Luisa Iacovelli

G protein-coupled receptors: heterologous regulation of homologous desensitization and its implications.

Two patterns of rapid desensitization have been characterized for G protein-coupled receptors: homologous desensitization, which mainly involves G protein-coupled receptor kinases and arrestins, and heterologous desensitization, which mainly involves protein kinases A (PKA) and C (PKC). In this review, Tsu Tshen Chuang and colleagues discuss evidence to show that PKA and PKC can modify the functional state of the G protein-coupled receptor kinases/arrestin homologous desensitization machinery, providing a novel level of cross-talk in signal transduction. Studies on regulation of G protein-coupled receptor kinases and arrestins confirm that the functional state of this machinery may have important consequences for cellular responsiveness and may represent new targets for therapeutic strategies.

Stress-Related Methylation of the Catechol-O-Methyltransferase Val158 Allele Predicts Human Prefrontal Cognition and Activity

DNA methylation at CpG dinucleotides is associated with gene silencing, stress, and memory. The catechol-O-methyltransferase (COMT) Val158 allele in rs4680 is associated with differential enzyme activity, stress responsivity, and prefrontal activity during working memory (WM), and it creates a CpG dinucleotide. We report that methylation of the Val158 allele measured from peripheral blood mononuclear cells (PBMCs) of Val/Val humans is associated negatively with lifetime stress and positively with WM performance; it interacts with stress to modulate prefrontal activity during WM, such that greater stress and lower methylation are related to reduced cortical efficiency; and it is inversely related to mRNA expression and protein levels, potentially explaining the in vivo effects. Finally, methylation of COMT in prefrontal cortex and that in PBMCs of rats are correlated. The relationship of methylation of the COMT Val158 allele with stress, gene expression, WM performance, and related brain activity suggests that stress-related methylation is associated with silencing of the gene, which partially compensates the physiological role of the high-activity Val allele in prefrontal cognition and activity. Moreover, these results demonstrate how stress-related DNA methylation of specific functional alleles impacts directly on human brain physiology beyond sequence variation.

The Wnt pathway, cell-cycle activation and β-amyloid: novel therapeutic strategies in Alzheimer's disease?

Beta-amyloid protein (betaAP) is thought to cause neuronal loss in Alzheimers disease (AD). Applied to neurons in culture, betaAP induces neuronal death and hyperphosphorylation of tau protein, which forms neurofibrillary tangles (NFTs) in AD brains. Neurons also undergo rapid apoptotic death following reactivation of a mitotic cycle. However, the molecular events that determine the fate of neurons challenged with betaAP (apoptotic death, formation of NFTs and survival) are unclear. We discuss a scenario for the pathogenesis of AD. This links betaAP-induced changes to the Wnt signaling pathway that promotes proliferation of progenitor cells and directs cells into a neuronal phenotype during brain development. We propose that betaAP-mediated facilitation of mitogenic Wnt signaling activates unscheduled mitosis in differentiated neurons. Furthermore, late downregulation of Wnt signaling by betaAP might lead to NFT formation. We propose that drugs that both inhibit the cell cycle and rescue Wnt activity could provide novel AD therapeutics.

Functional Characterization of WNT7A Signaling in PC12 Cells INTERACTION WITH A FZD5·LRP6 RECEPTOR COMPLEX AND MODULATION BY DICKKOPF PROTEINS

WNT factors represent key mediators of many processes in animal development and homeostasis and act through a receptor complex comprised of members of the Frizzled and low density lipoprotein-related receptors (LRP). In mammals, 19 genes encoding Wingless and Int-related factor (WNTs), 10 encoding Frizzled, and 2 encoding LRP proteins have been identified, but little is known of the identities of individual Frizzled-LRP combinations mediating the effects of specific WNT factors. Additionally, several secreted modulators of WNT signaling have been identified, including at least three members of the Dickkopf family. WNT7A is a WNT family member expressed in the vertebrate central nervous system capable of modulating aspects of neuronal plasticity. Gene knock-out models in the mouse have revealed that WNT7A plays a role in cerebellar maturation, although its function in the development of distal limb structures and of the reproductive tract have been more intensely studied. To identify a receptor complex for this WNT family member, we have analyzed the response of the rat pheochromocytoma cell line PC12 to WNT7A. We find that PC12 cells are capable of responding to WNT7A as measured by increased β-catenin stability and activation of a T-cell factor-based luciferase reporter construct and that these cells express three members of the Frizzled family (Frizzled-2, -5, and -7) and LRP6. Our functional analysis indicates that WNT7A can specifically act via a Frizzled-5·LRP6 receptor complex in PC12 cells and that this activity can be antagonized by Dickkopf-1 and Dickkopf-3.

Endogenous activation of metabotropic glutamate receptors supports the proliferation and survival of neural progenitor cells.

The use of neural progenitor cells (NPCs) is limited by the incomplete knowledge of the extracellular signals regulating their proliferation and survival. We report that cultured mouse NPCs express functional mGlu3 and mGlu5 metabotropic glutamate receptors. Pharmacological blockade of both receptors reduced NPC proliferation and survival, whereas activation of mGlu5 receptors substantially enhanced cell proliferation. Adult mice lacking mGlu5 receptors or treated with mGlu5 or mGlu3 receptor antagonists showed a dramatic reduction in the number of dividing neuroprogenitors present in the subventricular zone and in the dentate gyrus of the hippocampus. These data disclose a novel function of mGlu receptors and offer new potential strategies for the optimization of cell replacement therapy in neurodegenerative disorders.

Regulation of G-protein-coupled receptor kinase subtypes by calcium sensor proteins.

The process of G‐protein‐coupled receptor (GPCR) homologous desensitization is intrinsically related to the function of a class of S/T kinases named G‐protein‐coupled receptor kinases (GRK). GRK family is so far composed of six cloned members, named GRK1 to 6, which are classified into three subfamilies: GRK1 is alone in the first (rhodopsin kinase subfamily), GRK2 and 3 form the second [β‐adrenergic receptor kinase (βARK) subfamily], and GRK4, 5, and 6 constitute the third (GRK4 subfamily). Recent studies from different laboratories have demonstrated that different calcium sensor proteins (CSP) can selectively regulate the activity of GRK subtypes. In the presence of calcium, rhodopsin kinase (GRK1) is inhibited by the photoreceptor‐specific CSP recoverin through direct binding. Several other recoverin homologues (including NCS 1, VILIP 1, and hippocalcin) are also able to inhibit GRK1 in a calcium‐dependent manner. The ubiquitous calcium binding protein calmodulin (CaM) can inhibit GRK5 with a high affinity (IC50=40–50 nM). A direct interaction between GRK5 and Ca2+/CaM was documented and this binding did not influence the catalytic activity of the kinase, but rather reduced GRK5 binding to the membrane. These studies suggest that CSP act as functional analogs in mediating the regulation of different GRK subtypes by Ca2+. This mechanism, however, is highly selective with respect to the GRK subtypes: GRK1, but not GRK2 and GRK5, is regulated by recoverin and other NCS, but GRK4, 5, and 6, which belong to the GRK4 subfamily are potently inhibited by CaM, which has little or no effect on members of other GRK subfamilies. Calcium‐dependent inhibition of rhodopsin kinase by recoverin represents one of the mechanisms that control adaptation to light. For the other GPCR, CSP‐GRK interaction provides a feedback mechanism that can modulate homologous desensitization of these receptors.— Iacovelli, L., Sallese, M., Mariggió, S., De Blasi, A. Regulation of G‐protein‐coupled receptor kinase subtypes by calcium sensor proteins. FASEB J. 13, 1–8 (1999)

Native group-III metabotropic glutamate receptors are coupled to the mitogen-activated protein kinase/phosphatidylinositol-3-kinase pathways.

We used cultured cerebellar granule cells to examine whether native group‐III metabotropic glutamate (mGlu) receptors are coupled to the mitogen‐activated protein kinase (MAPK) and phosphatidylinositol‐3‐kinase (PI‐3‐K) pathways. Cultured granule cells responded to the group‐III mGlu receptor agonist, L‐2‐amino‐4‐phosphonobutanoate (l‐AP4), with an increased phosphorylation and activity of MAPKs (ERK‐1 and ‐2) and an increased phosphorylation of the PI‐3‐K target, protein kinase B (PKB/AKT). These effects were attenuated by the group‐III antagonists, α‐methyl‐serine‐O‐phosphate (MSOP) and (R,S)‐α‐cyclopropyl‐4‐phosphonophenylglycine (CPPG), or by pretreatment of the cultures with pertussis toxin. l‐AP4 also induced the nuclear translocation of β‐catenin, a downstream effector of the PI‐3‐K pathway. To assess the functional relevance of these mechanisms we examined the ability of l‐AP4 to protect granule cells against apoptosis by trophic deprivation, induced by lowering extracellular K+ from 25 to 10 mm. Neuroprotection by l‐AP4 was attenuated by MSOP and abrogated by the compounds PD98059 and UO126, which inhibit the MAPK pathway, or by the compound LY294002, which inhibits the PI‐3‐K pathway. Taken together, these results show for the first time that native group‐III mGlu receptors are coupled to MAPK and PI‐3‐K, and that activation of both pathways is necessary for neuroprotection mediated by this particular class of receptors.

Role of G Protein-coupled Receptor Kinase 4 and β-Arrestin 1 in Agonist-stimulated Metabotropic Glutamate Receptor 1 Internalization and Activation of Mitogen-activated Protein Kinases

The metabotropic glutamate 1 (mGlu1) receptor in cerebellar Purkinje cells plays a key role in motor learning and motor coordination. Here we show that the G protein-coupled receptor kinases (GRK) 2 and 4, which are expressed in these cells, regulate the mGlu1 receptor by at least in part different mechanisms. Using kinase-dead mutants in HEK293 cells, we found that GRK4, but not GRK2, needs the intact kinase activity to desensitize the mGlu1 receptor, whereas GRK2, but not GRK4, can interact with and regulate directly the activated Gαq. In cells transfected with GRK4 and exposed to agonist, β-arrestin was first recruited to plasma membranes, where it was co-localized with the mGlu1 receptor, and then internalized in vesicles. The receptor was also internalized but in different vesicles. The expression of β-arrestin V53D dominant negative mutant, which did not affect the mGlu1 receptor internalization, reduced by 70–80% the stimulation of mitogen-activated protein (MAP) kinase activation by the mGlu1 receptor. The agonist-stimulated differential sorting of the mGlu1 receptor and β-arrestin as well as the activation of MAP kinases by mGlu1 agonist was confirmed in cultured cerebellar Purkinje cells. A major involvement of GRK4 and of β-arrestin in agonist-dependent receptor internalization and MAP kinase activation, respectively, was documented in cerebellar Purkinje cells using an antisense treatment to knock down GRK4 and expressing β-arrestin V53D dominant negative mutant by an adenovirus vector. We conclude that GRK2 and GRK4 regulate the mGlu1receptor by different mechanisms and that β-arrestin is directly involved in glutamate-stimulated MAP kinase activation by acting as a signaling molecule.

Regulation of G protein-coupled receptor kinase subtypes by calcium sensor proteins

G protein-coupled receptor homologous desensitization is intrinsically related to the function of a class of S/T kinases named G protein-coupled receptor kinases (GRK). The GRK family is composed of six cloned members, named GRK1 to 6. Studies from different laboratories have demonstrated that different calcium sensor proteins (CSP) can selectively regulate the activity of GRK subtypes. In the presence of calcium, rhodopsin kinase (GRK1) is inhibited by the photoreceptor-specific CSP recoverin through direct binding. Several other recoverin homologues (including NCS 1, VILIP 1 and hippocalcin) are also able to inhibit GRK1. The ubiquitous calcium-binding protein calmodulin (CaM) can inhibit GRK5 with a high affinity (IC(50)=40-50 nM). A direct interaction between GRK5 and Ca(2+)/CaM was documented and this binding does not influence the catalytic activity of the kinase, but rather reduced GRK5 binding to the membrane. These studies suggest that CSP act as functional analogues in mediating the regulation of different GRK subtypes by Ca(2+). This mechanism is, however, highly selective with respect to the GRK subtypes: while GRK1, but not GRK2 and GRK5, is regulated by recoverin and other NCS, GRK4, 5 and 6, that belong to the GRK4 subfamily, are potently inhibited by CaM, which had little or no effect on members of other GRK subfamilies.

DRD2/AKT1 interaction on D2 c-AMP independent signaling, attentional processing, and response to olanzapine treatment in schizophrenia

The D2/AKT1/GSK-3β signaling pathway has been involved in the downstream intracellular effects of dopamine, in the pathophysiology of cognitive deficits and related brain activity in schizophrenia, as well as in response to treatment with antipsychotics. Polymorphisms in the D2 (DRD2 rs1076560) and AKT1 (AKT1 rs1130233) genes have been associated with their respective protein expression and with higher-order cognition and brain function, including attention. Given the strong potential for their relationship, we investigated the interaction of these polymorphisms on multiple molecular and in vivo phenotypes associated with this signaling pathway. We measured AKT1 and GSK-3β proteins and phosphorylation in human peripheral blood mononuclear cells, functional MRI cingulate response during attentional control, behavioral accuracy during sustained attention, and response to 8 wk of treatment with olanzapine in a total of 190 healthy subjects and 66 patients with schizophrenia. In healthy subjects, we found that the interaction between the T allele of DRD2 rs1076560 and the A allele of AKT1 rs1130233 was associated with reduced AKT1 protein levels and reduced phosphorylation of GSK-3β, as well as with altered cingulate response and reduced behavioral accuracy during attentional processing. On the other hand, interaction of these two alleles was associated with greater improvement of Positive and Negative Syndrome Scale scores in patients with schizophrenia after treatment with olanzapine. The present results indicate that these functional polymorphisms are epistatically associated with multiple phenotypes of relevance to schizophrenia. Our results also lend support to further investigation of this downstream molecular pathway in the etiology and treatment of this disorder.