Retrograde axonal transport of the alpha-subunit of the GTP-binding protein GZ in mouse sciatic nerve: a potential pathway for signal transduction in neurons

Gz proteins are functionally coupled to dopamine D2-like receptors in vivo

The receptors that couple to the G protein Gz in vivo are still relatively unknown. In this study, we investigated the effects of various dopamine receptor agonists in a mouse deficient in the alpha subunit of Gz. The dopamine D1-like receptor agonist SKF38393 stimulated comparable locomotor activity in both wildtype mice and mice lacking Galphaz. In contrast, the dopamine D2-like receptor agonist quinpirole suppressed locomotor activity in both groups of mice, but this suppression was significantly smaller in Galphaz knockout mice. Consistent with these behavioural observations, quinpirole inhibition of dopamine release in the forebrain nucleus accumbens evoked by electrical stimulation of dopamine axons was significantly attenuated in mice lacking Galphaz. In addition, hypothermia and adrenocorticotropic hormone release resulting from activation of dopamine D2-like receptors were also significantly reduced in Galphaz knockout mice. However, adrenocorticotropic hormone secretion induced by corticotrophin releasing hormone and the serotonin 1A receptor agonist 8-hydroxy-dipropylamino-tetralin were similar between wildtype and Galphaz knockout mice. Western blot analysis showed that the expression levels of Galphai, Galphao, Galphas, Galphaq and Gbeta were the same in the brains of mice of both genotypes. Overall, our data suggest that Gz proteins are functionally coupled to dopamine D2-like receptors in vivo.

Enhanced serotonin response in the hippocampus of Galphaz protein knock-out mice

The serotonin-1A [5-hydroxytryptamine 1A (5HT1A)] receptor is important for emotional and homeostatic processes in the central nervous system. In the hippocampus, the 5HT1A receptor couples to inhibitory Gi/o proteins to decrease pyramidal cell excitability. Here we investigate the 5HT1A receptor in a mouse deficient in the alpha-subunit of Gz protein (Galphaz knock-out). Behavioural tests showed heightened anxiety and depression-like behaviour in the Galphaz knock-out mice. Whole-cell recording in CA1 pyramidal neurons showed a significantly greater 5HT1A receptor-mediated potassium current in Galphaz knock-out mice. The effect was independent of 5HT4 receptors as the slow after-hyperpolarization was unaffected and a slow depolarization was absent in the Galphaz knock-out mice. Other receptors linked to Gi/o proteins [gamma-aminobutyric acid type B receptor (GABAB), adenosine A1 and muscarinic acetylcholine receptors] were not affected in Galphaz knock-out mice. These results suggest that the 5HT1A receptor may be linked to Galphaz protein, as reported previously in cell culture but shown here in an intact neural network.

Growth and neurotrophic factors regulating development and maintenance of sympathetic preganglionic neurons

The functional anatomy of sympathetic preganglionic neurons is described at molecular, cellular, and system levels. Preganglionic sympathetic neurons located in the intermediolateral column of the spinal cord connect the central nervous system with peripheral sympathetic ganglia and chromaffin cells inside and outside the adrenal gland. Current knowledge is reviewed of the development of these neurons, which share their origin with progenitor cells, giving rise to somatic motoneurons in the ventral horn. Their connectivities, transmitters involved, and growth factor receptors are described. Finally, we review the distribution and functions of trophic molecules that may have relevance for development and maintenance of preganglionic sympathetic neurons.

Fibroblast growth factor-5 is expressed in Schwann cells and is not essential for motoneurone survival

Fibroblast growth factor-5 (FGF-5) is a putative target-derived survival factor for motoneurones as it is concentrated in the synaptic portions of skeletal muscles and because it promotes the survival of embryonic motoneurones in vitro. A variety of experimental approaches have been used to examine this possibility. The expression of FGF-5 in the neuromuscular system was analysed using the reverse transcription-polymerase chain reaction (RT-PCR). Both splice variants of FGF-5 were detected in adult rat skeletal muscle, sciatic nerve, and spinal cord. The expression of FGF-5 in skeletal muscle was up-regulated after denervation. At first sight this appears to be consistent with FGF-5 being a target-derived factor. However, FGF-5 protein was detected in Schwann cells, macrophages, vascular smooth muscle and endothelial cells, but not in muscle fibres. The absence of FGF-5 in muscle fibres was confirmed by RT-PCR examination of isolated muscle fibres. Furthermore, FGF-5 protein was also not detected in denervated fibres, as would be expected for a neuronal survival factor. Denervation did however lead to up-regulation of FGF-5 in the Schwann cells of the distal nerve trunk. This may indicate that FGF-5 is either an autocrine regulator of Schwann cells or a Schwann cell-derived neurotrophic factor. The latter appears not to be the case for two reasons. First, the double-ligation technique was used to show that endogenous FGF-5 is not transported in motor axons. Second, stereological estimates of the number of motoneurones in an FGF-5 null mutant (Angora) mouse failed to reveal any loss of motoneurones. Collectively these experiments suggest that FGF-5 is not a physiological regulator of motoneurones, and therefore raise the possibility that it is an autocrine regulator of Schwann cells.

G(z) signaling: emerging divergence from G(i) signaling

A large variety of neurotransmitters, hormones, and chemokines regulate cellular functions via cell surface receptors that are coupled to guanine nucleotide-binding regulatory proteins (G proteins) belonging to the G(i) subfamily. All members of the G(i) subfamily, with the sole exception of G(z), are substrates for the pertussis toxin ADP-ribosyl transferase. G(z) also exhibits unique biochemical and regulatory properties. Initial portrayals of the cellular functions of G(z) bear high resemblance to those of other G(i) proteins both in terms of the receptors and effectors linked to G(z). However, recent discoveries have begun to insinuate a distinct role for G(z) in cellular communication. Functional interactions of the alpha subunit of G(z) (Galpha(z)) with the NKR-P1 receptor, Galpha(z)-specific regulator of G protein signaling, p21-activated kinase, G protein-regulated inducers of neurite outgrowth, and the Eya2 transcription cofactor have been demonstrated. These findings provide possible links for G(z) to participate in cellular development, survival, proliferation, differentiation and even apoptosis. In this review, we have drawn a sketch of a signaling network with G(z) as the centerpiece. The emerging picture is one that distinguishes G(z) from other members of the G(i) subfamily.

Transforming growth factor-beta 2 is anterogradely and retrogradely transported in motoneurons and up-regulated after nerve injury

The survival of motoneurons is dependent on them receiving continual trophic support from muscle fibres and various other cell types. Numerous putative survival factors have been identified and a set of criteria established by which these candidates can be assessed. These criteria include the need for the factor and its receptors to be in appropriate locations and for the factor or its second message to be retrogradely transported. In this paper, we demonstrate that a multifunctional cytokine, transforming growth factor-beta 2, appears to meet these criteria. The locations of the transforming growth factor-beta 2 and its receptors in the neuromuscular system were determined by reverse transcriptase-polymerase chain reaction and immunohistochemistry. Motoneurons were shown to synthesize the three proteins involved in transforming growth factor-beta 2 signalling (types I and II transforming growth factor-beta receptor and betaglycan) and to transport them anterogradely, where they were inserted into the axonal membrane and nerve terminal. Transforming growth factor-beta 2 was detected in the synaptic portions of muscle fibres, motoneurons and in injured nerves, indicating that motoneurons may be exposed to multiple and potentially redundant sources of transforming growth factor-beta 2. Double-ligation experiments were used to demonstrate that motoneurons transport transforming growth factor-beta 2 up and down their axons. The anterograde transport of both transforming growth factor-beta 2 and its receptors, coupled with the fact that most of a motoneuron's mitochondria are located in the axon, raises the issue of whether the repression of the initiation of apoptosis is restricted to the cell body or occurs along the entire length of a neuron.

Myr+-Gi2 alpha and Go alpha subunits restore the efficacy of opioids, clonidine and neurotensin giving rise to antinociception in G-protein knock-down mice

In mice whose Gi/o-protein function had been impaired by antisense 'knock-down' or pertussis toxin treatment, i.c.v. injection of myr+-Gi/o alpha subunits restored the effectiveness of beta-endorphin, morphine, DPDPE, clonidine and neurotensin to produce antinociception. Myr+-G alpha subunits of the class of G-proteins actually impaired were more effective than unlike but related myr+-G alpha subunits. Selectivity was noted in that only exogenous myr+-G alpha subunits affected (enhanced) the activity of agonists in G alpha-deficient signalling systems. This treatment had little effect on agonist potency when the impairment resided at the receptor level. The potential of the opioids, clonidine and R-PIA to increase G alpha-related in vitro hydrolysis of GTP was also re-established after injecting myr+-Gi2 alpha subunits into Gi2-knocked-down mice. Myr+-Gi2 alpha subunits pre-incubated with GTPgammaS or GDPbetaS before i.c.v. injection did not improve the activity of agonists in vivo (antinociception) or in vitro (regulation of low Km GTPase). After impairing the function of PKCbeta1 by antisense treatment or with the inhibitor H7, the effect of myr+-G alpha subunits on agonist potency was prevented. Electron microscope analysis showed the entry of gold-conjugated myr+-G alpha subunits into neural cells. These particles were found in the cytoplasm, associated with the plasma membranes of different neuronal processes and also in synaptic junctions. In cultured neurons and astrocytes myr+-Gi2 alpha-associated fluorescence was internalised in a dose-dependent manner and distributed in the plasma membrane and cytosol, as well as in nuclei of dividing astrocytes. Thus, G alpha subunits in CSF enter into neurons and functionally couple to the receptor-triggered signalling cascade. As G-proteins have been implicated in the pathophysiology of several neural disorders, this finding may be valuable in the therapy of such dysfunctions.

Transport of CSF antibodies to Galpha subunits across neural membranes requires binding to the target protein and protein kinase C activity

In the light of functional studies, it has been suggested that antibodies directed to alpha subunits of G-proteins delivered into cerebrospinal fluid (CSF) reached and blocked the function of neural transducer proteins. Current understanding indicates that IgGs do not move freely across plasma membranes. Therefore, to characterize the uptake of these antibodies by neural cells, anti-Gi2alpha IgGs were labeled with 125I, fluorescein or with gold particles. The expression of Galpha subunits was also reduced by blocking their mRNA with antisense oligodeoxynucleotides (ODN). Following intracerebroventricular (icv) injection of gold-conjugated anti-Gi2alpha IgGs, electrondense particles entered and became distributed in the cytoplasm and plasma membranes of neural cells. Scattered particles were also found in dendrites and nuclei. Unlabeled IgGs diminished cerebral signals of fluorescein-labeled anti-Galpha IgGs, indicating that this uptake can be saturated. Cerebral radiostaining promoted by in vivo anti-Gi2alpha 125I-IgGs was almost absent in Gi2alpha knocked-down mice, but not after decreasing the quantity of Gzalpha subunits. The immunosignals of CSF anti-Galpha 125I-IgGs, as well as the impairment of opioid-evoked antinociception, were increased by agonist-induced activation of G protein-coupled receptors. The impairing effect of the antibodies on opioid-evoked antinociception was prevented by agents blocking the cellular uptake of proteins, i.e., cytochalasin B, BSA, DMSO, H7, and by down regulation of protein kinase Cbeta1 (PKCbeta1). In mice treated with an ODN to PKCbeta1 mRNA, 125I-IgGs to Gi2alpha subunits remained bound to periventricular structures and did not spread to deeper areas of the CNS. These results indicate that IgGs delivered into the CSF show a saturable binding to Galpha subunits that translocate to the external side of the neural membrane before being internalized by a PKCbeta1-dependent mechanism.

Inducible and constitutive transcription factors in the mammalian nervous system: control of gene expression by Jun, Fos and Krox, and CREB/ATF proteins

This article reviews findings up to the end of 1997 about the inducible transcription factors (ITFs) c-Jun, JunB, JunD, c-Fos, FosB, Fra-1, Fra-2, Krox-20 (Egr-2) and Krox-24 (NGFI-A, Egr-1, Zif268); and the constitutive transcription factors (CTFs) CREB, CREM, ATF-2 and SRF as they pertain to gene expression in the mammalian nervous system. In the first part we consider basic facts about the expression and activity of these transcription factors: the organization of the encoding genes and their promoters, the second messenger cascades converging on their regulatory promoter sites, the control of their transcription, the binding to dimeric partners and to specific DNA sequences, their trans-activation potential, and their posttranslational modifications. In the second part we describe the expression and possible roles of these transcription factors in neural tissue: in the quiescent brain, during pre- and postnatal development, following sensory stimulation, nerve transection (axotomy), neurodegeneration and apoptosis, hypoxia-ischemia, generalized and limbic seizures, long-term potentiation and learning, drug dependence and withdrawal, and following stimulation by neurotransmitters, hormones and neurotrophins. We also describe their expression and possible roles in glial cells. Finally, we discuss the relevance of their expression for nervous system functioning under normal and patho-physiological conditions.

Developmental expression of messenger RNA levels of the alpha subunit of the GTP-binding protein, Gz, in the mouse nervous system

There has been recent evidence that Gz may play a role in the transmission of the neurotrophic signal from nerve terminals to the cell bodies [Johanson, S.O., Crouch, M.F., Hendry, I.A., Signal transduction from membrane to nucleus: the special case for neurons, Neurochem. Res. 21 (1996) 779-785]. We examined the developmental expression of the alpha subunit of Gz (Gzalpha) in the peripheral and central nervous systems of the mouse. Our laboratory has developed a quantitative reverse transcription-polymerase chain reaction (RT-PCR) for Gzalpha which makes use of a fragment of the PCR product shortened by 107 base pairs creating a standard which mimics the original RNA. Serial dilutions of the mouse RNA with a constant concentration of mimic RNA were made and the point where equal amounts of product are formed allows accurate measurement of Gzalpha mRNA in the tissue. We have demonstrated that in the developing mouse superior cervical ganglion (SCG), dorsal root ganglion (DRG) and trigeminal ganglion the expression of Gzalpha mRNA is highest perinatally. From 3 weeks of age, in all tissues with the exception of the SCG, Gzalpha mRNA levels fall to lower levels in the adult animal. The developmental pattern of expression of Gzalpha in both the cerebellum and the brain differs from the peripheral nervous system. In the cerebellum, Gzalpha mRNA expression is highest around birth and in the brain it is highest around third postnatal week and then the levels decline as adulthood is approached. These results suggest that the highest level of Gzalpha mRNA is expressed at the time when target tissue innervation is occurring. This further strengthens the hypothesis that Gzalpha is important in the transfer of information from target tissues to the innervating nerve cells.

A signaling organelle containing the nerve growth factor-activated receptor tyrosine kinase, TrkA

The topology of signal transduction is particularly important for neurons. Neurotrophic factors such as nerve growth factor (NGF) interact with receptors at distal axons and a signal is transduced by retrograde transport to the cell body to ensure survival of the neuron. We have discovered an organelle that may account for the retrograde transport of the neurotrophin signal. This organelle is derived from endocytosis of the receptor tyrosine kinase for NGF, TrkA. In vitro reactions containing semi-intact PC12 cells and ATP were used to enhance recovery of a novel organelle: small vesicles containing internalized NGF bound to activated TrkA. These vesicles were distinct from clathrin coated vesicles, uncoated primary endocytic vesicles, and synaptic vesicles, and resembled transport vesicles in their sedimentation velocity. They contained 10% of the total bound NGF and almost one-third of the total tyrosine phosphorylated TrkA. These small vesicles are compelling candidates for the organelles through which the neurotrophin signal is conveyed down the axon.

Identifying the G protein, Gz alpha, and its associated proteins in nervous tissue using mass spectrometry and microsequencing techniques

The signaling pathway associated with pertussis and cholera toxin sensitive G proteins have been extensively investigated. In contrast, the function and associated signal transduction cascade for the pertussis toxin insensitive G protein, Gz alpha have remained elusive. Therefore, the aim of this study was to identify the signal transduction pathway associated with Gz alpha by using the protein identification techniques of matrix assisted laser desorption ionization-time of flight mass spectroscopy and N-terminal Edman sequencing. We have chosen this technique to identify proteins that Gz alpha associates with and to gain insights into the potential role this G protein plays in cells. As Gz alpha is predominantly localized in neuronal tissues, homogenates of whole brain tissue were used. Gz alpha and its associated proteins were immunoprecipitated from brain tissue and identified. The immunoprecipitation of four proteins (140, 46, 41 and 36 kDa) was shown to be inhibited in the presence of the Gz alpha peptide. These proteins were subsequently identified as phospholipase C (PLC)-gamma, beta or gamma-actin, Gz alpha and G beta, the beta subunit of heterotrimeric G proteins, respectively. These results suggest that Gz alpha exists in a protein complex with the actin cytoskeleton and an important intracellular signalling enzyme, PLC-gamma. These methods are powerful techniques for determining protein-protein interactions, and provide the first step to the identification of signalling proteins that Gz alpha associates with. However further experimentation will be required to determine the biological relevance of these protein interactions.

Localization, differential expression and retrograde axonal transport suggest physiological role of FGF-2 in spinal autonomic neurons of the rat

Fibroblast growth factor-2 (FGF-2) has marked pharmacological neurotrophic effects on lesioned spinal autonomic neurons following target removal of the adrenal medulla, yet expression and axonal transport in autonomic neurons remain to be shown. We show here FGF-2 and FGF receptor type 1 (FGFR1) protein and mRNA expression in preganglionic intermediolateral neurons of the rat thoracic spinal cord. While immunoreactivity of both FGF-2 and FGFR1 co-localize to intermediolateral neurons, mRNA transcripts of FGFR1, but not of FGF-2, are detectable in intermediolateral preparations by RNase protection analysis, suggesting protein translocation in vivo. Unilateral microinjection of 125iodinated FGF-2 into the adrenal medulla (a major target of intermediolateral neurons) results in significant accumulation of specific radioactivity in thoracic spinal cord tissue, including the intermediolateral neurons, and the ipsilateral splanchnic nerve. Emulsion autoradiography demonstrated labelling over ipsilateral intermediolateral neurons only. Neuronal co-localization of FGF-2/FGFR1 protein, differential mRNA expression, specific retrograde axonal transport and the known neurotrophic actions in vivo, strongly suggest unique physiological roles of FGF-2 in the autonomic nervous system.

Signal transduction from membrane to nucleus: the special case for neurons

Neurons have a unique problem with signal transduction from the membrane in the region of their terminals back to the cell body and nucleus. This distance may be several meters in some nerves in some species, so there is a requirement for some mechanism to stabilize the signal. This review examines two complementary mechanisms for this signal transduction, either by the retrograde axonal transport of the neurotrophic factor together with its receptor, or the transport of a stable activated second messenger molecule. Extrapolation of studies on the fibroblast signal transduction pathway, where it has been shown that G1 can translocate from the membrane to the nucleus, has led to the demonstration of the retrograde axonal transport of several putative signaling molecules. The alpha subunits of both G1 and Gz are retrogradely transported and Gz alpha or possibly the intact heterotrimeric Gz subsequently accumulates in dorsal root ganglia nuclei. Thus Gz1 Gi1 and potentially other G-proteins and distinct signaling molecules may provide additional signal transduction pathways to that of the neurotrophins from terminal to nucleus.

Retrograde axonal transport of the alpha subunit of the GTP-binding protein Gz to the nucleus of sensory neurons

Nerve cells are exquisitely sensitive to target tissue derived factors and the discovery that nerve growth factor could be retrogradely transported in axons suggested that the physical translocation of proteins along the axon could be a mechanism to convey this signal. This message is not due to the neurotrophic factor itself but rather due to second messengers generated by interaction with receptors. We have previously demonstrated the retrograde axonal transport of the alpha subunits of two putative second messenger molecules Gi and Gz. We have investigated more thoroughly the transport of the alpha subunit of Gz (Gz alpha) and in order to be more certain that the immunoreactivity seen is due to Gz alpha, we have made antibodies to peptides from both the N- and C-terminal regions of Gz alpha, which recognise the same 41 kDa band on Western blots of brain and sciatic nerve extracts. This band is eliminated when the antibodies are previously incubated with the specific peptide to which they were made. Using these antibodies for immunohistochemical localisation for Gz alpha, we now report that the GTP-binding protein Gz, is not only retrogradely transported in axons but that it translocates to the neuronal nucleus. Furthermore, the levels seen in the nuclear compartment decline after axotomy or ligation of the mice under ether anaesthetic, suggesting it is the retrogradely transported Gz alpha that is accumulating in the nucleus after activation at the nerve terminal.

Retrograde axonal transport of signal transduction proteins in rat sciatic nerve

Neurons require a mechanism to transmit stable signals over the large distance from the nerve growth cone or terminal to the cell body, in order that information from the target tissue can be relayed to the cell body where it is required. Nerve growth factor (NGF), a target-derived neurotrophic factor, is thought to signal over this distance by receptor mediated internalization of NGF, followed by retrograde axonal transport of the NGF-receptor complex. In this paper we show, by immunohistochemistry of rat sciatic nerve, accumulation of phosphotyrosine immunoreactivity only on the distal side of a nerve crush, suggesting axonal transport of tyrosine kinases and/or tyrosine phosphorylated proteins primarily in a retrograde direction. Furthermore, we also show retrograde axonal transport of phosphoinositide 3-kinase, ERK, MEK and MEK kinase, of which all but MEK kinase are known to be activated downstream of tyrosine receptor kinase activation. The retrograde transport of these proteins suggests that they may be involved in transmission of signals along the axon, relaying neurotrophic factor receptor activation at the nerve terminal to the nerve cell body.