Abstract
Ciliary neurotrophic factor (CNTF) is an abundant cytosolic molecule in myelinating Schwann cells of adult rodents. In newborn animals in which CNTF is not yet expressed, exogenous CNTF that is locally administered very effectively protects motoneurons from degeneration by axotomy. To evaluate whether endogenous CNTF, released after nerve injury from the cytosol of Schwann cells, supports motoneuron survival, we transected the facial nerve in 4-week-oldpmn mice. In this mouse mutant a rapidly progressing degenerative disease of motoneurons starts by the third postnatal week at the hindlimbs and progresses to the anterior parts of the body, leading to death by the seventh to eighth week. Apoptotic death of motoneurons can be observed during this period, as revealed by TUNEL staining. In 6-week-old unlesioned pmn mice ∼40% of facial motoneurons have degenerated. Facial nerve lesion dramatically increased the number of surviving motoneurons in pmnmice. This protective effect was absent in pmn mice lacking endogenous CNTF. Quantitative analysis of leukemia inhibitory factor (LIF) mRNA expression revealed that the dramatic upregulation seen in wild-type mice after peripheral nerve lesion did not occur inpmn mice. Therefore, endogenous LIF cannot compensate for the lack of CNTF in pmn crossbred with CNTF knock-out mice. Thus, endogenous CNTF released from lesioned Schwann cells supports the survival of axotomized motoneurons under conditions in which motoneurons are in the process of rapid degeneration.
- ciliary neurotrophic factor
- leukemia inhibitory factor
- CNTF
- LIF
- motoneurons
- facial nucleus
- nerve lesion
- axotomy
- cell death
- apoptosis
Ciliary neurotrophic factor (CNTF) was discovered as a component of embryonic chick eye that supported the survival of isolated ciliary neurons in culture (Adler et al., 1979;Barbin et al., 1984). On the basis of these studies it was assumed that this factor is produced and secreted from target cells innervated by ciliary neurons. Further investigations demonstrated that CNTF has a much broader spectrum of actions, including sensory, sympathetic, and motoneurons. The identification of very high levels of CNTF-like biological activity in the sciatic nerve of adult animals was thought to represent CNTF transported retrogradely from target tissues of responsive neurons (Manthorpe and Varon, 1985; Manthorpe et al., 1986). The subsequent molecular cloning of CNTF (Lin et al., 1989;Stöckli et al., 1989) revealed that the CNTF protein lacks a hydrophobic leader sequence and is not secreted from transfected cells (Lin et al., 1989; Stöckli et al., 1989). Intense CNTF immunoreactivity was identified in the cytosol of Schwann cells of adult rat peripheral nerves (Stöckli et al., 1991; Rende et al., 1992). Moreover, CNTF mRNA expression in skeletal muscle was below the detection limit (Stöckli et al., 1989), and CNTF mRNA expression in peripheral nerves proved to be extremely low during the physiological cell death period of CNTF responsive neurons (Stöckli et al., 1991). CNTF expression in peripheral nerves is increasing continuously between the end of the first and fourth postnatal week. The developmental time course of CNTF production in Schwann cells, together with the observation that CNTF has a very effective protective action on axotomized motoneurons in newborn animals, has led to the hypothesis that the abundant CNTF protein in adult myelinating Schwann cells could act as a lesion factor after nerve injury (Sendtner et al., 1992c, 1994). However, studies in which peripheral nerves were lesioned in CNTF knock-out mice (Masu et al., 1993; Sendtner et al., 1996) were inconclusive, because most of the motoneurons survived in these mice after a lesion at an age of 4 weeks. This probably is attributable to the fact that in the later postnatal phase axotomy-initiated degeneration of motoneurons occurs much more slowly. Thus the lesion-mediated enhanced synthesis of other neurotrophic factors such as leukemia inhibitory factor (LIF), brain-derived neurotrophic factor (BDNF), glial-derived neurotrophic factor (GDNF), and insulin-like growth factor-I (IGF-I) comes into play, which occurs with some delay after lesion and thus no longer permits the rescue of motoneurons in newborn animals in which motoneuron degeneration occurs more rapidly (Meyer et al., 1992;Sendtner et al., 1992a; Yan et al., 1992; Hughes et al., 1993; Ishii et al., 1993; Koliatsos et al., 1993; Cheema et al., 1994; Henderson et al., 1994; Zurn et al., 1994; Li et al., 1995; Oppenheim et al., 1995;Trupp et al., 1995).
To analyze the function of CNTF as a lesion factor, we transected facial nerves in 4-week-old pmn mice (Schmalbruch et al., 1991; Sendtner et al., 1992b). In this mouse mutant motoneurons degenerate rapidly at this age, and a lesion factor becoming available immediately could be assumed to have a protective effect. Indeed, facial nerve lesion in 4-week-old pmn mutant mice prevented motoneuron cell death. The rescue effect was reduced dramatically inpmn mice lacking CNTF, indicating that the endogenous CNTF rescues motoneurons from cell death after nerve lesion.
MATERIALS AND METHODS
pmn and CNTF knock-out mice. Homozygous CNTF-deficient female mice on a 129/SV × C57BL/6 genetic background (Masu et al., 1993) were crossbred with pmnheterozygous mice (NMRI genetic background). F1 animals were crossbred, and F2 offspring were tested for homozygous pmn mice. Only animals from F2 and successive generations were used in this study. The CNTF gene mutation was detected by Southern blot analysis from tail biopsies, as described (Masu et al., 1993). Mice heterozygous for thepmn mutation could be detected only by their offspring, and these mice were used for expanding the mouse colony used in this study.pmn mice on this mixed genetic background showed a similar phenotype to those on the NMRI genetic background. The first signs of disease were observed by muscle weakness of hindlimbs between postnatal day 16 and 20, and the mice died after the fourth postnatal week by respiratory failure. Homozygous pmn mice lacking CNTF did not differ from pmn/CNTF +/+ mice with respect to development of first disease symptoms, course of the disease, postnatal survival, or other obvious parameters.
Facial nerve transection. pmn and control littermates were weaned at an age of 3 weeks, and facial nerve transection was performed unilaterally at an age of 28 d. They were anesthetized deeply with ether, and the facial nerve was exposed on the right side after the skin behind the ear was sectioned. At a position ∼1 mm distal to the foramen stylomastoideum, the nerve was transected with fine scissors. The distal nerve stump was deflected, and the skin wound was closed with silk (Ethicon 6–0). The effect of facial nerve transection was detectable by unilateral absence of whisker movement. At 42 d, the mice were killed by an overdose of anesthetics and fixed by transcardial perfusion with 4% paraformaldehyde in 0.1 m phosphate buffer, pH 7.2.
Histological analysis. Brain and brainstem were prepared from perfused mice and post-fixed for at least 3 additional hours in the same fixative. The brainstem was embedded in paraffin, and serial sections (7 μm) were prepared and Nissl-stained, as described (Sendtner et al., 1990; Masu et al., 1993). The number of facial motoneurons exhibiting Nissl structure and a clearly detectable nucleolus was counted in every fifth section. Correction for split nucleoli was applied, as described previously (Masu et al., 1993). Briefly, the diameters of nucleoli were determined in facial motoneurons both on the lesioned and unlesioned sides in each animal, and the raw neuronal counts were corrected according to the formula by Abercrombie.
Terminal deoxynucleotidyl transferase-mediated dUTP-X nick end labeling (TUNEL) staining. For quantitative determination of apoptotic cells in the facial nucleus of pmn mice, paraffin serial sections (7 μm) were prepared from brainstems of 28-d-oldpmn/CNTF +/+ (n = 4) and pmn/CNTF −/− mice (n = 2). The right facial nerve in these mice had been transected at postnatal day 21. After Nissl staining the facial nuclei were identified on both sides, and all sections spanning this anatomical region were used for further analysis. Sections were destained and rehydrated by washing in xylene and subsequent incubation in 100, 95, 90, 80, and 70% ethanol. Then slides were rinsed with PBS for 30 min and incubated with permeabilization solution (0.1% Triton X-100 in 0.1% sodium citrate) for 2 min on ice (4°C). After rinsing the slides twice with PBS, we added the TUNEL reaction mixture [containing terminal deoxynucleotidyl transferase (TdT) and fluorescin-dUTP] for 60 min at 37°C, according to the manufacturer’s instructions (In Situ Cell Death Kit, AP, Boehringer Mannheim, Mannheim, Germany). Slides were rinsed three times with PBS and incubated with anti-fluorescin antibody conjugated with alkaline phosphatase for 30 min at 37°C. To avoid evaporation and consequent destruction of the sections, we performed both incubation steps in a humidified chamber, and we protected the sections with a coverslip. Sections then were rinsed three times with PBS before the chromogen/substrate solution (New Fuchsin Substrate System, Dako, Hamburg, Germany) was added for 10 min at room temperature. Levamisole was added at a concentration of 1 mm for blocking endogenous AP activity.
Slides finally were mounted with coverslips and analyzed under the light microscope. The number of apoptotic residues was counted in each section of the facial nuclei both on the unlesioned and lesioned sides.
Determination of LIF mRNA. Total RNA was isolated from the sciatic nerves of 3-week-old pmn and control mice. A LIF-specific primer (5′-ACGGTACTTGTTGCACAGAC) was annealed at 70°C to 100 ng of RNA, and a reverse transcription reaction was started by the addition of Superscript II reverse transcriptase (Life Technologies, Eggenstein, Germany) according to the manufacturer’s instructions. Sciatic nerve RNA was added individually in tubes containing a serially decreasing amount of LIF RNA standard. This RNA standard, which functions as a competitor in the subsequent PCR, was identical to the LIF sequence except for an internal deletion of 81 bases (Sendtner et al., 1996). An aliquot of the resulting cDNA was amplified in a standard PCR with the forward primer 5′-ACCCTGTAAATGCCACCTG (located in exon 2) and the reverse primer 5′-CAACGACCATTGCTGAGGAGG (located in exon 3 of the LIF gene). The amplification product obtained thus from sciatic nerve RNA was 378 bp long; the competitor RNA gave rise to a 297 bp reaction product. Because the concentration of the tissue RNA was kept constant in each reaction and the concentration of the competitor was varied, the resulting PCR products were at equimolar concentrations when both RNA hybridization signals were of equivalent density in autoradiograms hybridized with a specific LIF cDNA probe.
Quantification of CNTF in nerve extracts by Western blot, ELISA, and bioassay. Sciatic and facial nerves were obtained from 28-d-old mice, shock-frozen in liquid nitrogen, and stored at −70°C until use. The individual nerves were thawed in a hypotonic buffer (5 mm NaPi and 30 mm NaCl, pH 7.0) and homogenized in a glass/glass homogenizer. After centrifugation for 15 min at 13,500 × g, the supernatants were removed, and the protein content was determined by Bradford’s Coomassie blue protein assay (Bio-Rad, Munich, Germany). Sciatic or facial nerve protein (15 μg) derived from individual animals was applied per lane on a 15% polyacrylamide gel under reducing conditions. Molecular mass markers (5 μg each of lysozyme, 14.3 kDa; trypsinogen, 24 kDa; and ovalbumin, 45 kDa; Sigma, Deisenhofen, Germany) and recombinant rat CNTF (Masiakowski et al., 1991) at different concentrations were coelectrophoresed in separate lanes. After they were blotted to nitrocellulose membranes (Schleicher & Schüll, Dassel, Germany) for 75 min at 150 mA with a semi-dry blotting apparatus (Fröbel Labortechnik, Lindau, Germany), the blots were blocked with Tris-buffered saline containing 5% horse serum and were incubated with the monoclonal CNTF antibody 4–68 hybridoma supernatant at a dilution of 1:50. The blots were washed three times, incubated with secondary antibody (affinity-purified goat anti-mouse IgG), and (H+L) horseradish peroxidase conjugate (Bio-Rad). After three washes the immunoreactive bands were visualized with 4-chloro-1-naphthol.
Sciatic nerves from 4-week-old control (n = 12) andpmn (n = 9) mice were prepared, and protein extracts were prepared as described above. In all, 5 μg of each protein extract was subjected to ELISA analysis by applying a commercial assay kit (R & D Systems, Wiesbaden, Germany). Recombinant rat CNTF was used as a standard, and 100 pg was added to 5 μg of each protein extract solution and analyzed in parallel as a recovery standard. Values were corrected by the calculated recovery, which was in the range of 50–80%.
Ciliary ganglia were prepared from 8-d-old chick embryos. After incubation in 0.1% trypsin in Ca/Mg-free PBS for 30 min at 37°C, the ganglia were washed three times with 5 ml of ice-cold F14 containing 10% horse serum (Sendtner et al., 1992c). Single-cell suspensions were obtained by trituration via a siliconized Pasteur pipette, and the cells were preplated for 2.5 hr for the enrichment of neuronal cells on a cell culture-treated plastic dish (10 cm; Nunc, Wiesbaden, Germany). The nonattached ciliary neurons were collected and plated at a density of 1000 cells per 16 mm culture dish in polyornithine/laminin-coated 24-multiwell dishes (Costar, Bodenheim, Germany). F14 medium containing 10% horse serum was used as a culture medium. The protein extracts from pmn and control nerves were added at different concentrations from 10 to 2500 ng. Surviving neurons were counted 24 hr after plating, and maximal survival (in the order of 90% of plated cells) was observed with 10 ng/ml of recombinant rat CNTF. To determine the specificity of this assay, we added 4 μg of purified IgG from a neutralizing rabbit CNTF antiserum (K10) per milliliter of culture medium to the highest concentration of each nerve extract sample. The addition of these antibodies abolished the survival response of the nerve extracts by >90% but did not reduce survival effects of bFGF or IGF-I (data not shown). These data indicate that the nerves obtained from these mice did not contain an additional ciliary neuronal survival-promoting activity at concentrations up to 2500 ng/ml culture medium, as has been observed previously with nerve extracts from CNTF +/+ mice (Masu et al., 1993). The protein concentration (ng/ml) supporting half-maximal survival was defined as 1 trophic unit (TU) and corresponded to ∼10 pg of pure recombinant rat CNTF.
In each group nerves from 3–12 animals were examined, and all determinations were done in duplicate. The values shown in Figure 1represent the mean ± SEM. Student’s t test was applied for statistical analysis of the results.
RESULTS
CNTF protein levels and bioactivity in the sciatic and facial nerve of pmn mice
To investigate whether endogenous expression of CNTF is altered inpmn mice, we determined levels of CNTF protein in sciatic and facial nerves of 4-week-old pmn and control mice obtained from the same litters by Western blot analysis. Figure1a shows that the intensity of CNTF immunoreactive bands was similar in mutant and wild-type mice of the same genetic background. There was a slight reduction of the signal intensity in the distal (Fig. 1, lane 4), as compared with the proximal (Fig. 1, lane 5), sciatic nerve inpmn mice. This probably reflects the downregulation of CNTF production occurring after the “dying back” of motor axons, which is a specific feature of the disease process in this mouse mutant. The intensity of CNTF reactive bands in facial nerves of pmnmice was slightly lower in comparison to control mice from the same litters, reflecting the loss of axons and subsequent demyelination and downregulation of endogenous CNTF synthesis. CNTF protein levels also were determined by ELISA (Fig. 1c). In sciatic nerves of 4-week-old control mice (n = 12), 95.7 ± 21.11 ng/mg protein (mean ± SEM) was measured in pmn mice (n = 9) 87.1 ± 16.4 ng/mg. The difference between the two groups was not statistically significant (p = 0.76 by two-tailed t test).
Similar results were obtained when CNTF biological activity in nerve extracts was tested by bioassay with embryonic chick ciliary neurons. Half-maximal survival of ciliary neurons in culture was achieved at 50–200 ng/ml of either pmn or control sciatic nerve extracts. Slightly lower levels of CNTF bioactivity were detected in nerve extracts from pmn mice. However, this difference was not statistically significant (p values of 0.18 and 0.25 for sciatic and facial nerve extracts; n was at least 6 for control nerves and at least 20 for pmn facial and sciatic nerves), indicating that CNTF biological activity and expression levels were comparable in control and pmnmice.
LIF mRNA is not upregulated in lesioned sciatic nerves ofpmn mice
After sciatic nerve lesion in adult rats, LIF mRNA is upregulated rapidly in the proximal and distal nerve stump (Curtis et al., 1994). In unlesioned sciatic nerves of adult rats (Curtis et al., 1994) and mice (Sendtner et al., 1996), levels of LIF mRNA are very low. In our study a more than fivefold increase of LIF mRNA expression was observed in both the proximal and the distal part of the sciatic nerve at 24 hr after transection in 3-week-old control mice (Fig.2a). Interestingly, LIF mRNA was not upregulated in lesioned sciatic nerves of pmn mice from the same litters (Fig. 2b). The absolute levels of LIF mRNA in lesioned sciatic nerves in pmn mice were so low (<3000 molecules of LIF mRNA per 100 ng of total mRNA extracted from the proximal and distal parts of the lesioned nerves) that LIF is unlikely to contribute to the survival of lesioned motoneurons in these mutant mice.
Lesion of the facial nerve in the mouse mutant pmnleads to increased motoneuron survival
To investigate whether peripheral nerve lesion affects motoneuron survival in 4-week-old pmn or control mice, we transected the facial nerve, and we prepared the brainstem region containing the facial nuclei from the unlesioned and the lesioned side 2 weeks later. In paraffin serial sections of this region, morphological appearance and the number of motoneurons were determined on both the lesioned and unlesioned sides. In comparison to control mice, the number of motoneurons was reduced by 40% (p < 0.005) on the unlesioned side (Table 1). These values are consistent with earlier studies (Sendtner et al., 1992b;Sagot et al., 1995), reflecting the degeneration of motoneurons during the disease process caused by the pmn mutation. Furthermore, most of the remaining motoneurons showed severe atrophic changes, such as reduction in Nissl structure, shrinkage, and displacement of nuclei (Fig. 3c).
In contrast to the unlesioned side, motoneuron numbers on the lesioned side (Fig. 3d) were significantly higher (Table 1). In comparison to control mice, the reduction in motoneuron number was much lower and did not reach statistical significance (p > 0.05). This indicates that the mechanisms initiated by the nerve lesion prevented the degeneration of the axotomized motoneurons.
The effect of nerve lesion on motoneuron survival inpmn mice is dependent on endogenous CNTF
To evaluate whether CNTF becoming available to the axotomized motoneurons from lesioned Schwann cells is responsible for the rescue of motoneurons after nerve lesion, we produced mice lacking endogenous CNTF by crossbreeding the pmn mice with CNTF −/− mice. In the F2 and F3 generation, animals homozygous both for the CNTF mutation and the pmn gene defect were obtained. These mice were compared with CNTF +/+ pmn/pmn and CNTF +/−pmn/pmn mice after nerve lesion at postnatal day 28. In contrast to pmn mice with endogenous CNTF expression, lesion of the facial nerve did not lead to a significant rescue of motoneurons (Fig. 3e,f). In comparison to the lesioned side, only 14% more motoneurons were detectable in comparison to 37% in CNTF +/− pmn/pmn mice and 57% in CNTF +/+ pmn/pmnmice (Table 1). This indicates that the lack of endogenous CNTF leads to a significantly reduced motoneuron survival after peripheral nerve lesion.
Loss of motoneurons in pmn mutant mice occurs by apoptosis
Serial sections of brainstems from 5-week-old CNTF +/+pmn/pmn mice and CNTF −/− pmn/pmn mice were prepared and analyzed by TUNEL staining.
In ∼120 sections spanning the facial nucleus of 4-week-old CNTF +/+pmn/pmn mice, 15.0 ± 3.9 (mean ± SEM,n = 4) TUNEL-positive cells were detected on the left unlesioned side. The low number of apoptotic cell bodies reflects the narrow time window during which TUNEL-positive cells can be detected. We assume that the loss of 900 neurons on the unlesioned side (Table 1) occurs during a period of at least 2 weeks so that, on average, ∼65 facial motoneurons degenerate per day in the facial nucleus ofpmn mice. It is known that dying cells are eliminated rapidly in the CNS. For example, a clearance time of 1 hr for pyknotic oligodendrocytes has been calculated (Barres et al., 1992). Thus the average number of 15.0 ± 3.9 apoptotic cells in the facial nucleus on the unlesioned side suggests that apoptotic motoneurons are eliminated within 5–6 hr in pmn mice. The significantly lower number of 4.3 ± 0.9 apoptotic cell on the lesioned side (p < 0.05 by Student’s t test, unpaired) is another proof that nerve lesion reduces the extent of apoptosis in the facial nucleus of pmn mice. In CNTF −/−pmn mice (n = 2), on average, 14 apoptotic neurons were seen both on the unlesioned (Fig.4e,f) and lesioned sides. These data support the observation that facial nerve lesion significantly can reduce the death of lesioned motoneurons in CNTF +/+ pmn mice, but not in CNTF −/− pmnmice.
DISCUSSION
We have shown previously that the injection of CNTF-producing cells into the peritoneal cavity of 3-week-old homozygous pmn mutant mice markedly prolongs survival and improves motor performance (Sendtner et al., 1992b). This is paralleled by a corresponding reduction in motoneuron loss in the facial nucleus and in myelinating nerve fibers in the phrenic nerve. Subsequent studies by Sagot et al. (1995) that used encapsulated cell implants producing CNTF after subcutaneous implantation confirmed and extended these results insofar as it could be shown that these mice survived for periods up to several months in comparison to untreated mice that die of respiratory failure between 5 and 7 weeks after birth.
However, it is not a lack of endogenous CNTF that leads to neurodegeneration in pmn mice. CNTF protein levels inpmn mice and control mice are similar. Levels equivalent to 100 ng CNTF/mg of extractable protein are present in the sciatic nerves of both control and pmn mice. This corresponds to the levels previously determined in lesioned and unlesioned peripheral nerves of adult rats (Sendtner et al., 1992c). In terms of biological activity, 3991 ± 1038 (mean ± SEM, n = 20) TUs of CNTF activity were detected in the facial nerve and 8191 ± 2250 (mean ± SEM, n = 20) in the sciatic nerve ofpmn mice. One trophic unit of CNTF supports half-maximal survival of responsive neurons in 1 ml of cell culture medium. Therefore, the levels of CNTF protein in the lesioned nerves are very high, and only small quantities need to be released by the nerve transection to provide sufficient local concentrations of the factor to support injured motoneurons. However, it cannot be excluded that the release of CNTF also leads to local cellular reactions in the peripheral nerve, in particular in Schwann cells and probably also in invading inflammatory cells expressing gp 130 and LIFR β. Soluble CNTFRα from the circulation or from Schwann cells then would help to form functional CNTF receptors on these cells and lead to complex cellular responses that either directly or indirectly result in the local production of neurotrophic factors that contribute in supporting motoneuron survival.
Nevertheless, the high quantities of CNTF in peripheral nerves of adult rodents, which are at least 1000 times higher than the levels of NGF (Heumann et al., 1987a,b), suggest that a direct effect of CNTF on lesioned motoneurons is very likely. For its rescue effect inpmn motoneurons, very little CNTF is necessary. For comparison, the levels of CNTF bioactivity in the circulation of CNTF tumor cell-treated pmn mice were in the range of 500 TUs/ml serum, corresponding to ∼5–10 ng of CNTF/ml of blood (Sendtner et al., 1992b). This indicates that the endogenous CNTF in untreatedpmn mice is highly abundant in comparison to the low levels of pharmacologically applied CNTF, which effectively prolonged survival and improved motor function. The only explanation for this apparent discrepancy is that the endogenous CNTF cannot rescue motoneurons, because it is not available to these cells under normal conditions.
After sciatic nerve lesion in adult rats, CNTF mRNA expression is downregulated rapidly in Schwann cells distal to the lesion site (Friedman et al., 1992; Sendtner et al., 1992c; Seniuk et al., 1992). The CNTF protein levels and bioactivity decreased much more slowly, and substantial quantities of CNTF protein and bioactivity were maintained at the lesion site and in the distal nerve stump. Moreover, CNTF immunoreactivity was detectable at sites associated with myelin breakdown products and basal membranes (Sendtner et al., 1992c). We have concluded from these findings that at least part of the CNTF at these sites seems to be extracellular and thus is available to lesioned neurons.
Mice were produced by homologous recombination in embryonic stem cells that lack endogenous CNTF (Masu et al., 1993). These mice develop normally during the first weeks after birth, but then ∼20% of the facial motoneurons degenerate between 8 weeks and 6 months of age. Peripheral nerve lesion in such mice does not lead to major loss of motoneurons (Sendtner et al., 1996), most probably because LIF mRNA is upregulated in the lesioned nerve (Curtis et al., 1994) and can act on motoneurons via LIFRβ and gp 130, the two signal-transducing receptor subunits that are identical in CNTF, LIF, and cardiotrophin (CT-1) receptors (for review, see Stahl and Yancopoulos, 1994). However, the levels of LIF mRNA are extremely low in unlesioned peripheral nerves (Curtis et al., 1994; Sendtner et al., 1996). Moreover, the rapid upregulation of LIF mRNA usually found after nerve lesion in adult rats and mice does not occur in pmn mice. This could explain why LIF does not rescue motoneurons in pmn mice via CNTF receptors. Nerve lesion in 4-week-old CNTF/LIF double knock-out mice leads to a significant loss of >30% of the lesioned motoneurons (Sendtner et al., 1996). This indicates that adult motoneurons still depend on these Schwann cell-derived neurotrophic factors for their survival after axotomy. Moreover, nerve root avulsion in adult mice that removes the peripheral nerves, including the Schwann cells, results in significant motoneuron death in adult mice (Li et al., 1995), whereas the more peripheral nerve transection does not. Together, these data indicate that Schwann cells provide survival factors to lesioned motoneurons and that CNTF plays an important role in these processes.
Nothing is known so far about the expression of cardiotrophin-1, another member of the CNTF/LIF family of neurotrophic cytokines (Pennica et al., 1995a,b, 1996) in adult peripheral nerves after lesion. This factor, although lacking a conventional hydrophobic signal peptide, has been reported to be released from muscle cells and thus to be a strong candidate as a target-derived neurotrophic factor for developing motoneurons (Pennica et al., 1996). It will be interesting to determine whether CT-1 expression is reduced in pmn mice, because the disease starts at the motor end plate (Schmalbruch et al., 1991), and the lack of target-derived neurotrophic factors supporting the maintenance of these specific synapses could play an essential role in the pathogenesis of the disease.
We have performed nerve lesions in 4-week-old pmn mice and find that the lesion protects motoneurons from degeneration to a similar extent as exogenous CNTF treatment (Sendtner et al., 1992b;Sagot et al., 1995). Furthermore, the number of TUNEL-positive cell bodies is reduced significantly on the lesioned side in comparison to the control side in these mutant mice. In contrast, most of the axotomized motoneurons in pmn mice lacking endogenous CNTF degenerate at a similar ratio to that in unlesioned motoneurons. We conclude from this finding that significant quantities of CNTF are released from injured Schwann cells after nerve lesion and that the factor is then available to the axons of the lesioned neurons. Furthermore, CNTF promotes survival of the lesioned adult motoneurons. This demonstrates that the CNTF located in the cytosol of myelinating Schwann cells can act as a lesion factor once it is released by nerve damage.
Footnotes
This work was initiated at the Max-Planck-Institut for Psychiatry in Martinsried and completed at the Department of Neurology, University of Würzburg. This study was supported by the Deutsche Forschungsgemeinschaft, Grant To 61/8, and the Bundesministerium für Bildung und Forschung, Grant 01 KO 9403. We thank Georg Kreutzberg for many helpful comments and discussions; Patrick Carroll for helping with the genotyping of the CNTF −/− mice; and Waltraud Komp, Heike Döppler, and Anita Kraiss for technical assistance.
Correspondence should be addressed to Dr. Michael Sendtner, Clinical Research Unit for Neuroregeneration, Department of Neurology, University of Würzburg, Josef-Schneider-Strasse 11, D-97080 Würzburg, Germany.