactin interaction, lamellipodia formation, and increased the membrane ruffling of the astrocytes. These data indicate that subcellular localization of expressed MLC1 at the plasma membrane is critical for changes in actin dynamics through ARP2/3 complex. Thus, our results suggest that misallocation of pathogenic mutant MLC1 may disturbs the stable cell-cell communication and the homeostatic regulation of astrocytes in patients with MLC.

Project description:The Parkinson's disease protein ?-synuclein (?Syn) promotes membrane fusion and fission by interacting with various negatively charged phospholipids. Despite postulated roles in endocytosis and exocytosis, plasma membrane (PM) interactions of ?Syn are poorly understood. Here, we show that phosphatidylinositol 4,5-bisphosphate (PIP2) and phosphatidylinositol 3,4,5-trisphosphate (PIP3), two highly acidic components of inner PM leaflets, mediate PM localization of endogenous pools of ?Syn in A2780, HeLa, SK-MEL-2, and differentiated and undifferentiated neuronal SH-SY5Y cells. We demonstrate that ?Syn binds to reconstituted PIP2 membranes in a helical conformation in vitro and that PIP2 synthesizing kinases and hydrolyzing phosphatases reversibly redistribute ?Syn in cells. We further delineate that ?Syn-PM targeting follows phosphoinositide-3 kinase (PI3K)-dependent changes of cellular PIP2 and PIP3 levels, which collectively suggests that phosphatidylinositol polyphosphates contribute to ?Syn's function(s) at the plasma membrane.

Project description:During the early stages of development, the embryo depends on the placenta as provider of oxygen and calcium, among other essential compounds. Although fetal liver accomplishes a well-known haematopoietic function, its contribution to calcium homeostasis upon development is poorly understood. The homeostasis of cell calcium contributes to diverse signaling pathways across developmental stages of most tissues and the calcium-ATPase located at the plasma membrane (PMCA) helps pumping excess calcium into the extracellular space. To date, the understanding of the equilibrium shift between PMCA isoforms during liver development is still missing. This review focuses on the characterization of the hepatic PMCA along the early stages of development, followed by a description of modern approaches to study calcium homeostasis involving several types of pluripotent cells. The application of interdisciplinary techniques to improve our understanding of liver development and the role calcium homeostasis plays in the definition of pathogenesis is also discussed.