Temperature Effect on Proximal to Distal Gradient of Quantal Release of Acetylcholine at Frog Endplate

The conduction velocity of the nerve terminal, mean quantal content, and release latencies of uniquantal endplate currents (EPCs) were recorded in proximal, central, and distal parts of the terminal by extracellular pipettes located 5, 50, and 100 mm from the end of myelinated nerve trunk. The spike conduction velocity, minimal latency, modal value of the latency histograms, and time interval during which 90% of EPCs released (P₉₀) at distal, central, and proximal part of the frog nerve terminal have different temperature dependency between 10° and 28°C. As shown by the size and time-course of reconstructed multiquantal EPCs, the secretion synchronization, which is greatest in distal parts, compensates at least partly for the progressive slowing of spike conduction velocity in the proximodistal direction, in particular at lower temperatures.     

Characteristics of electrical activity in different sections of nerve endings in the frog

In experiments on frog sartorius neuromuscular preparations, the evoked electrical responses of nerve endings were recorded by extracellular microelectrodes. It was shown that in proximal parts of the nerve ending, the three-phase response (+ - +) with a high amplitude negative phase occurred due to motor nerve stimulation. With movement of the extracellular electrode in distal direction a certain increase of the initial positive phase and a significant decrease of the negative one were observed. At the end of the terminal that response transformed to the monophasic one (+). On local iontophoretic application of tetrodotoxin (TTX) to the recording site two components of the nerve ending response were revealed: TTX-insensitive and TTX-sensitive. A significant decrease of the TTX-sensitive component occurred along the course of the nerve ending. That component was absent from the distal synaptic areas. It is concluded that in frog nerve ending, the action potential propogates with decrement while depolarization of the end parts of the terminal is passive in nature.     

Transmitter release in proximal and distal parts of a nerve terminal of the frog sartorius muscle

Evoked synaptic potential were recorded extracellularly in experiments on a nervemuscle preparation of the frog sartorius muscle. A decrease in evoked transmitter release was found from the proximal to the distal parts of the nerve ending, due to a decrease in the probability of transmitter quantum release. The terminal portions of the synapse are less sensitive than the proximal parts to changes in Ca⁺⁺ concentration, they show less marked facilitation of transmitter release during paired and repetitive stimulation, and exhibit deeper and more rapidly developing depression. It is concluded that differences in transmitter release in the terminal parts of the synapse are due to the low reserves of transmitter and the lower premeability of the presynaptic membrane to Ca⁺⁺.     

The single nerve ending of the frog sartorius muscle: its ultrastructural characteristics and mediator secretion

Electron microscopy and extracellular recordings were used for the investigation of structural and functional peculiarities of single frog sartorius muscle nerve terminal. It has been found that the diameter, length of the synaptic contact and quantity of synaptic vesicles decreased from proximal to distal parts of the nerve terminal. A number of varicosities, separated from each other by schwann cells, have been revealed along the course of the nerve terminal. This indicates the existence of an interrupted synaptic contact. Both the evoked and spontaneous transmitter release decreased from the initial to the end parts of the nerve terminal. The data obtained suggest that there is a correlation between structural heterogeneity and the differences in the transmitter release.     

Changes in the asynchronism of transmitter release in a neuromuscular synapse and the time course of evoke postsynaptic signals during growth and branching og frog nerve ending

The influence of both growth and branching of a nerve terminal on the asynchronism of transmitter release and the time-course of evoked postsynaptic responses was investigated using a model of a frog neuromuscular synapse in which the nerve terminal represents a population of spatially isolated active zones. It was shown that the appearance of additional branching in proximal parts of the nerve ending leads to decrease in the asynchronism of transmitter release, an increase in quantum content and the amplitude of the postsynaptic signal, and the shortening of its phase of growth. It was found that the asynchronism of transmitter release has a much stronger influence on the time-course of end plate currents compared with end plate potentials. The factors strengthening and weakening the asynchronism of transmitter release in a neuromuscular synapse and the reasons for various length and branching of vertebrate nerve terminals are considered.     

Quantitative freeze-fracture analysis of the frog neuromuscular junction synapse – II. Proximal–distal measurements

Neurotransmitter release from different parts of frog motor nerve terminals is often non-uniform. There is a decrease in release efficacy from the distal regions of frog motor nerve terminal branches. Since release is thought to occur near the double arrays of large intramembranous particles that constitute the pre-synaptic active zones (AZs), we have examined quantitatively the proximal–distal distribution of AZ structure, using a novel freeze-fracture technique that produces replicas of large fractions of terminals, including the region of nerve entry. This enables us to know the proximal–distal orientation of each branch. From 23 end-plates we have obtained fractures of 72 branches. For 27 of these branches we have obtained continuous fractures both greater than 25 μm in length and with sufficient information to determine their proximal–distal polarity. Only a few of these branches showed a marked distal decrease in AZ length/unit length of terminal, while several junctions had short regions (5–10 μm), either proximally or distally, that exhibited amounts of AZ that were substantially greater or smaller than the mean value for that terminal branch. The terminal area, post-synaptic gutter width and nerve terminal width all exhibit some distal decline concomitant with the distal tapering of nerve terminal branches. AZ length tends to have the least decline compared to the other parameters. Thus, the vast majority of frog motor nerve terminal branches do not display a significant proximal-distal gradient in the amount of AZ structure/μm terminal length. The present data do not provide an obvious ultrastructural correlate for the distal decline in transmitter release that some authors have observed.     

Effect of carbacholine on proximal and distal regions of motor nerve terminals in the frog]

Carbacholine depressed postsynaptic currents in the frog m. sartorius leaving intact presynaptic currents in proximal and distal portions of the motor nerve ending. The carbacholine depressing action was followed by an increase in the time gap between the beginning of presynaptic depolarisation and subsequent quantal release. This effect was considerably more obvious in the distal portions of the nerve endings. Effect of extracellular potassium was evident in a diminishing of presynaptic currents due to membrane depolarisation. The data obtained suggest that carbacholine presynaptically depresses synaptic transmission via metabotropic cholinergic receptors controlling the time course of the transmitter release.     

Conditions of dominant effectiveness of distal sites of active uniform dendrites with distributed tonic inputs

This simulation study aimed at assessing linkage between the membrane properties and the effectiveness of somatopetal current transfer from activated tonic excitatory inputs homogeneously distributed along uniform dendrites. It was shown that in the dendrites having anN-shaped steady current-voltage membrane characteristic due to the negative slope within a certain range of potentials, distal sites can be more effective than proximal sites in somatopetal current transfer from tonically activated excitatory synaptic inputs. Inhomogeneous dendritic depolarization produced by these inputs should be found everywhere within a range of the negative slope. In simulated dendrites receiving, as in rat abducens motoneurons, voltage-sensitive synaptic inputs of anN-methyl-D-aspartate (NMDA) type, such spatial effects occurred at low depolarization produced by subcritical excitation. At supercritical excitation, depolarization increased and left the range of the negative slope, and proximal sites became much more effective than distal ones. It is suggested that persistent inward currents (including other than of NMDA nature) can provide similar effects.     

A quantitative study on the myenteric plexus of the distal end of the duodenum and the proximal part of the jejunum

4 necropsy specimens taken from adult individuals were used in order to estimate the density of nerve cell bodies of the myenteric plexus in the last distal 5 cm of the duodenum and the proximal 5 cm of the jejunum (including the duodenojejunal flexure), that were subdivided into parts of approximately 1 cm and stained by Giemsa's method according to Barbosa (1970). Except for the first 2 parts, an increase of the neuron number was observed toward the duodenojejunal flexure, the greatest being at this point, and then decreasing progressively. The first duodenal parts, which corresponds approximately to the intersection of the mesenteric artery with the duodenum, showed the same neuron density as the duodenojejunal flexure. In this paper the 2 parts with higher neuron density were related to functional sphincteric zones, previously described.     

Task-dependent spatial distribution of neural activation pattern in human rectus femoris muscle

Compartmentalization of skeletal muscle by multiple motor nerve branches, named as neuromuscular compartment (NMC), has been demonstrated in animals as well as humans. While different functional roles among individual NMCs were reported in the animal studies, no studies have clarified the region-specific functional role within a muscle related with NMCs arrangement in human skeletal muscle. It was reported that the rectus femoris (RF) muscle is innervated by two nerve branches attached at proximal and distal parts of the muscle. The purpose of the present study is to clarify the possible region-specific functional role in the human RF muscle. Multi-channel surface electromyography (SEMG) were recorded from the RF muscle by using 128 electrodes during two different submaximal isometric contractions that the muscle contributes, i.e. isometric knee extension and hip flexion, at 20%, 40%, 60% and 80% of maximal voluntary contraction (MVC). Results indicated that the central locus activation for the amplitude map of SEMG during hip flexion located at more proximal region compared with that during knee extension. Significant higher normalized root mean square (RMS) values were observed at the proximal region during the hip flexion in comparison to those at middle and distal regions at 60% and 80% of MVC (p<0.05). In while, significant higher normalized RMS values were demonstrated at the distal region comparing with that at the proximal region at 80% of MVC (p<0.05). The results of the present study suggest possible region-specific functional role in the human RF muscle.     

Functional coordination of motor activity in colonic smooth muscles in rat experimental model

Spontaneous and electrically-elicited motor activity was recorded by triple organ bath in rat segment-model preparation as display of excitation of local nerve networks and ascending or descending reflex pathways underlying contractile potency and functional coordination of colonic longitudinal and circular muscles. Spontaneous high-amplitude contractions, but not relaxations, appeared synchronously in both muscles. Electrical field stimulation applied to proximal or distal part of segments elicited both tetrodotoxin (0.1 microM)-sensitive local motor responses of the stimulated part and ascending or descending motor responses of the contralateral, nonstimulated part of the preparations. Contractions characterized the local response of longitudinal muscle. The circular muscle responded with relaxation followed by contraction. Synchronous ascending contractions and descending contraction of the longitudinal muscle and relaxation followed by contraction of the circular muscle were observed when the middle part of segments was stimulated, thus indicating that locally-induced nerve excitation propagated via intrinsic ascending or descending nerve pathways that could be synchronously coactivated by one and the same stimulus. The ascending motor responses were more pronounced and the motor responses of longitudinal muscle were expressed more than those of circular muscle suggesting an essential role of ascending reflex pathways and longitudinal muscle in the coordinated motor activity of colon.     

RETROGRADE AXONAL TRANSPORT OF RAPIDLY MIGRATING PROTEINS IN THE VAGUS AND HYPOGLOSSAL NERVES OF THE RABBIT

—The redistribution of rapidly migrating [³H]leucine-labelled proteins was studied using double ligatures applied to the vagus nerve and single ligatures, applied to the hypoglossal nerves. Rapidly migrating proteins accumulating for 16 h proximal to a distal ligature of the cervical vagus redistributed to give a retrograde accumulation distal to a second ligature. Within 6 h a substantial redistribution occurred indicating a rapid retrograde transport. After 21 h there was a further accumulation with 70 per cent of the labelled material accumulating at the distal end of the isolated nerve segment and 16 per cent accumulating at the proximal end. It was shown that about a half of the retrograde accumulation was dependent on the distal accumulation zone. Rapidly migrating proteins accumulated distal to a ligature applied to the hypoglossal nerve 16 h after labelling of the nerve cell bodies indicating that a rapid retrograde transport of labelled macromolecules occurs from the peripheral parts of the nerve in the tongue. Labelled proteins accumulated proximal to ligatures and transections of both the hypoglossal and vagus nerve when applied 16 h after labelling of the nerve cell bodies, indicating the presence of axonal proteins, migrating at a rate of transport intermediate to that of rapidly and slowly migrating proteins.     

Formation of the tooth enamel rod pattern and the cytoskeletal organization in secretory ameloblasts of the rat incisor

The localization of actin, myosin, tropomyosin, alpha-actinin, vinculin, and desmoplakin I/II was visualized by immunofluorescence microscopy. Antibodies against myosin, tropomyosin, and alpha-actinin and rhodamine-phalloidin labeled strongly the proximal and distal terminal webs which ultrastructurally consist of dense microfilament bundles. In the distal terminal web, the staining by these reagents occurred mostly perpendicular to the long axis of the incisor. Antivinculin stained the general area where the distal terminal web is located in the ameloblast. Anti-desmoplakin I/II labeled the junctional area associated with the proximal and distal terminal webs. The anti-desmoplakin staining was stronger along the cell border perpendicular to the long axis of the incisor. Comparison of the rhodamine-phalloidin staining pattern of the distal terminal web and the enamel secretion pattern by ameloblasts revealed that a change in the distal terminal web staining pattern preceded a change in the secretion pattern. These observations suggest that the cytoskeletal organization in the ameloblast is involved in the formation of the enamel matrix pattern in the rat incisor.     

ENaC and ROMK channels in the connecting tubule regulate renal K+ secretion

We measured the activities of epithelial Na channels (ENaC) and ROMK channels in the distal nephron of the mouse kidney and assessed their role in the process of K⁺ secretion under different physiological conditions. Under basal dietary conditions (0.5% K), ENaC activity, measured as amiloride-sensitive currents, was high in cells at the distal end of the distal convoluted tubule (DCT) and proximal end of the connecting tubule (CNT), a region we call the early CNT (CNTe). In more distal parts of the CNT (aldosterone-sensitive portion [CNTas]), these currents were minimal. This functional difference correlated with alterations in the intracellular location of ENaC, which was at or near the apical membrane in CNTe and more cytoplasmic in the CNTas. ROMK activity, measured as TPNQ-sensitive currents, was substantial in both segments. A mathematical model of the rat nephron suggested that K⁺ secretion by the CNTe predicted from these currents provides much of the urinary K⁺ required for K balance on this diet. In animals fed a K-deficient diet (0.1% K), both ENaC and ROMK currents in the CNTe decreased by ∼50%, predicting a 50% decline in K⁺ secretion. Enhanced reabsorption by a separate mechanism is required to avoid excessive urinary K⁺ losses. In animals fed a diet supplemented with 3% K, ENaC currents increased modestly in the CNTe but strongly in the CNTas, while ROMK currents tripled in both segments. The enhanced secretion of K⁺ by the CNTe and the recruitment of secretion by the CNTas account for the additional transport required for K balance. Therefore, adaptation to increased K⁺ intake involves the extension of robust K⁺ secretion to more distal parts of the nephron.     

Anatomical consideration of reverse-flow island flap transfers from the midpalm for finger reconstruction.

Primary soft-tissue coverage for large palmar defects of the fingers is a difficult problem for cases in which homodigital or heterodigital flaps cannot be used. The aim of this study was to explore the vascular and neural anatomy of the midpalmar area to assess the possibility of reverse island flaps from this area. In 24 cadaver hands perfused with a silicone compound, the arterial pattern of the superficial palmar arch and common palmar digital artery was examined. The cutaneous perforating arteries and nerve branches supplying the midpalmar area were dissected, and the number, location, and arterial diameter of these branches were measured. In six other specimens, the common palmar digital artery was injected to determine the skin territory supplied by the artery. The superficial palmar arch contained the three common palmar digital arteries and its terminal branch coursed along the radial margin of the index metacarpus. This terminal branch had three to six cutaneous perforators (diameter range, 0.1 to 0.5 mm) and supplied the radial aspect of the midpalmar area located over the ulnar half of the adductor pollicis muscles. The midpalmar area was divided into two regions-the proximal and distal-according to the vascular distributions. The proximal region contained dense aponeurosis and thin subcutaneous tissue, and the cutaneous perforators were rather sparse (between three and nine) and had a small diameter (0.1 to 0.3 mm). The distal region, which had loose aponeurosis and abundant subcutaneous tissue, had a rich vascular supply from the common and proper digital artery. Perforating arteries of this region coursed frequently in an oblique fashion and the number of perforators (between eight and 15) and their arterial diameters (diameter range, 0.1 to 0.5 mm) were higher than those of the proximal region. The area of skin perfused by the common palmar digital artery was 5 x 3 cm at the distal midpalmar region. There were three to five cutaneous nerve branches from the palmar digital nerve supplying the midpalmar area. From this study, two different reverse flaps were proposed. First, a 5 x 2 cm flap from the distal midpalmar region was elevated on the basis of the common and proper palmar digital artery. Measurement of the rotation arc revealed that the pivot point of this flap was located at the proximal interphalangeal joint level and could cover the finger pulp of the digits. The second flap candidate was that from the radial aspect of the midpalm, which was supplied by the terminal branch of the superficial palmar arch. In studies with cadaver hands, connection of this artery with the deep arterial system enabled this flap to reach the thumb pulp. These flaps may be a useful reconstruction option for significant palmar soft-tissue loss of the fingers.     

Expression of cytotactin in the normal and regenerating neuromuscular system

Cytotactin is an extracellular glycoprotein found in a highly specialized distribution during embryonic development. In the brain, it is synthesized by glia, not neurons. It is involved in neuron-glia adhesion in vitro and affects neuronal migration in the developing cerebellum. In an attempt to extend these observations to the peripheral nervous system, we have examined the distribution and localization of cytotactin in different parts of the normal and regenerating neuromuscular system. In the normal neuromuscular system, cytotactin accumulated at critical sites of cell-cell interactions, specifically at the neuromuscular junction and the myotendinous junction, as well at the node of Ranvier (Rieger, F., J. K. Daniloff, M. Pincon-Raymond, K. L. Crossin, M. Grumet, and G. M. Edelman. 1986. J. Cell Biol. 103:379-391). At the neuromuscular junction, cytotactin was located in terminal nonmyelinating Schwann cells. Cytotactin was also detected near the insertion points of the muscle fibers to tendinous structures in both the proximal and distal endomysial regions of the myotendinous junctions. This was in striking contrast to staining for the neural cell adhesion molecule, N-CAM, which was accumulated near the extreme ends of the muscle fiber. Peripheral nerve damage resulted in modulation of expression of cytotactin in both nerve and muscle, particularly among the interacting tissues during regeneration and reinnervation. In denervated muscle, cytotactin accumulated in interstitial spaces and near the previous synaptic sites. Cytotactin levels were elevated and remained high along the endoneurial tubes and in the perineurium as long as muscle remained denervated. Reinnervation led to a return to normal levels of cytotactin both in inner surfaces of the nerve fascicles and in the perineurium. In dorsal root ganglia, the processes surrounding ganglionic neurons became intensely stained by anticytotactin antibodies after the nerve was cut, and returned to normal by 30 d after injury. These data suggest that local signals between neurons, glia, and supporting cells may regulate cytotactin expression in the neuromuscular system in a fashion coordinate with other cell adhesion molecules. Moreover, innervation may regulate the relative amount and distribution of cytotactin both in muscle and in Schwann cells.     

Structure of the kidney in the crab-eating frog, Rana cancrivora

The structure of the nephron in the ranid frog, Rana cancrivora, was studied by light and electron microscopy. This frog is the only amphibian species to live in mangrove swamps of very high salinity. The nephron consists of the following parts: renal corpuscle, ciliated neck segment, proximal tubule, ciliated intermediate segment, distal tubule, connecting tubule, and collecting duct. The distal tubule is located in the ventromedial region of the kidney, and the other tubules are situated in the dorsolateral region. Renal corpuscles are found between the two regions. Some renal corpuscles have a wide Bowman's space because of the small glomerulus within them. The proximal tubules are composed of columnar cells with a dense luminal brush border of long microvilli and numerous apical vesicles and vacuoles. The initial part of the distal tubule consists of heavily interdigitated cells, characterized by a very regular palisade arrangement of mitochondria. In the terminal part of the distal tubule, shorter mitochondria of the infolding cells are situated irregularly around the nucleus. The connecting tubule consists of principal cells and canaliculus cells. The collecting duct consists of columnar or cuboidal cells; cytoplasmic organelles are relatively sparse. The canaliculus cells are intercalated between principal cells from the terminal distal tubule to the proximal part of the collecting duct. Our findings indicate that the kidney of R. cancrivora is structurally similar to kidneys of other amphibians. These findings are discussed with regard to probable correlations between ultrastructure and function in R. cancrivora.     

Transmitter secretion in neuro-muscular junctions of different length and RAMIFI-cation

Nerve terminals with different length of their branches and with different types of ramification have been studied in the experiments performed on frog cutaneous-pectoralis muscle using electrophysiological and morphological techniques. It has been found that the spatial distribution of the nerve impulse-evoked transmitter secretion along each terminal branch is complex: The secretion increases distalward along the proximal by nearly a third of the terminal length and decreases linearly along its more distal portions. An increase in terminal length is followed by distalward shift of the secretion peak, by more gradual decay in the secretion if plotted along distal portions of the terminal, and by a decreased contribution of the secretion from distal portions to total secretion from the terminal. The critical terminal length at which total secretion from the terminal reached its maximum has been estimated. The distalward decrease of a secretion along the secondary terminal branches is similar to that found in the distal portion of the main terminal branch next to the ramification knot. An increase in terminal length and in the number of branchings is followed by decreased conduction velocity and transmitter release synchronism. The mechanisms determining limitations of the terminal length and the appearance of secondary terminal branches are discussed.Neirofiziologiya/Neurophysiology, Vol. 25, No. 3, pp. 170–175, May–June, 1993.     

Effect of Wallerian Degeneration on Histamine Concentration of the Peripheral Nerve

One sciatic nerve of a White Leghorn hen was severed and the distal portion was allowed to undergo Wallerian degeneration. The change in histamine and DNA concentration and mast cell number was measured at different times following nerve sectioning in the proximal regenerating, distal degenerating, and intact, contralateral nerves. The experimental results revealed a significant accumulation of histamine in the proximal desheathed segment and in the contralateral “functional nerve,” whereas the biogenic amine in the distal desheathed nerve significantly decreased. The pattern of change of histamine in the distal and proximal nerve sheaths was different: it dropped at 2 h and then rose in the later stages of Wallerian degeneration. In the distal desheathed nerves and in both the proximal and distal nerve sheaths DNA increased significantly by 14 days. The number of mast cells appeared to be highest in the 14-day distal nerve and in the 7-day proximal nerve sheaths. These results support a dual localization of histamine in the peripheral nerve, and are consistent with the interpretation that the amine has either some role in neurotransmission or in the process of growth and regeneration.