Leukemia inhibitory factor mediates an injury response but not a target-directed developmental transmitter switch in sympathetic neurons

Region-specific central nervous system expression and axotomy-induced regulation in sympathetic neurons of a VIP-beta-galactosidase fusion gene in transgenic mice

To assess the activity of cis-acting elements that direct human vasoactive intestinal peptide (VIP) expression in vivo, two independent transgenic mouse lines were created using a transgene comprised of 1.9 kb of 5'-flanking sequence of the human VIP gene joined to the Escherichia coli beta-galactosidase reporter gene. Transgene expression in brain was assessed using beta-galactosidase histochemistry and compared to the distribution of endogenous VIP expression. Transgene expression was observed in most central and peripheral nervous system sites in which endogenous VIP is expressed. We investigated whether the VIP-beta-galactosidase transgene was regulated in sympathetic neurons in experimental paradigms in which VIP regulation is dependent on the release of leukemia inhibitory factor (LIF). After dissociation in vitro and postganglionic axotomy in vivo there were parallel increases in endogenous VIP and transgene expression in superior cervical ganglia. These results indicate that the 1.9 kb region of 5'-flanking sequence of the human VIP gene includes genomic elements important for cell-specific expression and LIF-dependent regulation in neurons.

Interleukin-1 involvement in the induction of leukemia inhibitory factor mRNA expression following axotomy of sympathetic ganglia

Axotomy of superior cervical (sympathetic) ganglia (SCG) results in increased neuropeptide gene expression. In vitro, neuropeptide gene expression is similarly increased by exposure to the inflammatory cytokine interleukin-1 (IL-1). The effect of IL-1 in-vitro has been shown to be mediated by leukemia inhibitory factor (LIF). Since IL-1 regulates neuropeptide expression via LIF in vitro, we asked whether axotomy in vivo produces an increase in LIF mRNA, and whether that increase is regulated by IL-1 activity. Within 6 h following axotomy, ganglionic LIF mRNA is substantially elevated. Moreover, axotomy produces a rapid and transient increase in intraganglionic IL-1 beta mRNA, followed rapidly by an increase in ICAM-1 mRNA, thereby suggesting a local source of IL-1 activity. Pretreatment with the anti-inflammatory agent dexamethasone (DEX) reduces the increases of both IL-1 beta and LIF mRNAs following axotomy. mRNA encoding the specific signal-transducing Type I IL-1 receptor is present in unlesioned SCG in vivo, and increases following axotomy. Local application of IL-1 beta in vivo induces LIF mRNA even in uninjured ganglia, though not to the extent seen with axotomy. DEX treatment blocks this IL-1 beta-mediated increase in LIF mRNA. Therefore, DEX blocks the induction of LIF mRNA by inhibiting both the production of IL-1 and its action on LIF gene expression. Axotomy of a homozygous IL-1 receptor type I gene knockout mouse leads to a delayed and/or diminished induction of LIF mRNA in SCG, but does not prevent LIF mRNA expression. We conclude that while IL-1 is likely to be involved in the cascade of gene expression that follows axotomy, it alone is not sufficient to mediate the full induction of LIF mRNA by axotomy.

Influence of leukemia inhibitory factor on galanin/GMAP and neuropeptide Y expression in mouse primary sensory neurons after axotomy

The effect of unilateral transection of the sciatic nerve on expression of immunoreactive galanin (GAL), galanin-message-associated peptide (GMAP) and neuropeptide tyrosine (NPY) in dorsal root ganglia (DRGs) was studied in wild-type mice and in leukemia inhibitory factor (LIF)-deficient mice. In normal and contralateral DRGs small numbers of weakly fluorescent GAL- and GMAP-positive neuronal cell bodies and numerous positive fibers were observed. No NPY-positive cell bodies but a few fibers surrounding blood vessels were seen. In LIF deficient mice hardly any GAL- or GMAP-positive neurons or fibers were seen, nor was NPY-like immunoreactivity present in cell bodies. After axotomy there was a dramatic upregulation of all three peptides in wild-type DRG neurons, whereby 50-60% of the neuron profiles, encompassing both small and large profiles, were GAL- and GMAP-immunoreactive (IR). About one third of all neuron profiles, mainly large ones, were NPY-positive. In LIF-deficient mice this upregulation was much less pronounced. Thus GAL- and GMAP-IR neuron profiles were reduced by 65-70% compared with the wild-type mice. The number of NPY-positive neuron profiles was reduced to half but this difference was not significant. There was also an ipsilateral decrease in fluorescence intensity for all three peptide immunoreactivities in the LIF-deficient mice as compared with wild-type mice after axotomy. There was no apparent difference in size between, respectively, GAL- and GMAP-positive profiles when comparing LIF-deficient and wild-type mice before or after axotomy. There were, however, no small NPY-IR profiles in the LIF-deficient group. The present results suggests that LIF is important for the dramatic upregulation of GAL and GMAP seen after axotomy. It may also be important for the normal expression of galanin in mouse DRGs, since wild-type mice seemed to have somewhat more positive cell bodies and more fluorescent fibers. LIF seems to be less important for the control of NPY synthesis, but may be involved in NPY regulation in small-sized neurons.

Cytokine receptor signal transduction and the control of hematopoietic cell development

The cytokine receptor superfamily is characterized by structural motifs in the exoplasmic domain and by the absence of catalytic activity in the cytosolic segment. Activated by ligand-triggered multimerization, these receptors in turn activate a number of cytosolic signal transduction proteins, including protein tyrosine kinases and phosphatases, and affect an array of cellular functions that include proliferation and differentiation. Molecular study of these receptors is revealing the roles they play in the control of normal hematopoiesis and in the development of disease.

aFGF, bFGF and NGF differentially regulate neuropeptide expression in dorsal root ganglia after axotomy and induce autotomy

Using immunohistochemistry and in situ hybridization the in vivo effects of acidic and basic fibroblast growth factor (aFGF, bFGF), and of nerve growth factor (NGF) on the expression of galanin, neuropeptide Y (NPY) and substance P in axotomized dorsal root ganglia (DRGs) were examined. Self-mutilation (autotomy), a supposed pain-related behavior, was investigated after growth factor treatment. One microgram of aFGF, bFGF or NGF was applied directly to the transected sciatic nerve via a capsule. In normal rats 3.2%, 0% and 17.5% of the neuron profiles in the DRGs contained galanin-, NPY- and substance P-like immunoreactivity (LI), respectively. Sciatic nerve transection induced a distinct increase in galanin- and NPY-LIs, but a downregulation of substance P-LI. Thus three days after axotomy 23.5%, 26.9% and 9.8% of the DRG neuron profiles showed immunoreactivity for galanin-, NPY- and substance P-LI, respectively. In vivo administration of aFGF counteracted the axotomy-induced increase in galanin and NPY, whereas bFGF only suppressed NPY upregulation. NGF reversed in the injury-induced decrease in substance P-LI, but had no significant effect on galanin- and NPY-LIs. These results were confirmed by monitoring the mRNA levels for these neuropeptides. Moreover, aFGF was found to induce autotomy in 60% of the rats 3 days after axotomy. NGF produced autotomy in about 30% of the rats. Taken together, the present results suggest (1) that aFGF, bFGF and NGF differentially regulate neuropeptide expression in vivo; (2) that FGFs can inhibit neuropeptide upregulation of some peptides after nerve injury; and (3) that aFGF and NGF may induce pain-related behavior.

Synthesis, cytotoxic properties and effects on early and late gene induction of a chimeric diphtheria toxin-leukemia-inhibitory factor protein

Leukemia-inhibitory factor (LIF) is a neuropoietin able to regulate the differentiation and the survival of many cell types, which include some neuronal populations. The present study describes the genetic construction, expression, purification and properties of a diphtheria-toxin-related LIF gene fusion in which the native receptor-binding domain of diphtheria toxin was replaced with a gene encoding human LIF. The fusion protein expressed from the chimeric tox gene was designated DT-(1-389)-LIF-(2-184)-peptide. This fusion protein has a deduced molecular mass of 65980 Da and is formed by fusion of the first 389 amino acids of diphtheria toxin to amino acids 2-184 of mature human LIF, using a linker of 34 amino acids that includes six consecutive histidine residues. The latter span allows for single-step purification of the fusion protein by Ni(2+)-resin affinity chromatography. This linker provides a high degree of flexibility between the diphtheria toxin and LIF domains, thereby permitting aggregation-free refolding of the chimeric protein while bound to the affinity column. Both LIF and DT-(1-389)-LIF-(2-184)-peptide induced the phosphorylation of CLIP1 and CLIP2 in LIF-responsive neuroblastoma SH-N-BE cells. DT-(1-389)-LIF-(2-184)-peptide was selectively cytotoxic for cultured neuroblastoma cells bearing the LIF receptor, and for sympathetic neurons. The cytotoxic action of DT-(1-389)-LIF-(2-184)-peptide, like that of native diphtheria toxin, required receptor-mediated endocytosis, passage through an acidic compartment, and delivery of an ADP-ribosyltransferase to the cytosol of target cells. The latter point was confirmed by the fact that, while both LIF and DT-(1-389)-LIF-(2-184)-peptide increased c-fos mRNA expression in SH-N-BE cells, only LIF induced proenkephalin and c-fos promoter activities in cells transiently transfected with c-fos-chloramphenicol acetyltransferase and proenkephalin-chloramphenicol acetyltransferase fusion genes. Mutational analysis suggested that the C-terminal helix (helix D) of human LIF may, in part, constitute or contribute to the active site for LIF receptor binding and cell activation. The cytotoxic properties of DT-(1-389)-LIF-(2-184)-peptide may be useful in selectively depleting neuronal and immune cell populations that express the LIF beta receptor.

Interleukin-1 beta increases leukemia inhibitory factor mRNA levels through transient stimulation of transcription rate

Interleukin-1 beta (IL-1 beta) induces leukemia inhibitor factor (LIF) expression in a number of cell types including non-neuronal cells of the sympathetic superior cervical ganglion (SCG). Upregulation of LIF by inflammatory cytokines is usually associated with injury response. We characterized the molecular mechanism of LIF mRNA regulation by IL-1 beta in explanted neonatal rat SCG and a Schwann cell line. IL-1 beta increases LIF mRNA levels by interacting with IL-1 receptors in SCG, since this induction could be diminished by inclusion of either soluble IL-1 receptors or IL-1 receptor antagonist. The antiinflammatory glucocorticoid dexamethasone also inhibits LIF mRNA induction by IL-1 beta. LIF mRNA encodes a 3' AU-rich mRNA stability control sequence, but IL-1 beta does not appear to regulate the decay of LIF mRNA by this mechanism. IL-1 beta does not raise LIF gene transcription rate in cultured SCG 6 or 24 h after addition of IL-1 beta as measured by nuclear run-on assays. LIF gene transcription is induced repidly and transiently in an immortalized Schwann cell line, returning to uninduced rates by 1 h after induction. These results suggest that the IL-1 beta induction of LIF gene expression is at least partially transcriptional, but that LIF mRNA increases to a greater extent than LIF transcription, suggesting the possibility of posttranscriptional regulation as well.

Leukaemia inhibitory factor induced in the sciatic nerve after axotomy is involved in the induction of galanin in sensory neurons

Dramatic changes occur in neuropeptide expression in sensory and sympathetic neurons following axonal injury. Based on the finding that the cytokine leukemia inhibitory factor (LIF) plays an important role in mediating these changes in sympathetic neurons, its participation in triggering changes in sensory neurons was examined. By the use of transgenic mice in which the LIF gene had been knocked out, LIF was found to contribute to the induction of galanin expression in dorsal root ganglia (DRG) after sciatic nerve lesion. On the other hand, two other neuropeptide changes that occur in DRG under these conditions, the reduction of substance P and induction of neuropeptide Y, were independent of LIF expression. In the sympathetic superior cervical ganglion, transection of the postganglionic nerves close to the ganglion resulted in a rapid induction of LIF mRNA in the ganglion and in the lesioned nerve trunk. In contrast, transection of the sciatic nerve close to or distant from the DRG caused a rapid induction of LIF mRNA in the lesioned nerve, but not in the DRG. DRG were capable of making substantial amounts of LIF mRNA when placed in explant cultures, but, in vivo, only a slight induction was found even when both central and peripheral nerve processes of these sensory neurons were transected. These latter observations suggest that, in contrast to the superior cervical ganglia, the DRG environment inhibits the lesion-induced expression of LIF in vivo and/or explanted DRG produce stimulatory signals not found in vivo. Together with the data on the induction of galanin, these observations provide evidence that LIF, generated at a site at some distance from the ganglion, is involved in triggering part of the cell body reaction in sensory neurons.

Neuronal expression of leukemia inhibitory factor (LIF) in the rat brain

Very little is known about the action of the leukemia inhibitory factor (LIF) in the central nervous system. To analyze LIF expression in adult rat brain, we used non-radioactive in situ hybridization with digoxigenin-labeled RNA probes, in combination with immunohistochemistry to identify the cell types expressing LIF mRNA. Hippocampal pyramidal cells, hilar interneurons and granule cells of the dentate gyrus display strong hybridization signals, while neurons of the cerebral cortex, cerebellum, cholinergic basal forebrain nuclei, and the striatum are labeled as well. The most prominent expression in cerebral cortex is in layers IV and VI. Glial fibrillary acidic protein-positive astrocytes did not display a detectable LIF hybridization signal suggesting that LIF mRNA is predominantly expressed in neurons in the normal, adult rat brain, although a presence in resting microglial cells cannot be excluded.

Functional reinnervation of sweat glands in the adult cat paw by inappropriate postganglionic axons

Sympathetic postganglionic neurons were allowed to reinnervate the hairless skin of the cat paw pad, normally supplied by the tibial nerve, after suturing the central stump of the superficial peroneal nerve (supplying both hairy and hairless skin, eight animals) or of the sural nerve (supplying only hairy skin, seven animals) to the distal stump of the tibial nerve. Neural activation of sweat glands was studied by the starch iodine method and by recording the skin potential from the skin surface. Postganglionic neurons were activated by electrical stimulation of peripheral nerves or reflexly. There was good functional reinnervation of sweat glands by sudomotor neurons in all animals. The superficial peroneal nerve contains a few fibers that normally supply < 20% of the sweat glands on the foot pads. When this nerve regenerated into the innervation territory of the tibial nerve, sudomotor fibers consistently made functional contacts with sweat glands on the pads in all animals. These functional contacts were always weaker than those in the controls. Electrical stimulation of the sural nerve does not activate sweat glands in the paw pads of normal animals, indicating that this nerve does not contain postganglionic sudomotor axons. When the sural nerve regenerated into the foot pads, electrical stimulation activated some sweat glands in five of seven animals. We conclude that sudomotor neurons have a high capacity to functionally reinnervate sweat glands in the adult cat. There was also evidence that some noradrenergic vasoconstrictor neurons might take on "cholinergic features' in the adult animal when they reinnervate sweat glands suggesting that the peripheral target can specify the phenotypic properties of postganglionic neurons in the adult animal.

Activation of acidic sphingomyelinase and protein kinase C zeta is required for IL-1 induction of LIF mRNA in a Schwann cell line

Axotomy of sympathetic superior cervical ganglia (SCG) causes Schwann cells to induce mRNA encoding leukemia inhibitory factor (LIF), a neuropoietic cytokine that has been shown to promote sympathetic neuron survival and peptide gene regulation. LIF mRNA is virtually undetectable in uninjured SCG, but is induced by the inflammatory cytokine interleukin-1 (IL-1). The SC1 Schwann cell line was used to study this regulatory mechanism. LIF mRNA increased five-to-tenfold in SC1 cells when IL-1 receptors were stimulated with IL-1. The action of IL-1 is thought to be mediated by the type I IL-1 receptor (IL-1RI), which has been suggested to stimulate a ceramide-dependent protein kinase pathway, much like tumor necrosis factor-alpha. However, stimulation of the ceramide-dependent protein kinase pathways in SC1 cells with either 2-acetylceramide or sphingomyelinase treatment does not induce LIF mRNA accumulation, but 2-acetylceramide addition induces cyclooxygenase-2 mRNA in parallel experiments. Inhibition of phosphotidylcholine-phospholipase C activity, endosomal acidification, or activity of atypical protein kinase C reduce LIF induction by IL-1. These results are consistent with IL-1 regulation of LIF mRNA through stimulation of the endosomal, acidic sphingomyelinase pathway, leading to ceramide activation of protein kinase C zeta. Utilization of this branch of the ceramide signaling pathway may be cell type specific or may be specific for the LIF mRNA response.

Localization and axotomy-induced regulation of the peptide secretoneurin in the rat superior cervical ganglion

This study demonstrates the localization and regulation of a novel neuropeptide of 33 amino acids, secretoneurin (SN), in the rat superior cervical ganglion. Gel filtration chromatography of ganglion proteins followed by a specific radioimmunoassay revealed that SN is the predominant cleavage product of secretogranin II, a member of the chromogranin/secretogranin protein family, in adult ganglia. SN was detected within the majority of nerve endings surrounding postganglionic neurons that were identified by the presence of synaptophysin and, in part, colocalized leu-encephalin. Applying immuno-electronmicroscopy, SN was localized to large dense core vesicles of neuronal and small intensely fluorescent (SIF) cells. In situ hybridization revealed the presence of secretogranin II mRNA in postganglionic neurons and, to a lesser extent, in SIF cells. One week after transection of the postganglionic branches SN levels were not significantly altered; however, a decrease of secretogranin II mRNA was observed in postganglionic neurons but not in SIF cells. After decentralization of the ganglion, SN-immunoreactive nerve terminals disappeared and intraganglionic SN levels were reduced by 70%, indicating the preganglionic origin of SN-positive nerve fibres and varicosities. Secretogranin II mRNA was slightly reduced under this condition. Combined axotomy and decentralization further diminished intraganglionic secretogranin II mRNA, although peptide levels increased significantly above control values under these conditions. Double-labelling immunofluorescence with antibodies against the somatodendritic marker microtubule-associated protein 2 (MAP2) revealed that the increase in SN immunoreactivity was due to an accumulation of SN in axonal processes of postganglionic neurons. SN immunoreactivity was also detected in dissociated neonatal superior cervical ganglion cultures and increased significantly upon treatment with nerve growth factor, the survival and differentiation factor of sympathetic neurons during perinatal development. Co-culture with non-neuronal cells or addition of leukaemia inhibitory factor, a cytokine known to stimulate synthesis of various peptides after nerve transection, did not influence SN immunoreactivity. Therefore, since no fixed relationship between SN and any of the known neuropeptides or neurotransmitters expressed in sympathetic neurons was observed, the expression of this novel peptide appears to be independently regulated.

Localization, regulation and functions of neurotransmitters and neuromodulators in cervical sympathetic ganglia

Cervical sympathetic ganglia represent a suitable model for studying the establishment and plasticity of neurochemical organization in the nervous system since sympathetic postganglionic neurons: (1) express several neuromediators, i.e., short acting transmitters, neuropeptide modulators and radicals, in different combinations; (2) receive synaptic input from a limited number of morphologically and neurochemically well-defined neuron populations in the central and peripheral nervous systems (anterograde influence on phenotype); (3) can be classified morphologically and neurochemically by the target they innervate (retrograde influence on phenotype); (4) regenerate readily, making it possible to study changes in neuromediator content after axonal lesion and their possible influence on peripheral nerve regeneration; (5) can be maintained in vitro in order to investigate effects of soluble factors as well as of membrane bound molecules on neuromediator expression; and (6) are easily accessible. Acetylcholine and noradrenaline, as well as neuropeptides and the recently discovered radical, nitric oxide, are discussed with respect to their localization and possible functions in the mammalian superior cervical and cervicothoracic (stellate) paravertebral ganglia. Furthermore, mechanisms regulating transmitter synthesis in sympathetic neurons in vivo and in vitro, such as soluble factors, cell contact or electrical activity, are summarized, since modulation of transmitter synthesis, release and metabolism plays a key role in the neuronal response to environmental influences.

Chemical sympathectomy and postganglionic nerve transection produce similar increases in galanin and VIP mRNA but differ in their effects on peptide content

Large changes in neuronal gene expression occur in adult peripheral neurons after axonal transection. In the rat superior cervical ganglion, for example, neurons that do not normally express vasoactive intestinal peptide (VIP) or galanin do so after postganglionic nerve transection. These effects of axotomy could result from a number of aspects of the surgical procedure. To test the idea that the important variable might be the disconnection of axotomized neuronal cell bodies from their target tissues, we examined the effects of producing such a disconnection by means of the compound 6-hydroxydopamine (6-OHDA), a neurotoxin that causes degeneration of sympathetic varicosities and avoids many of the complications of surgery. Two days after 6-OHDA treatment, VIP and galanin immunoreactivities had increased two- and 40-fold, respectively. Nevertheless, these increases were substantially smaller than the 30- and 300-fold changes seen after surgical axotomy. When expression of VIP and galanin was examined at the mRNA level, however, comparable increases were found after either procedure. The results indicate that chemical destruction of sympathetic varicosities produces an equivalent signal for increasing VIP and galanin mRNA as does axonal transection. The differences in the neuropeptide levels achieved suggests that peptide expression after nerve transection is regulated both at the mRNA and protein levels.

The response of motoneurons to neurotrophins

The ongoing search for neurotrophic factors for motoneurons has led to the identification of a number of molecules which regulate motoneuron survival and function. Among these factors, the neurotrophins brain derived neurotrophic factor (BDNF), neurotrophin-3 (NT-3) and NT-4/5 but not nerve growth factor (NGF), can prevent embryonic and postnatal motoneuron cell death in a variety of experimental paradigms. Analysis of expression of p75, trkB and trkC-components of the neurotrophin receptors-supports a potential physiological role for these factors as muscle- and glial-derived trophic factors for motoneurons. However, the survival of motoneurons during embryonic development is not reduced in the absence of BDNF, NT-3 or NT-4, as revealed by gene knockout experiments. This points to the involvement of additional trophic factors in the regulation of embryonic and postnatal motoneuron survival. The purpose of this review is to bring together the often prophetic observations from earlier studies-prior to the identification and characterization of these neurotrophins-with more recent results.

Involvement of bone morphogenetic protein-4 and bone morphogenetic protein-7 in the differentiation of the adrenergic phenotype in developing sympathetic neurons

The neurotransmitter phenotype of sympathetic neurons is specified by interactions with the surrounding embryonic tissues. Adrenergic differentiation is elicited early during development in the vicinity of notochord and dorsal aorta and the importance of axial midline tissues for adrenergic differentiation has been well documented. We now provide evidence that bone morphogenetic proteins, BMP-4 and BMP-7 are signals produced by the dorsal aorta that direct sympathetic neuron differentiation. BMP-4 and BMP-7 are expressed in the dorsal aorta at critical times during sympathetic neuron differentiation and have the ability to enhance the formation of adrenergic sympathetic neurons both in cultures of neural crest cells and when ectopically expressed in the developing embryo.

Cryptic physiological trophic support of motoneurons by LIF revealed by double gene targeting of CNTF and LIF

BACKGROUND

The survival and differentiation of motoneurons during embryonic development, and the maintenance of their function in the postnatal phase, are regulated by a great variety of neurotrophic molecules which mediate their effects through different receptor systems. The multifactorial support of motoneurons represents a system of high security, because the inactivation of individual ligands has either no detectable, or relatively small, atrophic or degenerative effect on motoneurons.

RESULTS

Leukaemia inhibitory factor (LIF) has been demonstrated to support motoneuron survival in vitro and in vivo under different experimental conditions. However, when LIF was inactivated by gene targeting, there were no apparent changes in the number and structure of motoneurons and no impairment of their function. The slowly appearing, relatively mild degenerating effects in motoneurons that resulted from ciliary neurotrophic factor (CNTF) gene targeting were substantially potentiated by simultaneous inactivation of the LIF gene, however. Thus, in mice deficient in LIF and CNTF, the degenerative changes in motoneurons were more extensive and appeared earlier. These changes were also functionally reflected by a marked reduction in grip strength.

CONCLUSIONS

Degenerative disorders of the nervous system, in particular those of motoneurons, may be based on multifactorial inherited and/or acquired defects which individually do not result in degenerative disorders, but which become apparent when additional (cryptic) inherited disturbances or sub-threshold concentrations of noxious factors come into play. Accordingly, the inherited inactivation of the CNTF gene in a high proportion of the Japanese population may represent a predisposing factor for degenerative disorders of motoneurons.

Ca2+/calmodulin-dependent protein kinase type IV in dorsal root ganglion: colocalization with peptides, axonal transport and effect of axotomy

Using the indirect immunofluorescence technique, the distribution of Ca2+/calmodulin-dependent protein kinase IV (CaM kinase IV) was studied in dorsal root ganglia (DRGs) and the sciatic nerve under normal circumstances and after axotomy and nerve ligation. CaM kinase IV-like immunoreactivity (-LI) was observed mainly in small DRG neurons but also in some large ones with the immunoreactivity mainly confined to the cell nuclei and with varying levels in the cytoplasm. CaM kinase IV-LI was present in around 1/4 of all CGRP-positive neurons and in the vast majority of the somatostatin-positive neurons. The enzyme levels decreased markedly after axotomy. The enzyme was also observed in axons in the sciatic nerve and accumulated both proximal and distal to a ligation. The present results suggest that CaM kinase is not of direct importance for upregulation of neuropeptides in DRG neurons after nerve injury. In addition to a nuclear function it may also play a role in the peripheral processes of DRG neurons.

Vanilloid receptor loss is independent of the messenger plasticity that follows systemic resiniferatoxin administration

Resiniferatoxin (RTX) depletes vanilloid (capsaicin) receptors from lumbar dorsal root ganglia (DRG) of the rat. In addition, RTX causes changes in neuropeptide and nitric oxide synthase expression in lumbar DRG neurons, similar to those described following axotomy; this latter phenomenon is referred to as messenger plasticity. These findings suggested that vanilloid receptor loss may be part of the plasticity that follows RTX treatment. Here we show that vanilloid receptor expression, as detected by [3H]RTX autoradiography, is not changed in lumbar DRGs of axotomized rats, nor is it altered in a rat model (chronic constriction injury) of neuropathic pain. Thus, the in vivo expression of vanilloid receptors detected by specific [3H]RTX binding does not require the presence of intraaxonally transported trophic factors such as nerve growth factor. We conclude that messenger plasticity and vanilloid receptor loss are mediated by distinct mechanisms.

Minireview. Galanin-acetylcholine interactions: relevance to memory and Alzheimer's disease

The neuropeptide, galanin, and its receptors are localized in the cholinergic basal forebrain and its projection areas in mammalian brain. Centrally administered galanin inhibits acetylcholine release in the rat ventral hippocampus, and produces deficits in learning and memory tasks. In Alzheimer's disease, galanin is overexpressed in terminals innervating the nucleus basalis of Meynert cell bodies. Selective galanin receptor antagonists provide a novel approach for increasing cholinergic function, as a potential adjunct to the clinical treatment of dementias.

Target-dependent plasticity of galanin and vasoactive intestinal peptide in the rat superior cervical ganglion after nerve lesion and re-innervation

The expression of the neuropeptides galanin and vasoactive intestinal peptide (VIP) is increased in subpopulations of sympathetic neurons after axotomy of the rat superior cervical ganglion. We investigated whether postganglionic neurons innervating different targets show a prevalence for any of the two peptides in response to carotid nerve lesion. Before the respective postganglionic axons were crushed close to the ganglion, postganglionic neurons projecting either to the iris (through the internal carotid nerve) or to the submandibular gland (through both carotid branches) were identified by the retrograde tracer Fast Blue. Galanin and VIP immunoreactivities were demonstrated two and 30 days after crush and after successful regeneration of the lesioned neurons (60 days). In control ganglia, both peptides were detected in a few gland- but not in iris-projecting neurons. However, two days after crush of the respective carotid nerves, 14% of neurons within the iris and 46% within the gland population were immunoreactive for galanin. The percentage of neurons immunoreactive for VIP was significantly lower in both populations: only 3.5% of neurons projecting to the iris and 23% of the gland-projecting neuron population exhibited this peptide. After 30 days, the percentage of galanin- and VIP-positive neurons projecting to the submandibular gland was reduced (24% and 5.7%, respectively), whereas the proportion of galanin-immunoreactive neurons further increased within the iris population (55%), indicating that some neurons express galanin at later stages after the lesion. At 60 days after the crush, the percentage of galanin- or VIP-immunoreactive neurons had decreased to control levels within those neuron populations that re-innervated the iris or submandibular gland, although the total number of neurons exhibiting galanin or VIP was still increased within the ganglion, suggesting that re-establishment of target contact may play a role in down-regulation of both peptides.

Leukemia inhibitory factor induces mechanical allodynia but not thermal hyperalgesia in the juvenile rat

Systemic administration or local injection to the rat hindpaw of leukemia inhibitory factor induced a prolonged, dose dependent, mechanical hypersensitivity of the hindpaw flexion withdrawal reflex. Mechanical stimuli which were innocuous prior to leukemia inhibitory factor administration, evoked a rapid hindpaw withdrawal reflex indicative of mechanical allodynia. Pre-administration of anti-leukemia inhibitory factor antibodies prevented this behavioural hypersensitivity. Hindpaw sensitivity to a noxious thermal stimulus was unaffected by leukemia inhibitory factor administration. Anti-leukemia inhibitory factor had no effect upon hindpaw withdrawal thresholds when injected alone nor influenced the mechanical hypersensitivity produced by a subcutaneous injection of nerve growth factor. Injection of the closely related cytokine ciliary neurotrophic factor did not affect mechanical or thermal reflex withdrawal thresholds. Elevation of the neuroactive cytokine leukemia inhibitory factor following peripheral nerve injury may be a contributory factor to the pathogenesis of neuropathic pain.

A reciprocal cell-cell interaction mediated by NT-3 and neuregulins controls the early survival and development of sympathetic neuroblasts

Neurotrophin 3 (NT-3) can support the survival of some embryonic sympathetic neuroblasts before they become nerve growth factor dependent. We show that NT-3 is produced in vivo by nonneuronal cells neighboring embryonic sympathetic ganglia. NT-3 mRNA is produced by these nonneuronal cells in vitro and is up-regulated by platelet-derived growth factor, ciliary neurotrophic factor, and glial growth factor 2 (a neuregulin). Nonneuronal cell-conditioned medium promotes survival and induces TrkA expression in isolated sympathetic neuroblasts, and this activity is blocked by anti-NT-3 antibody. Neuroblasts also enhance NT-3 production by nonneural cells. Neuroblasts synthesize several forms of neuregulin, and antibodies to neuregulin attenuate the effect of the neuroblasts on the nonneuronal cells. These data suggest a reciprocal cell-cell interaction, in which neuroblast-derived neuregulins promote NT-3 production by neighboring nonneuronal cells, which in turn promotes neuroblast survival and further differentiation.

Neuroprotective effect of various cytokines on developing spinal motoneurons following axotomy

Ciliary neurotrophic factor (CNTF), a multipoietic factor, on a variety of neurons, prevents axotomy-induced motoneuron loss and can improve the outcome of murine motor neuron disease (MND). We carried out a study to determine whether other cytokines rescue spinal motoneurons from axotomy-induced cell death. Unilateral sciatic nerve was transected in neonatal rats. Two doses of recombinant murine cholinergic differentiation factor/leukemia inhibitory factor (CDF/LIF), recombinant rat CNTF, recombinant human granulocyte-colony stimulating factor (G-CSF), recombinant human interleukin-6 (IL-6), recombinant human tumor necrosis factor beta (TNF beta), or vehicle were administered daily for 2 weeks by intraperitoneal injection. After treatment, the number of spinal motoneurons was determined at the level of L4-5 segments. In comparison with vehicle, the higher doses of CDF/LIF, CNTF, and IL-6, and the lower doses of CDF/LIF and IL-6 significantly retarded the loss of motoneurons. G-CSF and TNF beta failed to inhibit motoneuron death. CDF/LIF and IL-6 rescued motoneurons from the retrograde death following axotomy, in a similar manner to CNTF. These results provide evidence that several cytokines may have therapeutic potential in human axonopathy or MND.

Sensory afferent processing in multi-responsive DRG neurons

The recent advance in molecular and neurobiological techniques disclosed the multi-responsive nature of DRG neurons. The survival, phenotype expression and electrical properties of these neurons are under the control of a variety of substances through their specific receptors. In pathological conditions, such as tissue inflammation or nerve injury, DRG neurons change their responsiveness through the dynamic reconstruction of their receptor system. This reconstruction is initiated by environmental stimuli. Thus the properties of polymodal nociceptors can be altered according to the environmental conditions. The whole story of this mechanism is not disclosed yet. In order to understand this mechanism, it is basically important to identify various receptor mRNAs in DRG neurons, precise localization of receptor proteins, site of synthesis and route of supply of ligands for these receptors.

Prominent expression of bFGF in dorsal root ganglia after axotomy

Using quantitative in situ hybridization and immunohistochemistry the expression of acidic and basic fibroblast growth factors (aFGF, bFGF) in dorsal root ganglia (DRGs) was examined. Around 5% of the small neurons expressed bFGF mRNA in normal DRGs. Nerve injury induced a very dramatic and rapid up-regulation in bFGF mRNA levels, and around 80% of all DRG neurons expressed bFGF mRNA 3 days after axotomy. A distinct increase in bFGF-like immunoreactivity (LI) was also detected as early as 15 h after axotomy. The elevation of bFGF mRNA and protein levels declined after 1 week. bFGF mRNA was also up-regulated in non-neuronal cells following axotomy. Normally bFGF-LI was mainly localized in the nuclei of DRG neurons and in some non-neuronal cells. After nerve section, bFGF-LI was in addition found in the cytoplasm, and many more bFGF-positive non-neuronal cells were observed. By means of confocal microscopy analysis of axotomized DRGs, some bFGF-LI could be detected in vesicle-like structures in the cytoplasm as well as in the nucleoli, in addition to the nuclear location. Application of leukaemia inhibitory factor to the transected sciatic nerve significantly increased the number of bFGF-positive neurons, whereas the bFGF-LI in non-neuronal cells was strongly suppressed. About 70% of the normal DRG neurons expressed aFGF mRNA and aFGF-LI. Axotomy produced a moderate increase in aFGF mRNA levels, but no detectable effect on protein levels. Taken together, the results show that bFGF may be involved in the neuronal response to injury and suggest a role in neuronal survival and regeneration in axotomized DRG neurons.

Activin A and follistatin expression in developing targets of ciliary ganglion neurons suggests a role in regulating neurotransmitter phenotype

The avian ciliary ganglion contains choroid neurons that innervate choroid vasculature and express somatostatin as well as ciliary neurons that innervate iris/ciliary body but do not express somatostatin. We have previously shown in culture that activin A induces somatostatin immunoreactivity in both neuron populations. We now show in vivo that both targets contain activin A; however, choroid expressed higher levels of activin A mRNA. In contrast, follistatin, an activin A inhibitor, was higher in iris/ciliary body. Iris cell-conditioned medium also contained an activity that inhibited activin A and could be depleted with anti-follistatin antibodies. These results suggest that development of somatostatin is limited to choroid neurons by differential expression of activin A and follistatin in ciliary ganglion targets.

Peripheral neuropathies and neurotrophic factors: animal models and clinical perspectives

A large body of data exists showing that a wide variety of neurotrophic factors can promote the survival or growth of different neuronal populations in vitro. More recently, several studies have been published on the survival-promoting effects of particular factors in animal models of peripheral neuropathies. Thus, the effect of axotomy on neuropeptide expression in dorsal root ganglion cells is partially reversed by nerve growth factor treatment, and the effect on choline acetyltransferase expression in motoneurones is partially reversed by glial-derived neurotrophic factor, neurotrophin-4/5 and brain-derived neurotrophic factor. Nerve growth factor also ameliorates some of the changes seen in sensory neurones in animal models of diabetic neuropathy and small fibre cytostatic drug neuropathy, whereas neurotrophin-3 has been found to reverse some changes in large sensory neurones associated with cisplatin neurotoxicity. The results of these studies provide grounds for optimism in the clinical uses of such factors, and, indeed, several clinical studies are now under way.

Quantitative analysis of the expression of a VIP transgene

We have analyzed the expression of a transgene bearing 2 kilobases of the 5' flanking region of the human vasoactive intestinal polypeptide (VIP) gene coupled to beta-galactosidase. Expression was assayed by beta-galactosidase histochemistry and by mRNA quantitation using polymerase chain reaction (PCR)-mediated amplification; we compared beta-galactosidase activity against both transgene and endogenous VIP mRNA levels. We found that the human 5' flanking sequence in this construct is able to direct tissue-specific expression of beta-galactosidase similar to the pattern for endogenous VIP. However, the transgene is also expressed in smooth muscle and Schwann cells, where VIP mRNA is rare. In various tissues where the transgene and endogenous gene are both active, the ratio between their message levels differs dramatically--transgene mRNA is more abundant where VIP is relatively scarce, but is much less abundant than the endogenous message at sites where VIP mRNA is most concentrated. These results suggest that sequence elements that may restrict VIP transcription or cause tissue-specific VIP mRNA accumulation are missing from the transgene. In the testis there is a high level of transgene message but no significant beta-galactosidase activity; this discrepancy is caused by transcription from a cryptic promoter within the beta-galactosidase sequence.

Coordinated up-regulation of choline acetyltransferase and vesicular acetylcholine transporter gene expression by the retinoic acid receptor alpha, cAMP, and leukemia inhibitory factor/ciliary neurotrophic factor signaling pathways in a murine septal cell line

The proteins responsible for acetylcholine (ACh) synthesis (choline acetyltransferase, ChAT) and storage (vesicular ACh transporter, VAChT) are encoded by two closely linked genes in vertebrates, with the VAChT coding sequence contained within the first intron of the ChAT gene. This unusual genomic organization suggests that the transcription of these two genes is coordinately regulated. Using Northern analysis we studied the modulation of ChAT and VAChT expression in a murine septal cell line (SN56) by three groups of agents: retinoids, trophic factors belonging to the leukemia inhibitory factor/ciliary neurotrophic factor (LIF/CNTF) family, and cAMP. All-trans-retinoic acid increased both ChAT and VAChT mRNA levels in SN56 cells up to 3.5-fold, and elevated intracellular ACh levels by 2.5-fold. This effect was mimicked by a retinoic acid receptor alpha (RAR alpha) agonist (Ro 40-6055) and prevented by a specific antagonist (Ro 41-5253), indicating that it was mediated by RAR alpha. ChAT- and VAChT-specific transcripts were also induced (up to 3-fold) by treatment with CNTF or LIF (20 ng/ml, 48 h), as well as by dibutyryl cAMP (1 mM). All these agents increased the ACh level in the cells (up to 2.5-fold). Dibutyryl cAMP had a greater effect on the level of VAChT mRNA (4-fold induction) than on the level of ChAT mRNA (2-fold induction), suggesting a quantitatively differential transcriptional regulation of the two genes by the cAMP pathway. The effects of the three groups of agents studied on ChAT and VAChT mRNA levels were additive, pointing to several independent mechanisms by which the cholinergic properties of septal neurons can be modulated.

Leukaemia inhibitory factor expression in cultured rat anterior pituitary is regulated by glucocorticoids

Leukaemia inhibitory factor (LIF) is the generally recognized nomenclature for a pleiotropic cytokine that exerts multiple biological effects in different systems. However, its role in the neuroendocrine system is relatively unexplored, with the exception of one report indicating that LIF may act to determine the unique vascular organization of the pituitary gland. In the present study the expression of LIF mRNA has been demonstrated for the first time in the pituitary gland of the rat, in all three pituitary lobes. However, LIF gene expression is restricted to tissues in explant culture where LIF transcripts are readily detectable by Northern Techniques. Similar studies using the reverse transcriptase-polymerase chain reaction (RT-PCR) technique also failed to detect LIF transcripts in fresh tissue from adult animals. These results are consistent with the hypothesis that LIF acts to mediate the response to trauma, a response that may include the induction of neuropeptide expression in the anterior pituitary. In further studies it has also been shown that anterior pituitary LIF mRNA is super-induced in the presence of protein synthesis inhibitors, a response that indicates a role for a labile protein in the attenuation of LIF expression. Both the explantation response, and the response to protein synthesis inhibitory drugs are decreased in the presence of dexamethasone indicating that a glucocorticoid receptor mechanism acts as a general modulatory influence on LIF mRNA levels. These findings are consistent with the presence of multiple regulatory controls on the expression of LIF that serve to restrict its expression to pathological conditions, and indicate that LIF does not participate in normal endocrine physiology.

Effects of postganglionic nerve section on synaptic transmission in the superior cervical ganglion of the guinea-pig

In sympathetic neurons, axotomy induces a marked depression in synaptic transmission. We asked whether the decrease in synaptic efficacy observed in a given axotomized cell is more severe if most of the postsynaptic neurons are also injured. Accordingly, we studied if the synaptic depression induced by axotomy in neurons with axons running in a postganglionic nerve is influenced by section of other postganglionic nerves. The excitatory postsynaptic potentials evoked by preganglionic stimulation were recorded intracellularly in an in vitro preparation of the superior cervical ganglion. Eight days after cutting the inferior postganglionic nerve, postsynaptic potentials recorded from neurons projecting through this nerve were smaller (median = 6 mV, n = 62) than the controls (median = 34 mV, n = 89), but were similar to those found after sectioning the inferior nerve plus most postganglionic nerves (median = 5 mV, n = 70). If the inferior nerve was left intact, but most postganglionic branches were cut, the synaptic potentials recorded from inferior nerve neurons were normal (median = 33 mV, n = 77). It is concluded that the synaptic depression induced by axotomy in a sympathetic neuron is not affected by axotomy of nearby ganglion cells, even if they share part of their presynaptic axons. This suggests that the effect of axotomy is restricted to the synaptic terminals on the injured neuron.

Differential regulation of motor neuron survival and choline acetyltransferase expression following axotomy

Although it is well known that motor neuron survival following axotomy is enhanced with maturation, the ability of surviving neurons to express the cholinergic enzyme choline acetyltransferase (ChAT) following axotomy has not ben closely examined. Moreover, the utility of the facial nucleus in studies of motoneuron response to injury and to trophic factors, coupled with the increasing importance of the mouse in gene targeting, compelled us to investigate the age dependence of neuronal survival and ChAT expression in the mouse facial nucleus following axotomy. We cut the facial nerve at postnatal day (P) 4, 7, 14, 21, and 28 or in the adult and used Nissl staining and ChAT immunocytochemistry to quantitate survival and ChAT expression, respectively, following 1, 2, or 3 weeks' survival at each age. We confirm in this model that the rate and extent of motor neuron death following axotomy is reduced with increasing maturity. The surviving neurons maintain a high ChAT content through P21; however, axotomy from P28 through adulthood results in a striking reduction in ChAT immunoreactivity. That is, although axotomy at P21 results in 61% motor neuron survival, with virtually all of the surviving neurons being ChAT positive, axotomy in the adult results in 72% survival but only 9% of the neurons are ChAT positive. Thus, surviving motor neurons in the adult animals are only weakly cholinergic. These results indicate that a change in the regulation of ChAT expression occurs following P21 so that cell survival and enzyme levels are uncoupled. We suggest that the putative factor or factors that enhances motor neuron survival in maturity is not capable of maintaining ChAT expression.

LIF-and IL-1 beta-mediated increases in substance P receptor mRNA in axotomized, explanted or dissociated sympathetic ganglia

Regulation of substance P receptor (SPR) mRNA was examined in the rat sympathetic superior cervical ganglion (SCG) in vitro and in vivo after axotomy. Interleukin-1 beta (IL-1 beta) treatment of explanted ganglia elevated levels of SPR mRNA. By contrast, dissociated cultures of purified sympathetic neurons, purified fibroblasts, and purified Schwann cells each expressed only low levels of SPR mRNA, and treatment with the cytokine did not alter levels of the receptor mRNA. Treatment of Schwann cell or fibroblast cultures with leukemia inhibitory factor (LIF) also did not alter SPR mRNA. However, treatment of pure neuronal cultures with LIF significantly elevated levels of the receptor mRNA. Further, SPR mRNA increased in pure sympathetic neurons cultured in the presence of conditioned medium from IL-1 beta treated fibroblasts or Schwann cells; this effect was blocked in the presence of LIF antibody. This suggests that the stimulatory effects of IL-1 beta on SPR mRNA in explants is mediated by LIF release. Axotomy of the SCG in vivo resulted in a significant increase in LIF mRNA. Further, axotomy resulted in a significant increase in SPR mRNA, suggesting that LIF may mediate the increase in SPR mRNA. In view of the known effects of substance P (SP) on inflammatory responses, these observations suggest that coordinated expression of SP and SPR mRNA in neurons after nerve injury may participate in inflammatory and repair processes in the ganglion.

Effect of vibrissae deprivation on follicle innervation, neuropeptide synthesis in the trigeminal ganglion, and S1 barrel cortex plasticity

Deprivation of vibrissae from an early age causes plasticity in S1 barrel cortex. This method of deprivation is most likely to induce plasticity by altering the balance of primary afferent activity from the deprived and spared vibrissae. To study whether or not induction or expression of this type of plasticity might be affected by follicle nerve injury caused by the deprivation technique, three different methods of detecting nerve injury were used: counting axon numbers in the distal follicle nerve, quantifying morphological changes in axons, and measuring neuropeptide expression in the trigeminal ganglion cells. First, nerves innervating follicles chronically deprived of vibrissae from birth had the same number of myelinated and unmyelinated axons as nerves from normally reared animals. Second, axons innervating deprived follicles showed no morphological changes in myelination or mitochondria characteristic of damaged nerves. Third, the corresponding nerve cell bodies in the trigeminal ganglion did not show upregulation of galanin or neuropeptide Y expression. In contrast, animals receiving mild injury of the follicle nerve endings (by cauterization of the follicle) showed profound changes in axonal myelination and mitochondria and increases in neuropeptide expression. These results imply that vibrissae deprivation does not act by inducing injury of the follicular nerve, suggesting that changes in the balance of follicle nerve activity are the cause of cortical plasticity. Consistent with this notion, a fourth experiment demonstrated that trimming the vibrissae induces cortical plasticity comparable to that induced by complete vibrissae removal.

Peripheral expression and biological activities of GDNF, a new neurotrophic factor for avian and mammalian peripheral neurons

Glial cell line-derived neurotrophic factor (GDNF) is a neurotrophic polypeptide, distantly related to transforming growth factor-beta (TGF-beta), originally isolated by virtue of its ability to induce dopamine uptake and cell survival in cultures of embryonic ventral midbrain dopaminergic neurons, and more recently shown to be a potent neurotrophic factor for motorneurons. The biological activities and distribution of this molecule outside the central nervous system are presently unknown. We report here on the mRNA expression, biological activities and initial receptor binding characterization of GDNF and a shorter spliced variant termed GDNF beta in different organs and peripheral neurons of the developing rat. Both GDNF mRNA forms were found to be most highly expressed in developing skin, whisker pad, kidney, stomach and testis. Lower expression was also detected in developing skeletal muscle, ovary, lung, and adrenal gland. Developing spinal cord, superior cervical ganglion (SCG) and dorsal root ganglion (DRG) also expressed low levels of GDNF mRNA. Two days after nerve transection, GDNF mRNA levels increased dramatically in the sciatic nerve. Overall, GDNF mRNA expression was significantly higher in peripheral organs than in neuronal tissues. Expression of either GDNF mRNA isoform in insect cells resulted in the production of indistinguishable mature GDNF polypeptides. Purified recombinant GDNF promoted neurite outgrowth and survival of embryonic chick sympathetic neurons. GDNF produced robust bundle-like, fasciculated outgrowth from chick sympathetic ganglion explants. Although GDNF displayed only low activity on survival of newborn rat SCG neurons, this protein was found to increase the expression of vasoactive intestinal peptide and preprotachykinin-A mRNAs in cultured SCG neurons. GDNF also promoted survival of about half of the neurons in embryonic chick nodose ganglion and a small subpopulation of embryonic sensory neurons in chick dorsal root and rat trigeminal ganglia. Embryonic chick sympathetic neurons expressed receptors for GDNF with Kd 1-5 x 10(-9) M, as measured by saturation and displacement binding assays. Our findings indicate GDNF is a new neurotrophic factor for developing peripheral neurons and suggest possible non-neuronal roles for GDNF in the developing reproductive system.

Changes in the macrophage population of the rat superior cervical ganglion after postganglionic nerve injury

Following peripheral nerve transection, a series of biochemical changes occurs in axons and Schwann cells both at the site of the lesion and distal to it. Macrophages differentiated from monocytes that invade the area in response to transection (elicited macrophages) and, perhaps, also macrophages normally present in the tissue (resident macrophages) play important roles in these changes. In addition, nerve transection produces changes in the cell bodies of axotomized neurons and their surrounding glial cells, located at some distance from the lesion. To determine whether macrophages might play a role in the changes occurring in the superior cervical ganglion (SCG) after axotomy, we examined the presence of macrophages before and after axonal damage. The monoclonal antibodies ED1, ED2, and OX6 were used, each of which recognizes a somewhat different population of macrophages. Ganglia from normal rats contained a population of resident cells that were ED2+ but very few that were ED1+. Within 2 days after the post-ganglionic nerves were transected, the number of ED1+ cells increased substantially, with little change in immunostaining for ED2. These data, in combination with published studies on other tissues, suggest that ED1 in the SCG is selective for elicited macrophages and ED2 for resident macrophages. OX6 immunostaining was prominent in normal ganglia but also increased significantly after axotomy, suggesting that it reflects both macrophage populations. Systemic administration of 6-hydroxydopamine, a neurotoxin that causes the destruction of sympathetic nerve endings, also produced an increase in ED1 immunostaining. Thus, the change in ED1 immunostaining in the SCG does not require surgery, with the attendant severing of local blood vessels and connective tissue, but rather only the disconnection of sympathetic neurons from their end organs. The time course of the invasion of monocytes after axotomy indicates that this process is not required to trigger the biochemical changes occurring in the ganglion within the first 24 h. On the other hand, the existence of a resident population of macrophages raises the possibility that changes in those cells might be involved.

Activins as candidate cholinergic differentiation factors in vivo

A number of cytokine families have been implicated in shaping neuronal survival, growth and gene expression. The neuropoietic and transforming growth factor-beta (TGF-beta) cytokines, in particular, have emerged as candidates for regulating the phenotype of sympathetic neurons. Culture studies have shown that neuropoietic cytokines (such as leukemia inhibitory factor, ciliary neurotrophic factor, oncostatin M, growth promoting activity) can induce the cholinergic enzyme, choline acetyltransferase (ChAT) and several neuropeptides, whereas certain members of the TGF-beta family (activin A, bone morphogenetic proteins-2 and -6) induce partially overlapping but distinct sets of transmitter and neuropeptide genes in sympathetic neurons. Since activins can induce ChAT in cultured neurons, we have investigated whether these cytokines are expressed by the appropriate cells and tissues to make them candidates for the cholinergic differentiation factor that is known to alter the phenotype of sympathetic neurons that innervate the sweat gland in the footpad in vivo. In-situ hybridization with the anti-sense probe for activin beta B specifically labels the sweat glands but not other tissues in the footpads of developing rats. Ribonuclease protection assays indicate that beta B as well as the other activin and inhibin subunit mRNAs are expressed by a number of tissues, including footpad, hairy skin and submaxillary gland. Homogenates of developing rat footpads, however, failed to induce the set of neuropeptide genes in cultured sympathetic neurons that is characteristic for activins, although neuropoietic cytokine activity was readily detectable in this assay. Thus, while activin beta B mRNA is expressed in the sweat gland, this tissue does not contain detectable activin protein as assayed by its ability to regulate neuronal gene expression. Moreover, activin subunit mRNAs are expressed by targets of noradrenergic sympathetic neurons in vivo, indicating that activin expression is not limited to targets of cholinergic neurons.

Targeted disruption of the low-affinity leukemia inhibitory factor receptor gene causes placental, skeletal, neural and metabolic defects and results in perinatal death

The low-affinity receptor for leukemia inhibitory factor (LIFR) interacts with gp130 to induce an intracellular signal cascade. The LIFR-gp130 heterodimer is implicated in the function of diverse systems. Normal placentation is disrupted in LIFR mutant animals, which leads to poor intrauterine nutrition but allows fetuses to continue to term. Fetal bone volume is reduced greater than three-fold and the number of osteoclasts is increased six-fold, resulting in severe osteopenia of perinatal bone. Astrocyte numbers are reduced in the spinal cord and brain stem. Late gestation fetal livers contain relatively high stores of glycogen, indicating a metabolic disorder. Hematologic and primordial germ cell compartments appear normal. Pleiotropic defects in the mutant animals preclude survival beyond the day of birth.

Developmental abnormalities in mice transgenic for bovine oncostatin M

Oncostatin M belongs to the subfamily of hematopoietin cytokines that binds a receptor complex containing gp130. To date, only the human form of oncostatin M has been identified, and its evolutionary conservation is unresolved. We have isolated a bovine gene whose open reading frame encodes a precursor protein that is 58% identical to human oncostatin M. A comparison of the bovine and human amino acid sequences predicts significant similarity, including the four-alpha-helical-bundle structure and the placement of disulfide bridges. As with the human protein, bovine oncostatin M binds specific receptors on human H2981 cells and inhibits the proliferation of human A375 tumor cells and mouse M1 leukemia cells. To identify activities regulated in vivo, we injected bovine oncostatin M fusion genes containing various tissue-specific promoters into mouse embryos. The frequencies of transgenic mice were reduced significantly, suggesting that overexpression of the bovine cytokine is detrimental to normal mouse development. In addition to deaths associated with expression in neurons and keratinized epithelia, bovine oncostatin M caused abnormalities in bone growth and spermatogenesis, stimulated fibrosis surrounding islets in the pancreas, and disrupted normal lymphoid tissue development. This work establishes the existence of a nonprimate oncostatin M gene and provides the first demonstration that this cytokine can function in a pleiotropic manner in vivo. Information regarding bovine oncostatin M may help characterize the structure and function of this cytokine in other vertebrate species.

The specification of neuronal fate: a common precursor for neurotransmitter subtypes in the rat cerebral cortex in vitro

Neurotransmitter choice is a crucial step in neural development. In the cerebral cortex, pyramidal neurons use the excitatory neurotransmitter glutamate, whereas non-pyramidal cells use the inhibitory neurotransmitter GABA. We are interested in how these two neuronal types are generated. We labelled precursor cells from embryonic rat cerebral cortex with a retroviral vector in dissociated cell cultures, and examined the neurotransmitter phenotype of their progeny immunohistochemically after 2 weeks in vitro. We discovered, first, that precursor cells in culture generate glutamatergic and GABAergic neurons in proportions similar to those in vivo. Second, we found that neuronal precursor cells gave rise to both GABAergic and glutamatergic neurons. These results suggest that neuronal precursor cells in the cerebral cortex have the potential to generate both neuronal subtypes. Moreover, these data are consistent with a stochastic model of neurotransmitter specification.

Getting there and being there in the cerebral cortex

The mammalian neocortex is composed of functional areas that are specified to process particular aspects of information. How is this specification achieved during development? Since cells migrate to their final positions in the developing nervous system, a central issue is the relation between cellular migration and positional information. This review combines evidence for early positional specification in the developing cortex with evidence for cellular dispersion during migration. A model is suggested whereby stable cues provide positional information and minorities of 'displaced' cells are respecified accordingly. Comparison with other parts of the CNS reveals that cellular dispersal is ubiquitous and has to be included in any mechanism relaying positional specification. Ontogenetic and phylogenetic considerations suggest that radial glial cells might provide the positional information in the developing nervous system.

Galanin expression in sympathetic ganglia after partial axotomy is highly localized to those neurons that are axotomized

The neuropeptide phenotype of adult sympathetic neurons changes dramatically after postganglionic nerve transection. Studies, thus far, have been done on the superior cervical ganglion; however, one limitation of this preparation is that it is necessary to transect the postganglionic axons quite close to the ganglion. In the present study, we examined the effects of axonal damage on galanin-like immunoreactivity in the middle and inferior cervical ganglion complex. With these ganglia, it is possible to transect postganglionic axons at a considerable distance from their cell bodies and, therefore, to examine the extent to which local tissue damage, rather than specific axonal transection, is required for these changes in neuropeptide phenotype to occur. The anatomy of this system also allowed us to determine the extent to which the changes in galanin expression are restricted to those neurons that have been axotomized. The axons of a small population of the neurons in the middle and inferior cervical ganglia complex project into the cervical sympathetic trunk. Within two days after this trunk was transected, there was an increase in the level of galanin-like immunoreactivity in the complex and in the number of immunostained principal neurons. These neurons were concentrated primarily in the most rostral part of the complex. An increase in galanin-like immunoreactivity also occurred in response to the systemic administration of the sympathetic neurotoxin 6-hydroxydopamine. In that case, many more neurons were affected than after transection of the cervical sympathetic trunk, and the neurons were distributed evenly throughout the ganglion complex.(ABSTRACT TRUNCATED AT 250 WORDS)