Role of AKAP5 in postsynaptic signaling complexes

Zhang, Mingxu

01 July 2010

Noradrenergic signaling has important functions in the central nervous system (CNS) with respect to emotion, learning and memory. Activation of β- adrenergic receptors (β ARs) stimulates protein kinase A via Gs-protein, adenylyl cyclase, and cAMP. Synaptic β←2 -adrenergic receptors, targets of the neurotransmitter norephinephrin, are associated with the GluA1 subunit of AMPA-type glutamate receptors, which mediate most excitatory synaptic transmission in mammalian CNS. PKA-mediated phosphorylation of GluA1 on Ser845 is important for GluA1 surface expression, activity induced postsynaptic accumulation, and synaptic plasticity. Postsynaptic localization of PKA is mediated by a major scaffolding protein `A kinase anchor protein 5 (AKAP5)'. AKAP5 associates with AMPA receptors via SAP97 and PSD95. We have two strains of AKAP5 mutant mice: AKAP5 knockout and AKAP5 D36. AKAP5 KO mice have a complete loss of AKAP5 gene expression. D36 mice miss the last 36 residues (PKA binding site) of AKAP5 but without affecting other interactions. These mutant mice provide us with appropriate in vivo models for studying the functional roles of AKAP5. We compared the functional and physical association of β2AR and AMPA receptors among wild type, AKAP5 KO, and AKAP5 D36 mice. Although AKAP5 was not necessary for the assembly of the β2AR / GluA1 complex, we found that AKAP5 anchored PKA activity was required for full β2AR stimulation-induced GluA1 Ser845 phosphorylation. Recording and analysis of field EPSPs (fEPSPs) of CA1 pyramidal neurons with brief bath perfusion of the β2AR agonist isoproterenol indicated a role of AKAP5 anchored PKA in the regulation of postsynaptic AMPAR responses by norephinephrin. Moreover, we observed a delayed extinction of contextual fear memory in AKAP5 D36 mice, which suggests the involvement of AKAP5 anchored PKA in memory formation and modification.

AKAP5

AMPA receptors

beta2 adrenergic receptors

synaptic functions

Pharmacology

Adrenergic signaling in insulin-sensitive tissues

Yamamoto, Daniel L.

January 2007

<p>Glucose metabolism in insulin-sensitive tissues such as skeletal muscle and adipose tissue is tightly regulated by external stimuli. Metabolic changes in these tissues have direct effects on whole body metabolism. Such metabolic changes can be induced or influenced by adrenergic stimulation.</p><p>In L6 skeletal muscle cells, we have seen that the β2-adrenergic receptor increases glycogen synthesis to the same extent as insulin. The β2-adrenergically mediated effect is independent of cyclic AMP but dependent on PI3K.</p><p>In brown adipocytes, our data suggest that signaling from the β-adrenergic receptors consists of an acute cyclic AMP effect that is rapidly desensitized and then a prolonged signal involving PI3K.</p><p>In skeletal muscle cells in culture, we have shown that DPI (a NADPH oxidase inhibitor) increases glucose uptake through a signaling pathway independent of NADPH oxidase and insulin signaling. DPI instead inhibits complex 1 in the mitochondrial respiratory chain, which lowers ATP levels. This activates AMPK, an activator of glucose uptake.</p><p>Furthermore, we have developed a model system for ordered fusion of skeletal muscle cells in culture. In this system, differentiating skeletal muscle cells can be studied separately. This system is optimal for microscopy techniques and easily adaptable for micromanipulations. We have seen that the myogenic factor MyoD can have different expression of the protein in different nuclei within the same myotube. This system could be used with advantage for intracellular signaling and metabolic studies.</p>

Metabolism

Adrenergic

Glucose

Signaling

Skeletal muscle

Animal physiology

Zoofysiologi

The effects of prenatal hypoxia on the levels of the α-subunits of G proteins in the heart of the Broiler chicken (<em>Gallus gallus</em>)

Rashdan, Nabil

January 2010

<p>Environmental stress during embryonic development could lead to growth restriction of the embryo, and act as a risk factor for the development of cardiovascular disease in adult life. A common environmental stressor that causes growth restriction is prenatal hypoxia, which has been shown to adversely affect adult health in mammalian models. Prenatal hypoxia causes an increase in catecholamines which results in over stimulation of the cardiac β-adrenergic receptors. Previous work on chickens has shown that prenatal hypoxia causes an increase in the sensitivity of β-adrenergic receptors to epinephrine in the embryonic heart. The sensitivity of these receptors was found to be decreased in prenatal hypoxic juvenile. Prenatal hypoxia has no significant effect on the density of these receptors in neither the embryo nor the juvenile. The lack of change in receptor density implies that the effects of hypoxia are further down stream in the signalling cascade. The β2 adrenergic receptor can couple to both the stimulatory Gα subunit (Gsα) and the inhibitory Gα subunit (Giα). We hypothesized that prenatal hypoxia would cause an increase in the Gsα in the sensitized embryos, while increasing Giα in the desensitized juveniles. This study evaluated the relative levels of Gsα and Giα in the hypoxic chicken embryo, and in the prenatally hypoxic juvenile, Using western blotting. Hypoxia considerably increased Giα in the chicken embryo while having no effect on Gsα. In the prenatally hypoxic juvenile Gsα was significantly increased while no changes were found in Giα. This dissociation between the levels of Gα subunit and receptor sensitivity implies that that hypoxia affects the signaling cascade downstream of the Gα subunit.</p>

Beta adrenergic receptors

fetal programming

Gα protein

Hypoxia.

Possible association between genetic polymorphisms of the adrenergic receptor genes and obesity and hypertension in South African female volunteers / Isabella Elizabeth van Lill

Van Lill, Isabella Elizabeth

January 2006

Thesis (M.Sc. (Biochemistry))--North-West University, Potchefstroom Campus, 2007.

Adrenergic receptor genes

Polymorphism -

The metabolic syndrome

Obesity

Hypertension

South Africa

Adrenergic signaling in insulin-sensitive tissues

Yamamoto, Daniel L.

January 2007

Glucose metabolism in insulin-sensitive tissues such as skeletal muscle and adipose tissue is tightly regulated by external stimuli. Metabolic changes in these tissues have direct effects on whole body metabolism. Such metabolic changes can be induced or influenced by adrenergic stimulation. In L6 skeletal muscle cells, we have seen that the β2-adrenergic receptor increases glycogen synthesis to the same extent as insulin. The β2-adrenergically mediated effect is independent of cyclic AMP but dependent on PI3K. In brown adipocytes, our data suggest that signaling from the β-adrenergic receptors consists of an acute cyclic AMP effect that is rapidly desensitized and then a prolonged signal involving PI3K. In skeletal muscle cells in culture, we have shown that DPI (a NADPH oxidase inhibitor) increases glucose uptake through a signaling pathway independent of NADPH oxidase and insulin signaling. DPI instead inhibits complex 1 in the mitochondrial respiratory chain, which lowers ATP levels. This activates AMPK, an activator of glucose uptake. Furthermore, we have developed a model system for ordered fusion of skeletal muscle cells in culture. In this system, differentiating skeletal muscle cells can be studied separately. This system is optimal for microscopy techniques and easily adaptable for micromanipulations. We have seen that the myogenic factor MyoD can have different expression of the protein in different nuclei within the same myotube. This system could be used with advantage for intracellular signaling and metabolic studies.

Metabolism

Adrenergic

Glucose

Signaling

Skeletal muscle

Animal physiology

Zoofysiologi

Autonomic Control of Cardiac Function

Steele, Shelby L

08 February 2011

Cardiac parasympathetic tone mediates hypoxic bradycardia in fish, however the specific cholinergic mechanisms underlying this response have not been established. In Chapter 2, bradycardia in zebrafish (Danio rerio) larvae experiencing translational knockdown of the M2 muscarinic receptor was either prevented or limited at two different levels of hypoxia (PO2 = 30 or 40 Torr). Also, M2 receptor deficient fish exposed to exogenous procaterol (a presumed β2-adrenergic receptor agonist) had lower heart rates than similarly treated control fish, implying that the β2-adrenergic receptor may have a cardioinhibitory role in this species. Zebrafish have a single β1-adrenergic receptor (β1AR), but express two distinct β2-adrenergic receptor genes (β2aAR and β2bAR). Zebrafish β1AR deficient larvae described in Chapter 3 had lower resting heart rates than control larvae, which conforms to the stereotypical stimulatory nature of this receptor in the vertebrate heart. However, in larvae where loss of β2a/β2bAR and β1/β2bAR function was combined, heart rate was significantly increased. This confirmed my previous observation that the β2-adrenergic receptor has an inhibitory effect on heart rate in vivo. Fish release the catecholamines epinephrine and norepinephrine (the endogenous ligands of adrenergic receptors) into the circulation when exposed to hypoxia, if sufficiently severe. Zebrafish have two genes for tyrosine hydroxylase (TH1 and TH2), the rate limiting enzyme for catecholamine synthesis, which requires molecular oxygen as a cofactor. In Chapter 4, zebrafish larvae exposed to hypoxia for 4 days exhibited increased whole body epinephrine and norepinephrine content. TH2, but not TH1, mRNA expression decreased after 2 days of hypoxic exposure. The results of this thesis provide some of the first data on receptor-specific control of heart rate in fish under normal and hypoxic conditions. It also provides the first observations that catecholamine turnover and the mRNA expression of enzymes required for catecholamine synthesis in larvae are sensitive to hypoxia. Taken together, these data provide an interesting perspective on the balance of adrenergic and cholinergic control of heart rate in zebrafish larvae.

zebrafish

development

cardiovascular

adrenergic receptor

muscarinic receptor

catecholamine

tyrosine hydroxylase

Autonomic Control of Cardiac Function

Steele, Shelby L

08 February 2011

Cardiac parasympathetic tone mediates hypoxic bradycardia in fish, however the specific cholinergic mechanisms underlying this response have not been established. In Chapter 2, bradycardia in zebrafish (Danio rerio) larvae experiencing translational knockdown of the M2 muscarinic receptor was either prevented or limited at two different levels of hypoxia (PO2 = 30 or 40 Torr). Also, M2 receptor deficient fish exposed to exogenous procaterol (a presumed β2-adrenergic receptor agonist) had lower heart rates than similarly treated control fish, implying that the β2-adrenergic receptor may have a cardioinhibitory role in this species. Zebrafish have a single β1-adrenergic receptor (β1AR), but express two distinct β2-adrenergic receptor genes (β2aAR and β2bAR). Zebrafish β1AR deficient larvae described in Chapter 3 had lower resting heart rates than control larvae, which conforms to the stereotypical stimulatory nature of this receptor in the vertebrate heart. However, in larvae where loss of β2a/β2bAR and β1/β2bAR function was combined, heart rate was significantly increased. This confirmed my previous observation that the β2-adrenergic receptor has an inhibitory effect on heart rate in vivo. Fish release the catecholamines epinephrine and norepinephrine (the endogenous ligands of adrenergic receptors) into the circulation when exposed to hypoxia, if sufficiently severe. Zebrafish have two genes for tyrosine hydroxylase (TH1 and TH2), the rate limiting enzyme for catecholamine synthesis, which requires molecular oxygen as a cofactor. In Chapter 4, zebrafish larvae exposed to hypoxia for 4 days exhibited increased whole body epinephrine and norepinephrine content. TH2, but not TH1, mRNA expression decreased after 2 days of hypoxic exposure. The results of this thesis provide some of the first data on receptor-specific control of heart rate in fish under normal and hypoxic conditions. It also provides the first observations that catecholamine turnover and the mRNA expression of enzymes required for catecholamine synthesis in larvae are sensitive to hypoxia. Taken together, these data provide an interesting perspective on the balance of adrenergic and cholinergic control of heart rate in zebrafish larvae.

zebrafish

development

cardiovascular

adrenergic receptor

muscarinic receptor

catecholamine

tyrosine hydroxylase

Inhibition of endotoxin-induced plasma leakage and edema in rat trachea and esophagus by urethan anesthesia and dimethylthiourea

Kuo, Shan-tsu

06 June 2006

Endotoxin (lipopolysaccharide, LPS) a chemical component of cell wall of gram-negative bacteria, is an important mediator in pathogenesis of sepsis and acute respiratory distress syndrome. It causes production and release of a wide array of mediators including cytokines, chemokines, oxygen free radicals and nitric oxide from neutrophils, macrophages, endothelial cells and epithelial cells through the NF-£eB pathway. LPS increases the permeability of microcirculation, and causes the acute formation of numerous endothelial gaps among venular endothelial cells, resulting in extensive plasma leakage in the inflammatory tissue. Urethan is commonly used as an animal anesthetic for nonrecovery laboratory surgery. It is aslo an £\2-adrenoreceptor antagonist, which can suppress the activation of the cardiovascular system and reduce the angiotensin which increases the blood pressure. Urethan or its metabolites protect animals against LPS, in part, by reducing TNF-£\ release. The aims of the present study to investigate the time-course of vascular permeability in microcirculation of rat trachea, bronchus and esophagus after intravenous application of a high dose of LPS (15 mg/kg), and to reveal the role of urethan (1 g/¢V) and dimethylthiourea (DMTU, 0.375 g/¢V) in inhibition of LPS-induced plasma leakage and edema. India ink was used as a tracer dye to mark leaky microvessels after LPS application. Endothelial gaps were made visible for light microscopy by staining the borders of endothelial cells with silver nitrate. Tracheal sections were stained with toluidine blue to show the subendothelial edema formation. A high dose of LPS was administered intravenously to induce serious plasma leakage and edema and a large number of endothelial gaps formed in postcapillary and collecting venules in the rat trachea and esophagus. The peak values of plasma leakage and edema occurred 5 min after LPS (P<0.01). Urethan anesthesia significantly inhibited LPS-induced plasma leakage by 95 ¡Ó 1.7% in various parts of the respiratory tracts and inhibited edema ratio in the trachea by 57%. Urethan was also found to reduce leukocyte infiltration and the number of endothelial gaps by 46.8 ¡Ó 4.6%. DMTU pretreatment significantly inhibited plasma leakage by 88.5 ¡Ó 2.5% in the respiratory tract and inhibited edema ratio in the trachea by 89% at 5 min after LPS. It is concluded that LPS-induced increase in plasma leakage and edema correlated with the formation of endothelial gaps, and association with activation of alpha 2-adrenergic receptors and hydroxyl free radical production.

adrenergic receptor

Endotoxin

dimethylthiourea

hydroxyl free radical

plasma leakage

On the physiological response to exercise in thyrotoxicosis effect of beta-adrenoceptor blockade and antithyroid treatment

余宇超, Yu, Yu-chiu, Donald.

January 1982

published_or_final_version / Medicine / Master / Doctor of Medicine

Hyperthyroidism - Physiological aspects.

Adrenergic beta blockers.

Thyroid antagonists.

Adrenergic control and its mechanism of stimulation of electrogenic anion secretion in primary cultures of rat epididymal eipthelialcells

陳浦棠, Chan, Po-tong, Timothy.

January 1990

published_or_final_version / Physiology / Master / Master of Philosophy

Epididymis - Secretion.

Epithelial cells.

Anions.

Rats - Physiology.

Adrenergic mechanisms.