Muscle ciliary neurotrophic factor receptor α promotes axonal regeneration and functional recovery following peripheral nerve lesion.

Ciliary neurotrophic factor (CNTF) administration maintains, protects, and promotes the regeneration of both motor neurons (MNs) and skeletal muscle in a wide variety of models. Expression of CNTF receptor α (CNTFRα), an essential CNTF receptor component, is greatly increased in skeletal muscle following neuromuscular insult. Together the data suggest that muscle CNTFRα may contribute to neuromuscular maintenance, protection, and/or regeneration in vivo. To directly address the role of muscle CNTFRα, we selectively-depleted it in vivo by using a "floxed" CNTFRα mouse line and a gene construct (mlc1f-Cre) that drives the expression of Cre specifically in skeletal muscle. The resulting mice were challenged with sciatic nerve crush. Counting of nerve axons and retrograde tracing of MNs indicated that muscle CNTFRα contributes to MN axonal regeneration across the lesion site. Walking track analysis indicated that muscle CNTFRα is also required for normal recovery of motor function. However, the same muscle CNTFRα depletion unexpectedly had no detected effect on the maintenance or regeneration of the muscle itself, even though exogenous CNTF has been shown to affect these functions. Similarly, MN survival and lesion-induced terminal sprouting were unaffected. Therefore, muscle CNTFRα is an interesting new example of a muscle growth factor receptor that, in vivo under physiological conditions, contributes much more to neuronal regeneration than to the maintenance or regeneration of the muscle itself. This novel form of muscle-neuron interaction also has implications in the therapeutic targeting of the neuromuscular system in MN disorders and following nerve injury. J. Comp. Neurol. 521: 2947-2965, 2013. © 2013 Wiley Periodicals, Inc.

CC10 mRNA and protein expression in Clara cells of CD-1 mice following exposure to styrene or its metabolites styrene oxide or 4-vinylphenol.

Styrene, widely used in manufacturing, has both acute and chronic effects in humans. In mice, styrene is both hepato- and pneumo-toxic and causes lung tumors. The primary site for styrene metabolism and its effects in mouse lung is the Clara cell, which secretes Clara cell 10kDa protein (CC10) and surfactant protein A (SPA). Both play important roles in host defenses and inflammation prevention. The mode of action for styrene-induced lung tumor formation has yet to be elicited, yet one possibility relates to oxidative stress and decreased CC10 levels. CC10 mRNA and protein expression were measured in isolated Clara cells 3, 12, and 24h following in vivo administration of styrene (600mg/kg i.p.) or its metabolites [R-, S-, racemic styrene oxide (SO) (300mg/kg i.p.), 4-vinylphenol (100mg/kg i.p.)]. The largest decreases in CC10 mRNA expression were seen with R-SO and racemic SO at 24h. To determine if rebound effects would be seen, CC10 mRNA and protein expression were determined 48, 120, and 240h following styrene and R-SO administration. The CC10 protein level did not reach its lowest point to correlate with mRNA expression until 120h after R-SO administration. Styrene exposure caused a significant decrease in CC10 protein after 24h, rebounding through 240h. SPA protein expression showed little change from control levels, indicating a more specific effect on CC10 in the Clara cell by styrene and its metabolites. These studies demonstrate that acute changes in lung CC10 protein and mRNA expression do occur following in vivo treatment with styrene and its metabolites. These changes may be early indicators for a potential mechanism for lung tumor formation in mice as it relates to oxidative stress and the possibility deserves further study.

Conditional, genetic disruption of ciliary neurotrophic factor receptors reveals a role in adult motor neuron survival.

Indirect evidence suggests that endogenous ciliary neurotrophic factor (CNTF) receptor signaling can promote motor neuron (MN) survival in the adult. If so, proper targeting of this signaling may selectively counteract the effects of adult MN diseases. However, direct evidence for CNTF receptor involvement in adult MN survival is lacking, presumably because the unconditional blockade of the mouse CNTF receptor in vivo [through genetic disruption of the essential CNTF receptor alpha (CNTFRalpha) gene] leads to uniform perinatal death of the mice. To overcome this limitation, we have developed a method to selectively disrupt CNTF receptor function in a targeted subset of adult MNs that are not required for survival. A 'floxed CNTFRalpha' mouse line was generated and characterized. In addition, an adeno-associated virus (AAV) vector that drives Cre recombinase (Cre) expression was constructed and shown, with reporter mouse lines, to selectively excise floxed genes in facial MNs following its stereotaxic injection into the facial motor nucleus. Adult floxed CNTFRalpha mice were then injected with the AAV-Cre vector to excise the CNTFRalpha gene in the targeted MNs. The resulting data indicate that adult CNTF receptor signaling, likely by the MNs themselves, can play an essential role in MN survival. The data further indicate that this role is independent of any developmental contributions CNTF receptor signaling makes to MN survival or function.