Axotomy-induced Down-regulation Research Articles

Regulation of the Na,K-ATPase Gamma-Subunit FXYD2 by Runx1 and Ret Signaling in Normal and Injured Non-Peptidergic Nociceptive Sensory Neurons

Dorsal root ganglia (DRGs) contain the cell bodies of sensory neurons which relay nociceptive, thermoceptive, mechanoceptive and proprioceptive information from peripheral tissues toward the central nervous system. These neurons establish constant communication with their targets which insures correct maturation and functioning of the somato-sensory nervous system. Interfering with this two-way communication leads to cellular, electrophysiological and molecular modifications that can eventually cause neuropathic conditions. In this study we reveal that FXYD2, which encodes the gamma-subunit of the Na,K-ATPase reported so far to be mainly expressed in the kidney, is induced in the mouse DRGs at postnatal stages where it is restricted specifically to the TrkB-expressing mechanoceptive and Ret-positive/IB4-binding non-peptidergic nociceptive neurons. In non-peptidergic nociceptors, we show that the transcription factor Runx1 controls FXYD2 expression during the maturation of the somato-sensory system, partly through regulation of the tyrosine kinase receptor Ret. Moreover, Ret signaling maintains FXYD2 expression in adults as demonstrated by the axotomy-induced down-regulation of the gene that can be reverted by in vivo delivery of GDNF family ligands. Altogether, these results establish FXYD2 as a specific marker of defined sensory neuron subtypes and a new target of the Ret signaling pathway during normal maturation of the non-peptidergic nociceptive neurons and after sciatic nerve injury.

Impairment of microglial responses to facial nerve axotomy in cathepsin S–deficient mice

Cathepsin S (CS) is a lysosomal/endosomal cysteine protease especially expressed in cells of a mononuclear lineage including microglia. To better understand the role of CS in microglia, we investigated microglial responses after a facial nerve axotomy in CS-deficient (CS-/-) and wild-type mice. Microglia in both groups accumulated in the facial motor nucleus following axotomy. However, the mean number of microglia in CS-/- mice on the axotomized side was significantly smaller than that in wild-type mice. Microglia were found to adhere to injured motoneurons in wild-type mice, whereas microglia abutted on injured motoneurons without spreading on their surface in CS-/- mice. At the same time, the axotomy-induced down-regulation of tenasin-R, an antiadhesive perineuronal net for microglia, was partially abrogated in CS-/- mice. Primary cultured microglia prepared from CS-/- mice showed that CS deficiency caused significant suppression of migration and transmigration of microglia. In CS-/- mice, impaired recruitments of circulating monocytes and T lymphocytes and reduced expression of the class II major compatibility complex on the axotomized side were observed. Interestingly, cathepsin B, a typical lysosomal cysteine protease, was markedly expressed on the axotomized side in CS-/- but not in wild-type microglia. Finally, we compared axotomy-induced neuronal death in the two groups and found that the percentage of motoneurons that survived in CS-/- mice was significantly smaller than that in wild-type mice. The present study strongly suggests that CS plays a role in the migration and activation of microglia to protect facial motoneurons against axotomy-induced injury.

Deletion of the neuropeptide Y Y1 receptor affects pain sensitivity, neuropeptide transport and expression, and dorsal root ganglion neuron numbers

Neuropeptide Y has been implicated in pain modulation and is substantially up-regulated in dorsal root ganglia after peripheral nerve injury. To identify the role of neuropeptide Y after axotomy, we investigated the behavioral and neurochemical phenotype of neuropeptide Y Y1 receptor knockout mice with focus on dorsal root ganglion neurons and spinal cord. Using a specific antibody Y1 receptor immunoreactivity was found in dorsal root ganglia and in dorsal horn neurons of wild-type, but not knockout mice. The Y1 receptor knockout mice exhibited a pronounced mechanical hypersensitivity. After sciatic nerve axotomy, the deletion of Y1 receptor protected knockout mice from the axotomy-induced loss of dorsal root ganglion neurons seen in wild-type mice. Lower levels of calcitonin gene-related peptide and substance P were identified by immunohistochemistry in dorsal root ganglia and dorsal horn of knockout mice, and the axotomy-induced down-regulation of both calcitonin gene-related peptide and substance P was accentuated in Y1 receptor knockout. However, the transcript levels for calcitonin gene-related peptide and substance P were significantly higher in knockout than in wild-type dorsal root ganglia ipsilateral to the axotomy, while more calcitonin gene-related peptide- and substance P-like immunoreactivity accumulated proximal and distal to a crush of the sciatic nerve. These results indicate that the deletion of the Y1 receptor causes increased release and compensatory increased synthesis of calcitonin gene-related peptide and substance P in dorsal root ganglion neurons. Together, these findings suggest that, after peripheral nerve injury, neuropeptide Y, via its Y1 receptor receptor, plays a key role in cell survival as well as in transport and synthesis of the excitatory dorsal horn messengers calcitonin gene-related peptide and substance P and thus may contribute to pain hypersensitivity.

Glial-Derived Neurotrophic Factor Upregulates Expression of Functional SNS and NaN Sodium Channels and Their Currents in Axotomized Dorsal Root Ganglion Neurons

Dorsal root ganglion (DRG) neurons produce multiple sodium currents, including several different TTX-sensitive (TTX-S) currents and TTX-resistant (TTX-R) currents, which are produced by distinct sodium channels. We previously demonstrated that, after sciatic nerve transection, the levels of SNS and NaN sodium channel alpha-subunit transcripts and protein in small (18-30 micrometer diameter) DRG neurons are reduced, as are the amplitudes and densities of the slowly inactivating and persistent TTX-R currents produced by these two channels. In this study, we asked whether glial-derived neurotrophic factor (GDNF), which has been shown to prevent some axotomy-induced changes such as the loss of somatostatin expression in DRG neurons, can ameliorate the axotomy-induced downregulation of SNS and NaN TTX-R sodium channels. We show here that exposure to GDNF can significantly increase both slowly inactivating and persistent TTX-R sodium currents, which are paralleled by increases in SNS and NaN mRNA and protein levels, in axotomized DRG neurons in vitro. We also show that intrathecally administered GDNF increases the amplitudes of the slowly inactivating and persistent TTX-R currents, and SNS and NaN protein levels, in peripherally axotomized DRG neurons in vivo. Finally, we demonstrate that GDNF upregulates the persistent TTX-R current in SNS-null mice, thus demonstrating that the upregulated persistent sodium current is not produced by SNS. Because TTX-R sodium channels have been shown to be important in nociception, the effects of GDNF on axotomized DRG neurons may have important implications for the regulation of nociceptive signaling by these cells.

The Expression of P2X3Purinoreceptors in Sensory Neurons: Effects of Axotomy and Glial-Derived Neurotrophic Factor

We have studied the distribution and regulation of the P2X3receptor (a ligand-gated ion channel activated by ATP) in adult dorsal root ganglion (DRG) neurons using a polyclonal antibody. P2X3receptor immunoreactivity was normally present in about 35% of L4/5 DRG neurons, virtually all small in diameter. In the dorsal horn, P2X3receptor expression was restricted to the terminals of sensory neurons terminating in lamina IIinner. P2X3receptors were expressed in approximately equal numbers of sensory neurons projecting to skin and viscera but in very few of those innervating skeletal muscle. P2X3receptors were found mostly in sensory neurons that bind the lectin IB4. After sciatic nerve axotomy, P2X3receptor expression dropped by more than 50% in L4/5 DRG. Glial cell line-derived neurotrophic factor (GDNF), delivered intrathecally, completely reversed axotomy-induced down-regulation of the P2X3receptor. We conclude that P2X3receptors are normally expressed in nociceptive primary sensory neurons, predominantly the nonpeptidergic nociceptors. P2X3receptors are down-regulated following peripheral nerve injury and their expression can be regulated by GDNF.

Involvement of leukemia inhibitory factor in the increases in galanin and vasoactive intestinal peptide mRNA and the decreases in neuropeptide Y and tyrosine hydroxylase mRNA in sympathetic neurons after axotomy.

In response to axonal injury, noradrenergic sympathetic neurons of the adult superior cervical ganglion (SCG) alter their neurotransmitter phenotype. These alterations include increases in the levels of the neuropeptides, galanin, vasoactive intestinal peptide (VIP), and substance P (SP) and a decrease in the catecholamine biosynthetic enzyme tyrosine hydroxylase (TH). Previous studies have indicated that after axotomy in vivo, leukemia inhibitory factor (LIF) plays an important role in increasing the contents of galanin and VIP in the SCG. In the present study, by examining the time courses of the changes in LIF and neuropeptide mRNA and by using LIF null mutant mice, we have determined that LIF alters neuropeptide content in part by increasing levels of peptide mRNA. In addition, LIF also makes a small contribution to the axotomy-induced down-regulation of mRNA encoding TH and neuropeptide Y, both of which are normally expressed at high levels in the SCG. Finally, by using a LIF-blocking antiserum, this cytokine was found to regulate SP expression in an in vitro axonal injury model. Thus, after axotomy, a single factor, LIF, participates in the down-regulation of peptides/proteins involved in normal neurotransmission and the up-regulation of a group of neuropeptides normally not present in the SCG that may be involved in regeneration.

Deletion of 3′-Untranslated Region Alters the Level of mRNA Expression of a Neurofilament Light Subunit Transgene

High levels of neurofilament (NF) mRNA expression are attained during early postnatal development and are a major determinant of axonal size. High level NF expression is also dependent upon axonal continuity since NF mRNA levels are down-regulated after nerve transection. This study shows that both postnatal up-regulation and axotomy-induced down-regulation are altered by deletion of 3'-UTR from the mouse light NF subunit (NF-L). Transgenes with (NF-L+) or without (NF-L-) 3'-UTR display similar patterns of neuron-specific expression but differ in their respective levels of expression. Whereas changes in the level of NF-L+ mRNA parallel those of the endogenous mouse NF-L mRNA, changes in the level of NF-L- mRNA differ from the pattern of endogenous NF-L expression during postnatal up-regulation and axotomy-induced down-regulation. Specifically, the NF-L- transgene undergoes a 3-fold aberrant up-regulation between embryonic days 15 (E15) and 18 (E18) and has lost its susceptibility to axotomy-induced down-regulation. Studies of transfected P19 cells show that 3'-UTR deletion leads to a severalfold stabilization of NF-L mRNA and an increase in steady-state mRNA level. The findings support the working hypothesis that the 3'-UTR contains determinants that alter stability and that stabilization of NF-L mRNA regulates the levels of NF-L mRNA in neuronal tissues and cells.

Axotomy transiently down-regulates androgen receptors in motoneurons of the spinal nucleus of the bulbocavernosus

Testosterone is an important trophic factor for motoneurons in the spinal nucleus of the bulbocavernosus (SNB), and SNB motoneurons are more responsive to testosterone than are other motoneurons. Axonal injury during early postnatal life prevents the normal development of steroid-sensitivity by adult SNB motoneurons. Axonal injury also causes changes in the expression by motoneurons of a wide range of proteins, including the up-regulation of trophic factor receptors. We have used a polyclonal antibody (PG-21; G.S. Prins) to study the expression of androgen receptors in SNB motoneurons after axonal injury. PG-21 labeled motoneuronal nuclei in the lower lumbar spinal cord of rats in a pattern that matched autoradiograpic reports of androgen accumulation in this region of the nervous system. A population of numerous, small cells located dorsal to the central canal also showed evidence of androgen receptor expression. Cutting the axons of SNB motoneurons in adulthood or in development caused a decrease in androgen receptor immunoreactivity in SNB motoneurons. This is the first report that a trophic factor receptor in motoneurons is down-regulated after axonal injury, and is interesting in light of reports that testosterone treatment can facilitate motoneuronal regeneration after nerve cut. Androgen receptor levels subsequently returned to normal, regardless of the age at axotomy, providing no evidence for a lasting effect of developmental axotomy on androgen receptor levels in SNB motoneurons. Thus, axotomy-induced down-regulation of androgen receptors does not underlie the inability of SNB motoneurons to respond to androgen treatment several months after pudendal nerve cut in development.

Plasticity of tyrosine hydroxylase and vasoactive intestinal peptide messenger RNAs in visceral afferent neurons of the nodose ganglion upon axotomy-induced deafferentation

The nodose ganglion contains placode-derived visceral sensory neurons of the vagus nerve. Previous study showed that axotomy-induced deafferentation reduced the number of tyrosine hydroxylaseimmunoreactive and increased the number of vasoactive intestinal peptide-immunoreactive neurons in the ganglion. The present study was conducted to determine whether the changes in neuropeptide/neurotransmitter enzyme content are associated with changes in the expression of tyrosine hydroxylase and vasoactive intestinal peptide messenger RNAs in the nodose ganglion. We used in situ hybridization histochemistry with 35S-labeled oligonucleotide probes for tyrosine hydroxylase and vasoactive intestinal peptide precursor messenger RNAs. Peripheral axotomy of visceral afferent inputs reduced tyrosine hydroxylase messenger RNA and increased vasoactive intestinal peptide messenger RNA expression in neurons of the nodose ganglion of the rat. The number of tyrosine hydroxylase messenger RNA-containing neurons was significantly reduced at three, seven and 14 days after axotomy-induced deafferentation compared with intact and sham-operated controls. Labeling density of tyrosine hydroxylase messenger RNA-containing neurons was significantly reduced at three and seven days. Conversely, the number of vasoactive intestinal peptide messenger RNA-containing neurons increased significantly at three, seven and 14 days, while the labeling density of vasoactive intestinal peptide messenger RNA-containing neurons also increased at one, three, seven and 14 days. The results of the present study indicate that the axotomy-induced down-regulation of tyrosine hydroxylase and up-regulation of vasoactive intestinal peptide in the neurons of the nodose ganglion are associated with changes in their messenger RNAs in response to axotomy-induced deafferentation.

Axonal dependency of the postnatal upregulation in neurofilament expression

A coordinated up-regulation in the expression of all three neurofilament (NF) proteins occurs during postnatal development in the rat (Schlaepfer and Bruce, J Neurosci Res [in press], 1990a). In the present study, sciatic nerves were transected in neonatal rats in order to determine the effects of axotomy on the postnatal upregulation of NF expression in neurons of rat dorsal root ganglia (DRG). Left sciatic nerves were transected at postnatal day 3 (P3), 6 (P6), 8 (P8), or 10 (P10). mRNA and protein levels of the light (NF-L), mid-sized (NF-M), and heavy (NF-H) NF proteins were compared in L4 and L5 DRGs from the transected (left) vs. control (right) sides of the same animals at varying intervals after transection. When nerves were transected at P10, mRNA levels of all three NF proteins declined markedly in the parent DRG neurons, thereby completely interrupting the postnatal upregulation of NF expression. P10 transections also led to widespread chromatolytic changes in axotomized neurons, indistinguishable from those that occur in adult DRG following sciatic nerve transection (Goldstein et al., J Neurosci 7:1586-1594, 1987). Nerve transections at earlier (e.g., P3) neonatal timepoints also led to a decrease of NF expression, but to a lesser extent than that which resulted from a P10 transection. Also, P3 transections caused only minimal chromatolytic changes in the axotomized neurons. Thus, the postnatal upregulation of NF expression is dependent upon axonal continuity and the extent of axonal dependency increases during early postnatal development. These findings support the hypothesis that the postnatal upregulation of NF expression, the axotomy-induced downregulation of NF expression and the chromatolytic reaction to nerve transection are all dependent upon or responsive to axonal- or target cell-derived signals that are acquired during postnatal maturation.