Adrenoceptors and signal transduction in neurons

The adrenergic system is an essential regulator of neuronal, endocrine, cardiovascular, vegetative, and metabolic functions. The endogenous catecholamines epinephrine and norepinephrine activate G-protein-coupled receptors to transmit their signal across the plasma membrane. These adrenoceptors can be divided into three different groups: the α₁-receptors (α_1A, α_1B, α_1D), α₂-receptors (α_2A, α_2B, α_2C), and β-receptors (β₁, β₂, β₃). This review summarizes recent findings in the field of adrenoceptor signaling in neurons and includes a discussion of receptor-associated proteins, receptor dimerization, subcellular trafficking, and fluorescence optical methods for studying the kinetics of adrenergic signaling. Spatio-temporal imaging may become an important future tool for identifying the physiological significance of these complex signaling mechanisms in vivo. Gene-targeted mouse models carrying deletions in α₂-adrenoceptor have provided detailed insights into specific neuronal functions of the three α₂-receptor subtypes.     

Two distinct, calcium-mediated, signal transduction pathways can trigger deflagellation in Chlamydomonas reinhardtii

The molecular machinery of deflagellation can be activated in detergent permeabilized Chlamydomonas reinhardtii by the addition of Ca2+ (Sanders, M. A., and J. L. Salisbury, 1989. J. Cell Biol. 108:1751- 1760). This suggests that stimuli which induce deflagellation in living cells cause an increase in the intracellular concentration of Ca2+, but this has never been demonstrated. In this paper we report that the wasp venom peptide, mastoparan, and the permeant organic acid, benzoate, activate two different signalling pathways to trigger deflagellation. We have characterized each pathway with respect to: (a) the requirement for extracellular Ca2+; (b) sensitivity to Ca2+ channel blockers; and (c) 45Ca influx. We also report that a new mutant strain of C. reinhardtii, adf-1, is specifically defective in the acid-activated signalling pathway. Both signalling pathways appear normal in another mutant, fa-1, that is defective in the machinery of deflagellation (Lewin, R. and C. Burrascano. 1983. Experientia. 39:1397-1398; Sanders, M. A., and J. L. Salisbury. 1989. J. Cell Biol. 108:1751-1760). We conclude that mastoparan induces the release of an intracellular pool of Ca2+ whereas acid induces an influx of extracellular Ca2+ to activate the machinery of deflagellation.     

Resonant activation of calcium signal transduction in neurons

The relevant parameters of calcium fluxes mediating activation of immediate-early genes and the collapse of growth cones in mouse DRG neurons in response to action potentials delivered in different temporal patterns were measured in a multicompartment cell culture preparation using digital flourescence videomicroscopy. Growth cone collapse was produced by trains of action potentials causing a large rise in [Ca²⁺]_i, but after chronic exposure to patterned stimulation growth cones regenerated and became insensitive to the stimulus-induced increase in [Ca²⁺]_i. Calcium reached similar peak concentrations, but the [Ca²⁺]_i increased more slowly than in naive growth cones (time constant of 6.0 s versus 1.4 s in naive growth cones). Semiquantitative PCR measurements of gene expression showed that pulsed stimulation delivered at 1-min intervals for 30 min induced expression of c-fos, but the same total number of action potentials delivered at 2-min intervals failed to induce c-fos expression, even though this stimulus induces a larger peak [Ca²⁺]_i than the effective stimulus pattern. The experiments suggest that the kinetics of calcium fluxes produced by different patterns of stimulation, and changes in the kinetics of calcium flux in neurons under different states of activation, are critical in determining the effects of action potentials on growth cone motility or expression of IE genes during development of neuronal circuits. We propose that differences in kinetics of individual reactions in the stimulus–response pathway may lead to resonance of activation in the neuron, such that certain processes will be selectively activated by particular temporal patterns of stimulation. 1994 John Wiley & Sons, Inc.     

Alterations of microRNAs expression profiles in small extracellular vesicle after traumatic brain injury in mice

Traumatic brain injury (TBI) is one of the leading causes of mortality and morbidity worldwide. Tools available for diagnosis and therapy are limited. Small extracellular vesicle (sEV) microRNAs (miRNAs) play an important role in TBI disease progression. This study aimed to investigate the alterations in sEV miRNAs expression in the mouse brain extracellular space after TBI. Twenty-four C57BL/6J mice were randomly divided into two groups (12/group). The TBI group was subjected to all surgical procedures and fluid percussion injury (FPI). The sham group only underwent surgery. Brain specimens were collected 3 h after TBI/sham. The brain sEV were isolated. Differentially expressed miRNAs were identified. A total of 50 miRNAs were observed to be differentially expressed (fold change ≥1.5 and P<0.05) after TBI, including 5 upregulated and 45 downregulated. The major enriched Gene Ontology terms were metabolic processes, cell, intracellular, organelle, cytoplasm, axon, binding, protein kinase activity, protein binding, and protein dimerization activity. The KEGG pathway analysis predicted that the pathways affected by the variation of miRNAs in sEVs after TBI included the Wnt signaling pathway and NF-κB signaling pathway. The changes in five miRNAs were confirmed by qRT-PCR. In conclusion, this study demonstrated the differential expression of a series of miRNAs in brain sEV after TBI, which might be correlated with post-TBI physiological and pathological processes. The findings might also provide novel targets for further investigating the molecular mechanisms underlying TBI and potential therapeutic interventions.     

Alterations in myocardial signal transduction due to aging and chronic dynamic exercise

Roth, David A., Cynthia D. White, Deborah A. Podolin, andRobert S. Mazzeo. Alterations in myocardial signal transduction due to aging and chronic dynamic exercise. J. Appl. Physiol.84(1): 177-184, 1998.Normal aging without disease leads todiminished chronotropic and inotropic responses to catecholaminestimulation, resulting in depressed cardiac function with stress. Thepurpose of this study was to determine molecular mechanisms fordecrements in adrenergic responsiveness of the left ventricle (LV) dueto aging and to study the effects of chronic dynamic exercise on signaltransduction. We measured -adrenergic receptor (-AR) density,adenylyl cyclase (AC) activity, and G-protein content and distributionin LV from 66 male Fischer 344 rats from three age groups that wereeither sedentary or treadmill trained (60 min/day, 5 days/wk, 10 wk at75% of the maximal capacity). Final ages were 7 mo(young), 15 mo (middle-age), and 25 mo (old). There was no significantdifference in -AR density among groups as a function of age ortraining. AC production of adenosine 3,5-cyclic monophosphate (cAMP)with the use of five pharmacological stimulations revealed that oldsedentary myocardium had depressed basal, receptor-dependent, G-protein-dependent, and AC catalyst stimulation (30-43%)compared with hearts from young and middle-age sedentary rats. Training did not alter AC activity in either middle-age or old groups but didincrease G-protein-dependent cAMP production in young myocardium (12-34%). Immunodetectable concentrations of stimulatory andinhibitory G proteins (G_s and G_i, respectively)showed 43% less total G_s with similar G_icontent in hearts from old sedentary compared with middle-age sedentaryrats. When compared with young sedentary animals, G_icontent was 39 and 50% higher in middle-age sedentary and oldsedentary myocardium, respectively. With age, there was a significantshift in the -subunit of G_s distribution from cytosolic fractions of LV homogenates to membrane-bound fractions (8-12% redistribution in middle-age sedentary vs. old sedentary). The mostsignificant training effect was a decrease in G_i content inhearts from old trained rats (23%), which resulted in values comparable with young sedentary rats and reduced theG_i/G_s ratio by 27% in old-rat LV. We reportthat age-associated reductions in cardiovascular -adrenergicresponsiveness correspond with alterations in postreceptor adrenergicsignaling rather than with a decrease in receptor number. Chronicdynamic exercise partially attenuates these reductions throughalterations in postreceptor elements of cardiac signal transduction.

     

Temporal patterns of cortical proliferation of glial cell populations after traumatic brain injury in mice

TBI (traumatic brain injury) triggers an inflammatory cascade, gliosis and cell proliferation following cell death in the pericontusional area and surrounding the site of injury. In order to better understand the proliferative response following CCI (controlled cortical impact) injury, we systematically analyzed the phenotype of dividing cells at several time points post-lesion. C57BL/6 mice were subjected to mild to moderate CCI over the left sensory motor cortex. At different time points following injury, mice were injected with BrdU (bromodeoxyuridine) four times at 3-h intervals and then killed. The greatest number of proliferating cells in the pericontusional region was detected at 3 dpi (days post-injury). At 1 dpi, NG2⁺ cells were the most proliferative population, and at 3 and 7 dpi the Iba-1⁺ microglial cells were proliferating more. A smaller, but significant number of GFAP⁺ (glial fibrillary acidic protein) astrocytes proliferated at all three time points. Interestingly, at 3 dpi we found a small number of proliferating neuroblasts [DCX⁺ (doublecortin)] in the injured cortex. To determine the cell fate of proliferative cells, mice were injected four times with BrdU at 3 dpi and killed at 28 dpi. Approximately 70% of proliferative cells observed at 28 dpi were GFAP⁺ astrocytes. In conclusion, our data suggest that the specific glial cell types respond differentially to injury, suggesting that each cell type responds to a specific pattern of growth factor stimulation at each time point after injury.     

Apoptosis-inducing and -preventing signal transduction pathways in cultured cerebellar granule neurons

1. Cultured cerebellar granule neurons maintained in medium containing 26 mM potassium (high K+ or HK+) undergo cell death when switched to medium with 5 mM potassium (low K+ or LK+). This low K(+)-induced cell death has typical features of apoptosis. The intracellular signaling pathway of low K(+)-induced apoptosis has been investigated. 2. Cerebellar granule neurons become committed to undergo apoptosis between 2 and 5 h after K+ deprivation, judging from the inability of high K+ to rescue them after this time. Although the levels of most mRNAs decrease markedly concomitant with commitment, expression of c-jun mRNA increases 2-3 h after K+ deprivation. Among the family of caspases, a caspase-3-like protease is activated within 4 h of lowering the K+ concentration. A caspase-1-like protease is also activated within 2 h of K+ deprivation. 3. Inhibition of phosphatidylinositol 3-kinase (PI3-K) activity by LY294002 or wortmannin also induces apoptosis in cerebellar granule neurons. The intracellular signaling pathway of LY294002-induced apoptosis has been investigated. The activity of c-Jun N-terminal kinase (JNK) increases 8 h after addition of LY294002 to high K+ medium or low K+ medium containing BDNF. Expression of c-Jun protein also increases almost simultaneously. 4. The low K(+)-induced apoptosis of cerebellar granule neurons is prevented by high K+ (membrane depolarization by high K+), BDNF, IGF-1, bFGF or cAMP. The intracellular signaling pathways by which these agents prevent low K(+)-induced apoptosis have been investigated. Agents other than cAMP prevent apoptosis through PI3-K and a Ser/Thr kinase, Akt/PKB. The survival-promoting effect of cAMP does not depend on the PI3-K-Akt pathway.     

Alterations of phosphatidylinositol signal transduction pathway in hepatic mitochondria following aflatoxin B1 administration

A single dose of aflatoxin B1 (7 mg/kg body wt) to male rats significantly stimulated the turnover of mitochondrial phosphoinositides 1-7 hr following its administration. The elevation of phosphatidylinositol 3,4,5-trisphosphate was most pronounced whose level continued to be moderately high even at 17 hr period. The level of diacylglycerol showed a marked increase from 4 hr till 7 hr after carcinogen treatment, whereas that of inositol 1,4,5-trisphosphate recorded an increase with a maximum at 7 hr followed by a gradual decrease to near normal level at 24 hr period. The activation of phosphatidylinositol cycle together with an activation of PI 3-kinase, whose product PIP3 is known to be involved in apoptosis might contribute to the early step in the manifestation of toxicity and/or carcinogenicity.     

Cholesterol in signal transduction

Membrane cholesterol impinges on signal transduction in several ways, which is highlighted in particular by the Hedgehog signaling pathway. In Hedgehog signaling, cholesterol is important for ligand biogenesis, as well as for signal transduction in receiving cells. Hedgehog ligands are post-translationally modified by cholesterol, and the Hedgehog receptor, Patched, is structurally similar to the Niemann-Pick C1 protein, which functions in intracellular lipid transport. Although the exact role of cholesterol in Hedgehog signal transduction remains elusive and is probably multifaceted, studies over the past year have implicated raft membrane subdomains, cholesterol transport and a link between protein and lipid trafficking in endocytic compartments.     

Mechanism of opioid and substance P-mediated modulation of cortical signal transduction through the striatum

A mechanism of opioid and substance P-mediated modulation of a cortical signal transduction through the striatum is suggested. According to this mechanism, an activation of postsynaptic receptors, bound to Gi/0 proteins, should increase the magnitude of NMDA-dependent (NMDA-independent) LTD (LTP) of excitatory inputs and LTP (LTD) of inhibitory inputs to all types of striatal cells. An activation of postsynaptic receptors, bound to Gs or Gq/11 proteins, should oppositely modulate LTD and LTD in the same inputs. It follows from the model that the negative feedback loops can held the activity of a striatal output cells at the stable level due to recurrent activation by endogenous opioids of delta receptors on striatopallidal cells, mu and kappa receptors on striatonigral cells of striosomes and matrix, respectively, and subsequent suppression of the efficacy of corticostriatal inputs. Cholinergic interneurons, affected by enkephalin and substance P, are also involved in these feedback loops. We hypothesized that an activation of mu and delta receptors and/or inactivation of kappa receptors on striatal spiny cells might alleviate parkinsonian symptoms and recover locomotor activity.     

同型半胱氨酸对心肌细胞的损伤作用及其信号转导机制探讨

目的：观察同型半胱氨酸（homocysteine,HCY)对心肌细胞的损伤作用,探讨该作用发生的信号转导机制及其关键调控环节。方法：分离培养Wistar乳鼠心肌细胞,经HCY作用后,以台盼蓝排斥实验测定细胞存活率,TUNEL法和流式细胞仪测定细胞凋亡率,免疫印迹法测定心肌细胞ERK2蛋白磷酸化水平,阻滞电泳法测定细胞NF－κB活化水平。结果：作用后,心肌细胞存活率显著降低,存活率降低程度与HCY的作用浓度、作用时间具有明确的剂量－效应关系及时间－效应关系;在10^-3mol/L HCY作用下,心肌细胞凋亡率升高,于4h达峰值,为7．56％;10^-3,10^-4、10^-5mol/L HCY均可抑制心肌细胞ERK2磷酸化,其中10^-3mol/L HCY作用于心肌细胞后,ERYK2蛋白磷酸化水平呈现迅速而明显的降低,4h降至对照组的3．04％（P＜0．01）;不同浓度HCY均明显阻抑NF－κB的活化。结论：HCY具有明显心肌细胞损伤作用,对心肌细胞凋亡的诱导是HCY心肌细胞损伤作用的形式之一;HCY可影响心肌细胞信号转导通路ERK,通过对转录因子NF－κB的活化抑制,导致心肌细胞损伤。     

Phosphotyrosine-binding domains in signal transduction

Protein phosphorylation provides molecular control of complex physiological events within cells. In many cases, phosphorylation on specific amino acids directly controls the assembly of multi-protein complexes by recruiting phospho-specific binding modules. Here, the function, structure, and cell biology of phosphotyrosine-binding domains is discussed.     

Drought signal transduction in plants

Water deficit is one of the most common environmental limitations of crop productivity by affecting growth through alterations in metabolism and gene expression. The mechanisms involved in drought perception and signal transduction pathways are poorly understood. The participation of the plant hormone abscisic acid (ABA) has been well established. ABA levels increase when there are changes in the environment that result in cellular dehydration. Different approaches have been taken to understanding the molecular responses to desiccation and how ABA regulates gene expression. Recent efforts have identified particular topics of importance in the dissection of the signal transduction pathway which are summarized as follows: physiological approaches: identification of signalling molecules. Genetic approaches: the use of mutants, and Molecular approaches: promoter analysis.     

Modelling organelle transport after traumatic axonal injury

This paper is motivated by recent experimental research (Tang-Schomer et al. 2012) on the formation of periodic varicosities in axons after traumatic brain injury (TBI). TBI leads to the formation of undulated distortions in the axons due to their dynamic deformation. These distortions result in the breakage of some microtubules (MTs) near the peaks of undulations. The breakage is followed by catastrophic MT depolymerisation around the broken ends. Although after relaxation axons regain their straight geometry, the structure of the axon after TBI is characterised by the presence of periodic regions where the density of MTs has been decreased due to depolymerisation. We modelled organelle transport in an axon segment with such a damaged MT structure and investigated how this structure affects the distributions of organelle concentrations and fluxes. The modelling results suggest that organelles accumulate at the boundaries of the region where the density of MTs has been decreased by depolymerisation. According to the model, the presence of such damaged regions decreases the organelle flux by only about 12%. This provides evidence that axon degradation after TBI may be caused by organelle accumulation rather than by starvation due to insufficient organelle flux.