Mechanisms of beta-cell death in response to double-stranded (ds) RNA and interferon-gamma: dsRNA-dependent protein kinase apoptosis and nitric oxide-dependent necrosis.

Viral infection is one environmental factor that has been implicated as a precipitating event that may initiate beta-cell damage during the development of diabetes. This study examines the mechanisms by which the viral replicative intermediate, double-stranded (ds) RNA impairs beta-cell function and induces beta-cell death. The synthetic dsRNA molecule polyinosinic-polycytidylic acid (poly IC) stimulates beta-cell DNA damage and apoptosis without impairing islet secretory function. In contrast, the combination of poly IC and interferon (IFN)-gamma stimulates DNA damage, apoptosis, and necrosis of islet cells, and this damage is associated with the inhibition of glucose-stimulated insulin secretion. Nitric oxide mediates the inhibitory and destructive actions of poly IC + IFN-gamma on insulin secretion and islet cell necrosis. Inhibitors of nitric oxide synthase, aminoguanidine, and N(G)-monomethyl-L-arginine, attenuate poly IC + IFN-gamma-induced DNA damage to levels observed in response to poly IC alone, prevent islet cell necrosis, and prevent the inhibitory actions on glucose-stimulated insulin secretion. N(G)-monomethyl-L-arginine fails to prevent poly IC- and poly IC + IFN-gamma-induced islet cell apoptosis. PKR, the dsRNA-dependent protein kinase that mediates the antiviral response in infected cells, is required for poly IC- and poly IC + IFN-gamma-induced islet cell apoptosis, but not nitric oxide-mediated islet cell necrosis. Alone, poly IC fails to stimulate DNA damage in islets isolated from PKR-deficient mice; however, nitric oxide-dependent DNA damage induced by the combination of poly IC + IFN-gamma is not attenuated by the genetic absence of PKR. These findings indicate that dsRNA stimulates PKR-dependent islet cell apoptosis, an event that is associated with normal islet secretory function. In contrast, poly IC + IFN-gamma-induced inhibition of glucose-stimulated insulin secretion and islet cell necrosis are events that are mediated by islet production of nitric oxide. These findings suggest that at least one IFN-gamma-induced antiviral response (islet cell necrosis) is mediated through a PKR-independent pathway.

Double-stranded RNA-dependent protein kinase is not required for double-stranded RNA-induced nitric oxide synthase expression or nuclear factor-kappaB activation by islets.

Environmental factors, such as viral infection, have been implicated in the destruction of beta-cells during the development of autoimmune diabetes. Double-stranded RNA (dsRNA), produced during viral replication, is an active component of a viral infection that stimulates antiviral responses in infected cells. Previous studies have shown that treatment of rat islets with dsRNA in combination with gamma-interferon (IFN-gamma) results in a nitric oxide-dependent inhibition of glucose-stimulated insulin secretion. This study examines the role of nuclear factor-kappaB (NF-kappaB) and the dsRNA-dependent protein kinase (PKR) in dsRNA + IFN-gamma-induced nitric oxide synthase (iNOS) expression and nitric oxide production by rat, mouse, and human islets. Treatment of rat and human islets with dsRNA in the form of polyinosinic-polycytidylic acid (poly IC) and IFN-gamma resulted in iNOS expression and nitric oxide production. Inhibitors of NF-kappaB activation-the proteasome inhibitor MG-132 and the antioxidant pyrrolidine-dithiocarbamate (PDTC)-prevented poly IC + IFN-gamma-induced iNOS expression and nitric oxide production. Incubation of rat islets for 3 h or human islets for 2 h with poly IC alone or poly IC + IFN-gamma resulted in NF-kappaB nuclear translocation and degradation of the NF-kappaB inhibitor protein, IkappaB, events that are prevented by MG-132. PKR has been shown to participate in dsRNA-induced NF-kappaB activation in a number of cell types, including mouse embryonic fibroblasts. However, poly IC stimulated NF-kappaB nuclear translocation and IkappaB degradation to similar levels in islets isolated from mice devoid of PKR (PKR-/-) and wild-type mice (PKR+/+). Furthermore, the genetic absence of PKR did not affect dsRNA + IFN-gamma-induced iNOS expression, nitric oxide production, or the inhibitory actions of these agents on glucose-stimulated insulin secretion. These results suggest that 1) NF-KB activation is required for dsRNA + IFN-gamma-induced iNOS expression, 2) PKR is not required for either dsRNA-induced NF-kappaB activation or dsRNA + IFN-y-induced iNOS expression by islets, and 3) PKR is not required for dsRNA + IFN-gamma-induced inhibition of glucose-stimulated insulin secretion by islets.

Potentiation of neuronal L calcium channels by IGF-1 requires phosphorylation of the alpha1 subunit on a specific tyrosine residue.

Insulin-like growth factor 1 (IGF-1) rapidly potentiates N and L calcium channel currents in cerebellar granule neurons by an unknown mechanism. Here, we show that the L channel alpha1C subunit is tyrosine phosphorylated in response to IGF-1. Moreover, expression of kinase-dead c-Src in neurons or acute block of Src family kinases with a cell-permeable inhibitor specifically blocks L channel potentiation. Purified Src kinase phosphorylates tyrosine residue Y2122 of the C terminus of neuronal alpha1C in vitro, and c- and v-Src directly bind the C terminus. When expressed in neuroblastoma cells, point mutation of Y2122 prevents both tyrosine phosphorylation of alpha1C and IGF-1 potentiation. Our data provide a biochemical mechanism whereby phosphorylation of a single specific tyrosine residue rapidly modifies ion channel physiology.

Akt-dependent potentiation of L channels by insulin-like growth factor-1 is required for neuronal survival.

The insulin-like growth factor-1 (IGF-1)/receptor tyrosine kinase recently has been shown to mediate neuronal survival and potentiate the activity of specific calcium channel subtypes; survival requires Akt, a serine/threonine kinase. We demonstrate here that Akt mediates the IGF-1-induced potentiation of L channel currents, but not that of N channels. Transient expression of wild-type, dominant-negative, and constitutively active forms of Akt in cerebellar granule neurons causes, respectively, no change in IGF-1/L channel potentiation, complete inhibition of potentiation, and a dramatic increase in basal L currents accompanied by the loss of ability to induce further increases. In no case is the IGF-1 potentiation of N currents affected. We additionally find that IGF-1 partially mediates granule neuron survival via L channel activity and that Akt-dependent L channel modulation is a necessary component. Interestingly, very brief exposure (1 min) to IGF-1 triggers nearly complete survival and requires L channel activity. These results strongly suggest that neuronal receptor tyrosine kinases can control long-term calcium-dependent processes via the rapid control of voltage-sensitive channels.

SAP90 binds and clusters kainate receptors causing incomplete desensitization.

The mechanism of kainate receptor targeting and clustering is still unresolved. Here, we demonstrate that members of the SAP90/PSD-95 family colocalize and associate with kainate receptors. SAP90 and SAP102 coimmunoprecipitate with both KA2 and GluR6, but only SAP97 coimmunoprecipitates with GluR6. Similar to NMDA receptors, GluR6 clustering is mediated by the interaction of its C-terminal amino acid sequence, ETMA, with the PDZ1 domain of SAP90. In contrast, the KA2 C-terminal region binds to, and is clustered by, the SH3 and GK domains of SAP90. Finally, we show that SAP90 coexpressed with GluR6 or GluR6/KA2 receptors alters receptor function by reducing desensitization. These studies suggest that the organization and electrophysiological properties of synaptic kainate receptors are modified by association with members of the SAP90/PSD-95 family.

IGF-1 modulates N and L calcium channels in a PI 3-kinase-dependent manner.

Receptor tyrosine kinases (RTKs) have long been associated with proliferation in non-neural cells, although they are also expressed in postmitotic neurons. We demonstrate that insulin-like growth factor-1 (IGF-1) induces within seconds a large, tyrosine-kinase-dependent increase in calcium channel currents in cerebellar granule neurons. Separation of channel subtypes reveals that, while P, Q, and R channels are unaffected, N and L channel activities are strongly potentiated at specific membrane voltages: N currents triple at depolarized potentials, while L currents rapidly increase 4-fold at hyperpolarized potentials. Moreover, transient expression of dominant-negative and wild-type phosphatidylinositol 3-OH kinase (PI 3-kinase) subunits, as well as application of specific inhibitors, demonstrates that PI 3-kinase is an essential and rate-limiting messenger in this signaling pathway. Our results indicate that N and L calcium channels are downstream targets of neuronal RTKs and suggest that RTK modulation may control calcium-dependent processes, such as neurotransmitter release and IGF-1-dependent differentiation or survival.

Insulin-like growth factor-I induces a rapid increase in calcium currents and spontaneous membrane activity in clonal pituitary cells.

The role of growth factors in the adult brain is largely unknown, although receptors for factors such as insulin-like growth factor-I (IGF-I) have been localized on nondividing mature neurons. Because neurons use the frequency and pattern of action potentials to encode information, we assessed the ability of IGF-I to modulate rapidly the electrical properties of GH4C1 cells, a spontaneously active pituitary line with neuronal L- and T-type calcium currents. Electrical quiescence (the absence of spontaneous activity) was induced by culture in serum-depleted conditions. IGF-I, which is synthesized locally in mammalian brain, induced a rapid increase in electrical activity that was accompanied by increased activation of calcium channel currents. These effects were dose and time dependent. The spontaneous activity of cells exposed to 20 ng/ml IGF-I increased in approximately 10 sec and, after a brief exposure, continued increasing for at least 8 hr. Currents carried by calcium channels doubled within 10 sec. Both the increase in spontaneous activity and the increased activation of calcium channel currents were blocked by tyrosine kinase inhibitors. These results suggest that IGF-I can act as a rapid neuromodulator of calcium currents.

Biophysical and pharmacological properties of cloned GABAA receptor subunits expressed in Xenopus oocytes.

Biochemical and immunological studies indicate that the GABAA receptor contains at least two types of subunit. Here we report that coexpression of two GABAA receptor subunit clones (alpha and beta) in Xenopus oocytes yields receptors with many biophysical properties of native GABAA receptors. These include ion selectivity, multiple single-channel conductance states, voltage-dependent gating and rectification, and complex desensitization kinetics. Furthermore, the receptors are competitively inhibited by bicuculline and display the expected allosteric and agonist effects of the barbiturate pentobarbital. The expressed receptors, however, appear to be activated by one molecule of GABA instead of two and fail to show potentiation by benzodiazepines. This implies that an additional factor(s) or subunit(s) is required for the reconstitution of a fully functional GABAA receptor.

Single subunits of the GABAA receptor form ion channels with properties of the native receptor.

The alpha and beta subunits of the gamma-aminobutyric acidA (GABAA) receptor were expressed individually in Xenopus oocytes by injection of RNA synthesized from their cloned DNAs. GABA-sensitive chloride channels were detected several days after injection with any one of three different alpha RNAs (alpha 1, alpha 2, and alpha 3) or with beta RNA. The channels induced by each of the alpha-subunit RNAs were indistinguishable, they had multiple conductance levels (10, 19, 28, and 42 picosiemens), and their activity was potentiated by pentobarbital and inhibited by picrotoxin. The beta channels usually expressed poorly but showed similar single channel conductance levels (10, 18, 27, and 40 picosiemens), potentiation by pentobarbital and inhibition by picrotoxin. The finding that both alpha and beta subunits, examined separately, form GABA-sensitive ion channels with permeation properties and regulatory sites characteristic of the native receptor suggests that the amino acid sequences that confer these properties are within the homologous domains shared by the subunits.

The mas oncogene encodes an angiotensin receptor.

The class of receptors coupled to GTP-binding proteins share a conserved structural motif which is described as a 'seven-transmembrane segment' following the prediction that these hydrophobic segments form membrane-spanning alpha-helices. Identified examples include the mammalian opsins, alpha 1-, alpha 2-, beta 1- and beta 2-adrenergic receptors, the muscarinic receptor family, the 5-HT1C-receptor, and the substance-K receptor. In addition, two mammalian genes have been identified that code for predicted gene products with sequence similarity to these receptors, but whose ligand specificity is unknown namely, G21 and the mas oncogene. The mas oncogene shows the greatest sequence similarity to the substance-K receptor, and on this basis it was predicted that it would encode a peptide receptor with mitogenic activity which would act through the inositol lipid signalling pathways. The mas oncogene product was transiently expressed in Xenopus oocytes, and stably expressed in a transfected mammalian cell line. The results demonstrate that the mas gene product is a functional angiotensin receptor.

Differentiation of a clone isolated from the HT29 cell line: polarized distribution of histocompatibility antigens (HLA) and of transferrin receptors.

The HT29 cell line, derived from a human colon adenocarcinoma, is able to differentiate if galactose replaces glucose in the culture medium. We have isolated a clone (HT29-18) from this cell line which displays differentiated properties of the parent cell line. HT29-18 cells grown in glucose-containing medium form multiple layers of round cells without specific cell-cell adhesion. In contrast, when grown in galactose-containing medium, they form a monolayer with tight junctions and exhibit a well differentiated brush border at their apical membrane, which faces the culture medium. The polarized properties of HT29-18 cells grown in galactose-containing medium were demonstrated by immunofluorescent techniques with antibodies against 2 plasma membrane proteins. Class I histocompatibility antigens (HLA) and transferrin receptors, 2 well characterized integral membrane proteins, are uniformly distributed on the cell surface of undifferentiated HT29-18 cells, but acquire a polarized distribution during differentiation, localized on the basolateral membranes and absent from the apical surface. Binding of 125I-labeled transferrin was used to determine transferrin receptor distribution on apical and basolateral membranes. Functional tight junctions in the differentiated cultures were demonstrated, as the monolayer was impermeable to a permeation dye (ruthenium red) as well as to antibodies. The sealing of these tight junctions is, as in vivo, Ca++-dependent as they could be opened by a short incubation in Ca++-free medium.

Developmental acquisition of Ca2+-sensitivity by K+ channels in spinal neurones.

A developmental change in the ionic basis of the inward current of action potentials has been observed in many excitable cells. In cultured spinal neurones of Xenopus, the timing of the development of the action parallels that seen in vivo. In vitro, as in vivo, neurones initially produce action potentials of long duration which are principally Ca-dependent; after 1 day of development the impulse is brief and primarily Na-dependent. At both ages, however, both inward components are present and the mechanism underlying shortening of the action potential is unknown. One possibility is that the outward currents change during development. Using the patch-clamp technique, we have recorded single K+-channel currents in membrane patches isolated from the cell bodies of cultured embryonic neurones. The unitary conductance of one class of K+ channels was approximately 155 pS and depolarization increased the probability of a channel being open. Neither conductance nor voltage dependence seemed to change with time in culture; in contrast, the Ca2+-sensitivity of this K+ channel increased. In younger neurones, Ca2+-sensitivity was greatly reduced or absent, whereas in more mature neurones, the activity of this channel was Ca-dependent. Such a change could account for the shortening of the action potential duration by increasing the relative contribution of outward currents.

The timing of protein synthesis required for the development of the sodium action potential in embryonic spinal neurons.

Embryonic amphibian neurons grown in dissociated cell culture extend neurites and can produce action potentials. The ionic dependence of the inward current of the action potential gradually changes from primarily calcium to primarily sodium. Early exposure of these neurons to protein synthesis inhibitors (cycloheximide, puromycin) blocked the appearance of neurites; later exposure blocked the normal change in the ionic basis of the action potential. These drugs apparently arrested the development of the sodium component of the action potential and, additionally, may have blocked a reduction in the calcium component. Inhibitor applied at still later times did not prevent the normal development of these traits. The development of voltage-sensitive delayed rectification was unaffected by the addition of inhibitor at any of the times tested.