Distinct cellular expression of pertussis toxin-sensitive GTP-binding proteins in rat cerebellum

Association and colocalization of G protein alpha subunits and Purkinje cell protein 2 (Pcp2) in mammalian cerebellum

Previously, we have demonstrated a novel interaction between Galpha(o) protein and Purkinje cell protein-2 (Pcp2, also known as L7) in vitro and in transfected cells (Luo and Denker [1999] J. Biol. Chem. 274:10685-10688). Pcp2 is uniquely expressed in cerebellar Purkinje cells and in retinal bipolar neurons, and it may function as a cell-type specific modulator for G protein-mediated cell signaling. This interaction has been further evaluated in the present studies. Coimmunoprecipitation experiments reveal that Pcp2 associates with Galpha(o) in vivo in mouse cerebellum and eye extract. Pcp2 also associate with Galpha(i2) in the cerebellum. No detectable associations of Pcp2 with Galpha(z) and Galpha(q) subunits are observed. The association of Galpha(o) and Pcp2 is detected at postnatal day 1 (P1), and the association remains stable from day 3 (P3) until adulthood. Further, immunofluorescent double labeling and confocal microscopy suggest that Pcp2 and Galpha(o) are colocalized in the distal processes of cerebellar Purkinje cells including axonal endings and dendritic spines. Taken together, these findings indicate colocalization and association of Galpha(o) and Pcp2 in cerebellum and suggest a functional role in regions of synaptic activity.

G protein betagamma complex-mediated apoptosis by familial Alzheimer's disease mutant of APP

In familial Alzheimer's disease (FAD), three missense mutations, V642I, V642F and V642G, that co-segregate with the disease phenotype have been discovered in the 695 amino acid form of the amyloid precursor protein APP. Expression of these mutants causes a COS cell NK1 clone to undergo pertussis toxin-sensitive apoptosis in an FAD trait-linked manner by activating the G protein Go, which consists of G alpha(o) and G betagamma subunits. We investigated which subunit was responsible for the induction of apoptosis by V642I APP in NK1 cells. In the same system, expression of mutationally activated G alpha(o) or G alpha(i) induced little apoptosis. Apoptosis by V642I APP was antagonized by the overexpression of the carboxy-terminal amino acids 495-689 of the beta-adrenergic receptor kinase-1, which blocks the specific functions of G betagamma. Co-transfection of G beta2gamma2 cDNAs, but not that of other G beta(x)gamma(z) (x = 1-3; z = 2, 3), induced DNA fragmentation in a manner sensitive to bcl-2. These data implicate G betagamma as a cell death mediator for the FAD-associated mutant of APP.

Elevated stimulatory and reduced inhibitory G protein alpha subunits in cerebellar cortex of patients with dominantly inherited olivopontocerebellar atrophy

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 (Gs alpha, Gi alpha, Go alpha, Gq/11 alpha, and G beta) 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 Gs alpha (52-kDa species) immunoreactivity was significantly elevated by 52% (p < 0.01) in the cerebellar cortex of the OPCA patients, whereas the Gi1 alpha concentration was reduced by 35% (p < 0.02). No statistically significant differences were observed for Go alpha, Gi2 alpha, G beta 1, G beta 2, or Gq/11 alpha in cerebellar cortex or for any G protein subunit in the two examined cerebral cortical subdivisions (frontal and occipital). The cerebellar Gs alpha 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 Gs alpha, 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 Gs alpha 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.