In many regions of the cerebral cortex, Ca2+ influx through NMDA (N-methyl-D-aspartate) sensitive glutamate receptors (NMDA receptors) can trigger two forms of synaptic plasticity: long-term depression (LTD) and long-term potentiation (LTP). LTD is induced by low levels of postsynaptic NMDA-receptor activation, for instance in response to low-frequency stimulation, whereas LTP is induced by the stronger activation that occurs following high-frequency stimulation. Theoretical studies have shown that the properties of synaptic LTD and LTP can account for many aspects of experience-dependent plasticity in the developing visual cortex, provided that the LTD-LTP crossover point (the modification threshold, theta(m)) varies as a function of the history of cortical activity. Here we provide direct experimental evidence that the value of theta(m) depends on sensory experience. We find in visual cortex of light-deprived rats that LTP is enhanced and LTD diminished over a range of stimulation frequencies, and that these effects can be reversed by as little as two days of light exposure. Our findings support the idea that a variable synaptic modification threshold allows synaptic weights in neural networks to achieve a stable equilibrium.
Abstract. Lysosomes are recruited to the invasion site during host cell entry by Trypanosoma cruzi, an unusual process suggestive of the triggering of signal transduction mechanisms. Previous studies showed that trypomastigotes, but not the noninfective epimastigotes, contain a proteolytically generated trypomastigote factor (PGTF) that induces intracellular free Ca 2+ transients in several mammalian cell types. Using confocal time-lapse imaging of normal rat kidney (NRK) fibroblasts loaded with the Ca2÷-sensitive dye fluo-3, we show that the initial intracellular free Ca 2÷ concentration ([Ca2+]i) transient detected a few seconds after exposure to trypomastigote extracts is a result of Ca 2÷ release from intracellular stores. Removal of Ca 2+ from the extracellular medium or inhibition of Ca 2÷ channels with NiC12 did not affect the response to PGTF, while depletion of intracellular stores with thapsigargin abolished it.[Ca2+]i transients induced by PGTF were shown to be coupled to the activity of phospholipase C (PLC), since the specific inhibitor U73122 completely blocked the response, while its inactive analogue U73343 had no effect. In addition, polyphosphoinositide hydrolysis and inositol 1,4,5-trisphosphate (IP3) were detected upon cell stimulation with PGTF, suggesting the participation of IP3-sensitive intracellular Ca 2÷ channels.An immediate effect of the signaling induced by PGTF and live trypomastigotes was a rapid and transient reorganization of host cell microfilaments. The redistribution of F-actin appeared to be a direct consequence of increased [Ca2+]i, since thrombin and the Ca 2÷ ionophore ionomycin produced a similar effect, with a time course that corresponded to the kinetics of the elevation in [Ca2+]i . These observations support the hypothesis that PGTF-induced disassembly of the cortical actin cytoskeleton may play a role in T. cruzi invasion, by facilitating lysosome access to the invasion site. Taken together, our findings suggest that the proteolytically generated trypomastigote factor PGTF is a novel agonist that acts through the PLC/phosphoinositide signaling pathway of mammalian cells.
Abstract. Invasion of mammalian cells by the protozoan parasite Trypanosoma cruzi occurs by an actinindependent mechanism distinct from phagocytosis. Clusters of host lysosomes are observed at the site of parasite attachment, and lysosomal markers are detected in the vacuolar membrane at early stages of the entry process. These observations led to the hypothesis that the trypanosomes recruit host lysosomes to their attachment site, and that lysosomal fusion serves as a source of membrane to form the parasitophorous vacuole.Here we directly demonstrate directional migration of lysosomes to the parasite entry site, using time-lapse video-enhanced microscopy of L6E 9 myoblasts exposed to T. cruzi trypomastigotes. BSA-gold-loaded lysosomes moved towards the cell periphery, in the direction of the parasite attachment site, but only when their original position was less than 11-12 Ixm from the invasion site. Lysosomes more distant from the invasion area exhibited only the short multi-directional saltatory movements previously described for lysosomes, regardless of their proximity to the cell margins.Specific depletion of peripheral lysosomes was obtained by microinjection of NRK cells with antibodies against the cytoplasmic domain of lgp 120, a treatment that aggregated lysosomes in the perinuclear area and inhibited T. cruzi entry. The microtubule-binding drugs nocodazole, colchicine, vinblastine, and taxol also inhibited invasion, in both NRK and LrE 9 cells. Furthermore, microinjection of antibodies to the heavy chain of kinesin blocked the acidification-induced, microtubule-dependent redistribution of lysosomes to the host cell periphery, and reduced trypomastigote entry.Our results therefore demonstrate that during T. cruzi invasion of host cells lysosomes are mobilized from the immediately surrounding area, and that availability of lysosomes at the cell periphery and microtubule/kinesin-mediated transport are requirements for parasite entry.
Astrocytes respond to the excitatory neurotransmitter glutamate with dynamic spatio-temporal changes in intracellular calcium [Ca2+]i. Although they share a common wave-like appearance, the different [Ca2+]i changes--an initial spike, sustained elevation, oscillatory intracellular waves, and regenerative intercellular waves--are actually separate and distinct phenomena. These separate components of the astrocytic Ca2+ response appear to be generated by two different signal transduction pathways. The metabotropic response evokes an initial spatial Ca2+ spike that can propagate rapidly from cell to cell and appears to involve IP3. The metabotropic response can also produce oscillatory intracellular waves of various amplitudes and frequencies that propagate within cells and are sustained only in the presence of external Ca2+. The ionotropic response, however, evokes a sustained elevation in [Ca2+]i associated with receptor-mediated Na+ and Ca2+ influx, depolarization, and voltage-dependent Ca2+ influx. In addition, the ionotropic response can lead to regenerative intercellular waves that propagate smoothly and nondecrementally from cell to cell, possibly involving Na+/Ca2+ exchange. All these astrocytic [Ca2+]i changes tend to appear wave-like, traveling from region to region as a transient rise in [Ca2+]i. Nevertheless, as our understanding of the cellular events that underlie these [Ca2+]i changes grows, it becomes increasingly clear that glutamate-induced Ca2+ signaling is a composite of separate and distinct phenomena, which may be distinguished not based on appearance alone, but rather on their underlying mechanisms.
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