Cyclic AMP promotes neuronal survival by phosphorylation of glycogen synthase kinase 3beta.

Agents that elevate intracellular cyclic AMP (cAMP) levels promote neuronal survival in a manner independent of neurotrophic factors. Inhibitors of phosphatidylinositol 3 kinase and dominant-inactive mutants of the protein kinase Akt do not block the survival effects of cAMP, suggesting that another signaling pathway is involved. In this report, we demonstrate that elevation of intracellular cAMP levels in rat cerebellar granule neurons leads to phosphorylation and inhibition of glycogen synthase kinase 3beta (GSK-3beta). The increased phosphorylation of GSK-3beta by protein kinase A (PKA) occurs at serine 9, the same site phosphorylated by Akt. Purified PKA is able to phosphorylate recombinant GSK-3beta in vitro. Inhibitors of GSK-3 block apoptosis in these neurons, and transfection of neurons with a GSK-3beta mutant that cannot be phosphorylated interferes with the prosurvival effects of cAMP. These data suggest that activated PKA directly phosphorylates GSK-3beta and inhibits its apoptotic activity in neurons.

The permeability transition pore triggers Bax translocation to mitochondria during neuronal apoptosis.

Cerebellar granule neurons (CGNs) require depolarization for their survival in culture. When deprived of this stimulus, CGNs die via an intrinsic apoptotic cascade involving Bim induction, Bax translocation, cytochrome c release, and caspase-9 and -3 activation. Opening of the mitochondrial permeability transition pore (mPTP) is an early event during intrinsic apoptosis; however, the precise role of mPTP opening in neuronal apoptosis is presently unclear. Here, we show that mPTP opening acts as an initiating event to stimulate Bax translocation to mitochondria. A C-terminal (alpha9 helix) GFP-Bax point mutant (T182A) that constitutively localizes to mitochondria circumvents the requirement for mPTP opening and is entirely sufficient to induce CGN apoptosis. Collectively, these data indicate that the major role of mPTP opening in CGN apoptosis is to trigger Bax translocation to mitochondria, ultimately leading to cytochrome c release and caspase activation.

Myocyte enhancer factor 2A and 2D undergo phosphorylation and caspase-mediated degradation during apoptosis of rat cerebellar granule neurons.

Myocyte enhancer factor 2 (MEF2) proteins are important regulators of gene expression during the development of skeletal, cardiac, and smooth muscle. MEF2 proteins are also present in brain and recently have been implicated in neuronal survival and differentiation. In this study we examined the cellular mechanisms regulating the activity of MEF2s during apoptosis of cultured cerebellar granule neurons, an established in vitro model for studying depolarization-dependent neuronal survival. All four MEF2 isoforms (A, B, C, and D) were detected by immunoblot analysis in cerebellar granule neurons. Endogenous MEF2A and MEF2D, but not MEF2B or MEF2C, were phosphorylated with the induction of apoptosis. The putative sites that were phosphorylated during apoptosis are functionally distinct from those previously reported to enhance MEF2 transcription. The increased phosphorylation of MEF2A and MEF2D was followed by decreased DNA binding, reduced transcriptional activity, and caspase-dependent cleavage to fragments containing N-terminal DNA binding domains and C-terminal transactivation domains. Expression of the highly homologous N terminus of MEF2A (1-131 amino acids) antagonized the transcriptional activity and prosurvival effects of a constitutively active mutant of MEF2D (MEF2D-VP16). We conclude that MEF2A and MEF2D are prosurvival factors with high transcriptional activity in postmitotic cerebellar granule neurons. When these neurons are induced to undergo apoptosis by lowering extracellular potassium, MEF2A and MEF2D are phosphorylated, followed by decreased DNA binding and cleavage by a caspase-sensitive pathway to N-terminal fragments lacking the transactivation domains. The degradation of MEF2D and MEF2A and the generation of MEF2 fragments that have the potential to act as dominant-inactive transcription factors lead to apoptotic cell death.

Reduction of insulin-stimulated glucose uptake in L6 myotubes by the protein kinase inhibitor SB203580 is independent of p38MAPK activity.

Insulin increases glucose uptake through translocation of the glucose transporter GLUT4 to the plasma membrane. We previously showed that insulin activates p38MAPK, and inhibitors of p38MAPKalpha and p38MAPKbeta (e.g. SB203580) reduce insulin-stimulated glucose uptake without affecting GLUT4 translocation. This observation suggested that insulin may increase GLUT4 activity via p38alpha and/or p38beta. Here we further explore the possible participation of p38MAPK through a combination of molecular strategies. SB203580 reduced insulin stimulation of glucose uptake in L6 myotubes overexpressing an SB203580-resistant p38alpha (drug-resistant p38alpha) but barely affected phosphorylation of the p38 substrate MAPK-activated protein kinase-2. Expression of dominant-negative p38alpha or p38beta reduced p38MAPK phosphorylation by 70% but had no effect on insulin-stimulated glucose uptake. Gene silencing via isoform-specific small interfering RNAs reduced expression of p38alpha or p38beta by 60-70% without diminishing insulin-stimulated glucose uptake. SB203580 reduced photoaffinity labeling of GLUT4 by bio-LC-ATB-BMPA only in the insulin-stimulated state. Unless low levels of p38MAPK suffice to regulate glucose uptake, these results suggest that the inhibition of insulin-stimulated glucose transport by SB203580 is likely not mediated by p38MAPK. Instead, changes experienced by insulin-stimulated GLUT4 make it susceptible to inhibition by SB203580.

Degradation of insulin receptors in rat adipocytes.

Insulin receptors on viable rat adipocytes were affinity-labeled using a biologically active and photosensitive analogue of insulin, 125I-B2(2-nitro, 4 azidophenylacetyl)-des-PheB1-insulin (125I-NAPA-DP-insulin). The radiolabeled proteins were identified by SDS polyacrylamide gel electrophoresis and autoradiography. Binding of 125I-NAPA-DP-insulin (40 ng/ml) to rat adipocytes at 16 degrees C, followed by photolysis, resulted in the specific labeling of essentially one protein with an apparent molecular weight of 430-450,000 daltons. When this radiolabeled protein was treated with dithiothreitol prior to electrophoresis, specific labeling occurred predominantly in a 125,000-dalton protein and to a lesser extent in a 90,000-dalton protein. In addition, there was a minimal amount of specific labeling of a 115,000-dalton protein. Under certain experimental conditions, the nonreduced form of the photoaffinity-labeled receptor appeared as a heterogeneous population of proteins having apparent molecular weights of 430,000, 350,000, and 270,000 daltons. Subsequent to photoaffinity labeling of insulin receptors at 16 degrees C, adipocytes were incubated at 37 degrees C for various periods of time to allow for internalization. This resulted in an initial rapid loss of radioactivity in the 430,000- and 125,000-dalton bands. At 60 min the amount of radioactivity in each of these bands was approximately 50% of that present before incubation at 37 degrees C and stayed constant for 120 min. A first-order plot of the decline in receptor-associated radioactivity was biphasic with the initial phase having a half-life of 1.4 h.(ABSTRACT TRUNCATED AT 250 WORDS)

Insulin in the brain what is its role?

Insulin and insulin receptors are present in brain and appear to function outside the realm of glucose homeostasis. Insulin receptors in the brain are structurally unique and appear to be found exclusively on neurons. Evidence from a variety of experimental systems indicates that insulin plays a role in neuronal growth and differentiation; additional functions may exist in the adult brain. Insulin action in neurons may be associated with unique signal transduction pathways.

Growth arrest-specific gene 6 (Gas6)/adhesion related kinase (Ark) signaling promotes gonadotropin-releasing hormone neuronal survival via extracellular signal-regulated kinase (ERK) and Akt.

We identified Ark, the mouse homolog of the receptor tyrosine kinase Axl (Ufo, Tyro7), in a screen for novel factors involved in GnRH neuronal migration by using differential-display PCR on cell lines derived at two windows during GnRH neuronal development. Ark is expressed in Gn10 GnRH cells, developed from a tumor in the olfactory area when GnRH neurons are migrating, but not in GT1-7 cells, derived from a tumor in the forebrain when GnRH neurons are postmigratory. Since Ark (Ax1) signaling protects from programmed cell death in fibroblasts, we hypothesized that it may play an antiapoptotic role in GnRH neurons. Gn10 (Ark positive) GnRH cells were more resistant to serum withdrawal-induced apoptosis than GT1-7 (Ark negative) cells, and this effect was augmented with the addition of Gas6, the Ark (Ax1) ligand. Gas6/Ark stimulated the extracellular signal-regulated kinase, ERK, and the serine-threonine kinase, Akt, a downstream component of the phosphoinositide 3-kinase (PI3-K) pathway. To determine whether ERK or Akt activation is required for the antiapoptotic effects of Gas6/Ark in GnRH neurons, cells were serum starved in the absence or presence of Gas6, with or without inhibitors of ERK and PI3-K signaling cascades. Gas6 rescued Gn10 cells from apoptosis, and this effect was blocked by coincubation of the cells with the mitogen-activated protein/ERK kinase (MEK) inhibitor, PD98059, or wortmannin (but not rapamycin). These data support an important role for Gas6/Ark signaling via the ERK and PI3-K (via Akt) pathways in the protection of GnRH neurons from programmed cell death across neuronal migration.

Oligosaccharide heterogeneity of insulin receptors. Comparison of N-linked glycosylation of insulin receptors in adipocytes and brain.

We tested the hypothesis that the molecular weight discrepancy between insulin receptors in brain and adipocytes is due to differences in glycosylation by treating photoaffinity-labeled insulin receptors from both tissues with endo-beta-N-acetylglucosaminidase F (Endo F) and analyzing the products by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Endo F removed glycans from the adipocyte 125-kilodalton (kDa) subunit and the brain 115-kDa subunit in a manner dependent upon the concentration of enzyme and time of incubation. At a maximally effective concentration of Endo F, the adipocyte alpha-subunit was reduced from 125-kDa to 100-kDa and the brain alpha-subunit from 115-kDa to 100-kDa. We also examined the type of oligosaccharides present in both alpha-subunits by treating the proteins with endo-beta-N-acetylglucosaminidase H (Endo H), which selectively removes high mannose residues, and neuraminidase. Endo H treatment reduced the apparent molecular weight of both the adipocyte and brain alpha-subunits. In both receptors, the deglycosylated product obtained with Endo H was larger than that generated by Endo F. The adipocyte alpha-subunit demonstrated a shift in mobility on sodium dodecyl sulfate gels after neuraminidase treatment, whereas the brain alpha-subunit did not. We conclude from these studies that 1) The discrepancy in apparent molecular weight of alpha-subunits in brain and adipocytes is due to differences in N-linked glycosylation; 2) high mannose and complex type oligosaccharides are present in both receptor types; and 3) the complex oligosaccharides in the adipocyte alpha-subunit are terminated in a manner different from the complex glycans of the brain alpha-subunit.

Insulin receptors mediate growth effects in cultured fetal neurons. I. Rapid stimulation of protein synthesis.

In this study we have examined the effects of insulin on protein synthesis in cultured fetal chick neurons. Protein synthesis was monitored by measuring the incorporation of [3H]leucine (3H-leu) into trichloroacetic acid (TCA)-precipitable protein. Upon addition of 3H-leu, there was a 5-min lag before radioactivity occurred in protein. During this period cell-associated radioactivity reached equilibrium and was totally recovered in the TCA-soluble fraction. After 5 min, the incorporation of 3H-leu into protein was linear for 2 h and was inhibited (98%) by the inclusion of 10 micrograms/ml cycloheximide. After 24 h of serum deprivation, insulin increased 3H-leu incorporation into protein by approximately 2-fold. The stimulation of protein synthesis by insulin was dose dependent (ED50 = 70 pM) and seen within 30 min. Proinsulin was approximately 10-fold less potent than insulin on a molar basis in stimulating neuronal protein synthesis. Insulin had no effect on the TCA-soluble fraction of 3H-leu at any time and did not influence the uptake of [3H]aminoisobutyric acid into neurons. The isotope ratio of 3H-leu/14C-leu in the leucyl tRNA pool was the same in control and insulin-treated neurons. Analysis of newly synthesized proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that insulin uniformly increased the incorporation of 14C-leu into all of the resolved neuronal proteins. We conclude from these data that 1) insulin rapidly stimulates overall protein synthesis in fetal neurons independent of amino acid uptake and aminoacyl tRNA precursor pools; 2) stimulation of protein synthesis is mediated by the brain subtype of insulin receptor; and 3) insulin is potentially an important in vivo growth factor for fetal central nervous system neurons.

Insulin receptors mediate growth effects in cultured fetal neurons. II. Activation of a protein kinase that phosphorylates ribosomal protein S6.

As an initial attempt to identify early steps in insulin action that may be involved in the growth responses of neurons to insulin, we investigated whether insulin receptor activation increases the phosphorylation of ribosomal protein S6 in cultured fetal neurons and whether activation of a protein kinase is involved in this process. When neurons were incubated for 2 h with 32Pi, the addition of insulin (100 ng/ml) for the final 30 min increased the incorporation of 32Pi into a 32K microsomal protein. The incorporation of 32Pi into the majority of other neuronal proteins was unaltered by the 30-min exposure to insulin. Cytosolic extracts from insulin-treated neurons incubated in the presence of exogenous rat liver 40S ribosomes and [gamma-32P]ATP displayed a 3- to 8-fold increase in the phosphorylation of ribosomal protein S6 compared to extracts from untreated cells. Inclusion of cycloheximide during exposure of the neurons to insulin did not inhibit the increased cytosolic kinase activity. Activation of S6 kinase activity by insulin was dose dependent (seen at insulin concentration as low as 0.1 ng/ml) and reached a maximum after 20 min of incubation. Addition of phosphatidylserine, diolein, and Ca2+ to the in vitro kinase reaction had no effect on the phosphorylation of ribosomal protein S6. Likewise, treatment of neurons with (Bu)2cAMP did not alter the phosphorylation of ribosomal protein S6 by neuronal cytosolic extracts. We conclude that insulin activates a cytosolic protein kinase that phosphorylates ribosomal S6 in neurons and is distinct from protein kinase-C and cAMP-dependent protein kinase. Stimulation of this kinase may play a role in insulin signal transduction in neurons.

Insulin and insulin-like growth factors stimulate in vivo receptor autophosphorylation and tyrosine phosphorylation of a 70K substrate in cultured fetal chick neurons.

Insulin and insulin-like growth factors (IGFs) have been shown to regulate neuronal growth and differentiation. To investigate the possible role of tyrosine phosphorylation in the neurotrophic actions of these peptides, we examined the effects of insulin, IGF-I, and IGF-II on tyrosine phosphorylation in cultured fetal chick neurons. Tyrosine phosphorylation was detected by immunoblot analysis using antiphosphotyrosine antibodies. Under basal conditions five major phosphoproteins (170K, 140K, 115K, 103K, and 44K) and a number of minor proteins were detected by three separate antisera. In response to insulin, IGF-I, or IGF-II, an 87K membrane-associated protein (pp87) became phosphorylated on tyrosine in a rapid, dose-dependent manner. The Mr of pp87 was identical to that of the insulin and IGF-I receptor beta-subunits. Comparison of the dose-response curves for pp87 phosphorylation by insulin and IGF-I suggests that each peptide stimulated autophosphorylation of its own receptor beta-subunit. The maximal response obtained with IGF-I was approximately 10-fold higher than that obtained with insulin (3- to 5-fold), consistent with the larger number of IGF-I receptors in these cells. The maximal response obtained with IGF-II was 4- to 7-fold higher than that with insulin, suggesting that it acts through the insulin receptor as well. Tyrosine that IGF-II acts through the insulin receptor as well. Tyrosine phosphorylation of other proteins by the activated receptor kinases was not detected in neurons cultured for 5 days, however neurons cultured for only several h contained a predominant 70K protein (pp70) that was phosphorylated on tyrosine in response to all three hormones. Tyrosine phosphorylation of pp70 was maximal after 2-5 h in culture and was undetectable in neurons cultured longer than 24 h. The time course and dose dependence of pp70 phosphorylation in response to hormone paralleled that of insulin and IGF-I receptor autophosphorylation. These results demonstrate that both insulin and IGF-I receptors are active tyrosine kinases in fetal neurons, and that pp70 represents a potential endogenous substrate for the insulin and IGF-I receptor kinases. The transient phosphorylation of pp70 may be involved in the neurotrophic effects of insulin and insulin-like growth factors.

Evidence that p21ras mediates the neurotrophic effects of insulin and insulin-like growth factor I in chick forebrain neurons.

Insulin and insulin-like growth factors (IGF-I and IGF-II) support the survival and differentiation of many types of neurons, including those from fetal chick forebrain. The mechanisms by which these peptides exert their neurotrophic actions are poorly understood. The aims of this study were to determine if insulin and IGF-I activate p21ras in fetal chick forebrain neurons and if activation of p21ras mediates the neurotrophic actions of these peptides. Activation of neuronal p21ras was examined by measuring the amount of GTP bound to p21ras before and after growth factor treatment. Insulin and IGF-I increased the ratio of GTP/GTP + GDP by 31 +/- 9.0% and 36 +/- 8.0%, respectively, p21Ras activation by insulin and IGF-I was maximal within 5 min. In the presence of insulin the response was sustained out to 180 min, whereas the response to IGF-I decreased significantly by 180 min. Both peptides stimulated p21ras at low concentrations with a maximal response obtained at 10 ng/ml for each peptide, idicating that insulin and IGF-I activate ras by interacting with their homologous receptor. Pretreatment of neurons with lovastatin (2 micrograms/ml), an inhibitor of ras isoprenylation, completely blocked the activation of p21ras by insulin and IGF-I. Lovastatin also blocked the ability of these growth factors to support the survival and differentiation of fetal chick neurons in culture. We conclude that insulin and IGF-I activate p21ras in fetal chick forebrain neurons by increasing the amount of GTP bound to p21ras. The activation of neuronal p21ras is necessary for insulin and IGF-I to promote survival and differentiation in these neurons.

Protein phosphatase-1 and -2a activities in cultured fetal chick neurons: differential regulation by insulin and insulin-like growth factor-I.

In this study, we examined the developmental expression and regulation by insulin and insulin-like growth factor-I (IGF-I) of protein phosphatase-1 (PP-1) and protein phosphatase-2A (PP-2A) in cultured fetal chick neurons. Protein phosphatase activities were measured using 32P-labeled phosphorylase-a or 32P-labeled S6 kinase substrate peptide. In cell extracts from day 1-5 cultures, 40-45% of spontaneous protein phosphatase activity was due to PP-1. PP-2A accounted for the remaining 55-60% of enzyme activity. Spontaneous PP-1 activity increased by 100% in day 2 cultures and remained constant thereafter. PP-2A activity increased by 48% in day 2 cultures, with minimal increases in enzyme activity in later cultures. Under the assay conditions employed, at all times in culture a significant proportion (45-50%) of PP-1 was in an inactive form that could be reactivated by trypsin. PP-2A activity was not influenced by trypsin. Insulin stimulated neuronal PP-1 activity in day 4 and 5 cultures, but had no effect in earlier cultures. The activation of PP-1 by insulin was rapid, with a maximal effect (30-40% increase over basal levels) at 5 min with 10 ng/ml insulin. Insulin did not alter total (trypsin-released) PP-1 activity, the content of PP-1 catalytic subunit, or PP-2A activity at any time in culture. In contrast to insulin, IGF-I had no effect on PP-1 activity at any time in culture, but significantly increased PP-2A activity in day 5 cultures. Maximal stimulation of PP-2A activity by IGF-I was observed at 10 min, with an EC50 of 5 ng/ml. These results indicate that chick forebrain neurons contain both PP-1 and PP-2A activities and that neuronal PP-1 and PP-2A activities are differentially regulated by insulin and IGF-I. We conclude that although insulin and IGF-I share many steps in signal transduction, these growth factors have distinct actions on neuronal phosphatase activity that may impact on differences in their neurotropic actions.

Insulin-like growth factor binding proteins in fetal rat mesencephalic cultures: regulation by fibroblast growth factor and insulin-like growth factor I.

In rat ventral mesencephalic cultures, IGF-I and bovine fibroblast growth factor (bFGF) act cooperatively to support the survival of dopaminergic neurons. To determine the potential role of IGFBPs in modulating the actions of IGF-I in the ventral mesencephalon, we identified the IGFBPs present in ventral mesencephalic cultures and examined their regulation by IGF-I and bFGF. In the absence of added growth factors, the major binding protein secreted from these cultures was IGFBP-2. Small amounts of IGFFBP-3 and IGFBP-4 were also detected. Addition of bFGF to the cultures increased the amounts of IGFBP-3 and IGFBP-4 released from the cells by 4.4 +/- 2.6 -fold (P < 0.1) and 11.5 +/- 3.5 -fold (P < 0.05), respectively. IGF-I, itself, had little effect on the production of IGFBPs, but when added together with bFGF increased the levels of IGFBP-3 and IGFBP-4 by 12.4 +/- 5.1 -fold (P < 0.05) and 27.4 +/- 5.3 -fold (P < 0.02), respectively. The stimulatory effect of bFGF and IGF-I on IGFBP production was apparent after a 2- to 3-day exposure of the mesencephalic cultures to the peptides. IGFBP-4, the most abundant IGFBP present in the cultures after 7 days of growth factor treatment, was immunocyto-chemically localized primarily to neurons, of which a subset were dopaminergic neurons. The addition of purified rat IGFBP-4 to the cultures in the absence of added growth factors had no effect on the survival of dopaminergic neurons, but when added with IGF-I potentiated the effect of IGF-I on neuronal survival. We propose that the up-regulation of IGFBP-4 by IGF-I and bFGF may serve to localize IGF-I to sites of action in the nervous system and thereby potentiate the neurotrophic actions of IGF-I.

Peptide mapping on Northern blot analyses of insulin receptors in brain and adipocytes.

Previous studies have demonstrated differences in the size of insulin receptor subunits in brain and adipocytes that appear to involve variations in glycosylation of the proteins. In this report, we examined the degree of homology in the protein backbones of insulin receptors in both tissues by peptide mapping and compared the mRNAs encoding the receptors by Northern blot analysis. Photoaffinity-labeled insulin receptors from rat brain and adipocytes were deglycosylated and then subjected to partial proteolysis by five different enzymes with differing substrate specificities. The intact receptors and their proteolytic fragments were analyzed by electrophoresis and autoradiography. Each enzyme yielded a unique pattern of fragments ranging from 70 to 11 kDa. In all cases, there was a striking similarity in the peptide maps generated from insulin receptors in brain and adipocytes. Northern hybridization experiments were carried out using poly(A)+ RNA from rat brain, rat adipocytes, and human hepatocarcinoma (HEP G2) cells. In rat brain, two bands of 9.5 and 7.4 kb were detected and, in rat adipocytes, the same two bands were observed. The two mRNA bands observed in rat tissues represented only two of the five mRNA species seen in human HEP G2 cells. The results indicate that the protein domains and the mRNAs encoding of insulin receptors in brain and adipocytes are very similar, if not identical.

GABAA receptor function and regional analysis of subunit mRNAs in long-sleep and short-sleep mouse brain.

The greater sensitivity of long-sleep (LS), as compared with short-sleep (SS), mice to ethanol is due in part to differences in GABAA receptor function in specific brain regions. To determine if differences in subunit composition of GABAA receptors contribute to this differential sensitivity, we measured alpha 1 and gamma 2 subunit mRNAs with Northern analysis and in situ hybridization and gamma 2S, gamma 2L and alpha 6 subunit mRNAs with polymerase chain reaction (PCR) amplification. No differences in mRNAs in whole brain were apparent by Northern analysis. In situ hybridization revealed that alpha 1 and gamma 2 subunit mRNAs were co-localized in many brain regions but that they still had distinct patterns of hybridization. However, the few differences observed between LS and SS mice in the levels of hybridization for these subunits did not show a regional distribution consistent with ethanol sensitivity differences. Similar ratios of gamma 2L, and gamma 2S subunit mRNAs were found in LS and SS mouse cerebral cortex and hippocampus, and both mouse lines expressed essentially only gamma 2L subunit mRNA in cerebellum. mRNA for the alpha 6 subunit was detected only in cerebellum and also was qualitatively similar between LS and SS mice. Studies of muscimol-stimulated 36Cl- uptake by cortical membrane vesicles confirmed earlier findings that ethanol does not enhance function of GABAA receptors in SS mice when assayed at 30 degrees C. However, at 34 degrees C ethanol did increase this function in SS mice although the enhancement remained greater in LS mice. These functional results, together with the results showing similar levels of alpha 1, gamma 2S, gamma 2L and alpha 6 subunits in LS and SS mice, suggest that the ethanol-insensitivity of SS mouse GABAA receptors cannot be due solely to lack of subunits required for ethanol action and further suggest that differences in catalytic mechanisms affecting post-translational processing may account for some genetic differences in ethanol sensitivity of GABAA receptors.

Insulin and IGF-I receptor signaling in cultured neurons.

The data presented in this chapter are summarized in the schematic shown in Figure 9. Insulin binds to and stimulates autophosphorylation of neuronal insulin receptors, whereas, IGF-I and IGF-II binds to and stimulate autophosphorylation of neuronal IGF-I receptors. IGF-II is also capable of binding to the insulin receptor. Whether or not it activates the insulin receptor kinase remains to be clarified. Activated insulin and IGF-I receptor kinases phosphorylate a 70-kDa protein at early times in culture. This protein may mediate some actions of insulin, but we speculate that there are other intermediary proteins involved in the transduction pathway resulting in the activation of S6 kinase and PKC epsilon. The stimulation of S6 kinase by insulin and IGF-I may be associated with the translational activation of protein synthesis by these peptides. The stimulation of PKC epsilon appears to be a necessary step in the transcriptional regulation of the c-fos gene by insulin and IGF-I. The regulation of neuronal protein synthesis at a translational step and the initiation of transcriptional programs regulated by AP-1 represent two mechanisms by which insulin and IGFs alter neuronal growth and differentiation.

In vitro studies on the action of CS-045, a new antidiabetic agent.

The mechanism of action of CS-045, a new orally active antidiabetic agent, was studied in vitro using cultured hepatoma cells (Hep G2) and muscle cells (BC3H-1). Treatment of both types of cultured cells with varying doses of CS-045 did not significantly alter insulin receptor binding. Basal and insulin-stimulated glucose transport in BC3H-1 cells was also unaltered by the drug. In contrast, CS-045 increased glycogen synthase I activity in both cell types. This effect was maximal after 24 hours and in Hep G2 cells was associated with a threefold increase in the apparent affinity of the enzyme for glucose-6-phosphate. Gluconeogenesis from lactate in Hep G2 cells was greatly reduced by CS-045 treatment. We conclude that CS-045 may act directly on muscle and liver cells to increase glucose utilization. It is also effective in reducing glucose production. These multiple effects may account in part for the ability of CS-045 to reduce blood sugar levels in vivo.

Evidence for a subtype of insulin-like growth factor I receptor in brain.

We examined the structure of receptors for insulin-like growth factor I (IGF-I), insulin, and epidermal growth factor (EGF) in human brain and human placenta using affinity cross-linking procedures and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In human brain, proteins specifically cross-linked to 125I-IGF-I, 125I-insulin, and 125I-EGF had apparent molecular weights of 120,000, 115,000 and 170,000, respectively. In human placenta, proteins cross-linked to 125I-IGF-I and 125I-insulin were 10 kDa larger than the corresponding subunits in brain. The receptor labeled by 125I-EGF in placenta was indistinguishable from the EGF receptor in brain. The size discrepancy of IGF-I receptors in brain and placenta was no longer apparent after removing the carbohydrate moieties of the proteins with endo-beta-N-acetylglucosaminidase F (EndoF). Furthermore, the brain IGF-I receptor was not cleaved by neuraminidase, whereas, the placental IGF-I receptor had increased mobility on SDS gels following neuraminidase treatment. The results indicate that receptors for IGF-I and insulin in human brain are structurally distinct from the corresponding receptors in human placenta, the structural heterogeneity of the receptors involves differences in N-linked glycosylation, particularly the terminal processing steps, and EGF receptors are present in human brain and human placenta but are structurally similar in these tissues. We conclude that there is a selective modification in the glycosylation of receptors for IGF-I and insulin in brain.

Inhibitors of p38 MAP kinase increase the survival of transplanted dopamine neurons.

Fetal cell transplantation therapies are being developed for the treatment of a number of neurodegenerative disorders including Parkinson's disease [10-12,21,22,24,36,43]. Massive apoptotic cell death is a major limiting factor for the success of neurotransplantation. We have explored a novel protein kinase pathway for its role in apoptosis of dopamine neurons. We have discovered that inhibitors of p38 MAP kinase (the pyridinyl imidazole compounds: PD169316, SB203580, and SB202190) improve survival of rat dopamine neurons in vitro and after transplantation into hemiparkinsonian rats. In embryonic rat ventral mesencephalic cultures, serum withdrawal led to 80% loss of dopamine neurons due to increased apoptosis. Incubation of the cultures with p38 MAP kinase inhibitors at the time of serum withdrawal prevented dopaminergic cell death by inhibiting apoptosis. In the hemiparkinsonian rat, preincubation of ventral mesencephalic tissue with PD169316 prior to transplantation accelerated behavioral recovery and doubled the survival of transplanted dopamine neurons. We conclude that inhibitors of stress-activated protein kinases improve the outcome of cell transplantation by preventing apoptosis of neurons after grafting.