Differential Cyclin D1 Requirements of Proliferating Schwann Cells during Development and after Injury

Neurons regulate Schwann cell proliferation, but little is known about the molecular basis of this interaction. We have examined the possibility that cyclin D1 is a key regulator of the cell cycle in Schwann cells. Myelinating Schwann cells express cyclin D1 in the perinuclear region, but after axons are severed, cyclin D1 is strongly upregulated in parallel with Schwann cell proliferation and translocates into Schwann cell nuclei. During development, cyclin D1 expression is confined to the perinuclear region of proliferating Schwann cells and the analysis of cyclin D1-null mice indicates that cyclin D1 is not required for this type of Schwann cell proliferation. As in the adult, injury to immature peripheral nerves leads to translocation of cyclin D1 to Schwann cell nuclei and injury-induced proliferation is impaired in both immature and mature cyclin D1-deficient Schwann cells. Thus, our data indicate that the molecular mechanisms regulating proliferation of Schwann cells during development or activated by axonal damage are fundamentally different.     

Proliferation of Schwann cells and regulation of cyclin D1 expression in an animal model of Charcot-Marie-Tooth disease type 1A

Overexpression of PMP22 is responsible for the most common form of inherited neuropathy, Charcot-Marie-Tooth disease (CMT) type 1A. The PMP22-transgenic rat (CMT rat) is an animal model of CMT1A, and its peripheral nerves show the characteristic features of ongoing demyelination and remyelination that is also seen in CMT1A patients. Since Schwann cell proliferation is a prominent feature of peripheral nerves in inherited peripheral neuropathies, we examined proliferation and the expression of cyclin D1 in CMT rats. D-type cyclins are required for the initial steps in cell division and nuclear import is crucial for the function of cyclin D1 in promoting cell proliferation. Like normal myelinating Schwann cells in wild-type rats, remyelinating Schwann cells in CMT rats show perinuclear cyclin D1 expression. Schwann cells with nuclear cyclin D1 expression, as well as proliferating Schwann cells, were both associated with demyelinated axonal segments. Supernumerary onion bulb Schwann cells, however, do not express cyclin D1 and were not proliferating. Thus, cyclin D1 expression and its subcellular localization correlate directly with distinct physiological states of Schwann cells in this animal model of CMT1A.     

Multipotentiality of Schwann cells in cross-anastomosed and grafted myelinated and unmyelinated nerves: quantitative microscopy and radioautography.

Cross-anastomoses and autogenous grafts of unmyelinated and myelinated nerves were examined by electron microscopy and radioautography to determine if Schwann cells are multipotential with regard to their capacity to produce myelin or to assume the configuration seen in unmyelinated fibres. Two groups of adult white mice were studied. (A) In one group, the myelinated phrenic nerve and the unmyelinated cervical sympathetic trunk (CST) were cross-anastomosed in the neck. From 2 to 6 months after anastomosis, previously unmyelinated distal stumps contained many myelinated fibres while phrenic nerves joined to proximal CSTs became largely unmyelinated. Radioautography of distal stumps indicated that proliferation of Schwann cells occurred mainly in the first few days after anastomosis but was also present to a similar extent in isolated stumps. (B) In other mice, CSTs were grafted to the myelinated sural nerves in the leg. One month later, the unmyelinated CSTs became myelinated and there was no radioautographic indication of Schwann cell migration from the sural nerve stump to the CST grafts. Thus, Schwann cell proliferation in distal stumps is an early local response independent of axonal influence. At later stages, axons from the proximal stumps cause indigenous Schwann cells in distal stumps from the previously unmyelinated nerves to produce myelin while Schwann cells from the previously unmyelinated nerves to produce myelin while Schwann cells from the previously myelinated nerves become associated with unmyelinated fibres. Consequently, the regenerated distal nerve resembled the proximal stump. It is suggested that this change is possible because Schwann cells which divide after nerve injury reacquire the developmental multipotentiality which permits them to respond to aoxonal influences.     

Transforming growth factor beta 1, a cytokine with regenerative functions

We review the biology and role of transforming growth factor beta 1(TGF-β1) in peripheral nerve injury and regeneration, as it relates to injuries to large nerve trunks(i.e., sciatic nerve, brachial plexus), which often leads to suboptimal functional recovery. Experimental studies have suggested that the reason for the lack of functional recovery resides in the lack of sufficient mature axons reaching their targets, which is a result of the loss of the growth-supportive environment provided by the Schwann cells in the distal stump of injured nerves. Using an established chronic nerve injury and delayed repair animal model that accurately mimics chronic nerve injuries in humans, we summarize our key findings as well as others to better understand the pathophysiology of poor functional recovery. We demonstrated that 6 month TGF-β1 treatment for chronic nerve injury significantly improved Schwann cell capacity to support axonal regeneration. When combined with forskolin, the effect was additive, as evidenced by a near doubling of regenerated axons proximal to the repair site. We showed that in vivo application of TGF-β1 and forskolin directly onto chronically injured nerves reactivated chronically denervated Schwann cells, induced their proliferation, and upregulated the expression of regeneration-associated proteins. The effect of TGF-β1 and forskolin on old nerve injuries is quite impressive and the treatment regiment appears to mediate a growth-supportive milieu in the injured peripheral nerves. In summary, TGF-β1 and forskolin treatment reactivates chronically denervated Schwann cells and could potentially be used to extend and prolong the regenerative responses to promote axonal regeneration.     

Postnatal Schwann cell proliferation but not myelination is strictly and uniquely dependent on cyclin-dependent kinase 4 (cdk4)

Peripheral myelin formation depends on axonal signals that tightly control proliferation and differentiation of the associated Schwann cells. Here we demonstrate that the molecular program controlling proliferation of Schwann cells switches at birth. We have analyzed the requirements for three members of the cyclin-dependent kinase (cdk) family in Schwann cells using cdk-deficient mice. Mice lacking cdk4 showed a drastic decrease in the proliferation rate of Schwann cells at postnatal days 2 and 5, but proliferation was unaffected at embryonic day 18. In contrast, ablation of cdk2 and cdk6 had no significant influence on postnatal Schwann cell proliferation. Taken together, these findings indicate that postnatal Schwann cell proliferation is uniquely controlled by cdk4. Despite the lack of the postnatal wave of Schwann cell proliferation, axons were normally myelinated in adult cdk4-deficient sciatic nerves. Following nerve injury, Schwann cells lacking cdk4 were unable to re-enter the cell cycle, while Schwann cells deficient in cdk2 or cdk6 displayed proliferation rates comparable to controls. We did not observe compensatory effects such as elevated cdk4 levels in uninjured or injured nerves of cdk2 or cdk6-deficient mice. Our data demonstrate that prenatal and postnatal Schwann cell proliferation are driven by distinct molecular cues, and that postnatal proliferation is not a prerequisite for the generation of Schwann cell numbers adequate for correct myelination.     

Proliferating immature Schwann cells contribute to nerve regeneration after ischemic peripheral nerve injury

Schwann cells exhibit a high degree of plasticity in adult peripheral nerves after mechanical injury; they have, therefore, been implicated in promoting nerve regeneration. However, Schwann cell behavior after ischemic injury has not yet been elucidated. To determine how Schwann cell plasticity may contribute to recovery from ischemic neuropathy, we used a rat model in which ischemia was induced in the tibial nerve by a 5-hour occlusion of the supplying arteries. Proliferation of immature Schwann cells that emerged in the injured nerve was evaluated by double immunostaining for the p75 neurotrophin receptor and proliferating cell nuclear antigen. The number of proliferating cell nuclear antigen/p75 neurotrophin receptor double-positive cells increased significantly in 1 to 2 weeks after ischemia and subsequently decreased by 4 weeks. During this time, the postmitotic Schwann cells differentiated into mature cells, as demonstrated with bromodeoxyuridine incorporation, which facilitated axon guidance and subsequent axon remyelination. These results suggest the emergence and proliferation of immature Schwann cells that contribute to nerve regeneration after ischemic injury. The manipulation of this population of proliferating immature Schwann cells may be a useful strategy for treating ischemic peripheral neuropathy.     

MMP‐9 controls Schwann cell proliferation and phenotypic remodeling via IGF‐1 and ErbB receptor‐mediated activation of MEK/ERK pathway

Phenotypic remodeling of Schwann cells is required to ensure successful regeneration of damaged peripheral axons. After nerve damage, Schwann cells produce an over 100‐fold increase in metalloproteinase‐9 (MMP‐9), and therapy with an MMP inhibitor increases the number of resident (but not infiltrating) cells in injured nerve. Here, we demonstrate that MMP‐9 regulates proliferation and trophic signaling of Schwann cells. Using in vivo BrdU incorporation studies of axotomized sciatic nerves of MMP‐9?/? mice, we found increased Schwann cell mitosis in regenerating (proximal) stump relative to wild‐type mice. Treatment of cultured primary Schwann cells with recombinant MMP‐9 suppressed their growth, mitogenic activity, and produced a dose‐dependent, biphasic, and selective activation of ERK1/2, but not JNK and p38 MAPK. MMP‐9 induced ERK1/2 signaling in both undifferentiated and differentiated (using dbcAMP) Schwann cells. Using inhibitors to MEK and trophic tyrosine kinase receptors, we established that MMP‐9 regulates Ras/Raf/MEK—ERK pathways through IGF‐1, ErbB, and PDGF receptors. We also report on the early changes of MMP‐9 mRNA expression (within 24 h) after axotomy. These studies establish that MMP‐9 controls critical trophic signal transduction pathways and phenotypic remodeling of Schwann cells. © 2009 Wiley‐Liss, Inc.     

Schwann cell multiplication after crush injury of unmyelinated fibers.

The intensity and duration of Schwann cell multiplication in unmyelinated fibers after crush injury of cervical sympathetic trunks (CSTs) in adult mice was studied using radioautography and electron microscopy. At the level of crush, labeling indexes rose to 22.5% on the second day after injury, but distal to this level, labeling reached a peak of only 2.5%. By the ninth day labeling declined to 1% or less at both sites. Electron microscopy confirmed that the increase in nuclei at the crush was mainly an increase in Schwann cells. Thus, the intensity of Schwann cell multiplication differed between crush and distal sites along the same unmyelinated nerve. The Schwann cell proliferation in the distal CSTs was less intense than that reported in previous studies on myelinated nerves.     

The expression of the low affinity nerve growth factor receptor in long-term denervated Schwann cells

Schwann cells in the distal stump of injured peripheral nerves synthesize the low affinity nerve growth factor receptor (p75). In this study we used short-term (1 week) and long-term (1-12 months) transected distal sciatic nerves of rats to determine the variations of p75 expression by using immunocytochemistry and in situ hybridization. Semi-quantitative analysis revealed that the synthesis of the protein product of the p75 gene is rapidly enhanced to reach a peak within the 1 month after denervation. After that it gradually decreased and was barely detectable 6 months following denervation. Double immunocytochemistry for p75 and the S100 protein revealed that p75 immunoreactivity is confined to the Schwann cells. Quantitative analysis of our in situ hybridization experiments revealed that the upregulation of the p75 mRNA parallels the enhanced synthesis of the corresponding protein and reaches a peak within 1 month, which is maintained until the second month after the transection and declines thereafter to reach background levels at 4 months. The electron microscopic observations reveal that the increase in the number of nuclei in the distal stump belong to severely atrophied Schwann cells and fibroblasts. Since the presence of p75 in the Schwann cells is necessary for reinnervation, our results indicate that, based on the expression of p75, the Schwann cells will provide a most suitable environment for the regenerating axons up to the first month. At later stages the ability of the Schwann cells to synthesize p75 and cell adhesion proteins such as N-CAM and GAP 43 decreases which may be one of the factors that contribute to poor functional recovery if the regenerating axons reach the distal stump after long periods of time. GLIA 20:87-100, 1997. © 1997 Wiley-Liss Inc.     

Schwann cells express erythropoietin receptor and represent a major target for Epo in peripheral nerve injury

Erythropoietin (Epo) expresses potent neuroprotective activity in the peripheral nervous system; however, the underlying mechanism remains incompletely understood. In this study, we demonstrate that Epo is upregulated in sciatic nerve after chronic constriction injury (CCI) and crush injury in rats, largely due to local Schwann cell production. In uninjured and injured nerves, Schwann cells also express Epo receptor (EpoR), and its expression is increased during Wallerian degeneration. CCI increased the number of Schwann cells at the injury site and the number was further increased by exogenously administered recombinant human Epo (rhEpo). To explore the activity of Epo in Schwann cells, primary cultures were established. These cells expressed cell-surface Epo receptors, with masses of 71 and 62 kDa, as determined by surface protein biotinylation and affinity precipitation. The 71-kDa species was rapidly but transiently tyrosine-phosphorylated in response to rhEpo. ERK/MAP kinase was also activated in rhEpo-treated Schwann cells; this response was blocked by pharmacologic antagonism of JAK-2. RhEpo promoted Schwann cell proliferation, as determined by BrdU incorporation. Cell proliferation was ERK/MAP kinase-dependent. These results support a model in which Schwann cells are a major target for Epo in injured peripheral nerves, perhaps within the context of an autocrine signaling pathway. EpoR-induced cell signaling and Schwann cell proliferation may protect injured peripheral nerves and promote regeneration.     

蛛网膜下腔移植自体激活许旺细胞治疗大鼠脊髓损伤***

背景：许旺细胞能够分泌多种神经营养因子,促进脊髓损伤功能的恢复。但异体许旺细胞移植可引发自身免疫反应,且在移植方式上,局部移植无法避免二次损伤,静脉移植虽可以透过血脊髓屏障到达损伤局部,但不能达到有效的治疗浓度。 目的：探讨经蛛网膜下腔移植自体激活许旺细胞对脊髓损伤大鼠功能恢复的影响。 方法：66只大鼠均建立脊髓损伤模型,造模后随机分为3组,自体激活许旺细胞组通过结扎单侧隐神经从而激活许旺细胞,自体未激活许旺细胞组、模型对照组仅在相同部位手术但不结扎神经。切除各组手术远端1 cm神经,采用组织块法进行许旺细胞的体外分离培养及纯化。1周后,自体激活许旺细胞组、自体未激活许旺细胞组分别通过蛛网膜下腔注入经Hoechst33342标记的对应许旺细胞悬液,模型对照组仅注入等量DMEM。对脊髓损伤后肢体功能的恢复进行BBB运动功能评分及脚印分析,通过苏木精-伊红染色和GFAP染色从组织学角度评价脊髓损伤恢复情况。 结果与结论：从术后第4周开始,自体激活许旺细胞组BBB后肢功能评分明显优于另两组(P < 0.05)。移植后2周,可见迁移至大鼠脊髓损伤局部的许旺细胞。与自体未激活许旺细胞组比较,移植后5周自体激活许旺细胞组的前后足中心距离、后肢第3足趾外旋角度均显著减小(P < 0.05),移植后13周损伤区胶质瘢痕面积明显减小(P < 0.05),损伤区空洞面积明显减小(P < 0.05)。证实经蛛网膜下腔移植自体激活许旺细胞可以促进脊髓损伤的恢复。     

Gene transfer to schwann cells after peripheral nerve injury: A delivery system for therapeutic agents

We transferred a reporter gene to Schwann cells to test whether they might serve as an endoneurial delivery system for therapeutic proteins. A replication-defective adenoviral vector carrying the gene for β-galactosidase (lacZ) was injected into the distal segment of intact or crushed sciatic nerves of adult rats, and the expression of lacZ was histochemically assessed. Less than 1% of the Schwann cells became reactive in intact nerves, but up to 18% of the proliferating Schwann cells of injured nerves expressed lacZ. Gene expression decayed with time but might persist for up to 2 months. It was enhanced by immunosuppression: daily cyclosporin A injections reduced both proliferation of Schwann cells and lymphocytic infiltration of the nerve, whereas tolerance induced by a single intrathymic injection of the vector 4 days after birth abolished the inflammatory response but not the proliferation of Schwann cells. The vector itself did not impede axonal regeneration. The results indicate that adenoviral gene transfer to Schwann cells in injured nerves is possible and suggest that induced production of neurotrophic factor may represent a therapeutic supplement to surgical nerve repair.     

Quantitation of Schwann cells and endoneurial fibroblast-like cells after experimental nerve trauma

Summary Schwann cells and endoneurial fibroblastlike cells were quantitatied for 30 weeks in both nonregenerating and freely regenerating, transected rat sciatic nerve. Immunocytochemical recognition of S-100 protein was used as a marker for Schwann cells and other immunocytochemical and histological methods in the differentiation of S-100 protein-negative endoneurial cells in cross sections of the distal stump 10 mm distal to the site of transection. A marked increase in the total number of cells was observed during the first 4 weeks after the injury in both operative groups. The quantitative relationships between cell populations remained essentially the same as in normal nerves, although the proliferation of the S-100 protein-negative cell population was proportionately slightly stronger when compared to the number of these cells in normal nerves. After the initial proliferation, a gradual decrease occurred in the total number of cells per cross section. This was most marked in the non-regenerating nerves, whereas in the regenerating nerves the decrease in cell number ceased at 16 weeks. The number of Schwann cells was 3.5 times as high as in the control nerves in this phase. The method used in the present study is less laborious than morphometry employing electron microscopy. Furthermore, electron microscopic characteristics of endoneurial cells are not always reliable after nerve trauma, because normal anatomical relationships have become disturbed. This study demonstrates that S-100 protein immunocytochemistry is useful in the study of traumatic lesions of peripheral nerve.Supported by a grant (to V. S.) from the Research and Science Foundation of Farmos and by institutional grants from the Sigrid Jusélius Foundation and the Turku University Foundation     

p38 MAPK activation promotes denervated Schwann cell phenotype and functions as a negative regulator of Schwann cell differentiation and myelination

Physical damage to the peripheral nerves triggers Schwann cell injury response in the distal nerves in an event termed Wallerian degeneration: the Schwann cells degrade their myelin sheaths and dedifferentiate, reverting to a phenotype that supports axon regeneration and nerve repair. The molecular mechanisms regulating Schwann cell plasticity in the PNS remain to be elucidated. Using both in vivo and in vitro models for peripheral nerve injury, here we show that inhibition of p38 mitogen-activated protein kinase (MAPK) activity in mice blocks Schwann cell demyelination and dedifferentiation following nerve injury, suggesting that the kinase mediates the injury signal that triggers distal Schwann cell injury response. In myelinating cocultures, p38 MAPK also mediates myelin breakdown induced by Schwann cell growth factors, such as neuregulin and FGF-2. Furthermore, ectopic activation of p38 MAPK is sufficient to induce myelin breakdown and drives differentiated Schwann cells to acquire phenotypic features of immature Schwann cells. We also show that p38 MAPK concomitantly functions as a negative regulator of Schwann cell differentiation: enforced p38 MAPK activation blocks cAMP-induced expression of Krox 20 and myelin proteins, but induces expression of c-Jun. As expected of its role as a negative signal for myelination, inhibition of p38 MAPK in cocultures promotes myelin formation by increasing the number as well as the length of individual myelin segments. Altogether, our data identify p38 MAPK as an important regulator of Schwann cell plasticity and differentiation.     

Overexpression of P2X4 receptor in Schwann cells promotes motor and sensory functional recovery and remyelination via BDNF secretion after nerve injury

Of the seven P2X receptor subtypes, P2X4 receptor (P2X4R) is widely distributed in the central nervous system, including in neurons, astrocytes, and microglia. Accumulating evidence supports roles for P2X4R in the central nervous system, including regulating cell excitability, synaptic transmission, and neuropathic pain. However, little information is available about the distribution and function of P2X4R in the peripheral nervous system. In this study, we find that P2X4R is mainly localized in the lysosomes of Schwann cells in the peripheral nervous system. In cultured Schwann cells, TNF-a not only enhances the synthesis of P2X4R protein but also promotes P2X4R trafficking to the surface of Schwann cells. TNF-a-induced BDNF secretion in Schwann cells is P2X4R dependent. in vivo experiments reveal that expression of P2X4R in Schwann cells of injured nerves is strikingly upregulated following nerve crush injury. Moreover, overexpression of P2X4R in Schwann cells by genetic manipulation promotes motor and sensory functional recovery and accelerates nerve remyelination via BDNF release following nerve injury. Our results suggest that enhancement of P2X4R expression in Schwann cells after nerve injury may be an effective approach to facilitate the regrowth and remyelination of injured nerves.     

Lysophosphatidic acid promotes the proliferation of adult Schwann cells isolated from axotomized sciatic nerve

We have previously found that adult Schwann cells express receptors for lysophosphatidic acid (EDG2, EDG7) and sphingosine-1-phosphate (EDG5) and that expression of these receptors is significantly upregulated in injured sciatic nerve coincident with postaxotomy Schwann cell proliferation. Based on these observations, we hypothesized that lysophosphatidic acid and/or sphingosine-1-phosphate promote Schwann cell mitogenesis in injured adult nerve. We found that both saturated and unsaturated forms of lysophosphatidic acid, but not sphingosine-1-phosphate, induce DNA synthesis in adult Schwann cells isolated from surgically transected sciatic nerve. Lysophosphatidic acid induces adult Schwann cell DNA synthesis in a dose-dependent manner, acting at 0.1- to 10-microM concentrations. Lysophosphatidic acid-mediated stimulation of adult Schwann cell DNA synthesis occurs via a signaling pathway involving a pertussis toxin-sensitive (G(i)/G(o)) G-protein. Activation of phosphatidylinositol-3-kinase, cAMP-dependent protein kinase A and mitogen-activated protein kinase kinase is also required for lysophosphatidic acid-induced Schwann cell mitogenesis. These findings demonstrate that lysophosphatidic acid promotes proliferation of adult Schwann cells isolated from injured nerve and are consistent with the hypothesis that lysophosphatidic acid promotes in vivo Schwann cell mitogenesis in regenerating peripheral nerve.