Succinate dehydrogenase activity in rat dorsolateral ventral horn motoneurons at L6 after spaceflight and recovery

Succinate dehydrogenase (SDH) activity levels of motoneurons in the rostral, middle, and caudal portions of the dorsolateral region of the ventral horn of the 6th lumbar (L6) segment of the rat spinal cord were determined after 14 days of spaceflight and after 9 days of recovery on Earth. The mean SDH activity of motoneurons with cell body sizes between 500 and 800 micrometers2 located in the rostral portion of the L6 segment was lower in spaceflight than in age-matched control rats. The decrease in motoneuron SDH activity persisted for at least 9 days of recovery on Earth. In contrast, the mean SDH activity of motoneurons located in the middle and caudal portions of the L6 segment were unaffected by spaceflight and recovery on Earth. The motoneurons in the rostral portion of the L6 segment presumably innervate both high- and low-oxidative fibers in hindlimb muscles, whereas those in the middle and caudal portions presumably innervate perineal muscles that are comprised only of low-oxidative fibers. These data indicate that moderate-sized motoneurons, most likely innervating fibers in high-oxidative muscles, are responsive to the microgravity environment.     

Decreased Succinate Dehydrogenase Activity of Gamma and Alpha Motoneurons in Mouse Spinal Cords Following 13 Weeks of Exposure to Microgravity

Cell body size and succinate dehydrogenase activity of motoneurons in the dorsolateral region of the ventral horn in the lumbar and cervical segments of the mouse spinal cord were assessed after long-term exposure to microgravity and compared with those of ground-based controls. Mice were housed in a mouse drawer system on the International Space Station for 13 weeks. The mice were transported to the International Space Station by the Space Shuttle Discovery and returned to Earth by the Space Shuttle Atlantis. No changes in the cell body size of motoneurons were observed in either segment after exposure to microgravity, but succinate dehydrogenase activity of small-sized (<300 μm²) gamma and medium-sized (300–700 μm²) alpha motoneurons, which have higher succinate dehydrogenase activity than large-sized (>700 μm²) alpha motoneurons, in both segments was lower than that of ground-based controls. We concluded that exposure to microgravity for longer than 3 months induced decreased succinate dehydrogenase activity of both gamma and slow-type alpha motoneurons. In particular, the decreased succinate dehydrogenase activity of gamma motoneurons was observed only after long-term exposure to microgravity.     

Cell Body Size and Succinate Dehydrogenase Activity of Spinal Motoneurons Innervating the Soleus Muscle in Mice, Rats, and Cats

The cell body sizes and succinate dehydrogenase (SDH) activities of motoneurons in the retrodorsolateral region of the ventral horn in the spinal cord innervating the soleus muscle in mice, rats, and cats were compared using quantitative enzyme histochemistry. There was an inverse relationship between cell body size and SDH activity of motoneurons in the three species. The mean cell body sizes of both gamma and alpha motoneuron pools were in the rank order of mice < rats < cats, while the mean SDH activities of both gamma and alpha motoneuron pools were in the rank order of mice > rats > cats. It is concluded that smaller motoneurons innervating the soleus muscle have higher SDH activities than larger motoneurons, irrespective of the species, and that motoneuron pools innervating the soleus muscle in smaller animals have smaller mean cell body sizes and higher mean SDH activities than those in larger animals.     

Effects of hindlimb suspension on soleus muscle fibers and their spinal motoneurons in Wistar Hannover rats

Cross-sectional areas and succinate dehydrogenase (SDH) activities of soleus muscle fibers and their spinal motoneurons in male Wistar Hannover rats were determined after 16 days of hindlimb suspension. A decreased percentage of type I fibers and an increased percentage of type I+II fibers were observed after hindlimb suspension. Cross-sectional areas of all types of fibers were smaller in the hindlimb suspended than control rats. SDH activities of all types of fibers did not change after hindlimb suspension. Numbers, cross-sectional areas, or SDH activities of spinal motoneurons did not change after hindlimb suspension. It is suggested that spinal motoneurons innervating the rat soleus muscle are not affected by decreased neuromuscular activity on Earth and that gravity itself is important for maintaining of spinal motoneuron metabolic properties.     

Distribution of Calcitonin Gene-Related Peptide in Rat and Rabbit Spinal Cords: Effect of Intrathecal 5,7-Dihydroxytryptamine

Calcitonin gene-related peptide-like immunoreactivity (CGRP-LI) was measured in selected regions of the cervical, thoracic, and lumbar spinal cord of untreated rabbits and, following intrathecal injection of the serotonergic neurotoxin 5,7-dihydroxytryptamine (5,7-DHT), in the thoracolumbar cord in rats using a sheep antiserum raised against tyrosine0 calcitonin gene-related peptide28-37. In the cervical, thoracic, and lumbar segments of the rabbit spinal cord, CGRP-LI levels were 15-50-fold higher in the dorsal than in the ventral grey region in the same segment. The only segmental variation in CGRP-LI levels was in the dorsal white region, where levels in the thoracic cord were lower than those in cervical or lumbar segments. Within individual spinal segments, the pattern of distribution of CGRP-LI in the rabbit spinal cord was analogous to that in other species previously examined, including rat, human, and cat spinal cord. Intrathecal injection of 5,7-DHT, which caused 85-91% depletion of 5-hydroxytryptamine and 5-hydroxyindoleacetic acid from the thoracolumbar ventral spinal cord, did not affect choline acetyltransferase activity, which is colocalized with CGRP in motoneurones in this spinal cord region. In contrast, intrathecal 5,7-DHT produced a threefold increase in CGRP-LI in the ventral thoracolumbar cord, suggesting that spinal motoneurones selectively increase production of CGRP 10 days after neurotoxin-induced denervation of bulbospinal raphe neuronal input.     

A Threshold Dose of Heavy Ion Radiation that Decreases the Oxidative Enzyme Activity of Spinal Motoneurons in Rats

The effect of heavy ion radiation exposure of the spinal cord on the properties of the motoneurons innervating the slow soleus and fast plantaris muscles was investigated. A 15-, 20-, 40-, 50-, or 70-Gy dose of carbon ions (5 Gy/min) was applied to the 2nd to the 6th lumbar segments of the spinal cord in rats. After a 1-month recovery period, the number and cell body size of the irradiated motoneurons innervating the soleus and plantaris muscles did not differ from that of the non-irradiated controls, irrespective of the dose received. However, the oxidative enzyme activity of these motoneurons was decreased by heavy ion radiation at doses of 40, 50, and 70 Gy compared to that of the non-irradiated controls. This decrease in oxidative enzyme activity levels in the motoneurons returned to that of the non-irradiated controls after a 6-month recovery period. We conclude that heavy ion radiation at doses of 40–70 Gy reversibly decreases the oxidative enzyme activity of motoneurons in the spinal cord of rats.     

The Beneficial Effects of Treadmill Step Training on Activity-Dependent Synaptic and Cellular Plasticity Markers After Complete Spinal Cord Injury

Several studies have shown that treadmill training improves neurological outcomes and promotes plasticity in lumbar spinal cord of spinal animals. The morphological and biochemical mechanisms underlying these phenomena remain unclear. The purpose of this study was to provide evidence of activity-dependent plasticity in spinal cord segment (L5) below a complete spinal cord transection (SCT) at T8-9 in rats in which the lower spinal cord segments have been fully separated from supraspinal control and that subsequently underwent treadmill step training. Five days after SCT, spinal animals started a step-training program on a treadmill with partial body weight support and manual step help. Hindlimb movements were evaluated over time and scored on the basis of the open-field BBB scale and were significantly improved at post-injury weeks 8 and 10 in trained spinal animals. Treadmill training also showed normalization of withdrawal reflex in trained spinal animals, which was significantly different from the untrained animals at post-injury weeks 8 and 10. Additionally, compared to controls, spinal rats had alpha motoneuronal soma size atrophy and reduced synaptophysin protein expression and Na(+), K(+)-ATPase activity in lumbar spinal cord. Step-trained rats had motoneuronal soma size, synaptophysin expression and Na(+), K(+)-ATPase activity similar to control animals. These findings suggest that treadmill step training can promote activity-dependent neural plasticity in lumbar spinal cord, which may lead to neurological improvements without supraspinal descending control after complete spinal cord injury.     

Effect of local depression of inhibition on intercentral relations in the rat spinal cord

Changes in spinal reflexes of rats were studied after the formation of local depression of inhibition (a "determining dispatch station" of paroxysmal activity), generating an increased excitation wave, by means of tetanus toxin. Tonic and rhythmic paroxysmal activity generated in the poisoned half of the lumbar segments was shown to evoke discharges of all spinal and bulbar motoneurons with certain temporal characteristics. Depression of unit activity in the focus with glycine abolished this phenomenon. Excitation of the focus created on one side of the cervical segments evoked a pathologically increased scratch reflex of the ipsilateral hind limb, unconnected with a disturbance of inhibition of lumbar motoneurons. The focus had enhanced excitatory and inhibitory effects on monosynaptic reflexes of lumbar flexor motoneurons. The role of local depression of inhibition in the function of the nervous system is discussed.     

Distribution of the fibers of the descending respiratory pathway in the phrenic nucleus of the cat

A distribution of degenerated fibers in contralateral phrenic nucleus of cats with chronic hemisection of the spinal cord under medulla oblongata has been studied. These fibers approach the nucleus after the partial secondary crossing of the descending respiratory pathway on the level of cervical segments. Degenerated fibers follow the dendrites of phrenic motoneurons and approach the basal segments of dendrites but do not reach the cell bodies. Possible mode of control over phrenic nucleus activity is under discussion.     

肝细胞生长因子在正常大鼠腰段脊髓和背根神经节的表达

目的:观察肝细胞生长因子(hepatocyte growth factor,HGF)在大鼠脊髓和背根神经节(dorsal root ganglion,DRG)的表达。方法:取健康成年6只SD大鼠运用免疫组织化学染色技术检测HGF在腰段脊髓、背根神经节内的表达和分布。结果:在L4-6段脊髓,HGF免疫阳性产物可见于各板层神经元,尤以脊髓前角运动神经元明显;在DRG中,HGF免疫阳性物质可见于以大、中型为主的神经元的胞浆及突起中。结论:脊髓和背根神经节内的HGF通过与受体c-Met结合可能在神经再生及突触可塑性方面起一定作用。     

Calcium imaging of network function in the developing spinal cord

We have used calcium imaging to visualize the spatiotemporal organization of activity generated by in vitro spinal cord preparations of the developing chick embryo and the neonatal mouse. During each episode of spontaneous activity, we found that chick spinal neurons were activated rhythmically and synchronously throughout the transverse extent of the spinal cord. At the onset of a spontaneous episode, optical activity originated in the ventrolateral part of the cord. Back-labeling of spinal interneurons with calcium dyes suggested that this ventrolateral initiation was mediated by activation of a class of interneurons, located dorsomedial to the motor nucleus, that receive direct monosynaptic input from motoneurons. Studies of locomotor-like activity in the anterior lumbar segments of the neonatal mouse cord revealed the existence of a rostrocaudal wave in the oscillatory component of each cycle of rhythmic motoneuron activity. This finding raises the possibility that the activation of mammalian motoneurons during locomotion may share some of the same rostrocaudally organized mechanisms that evolved to control swimming in fishes.     

Morphofunctional characteristics of the rat distal spinal cord after its complete experimental transection with subsequent animal treadmill training

Motor activity of rats was studied after experimental complete transection of the spinal cord at lower thoracic level. Treadmill training 1 day after the surgery was shown to lead to the appearance of movements in hindlimbs and restoration of the body weight support function. According to our data, the key moment in initiation of locomotor movements is stimulation of foot. Morphoimmunohistochemical investigation of the lumbar enlargement (study of proliferating cell nuclear protein, synaptophysin, and glial fibrillary acidic protein immunohistochemistry) revealed a rearrangement of motoneurons, interneurons, and the afferent chain in the distal part of the transected spinal cord. In the trained animals, there was observed the normal structure of motoneurons and the appearance of aggregates of the synaptophysin-immunoreactive structures lost after the surgery.     

Evoked activity of spinal neurons in the early period after sciatic nerve division

The character of dorsal horn motoneurons and interneurons evoked by stimulation of the dorsal root, and activity of Renshaw cells in response to stimulation of the ventral root were studied in albino rats in the lower lumbar segments of the spinal cord 5 days after sciatic nerve division. A significant increase in the mean amplitude of excitatory postsynaptic potentials of motoneurons was observed on the side of division of the nerve. No significant change in membrane potential and in the threshold of appearance of the action potential of these motoneurons took place. The mean number of action potentials and the duration of discharge of the Renshaw cells and dorsal horn interneurons likewise were not significantly changed.Dnepropetrovsk Medical Institute, Ukrainian Ministry of Health. Translated from Neirofiziologiya, Vol. 24, No. 3, pp. 306–314, May–June, 1992.     

Evidence for neuropeptide FF (FLFQRFamide) in rat dorsal root ganglia.

By using specific antibodies and radioimmunological and immunohistochemical methods, we here show that neuropeptide FF (NPFF) occurs in cervical and lumbar dorsal root ganglia cells. Levels in the ganglia were low because they were detectable only after colchicine treatment or after unilateral dorsal rhizotomy. Similar high-performance liquid chromatography profiles were obtained from dorsal root ganglia and spinal cord extracts, indicating that the NPFF-immunoreactivity in the dorsal root ganglia represented similar molecular forms to that in the spinal cord. Immunocytochemistry localized NPFF-immunoreactivity in small- and medium-sized cells. These data suggest that low levels of NPFF present in fine diameter primary afferent fibers could be involved in the treatment of nociceptive information from fore- or hindlimb.     

Evaluation of Avulsion-Induced Neuropathology in Rat Spinal Cords with 18F-FDG Micro-PET/CT

Brachial plexus root avulsion (BPRA) leads to dramatic motoneuron death and glial reactions in the corresponding spinal segments at the late stage of injury. To protect spinal motoneurons, assessment of the affected spinal segments should be done at an earlier stage of the injury. In this study, we employed ¹⁸F-FDG small-animal PET/CT to assess the severity of BPRA-induced cervical spinal cord injuries. Adult Sprague-Dawley rats were randomly treated and divided into three groups: Av+NS (brachial plexus root avulsion (Av) treated with normal saline), Av+GM1 (treated with monosialoganglioside), and control. At time points of 3 day (d), 1 week (w), 2 w, 4 w and 8 w post-injury, ¹⁸F-FDG micro-PET/CT scans and neuropathology assessments of the injured spinal roots, as well as the spinal cord, were performed. The outcomes of the different treatments were compared. The results showed that BPRA induced local bleeding and typical Wallerian degeneration of the avulsed roots accompanied by ¹⁸F-FDG accumulations at the ipsilateral cervical intervertebral foramen. BPRA-induced astrocyte reactions and overexpression of neuronal nitric oxide synthase in the motoneurons correlated with higher ¹⁸F-FDG uptake in the ipsilateral cervical spinal cord during the first 2 w post-injury. The GM1 treatment reduced BPRA-induced astrocyte reactions and inhibited the de novo nNOS expressions in spinal motoneurons. The GM1 treatment also protected spinal motoneurons from avulsion within the first 4 w post-injury. The data from this study suggest that ¹⁸F-FDG PET/CT could be used to assess the severity of BPRA-induced primary and secondary injuries in the spinal cord. Furthermore, GM1 is an effective drug for reducing primary and secondary spinal cord injuries following BPRA.     

The distribution of motoneurons supplying hind limb muscles in the clawed toad, Xenopus laevis

The distribution of motoneurons in the lumbar spinal cord (spinal segments 8-10) of the clawed toad, Xenopus laevis, was studied with the horseradish peroxidase technique. In a total of 13 different hind limb muscles this tracer was applied in a slow-release gel. Motoneurons innervating a particular hind limb muscle were clustered in longitudinally arranged motor pools. Motor pools of different muscles did show considerable overlap both in the rostrocaudal and transverse plane. But, the various motor pools clearly show a somatotopic organization of motoneurons even in such a condensed lumbar spinal cord as in Xenopus laevis. Motoneurons innervating more distally positioned muscles are generally found in more caudal segments, while proximal muscles (with the exception of the m. adductor magnus) are supplied by motoneurons more or less throughout the lumbar enlargement. Flexor muscles usually are innervated by motoneurons situated ventrolaterally in the ventral horn, extensor muscles by dorsomedially found motoneurons. This pattern is particularly apparent for proximal (thigh) muscles, less so for more distal (shank and foot) muscles. The present data are in keeping with those obtained with the retrograde cell degeneration technique in ranid frogs and are consistent with observations in other tetrapods, although a more clear separation of motor pools is evident in "higher" vertebrates such as birds and mammals.     

Neurochemical and Immunocytochemical Studies on the Distribution of N-Acetyl-Aspartylglutamate and N-Acetyl-Aspartate in Rat Spinal Cord and Some Peripheral Nervous Tissues

HPLC analysis of rat spinal cord revealed a uniform distribution of N-acetyl-aspartate (NAA) across both longitudinal and dorsoventral axes. In contrast, ventral cord N-acetyl-aspartylglutamate (NAAG) levels were significantly higher than those measured in dorsal halves of cervical, thoracic, and lumbar segments. Immunocytochemical studies using an affinity-purified antiserum raised against NAAG-bovine serum albumin revealed an intense staining of motoneurons within rat spinal cord. Along with the considerable NAAG content in ventral roots, these results suggest that NAAG may be concentrated in motoneurons and play a role in motor pathways. NAAG was also present in other peripheral neural tissues, including dorsal roots, dorsal root ganglia, superior cervical ganglia, and sciatic nerve. It is interesting that NAA levels in peripheral nervous tissues were lower than those in CNS structures and that NAA levels in ventral roots and sciatic nerve were lower than NAAG levels. These findings further document a lack of correlation between NAAG and NAA levels in both central and peripheral nervous tissues. Taken together, these data demonstrate the presence of NAAG in nonglutamatergic neuronal systems and suggest a more complex role of NAAG in neuronal physiology than previously postulated.     

Functional organization of locomotor interneurons in the ventral lumbar spinal cord of the newborn rat

Although the mammalian locomotor CPG has been localized to the lumbar spinal cord, the functional-anatomical organization of flexor and extensor interneurons has not been characterized. Here, we tested the hypothesis that flexor and extensor interneuronal networks for walking are physically segregated in the lumbar spinal cord. For this purpose, we performed optical recordings and lesion experiments from a horizontally sectioned lumbar spinal cord isolated from neonate rats. This ventral hemi spinal cord preparation produces well-organized fictive locomotion when superfused with 5-HT/NMDA. The dorsal surface of the preparation was visualized using the Ca(2+) indicator fluo-4 AM, while simultaneously monitoring motor output at ventral roots L2 and L5. Using calcium imaging, we provided a general mapping view of the interneurons that maintained a stable phase relationship with motor output. We showed that the dorsal surface of L1 segment contains a higher density of locomotor rhythmic cells than the other segments. Moreover, L1 segment lesioning induced the most important changes in the locomotor activity in comparison with lesions at the T13 or L2 segments. However, no lesions led to selective disruption of either flexor or extensor output. In addition, this study found no evidence of functional parcellation of locomotor interneurons into flexor and extensor pools at the dorsal-ventral midline of the lumbar spinal cord of the rat.     

Arylamidase activity in the rabbit spinal cord after ligation of the abdominal aorta

Effect of ischaemia, induced by abdominal aorta occlusion, and subsequent survival on the activity of arylamidases was studied in the lumbar and cervical spinal cord of the rabbit. No effect of 40 min ischaemia on the activity of arylamidases was found either in homogenates or in subcellular fractions of the spinal cord. In the lumbar spinal cord a moderate decrease in arylamidase activity was observed after 1 day of survival and a marked decrease was found after 4 days. The decrease were localized in the microsomal and, particularly, in the cytosole fraction. No changes were found in the cervical spinal cord at the corresponding intervals.     

Progesterone prevents mitochondrial dysfunction in the spinal cord of wobbler mice

In the Wobbler mouse, a mutation of the Vps54 protein increases oxidative stress in spinal motoneurons, associated to toxic levels of nitric oxide and hyperactivity of nitric oxide synthase (NOS). Progesterone neuroprotection has been reported for several CNS diseases, including the Wobbler mouse neurodegeneration. In the present study, we analyzed progesterone effects on mitochondrial-associated parameters of symptomatic Wobbler mice. The activities of mitochondrial respiratory chain complexes I, II-III and IV and protein levels of mitochondrial and cytosolic NOS were determined in cervical and lumbar cords from control, Wobbler and Wobbler mice receiving a progesterone implant for 18 days. We found a significant reduction of complex I and II-III activities in mitochondria and increased protein levels of mitochondrial, but not cytosolic nNOS, in the cervical cord of Wobbler mice. Progesterone treatment prevented the reduction of complex I in the cervical region and the increased level of mitochondrial nNOS. Wobbler motoneurons also showed accumulation of amyloid precursor protein immunoreactivity and decreased activity and immunostaining of MnSOD. Progesterone treatment avoided these abnormalities. Therefore, administration of progesterone to clinically afflicted Wobblers (i) prevented the abnormal increase of mitochondrial nNOS and normalized respiratory complex I; (ii) decreased amyloid precursor protein accumulation, a sign of axonal degeneration, and (iii) increased superoxide dismutation. Thus, progesterone neuroprotection decreases mitochondriopathy of Wobbler mouse cervical spinal cord.