George N.M. Gurguis

Platelet alpha2A-adrenoceptor function in major depression: Gi coupling, effects of imipramine and relationship to treatment outcome

Studies suggest alpha2A-adrenoceptors (alpha(2A)AR) dysregulation in major depressive disorder (MDD). Platelet alpha(2A)ARs exist in high- and low-conformational states that are regulated by Gi protein. Although alpha(2A)AR coupling to Gi protein plays an important role in signal transduction and is modulated by antidepressants, it has not been previously investigated. Alpha2AR density in the high- and low-conformational states, agonist affinity and coupling efficiency were investigated in 27 healthy control subjects, 23 drug-free MDD patients and 16 patients after imipramine treatment using [3H]yohimbine saturation and norepinephrine displacement of [3H]yohimbine binding experiments. Coupling measures were derived from NE-displacement experiments. Patients had significantly higher alpha(2A)AR density, particularly in the high-conformational state, than control subjects. Coupling indices were normal in patients. High pre-treatment agonist affinity to the receptor in the high-conformational state and normal coupling predicted positive treatment outcome. Decreased coupling to Gi predicted a negative treatment outcome. Imipramine induced uncoupling (-11%) and redistribution of receptor density in treatment responders only, but had no effect on alpha(2A)AR coupling or density in treatment non-responders. Increased alpha(2A)AR density may represent a trait marker in MDD. The results provide indirect evidence for abnormal protein kinase A (PKA) and protein kinase C (PKC) in MDD which may be pursued in future investigations.

Adrenergic receptor function in panic disorder II. Neutrophil β2 receptors: Gs protein coupling, effects of imipramine treatment and relationship to treatment outcome

Panic attacks are associated with increased autonomic symptoms, suggesting increased beta 2-adrenergic receptor (beta 2AR) function in PD. Tricyclic antidepressants downregulate beta AR function. Previous studies on beta AR function in PD, however, are inconsistent. We recently found increased beta AR coupling and density in neutrophils of symptomatic drug-free PD patients. This study evaluated beta AR coupling to Gs protein in 28 controls, 25 drug-free PD patients and 8 PD imipramine-treated patients. PD patients had significantly higher coupling and receptor density, particularly in the high-conformational state. Differences were more pronounced in patients with less depressive symptomatology. Treatment with imipramine was associated with decreased beta AR coupling and density in the high-conformational state. Several beta AR binding parameters were related to severity of anxiety symptoms and treatment outcome. Antidepressants downregulate beta AR density and induce uncoupling from Gs protein in PD. Future studies may investigate beta AR coupling in relationship to treatment outcome and the role of beta AR kinase in PD.

Adrenergic receptor function in panic disorder. I. Platelet α2 receptors : Gi protein coupling, effects of imipramine, and relationship to treatment outcome

Various studies suggest α2-adrenergic receptor (α2AR) dysregulation in panic disorder (PD). Platelet α2-AR exist in high- and low-conformational states as a function of their coupling to Gi protein. α2AR coupling is important in signal transduction and is modulated by antidepressants. α2AR density in the high- and low-conformational states, agonist affinity, and coupling efficiency were investigated in 21 healthy controls, 21 drug-free PD patients, and eight imipramine-treated patients using norepinephrine displacement of 3H-yohimbine binding. Percentage of receptors in the high-conformational state (%RH) and the ratio of the agonist dissociation constant to the receptor in the low-/high-conformational state (KL/KH), calculated from displacement experiments, were used as coupling indices. Patients had high α2AR density in both conformational states. %R H and KL/KH ratio were significantly different, particularly in patients with Hamilton scale for depression (HAMD) scores ⩾15. Imipramine treatment (29 weeks) had no effect on α2AR density or coupling, despite improvement in anxiety ratings. High pretreatment α2AR density and coupling predicted low severity of anxiety after treatment. Increased α2AR density and abnormal coupling may represent an adaptive mechanism or trait marker in PD.

Neutrophil β2-adrenoceptor function in major depression: Gs coupling, effects of imipramine and relationship to treatment outcome

Abnormal beta(2)-adrenoceptor density and beta(2)-adrenoceptor-mediated cyclic adenosine monophosphate (cAMP) responses were inconsistently reported in major depressive disorder. Tricyclic antidepressants downregulate beta-adrenoceptor density and decrease coupling to G(s) protein. Abnormal beta-adrenoceptor coupling may exist in major depressive disorder and may relate to treatment response. We investigated beta(2)-adrenoceptor coupling to G(s) protein in 25 controls, 23 major depressive disorder drug-free patients and 16 major depressive disorder patients after chronic imipramine treatment using agonist displacement experiments. Pretreatment beta(2)-adrenoceptor coupling and density were normal in patients as a whole. Chronic imipramine induced beta(2)-adrenoceptor uncoupling. This effect was observed in treatment responders who had increased beta(2)-adrenoceptor density in the high-conformational state and supercoupling prior to treatment. Beta(2)-adrenoceptor density decreased after imipramine treatment. Treatment non-responders had seemingly normal pretreatment beta(2)-adrenoceptor function, which was not changed by imipramine. Differences in beta(2)-adrenoceptor regulation in major depressive disorder may underlie treatment response. The results indirectly implicate abnormal agonist-mediated beta(2)-adrenoceptor gene expression, protein kinase A, and protein kinase C in major depressive disorder.

Neuropathology markers and pathways associated with molecular targets for antipsychotic drugs in postmortem brain tissues: Exploration of drug targets through the Stanley Neuropathology Integrative Database

The atypical antipsychotics bind multiple receptor targets, including dopamine D₂ receptors (DRD2), 5-HT₂ receptors (HTR2A), α-2 adrenergic receptors (ADRA2A), and muscarinic receptors (CHRM1/4). Deficits in antipsychotic targets, their associated pathways, and the causal relationships between the various targets were explored using the Stanley Neuropathology Consortium Integrative Database (SNCID; http://sncid.stanleyresearch.org) and the Network Edge Orienting (NEO) software. There were brain region-specific deficits in the level of the antipsychotic targets, and the level of each target correlated with the mRNA level of the neurotrophic factor BDNF. While myelination was a common process correlated with both DRD2 mRNA levels and ADRA2A activity in the frontal cortex, metabolic processes were specifically correlated with DRD2 mRNA. Immune and inflammatory responses and apoptosis pathways were correlated with group II metabotropic glutamate receptors (GRM2), which are a target for the development of the next-generation antipsychotics. The NEO analysis revealed that HTR2A and GRM2 are likely to regulate BDNF levels in the hippocampus and frontal cortex, respectively, whereas DRD2 and ADRA2A activity are likely to be regulated by BDNF in the frontal cortex. BDNF may play an important role in mechanisms of action of the current antipsychotics and the next-generation antipsychotics that target GRM2. However, this data-mining approach indicates that the next-generation antipsychotics are likely to work through pathways that are distinct from those through which the current antipsychotics work. Exploratory analyses such as these may initiate future hypothesis-driven studies to reveal the mechanisms of action underlying the efficacy and side-effects of the antipsychotics.

Characteristics of norepinephrine and clonidine displacement of [3H]yohimbine binding to platelet alpha2-adrenoreceptors in healthy volunteers

Clonidines estimates of platelet alpha2-adrenoreceptor (alpha2AR) density are substantially lower than yohimbines. This discrepancy could have contributed to inconsistent results from studies on the role of alpha2AR in depression. Furthermore, few studies have investigated the relative distribution of alpha2AR between the high- and low-affinity states or their Gi protein coupling. [3H]yohimbine saturable binding to platelet alpha2AR, its displacement by norepinephrine and clonidine, and the effects of Gpp(NH)p on agonist displacement curves were investigated in 11 healthy volunteers. Clonidine estimates of alpha2AR density were close to norepinephrine estimates, and both were strongly correlated. Clonidines K(L)/K(H) ratio was lower than norepinephrines, consistent with its partial agonist nature. Norepinephrine and clonidine displacement curves revealed two affinity states. Gpp(NH)p induced a significant rightward shift to a single low-affinity state. When used in combination with a specific antagonist, clonidines estimates of alpha2AR density were similar to those of norepinephrines, and both were higher than previously reported, when clonidine was used alone. Re-evaluation of previous studies on alpha2AR in depression using clonidine is needed. The combined use of antagonist-saturation and agonist-displacement experiments to examine possible dysregulation in alpha2AR coupling to Gi protein in psychiatric disorders is recommended.

Indices of brain beta-adrenergic receptor signal transduction in the learned helplessness animal model of depression

Both stress response and antidepressant drug action may be mediated by beta-adrenergic receptors (beta AR). Since learned helplessness is a stress-induced animal model of depression, beta AR are relevant to investigate in this model. To date, studies have measured changes in total receptor density (RT), but have not examined more detailed aspects of signal transduction mechanisms such as coupling of the receptor to GS protein. We have investigated brain beta AR coupling in the frontal cortex, hippocampus and hypothalamus of rats exposed to inescapable shock and then tested for learned helplessness, and in both tested and naive controls using [125I]-iodocyanopindolol (ICYP) as the ligand. Both antagonist-saturation and agonist-displacement experiments were conducted, and the specificity for the beta AR was optimized by excluding ICYP binding to 5HT1B receptors. The percentage receptor density in the high-conformational state (%RH) and the ratio of agonist (isoproterenol) dissociation constant from the receptor in the low-/high-conformational states (KL/KH) were used as indices of coupling to GS protein. No significant differences were found between rats developing learned helplessness and non-helpless rats after inescapable stress in any parameter measured in any brain region. In the frontal cortex, exposure to inescapable shock induced beta AR uncoupling from GS protein as suggested by a low KL/KH ratio both in helpless and non-helpless rats but not in either control group. In the hypothalamus, there were trends for higher RL, RT and KL/KH ratio in helpless rats and stressed controls compared to naive controls. These findings suggest that beta AR binding parameters in frontal cortex, hippocampus or hypothalamus did not differentiate between helpless and non-helpless rats. Changes in beta AR coupling observed in these brain regions may reflect effects of stress, which appeared to be region-specific, rather than stress-induced behavioral depression.

CHAPTER 44 – Psychiatric Disorders

Since the 1960s, an extensive body of investigation has employed platelets as a peripheral model of central nervous system (CNS) neuronal function to investigate the neurobiology of psychiatric disorders. The major forces driving these studies are the inherent difficulty of directly accessing brain function in vivo and the substantial similarities between platelets and central neurons.1-5 However, as the rationale for extrapolating platelet findings to CNS function has been challenged (i.e. changes found in platelets might not necessarily mirror changes in the CNS), the rationale for platelet studies has shifted to using abnormalities in platelet receptor-signal transduction systems as peripheral markers in psychiatric disorders.