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Notes: Abstract: Experimental animal and peripheral blood cell studies point to guanine nucleotide regulatory (G) protein disturbances in bipolar affective disorder. We have previously reported elevated prefrontal cortex Gsα protein in bipolar affective disorder and have now extended these preliminary observations in a larger number of subjects, assessing the brain regional specificity of these changes in greater detail, determining the functional biochemical correlates of such changes, and evaluating their diagnostic specificity. Membrane G protein (Gsα, Giα, Goα, and Gβ) immunoreactivities were estimated by western blotting in postmortem brain regions obtained from 10 patients with a DSMIII-R diagnosis of bipolar affective disorder and 10 nonpsychiatric controls matched on the basis of age, postmortem delay, and brain pH. To examine whether there were functional correlates to the observed elevated Gsα levels, basal and GTPγS-and forskolin-stimulated cyclic AMP production was determined in the same brain regions. Compared with controls, Gsα (52-kDa species) immunoreactivity was significantly (p 〈 0.05) elevated in prefrontal (+36%), temporal (+65%), and occipital (+96%) cortex but not in hippocampus (+28%), thalamus (-23%), or cerebellum (+21%). In contrast, no significant differences were found in the other G protein subunits (Giα, Goα, Gβ) measured in these regions. Forskolin-stimulated cyclic AMP production was significantly increased in temporal (+31%) and occipital (+96%) cortex but not in other regions. No significant differences were apparent in basal or GTPγS-stimulated cyclic AMP production. A significant correlation (r= 0.60, p 〈 0.001) was observed between forskolin-stimulated cyclic AMP formation and Gsα (52 kDa) immunoreactivity when examined across these cortical regions. The observed increase in Gsα may be specific to bipolar disorders as no significant differences were detected in Gsα levels in temporal cortex from patients with either schizophrenia (n = 7) or Alzheimer's disease (n = 7). In summary, the present study confirms and extends our earlier findings and supports the notion that increased Gsα levels and possibly Gsα-adenylyl cyclase-mediated signal transduction are relevant to the pathophysiology of bipolar affective disorder.

Notes: Abstract: Specific [3H]inositol 1,4,5-trisphosphate ([3H]InsP3) binding was studied in regions of postmortem brain from 15 patients with Huntington's disease (HD) and 13 nonneurological controls. Single-point binding analyses, using 5.0 nM InsP3, showed statistically significant reductions in specific [3H]InsP3 binding in the caudate (–71%) and putamen (–75%) of HD patients compared with controls. Frontal and occipital cortical [3H]InsP3 binding was not significantly different between HD and controls, a finding suggesting that the reduced [3H]InsP3 binding parallels the brain regional specificity of the neuropathological changes in HD. Scatchard analyses of data from [3H]InsP3 competition binding assays performed on caudate nucleus revealed that the reductions found using single-point binding assays were due to a decrease in both binding density (–57%) and affinity (–50%) in HD brain compared with controls. The concomitant changes in InsP3 receptor density and affinity in HD brain suggest that these alterations may be produced by processes in addition to cell loss. These results suggest the possibility that disturbances in InsP3 receptor function, possibly resulting in altered intracellular calcium flux and homeostasis, occur in HD and may participate in the pathogenesis of this neurodegenerative disorder.

Notes: Abstract— Recent work indicates that the therapeutic action of lithium may be mediated through perturbation of postreceptor second messenger systems. To elucidate further the postreceptor cellular sites of action(s) of lithium, the effect of chronic lithium treatment on various components of the receptor-activated phosphoinositide pathway was investigated. We found that chronic administration of lithium (0.2% LiCI, 21 days) to adult male rats did not significantly affect phosphoinositide hydrolysis in cerebral cortical slices induced by carbachol (1 mM) or NaF (10 mM). Nor did the same treatment alter the carbachol (1 mM) potentiation of guanosine 5′-(γ-thio)triphosphate (30 μM) stimulation of phosphoinositide hydrolysis (an index of receptor/G protein coupling) in cortical membranes. Immunoblotting studies revealed no changes in the levels of Gαq/11 immunoreactivity in the cortex after chronic lithium treatment. The levels of protein kinase C, as revealed by specific binding of [3H]phorbol dibutyrate ([3H]PDBu), were significantly reduced in the cytosolic fraction and increased in the particulate fraction of rat cortex after chronic lithium, whereas the KD of [3H]PDBu binding remained relatively constant. A small and insignificant decrease in the density of [3H]inositol 1,4,5-trisphosphate binding was also found in the cortex. The above data suggest that chronic lithium treatment affects neither the muscarinic cholinergic-linked phosphoinositide turnover nor the putative G protein α subunit (Gαq/11) responsible for phospholipase C activation. However, a possible translocation and activation of protein kinase C activity may be significant in the therapeutic effect of this mood-stabilizing agent.

Notes: Abstract: The function of the phosphoinositide second messenger system was assessed in occipital, temporal, and frontal cortex obtained postmortem from subjects with bipolar affective disorder and matched controls by measuring the hydrolysis of [3H]phosphatidylinositol ([3H]PI) incubated with membrane preparations and several different stimulatory agents. Phospholipase C activity, measured in the presence of 0.1 mM Ca2+ to stimulate the enzyme, was not different in bipolar and control samples. G proteins coupled to phospholipase C were concentration-dependently activated by guanosine 5′-O-(3-thiotriphosphate) (GTPγS) and by NaF. GTPγS-stimulated [3H]PI hydrolysis was markedly lower (50%) at all tested concentrations (0.3–10 µM GTPγS) in occipital cortical membranes from bipolar compared with control subjects. Responses to GTPγS in temporal and frontal cortical membranes were similar in bipolars and controls, as were responses to NaF in all three regions. Brain lithium concentrations correlated directly with GTPγS-stimulated [3H]PI hydrolysis in bipolar occipital, but not temporal or frontal, cortex. Carbachol, histamine, trans-1-aminocyclopentyl-1,3-dicarboxylic acid, serotonin, and ATP each activated [3H]PI hydrolysis above that obtained with GTPγS alone, and these responses were similar in bipolars and controls except for deficits in the responses to carbachol and serotonin in the occipital cortex, which were equivalent to the deficit detected with GTPγS alone. Thus, among the three cortical regions examined there was a selective impairment in G protein-stimulated [3H]PI hydrolysis in occipital cortical membranes from bipolar compared with control subjects. These results directly demonstrate decreased activity of the phosphoinositide signal transduction system in specific brain regions in bipolar affective disorder.

Notes: To examine whether multiple subtypes of the excitatory amino acid (EAA) receptor coupled to phosphoino-sitide (PPI) hydrolysis exist, we have pharmacologically characterized the PPI response in neonatal and adult rat brain. Activation of PPI hydrolysis was determined by the accumulation of [3H]inositol monophosphate in brain slices prelabeled with [3H]inositol. In neonatal hippocampus, D,L-2-amino-3-phosphonopropionic acid (AP3; 1 mM) inhibited the m-1-aminocyclopentane-1,3-dicarboxylic acid (IUPAC nomenclature; ACPD; 100 μM)- and quisqualate (Quis; 100 μM)-stimulated PPI hydrolysis by 73 and 66%, respectively, but had no effect in neonatal cerebellum. In adult hippocampus, AP3 stimulated PPI hydrolysis with potency and efficacy comparable to those of Quis and ACPD and completely masked the Quis concentration-response curve. In adult cerebellum, only Quis behaved as a full agonist on the PPI response. The Quis concentration-response curve was shifted rightward with a fourfold decrease in potency in the presence of ACPD (5 mM), whereas it was nearly additive with the PPI response induced by AP3 (5 mM). Thus, our data reveal significant developmental and brain regional differences in metabotropic EAA receptor responses and support the notion that this receptor is heterogeneous, in both a regionally specific and a develop-mentally dependent manner.

Notes: Abstract: Although guanine nucleotide binding proteins (G proteins) are one of the critical components of signal transduction units for various membrane receptor-mediated responses, little information is available regarding their status in brain of patients with neurodegenerative illnesses. We measured the immunoreactivity of G protein subunits (Gsα, Giα, Goα, Gq/11α, and Gβ) in autopsied cerebellar and cerebral cortices of 10 end-stage patients with dominantly inherited olivopontocerebellar atrophy (OPCA) who all had severe loss of Purkinje cell neurons and climbing fiber afferents in cerebellar cortex. Compared with the controls, the long-form Gsα (52-kDa species) immunoreactivity was significantly elevated by 52% (p 〈 0.01) in the cerebellar cortex of the OPCA patients, whereas the Gi1α concentration was reduced by 35% (p 〈 0.02). No statistically significant differences were observed for Goα, Gi2α, Gβ1, Gβ2, or Gq/11α in cerebellar cortex or for any G protein subunit in the two examined cerebral cortical subdivisions (frontal and occipital). The cerebellar Gsα elevation could represent a compensatory response (e.g., sprouting, reactive synaptogenesis) by the remaining cerebellar neurons (granule cells?) to neuronal damage but also might contribute to the degenerative process, as suggested by the ability of Gsα, in some experimental preparations, to promote calcium flux. Further studies will be required to determine the actual functional consequences of the G protein changes in OPCA and whether the elevated Gsα is specific to OPCA cerebellum, because of its unique cellular pattern of morphological damage, or is found in brain of patients with other progressive neurodegenerative disorders.

Notes: NaF and guanosine 5′-O-thiotriphosphate [GTP(S)] stimulated the accumulation of [3H]inositol monophosphate ([3H]lnsP) in rat brain cortical membranes, with half-maximal stimulation at 2 mM and 1 μM, respectively. Calcium also increased basal [3H]lnsP formation over a range of concentrations from 10-7 to 10-4M. The stimulatory effect of GTP(S) (30 μM) on [3H]InsP production was insensitive to Ca2+, whereas NaF-evoked [3H]InsP formation was dependent on Ca2+ concentrations. Guanosine 5′-O-thiodiphosphate significantly attenuated GTP(S)- but not NaF-stimulated [3H]InsP production. Coincubation of GTP(S) (30 μM) and submaximal concentrations of NaF (1 or 3 mM) stimulated [3H]InsP formation to a degree that was nearly additive with that produced by either drug alone. However, the resultant accumulation of [3H]InsP in the presence of maximally effective concentrations of GTP(S) and NaF was not different from that produced by NaF alone. Incubation of cortical membranes with GTP(S) and NaF for 1 min stimulated the accumulation of [3H]inositol bisphosphate (InsP2) but not [3H]InsP. [3H]InsP2 production elicited by GTP(S) was markedly enhanced by the muscarinic cholinergic agonist carbachol. In contrast, NaF-stimulated [3H]InsP2 formation was not potentiated by carbachol. Our findings of different characteristics of GTP(S) and fluoride activation of polyphosphoinositide (PPI) hydrolysis suggest that separate regulatory mechanisms are involved in these two modes of stimulation in brain membranes. Activation of PPI hydrolysis by fluoride may be mediated by a direct stimulation of PPI phosphodiesterase or by activating a putative guanine nucleotide regulatory protein at a location distinct from the GTP-binding site.

Notes: Abstract: Although the nucleus accumbens is assumed to be a critical brain “pleasure center,” its function in humans is unknown. As animal data suggest that a unique feature of this small brain area is its high sensitivity to down-regulation of an inhibitory G protein by drugs of abuse, we compared G protein levels in postmortem nucleus accumbens with those in seven other brain regions of chronic users of cocaine, methamphetamine, and heroin, and of matched controls. Biochemical changes were restricted to the nucleus accumbens in which concentrations of Gαi1 and/or Gαi2 were reduced by 32-49% in the methamphetamine and heroin users. This selective responsiveness to these abused drugs implies a special role for the human nucleus accumbens in mechanisms of drug reinforcement and suggests that some features of the drug-dependent state (e.g., tolerance) might be related to inhibition of Gαi-linked receptor activity.

Notes: Abstract : Previous observations of reduced [3H]cyclic AMP binding in postmortem brainregions frombipolar affective disorder subjects imply cyclic AMP-dependent proteinkinase functionmay be altered in this illness. To test this hypothesis, basal and stimulated cyclic AMP-dependent protein kinase activity was determined in cytosolic and particulate fractions of postmortem brain from bipolar disorder patients and matched controls. Maximal enzyme activity was significantly higher (104%) in temporal cortex cytosolic fractions from bipolar disorder brain compared with matched controls. In temporal cortex particulate fractions and in the cytosolic and particulate fractions of other brain regions, smaller but statistically nonsignificant increments in maximal enzyme activity were detected. Basal cyclic AMP-dependent protein kinase activity was also significantly higher (40%) in temporal cortex cytosolic fractions of bipolar disorder brain compared with controls. Estimated EC50 values for cyclic AMP activation of this kinase were significantly lower (70 and 58%, respectively) in both cytosolic and particulate fractions of temporal cortex from bipolar disorder subjects compared with controls. These findings suggest that higher cyclic AMP-dependent proteinkinase activity in bipolar disorder brain may be associated with a reduction of regulatory subunits of this enzyme, reflecting a possible adaptive response of this transducing enzyme to increased cyclic AMP signaling in this disorder.