Differences in the subcellular localization of calreticulin and organellar Ca(2+)-ATPase in neurons

Potassium-induced structural changes of the endoplasmic reticulum in pyramidal neurons in murine organotypic hippocampal slices

The endoplasmic reticulum (ER) structure is of central importance for the regulation of cellular anabolism, stress response, and signal transduction. Generally continuous, the ER can temporarily undergo dramatic structural rearrangements resulting in a fragmented appearance. In this study we assess the dynamic nature of ER fission in pyramidal neurons in organotypic hippocampal slice cultures stimulated by depolarizing concentration of potassium (50 mM). The slices were obtained from transgenic mice expressing fluorescent ER-targeted DsRed2 protein. We employed live tissue confocal microscopy imaging with fluorescence recovery after photobleaching (FRAP) to monitor the extent of structural rearrangements of the ER. In control slices, the ER structure was continuous. Potassium stimulation resulted in extensive fragmentation (fission), whereas return to basal potassium levels (2.5 mM) led to ER fusion and normalization of ER structure. This ER fission/fusion could be repeated several times in the same neuron, demonstrating the reversibility of the process. Blockade of the N-methyl-D-aspartate receptor (NMDAR) with the antagonist D-AP5 or removal of extracellular Ca(2+) prevented depolarization-induced ER fission. ER fission is sensitive to temperature, and decreasing temperature from 35°C to 30°C augments fission, implying that the altering of ER continuity may be a protective response against damage. We conclude that events that generate membrane depolarisation in brain tissue lead to the release of endogenous glutamate that may regulate neuronal ER continuity. The rapid and reversible NMDAR-mediated changes in ER structure reflect an adaptive, innate property of the ER for synaptic activation as well as response to tissue stress, injury, and disease.

Presence and functional significance of presynaptic ryanodine receptors

Ca(2+)-induced Ca(2+) release (CICR) mediated by sarcoplasmic reticulum resident ryanodine receptors (RyRs) has been well described in cardiac, skeletal and smooth muscle. In brain, RyRs are localised primarily to endoplasmic reticulum (ER) and have been demonstrated in postsynaptic entities, astrocytes and oligodendrocytes where they regulate intracellular Ca(2+) concentration ([Ca(2+)](i)), membrane potential and the activity of a variety of second messenger systems. Recently, the contribution of presynaptic RyRs and CICR to functions of central and peripheral presynaptic terminals, including neurotransmitter release, has received increased attention. However, there is no general agreement that RyRs are localised to presynaptic terminals, nor is it clear that RyRs regulate a large enough pool of intracellular Ca(2+) to be physiologically significant. Here, we review direct and indirect evidence that on balance favours the notion that ER and RyRs are found in presynaptic terminals and are physiologically significant. In so doing, it became obvious that some of the controversy originates from issues related to (i) the ability to demonstrate conclusively the physical presence of ER and RyRs, (ii) whether the biophysical properties of RyRs are such that they can contribute physiologically to regulation of presynaptic [Ca(2+)](i), (iii) how ER Ca(2+) load and feedback gain of CICR contributes to the ability to detect functionally relevant RyRs, (iv) the distance that Ca(2+) diffuses from plasma membranes to RyRs to trigger CICR and from RyRs to the Active Zone to enhance vesicle release, and (v) the experimental conditions used. The recognition that ER Ca(2+) stores are able to modulate local Ca(2+) levels and neurotransmitter release in presynaptic terminals will aid in the understanding of the cellular mechanisms controlling neuronal function.

Extracellular signal-regulated kinase, synaptic plasticity, and memory

The mitogen-activated protein kinase, extracellular signal-regulated kinase (ERK), has been studied extensively in recent years for its involvement in synaptic plasticity and memory function. Activation of ERK is coupled to stimulation of cell-surface proteins via several different upstream signaling pathways, and contributes to the regulation of diverse cellular processes, ranging from cell excitability to gene expression. We herein review evidence for ERK's role in different forms of synaptic plasticity and different types of learning paradigms, drawing on examples from different systems in molluscs as well as the mammalian brain. The picture that emerges is that ERK activation in response to conditions that give rise to synaptic and behavioral modification contributes to that modification in a multitude of functionally distinct ways. The functional diversity is likely to be achieved by the operation of multiple, parallel ERK cascades that differ with respect to the subcellular compartments in which ERK exerts its effects and the temporal windows during which the effects are manifested. We conclude that our understanding of the mechanisms by which ERK contributes to synaptic plasticity and memory has much to gain by further study of the signaling events up- and downstream of ERK activation and the spatiotemporal characteristics of ERK activation in association with activity-dependent synaptic modification and information processing.

Cholinergic stimulation enhances cytosolic calcium ion accumulation in mouse hippocampal CA1 pyramidal neurones during short action potential trains

Acetylcholine is a regulatory cofactor for numerous activity-dependent processes of central nervous system development and plasticity in which increases in cytosolic calcium ion concentration ([Ca(2+)](cyto) couple membrane excitation to cellular changes. We examined how cholinergic receptor activation affects temporal and spatial aspects of increases in [Ca(2+)](cyto) during short trains of action potentials in hippocampal CA1 pyramidal neurones. Membrane-impermeant Ca(2+)-sensitive dye was introduced into the cytosol during whole-cell recordings, and Ca(2+)-dependent fluorescence was recorded from somatic, nuclear and proximal dendrite regions with high temporal resolution. In all neuronal compartments, the cholinergic agonist carbachol (5 microM) increased resting [Ca(2+)](cyto) and the maximum [Ca(2+)](cyto) attained during a short action potential train. Carbachol also slowed the recovery of [Ca(2+)](cyto) towards resting levels. The largest increases in peak cytosolic Ca(2+) concentration (delta [Ca(2+)](cyto) were seen in the dendrite and apical cell body, while relaxations of the carbachol-induced increase in delta [Ca(2+)](cyto) showed greater prolongation in the nucleus and basal cell body. Most significantly, the difference between Ca(2+) signals recorded before and during exposure to carbachol consistently showed a monotonic rise and smooth fall in all cell compartments, suggesting that the increase in [Ca(2+)](cyto) associated with each action potential was not altered by carbachol. Consistent with this view, changes in Ca(2+) signalling were not accompanied by changes in action potential waveforms. The effects of carbachol were partially reversed by simultaneous exposure to atropine, or partially inhibited by inclusion of heparin in the intracellular solution, indicating the involvement of muscarinic acetylcholine receptors and InsP(3)-sensitive Ca(2+)-release channels. Our data indicate that carbachol-induced slowing of [Ca(2+)]cyto relaxations after each action potential results in enhanced accumulation of Ca(2+) in the cytosol in the absence of changes in action potential-driven Ca(2+) entry. By modulating the time course of Ca(2+) signals, cholinergic stimulation may regulate the activation of Ca(2+)-dependent intracellular processes dependent on patterns of [Ca(2+)](cyto) changes.

Targeting of endoplasmic reticulum-associated proteins to axons and dendrites in rotavirus-infected neurons

To analyze sorting and compartmentalization of molecules in neuronal endomembranes, the distribution of endogenous proteins associated with the endoplasmic reticulum (ER), intermediate compartment, the Golgi apparatus in cultures of dorsal root ganglion (DRG), and hippocampal neurons was compared with that of newly synthesized ER-associated rotavirus proteins. The endogenous ER-retained immunoglobulin heavy chain binding protein, protein disulfide isomerase, and a peptide containing the KDEL amino acid sequence appeared in the soma and dendrites up to their first branching, but not in axons. However, two other endogenous ER-associated proteins, calreticulin and calnexin, occurred in axons as well as in the somatodendritic domains. The ER-associated rotavirus proteins, VP7 and NSP4, were widely distributed in cell bodies and dendrites. The former appeared also in axons and its localization partially overlapped with that of calreticulin and calnexin. One intermediate compartment protein, ER-Golgi-intermediate compartment-protein-53 (ERGIC-53), extended beyond the first division of the dendrites and did not, as the small guanosine 5'-triphosphate (GTP)-binding protein rab2, appear in axons. The location of rab2 to small vesicles was distinct from that of rotavirus VP7. Cis/medial Golgi cistern proteins were restricted to the cell bodies and proximal dendrites. This study emphasizes the marked heterogeneity in the targeting to axons and dendrites of proteins associated with ER and intermediate compartments. Therefore, the composition of axonal ER-retained molecules differs from that in the soma and this variation may reflect differences in functions between the ER compartments. Viral proteins are useful reporters for such heterogeneities and rotavirus VP7 may be a tool to reveal sorting signals for targeting of vesicular proteins to axons via a nonclassical Golgi-independent mechanism. Such signals may also determine viral targeting to different regions of the brain.

Increased calreticulin stability in differentiated NG-108-15 cells correlates with resistance to apoptosis induced by antisense treatment

Since its first identification as a high-affinity calcium-binding protein over two decades ago [T.J. Ostwald and D.H. MacLennan, Isolation of a high-affinity calcium-binding protein from sarcoplasmic reticulum, J. Biol. Chem., 249 (1974) 974-979], calreticulin has become recognized as a multifunctional protein involved in a wide variety of cellular processes. We have previously shown that it has a protective function in Ca2+-mediated cell death [N. Liu, R.E. Fine, E. Simons and R.J. Johnson, Decreasing calreticulin expression lowers the Ca2+ response to bradykinin and increases sensitivity to ionomycin in NG-108-15 cells, J. Biol. Chem. , 269 (1994) 28635-28639]. We report here that in NG-108-15 neuroblastomaxglioma hybrid cells, calreticulin protein levels increase markedly when these cells are induced to differentiate by treating them with N,N-dibutyryl cAMP (db-cAMP). We demonstrate that the reason for this increase is mostly due to a large increase in the turnover time of calreticulin in differentiated cells. We also show that a calreticulin antisense oligonucleotide, CrtAS1, previously described by Liu and co-workers [N. Liu, R.E. Fine, E. Simons and R.J. Johnson, Decreasing calreticulin expression lowers the Ca2+ response to bradykinin and increases sensitivity to ionomycin in NG-108-15 cells, J. Biol. Chem., 269 (1994) 28635-28639] causes cell death in undifferentiated NG-108-15 cells when antisense treatment is extended for more than 24 h. This effect is not seen in NG-108-15 cells that have been induced to differentiate with db-cAMP until the cells have been treated with antisense for more than 4 days, due to the increased stability of Crt in these cells. Our results indicate that the mechanism by which these cells die is likely to be apoptosis.

Ca(2+)-ATPase pump forms and an endogenous inhibitor in bovine brain synaptosomes

Two forms of Ca(2+)-pump were identified in bovine brain synaptic membranes as aspartylphosphate intermediates and were characterized. The 140 kDa and 97 kDa phosphoproteins were digested by calpain, producing two phosphorylated fragments, of M.W. 124 and 80 kDa respectively, not inhibited by thapsigargin, and displayed a trypsin digestion pattern with the formation of one phosphorylatable fragment of about 80 kDa. These results suggest that both pumps belong to the Plasma Membrane-type of Ca2+ ATPases, differing from the Sarco- or Endoplasmic Reticulum kind. A plasma membrane Ca(2+)-ATPase proteinaceous inhibitor with molecular weight between 6,000 and 10,000 Da was resolved from synaptic terminal cytosol, where it is enriched by fourfold with respect to frontal cortex brain cytosol. Such enrichment is already evident in the correspondent crude fractions. The presence of calcium pump and its proteinaceous inhibitor inside the synaptic terminals from bovine brain is discussed in terms of free calcium level regulation in neuron synaptoplasm.

Immunolocalization of the plasma membrane Ca2+ pump isoforms in the rat brain

Ca2+ homeostasis in nerve cells is dependent on at least three mechanisms: Ca2+ channels, calcium-binding proteins and Ca2+ exchangers/pumps. Only limited information is available on the regional/cellular distribution of these Ca2+-regulating systems in the brain. The distribution of three of the isoforms of one of the systems, plasma membrane Ca2+-ATPase (PMCA), was analyzed in this study. Using antibodies against epitopes specific for each isoform, a map of the distribution of the pump in the whole brain was produced. The pump was mainly expressed in neurons and was apparently absent from glia cells. Isoform 1 was ubiquitous and occurred in varying, but always significant, concentrations in almost all nerve cells. Isoform 2 was abundant in cerebellar Purkinje cells but less concentrated in other brain regions. Isoform 3 had a predominantly extra neuronal location, e.g. it was abundant in the choroid plexuses. The three isoforms were found to be distributed in a highly characteristic manner, suggesting that nerve cells have different requirements for the preservation of their intracellular calcium homeostasis.

Calreticulin expression in spinal motoneurons of the rat

We have examined the expression of calreticulin in rat spinal motoneurons in order to reveal the occurrence and distribution of Ca2(+)-storage organelles in these neurons. Calreticulin, the non-muscle equivalent of calsequestrin, is the low-affinity, high-capacity calcium-binding protein responsible for intracompartmental Ca2(+)-storage in a number of different cell types. The results of the present immunohistochemical study show that all spinal motoneurons express calreticulin at approximately the same level; no significant differences in cytoplasmic immunostaining intensity were observed between different motoneuron pools or between small and large spinal motoneurons. Immunoelectron microscopy revealed that the intracellular localization of calreticulin within spinal motoneurons was confined to the endoplasmic reticulum and to spherical or pleiomorphic, frequently 'coated' vesicles with a diameter ranging between 120 and 150 nm. Some of these vesicles may represent the so-called calciosomes, the intracellular Ca2(+)-storage vesicles described in liver cells and in cerebellar Purkinje cells. The molecular components responsible for the uptake and release of Ca2+ from the Ca2(+)-storage organelles in spinal motoneurons still remain to be identified.