Sodium channel inactivation in an animal model of acute quadriplegic myopathy

We previously demonstrated that muscle fibers become unable to fire action potentials in both patients and an animal model of acute quadriplegic myopathy (AQM). In the animal model, skeletal muscle is denervated in rats treated with high-dose corticosteroids (steroid-denervated; SD), and muscle fibers become inexcitable despite resting potentials and membrane resistances similar to those of control denervated fibers that remain excitable. We show here that unexcitability of SD fibers is due to increased inactivation of sodium channels at the resting potential of affected fibers. A hyperpolarizing shift in the voltage dependence of inactivation in combination with the depolarization of the resting potential induced by denervation results in inexcitability. Our findings suggest that paralysis in the animal model of AQM is the result of an abnormality in the voltage dependence of sodium channel inactivation.

Canine motor neuron disease: clinicopathologic features and selected indicators of oxidative stress

Hereditary canine spinal muscular atrophy (HCSMA) is an inherited motor neuron disease affecting a kindred of Brittanies. We have examined the clinicopathologic abnormalities in 57 animals with HCSMA, including 43 affected adult dogs and 14 homozygote pups. We also measured selected biochemical indices of oxidative stress: serum vitamin E (alpha-tocopherol) and Se concentrations; serum concentrations of Cu, Zn, Mg, and Fe; and total superoxide dismutase and glutathione peroxidase activities in red blood cells. Dogs with HCSMA had the following abnormalities: regenerative anemia, hypoglobulinemia, hypochloremia, and abnormally high creatine kinase and liver alkaline phosphatase activities. Serum Cu concentration was significantly (P = .01) increased in adult dogs with HCSMA compared to control dogs. Serum vitamin E concentrations tended to be lower in adult dogs with HCSMA compared to controls, and were significantly (P = .01) lower in homozygote pups compared to control pups.

Congenital bilateral ureteral stenosis and hydronephrosis in a neonatal puppy

Three days after an uneventful parturition, a Brittany spaniel/beagle puppy (Canis familiaris) was nursing but not gaining weight as rapidly as were its littermates. Although its diet was supplemented, the puppy died 10 days after birth. The renal pelves were enlarged and filled with urine. Both ureters were thin throughout their length, and urine could not be expressed from either kidney into its respective ureter. The bladder contained no urine and was firmly embedded in the umbilicus. Histologically, both kidneys were hydronephrotic and contained hypoplastic collecting tubules. The diameter of the right (0.55 mm) and left (0.57 mm) ureters at the uteropelvic junction were narrower than those of an age-matched control of the same breed (1.03 mm and 1.02 mm) and were lined by hypoplastic urothelium. Trichrome staining of the ureters revealed excessive collagen and disorganized smooth muscle fibers; in contrast, the control had predominantly circular smooth muscle fibers and less fibrous tissue. Although neither blood nor aqueous humor could be evaluated for urea nitrogen, we suspect that the puppy died from uremia. The congenital bilateral ureteral stenosis and hydronephrosis of the described puppy is similar to a form of uteropelvic obstruction in humans.

Functional motor unit failure precedes neuromuscular degeneration in canine motor neuron disease

Hereditary canine spinal muscular atrophy (HCSMA) features rapidly progressive muscle weakness that affects muscles in an apparent proximal-to-distal gradient. In the medial gastrocnemius (MG) muscle of homozygous HCSMA animals, motor unit tetanic failure is apparent before the appearance of muscle weakness and appears to be presynaptic in origin. We determined whether structural changes in neuromuscular junctions or muscle fibers were apparent at times when tetanic failure is prevalent. We were surprised to observe that, at ages when motor unit tetanic failure is common, the structure of neuromuscular junctions and the appearance of muscle fibers in the MG muscle were indistinguishable from those of symptom-free animals. In contrast, in more proximal muscles, many neuromuscular junctions were disassembled, with some postsynaptic specializations only partially occupied by motor nerve terminals, and muscle fiber atrophy and degeneration were also apparent. These observations suggest that the motor unit tetanic failure observed in the MG muscle in homozygous animals is not due to synaptic degeneration or to pathological processes that affect muscle fibers directly. Together with previous physiological analyses, our results suggest that motor unit failure is due to failure of neuromuscular synaptic transmission that precedes nerve or muscle degeneration.

Nerve injury induces gap junctional coupling among axotomized adult motor neurons

Neonatal spinal motor neurons are electrically and dye-coupled by gap junctions, but coupling is transient and disappears rapidly after birth. Here we report that adult motor neurons become recoupled by gap junctions after peripheral nerve injury. One and 4-6 weeks after nerve cut, clusters of dye-coupled motor neurons were observed among axotomized, but not control, lumbar spinal motor neurons in adult cats. Electrical coupling was not apparent, probably because of the electrotonic distance between dendrodendritic gap junctions and the somatic recording location. Analyses of gap junction protein expression in cat and rat showed that the repertoire of connexins expressed by normal adult motor neurons, Cx36, Cx37, Cx40, Cx43, and Cx45, was unchanged after axotomy. Our results suggest that the reestablishment of gap junctional coupling among axotomized adult motor neurons may occur by modulation of existing gap junction proteins that are constitutively expressed by motor neurons. After injury, interneuronal gap junctional coupling may mediate signaling that maintains the viability of axotomized motor neurons until synaptic connections are reestablished within their targets.

Gap junctional coupling and patterns of connexin expression among neonatal rat lumbar spinal motor neurons

Interneuronal gap junctional coupling is a hallmark of neural development whose functional significance is poorly understood. We have characterized the extent of electrical coupling and dye coupling and patterns of gap junction protein expression in lumbar spinal motor neurons of neonatal rats. Intracellular recordings showed that neonatal motor neurons are transiently electrically coupled and that electrical coupling is reversibly abolished by halothane, a gap junction blocker. Iontophoretic injection of Neurobiotin, a low molecular weight compound that passes across most gap junctions, into single motor neurons resulted in clusters of many labeled motor neurons at postnatal day 0 (P0)-P2, and single labeled motor neurons after P7. The compact distribution of dye-labeled motor neurons suggested that, after birth, gap junctional coupling is spatially restricted. RT-PCR, in situ hybridization, and immunostaining showed that motor neurons express five connexins, Cx36, Cx37, Cx40, Cx43, and Cx45, a repertoire distinct from that expressed by other neurons or glia. Although all five connexins are widely expressed among motor neurons in embryonic and neonatal life, Cx36, Cx37, and Cx43 continue to be expressed in many adult motor neurons, and expression of Cx45, and in particular Cx40, decreases after birth. The disappearance of electrical and dye coupling despite the persistent expression of several gap junction proteins suggests that gap junctional communication among motor neurons may be modulated by mechanisms that affect gap junction assembly, permeability, or open state.

Alterations in cyclin-dependent protein kinase 5 (CDK5) protein levels, activity and immunocytochemistry in canine motor neuron disease

Hereditary canine spinal muscular atrophy (HCSMA) is a dominantly inherited motor neuron disease in Brittany spaniels that is clinically characterized by progressive muscle weakness leading to paralysis. Histopathologically, degeneration is confined to motor neurons with accumulation of phosphorylated neurofilaments in axonal internodes. Cyclin-dependent kinase 5 (CDK5), a kinase related to the cell cycle kinase cdc2, phosphorylates neurofilaments and regulates neurofilament dynamics. We examined CDK5 activity, protein levels, and cellular immunoreactivity in nervous tissue from dogs with HCSMA, from closely age-matched controls and from dogs with other neurological diseases. On immunoblot analysis, CDK5 protein levels were increased in the HCSMA dogs (by approximately 1.5-fold in both the cytosolic and the particulate fractions). CDK5 activity was significantly increased (by approximately 3-fold) in the particulate fractions in the HCSMA dogs compared to all controls. The finding that CDK5 activity was increased in the young HCSMA homozygotes with the accelerated form of the disease, who do not show axonal swellings histologically, suggests that alterations in CDK5 occurs early in the pathogenesis, prior to the development of significant neurofilament pathology. Immunocytochemically, there was strong CDK5 staining of the nuclei, cytoplasm and axonal processes of the motor neurons in both control dogs and dogs with HCSMA. Further immunocytochemical studies demonstrated CDK5 staining where neurofilaments accumulated, in axonal swellings in the dogs with HCSMA. Our observations suggest phosphorylation-dependent events mediated by CDK5 occur in canine motor neuron disease.

Loss of electrical excitability in an animal model of acute quadriplegic myopathy

In rats treated with high-dose corticosteroids, skeletal muscle that is denervated in vivo (steroid-denervated [S-D]) develops electrical inexcitability similar to that seen in patients with acute quadriplegic myopathy. In studies of affected muscles in vitro, the majority of S-D fibers failed to generate action potentials in response to intracellular stimulation although the average resting potential of these fibers was no different from that of control denervated muscle. The downregulation of membrane chloride conductance (G[Cl]) seen in normal muscle after denervation did not occur in S-D muscle. Although block of chloride channels in S-D muscle produced high specific membrane resistance, comparable to similarly treated control denervated muscle, and partially restored excitability in many fibers, action potential amplitude was still reduced in S-D fibers, suggesting a concomitant reduction in sodium current. 3H-saxitoxin binding measurements revealed a reduction in the density of the adult muscle sodium channel isoform in S-D muscle, suggesting that a decrease in the number of sodium channels present may play a role in the reduction of sodium current, although altered properties of channels may also contribute. The weakness seen in S-D muscle may involve the interaction of a number of factors that modify membrane excitability, including membrane depolarization, persistence of G(Cl), and reduced voltage-gated sodium currents.

Effects of 4-aminopyridine on muscle and motor unit force in canine motor neuron disease

Hereditary Canine Spinal Muscular Atrophy (HCSMA) is an autosomal dominant disorder of motor neurons that shares features with human motor neuron disease. In animals exhibiting the accelerated phenotype (homozygotes), we demonstrated previously that many motor units exhibit functional deficits that likely reflect underlying deficits in neurotrans-mission. The drug 4-aminopyridine (4AP) blocks voltage-dependent potassium conductances and is capable of increasing neurotransmission by overcoming axonal conduction block or by increasing transmitter release. In this study, we determined whether and to what extent 4AP could enhance muscle force production in HCSMA. Systemic 4AP (1-2 mg/kg) increased nerve-evoked whole muscle twitch force and electromyograms (EMG) to a greater extent in older homozygous animals than in similarly aged, symptomless HCSMA animals or in one younger homozygous animal. The possibility that this difference was caused by the presence of failing motor units in the muscles from homozygotes was tested directly by administering 4AP while recording force produced by failing motor units. The results showed that the twitch force and EMG of failing motor units could be significantly increased by 4AP, whereas no effect was observed in a nonfailing motor unit from a symptomless, aged-matched HCSMA animal. The ability of 4AP to increase force in failing units may be related to the extent of failure. Although 4AP increased peak forces during unit tetanic activation, tetanic force failure was not eliminated. These results demonstrate that the force outputs of failing motor units in HCSMA homozygotes can be increased by 4AP. Possible sites of 4AP action are considered.

Regenerated dorsal root fibers form functional synapses in embryonic spinal cord transplants

1. The aim of the present study was to determine whether synapses formed by dorsal root afferents that regenerate into intraspinal transplants of fetal spinal cord are functional. Severed L4 or L5 dorsal root stumps were placed at the bottom of dorsal quadrant cavities made in the lumbar spinal cords of adult rats and juxtaposed to embryonic day 14 spinal cord transplants. 2. In animals examined 5-10 weeks later, we recorded extracellularly in transplants from 43 units that fired in response to electrical stimulation of the implanted dorsal root. Latency fluctuations of extracellular firing that increase with stimulus and failure to follow high-frequency and posttetanic potentiation of extracellular firing stimulation suggest that synapses with conventional properties are formed between regenerating afferents and transplant neurons. Limited intracellular recordings confirmed the existence of excitatory postsynaptic potentials in transplant neurons after dorsal root stimulation. 3. In 16 units, extracellular firing occurred in response to single shock stimulation. The remainder of the units required two or more dorsal root shocks to evoke firing; some of these connections also may be monosynaptic. 4. Under the assumption that single shock firing was most likely the result of monosynaptic connections between transplant neurons and regenerated dorsal root fibers, we estimated the conduction velocities of regenerated fibers. These estimates suggest that fibers with conduction velocities in the C, A delta, and A alpha/beta ranges regenerate into transplants of embryonic spinal cord. 5. The results demonstrate that regenerated dorsal root axons establish functional synaptic connections with transplant neurons. The implications for using fetal transplants to help rebuild spinal reflex circuits after spinal cord injury are considered.

The Size Principle: Still Working After All These Years

Orderly recruitment of motor units is viewed by many as a fundamental motor control strategy. The size principle is an idea that attempts to explain how orderly recruitment operates. Does the size principle work? We summarize how the size principle came about, consider its mechanisms, and probe its limits.

Properties of motor units after self-reinnervation of the cat superior oblique muscle

1. The mechanical properties of motor units of the cat superior oblique muscle and axonal conduction velocities of trochlear motoneurons have been studied at several postoperative times after intracranial axotomy of the trochlear nerve. 2. Whole muscle twitch forces were generally within the normal range by approximately 4 mo postoperative, indicating that reinnervation is complete at this time. 3. Among animals studied 3.5-4.5 months after trochlear axotomy, average motor-unit tetanic forces were increased by a factor of approximately 2.5 compared with units studied in normal superior oblique muscle. Average motor-unit tetanic forces in animals studied 14.5-23 mo after axotomy were also increased relative to normal, but the difference was not significant. Among all reinnervated motor units, there was a tendency for increased twitch time-to-peak relative to control. Reinnervated motor-unit fatigue properties were similar to normal. 4. Average trochlear motoneuron conduction velocities for animals at all postoperative intervals remained significantly lower than the average conduction velocities from three of four normal animals. 5. Counts of Nissl-stained cell bodies in axotomized and control, contralateral trochlear nuclei showed that some cell loss had occurred, averaging approximately 17% 3.5-4.5 mo postoperative and 24% 14.5-23 mo postoperative. Associated with this loss was an increase (10%) of axotomized motoneuron soma cross-sectional area. 6. Muscle fiber cross-sectional areas (CSA) were measured in reinnervated superior oblique muscles and compared with CSAs from contralateral, control muscles. Average CSA was significantly decreased in all reinnervated muscles, with the relative decreases ranging from approximately 10 to 28%. 7. The results are discussed in terms of factors that determine motor-unit force; muscle fiber CSA, specific force, and innervation ratio. We conclude that the increases of average motor-unit force in short-term reinnervated superior oblique muscles are most likely related to polyneuronal innervation of muscle fibers and that the return of these forces to normal levels in long-term muscles is related to synapse elimination. Our results are compared with those of other self-reinnervation studies, and the potential role played by the time muscle remains denervated in determining the persistence of polyneuronal innervation after reinnervation is considered.

Motor unit behavior in canine motor neuron disease

Hereditary canine spinal muscular atrophy (HCSMA) is an autosomally dominant disease of motor neurons that shares many pathological features with human motor neuron disease. A particularly striking feature of the affected, accelerated phenotype (homozygous HCSMA) is that profound weakness develops before appreciable motor neuron cell death occurs (Cork et al., 1989a), implying that motor unit functional defects occur initially. The purpose of this study was to identify the site of these defects and characterize their nature. In most young homozygotes (2-3 months postnatal), motor neurons were encountered that could support orthodromic action potential propagation to the muscle but did not activate muscle fibers. The tetanic forces of innervated motor units in young homozygotes tended to be smaller than those in closely age-matched clinically normal animals. In older homozygotes (approximately 4.5 months, postnatal), all motor neurons sampled were capable of activating muscle fibers, but many motor units displayed abnormal behavior including an inability to sustain force output during high frequency activation. Motor units exhibiting tetanic failure also showed proportionately greater twitch potentiation than nonfailing units of similar unpotentiated twitch amplitude. Tetanic failure and large potentiation tended to occur in motor units that possessed the slowest contraction speeds. These results indicate that motor neuron functional defects in HCSMA appear initially in the most distal parts of the motor axon and involve defective neurotransmission. The possible roles of distal nerve degeneration, motor terminal sprouting, and synaptic transmission in causing these deficits are considered.

Adult spinal motoneurons remain viable despite prolonged absence of functional synaptic contact with muscle

Several rat medial gastrocnemius (MG) motor axons were allowed to regenerate into normally innervated muscle. Under these conditions, synapse formation is known to be prevented by the existence of the original innervation of the host muscle. A study was made of the ability of the implanted spinal motoneurons to acquire and retrogradely transport horseradish peroxidase (HRP) injected into the host muscle at various postoperative intervals. HRP-labeled MG motoneurons on the implanted side were observed at postoperative intervals as long as 290 days. A comparison of the number of labeled MG motoneurons on the implanted side versus the number on the unoperated, control side indicated no significant differences. At all investigated postoperative intervals except the earliest (7 DPO), a significant decrease in the mean MG motoneuron soma cross-sectional area was observed relative to the unoperated, control side. Analysis of labeled motoneuron size distributions showed that postoperative atrophy of larger, presumably alpha, motoneurons occurred at a significantly faster rate than in smaller, presumably gamma, motoneurons. These results demonstrate that axotomized adult spinal motoneurons survive and remain viable for prolonged periods when denied the opportunity to reinnervate muscle but do so in an atrophied state. The results indicate further that alpha and gamma motoneurons differ quantitatively in their responses to peripheral axotomy.

Time courses of calcium and calcium-bound buffers following calcium influx in a model cell

Fixed and diffusible calcium (Ca) buffers shape the spatial and temporal distribution of free Ca following Ca entry through voltage-gated ion channels. This modeling study explores intracellular Ca levels achieved near the membrane and in deeper locations following typical Ca currents obtained with patch clamp experiments. Ca ion diffusion sets an upper limit on the maximal average Ca concentration achieved near the membrane. Fixed buffers restrict Ca elevation spatially to the outermost areas of the cell and slow Ca equilibration. Fixed buffer bound with Ca near the membrane can act as Ca source after termination of Ca influx. The relative contribution of fixed versus diffusible buffers to shaping the Ca transient is determined to a large extent by the binding rate of each buffer, with diffusible buffer dominating at equal binding rates. In the presence of fixed buffers, diffusible buffers speed Ca equilibration throughout the cell. The concentration profile of Ca-bound diffusible buffer differs from the concentration profile of free Ca, reflecting theoretical limits on the temporal resolution which can be achieved with commonly used diffusible Ca indicators. A Ca indicator which is fixed to an intracellular component might more accurately report local Ca concentrations.

Trigeminal excitation of dorsal neck motoneurones in the cat

Excitation of dorsal neck motoneurones evoked by electrical stimulation of primary trigeminal afferents in the Gasserian ganglion has been investigated with intracellular recording from alpha-motoneurones in the cat. Single stimulation in the Gasserian ganglion ipsi- and contralateral to the recording side evoked excitatory postsynaptic potentials (EPSPs) in motoneurones innervating the lateral head flexor muscle splenius (SPL) and the head elevator muscles biventer cervicis and complexus (BCC). The gasserian EPSPs were composed of early and late components which gave the EPSPs a hump-like shape. A short train of stimuli, consisting of two to three volleys, evoked temporal facilitation of both the early and late EPSP components. The latencies of the gasserian EPSPs ranged from 1.6 to 3.6 ms in SPL motoneurones and from 1.6 to 5.8 ms among BCC motoneurones. A rather similar latency distribution between 1.6 and 2.4 ms was found for ipsi- and contralateral EPSPs in SPL and BCC motoneurones, which is compatible with a minimal disynaptic linkage between primary trigeminal afferents and neck motoneurones. Systematic transections of the ipsi- and contralateral trigeminal tracts were performed in the brain stem between 3 and 12 mm rostral to the level of obex. The results demonstrate that both the ipsi- and contralateral disynaptic and late gasserian EPSPs can be mediated via trigeminospinal neurones which take their origin in the nucleus trigeminalis spinalis oralis. Transection of the midline showed that the contralateral trigeminospinal neurones cross in the brain stem. Systematic tracking in and around the ipsilateral trigeminal nuclei demonstrated that the axons of ipsilateral trigeminospinal neurones descend just medial to and/or in the medial part of the nucleus. Spinal cord lesions revealed a location of the axons of the ipsilateral trigeminospinal neurones in the lateral and ventral funiculi. Interaction between the ipsi- and contralateral gasserian EPSPs showed complete summation of the disynaptic EPSP component, while the late components were occluded by about 45%. These results show that the disynaptic EPSPs are mediated by separate trigeminospinal neurones from the ipsi- and contralateral side, while about half of the late EPSPs are mediated by common neurones which receive strong bilateral excitation from commissural neurones in the trigeminal nuclei. Spatial facilitation was found in the late gasserian EPSP but not in the disynaptic gasserian EPSP by conditioning stimulation of cortico- and tectofugal fibres. Disynaptic pyramidal and tectal EPSPs, which are mediated by reticulospinal neurones, were facilitated by a single stimulation in the gasserian ganglion at an optimal interval of 2 ms.(ABSTRACT TRUNCATED AT 400 WORDS)

Descending pathways mediating disynaptic excitation of dorsal neck motoneurones in the cat: facilitatory interactions

Facilitatory interactions between disynaptic EPSPs evoked from the contralateral tectum, ipsilateral tegmentum and contra- and/or ipsilateral pyramid have been investigated in dorsal neck motoneurones of the cat. Monosynaptic convergence on common intercalated neurones was found from ipsi- and contralateral pyramidal, contralateral tectal and ipsilateral tegmental fibres. In addition, disynaptic facilitation was observed from ipsilateral pyramidal fibres on disynaptic contralateral pyramidal EPSPs. Transection of cortico-fugal fibres in the pyramid showed that the location of the interactions occurred in the lower brain stem, suggesting that reticulospinal neurones are mediating the effects.

Descending pathways mediating disynaptic excitation of dorsal neck motoneurones in the cat: brain stem relay

The location of intercalated neurones mediating disynaptic excitation from tectum, tegmentum and pyramids to dorsal neck motoneurones has been investigated by: (a) recording field potentials in the lower brain stem evoked from the above systems, (b) systematic stimulation in the brain stem during intracellular recording from motoneurones innervating the splenius, biventer cervicis and complexus muscles, and (c) comparing the effects of lesions of the brain stem with kainic acid on the disynaptic EPSPs elicited from the above three systems. Electrical stimulation of the contralateral superior colliculus evoked monosynaptic field potentials which were largest in the caudal pontine reticular formation rostral to the abducens nucleus and in the rostral part of the medullary reticular formation caudal to the abducens nucleus. Likewise, stimulation of the ipsilateral tegmentum (the cuneiform and subcuneiform nucleus) evoked field potentials which were large in the caudal medulla and small in the pons. In contrast, stimulation of the contralateral tegmentum was ineffective in evoking field potentials. Stimulation of the pyramid 2-3 mm rostral to the obex elicited monosynaptic field potentials in the reticular formation of the lower brain stem that were only about 25% of those from the superior colliculus. In contrast to the field potentials from the superior colliculus, the pyramidal ones were large in the medulla and small in the pons. Lesions of the reticular formation in the lower brain stem by unilateral kainic acid injection caused disappearance of disynaptic EPSPs in motoneurones from the above three systems. These results strongly suggest that the intercalated neurones mediating pyramidal, tectal and tegmental EPSPs are reticulospinal neurones in the lower brain stem. Systematic stimulation in various locations of the lower brain stem showed that monosynaptic EPSPs were evoked from the regions of the reticular formation which received projection from the above three descending systems. The effective regions for evoking the EPSPs in splenius (SPL) were located somewhat more dorsally than for biventer cervicis and complexus (BCC) motoneurones. The descending axons of presumed reticulospinal neurones were stimulated with electrodes placed in medial, middle and lateral positions at the spinomedullary junction. Monosynaptic EPSPs in SPL and BCC motoneurones were evoked from the medial and middle electrodes but not from the lateral electrode.

Tectal and tegmental excitation in dorsal neck motoneurones of the cat

1. Intracellular recordings were made from 116 splenius (SPL) and 103 biventer cervicis and complexus (BCC) alpha-motoneurones in nineteen cats anaesthetized with alpha-chloralose. 2. Electrical stimulation in the contralateral tectum evoked disynaptic excitatory postsynaptic potentials (EPSPs) in the motoneurones when a train of stimuli was applied in the ventral layers throughout the superior colliculus. In the rostral half of the superior colliculus, these EPSPs were due to stimulation of ascending collaterals of tectofugal neurones. EPSPs of a presumed trisynaptic linkage could only be evoked from the dorsal and intermediate tectal layers in the caudal half of the superior colliculus. It is concluded that the tectofugal neurones which evoked the disynaptic EPSPs are mainly located in the caudal half of the superior colliculus. 3. Disynaptic EPSPs were evoked in the motoneurones by a train of stimuli in the contralateral fields of Forel and Zona incerta, which were due to stimulation of ascending collaterals from the tectofugal neurones. 4. Spatial facilitation experiments revealed that tectal disynaptic EPSPs in the neck motoneurones were mediated via reticulospinal neurones with convergent input from cortico-reticular neurones. 5. A train of stimuli in the ipsilateral tectum evoked EPSPs with latencies compatible with a trisynaptic linkage, while disynaptic EPSPs at low threshold could be elicited from the underlying tegmentum. Similar disynaptic EPSPs could be evoked from the ipsilateral fields of Forel. It is suggested that some of the disynaptic tegmental EPSPs in SPL and BCC motoneurones can be mediated via a tegmento-reticulospinal pathway which originates in the cuneiform nucleus.

Axotomy-like changes in cat motoneuron electrical properties elicited by botulinum toxin depend on the complete elimination of neuromuscular transmission

The electrical properties of cat medial gastrocnemius (MG) spinal motoneurons were studied 14-21 d following injection of type A botulinum toxin (BTX) into the MG muscle. Treated MG muscles were atrophic, displayed pronounced fibrillation activity, and were markedly but not completely paralyzed. MG motoneuron electrical properties from animals with the highest MG muscle-twitch forces (greater than 20 gm) appeared normal, while motoneuron properties from animals with the lowest MG muscle-twitch forces (less than 10 gm) exhibited axotomy-like changes, though these changes were less pronounced than after axotomy itself. No changes in the axonal conduction velocity were observed, however. Motoneuron connectivity with MG muscle fibers was determined following intracellular stimulation of MG motoneurons by averaging EMG signals from 3 or 4 pairs of recording electrodes inserted into the BTX-treated MG muscles. Normal electrical properties were observed among motoneurons in which detectable EMG activity linked to the intracellular stimulation pulse was observed. The level of this connectivity, however, indicated that a relatively small number of muscle fibers were activated by individual motoneuron action potentials. Axotomy-like changes of electrical properties were observed in MG motoneurons that could not be associated with detectable EMG activity in the BTX-treated MG muscle following repeated trials of intracellular stimulation. These results indicate that the existence of effective neuromuscular transmission at a small number of motor terminals is sufficient to prevent the appearance of axotomy-like changes in motoneuron electrical properties, and that the absence of such transmission at all motor terminals is associated with the appearance of axotomy-like changes. The results suggest that the effects of axotomy itself on motoneuron properties may be based upon the loss or elimination of a potent interaction between muscle and motoneurons normally mediated by neuromuscular transmission.

Integration in descending motor pathways controlling the forelimb in the cat. 17. Axonal projection and termination of C3-C4 propriospinal neurones in the C6-Th1 segments

Collateralization and termination of single C3-C4 propriospinal neurones (PNs) have been studied in the C6-Th1 segments of the cat using two methods: threshold mapping for antidromic activation of C3-C4 PNs and intra-axonal injection of horseradish peroxidase. Low threshold points for antidromic activation of C3-C4 PNs were found in the region of different motor nuclei in lamina IX both at one level and at different segmental levels, in all parts of lamina VII, in the lateral part of lamina VI and in the dorsal and ventral parts of lamina VIII. Collaterals were found from C6 to Th1. A marked decrease of conduction velocity of the stem axon occurred in the caudal region of termination, while it was almost constant in the rostral region of termination. HRP was injected iontophoretically in C6-Th1 into stem axons of neurones, which were activated antidromically from the ventral part of the lateral funiculus in C5/C6, from the lateral reticular nucleus (LRN) and monosynaptically from the corticospinal fibres (stimulated in the contralateral pyramid) which were transected in C5/C6. Reconstruction of successfully stained stem axons, revealed collaterals with terminals on presumed motoneurones in different parts of lamina IX and on interneurones in laminae IV-VIII. These findings confirm previous results which showed monosynaptic projections from C3-C4 PNs to forelimb motoneurones and Ia inhibitory interneurones. With respect to termination in the region of the motoneurones in lamina IX and in the region of Ia inhibitory interneurones in lamina VII, three patterns were found: 1) termination mainly in lamina IX (n = 1) 2) termination in laminae IX and VII (n = 15) and 3) termination mainly in lamina VII (n = 2). However, in some cases the same stem axon gave off collaterals which terminated either on motoneurones in lamina IX or on presumed Ia inhibitory interneurones in lamina VII. Furthermore, when the stem axons had collaterals which terminated in different motor nuclei only some of these collaterals had additional terminations on presumed Ia inhibitory interneurones. This result suggest that C3-C4 PNs do not follow a strict Ia pattern of reciprocal innervation. It is tentatively proposed that the difference of innervation may be related to the type of multi-joint movement, such as target-reaching with the forelimb, which has been shown to be controlled by the C3-C4 PNs. Termination in laminae VI, VIII and different parts of lamina VII indicates that C3-C4 PNs also project to other types of neurones than motoneurones and Ia inhibitory interneurones.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of preventing reinnervation on axotomized spinal motoneurons in the cat. I. Motoneuron electrical properties

1. The intent of this study was to determine the effect on the electrical properties of axotomized spinal motoneurons when motor axons are allowed to regenerate but are denied the opportunity to reinnervate muscle. 2. The nerve supplying the medial gastrocnemius (MG) muscle in cats was served close to its entry into the muscle and sutured onto the surface of the lateral gastrocnemius (LG) muscle. The MG muscle was excised to prevent availability of vacant end-plates to the regenerating MG axons. The electrical properties of antidromically identified MG motoneurons were studied using intracellular recording at various postoperative intervals. 3. In 9 of 12 experimental animals, no sign of functional innervation by MG axons of the LG muscle could be detected. In three experimental animals, electrical and contraction activity in the LG muscle was observed following electrical stimulation of the transplanted MG nerve. The observed electrical and contraction activity was, however, negligible compared to the effects of electrical stimulation of the intact LG-soleus nerve. 4. At the earliest postoperative interval studied (20 days), MG motoneuron electrical properties [input resistance, afterhyperpolarization (AHP) duration, conduction velocity, time constant, rheobase current, and sag] exhibited significant changes that were nearly identical to those described for spinal motoneurons following section of ventral roots or motor nerves or in the earliest stages of reinnervation. 5. At the 44-60 day postoperative (DPO) intervals, several motoneuron electrical properties showed signs of recovery to control levels. At 44 DPO, average values of input resistance, time constant, and AHP duration declined from the significant increases observed at 20 DPO and could not be distinguished statistically from control mean values. 6. These indications of an early recovery of normal electrical properties were not sustained. At subsequent postoperative intervals (90, 120, and 150-180 DPO), average values of motoneuron electrical properties tended to be similar to those observed at 20 DPO. 7. Correlations observed among control motoneuron electrical properties were weakened and the pattern of correlation was disrupted at all postoperative intervals. 8. In conjunction with previous results demonstrating recovery of normal electrical properties following reinnervation (Foehring et al. 1986b), our findings suggest that functional contact with muscle is required for the full expression of the normal range of motoneuron electrical properties.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of preventing reinnervation on axotomized spinal motoneurons in the cat. II. Changes in group Ia synaptic function

1. Composite excitatory postsynaptic potentials (EPSPs) evoked by electrical stimulation of heteronymous group Ia afferents have been studied at various postoperative times in axotomized motoneurons that were denied the opportunity to reinnervate muscle. 2. The medial gastrocnemius (MG) nerve was transected and sutured onto the surface of the normally innervated lateral gastrocnemius (LG) muscle. The denervated MG muscle was excised thereby eliminating access of regenerating MG motor axons to vacant end-plates. 3. The mean amplitude of monosynaptic Ia EPSPs evoked by electrical stimulation of the LG-soleus (LGS) nerve and recorded in axotomized MG motoneurons showed an initial decline at 20 days postoperative (DPO) that was not significant. At 44 DPO, mean amplitude had declined significantly to 43% of the control mean amplitude. At 90 DPO, mean EPSP amplitude was not significantly different from control. At the latest postoperative time (150-180 DPO), mean amplitude was significantly less than the control amplitude. 4. Mean EPSP rise time (time-to-peak) was significantly increased (27%) at the earliest postoperative times (20-44 DPO). At later postoperative times (90-180), mean EPSP rise time was not significantly different from mean control rise time. 5. "Partial responses" superimposed on EPSPs were not observed at any postoperative time. 6. Mean posttetanic potentiation (PTP) of the LGS EPSP was significantly depressed at 20 DPO. At later postoperative times, PTP did not differ significantly from mean control PTP. 7. The possibility is considered that postaxotomy alterations in the electrical properties of motoneurons may explain these complex variations of mean EPSP amplitude and rise time.

Branching and termination of C3-C4 propriospinal neurones in the cervical spinal cord of the cat

Antidromic stimulation and intra-axonal injections of horseradish peroxidase have been used to investigate axonal branching and termination of single C3-C4 propriospinal neurones (PNs) that project to the forelimb segments (C6-Th1). Branching at several spinal cord levels and terminations were found in laminae VI-VIII and IX. With respect to terminations in laminae VII and IX, 3 patterns were observed: (i) termination only in lamina IX, (ii) only in lamina VII in the region of Ia inhibitory interneurones and (iii) in both laminae VII and IX. These findings are consistent with previous results showing monosynaptic projections of C3-C4 PNs to forelimb motoneurones and Ia inhibitory interneurones. Terminations in laminae VI, VIII and other parts of lamina VII suggest that C3-C4 PNs also project to other neurones in the forelimb segments.

The effect of axotomy on posttetanic potentiation of group Ia synapses in the cat

Posttetanic potentiation (PTP) of composite Ia excitatory postsynaptic potentials (EPSPs) has been studied in normal cat alpha-motoneurons and in motoneurons axotomized 2-3 wk earlier by ventral root section. The maximal amount of PTP of EPSP amplitude (expressed relative to unpotentiated amplitude) was considerably less in the axotomized population compared with the normal population. The decrease in PTP provoked by axotomy occurs in association with a postaxotomy increase of input resistance, the net effect being that PTP in axotomized cells was much the same as that observed by others in normal motoneurons possessing similarly high input resistance. In agreement with previous results, EPSP peak amplitudes were decreased after axotomy. This decrease seemed to be largely related to an absence of the largest EPSPs, since otherwise the EPSP distributions of normal and axotomized motoneurons showed considerable overlap. It is suggested that the observed decrease in PTP after axotomy is related to a change in synaptic release properties and not secondary to changes in the electrical properties of motoneurons. A previous analysis has suggested that axotomy causes an alteration of the distribution of passive electrical properties among motoneurons such that axotomized cells resemble normal high-resistance motoneurons. The present results suggest that axotomy may affect the distribution of Ia synaptic release properties in a similar manner, since PTP in axotomized motoneurons resembles that observed in normal high-resistance motoneurons.

Cross-reinnervated motor units in cat muscle. II. Soleus muscle reinnervated by flexor digitorum longus motoneurons

The properties of whole soleus (SOL) muscles and of individual motor units were studied in cats 30-50 wk after self-reinnervation by soleus (SOL) motoneurons (SOL----SOL) or cross-reinnervation by flexor digitorum longus (FDL) motoneurons (FDL----SOL). As in the preceding paper (22), intracellular and glycogen-depletion methods were used to examine the physiological and histochemical properties of individual motor units. The results were compared with data from normal SOL motor units (8, 12). Intentionally self-reinnervated SOL muscles (SOL----SOL; n = 6) were normal in size and wet weight, and all of the five SOL----SOL motor units studied had physiological and histochemical characteristics that matched those of normal SOL units. Cross-reinnervation of SOL by FDL alpha-motoneurons (FDL----SOL; n = 7) produced muscles with wet weights and appearance essentially identical to normal SOL. However, whole-muscle twitch contraction times were much shorter (mean 60.4 ms) than those of normal (mean 136.9 ms, n = 18) or SOL----SOL muscles (mean 115.3 ms; n = 6). Despite this difference, none of the FDL----SOL muscles contained more than 7% histochemical type II muscle fibers, all of which were type IIA. Normal cat SOL muscles can contain up to 5% type IIA fibers, but none of our SOL----SOL muscles showed any type II fibers. Two FDL----SOL muscles had significant amounts of unintended self-reinnervation, permitting side-by-side comparison of FDL----SOL and SOL----SOL muscle fibers. The twitch contraction times of the two populations differed markedly, but they were histochemically indistinguishable except for the fact that SOL----SOL fibers had high neutral fat content (as do normal SOL fibers), whereas FDL----SOL showed much lower fat content. The 23 FDL----SOL muscle units studied were classified as physiological type S by criteria ("sag" test and fatigue resistance) used to identify motor-unit types in normal cat muscles. All five of the FDL----SOL units studied histochemically after glycogen depletion showed the type I histochemical profile, which is characteristic of the normal cat SOL. In marked contrast to the preceding study, cross-reinnervation of cat SOL by FDL motoneurons produced no conversion of muscle-unit properties into those associated with fast-twitch unit types, despite significant decreases in isometric twitch contraction time. The altered twitch speed was not associated with evident changes in conventional myofibrillar adenosine triphosphatase (ATPase) histochemistry.(ABSTRACT TRUNCATED AT 400 WORDS)

Kinesiological studies of self- and cross-reinnervated FDL and soleus muscles in freely moving cats

The activity patterns in self- and cross-reinnervated flexor digitorum longus (FDL) and soleus (SOL) muscles were examined during natural movements in awake, unrestrained cats in which electromyographic (EMG) electrodes, tendon-force gauges, and muscle-length gauges had been chronically implanted under anesthesia and aseptic conditions. Kinesiological data were recorded between 13 and 22 mo after nerve surgery. Self-reinnervated FDL and SOL muscles (i.e., FDL----FDL and SOL----SOL, respectively) exhibited locomotor activity patterns that were the same as observed in normal, unoperated FDL and SOL muscles (26). FDL----FDL muscles exhibited primarily brief bursts of activity in early swing, just after the toes had left the ground, whereas SOL----SOL muscles showed bursts of activity just before and during stance. In contrast, the cross-reinnervated muscles (both SOL----FDL and FDL----SOL) that had little or no unwanted self-reinnervation showed the patterns of activity that are associated with the innervating foreign motoneurons. That is, cross-reinnervated SOL----FDL muscles were intensely active in quadrupedal standing and, during the stance phase of stepping, producing large force transients while actively lengthening. Conversely, cross-reinnervated FDL----SOL muscles were active mainly in short bursts at the onset of the swing phase of stepping, just after the foot had left the ground. There was considerable modulation of EMG and peak force output in FDL----SOL muscles with changing speed of locomotion, whereas little modulation was evident in SOL----FDL muscles. The activity patterns in self- and cross-reinnervated FDL and SOL muscles were also recorded during scratch and paw-shaking reflexes. As in locomotion, the observed patterns were in all cases consistent with those expected for the innervating motor pool rather than the innervated muscle. Muscles that had been dually reinnervated by both the original and foreign motor pools displayed activity patterns that were a mixture of the FDL and SOL activity patterns described above. The present results demonstrate that motoneuron activation patterns remain qualitatively unaltered when their motor axons reinnervate foreign muscles. In addition, the observations permit some quantitative estimates of the degree to which cross-reinnervated muscles are subjected to patterns of motoneuron activity and to conditions of mechanical loading that are markedly different from those in the self-reinnervated or normal conditions.

Pyramidal effects in dorsal neck motoneurones of the cat

The effects of contralateral pyramidal stimulation have been investigated with intracellular recording from cat alpha-motoneurones that innervate the dorsal neck musculature. A short train of stimuli evoked three types of synaptic effects: predominant excitation or inhibition and mixed effects characterized chiefly by early excitation followed by inhibition. Latency measurements indicated a minimal disynaptic linkage for excitation and for inhibition. Splenius motoneurones received primarily excitation whereas biventer cervicis-complexus motoneurones received a more varied input characterized by mixed effects or inhibition. Following transection of the pyramid just rostral to the decussation (lower pyramidal lesion) pyramidal stimulation above the lesion still produced disynaptic excitation and longer latency (possibly trisynaptic) inhibition. Pyramidal stimulation just caudal to this transection evoked inhibition with a minimal disynaptic latency, as well as longer latency excitation. The incidence of longer latency excitation was found to be reduced in cats with corticospinal tract transections at the level of the second cervical spinal segment. No post-synaptic potentials were evoked by pyramidal stimulation rostral to a pyramidal transection at the level of the trapezoid body. It is suggested that disynaptic excitation evoked by pyramidal stimulation above the lower pyramidal lesion is mediated by medullary reticulospinal neurones possessing monosynaptic excitatory connexions with neck motoneurones. Longer latency excitation appears to be mediated by neurones that receive corticospinal tract input and are located in the spinal segments containing the neck motoneurones. Disynaptic inhibition is mediated by neurones likely to be situated between the second cervical spinal segment and the level of the lower pyramidal lesion. The results also suggest that the first neurone in the chain mediating longer latency inhibition is located in the brain stem. The differences in pyramidal synaptic input between splenius and biventer cervicis-complexus motoneurones are considered in relation to the roles these muscles may serve in head position control.

Factors determining the variation of the afterhyperpolarization duration in cat lumbar alpha-motoneurones

The duration of the afterhyperpolarization (AHP) in cat spinal alpha-motoneurones varies systematically with motoneurone type, being shorter in motoneurones projecting to fast-contracting muscle units. Recent experiments have shown that the AHP duration is correlated with the amount of sag found in the voltage response to injected constant current pulses. Using a model of the sag process, the present study shows that this correlation is likely to be causal to a substantial extent. Short AHP durations in fast motoneurones may thus be as much, or more, a consequence of a more developed sag process than of faster kinetics of the K conductance process underlying the AHP. This notion is also supported by the experimental observation of a decreased amount of sag and a prolonged AHP duration after axotomy.

An investigation of threshold properties among cat spinal alpha-motoneurones

In anaesthetized cats, thresholds for long (rheobase) and brief duration current pulses have been obtained from spinal motoneurones and compared with other cell parameters and membrane properties. Rheobase showed only weak over-all relationships with conduction velocity and with cell size, estimated as the total capacitance of individual motoneuronal equivalent cylinders. Rheobase showed a clear tendency to vary inversely with after-hyperpolarization (a.h.p.) duration and was strongly correlated with the input conductance and with the inverse of the membrane time constant. However, the range of rheobase current exceeded that of input conductance by almost a factor of 2. Part of this range discrepancy arose because threshold depolarization tended to increase with rheobase current. Thus, among motoneurones grouped according to rheobase magnitude (three groups), those within the lowest rheobase group had threshold depolarizations about 6 mV on average lower than those within the highest rheobase group. Even though this difference was not directly related to resting potential differences between the groups, further analysis suggested that it may have arisen secondarily to impalement-induced depolarization. The finding that experimentally estimated threshold depolarizations in individual motoneurones were generally larger than those predicted by the product of input resistance and rheobase indicated that a subthreshold rectification process also contributed to the range of rheobase. The difference was largest in the low-rheobase group and smallest in the high-rheobase group. Because these differences were proportional to the differences in input resistance between the separate motoneurone groups, it is suggested that the magnitude of the current underlying the rectification process does not differ systematically among motoneurones. Within groups of motoneurones classified on the basis of rheobase or a.h.p. duration, significant correlations existed between rheobase current and input conductance. An analysis of variance indicated that even within such functional subgroups of motoneurones, rheobase was appreciably better correlated with membrane time constant than with estimated cell size. Although showing a range approximately half that of rheobase, the brief current threshold was similar to rheobase in its relations with total cell capacitance, a.h.p. duration and the inverse of membrane time constant.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of axotomy on the distribution of passive electrical properties of cat motoneurones

Previously obtained experimental results concerning the effect of axotomy on motoneurone passive electrical properties have been re-analysed. As shown earlier, axotomy causes an average increase of motoneurone input resistance, membrane time constant and after-hyperpolarization duration. The present analysis suggests that the increased input resistance is related to a higher specific membrane resistivity, a decreased cell size and an altered dendritic geometry. The results also suggest that the change takes place only in neurones projecting to fast-twitch muscle units and produces in them passive electrical properties normally exhibited only by motoneurones projecting to slow-twitch units. Based on the notion that axotomy causes a 'dedifferentiation' of motoneurone properties, the present results might be taken to indicate that undifferentiated motoneurones are slow in character. A possible scheme in which a post-natal differentiation of motoneurone properties may lead to muscle differentiation is discussed.

Relations among passive electrical properties of lumbar alpha-motoneurones of the cat

The relations among passive membrane properties have been examined in cat motoneurones utilizing exclusively electrophysiological techniques. A significant relation was found to exist between the input resistance and the membrane time constant. The estimated electrotonic length showed no evident tendency to vary with input resistance but did show a tendency to decrease with increasing time constant. Detailed analysis of this trend suggests, however, that a variation in dendritic geometry is likely to exist among cat motoneurones, such that the dendritic trees of motoneurones projecting to fast-twitch muscle units are relatively more expansive than those of motoneurones projecting to slow-twitch units. Utilizing an expression derived from the Rall neurone model, the total capacitance of the equivalent cylinder corresponding to a motoneurone has been estimated. With the assumption of a constant and uniform specific capacitance of 1 mu F/cm2, the resulting values have been used as estimates of cell surface area. These estimates agree well with morphologically obtained measurements from cat motoneurones reported by others. Both membrane time constant (and thus likely specific membrane resistivity) and electrotonic length showed little tendency to vary with surface area. However, after-hyperpolarization (a.h.p.) duration showed some tendency to vary such that cells with brief a.h.p. duration were, on average, larger than those with longer a.h.p. durations. Apart from motoneurones with the lowest values, axonal conduction velocity was only weakly related to variations in estimated surface area. Input resistance and membrane time constant were found to vary systematically with the a.h.p. duration. Analysis suggested that the major part of the increase in input resistance with a.h.p. duration was related to an increase in membrane resistivity and a variation in dendritic geometry rather than to differences in surface area among the motoneurones. The possible effects of imperfect electrode seals have been considered. According to an analysis of a passive membrane model, soma leaks caused by impalement injury will result in underestimates of input resistance and time constant and over-estimates of electrotonic length and total capacitance. Assuming a non-injured resting potential of -80 mV, a comparison of membrane potentials predicted by various relative leaks (leak conductance/input conductance) with those actually observed suggests that the magnitude of these errors in the present material will not unduly affect the presented results.+4

Influence of post-synaptic properties on the time course of synaptic potentials in different types of cat lumbar alpha-motoneurons

Shape indices of excitatory post-synaptic potentials (EPSPs) have been calculated on compartmental models assembled using average properties obtained from two motoneuron groups classified as fast and slow, on the basis of rheobase current and input conductance. The calculated EPSP time courses differed considerably between the two models, the rise-time and half-width being more prolonged in the slow model. With a conductance change distributed uniformly among compartments 3-6 in a 10-compartment model, the resulting shape indices in the slow and fast model, respectively, were quite similar to the apparent average values previously observed experimentally for composite Ia EPSPs in types S (slow) and F (fast) motoneurons. The results of the calculations suggest that differences in EPSP shape indices observed between F and S motoneurons arise from systematic differences in motoneuron postsynaptic properties (specific membrane resistivity and dendritic geometry) rather than differences in dendritic location of synaptic input. The results also suggest that changes in EPSP time course, following section of the motor axon, may similarly be related to changes in motorneuron postsynaptic properties.

Voltage threshold and excitability among variously sized cat hindlimb motoneurons

Intracellular recording has been performed to examine whether any differences in apparent initial-segment voltage threshold exist between types F and S cat triceps surae motoneurons. Voltage threshold was estimated using orthodromic action potentials initiated by large, monosynaptic excitatory postsynaptic potentials (EPSPs) evoked by dorsal root stimulation. No significant differences in voltage threshold could be detected between types F and S motoneurons. Further, voltage thresholds did not covary with motoneuron input resistance, afterhyperpolarization duration, or the twitch contraction time of functionally isolated muscle units. Significant positive correlations were observed between voltage threshold and the motoneuron resting potential. Utilizing a compartmental neuron model, a theoretical analysis has been performed that examines the influence of specific passive membrane properties on current threshold for action potentials initiated by large, monosynaptic EPSPs. This analysis indicates that total membrane capacitance will be the primary determinant of these thresholds. Further analysis of available data suggests that active membrane properties will play a minimal role in setting these thresholds. Since specific membrane capacitance is likely to be similar among cat motoneurons, it is concluded that only size or surface area-related current threshold differences will exist among these cells for activation with brief currents such as those underlying large EPSPs. For motoneurons thus activated, it is suggested that variations in the excitatory/inhibitory balance or density of synaptic input would be the major mechanisms for producing differential recruitment thresholds among the motoneuron population. Other available evidence is discussed that indicates that factors intrinsic to the motoneurons themselves will contribute to the setting of functional recruitment thresholds for activation with longer duration currents.

Posttetanic potentiation of group Ia EPSPs: possible mechanisms for differential distribution among medial gastrocnemius motoneurons

We have reinvestigated the phenomenon of posttetanic potentiation (PTP) of group Ia monosynaptic excitatory postsynaptic potentials (EPSPs) in medial gastrocnemius (MG) alpha-motoneurons of pentobarbital-anesthetized cats. The results generally confirm earlier reports by Lüscher and colleagues (43, 44) of a negative correlation between the maximum percentage potentiation of Ia EPSP amplitude (Pmax) and 1) the mean amplitude of the pretetanic control EPSP in the same cell and 2) the input resistance of the postsynaptic motoneuron. These negative correlations, which we will refer to as "differential distribution of PTP" within the MG motor pool, were less strong in the present work than reported by Lüscher et al. (43, 44). We also found a relatively strong negative correlation between posttetanic EPSP depression, assessed by the amplitude of the first posttetanic EPSP, and the level of Pmax subsequently attained. We found no evidence that posttetanic depression is caused by failure of presynaptic action potentials. We investigated a second type of depression, referred to as "specific" synaptic depression, in which the second EPSP of paired responses (interval 250 ms) is, on average, smaller in peak amplitude than the first EPSP. This phenomenon appears to reflect decreases in the probability of transmitter release from previously activated synapses. Specific synaptic depression was consistently increased when paired responses were conditioned by a high-frequency tetanus. This is most easily explained by postulating that PTP results, at least in part, from an increase in the statistical probability of transmitter liberation from group Ia synapses that are activated (i.e., presumably invaded by action potentials) both before and after afferent tetanization. On the basis of the present results and other available evidence, we conclude that the differential distribution of PTP can be explained by two main factors: 1) the nonlinear relation between conductance and voltage changes inherent in all chemical synapses and 2) systematic variations in the properties of group Ia synapses that innervated different motoneurons, which remain to be clarified.

A HRP study of the relation between cell size and motor unit type in cat ankle extensor motoneurons

The dimensions of the somata and stem dendrites of 57 alpha- and three gamma-motoneurons, identified as to motor unit type and labeled by intracellular injection of horseradish peroxidase, were measured in the triceps surae and plantaris motor pools. The somata of type S motoneurons tended to be smaller (mean diameter 47.9 micrometers) than those of FF and FR units (52.5 and 53.1 micrometer, respectively) but these mean values were not significantly different and the data distributions showed considerable overlap between the unit types. The mean numbers and diameters of stem dendrites exhibited somewhat larger differences related to motor unit type and some of these were statistically significant. The total membrane area (AN) of each cell was estimated from measurements of the soma and stem dendrites, by using recent data and Ulfhake and Kellerth ('81) to calculate the membrane area of a dendritic tree from stem dendrite diameter. Mean AN varied with motor unit type in the sequence FF greater than FR greater than S (average values: 369 X 100(3) micrometers 2, 323 X 100(3) micrometers 2, and 250 X 100(3) micrometers 2, respectively). There was covariation between AN and the conduction velocity of the motor axon as well as with the force output from the muscle unit. Comparison of AN and motoneuron input resistance (RN) in 19 alpha-motoneurons suggested that the specific resistivity of the cell membrane in type S motoneurons was systematically higher than that characteristic of type FF or FR motoneurons.

Supraspinal facilitation of cutaneous polysynaptic EPSPs in cat medical gastrocnemius motoneurons

We examined the characteristics of postsynaptic potentials (PSPs) produced in antidromically-identified medical gastrocnemius (MG) alpha-motoneurons by electrical stimulation of low threshold (less than 3 x T) distal limb cutaneous afferents in the sural (SUR) nerve in adult cats anesthetized with alpha-chloralose, together with the effects of SUR PSPs of supraspinal conditioning stimulation of the contralateral red nucleus (RN) and pyramidal tract (PT). In the majority of MG motoneurons, SUR afferents with electrical thresholds less than 1.5 x T produced early excitatory synaptic potentials (EPSPs) with minimum central latency of about 2.0 ms, suggesting activation of a trisynaptic segmental pathway with two interposed interneurons. Such early EPSPs were often detectable with stimuli less than 1.2 x T, as determined by recording the compound action potential in the sciatic nerve and from the first appearance of the N1 wave of the cord dorsum potential. Inhibitory synaptic potentials (IPSPs) were regularly produced by SUR volleys of only slightly greater strength (often as low as 1.3 x T) and these had minimum central latencies of about 3.0 ms (about 1.0 ms longer than the earliest EPSPs), suggesting a three interneuron central pathway. Repetitive stimulation of RN and PT regularly produced facilitation of both EPSP and IPSP components in the SUR response, suggesting that these supraspinal systems directly or indirectly excite some of the same interneurons that convey the SUR effects to MG motoneurons. When using very low strength SUR stimuli, PT conditioning produced relatively pure facilitation of the SUR EPSPs but with larger SUr volleys, PT clearly facilitated both EPSPs and IPSPs. RN conditioning produced more parallel facilitation of SUR EPSPs and IPSPs. Supraspinal control of the polysynaptic pathway producing SUR EPSPs is of particular interest because of earlier evidence that this pathway is differentially distributed to motoneurons of fast twitch versus slow twitch MG motor units.