Ocular anomaly in Atlantic midshipman Porichthys plectrodon (Batrachoidiformes: Batrachoididae) from the Mississippi Canyon, north-central Gulf of Mexico.

The first record of an ocular anomaly in Atlantic midshipman Porichthys plectrodon (Batrachoidiformes: Batrachoididae) is reported from a specimen captured in the Mississippi Canyon. The anomalous specimen was bilaterally anophthalmic and the nape and dorsum were darkly pigmented but alizarin staining and histology revealed a complete eye embedded within the cranium beneath a markedly thickened dermal component of the cornea, along with seemingly minor elaboration of the choroid rete between the cornea and lens. Aetiology is indeterminate and beyond the scope of the study materials but barotrauma, infectious disease and previous wounding are doubtful.

Comparative analysis of the effects of sample source and test methodology on the assessment of protein expression in acute myelogenous leukemia.

Numerous studies have analyzed the expression and prognostic importance of various proteins in acute myelogenous leukemia (AML). We sought to determine whether the sample source and methodology used to measure protein expression affect the results obtained. To determine the importance of sample source, we used Western blotting to compare the expression of eight proteins and phosphoproteins in the leukemia blast-enriched fraction of 118 blood- and 108 marrow-derived samples, including 37 paired samples. To determine the importance of methodology, the expression of five proteins was measured in 20 paired samples by Western blotting, laser scanning cytometry (LSC), and flow cytometry. The mean expression and range of expression in blood- and marrow-derived samples were statistically identical for all eight proteins. Expression measurements for the 37 paired blood and marrow samples also had very high statistical correlation. The LSC and flow cytometry data had the highest concordance when compared using Kolmogorov-Smirnoff D-stats (range of R values, 0.8-1.0). High concordance was also observed between the LSC and flow cytometry results when the percentage of cells positive for expression was dichotomized into positive or negative expression. However, there was less correlation between LSC and flow cytometry when the actual percentages of positive cells were compared. The majority of discordant situations involved samples that were positive by flow cytometry but negative by LSC. The correlation between Western blotting signal intensity and the percentage of expression-positive cells measured by LSC or flow cytometry varied by protein but was limited when there was little heterogeneity in expression by either method. In conclusion, provided that leukemia blast-enriched fractions were analyzed, the blood- and marrow-derived samples had identical protein expression. There was good concordance of results between flow cytometry and LSC, which share similar technology, but more limited correlation between these methods and Western blotting.

Urine analysis by laser Raman spectroscopy.

BACKGROUND AND OBJECTIVE: We examine the use of Raman spectroscopy to analyze components in human urine. STUDY DESIGN/MATERIALS AND METHODS: Targeted urine components include urea, uric acid, and creatinine. RESULTS: Urea concentration in urine is sufficiently high that normal Raman spectroscopy may be used for its analysis. All other components are in low concentrations requiring the use of surface-enhanced Raman spectroscopic methods (SERS). CONCLUSIONS: Both normal Raman and SERS approaches have been investigated for total urine-nitrogen determination, urine urea-nitrogen determination, and for the urea/creatinine excretion ratio.

Nerve growth factor facilitates cholinergic neurotransmission between nucleus basalis and the amygdala in rat: an electrophysiological analysis.

Treatment of rats in vivo with NGF promotes the survival and enhances the neurotransmitter phenotype of basal forebrain cholinergic neurons. We showed recently (Williams et al., 1993) that NGF-induced stimulations of the cholinergic markers ChAT and high-affinity choline uptake are reflected in an enhanced synthesis and release of ACh in terminals fields of basal forebrain cholinergic neurons. The objective of the present study was to determine whether such effects translate into an enhancement in neurotransmission between nucleus basalis neurons and postsynaptic target cells, and therefore are likely to be of physiological significance. Changes in cholinergic neurotransmission after NGF were assessed by comparing the ability of cholinergic pathway activation, produced by electrical stimulation of nucleus basalis or the external capsule, to elicit intracellularly recorded muscarinic responses in basolateral amygdaloid (BLA) neurons in ventral forebrain slice preparations from NGF-treated and control Fischer 344 adult rats. Chronic infusion of NGF for 3 weeks (1.2 micrograms/d, i.c.v.) increased the likelihood of eliciting cholinergic slow depolarizations (slow EPSP) via stimulation of cholinergic pathways in the slice. In addition, the frequency-response curves for generation of the cholinergic slow EPSP by nucleus basalis or external capsule stimulation were shifted approximately twofold to the left and the EF50 values significantly reduced in neurons from NGF-treated slices, compared to those in preparations from vehicle-treated or untreated controls. Treatment with NGF also resulted in a leftward shift in the frequency-response curve for cholinergic pathway-induced blockade of the slow afterhyperpolarization, without change in the maximal inhibitory effect. The NGF-induced enhancement in cholinergic synaptic effectiveness was not accompanied by alterations in the resting membrane properties or intrinsic excitability of BLA pyramidal neurons. Nor did treatment with NGF affect their chemosensitivity or responsiveness to direct postsynaptic applications of the cholinergic carbachol. We conclude from these results that chronic administration of exogenous NGF can facilitate neurotransmission within basal forebrain cholinergic projections in normal adult brain, presumably as a consequence of its ability to stimulate presynaptic mechanisms involved in synthesis and/or release of ACh.

Multiple effects of long-term morphine treatment on postsynaptic beta-adrenergic receptor function in hippocampus: an intracellular analysis.

We previously reported that beta-adrenergic receptors are increased in cerebral cortex and hippocampus in rats treated chronically with morphine and subsequently down-regulated after morphine withdrawal [22,23]. The changes in receptor density in hippocampus were accompanied by a corresponding super- and subsensitivity, respectively, in beta-adrenergic responsiveness, as assessed electrophysiologically by measuring the ability of isoproterenol to augment population spike responses in the slice. In this study, we compared the ability of isoproterenol to reduce the Ca(2+)-activated K+ slow afterhyperpolarization (slow AHP) in pyramidal neurons in hippocampal slices from opiate-naive and chronic morphine-treated rats to determine whether such changes in beta-adrenergic receptor function are localized postsynaptically. Chronic treatment of rats with morphine produced a 3.5-fold parallel shift to the left in the concentration-response curve for isoproterenol and reduced the EC50 from 4.8 +/- 1.3 to 1.4 +/- 0.5 nM. In contrast, sensitivity and maximal responsiveness to isoproterenol was markedly decreased in pyramidal neurons recorded in slices from morphine withdrawn animals. The concentration-response curves for inhibition of the slow AHP by carbachol or forskolin were not affected by chronic morphine treatment. However, blockade of the slow AHP by forskolin was significantly reduced in pyramidal neurons studied after morphine withdrawal. These data suggest that the increase in electrophysiological responsiveness to beta-adrenergic receptor stimulation found in hippocampus after chronic morphine treatment most likely resulted from an up-regulation in postsynaptic membrane receptors, whereas alterations occurring beyond the receptor level may be involved in the desensitization that is associated with morphine withdrawal.

Metabotropic glutamate receptor agonist ACPD inhibits some, but not all, muscarinic-sensitive K+ conductances in basolateral amygdaloid neurons.

Muscarinic agonists produce membrane depolarization and losses of spike frequency accommodation and the slow afterhyperpolarization (AHP) when applied to neurons of the basolateral amygdala (BLA). Underlying these changes are the muscarinic-induced inhibitions of several K+ conductances, including the voltage-activated M-current (IM), a slowly decaying Ca(2+)-activated current (IAHP), a voltage-insensitive leak current (ILeak), and the hyperpolarization-activated inward rectifier current (IIR). Similar depolarizations and losses of the slow AHP have been observed in other neuronal cell types following stimulation of metabotropic glutamate receptors. Therefore, we tested the effects of the metabotropic glutamate receptor agonist, 1-aminocyclopentane-1s,3R-dicarboxylic acid (ACPD), on pyramidal neurons impaled with a single microelectrode for current- and voltage-clamp recordings in a brain slice preparation of the rat BLA. Application of ACPD (20 or 100 microM) to BLA neurons inhibited IM and IAHP, resulting in membrane depolarization and reductions in the amplitude and duration of the slow AHP. However, ACPD did not inhibit the muscarinic-sensitive current IIR, nor was ILeak blocked in the majority of neurons examined. These findings suggest the possibility that muscarinic cholinergic and metabotropic glutamatergic receptor agonists may activate separate intracellular transduction pathways which have convergent inhibitory effects onto IM and IAHP in BLA pyramidal neurons.

Hyperpolarization-activated currents in neurons of the rat basolateral amygdala.

1. A single microelectrode was used to obtain current-clamp or voltage-clamp recordings from two neuronal cell types (pyramidal and late-firing neurons) in the basolateral nucleus of the amygdala (BLA) in slices of the rat ventral forebrain. Conductances activated by hyperpolarizing voltage steps from a holding potential of -70 mV were identified and their sensitivity to muscarinic modulation was determined using bath superfusion of carbachol. 2. Unclamped pyramidal neurons exhibited anomalous rectification, seen as a slowly developing depolarizing sag in the electronic potential in response to a hyperpolarizing current pulse. 3. Stepping voltage-clamped pyramidal neurons to command potentials of between -70 and -100 mV activated a slowly developing inward current (ISlow) that followed a single exponential time course. Larger hyperpolarizing voltage steps evoked a rapidly developing inward current (IFast) that preceded the development of ISlow. 4. The ISlow component reversed at a level positive to the -70 mV holding potential. Its rate of activation accelerated as the hyperpolarizing voltage step was made more negative. The threshold for activation of the conductance underlying ISlow was approximately -60 mV, with half-activation occurring at -90 mV. 5. Extracellular Cs+ (2 mM) blocked ISlow and eliminated anomalous rectification in unclamped pyramidal neurons. The inhibition of ISlow by Cs+ was also associated with membrane hyperpolarization and reduction of the medium afterhyperpolarization. ISlow was unaffected by extracellular Ba2+ (100 microM). The properties of this current appeared similar to that of the mixed cationic H-current previously identified in other neurons. 6. In comparison with pyramidal cells, unclamped late-firing neurons displayed a lesser but more rapidly developing anomalous rectification in response to large hyperpolarizations from rest. In voltage clamp, hyperpolarizing steps to command potentials more negative than -100 mV elicited IFast. Late-firing neurons expressed little or no ISlow. 7. The properties of IFast were identical in both pyramidal and late-firing neurons. This current reversed at a potential negative to -70 mV. Its rate of current activation increased with the magnitude of the hyperpolarizing voltage step. This rate was approximately sevenfold faster than ISlow activation recorded at the same membrane potential. IFast was blocked by 2 mM extracellular Cs+ and reduced by 100 microM extracellular Ba2+. The threshold for activation of the underlying conductance was approximately -85 mV, with half-activation occurring at -112 mV. The properties of IFast were similar to those of the inward rectifier current previously identified in other central neurons. 8. Carbachol (40 microM) largely blocked IFast without affecting its rate of activation.(ABSTRACT TRUNCATED AT 400 WORDS)

Muscarinic modulation of conductances underlying the afterhyperpolarization in neurons of the rat basolateral amygdala.

The excitability level of pyramidal neurons in the basolateral amygdala (BLA) is greatly increased following muscarinic receptor activation, an effect associated with an increased rate of action potential firing and reduction of the afterhyperpolarization (AHP). We impaled BLA pyramidal neurons in slices of rat ventral forebrain with a single microelectrode to examine the currents underlying the AHP and spike frequency accommodation and determine their sensitivities to muscarinic modulation. In voltage-clamp, depolarizing steps were followed by biphasic outward tail currents, consisting of rapidly decaying (IFast) and slowly decaying (ISlow) current components. These corresponded temporally with the medium and slow portions of the AHP, respectively. The reversal potential for the IFast component of the AHP tail current shifted in the depolarizing direction with increases in the extracellular K+ concentration. The amplitude of IFast was reduced during perfusion of 0-Ca2+ medium or by superfusion of TEA (1-5 mM) or carbachol (10-40 microM). It is suggested that IFast was produced by the rapidly decaying Ca(2+)-activated K+ current (IC) and the muscarinic-sensitive M-current (IM). The ISlow tail current component reversed at the estimated values for EK in medium containing either normal or elevated K+ levels. This component was eliminated by perfusion of 0-Ca2+ medium or inclusion of cyclic-AMP in the recording electrode. It was not blocked by TEA (5 mM) or apamin (50-500 nM), but was reduced by carbachol in a dose-dependent manner (IC50 = 0.5 microM). Electrical stimulation of cholinergic afferent pathways to the BLA produced inhibition of ISlow, an effect which was enhanced by eserine and prevented by atropine. Loss of the ISlow component was always accompanied by similar reductions in accommodation and the slow AHP. It was concluded that this tail current component resulted from the slowly decaying Ca(2+)-activated K+ current, IAHP. Thus, the muscarinic inhibition of IAHP contributes to the enhanced excitability exhibited by BLA pyramidal neurons following cholinergic stimulation.

Muscarinic inhibition of M-current and a potassium leak conductance in neurones of the rat basolateral amygdala.

1. Voltage-clamp recordings using a single microelectrode were obtained from pyramidal neurones of the basolateral amygdala (BLA) in slices of the rat ventral forebrain. Slow inward current relaxations during hyperpolarizing voltage steps from a holding potential of -40 mV were identified as the muscarinic-sensitive M-current (IM), a time- and voltage-dependent potassium current previously identified in other neuronal cell types. 2. Activation of IM was voltage dependent with a threshold of approximately -70 mV. At membrane potentials positive to this, the steady-state current-voltage (I-V) relationship showed substantial outward rectification, reflecting the time- and voltage-dependent opening of M-channels. The underlying conductance (gM) also increased sharply with depolarization. 3. The reversal potential for IM was -84 mV in medium containing 3.5 mM K+. This was shifted positively by 27 mV when the external K+ concentration was raised to 15 mM. 4. The time courses of M-current activation and deactivation were fitted by a single exponential. The time constant for IM decay, measured at 24 degrees C, was strongly dependent on membrane potential, ranging from 330 ms at -40 mV to 12 ms at -100 mV. 5. Bath application of carbachol (0.5-40 microM) inhibited IM, as evidenced by the reduction or elimination of the slow inward M-current relaxations evoked during hyperpolarizing steps from a holding potential of -40 mV. The outward rectification of the steady-state I-V relationship at membrane potentials positive to -70 mV was also largely eliminated. The inhibition of IM by carbachol was dose dependent and antagonized by atropine. 6. Carbachol produced an inward current shift at a holding potential of -40 mV that was only partially attributable to inhibition of IM. An inward current shift was also produced by carbachol at membrane potentials negative to -70 mV, where IM is inactive. These effects were dose dependent and antagonized by atropine. They were attributed to the muscarinic inhibition of a voltage-insensitive potassium leak conductance (ILeak). 7. In most cells, carbachol reduced the slope of the instantaneous I-V relationship obtained from a holding potential of -70 mV so that it crossed the control I-V plot at the reversal potential for ILeak. This was found to be -108 mV in 3.5 mM K+ saline, shifting to -66 mV in 15 mM K+ saline.(ABSTRACT TRUNCATED AT 400 WORDS)

Postlarval growth of the peripheral gustatory system in the channel catfish, Ictalurus punctatus.

The phenomenon of postlarval cell addition to the peripheral nervous system of fish has been reported for some sensory systems, but has yet to be characterized for the gustatory system. Many fishes, such as catfish, possess taste buds scattered across their body surface, and presumably, the number of taste buds increases during growth of the animal. The present study was undertaken in order to examine the process of growth in the peripheral gustatory system and to determine whether the degree of convergence of receptors onto primary sensory afferents changes during growth. The recurrent facial nerve of channel catfish was used for these studies since this nerve contains no general cutaneous components and innervates taste buds along the fish's body surface. Electron micrographs were made of cross sections of this nerve taken from individuals ranging in size from 5.1 to 39.5 cm standard length. In addition, estimates were made of the number of taste buds innervated by this nerve by determining taste bud density along selected regions of the flank and fins in large and small fish. As catfish get larger, the number of both myelinated and unmyelinated axon profiles in the recurrent facial nerve increases, but at a slower rate than the number of taste buds innervated by this nerve. Thus, on average, the number of taste buds innervated by each fiber increases as the fish enlarges; on average there are 2 taste buds per axons profile in small fish and nearly 14 taste buds per axon profile in large fish. The rate of addition of new axon profiles to the nerve is estimated at roughly 70 per day over the range of sizes studied. Although generation of new ganglion cells and axons may contribute to this increase, several lines of evidence indicate that axonal branching occurs. In addition, the mean axon diameter for both myelinated and unmyelinated axons increases during postlarval growth. The finest myelinated fibers (0.2 micron) in small animals were significantly smaller than the finest myelinated fibers (0.7 micron) in larger animals.

Inhibition of a cAMP-dependent Ca-activated K conductance by forskolin prolongs Ca action potential duration in lamprey sensory neurons.

Intracellular recordings from primary mechanosensory neurons (dorsal cells) of the lamprey spinal cord were made to test the membrane effects of forskolin, an activator of adenylate cyclase in these cells. At a concentration of 50 microM, forskolin was found to have a pronounced broadening effect on calcium action potentials (Ca APs) produced in the presence of voltage-activated K channel blockers (TEA, 3,4-DAP). Forskolin had no effect on passive membrane properties of the cells, such as resting potential or input resistance. Nor did it affect delayed rectification or Na APs and thus appeared not to block voltage-activated K channels. Forskolin's effect was evident only when a significant Ca component to the AP was present. It appeared not to increase the conductance of the Ca channel since its action was accompanied by a decrease in membrane conductance during the Ca AP, indicating instead an inhibition of a repolarizing Ca-activated conductance, other than a Ca-activated Cl conductance. The prolongation of Ca APs by forskolin, barium or the neurotransmitter GABA were all correlated in voltage-clamp with a decrease in outward current. Under the conductions used here, the major outward conductance in dorsal cells is a Ca-activated K conductance (gK(Ca]28, and it is concluded that the most probable mode of action for forskolin is via a cyclic AMP-mediated inhibition of this conductance. GABA has also been shown to prolong Ca APs in lamprey dorsal cells by inhibiting a repolarizing gK(Ca)28. Thus, the action of this transmitter may be mediated by an increase in intracellular cyclic AMP.

Synapsin I-like immunoreactivity in nerve fibers associated with lingual taste buds of the rat.

Immunoreactivity to synapsin I, a neuronal phosphoprotein, was localized in free-floating tissue sections prepared from lingual tissue of rats. Many nerve fibers within the tissue exhibited clear immunoreactivity including motor endplates on striated muscle, autonomic fibers innervating blood vessels or glands, and sensory fibers innervating muscles or the lingual epithelium including taste buds. Numerous immunoreactive fibers occurred within each taste bud, with fewer, fine fibers being dispersed in the epithelium between taste buds. The majority of the intragemmal immunoreactive fibers extended throughout the taste buds most of the distance outward from the basal lamina toward the surface of the epithelium. Fine, perigemmal fibers reached nearly to the epithelial surface. Ultrastructural analysis of the immunoreactive sensory fibers revealed that synapsin I-immunoreactivity occurred diffusely throughout the cytoplasm, and heavily in association with microvesicles. The synaptic vesicles at the taste receptor cell-to-afferent fiber synapse were, however, not immunoreactive for synapsin I, although these vesicles fall into the size class shown to be immunoreactive in other systems. This absence of synapsin I may be a common property of vesicles in axonless short receptor cells.

Synodontid catfish: a new group of weakly electric fish. Behavior and anatomy.

Three species of synodontid catfish can produce weak biphasic electric discharges in either continuous or burst-like fashion. The peak-power frequency of these electric organ discharges is around 100 Hz. The electric organ appears to have originated from a sonic muscle: the organ lies dorsal to the swim bladder, contains modified muscle tissue, and is innervated from a motor nucleus located in the caudal medulla. It is possible that synodontid catfish use electric signals in communication and/or object detection.

Activation of adenylate cyclase by forskolin prolongs calcium action potential duration in lamprey sensory neurons.

Calcium-dependent action potentials of primary sensory neurons in the isolated spinal cord of the lamprey were greatly prolonged in duration by forskolin, an activator of adenylate cyclase in other systems. This effect was dose-dependent over the tested range of 25-400 microM with an EC50 of 55 microM. Experiments were performed to establish a role for adenylate cyclase and adenosine 3',5'-cyclic monophosphate (cAMP) as mediators of the forskolin effect. The prolonging action of forskolin on the Ca action potential was significantly reduced in the presence of the adenylate cyclase inhibitor 2',5'-dideoxyadenosine. The inactive forskolin analogue 1,9-dideoxyforskolin did not prolong the duration of the Ca action potential, while forskolin treatment of the same cells produced a large and rapid increase in action potential duration. In addition, the prolonging action of forskolin was potentiated by the phosphodiesterase inhibitor, theophylline. It is concluded that forskolin acts in lamprey sensory neurons to activate adenylate cyclase and raise intracellular cAMP levels which in turn mediate the increase in Ca action potential duration.

Accessibility of colloidal gold and horseradish peroxidase to cytosolic spaces in Limulus ventral photoreceptors.

Physiological studies of intracellular messengers frequently employ intracellular injections of large molecules that either monitor or modulate the metabolism of the messenger cascade. Injected molecules have unknown mobility in the cytosol and unknown accessibility to various cytosolic compartments, including those postuiated to be traversed by intracellular messenger molecules. In order to determine whether injected molecules have access to the confined spaces through which messenger molecules must diffuse, we injected 5-nm colloidal gold or horseradish peroxidase, or both, into Limulus ventral photoreceptors. Injections were made by applying pressure pulses to the back of an intracellular micropipette that also monitored membrane voltage. The tissue was fixed at varying times after injection and processed for electron microscopy by conventional techniques. Cells fixed 1-3 min after injection contained HRP reaction product only in the cell body. HRP reaction product was found at varying distances down axons in direct relation to the interval between injection and fixation. Colloidal gold particles were found throughout the cell body but not in axons of tissue fixed 1-3 min after injection. Both HRP reaction product and 5-nm colloidal gold particles were observed within the microvillar projections of internal and external rhabdomere, as well as within the extracisternal spaces of endoplasmic reticulum. We conclude that large molecules injected from an intracellular micropipette into an arbitary locus of ventral photoreceptor cells have access to all of the presumed sites of the phototranduction cascade.

Retrograde effects of target atrophy on submandibular ganglion neurons.

1. To study the retrograde effects of changes in target tissue upon the innervating nerve supply, we have examined the parasympathetic submandibular ganglion of the adult rat. Neurons of this ganglion innervate the submandibular and sublingual salivary glands. 2. Ligating the salivary ducts leads to rapid and prolonged salivary gland cell atrophy. 3. Duct ligations, without direct injury to the glandular nerve supply, initially produced few alterations in the ganglion. After 8 wk, however, neuron number was reduced by 50%. The numbers of presynaptic inputs/neuron and synapses/neuron perimeter were not affected by the cell loss. 4. After 1 wk of duct ligation in which the glandular nerve supply was intentionally damaged, some ganglionic neurons have lost all presynaptic inputs, suggesting synaptic disjunction. This is followed at 3 wk by a 40% decrease in neuron number and an increase in the number of inputs per (remaining) ganglion cell. However, the number of synapses/neuronal profile was unchanged. 5. Thus axotomy plus target atrophy causes synaptic disjunction, neuron cell death, and input rearrangement, presumably due to a combination of direct injury effects and an abrupt loss of peripheral trophic supplies. 6. In contrast, target atrophy alone produced more gradual changes in submandibular ganglion neurons. Only prolonged target atrophy leads to a decrease in the number of ganglionic neurons, perhaps due to the gradual loss of peripheral trophic supplies. However, other features, such as the number of inputs/cell and the number of synapses/neuron perimeter, remain unaltered. Evidently, the gradual loss of trophic support does not result in synaptic disjunction to the degree needed to produce presynaptic input rearrangement.

Neonatal synapse elimination in the rat submandibular ganglion: effect of retarded target growth.

1. We have studied synapse elimination in the submandibular ganglion of neonatal rats to determine the effects of retarded target growth on synaptic development. Neurons of this ganglion provide parasympathetic innervation to the submandibular and sublingual salivary glands. 2. Ligating the main salivary ducts 2-4 days after birth at a point where nerve fibers were not damaged reduces gland weight by 55% during the 2nd wk after birth and 80% by adulthood. 3. In control animals, the average number of preganglionic inputs/neuron normally declines steadily during the first few weeks after birth, before stabilizing during the 5th wk at the control adult level. Between birth and adulthood, the number of ganglionic neurons increases by 150%. 4. Ganglia from duct-ligated animals showed an acceleration in the process of synapse elimination. Input number in experimental ganglia reached the control adult level during the 3rd wk after birth. This acceleration is confined solely to ganglia that innervate the underdeveloped glands. 5. The loss of inputs was not further enhanced by prolonged target atrophy. Thus average input numbers to neurons of 5th wk or adult experimental ganglia were not different from age-matched control values. 6. No differences from control values were seen in most cases for resting potentials, input resistances, or cell size. However, the increase in neuron number was retarded in experimental animals, and the number of synapses/neuronal profile was reduced in the adult animals. 7. Thus subnormal target growth leads to an acceleration in the process of synaptic elimination in neonatal rats. This acceleration may be mediated by alterations in the level of trophic factors emanating from the target.

The clustering of acetylcholine receptors and formation of neuromuscular junctions in regenerating mammalian muscle grafts.

The present investigation was undertaken to study the relationship between acetylcholine receptor (AchR) clustering and endplate formation within regenerating skeletal muscle grafts. Silver staining of nerves was combined with rhodamine-alpha-bungarotoxin labeling of AchR clusters in heterotopic grafts of the rat soleus muscle. Two major graft procedures were used: whole muscle grafts and grafts which lacked the zone of original motor endplates (MEP-less grafts). These categories were subdivided into standard grafts, where subsequent innervation was allowed, and noninnervated grafts, which were experimentally deprived of innervation. Grafting brought about the death and removal of muscle fibers, followed by regeneration of myotubes within surviving basal lamina sheaths. A transient population of small extra-junctional AchR clusters spontaneously appears shortly after myotube formation in all four muscle graft types. Early myotubes of whole muscle grafts (both innervated and standard grafts, prior to the time of innervation) also develop presumptive secondary synaptic clefts and large, organized aggregations of AchRs at original synaptic sites. At later times, nerves regenerating into standard whole muscle and MEP-less grafts lead to the formation of numerous ectopic endplates. In whole muscle grafts, endplates may also form at original synaptic sites. Functional graft innervation is achieved in whole muscle and MEP-less grafts as early as 20 days postgrafting. The results of this study support the existence of still-unknown factors associated with the original synaptic site which can direct postsynaptic differentiation independent of innervation. They also demonstrate that functional endplates may form in mammalian muscle grafts at both original synaptic sites and ectopic locations, thus indicating that the zone of original synaptic sites is not necessary for the establishment of numerous functional and morphologically well-differentiated endplates.

Increased phenylalanine incorporation in regenerating skeletal muscle grafts.

Skeletal muscle regenerates following grafting, but little is known about protein synthesis and its regulation during regeneration. We determined the sequence of changes in protein synthesis in rat extensor digitorum longus (EDL) muscle by the measurement of phenylalanine (Phe) incorporation into muscle protein at various times after grafting. Compared with control EDL, Phe incorporation in grafts doubled in 1 day, was four- to eight-fold greater from days 2 to 10 after grafting, and then subsided. Tissue mass (wet weight) increased rapidly from days 7 to 20 in EDL grafts. The maximal increase in protein synthesis occurred 7-10 days after grafting, whether or not the nerve was left intact. Autoradiography indicated that incorporated radioactivity was associated with regenerating muscle fibers on day 10. Deficiencies of insulin, pituitary or testicular hormones, or chronic in vivo administration of insulin, growth hormone, testosterone, or tri-iodothyronine did not substantially alter the elevation in incorporation of the Phe into muscle protein 10 days after grafting. The breakdown of EDL protein, measured in vitro simultaneously with protein synthesis, was increased five-fold, and overall protein degradation was elevated six-fold 10 days after grafting. These findings indicate that Phe incorporation is rapidly elevated following grafting of the EDL, and that by days 7-10 reflects synthesis in regenerating muscle fibers. The increase in protein synthesis associated with muscle regeneration at this time appears to be independent of innervation and anabolic hormones.

Developmental fate of a distinct class of chick myoblasts after transplantation of cloned cells into quail embryos.

A technique appropriate to investigation of the developmental fates of distinct embryonic cell types is described and the fate of a particular type of chick myoblast (CMR-I) examined. CMR-I myoblast clones are morphologically different from other chick myoblast clone types and can readily be identified in living cultures. After two weeks of culture CMR-I myoblast clones were collected, aggregated, and transplanted into the prospective dorsal thigh region of young quail embryos. After four days of growth, cells of the transplant-containing quail legs were grown as clones. Chick clones were located by Feulgen staining and identified as muscle or non-muscle and, if muscle, as CMR-I or not; 91% of the chick clones recovered from transplants were muscle clones, and of these 97% were CMR-I. It was concluded that CMR-I myoblasts do not undergo a change in differentiated state identifiable by clonal analysis. Other transplant-containing quail legs were fixed, sectioned, and Feulgen stained. The locations of chick nuclei were determined. The only region in which chick nuclei appeared at significantly greater frequency than in control tissue was the dorsal thigh muscle, the region into which the cloned chick cells were placed originally. Dorsal thigh multinucleated myotubes exhibited the highest percentage of chick nuclei of all tissues examined. It was concluded that the fate of CMR-I myoblasts is fusion to form myotubes.