Conditionally immortalised neural stem cells promote functional recovery and brain plasticity after transient focal cerebral ischaemia in mice

Cell therapy has enormous potential to restore neurological function after stroke. The present study investigated effects of conditionally immortalised neural stem cells (ciNSCs), the Maudsley hippocampal murine neural stem cell line clone 36 (MHP36), on sensorimotor and histological outcome in mice subjected to transient middle cerebral artery occlusion (MCAO).Adult male C57BL/6 mice underwent MCAO by intraluminal thread or sham surgery and MHP36 cells or vehicle were implanted into ipsilateral cortex and caudate 2 days later. Functional recovery was assessed for 28 days using cylinder and ladder rung tests and tissue analysed for plasticity, differentiation and infarct size.MHP36-implanted animals showed accelerated and augmented functional recovery and an increase in neurons (MAP-2), synaptic plasticity (synaptophysin) and axonal projections (GAP-43) but no difference in astrocytes (GFAP), oligodendrocytes (CNPase), microglia (IBA-1) or lesion volumes when compared to vehicle group.This is the first study showing a potential functional benefit of the ciNSCs, MHP36, after focal MCAO in mice, which is probably mediated by promoting neuronal differentiation, synaptic plasticity and axonal projections and opens up opportunities for future exploitation of genetically altered mice for dissection of mechanisms of stem cell based therapy.     

Single, high-dose 17β-estradiol therapy has anti-apoptotic effect and induces cerebral plasticity following transient forebrain ischemia in gerbils (Short communication)

Although much is known about the protective effect of acute estrogen therapy in cerebral ischemia, relatively little is known about the importance of apoptosis and cerebral plasticity in this mechanism. In this work 10 min global cerebral ischemia was produced by transient bilateral carotid occlusion in 4-month-old ovariectomized female gerbils. In every of our experimental group (sham for ischemia group, ischemia group and ischemia + a high, single dose 17β-estradiol pre-treatment group) apoptotic (bcl-Xl, bax) and cerebral plasticity (GAP-43, synapsin-I, nestin) hippocampal genes' expression was measured four days after surgery. Expression of the anti-apoptotic bcl-Xl (p<0.01) and the cerebral plasticity marker synapsin-I and nestin (p<0.01) increased with acute estrogen pretreatment in ischemic animals. No change, however, in bax or GAP-43 expression was detected in estrogen treated animals compared to ischemic gerbils. These results suggest that acute estrogen therapy has anti-apoptotic effect and increases cerebral plasticity, which play an important role in cytoprotection or cerebroprotection.     

Intrinsic Neuronal Determinants Locally Regulate Extrasynaptic and Synaptic Growth at the Adult Neuromuscular Junction

Long-term functional plasticity in the nervous system can involve structural changes in terminal arborization and synaptic connections. To determine whether the differential expression of intrinsic neuronal determinants affects structural plasticity, we produced and analyzed transgenic mice overexpressing the cytosolic proteins cortical cytoskeleton–associated protein 23 (CAP-23) and growth-associated protein 43 (GAP-43) in adult neurons.

Like GAP-43, CAP-23 was downregulated in mouse motor nerves and neuromuscular junctions during the second postnatal week and reexpressed during regeneration. In transgenic mice, the expression of either protein in adult motoneurons induced spontaneous and greatly potentiated stimulus-induced nerve sprouting at the neuromuscular junction. This sprouting had transgene-specific features, with CAP-23 inducing longer, but less numerous sprouts than GAP-43. Crossing of the transgenic mice led to dramatic potentiation of the sprout-inducing activities of GAP-43 and CAP-23, indicating that these related proteins have complementary and synergistic activities. In addition to ultraterminal sprouting, substantial growth of synaptic structures was induced. Experiments with pre- and postsynaptic toxins revealed that in the presence of GAP-43 or CAP-23, sprouting was stimulated by a mechanism that responds to reduced transmitter release and may be independent of postsynaptic activation.

These results demonstrate the importance of intrinsic determinants in structural plasticity and provide an experimental approach to study its role in nervous system function.

     

Determination of the effects on learning and memory performance and related gene expressions of clothianidin in rat models

Clothianidin (CLO) is one of the pesticides used to protect against insects, and its potential toxic effects on cognitive functions are not clearly known. This study aims to evaluate the possible effects of dose-dependent CLO on learning and memory in infant and adult male rats and the expression of related genes in the hippocampus. Doses of 2, 8 and 24 mg/kg of CLO were administered to newborn infant and adult albino Winstar rats in the form of gavage and dissolved in vehicle matter. Their cognitive and learning functions were evaluated by the Morris water maze and probe tests. Expression levels of N-methyl D-aspartate 1 (GRIN1), muscuranic receptor M1, synoptophysin (SYP) and growth-associated protein 43 (GAP-43) of tissues isolated from the hippocampus were determined using the real-time PCR method. In the Morris water maze test, no change (p > 0.05) was exhibited in the adult and infant rats after CLO was applied, although there was a significant difference (p < 0.05) in performance between infants and the control group after 24 mg/kg was applied in the probe test. Also, expression levels GRIN1, M1, SYP, GAP-43 did not change when compared to the control (p > 0.05). Our study shows that exposure to high doses of CLO causes deterioration of cognitive functions in infant rats.     

Bone marrow-derived mesenchymal stem cells improve post-ischemia neurological function in rats via the PI3K/AKT/GSK-3β/CRMP-2 pathway

Background: Transplantation of bone marrow-derived mesenchymal stem cells (BMSCs) is a potential therapy for cerebral ischemia. However, the underlying protective mechanism remains undetermined. Here, we tested the hypothesis that transplantation of BMSCs via intravenous injection can alleviate neurological functional deficits through activating PI3K/AKT signaling pathway after cerebral ischemia in rats.

Methods: A cerebral ischemic rat model was established by the 2 h middle cerebral artery occlusion (MCAO). Twenty-four hours later, BMSCs (1?×?10⁶ in 1 ml PBS) from SD rats were injected into the tail vein. Neurological function was evaluated by modified neurological severity score (mNSS) and modified adhesive removal test before and on d1, d3, d7, d10 and d14 after MCAO. Protein expressions of AKT, GSK-3β, CRMP-2 and GAP-43 were detected by Western-bolt. NF-200 was detected by immunofluorescence.

Results: BMSCs transplantation did not only significantly improve the mNSS score and the adhesive-removal somatosensory test after MCAO, but also increase the density of NF-200 and the expression of p-AKT, pGSK-3β and GAP-43, while decrease the expression of pCRMP-2. Meanwhile, these effects can be suppressed by LY294002, a specific inhibitor of PI3K/AKT.

Conclusion: These data suggest that transplantation of BMSCs could promote axon growth and neurological deficit recovery after MCAO, which was associated with activation of PI3K/AKT /GSK-3β/CRMP-2 signaling pathway.

     

Prenatal stress in rat causes long-term spatial memory deficit and hippocampus MRI abnormality: differential effects of postweaning enriched environment

Prenatal stress (PS) can cause long-term hippocampus alternations in structure and plasticity in adult offspring. Enriched environment (EE) has an effect in rescuing a variety of neurological disorders. Pregnant dams were left undisturbed (prenatal control, PC) or restrained 6h per day from days 14 to 21 (prenatal stress, PS). Control and prenatal stressed offspring rats were subjected to a standard rearing environment (SE) or an EE on postnatal days 22-120 (PC/SE PC/EE, PS/SE, and PS/EE; n=5, each group). At ～4 months of age, all rats underwent Morris water maze test and brain MRI examination. Hippocampi were then dissected for biochemical analyses, including, Western blot for NMDA receptor (NR) subunits and synaptophysin and RT-PCR forβ1 integrin and tissue-plasminogen activator (t-PA). MRI showed all 5 rats in the PS/SE group and 5 in the PS/EE group exhibited increased signals in bilateral hippocampus and increased T2 time in the PS/SE group. Exposure to EE treatment on postnatal days 22-120 counteracted the deficit in spatial memory and increased NR1 protein expression, but it did not affect the rate of high signals and increased T2 time, decreased NR2, synaptophysin, β1 integrin and t-PA mRNA expressions in PS adult offspring. The results of this study indicate PS in rats causes long-term spatial memory deficits and gross hippocampus pathology. Postnatal EE treatment has differential benefits in terms of spatial learning, signaling molecules, and gross hippocampus pathology.     

精氨酸酶Ⅰ参与环腺苷酸促进脑缺血再灌注大鼠的轴突再生

环腺苷酸（cAMP）作为细胞内的重要第二信使之一,主要通过激活下游cAMP依赖性蛋白激酶A（PKA）,进一步激活转录因子-cAMP效应元件结合蛋（CREB）,达到促进损伤轴突再生的作用.精氨酸酶Ⅰ主要是通过促进多胺的表达,从而克服髓鞘相关抑制因子对轴突再生的抑制作用,达到促进轴突再生的效果.在脑缺血中,cAMP促进轴突再生的过程是否有精氨酸酶Ⅰ的参与及其与RhoA信号通路的关系尚不清楚.本研究采用线栓法制备脑缺血再灌注模型（MACO）,采用Longa 5评分法对大鼠运动功能进行评分,利用逆转录聚合酶链反应（RT-PCR）和Western蛋白印迹方法分别检测缺血灶周边脑组织生长相关蛋白43（GAP-43）和RhoA的mRNA和蛋白表达,免疫组化法进行GAP-43的形态学检测,作为轴突再生的标志.通过尾静脉注射cAMP类似物db-cAMP增加脑缺血后大鼠脑组织内cAMP的浓度后发现：db-cAMP处理可明显降低MACO大鼠的运动功能评分,且可促进GAP-43 mRNA及蛋白的表达,抑制RhoA mRNA及蛋白的表达,由此可见db-cAMP处理可促进脑缺血后大鼠运动功能的恢复,且这一过程与抑制RhoA通路,进而促进轴突再生有关;通过在db-cAMP的基础上给予精氨酸酶Ⅰ拮抗剂NOHA来降低精氨酸酶Ⅰ的活性发现：给予NOHA的大鼠运动功能评分明显增加,这一变化趋势与RhoA mRNA及蛋白表达的变化趋势相一致,而与GAP-43 mRNA及蛋白表达的变化趋势相反. 因此可推断：精氨酸酶Ⅰ参与了db-cAMP促进轴突再生、改善脑缺血后大鼠运动功能的过程,且与钝化RhoA通路有关.     

在大鼠创伤性脑损伤模型中神经干细胞移植对突触素表达的影响

目的探讨神经干细胞（NSCs）移植对创伤性脑损伤（TBI）模型大鼠感觉运动功能的恢复作用及其对损伤脑组织中突触素（SYP）表达的影响。方法体外培养大鼠胚胎皮质NSCs;采用Feeney法制备TBI模型,于造模后72h,移植组采用PKH26荧光示踪剂标记的NSCs直接移植于脑损伤区,对照组以等量生理盐水代替NSCs;分别于移植后不同时间点,采用Gridwalk和Latency试验检测TBI大鼠的感觉运动功能;荧光显微镜下计数移植细胞的存活数量;采用免疫印迹和RT-PCR技术检测脑损伤区及周围组织中SYP的表达。结果 NSCs移植大鼠前、后肢功能分别在移植后第2w和4w恢复至手术前水平,而直到第8w,对照组大鼠后肢功能和通过平板移动时间与NSCs移植组和基线比较仍有显著性差异（P〈0.05）。移植的NSCs随移植时间延长存活数量减少,移植后第4w和8w的存活数分别为6.3%±1.0%和4.1%±0.9%。在移植后的8w期间,移植组脑损伤区及周围组织中SYP的表达均明显高于对照组（P〈0.05）。结论移植的NSCs在TBI脑内能够存活,并明显改善了TBI大鼠对侧肢体的感觉运动功能;NSCs移植促进了脑损伤区及周围组织中SYP的表达,这可能是NSCs移植促进功能恢复的机理之一。     

Palmitoylation of GAP-43 by the ER-Golgi intermediate compartment and Golgi apparatus.

Palmitoylation of the neuronal plasticity protein GAP-43 has previously been shown to occur at the plasma membrane, but the site of initial palmitoylation has not been identified. To identify this organelle we have incubated GAP-43 with various subcellular fractions and have analyzed palmitoylation by the Triton X-114 partitioning method. In vitro-translated [(35)S]methionine-labeled GAP-43 was incubated with plasma membrane, nuclei, mitochondria, Golgi apparatus and a rough microsome preparation that contained the ER-Golgi intermediate compartment (ERGIC), but not plasma membrane or Golgi apparatus. GAP-43 partitioned into Triton X-114 in the presence of plasma membrane, Golgi, and ERGIC membranes, but not nuclei or mitochondria. Partitioning caused by the ERGIC was blocked by pretreatment of the membranes with the palmitoylation inhibitors dithiothreitol, tunicamycin, and low temperature, and by treatment of GAP-43 with iodoacetamide. The time course of partitioning agreed closely with the time course of incorporation of radioactive palmitate into proteins as reported previously. Because the ERGIC has a broad distribution in the cell, our results provide evidence that the ERGIC is the initial site of GAP-43 palmitoylation.     

Effects of estrogens on choline-acetyltransferase immunoreactivity and GAP-43 mRNA in the forebrain of young and aging male rats

1. Previous work demonstrated that estradiol (E₂) treatment prevented the abnormal response to stress and the reduction of glucocorticoid receptors (GR) in hippocampus from aging male rats. The mechanisms originating these effects were unknown.2. In the present work, we investigated the E₂ effects on the cholinergic, growth-associated protein (GAP-43) expressing neurons of the medial septum (MS) and vertical limb of diagonal band of Broca (VDB). These areas project to the hippocampus, and may be involved in the mentioned E₂ effects in aging animals. Therefore, the response to E₂ of choline-acetyltransferase (ChAT) in neurons and cell processes and GAP-43 mRNA as a marker of neurite outgrowth was studied in young and old male rats.3. Young (3–4 months) and old (18–20 months) male Sprague-Dawley rats remained untreated or were implanted s.c. with a 14 mg pellet of E₂ benzoate during 6 weeks. We used immoucytochemistry to determine ChAT and isotopic in situ hybridization to analyze GAP-43 mRNA expression.4. Aging males showed a reduction in the number and length of ChAT-immunoreactive cell processes, but not in the number of positive neurons in MS and VDB. E₂ reverted both parameters in old rats to levels of young animals. Regarding basal levels of GAP-43 mRNA, they were similar in old and young animals, but E₂ treatment up-regulated GAP-43 mRNA expression in MS and VDB of old animals only.5. Our data suggest that prolonged E₂ treatment may affect hippocampal function of aging male rats by regulating in part the plasticity of cholinergic, GAP-43 expressing neurones of the basal forebrain. Without discarding a direct E₂ effect on the limbic tissue, effects on the cholinergic system may have a pronounced impact on the neuroendocrine and stress responses of the aging hippocampus.     

Phosphorylation-site mutagenesis of the growth-associated protein GAP- 43 modulates its effects on cell spreading and morphology

The 43-kD growth-associated protein (GAP-43) is a major protein kinase C (PKC) substrate of axonal growth cones, developing nerve terminals, regenerating axons, and adult central nervous system areas associated with plasticity. It is a cytosolic protein associated with the cortical cytoskeleton and the plasmalemma. Membrane association of GAP-43 is mediated by palmitoylation at Cys3Cys4. In vitro and in vivo, phosphorylation by PKC exclusively involves Ser41 of mammalian GAP-43 (corresponding to Ser42 in the chick protein). To identify aspects of GAP-43 function, we analyzed the actions of wild-type, membrane- association, and phosphorylation-site mutants of GAP-43 in nonneuronal cell lines. The GAP-43 constructs were introduced in L6 and COS-7 cells by transient transfection. Like the endogenous protein in neurons and their growth cones, GAP-43 in nonneuronal cells associated with the cell periphery. GAP-43 accumulated in the pseudopods of spreading cells and appeared to interact with cortical actin-containing filaments. Spreading L6 cells expressing high levels of recombinant protein displayed a characteristic F-actin labeling pattern consisting of prominent radial arrays of peripheral actin filaments. GAP-43 had dramatic effects on local surface morphology. Characteristic features of GAP-43-expressing cells were irregular cell outlines with prominent and numerous filopodia. The effects of GAP-43 on cell morphology required association with the cell membrane, since GAP-43(Ala3Ala4), a mutant that failed to associate with the cell cortex, had no morphogenetic activity. Two GAP-43 phosphorylation mutants (Ser42 to Ala42 preventing and Ser42 to Asp42 mimicking phosphorylation by PKC) modulated the effects of GAP-43 in opposite ways. Cells expressing GAP- 43(Asp42) spread extensively and displayed large and irregular membranous extensions with little filopodia, whereas GAP-43(Ala42) produced small, poorly spreading cells with numerous short filopodia. Therefore, GAP-43 influences cell surface behavior and phosphorylation modulates its activity. The presence of GAP-43 in growing axons and developing nerve termini may affect the behavior of their actin- containing cortical cytoskeleton in a regulatable manner.     

Differential Changes in the Phosphorylation of the Protein Kinase C Substrates Myristoylated Alanine-Rich C Kinase Substrate and Growth-Associated Protein-43/B-50 Following Schaffer Collateral Long-Term Potentiation and Long-Term Depression

Activation of protein kinase C (PKC) is one of the biochemical pathways thought to be activated during activity-dependent synaptic plasticity in the brain, and long-term potentiation (LTP) and long-term depression (LTD) are two of the most extensively studied models of synaptic plasticity. Here we have examined changes in the in situ phosphorylation level of two major PKC substrates, myristoylated alanine-rich C kinase substrate (MARCKS) and growth-associated protein (GAP)-43/B-50, after pharmacological stimulation or induction of LTP or LTD in the CA1 field of the hippocampus. We find that direct PKC activation with phorbol esters, K+-induced depolarization, and activation of metabotropic glutamate receptors increase the in situ phosphorylation of both MARCKS and GAP-43/B-50. The induction of LTP increased the in situ phosphorylation of both MARCKS and GAP-43/B-50 at 10 min following high-frequency stimulation, but only GAP-43/B-50 phosphorylation remained elevated 60 min after LTP induction. Furthermore, blockade of LTP induction with the NMDA receptor antagonist D-2-amino-5-phosphonopentanoic acid prevented elevations in GAP-43/B-50 phosphorylation but did not prevent the elevation in MARCKS phosphorylation 10 min following LTP induction. The induction of LTD resulted in a reduction in GAP-43/B-50 phosphorylation but did not affect MARCKS phosphorylation. Together these findings show that activity-dependent synaptic plasticity elicits PKC-mediated phosphorylation of substrate proteins in a highly selective and coordinated manner and demonstrate the compartmentalization of PKC-substrate interactions. Key Words: Protein kinase C-Myristoylated alanine-rich C kinase substrate-Growth-associated protein-43-Long-term potentiation-Long-term depression-(RS)-alpha-Methyl-4-carboxyphenylglycine-D-2-Amino-5-ph osphonopentanoic acid-Glutamate.     

Patterns of aberrant sprouting in Alzheimer's disease.

Alzheimer's disease (AD) is characterized by extensive synaptic and neuronal loss and by plaque formation in the cortex, but the mechanisms responsible for synaptic plasticity in the neocortex are still not completely understood. To analyze the sprouting response in AD cortex, we compared the patterns of GAP-43 with synaptophysin immunoreactivity. In AD, GAP-43 immunohistochemistry revealed extensive sprouting in the hippocampal molecular layer, stratum polymorphous, CA1 region, and prosubiculum. These regions presented abundant anti-GAP-43-immunoreactive coiled fibers and dystrophic neurites in association with plaques. Some of these sprouting structures were colocalized with anti-synapto-physin- and anti-neurofilament-positive neurites. The AD neocortex was characterized by an overall decrease in GAP-43 immunoreactivity accompanied by sprouting neurites in the areas of synaptic pathology. We conclude that GAP-43 might be involved in the mechanisms of synaptic plasticity in the AD cortex, as well as in the process of aberrant sprouting in the neuritic plaques.     

Gonadal Steroid Regulation of Growth-Associated Protein GAP-43 mRNA Expression in Axotomized Hamster Facial Motor Neurons

Treatment with testosterone propionate (TP) after nerve injury is known to accelerate both the rate of axonal regeneration and functional recovery from facial paralysis in the adult male hamster. Peripheral nerve injury is also known to increase the expression of a 43 kilodalton growth-associated protein (GAP-43). In the intact brain, GAP-43 expression is affected by gonadal steroids. We thus postulated that steroidal modulation of GAP-43 gene expression may be a component of the neurotrophic action of TP in regenerating neurons. This issue was examined in hamster facial motor neurons (FMN) which contain androgen receptors and which have been shown to respond to exogenous steroids in a number of previous studies. Castrated adult male hamsters were subjected to right facial nerve transection and treated with either TP via subcutaneous hormone capsule implants, or left untreated (no hormone replacement). At post-injury/treatment times of 0.25, 2, 4, 7, and 14 d, the brain stem regions were harvested, cryostat sections were collected through the facial motor nucleus, and in situ hybridization was done using a ³³P-labeled GAP-43 cDNA probe. Quantitative analysis of the autoradiograms by computer assisted grain counting revealed that axotomy produced a dramatic increase in GAP-43 mRNA levels in FMN by 2 d post-axotomy and that this increase remained through 14 d post-injury in both the TP-treated and the untreated group. In the nonhormone-treated group, there was a statistically significant dip in GAP-43 mRNA levels in FMN at 7 d post-operative, relative to 4 d post-operative levels. TP-treatment prevented this transient decline in GAP-43 mRNA levels in axotomized FMN.     

Long-Term Moderate Dose Exogenous Erythropoietin Treatment Protects from Intermittent Hypoxia-Induced Spatial Learning Deficits and Hippocampal Oxidative Stress in Young Rats

Exposure to intermittent hypoxia (IH) is associated with cognitive impairments and oxidative stress in brain regions involved in learning and memory. In earlier studies, erythropoietin (EPO) showed a neuroprotective effect in large doses. The aim of the present study was to explore the effect of smaller doses of EPO, such as those used in the treatment of anemia, on IH-induced cognitive deficits and hippocampal oxidative stress in young rats. The effect of concurrent EPO treatment (500 and 1,000 IU/kg/day ip) on spatial learning and memory deficits induced by long-term exposure to IH for 6 weeks was tested using the Morris water maze (MWM) test and the elevated plus maze (EPM) test. Moreover, the effect on hippocampal glutamate and oxidative stress were assessed. Exposure to IH induced a significant impairment of spatial learning and cognition of animals in both MWM and EPM performance parameters. Moreover, hippocampal glutamate and thiobarbituric acid reactive substances (TBARS) increased while antioxidant defenses (GSH and GSH-Px) decreased. EPO in the tested doses significantly reduced the IH-induced spatial learning deficits in both MWM and EPM tests and dose-dependently antagonized the effects of IH on hippocampal glutamate, TBARS, GSH levels, and GSH-Px activity. Treatment with EPO in moderate doses that used for anemia, concurrently with IH exposure can antagonize IH-induced spatial learning deficits and protect hippocampal neurons from IH-induced lipid peroxidation and oxidative stress-induced damage in young rats, possibly through multiple mechanisms involving a potential antioxidative effect.     

IT Delivery of ChABC Modulates NG2 and Promotes GAP-43 Axonal Regrowth After Spinal Cord Injury

Chondroitin sulphate proteoglycans (CSPGs) with the major component NG2 have an inhibitory effect on regeneration of damaged axons after spinal cord injury. In this study, we investigate whether the digestion of CSPGs by chondroitinase ABC (ChABC) may decrease the NG2 expression and promote axon regrowth through the lesion site. Rats underwent spinal cord compression injury and were treated with ChABC or vehicle through an intrathecal catheter delivery at 2, 3, and 4 days after injury. In addition, animals were behaviorally scored using BBB test in weekly intervals after SCI. Based on immunocytochemical analyses, we have quantified distribution of NG2 glycoprotein and GAP-43 in spinal cord tissue in both experimental groups. Multiple injections of ChABC caused decrease of NG2 expression at lesion site at 5 and 7 days, but not at 14 and 28 days in comparison with vehicle-treated rats and significantly enhanced GAP-43 expression during the entire survival. The densitometry analysis showed significantly higher GAP-43 immunoreactivity (1.8–2.2-fold) in the regrowing axons and cell bodies within the central lesion cavity when compared with vehicle group. Longitudinally oriented and disorganized GAP-43-labeled axons were able to infiltrate and penetrate damaged tissue. The outgrowth of GAP-43 axons after CHABC delivery was significantly longer (≤0.457 mm) when compared with the length of axons in vehicle-treated rats (≤0.046 mm). Present findings suggest that degradation of NG2 with acute IT ChABC treatment may promote ongoing (long-lasting) axonal regenerative processes at late survival (14 and 28 days), but with no significant impact on the improvement of motor function.     

Increased expression of GAP-43 in small sensory neurons after stimulation by NGF indicative of neuroregeneration in capsaicin-treated rats.

Intraplantar injections of human recombinant nerve growth factor (rhNGF-beta) into the hind paw of capsaicin-treated adult rats are known to lead to a recovery of depleted peptide transmitter substances, to the immunohistochemical reappearance of peptidergic innervation in the skin and in the dorsal horn of the spinal cord, as well as to a recovery of the function of capsaicin-lesioned neurons. In the present study a marker peptide for neuronal regeneration and outgrowth, growth associated protein 43 (GAP-43), was investigated in lumbar dorsal root ganglia (DRGs) and in the hindpaw skin, in order to differentiate which population of the sensory neurons responds with a neuroregenerative behaviour. In situ hybridization histochemistry (ISH) revealed that at day 8 after the capsaicin treatment GAP-43 expression was significantly increased in small DRG cells as compared to control animals, and treatment with NGF in capsaicinized rats lead to an even more pronounced increase of GAP-43 expression in the small-sized cell population. Intraepidermal labelling of GAP-43 peptide was observed in the skin of control animals, but was markedly reduced in the animals that were treated with capsaicin alone. However, intraepidermal GAP-43 immunoreactive (GAP-43-IR) fibres nearly fully recovered in the capsaicin + NGF-treated group. These results indicate that the population of small DRG cells shows spontaneous regenerative activity after a capsaicin lesion which does not lead to a successful recovery of nerve terminals in the skin. Only after an additional NGF treatment small DRG cells show an even stronger regenerative response which now also involves structural reorganization of neuron membranes and axogenesis in the periphery.