Maturation of cultured embryonic CNS tissues during chronic exposure to agents which prevent bioelectric activity

Engineering circuits of human iPSC-derived neurons and rat primary glia

Novel in vitro platforms based on human neurons are needed to improve early drug testing and address the stalling drug discovery in neurological disorders. Topologically controlled circuits of human induced pluripotent stem cell (iPSC)-derived neurons have the potential to become such a testing system. In this work, we build in vitro co-cultured circuits of human iPSC-derived neurons and rat primary glial cells using microfabricated polydimethylsiloxane (PDMS) structures on microelectrode arrays (MEAs). Our PDMS microstructures are designed in the shape of a stomach, which guides axons in one direction and thereby facilitates the unidirectional flow of information. Such circuits are created by seeding either dissociated cells or pre-aggregated spheroids at different neuron-to-glia ratios. Furthermore, an antifouling coating is developed to prevent axonal overgrowth in undesired locations of the microstructure. We assess the electrophysiological properties of different types of circuits over more than 50 days, including their stimulation-induced neural activity. Finally, we demonstrate the inhibitory effect of magnesium chloride on the electrical activity of our iPSC circuits as a proof-of-concept for screening of neuroactive compounds.

Activity-Dependent Inhibitory Synaptogenesis in Cerebellar Cultures

Inhibitory synapses on Purkinje cell somata in organotypic cerebellar cultures derived from newborn mice were increased after chronic exposure post explantation to agents that enhance neuronal activity. Inhibitory synaptogenesis was reduced in similar cultures after continuous blockade of spontaneous neuronal discharges. By contrast, excitatory synapses developed fully in the absence of neuronal activity. The reduction of inhibitory synaptogenesis was prevented by the simultaneous application of activity blocking agents and neurotrophins BDNF or NT-4, which are TrkB receptor ligands, but not with NT-3, a TrkC receptor ligand. The effect of endogenous neurotrophins was evaluated by continuously exposing cerebellar cultures to antibodies to BDNF and NT-4, which caused a significant reduction in the development of inhibitory Purkinje cell axosomatic synapses. These combined results indicated a role for TrkB receptors in activity-dependent inhibitory synaptogenesis. This concept was supported by the promotion of inhibitory synaptogenesis by specific antibody activation of TrkB receptors.

The changeable nervous system: studies on neuroplasticity in cerebellar cultures

Circuit reorganization after injury was studied in a cerebellar culture model. When cerebellar cultures derived from newborn mice were exposed at explantation to a preparation of cytosine arabinoside that destroyed granule cells and oligodendrocytes and compromised astrocytes, Purkinje cells surviving in greater than usual numbers were unensheathed by astrocytic processes and received twice the control number of inhibitory axosomatic synapses. Purkinje cell axon collaterals sprouted and many of their terminals formed heterotypical synapses with other Purkinje cell dendritic spines. The resulting circuit reorganization preserved inhibition in the cerebellar cortex. Following this reorganization, replacement of the missing granule cells and glia was followed by a restitution of the normal circuitry. Most of these developmental and reconstructive changes were not dependent on neuronal activity, the major exception being inhibitory synaptogenesis. The full complement of inhibitory synapses did not develop in the absence of neuronal activity, which could be mitigated by application of exogenous TrkB receptor ligands. Inhibitory synaptogenesis could also be promoted by activity-induced release of endogenous TrkB receptor ligands or by antibody activation of the TrkB receptor.

From neural plate to cortical arousal-a neuronal network theory of sleep derived from in vitro "model" systems for primordial patterns of spontaneous bioelectric activity in the vertebrate central nervous system

In the early 1960s intrinsically generated widespread neuronal discharges were discovered to be the basis for the earliest motor behavior throughout the animal kingdom. The pattern generating system is in fact programmed into the developing nervous system, in a regionally specific manner, already at the early neural plate stage. Such rhythmically modulated phasic bursts were next discovered to be a general feature of developing neural networks and, largely on the basis of experimental interventions in cultured neural tissues, to contribute significantly to their morpho-physiological maturation. In particular, the level of spontaneous synchronized bursting is homeostatically regulated, and has the effect of constraining the development of excessive network excitability. After birth or hatching, this "slow-wave" activity pattern becomes sporadically suppressed in favor of sensory oriented "waking" behaviors better adapted to dealing with environmental contingencies. It nevertheless reappears periodically as "sleep" at several species-specific points in the diurnal/nocturnal cycle. Although this "default" behavior pattern evolves with development, its essential features are preserved throughout the life cycle, and are based upon a few simple mechanisms which can be both experimentally demonstrated and simulated by computer modeling. In contrast, a late onto- and phylogenetic aspect of sleep, viz., the intermittent "paradoxical" activation of the forebrain so as to mimic waking activity, is much less well understood as regards its contribution to brain development. Some recent findings dealing with this question by means of cholinergically induced "aroused" firing patterns in developing neocortical cell cultures, followed by quantitative electrophysiological assays of immediate and longterm sequelae, will be discussed in connection with their putative implications for sleep ontogeny.

An electron microscopic study of the development of synapses in cultured fetal mouse cerebrum continuously exposed to xylocaine

Explants of fetal mouse cerebral cortex, continuously exposed to the local anesthetic Xylocaine from the time of explantation to the time of fixation, were examined in the electron microscope to determine whether morphologically normal synapses and potentially functional interneuronal synaptic networks can form in the absence of electrical impulse activity. Morphological differentiation of complex synaptic networks proceeds normally, and the drug does not alter the fine structure of the formed synapses. These observations are consonant with the electrophysiological data which show that the potential for complex bioelectric activity can develop in the absence of its expression. The development and maturation of functional synaptic networks, then, is not contingent upon prior electrical impulse activity. These data support the concept that organized neuronal assemblies are formed in forward reference to their ultimate function.

Chronic Suppression of Bioelectric Activity and Cell Survival in Primary Cultures of Rat Cerebral Cortex: Biochemical Observations

Chronic suppression of spontaneously occurring bioelectric activity (BEA) has been shown to increase neuronal cell death in tissue culture, but may also affect astrocytes. We investigated this process in primary cultures of rat cerebral cortex by measuring the levels of NSE (neuron-specific enolase) and GFAP (glial fibrillary acidic protein) in relation to general tissue markers, including measurements for cell death and proliferation. In electrically active (control) cultures, the content of DNA, protein, and NSE became maximal between 21 and 28 days in vitro (DIV) and thereafter decreased, whereas the content of GFAP rose continuously up to 43 DIV. Chronic suppression of BEA by tetrodotoxin (TTX; from 6 DIV) decreased the content of DNA, total protein, and especially NSE. The content of GFAP was decreased in all culture series investigated, but with great temporal variations among culture series. Chronic TTX treatment (started at 6 DIV) increased the efflux of lactate dehydrogenase, a marker for cell lysis, between 12 and 21 DIV, but this efflux was mainly derived from the supporting glial cells with which the cerebral cortex cultures were cocultured. Chronic, but not acute (7 h) TTX treatment decreased total [3H]thymidine incorporation into DNA from 14 DIV; this appeared to be due to a reduced number of astrocytes. Chronic suppression of BEA with xylocaine from 6 DIV had similar effects on DNA-, protein-, and NSE-content as TTX, but led to an increased content of GFAP at 21 DIV. Chronic suppression of synaptic transmission with 10 mM Mg2+ and 0.2 mM Ca2+, starting at 6 DIV, increased the content of DNA, protein, and GFAP at 21 DIV, but NSE was still decreased. We conclude that chronic suppression of BEA in cerebral cortex cultures enhances neuronal cell death, whereas astrocytes are differentially affected, depending on the suppressing agent. As astrocytes may have a modulating effect on neuronal survival, their involvement should be regarded when studying the effects of chronic suppression of BEA on neuronal development.

Physiological effects of sustained blockade of excitatory synaptic transmission on spontaneously active developing neuronal networks--an inquiry into the reciprocal linkage between intrinsic biorhythms and neuroplasticity in early ontogeny

Spontaneous bioelectric activity (SBA) taking the form of extracellularly recorded spike trains (SBA) has been quantitatively analyzed in organotypic neonatal rat visual cortex explants at different ages in vitro, and the effects investigated of both short- and long-term pharmacological suppression of glutamatergic synaptic transmission. In the presence of APV, a selective NMDA receptor blocker, 1-2- (but not 3-)week-old cultures recovered their previous SBA levels in a matter of hours, although in imitation of the acute effect of the GABAergic inhibitor picrotoxin (PTX), bursts of action potentials were abnormally short and intense. Cultures treated either overnight or chronically for 1-3 weeks with APV, the AMPA/kainate receptor blocker DNQX, or a combination of the two were found to display very different abnormalities in their firing patterns. NMDA receptor blockade for 3 weeks produced the most severe deviations from control SBA, consisting of greatly prolonged and intensified burst firing with a strong tendency to be broken up into trains of shorter spike clusters. This pattern was most closely approximated by acute GABAergic disinhibition in cultures of the same age, but this latter treatment also differed in several respects from the chronic-APV effect. In 2-week-old explants, in contrast, it was the APV+DNQX treated group which showed the most exaggerated spike bursts. Functional maturation of neocortical networks, therefore, may specifically require NMDA receptor activation (not merely a high level of neuronal firing) which initially is driven by endogenous rather than afferent evoked bioelectric activity. Putative cellular mechanisms are discussed in the context of a thorough review of the extensive but scattered literature relating activity-dependent brain development to spontaneous neuronal firing patterns.

Activity-dependent development of spontaneous bioelectric activity in organotypic cultures of rat occipital cortex

The development of spontaneous bioelectric activity (SBA) in organotypic tissue cultures (OTCs) from rat occipital cortex was studied by means of extracellular recording techniques in OTCs grown normally for 6-51 days in vitro (DIV), and in OTCs in which SBA had been silenced from DIV 4 on for 2 to 3 weeks by elevating the Mg(2+) levels in the growth medium. The proportions of spontaneously active neurones increased from about 25% at 6-14 DIV to more than 80% beyond the third week in vitro. Mature neurones discharged at shorter intervals and more vigorously than immature neurones; the developmental increase in firing rate was not significant, however. In OTCs 6-14 DIV the majority of spontaneously active neurones fired sluggishly in a regular manner. The remaining neurones fired action potentials in the form of discrete bursts resembling interictal activity in vivo. The proportions of these neurones increased from about 40% at 6-14 DIV to more than 80% beyond the third week in vitro. During development in vitro the mean burst duration increased from 3.5 s to about 8 s whereas the mean burst rate (between 0.7-1 bursts/min) remained constant. Activity-deprived neurons had low firing rates and fired action potentials in the form of discrete bursts with a mean burst rate of 0.4/min. The proportions of spontaneously active neurons, the variability of neuronal firing and the viability of the explants either were not altered by the activity blockade or had recovered to control values after 5-6 days in normal growth medium. We conclude that in OTCs of rat neocortex the absence of SBA during development in vitro delays the maturation of excitatory mechanisms responsible for the developmental increase in firing intensity. The development of burst firing modes is less affected by activity blockade.

Development of specific synaptic network functions in organotypic central nervous system (CNS) cultures: implications for transplantation of CNS neural cells in vivo

This article provides a broad overview of the significant roles that morphophysiologic analyses of organotypic cultures of neural tissues explanted in vitro-initiated during the 1950s-have played in stimulating the more recent development of techniques for transplantation of neural cells and tissues into specific regions of the central nervous system (CNS) in vivo. The demonstrations by Crain and co-workers in the 1950s and 1960s that fetal rodent and human CNS neurons can continue to develop a remarkable degree of mature structure and function during many months of complete isolation in culture provided crucial evidence that development of many organotypic properties of nerve cells is regulated by epigenetic factors that ensure rather stereotyped expression despite wide variations in environmental conditions. These in vitro studies strongly suggested that fetal neural cells should, indeed, be capable of even more highly organotypic development after transplantation in vivo, as has been elegantly demonstrated by many of the successful CNS transplantation studies reviewed here.

Control of myelination, axonal growth, and synapse formation in spinal cord explants by ion channels and electrical activity

The involvement of axonal electrical activity and ion channels as mediators of neuron-glial communication during myelin formation has been tested in explant culture. Transverse slices of embryonic mouse spinal cord were maintained under conditions normally leading to extensive myelination. Axonal conduction was measured optically through the use of a voltage-sensitive dye. Glial development was at a very early stage at the time of plating, and oligodendrocyte precursor cells had not yet appeared. Spontaneous electrical activity was blocked either by tetrodotoxin or by elevation of external K+ concentrations. Myelin development was unaffected by tetrodotoxin and was also present, though quantitatively reduced, in elevated K+. Tetraethylammonium ion (TEA+), a blocker of many K+ channels, almost entirely eliminated myelination at a concentration of 1 mM, but axonal growth and conduction were unaffected. Synapse formation was followed both morphologically and functionally, and was altered neither by conduction block nor by 1 mM TEA+. It is concluded that in the spinal cord oligodendrocyte development and myelination can proceed in the absence of axonal action potentials, but ion channels, possibly in glial membranes, play an important role in these events.

Reduced cortical inhibitory synaptogenesis in organotypic cerebellar cultures developing in the absence of neuronal activity

Organotypic cerebellar cultures derived from newborn mice were continuously exposed to medium containing tetrodotoxin and elevated levels of magnesium to block all electrical activity. After 2 weeks in vitro, no activity was evident during the first 15-20 minutes following transfer to a recording medium without blocking agents. Thereafter, cortical discharge rates increased until a state of sustained hyperactivity was reached. Ultrastructural examination of such cultures revealed a reduction of inhibitory Purkinje cell somatic synapses to half the control value along with an even greater reduction of axodendritic synapses (largely inhibitory) in the cortical neuropil. No loss of axospinous synapses (excitatory) was evident. These results support the concept that spontaneous neuronal activity is necessary for the full development of inhibitory circuitry.

Spontaneous firing as an epigenetic factor in brain development--physiological consequences of chronic tetrodotoxin and picrotoxin exposure on cultured rat neocortex neurons

Functional consequences of either suppressing or intensifying spontaneous neuronal firing have been studied in developing rat cerebral cortex cultures using, respectively, tetrodotoxin (TTX) and picrotoxin (PTX) added chronically to the growth medium. Simple measures derived from the interspike interval histogram were able to powerfully discriminate between age and treatment groups. After return to control medium, most TTX-treated neurons spontaneously displayed stereotyped clustering of action potentials ('phasic' firing) which closely resembled the characteristic firing patterns seen acutely in the presence of PTX. The 'TTX-syndrome' thus suggests that GABAergic synaptic inhibition is ineffective in cortical networks grown under conditions which prevent the expression of bioelectric activity. In contrast, after return to control medium, neurons which had been partially disinhibited throughout development (by continuous exposure to PTX) had even less phasic firing than was measured in age-matched controls. Based upon these and previous findings, a two (main) factor model is put forth which can economically account for the major effects. The working hypothesis embodied in this model is that phasic neuronal discharges not only accelerate the maturation of excitatory connections within the neocortex but, even more important, are crucial for the development of adequate inhibitory synaptic transmission.

Chronic blockade of bioelectric activity in neonatal rat neocortex in vitro: physiological effects

We have examined what effect the loss of spontaneous bioelectric activity has on neural network formation in organotypic rat neocortical explants grown under serum-free culture conditions. Explants were taken from dorsal midline (presumptive visual) and lateral (presumptive auditory) occipital cortex and chronically exposed to tetrodotoxin which blocked all measurable bioelectric activity between change of medium. Extracellular recordings revealed complex, rhythmic spontaneous and evoked multiunit discharges in all explants examined (following tetrodotoxin washout in the experimental group). Control auditory explants had significantly more sites from which electric activity could be recorded compared with control visual explants. Auditory cultures showed no effect of the tetrodotoxin treatment, whereas visual explants showed significant increases over control values, equalling the auditory values. This increased level of spontaneous bioelectric activity was maintained for at least 10 days following transfer of the cultures to control growth medium. There was no significant difference between control visual and auditory explants regarding the number of sites from which evoked activity was seen. Nor did either cortex group show an effect of tetrodotoxin on the number of sites from which evoked activity was seen. The frequency with which spontaneous bioelectric discharges occurred per site increased with age in auditory vs visual cortex. These differences, however, were abolished in the tetrodotoxin-treated groups. It was concluded that neocortical explants which have experienced chronic suppression of spontaneous electric activity did not suffer deficits in neural network formation, though there is an effect on the incidence and frequency with which such activity is given.

Effect of chronic exposure to high magnesium on neuron survival in long-term neocortical explants of neonatal rats in vitro

In order to assess the effect of elevated magnesium, neuronal morphology and physiology was studied in chronically cultured organotypic neonatal rat occipital neocortex. Explants grown in 10 mM magnesium were found to experience an approximate 30% cell loss (as shown by cell count and DNA-protein analysis), while 12.5 and 15 mM magnesium showed ca. 47 and 60% cell losses, respectively. Intracellular recording from 10 mM magnesium explants revealed that measurable postsynaptic potentials and action potentials could occur, apparently depending on the type of cell examined. All post-synaptic activities ceased in 12.5 mM magnesium cultures, though action potentials could be elicited by current stimulation. The effects of known depolarizing agents, viz. potassium and N-methyl-D-aspartate, on 12.5 mM magnesium-grown explants were also examined. Explants grown in the presence of 12.5 mM magnesium plus 10 mM potassium showed a dramatic increase in the loss of neurons. The simultaneous addition of 6,7-dinitro-quinoxaline-2,3-dione showed this to be due to an increase in non-N-methyl-D-aspartate mediated cell death in response to glutamate release brought about by the depolarizing effects of the potassium. The addition of 10 microM N-methyl-D-aspartate to 12.5 mM magnesium-grown cultures, on the other hand, improved cell survival to control levels. The mechanism of this reciprocal neuroprotective effect of N-methyl-D-aspartate against magnesium has yet to be elucidated. We conclude that these findings are consistent with regard to the opposing actions of N-methyl-D-aspartate and magnesium on calcium influx and various metabolic processes within the explants.

Chronic blockade of bioelectric activity in neonatal rat cortex grown in vitro: morphological effects

Culture thickness, numerical density of neurons and neuronal survival were studied in timed series of control and tetrodotoxin-silenced neocortical cultures to provide information on the role of bioelectric activity on neuronal development. In control cultures, culture thickness and number of surviving neurons decrease during the first weeks in vitro, but remain constant between 2 and 3 weeks indicating that the cultures are essentially mature. In the 4th week in vitro a further decrease in surviving neurons was observed. In tetrodotoxin-treated cultures the number of surviving neurons decreased significantly between 1 and 2 weeks in vitro, to remain constant thereafter. However, culture thickness significantly increased at 3 and 4 weeks in vitro after an initial drop between 1 and 2 weeks. Compared to age-matched controls at 2 and 3 weeks in vitro, only ca 50% of the neurons survived the loss of bioelectric activity. Similar differences were present between 1 and 2 weeks. Thus, the loss of all measurable bioelectric activity induces neuronal death in neocortical explants, but promotes neuropil formation by the surviving cells.

Eliminating afferent impulse activity does not alter the dendritic branching of the amphibian Mauthner cell

In the developing amphibian, the formation of extra vestibular contacts on the Mauthner cell (M-cell) enhances dendritic branching, while deprivation reduces it (Goodman and Model, 1988a). The mechanism underlying the interaction between afferent fibers and developing dendritic branches is not known; neural activity may be an essential component of the stimulating effect. We examined the role of afferent impulse activity in the regulation of M-cell dendritic branching in the axolotl (Ambystoma mexicanum) embryo. M-cells occur as a pair of large, uniquely identifiable neurons in the axolotl medulla. Synapses from the ipsilateral vestibular nerve (nVIII) are restricted to a highly branched region of the M-cell lateral dendrite. We varied the amount of nVIII innervation and eliminated neural activity. First, unilateral transplantation of a vestibular primordium deprived some M-cells of nVIII innervation and superinnervated others. Second, surgical fusion of axolotls to TTX-harboring California newt (Taricha torosa) embryos paralyzed the Ambystoma twin: voltage-sensitive Na+ channel blockade by TTX eliminated action potential propagation. Reconstruction of M-cells in 18 mm larvae revealed that dendritic growth was influenced by in-growing axons even in the absence of incoming impulses: impulse blockade had no effect on the stimulation of dendritic growth by the afferent fibers.

Role of Ca2+ channels in the ability of membrane depolarization to prevent neuronal death induced by trophic-factor deprivation: evidence that levels of internal Ca2+ determine nerve growth factor dependence of sympathetic ganglion cells

Sympathetic neurons depend on nerve growth factor (NGF) for their survival both in vivo and in vitro; these cells die upon acute deprivation of NGF. We studied the effects of agents that cause membrane depolarization on neuronal survival after NGF deprivation. High-K+ medium (greater than or equal to 33 mM) prevented cell death; the effect of K+ was dose-dependent (EC50 = 21 mM). The protection by high K+ was abolished either by withdrawal of extracellular Ca2+ or by preloading the cells with a Ca2+ chelator. The involvement of Ca2+ flux across membranes in high-K+ saving of NGF-deprived neurons was also supported by experiments using Ca2+-channel antagonists and agonists. The Ca2+ antagonists nimodipine and nifedipine effectively blocked the survival-promoting effect of high K+. The Ca2+ agonists Bay K 8644 and (S)-202-791 did not by themselves save neurons from NGF deprivation but did strongly augment the effect of high K+; EC50 was shifted from 21 mM to 13 mM. These data suggest that dihydropyridine-sensitive L-type Ca2+ channels play a major role in the high-K+ saving. The depolarizing agents choline (EC50 = 1 mM) and carbamoylcholine (EC50 = 1 microM), acting through nicotinic cholinergic receptors, also rescued NGF-deprived neurons. The saving effect of nicotinic agonists was not blocked by withdrawal of extracellular Ca2+ but was counteracted by a chelator of intracellular Ca2+, suggesting the possible involvement of Ca2+ release from internal stores. Based on these findings we propose a "Ca2+ set-point hypothesis" for the degree of trophic-factor dependence of sympathetic neurons in vitro.

Gangliosides of the mouse spinal cord: a comparison in in vivo and in vitro tissues

Ganglioside profiles in spinal cord from 13-day mouse fetuses, 21-day postnatal and adult mice were compared with those harvested from organotypic cross-sections of fetal mouse spinal cord grown for 28 days in vitro in a serum-free medium. All the major species of gangliosides reported for brain were present both in the in vivo tissue and cultured spinal cord, though not necessarily at each developmental stage examined. Fresh tissues showed increases and decreases in various gangliosides as have been reported for higher brain centers at similar stages of development in mammals and birds. However, qualitative and quantitative differences exist between fresh spinal cord and cultured cord explants as well as between galactose-grown and galactose-free cultures. Spinal cord explants grown in the presence of galactose showed measurable amounts of GM2 and GM3 which were not detected in the control-defined medium-grown cultures. The differences between the two culture groups may be related to interneuronal connectivity patterns.

Some functional effects of suppressing bioelectric activity in fetal mouse spinal cord-dorsal root ganglion explants

Organotypic explants of fetal mouse spinal cord-dorsal root ganglia were grown for 3 weeks in the presence of 10 mM magnesium ion, which effectively eliminated all recordable bioelectric activity throughout the culturing period. When tested in minimal essential medium, the chronically silenced explants had significantly fewer points from which spontaneous neuronal activity could be recorded. In addition, fewer points could be found that showed dorsal root ganglion-evoked responses, resulting from a greater tendency for the spinal cord activity to be restricted to the vicinity of the dorsally entering DRG fibers. These findings, therefore, support the hypothesis that spontaneous bioelectric activity is required for functional as well as structural maturation of neural networks.

Eye-specific segregation of optic afferents in mammals, fish, and frogs: the role of activity

Eye-specific patches or stripes normally develop in the visual cortex and superior colliculus of many (but not all) mammals and are also formed, after surgically produced binocular innervation, in the optic tectum of fish and frogs. The segregation of ocular dominance patches or columns has been studied using a variety of anatomical pathway-tracing techniques, by electrophysiological recording of postsynaptic units or field potentials, and by the 2-deoxyglucose method following visual stimulation of only one eye. In the tectum of both fish and frogs and in the cortex and colliculus of mammals, eye-specific patches develop from initially diffuse, overlapping projections. Of the various mechanisms that might cause such segregation, the evidence favors an activity-dependent process that stabilizes synapses from the same eye because of their correlated activity. First, several environmental manipulations affect the segregation of afferents in visual cortex: strabismus and alternate monocular exposure apparently enhance segregation, whereas dark rearing slows the segregation process, and monocular deprivation causes the experienced eye to form larger patches at the expense of those of the deprived eye. Second, blocking activity in both eyes is effective in preventing the segregation both in the tectum of fish and frog and in the visual cortex of cat. With the eyes blocked, alternate stimulation of the optic nerves permits the segregation of ocular dominance, at least onto single cells in the cat visual cortex. These findings are discussed in terms of an activity-dependent stabilization of those synapses having correlated activity (those from neighboring ganglion cells within one eye) but not of those lacking correlated activity (those from left and right eyes). We suggest that the eye-specific patches represent a compromise between total segregation of the projections from the two eyes and the formation of a single continuous retinotopic map across the surface of the cortex or tectum.

Horseradish peroxidase tracing of dorsal root ganglion afferents within fetal mouse spinal cord explants chronically exposed to tetrodotoxin

Afferent projection patterns within organotypic explants of fetal mouse spinal cord-dorsal root ganglia (DRG) were mapped out histologically using an HRP-staining method. The role of spontaneous bioelectric activity in the development of cord-DRG connections was studied using tetrodotoxin (TTX) to eliminate action potential discharges in the experimental cultures. Cultures grown in TTX-supplemented medium had a significantly lower proportion of DRG afferents within the dorsal half of the cord explant than did untreated cultures. In addition, afferent fiber entrances were made predominantly on the dorsolateral aspect in control cord explants, in contrast with the more diffuse entrance pattern displayed by the experimental group. Comparison of those cultures in both groups where the fiber entrances were chiefly dorsal revealed a greater tendency in the TTX group for DRG afferents to grow ventrally after penetrating the cord. Thus, it appears that bioelectric activity of the target neurons may be required by DRG afferents for the development of selective innervation patterns.

Synaptogenesis in rat cerebral cortex cultures is affected during chronic blockade of spontaneous bioelectric activity by tetrodotoxin

Reaggregated occipital cortex cells of 19-day-old fetal rats were grown in a serum-free, chemically defined medium, and chronically exposed to impulse-blocking levels of tetrodotoxin (TTX) in order to study the role of bioelectric activity in synaptogenesis. As judged by phase-contrast microscopy, no differences were noticed in the development of neuronal networks in the TTX-treated vs control cultures. In addition, when TTX was withdrawn from experimental cultures at any stage of development, bioelectric activity qualitatively comparable to that of the control cultures appeared within 1 min. However, quantitative stereological EM analysis revealed a significant retardation in synapse formation and ultrastructural maturation of synaptic junctions during the first 3 weeks. Around 23 days in vitro, the central zone of the reaggregates in control cultures started to degenerate, but not earlier then day 27 in TTX-treated cultures. During this time, the control, but not the experimental cultures showed (in intact tissue regions mainly situated at the outside of the aggregates) a large and selective loss of spine synapses. It is concluded that functional blockade not only retards the early growth and maturation of synaptic networks but also prevents the later occurring selective loss of spine synapses.

Interaction between trophic action and electrical activity in spinal cord cultures

The effect of conditioned medium (CM) on tetrodotoxin (TTX)-mediated neuronal cell death was investigated in dissociated spinal cord-dorsal root ganglion (SC-DRG) cultures. Nutrient medium was collected from donor SC-DRG cultures at 3--4-day intervals throughout development. The presence of survival-promoting neurotrophic material (NTM) in the conditioned medium was tested on TTX-treated cultures which were within the critical period of vulnerability to electrical blockade (days 7-21 in culture). Cultures were assayed by neuronal cell counts, choline acetyltransferase (ChAT) activity or fixation of [125I]tetanus toxin, a neuronal surface marker. Evidence of NTM was found in CM collected prior to day 8 and after day 21 in culture. Increasing the percentage of CM in fresh nutrient medium resulted in a dose-dependent increase in [125I]tetanus toxin fixation and ChAT activity in TTX-treated cultures. In addition, CM plus TTX treatment produced a 25% increase in neuronal cell counts as compared to controls. TTX treatment alone resulted in 20-25% decrease in neuronal number from that of control cultures. Cultures treated with CM alone had neuronal counts that were similar to controls. When electrical activity was blocked with TTX, NTM was not detectable in CM collected from donor cells during days 1-5. CM obtained from control cultures during the same interval had NTM activity. The existence of the critical period for electrical blockade-associated neuron death is associated with a decrease in the availability of NTM. Furthermore, the release of NTM from donor cells and the survival response of target neurons to NTM are apparently dependent on ongoing electrical activity.

Isolation and cultivation of mature oligodendroglial cells

CNS axons are ensheathed by myelin which is produced and maintained by oligodendrocytes. A disorder of this assembly results in functional disturbances, e.g., paralysis in multiple sclerosis. Methods are now available to isolate and cultivate oligodendrocytes in vitro. Thus, basic oligodendroglial properties can be now investigated: signals for oligodendroglial gene expression and their role in myelinogenesis and the interaction between oligodendrocytes and other neural cells by, e.g., the release of informational substances.

Developmental and neurochemical specificity of neuronal deficits produced by electrical impulse blockade in dissociated spinal cord cultures

Blockade of spontaneous electrical activity in dissociated fetal spinal cord cultures produced neuronal deficits as measured by biochemical and morphological techniques. Spinal cord cultures exhibited an age-dependent vulnerability to impulse blockade with tetrodotoxin (TTX) or xylocaine. Neuronal cell counts, [125I]tetanus toxin fixation and [125I]scorpion toxin binding indicated that TTX application produced neuronal deficits during the second or third week in culture. Application of TTX during the first or fourth week did not produce a difference in tetanus toxin fixation from controls. Radioautography of [125I]tetanus toxin revealed no obvious change in the label distribution after TTX treatment. Suppression of electrical activity during the first 6 days in culture had no effect on choline acetyltransferase (CAT) activity and no apparent effect on the appearance of the cultures. Application of TTX during the seventh day in culture decreased CAT activity to 68% of control. Chronic electrical blockade produced a progressively greater loss of CAT activity through 21 days in culture. GABAergic neurons, as indicated by high-affinity GABA uptake, glutamic acid decarboxylase activity and [3H]GABA radioautography, were not affected by electrical blockade. These data indicate that there is developmental and neurochemical specificity in the neuronal death produced by blocking spontaneous electrical activity in dissociated spinal cord cultures.

The re-establishment of synaptic transmission by regenerating optic axons in goldfish: time course and effects of blocking activity by intraocular injection of tetrodotoxin

Intraocular injections of tetrodotoxin were used to block activity for 27 days in normal fish and for the first 27 or 31 days of regeneration in fish with one optic nerve crushed. Synaptic activity was then assessed by a current source-density analysis of field potentials evoked by optic nerve shock at different times following the TTX treatment. In normal fish, the lack of activity for 4 weeks had no significant effect on the maintenance of synaptic strength. Likewise, in fish with nerve crush, lack of activity did not prevent the regenerating optic fibers from forming synapses that were nearly as effective as those formed in controls injected with the citrate buffer vehicle. The earliest synapses were formed at the rostromedial corner of the tectum (where the tract enters) at 20 days after nerve crush, when fibers had not yet reached the caudal areas. By 28 days synaptic potentials could be recorded everywhere on the surface of the tectum in both controls and TTX injected fish. However, the latency of the responses with TTX were longer, suggesting a smaller caliber of fiber, which is consistent with an earlier finding of decreased axonal transport in TTX fish. Maturation of the regenerating fibers proceeded slowly in both TTX and control fish. After more than 5 months, the projections were nearly normal but still not completely normal.

Intraocular tetrodotoxin in goldfish hinders optic nerve regeneration

Repeated intraocular injection of tetrodotoxin (TTX) was used to produce a maintained block of neural activity in goldfish optic axons which were regenerating following a crush of the optic nerve. The recovery of visual function was delayed in the TTX-treated fish, as demonstrated by delays in the return of the startle reaction to sudden illumination, the dorsal light reflex and food pellet localization. A single injection of TTX at the time of optic nerve crush delayed recovery of the startle reaction but not of food localization. There was no loss of ganglion cells in the TTX-treated animals, but the number of regenerated axons detectable by light microscopy was reduced. Also, axonal transport of radioactively labeled protein in some of the regenerating axons showed a deficit at 21-28 days after the lesion, i.e., during innervation of the tectum. Incorporation of labeled amino acid into protein in the retinal ganglion cells was depressed during the same period, but both the transport and incorporation had returned to normal by 36 days after the lesion. These results, together with the results of the accompanying electrophysiological analysis of the effects of TTX58,59, suggest that TTX treatment interferes with two separate events in regeneration, one occurring soon after the nerve lesion and the other during innervation of the tectum. During at least the first of these events the effect of TTX treatment may be to reduce the number of size of the regenerating axon branches. We propose that the TTX effect may be mediated by a reduction in the axonal transport of certain materials, including gangliosides, nucleosides, or proteins specifically involved in regeneration.

Influence of growth medium, age in vitro and spontaneous bioelectric activity on the distribution of sensory ganglion-evoked activity in spinal cord explants

The role of serum added to the culture medium and of spontaneous bioelectric activity in the development of sensory afferent connections was studied, employing fetal mouse spinal cord explants with attached dorsal root ganglia (DRG) as an in vitro model system. Afferent DRG terminals in the cord explants were localized on the basis of 'fixed-latency' DRG-evoked action potentials, which were anatomically verified in several experiments using horseradish peroxidase histology. In serum-supplemented medium (HSSM), but not in chemically defined medium (CDM), those DRG fibers which grew into the dorsal side of the cord terminated predominantly within the dorsal cord region, and remained there throughout the experimental period (18-33 days in vitro). In contrast, ventrally entering fibers terminated equally in both the dorsal and the ventral cord regions in young cultures (18-24 days in vitro) but were no longer observed after 27 days in vitro. Cultures grown in HSSM with the addition of xylocaine, in order to chronically suppress spontaneous bioelectric activity, essentially corresponded (at 25-32 days in vitro) to the picture seen in the control series at the same age. On the basis of polysynaptic DRG-evoked responses in the cord, developmental changes in local neuronal networks were inferred which resulted in less spread of DRG-evoked activity with age in HSSM, and more spread with age in CDM-grown cultures. It is concluded that for the formation of selective DRG connections in the spinal cord: (i) a serum-borne factor plays a role: and (ii) functional activity is not required.

A morphometric study of cultured rat cerebral synapses exposed to different cationic media

Quantitative techniques have been applied to compare the effects of high-K+, Mg2+ and Li+ media on the ultrastructure of cultured synapses alongside Na+-incubated controls. The explant cultures were prepared from 18-day-old embryonic rat cerebral cortices and maintained for 19 days in vitro. K+ -Stimulation for 25 min resulted in an increase in the mean perimeter and area of presynaptic terminals. Of these, the perimeter increase was the more pronounced, as indicated by a decrease in the value of the two-dimensional form factor. Reductions were also observed in the number of synaptic vesicles per presynaptic terminal, in the vesicle-terminal area ratio and in the synaptic vesicle density in an area adjacent to the presynaptic membrane, the latter two parameters being in positive linear correlation. The frequency of presynaptic cisternal/vacuolar profiles increased, and the synaptic curvature shifted in a positive direction. Synaptic length did not change following K+-exposure. Qualitative assessment indicated the presence of a network subjacent to the post-synaptic thickening and swelling of the postsynaptic ending after K+-stimulation. Incubation and fixation in Mg2+-media of two concentrations resulted in an increase in the number and area ratio of synaptic vesicles per terminal, and an elevation in the synaptic vesicle density in the higher Mg2+ concentration medium. Li+-treatment reduced the number of synaptic vesicles per terminal, the vesicle-terminal area ratio, and the vesicle density in the vicinity of the presynaptic membrane, while the synaptic curvature shifted in the positive direction. These changes were less pronounced than those characteristic of synapses in the K+ medium.

Junctions in rat neocortical explants cultured in TTX-, GABA-, and Mg++-environments

The occurrence of various cell-to-cell contacts and membrane specializations was quantitated in neocortical explant cultures prepared from 18-day-old rat embryos and exposed continuously to tetrodotoxin (TTX), gamma-aminobutyric acid (GABA) and an elevated level of magnesium ions (Mg++), respectively. Chronic TTX treatment resulted in a decrease in the number of synapses, paired neuronal membrane thickenings and nerve terminals with synaptic vesicles; the area of the neuronal compartment also decreased. By contrast, the gap junctions between glial cells increased, although the glial paired membrane thickenings decreased in number per unit area. Long-term GABA and Mg++ exposures did not alter significantly the occurrence of any of the cell contacts and membrane specializations analyzed when compared to control values. The results suggest an inhibitory effect of TTX on neuronal maturation and synapse formation in explant cultures of rat neocortex; this may lead secondarily to an increased demand for glial cell-to-cell communication.

A quantitative electron microscopic study on synapse formation in dissociated fetal rat cerebral cortex in vitro

Occipital cortex of 19-day-old fetal rats was dissociated and cultured in vitro for 2-5 weeks in horse serum supplemented Eagle's MEM. The outgrowing neurons rapidly formed a dense network which started to degenerate after 3 weeks in vitro. By means of electron microscopy the numerical development of 6 different categories of synapses was followed during the time in culture. This approach revealed a sigmoid growth curve emerging over the first 3 weeks for the category of axo-dendritic synapses (which comprised the bulk of all synapses counted). Thereafter a decline in number set in. Chronic exposure of these dissociated cerebral cortex cultures to 50 microgram/ml xylocaine (a concentration adequate to block all measurable bioelectrical activity) did not prevent the formation of functional synaptic networks having normal synaptic ultrastructure. These results are in agreement with previous studies on fetal cerebral explants in culture. However, in some groups of our cultures, xylocaine led to a retardation in neurite outgrowth and in numerical synapse formation. Since these xylocaine effects were dose-related at a concentration double that required to silence the cultures, the growth retardation was probably not due to selective suppression of bioelectric activity, but rather to some general cytotoxic effect of the drug. In one of the xylocaine-treated groups (50 microgram/ml) which showed an exceptionally rapid neuronal outgrowth by the use of horse serum obtained from a different source than in the other groups, no deficit was noted in the number of synapses formed. Extracellular recording in this latter drug-treated group of cultures during the third week revealed (after return to control medium) spontaneous isolated action potentials, burst patterns and slow waves which were indistinguishable from the bioelectric activity seen in the control cultures. It is concluded that bioelectric activity in dissociated cortex cultures is not a prerequisite for the formation of apparently normal, functional synaptic networks.

Neuronal maturation in mammalian cell culture is dependent on spontaneous electrical activity

Fetal mouse spinal cord (SC) and dorsal root ganglion (DRG) neurons undergo a process of maturation in cell culture lasting a month or more. We have investigated the role of electrical activity in this maturational process with the use of tetrodotoxin (TTX), the specific blocker of the voltage-sensitive sodium channel responsible for action potential generation. This agent completely eliminates the spikes and related synaptic activity which occur abundantly in untreated cultures. Such blockade of electrical activity in the cultures, when begun early (day 1 or day 8 in vitro), results in a 85-95% reduction in the number of large SC neurons, without affecting DRG neuron numbers. TTX treatment initiated when cultures are mature (day 70) has no significant effect on either DRG or SC neurons. Intermediate effects are obtained when treatment is initiated at day 35 in vitro. The activity of the nerve-specific enzyme choline acetyltransferase, is significantly decreased by early TTX treatment, while DNA and protein content of the cultures (primarily contributed by glial and fibroblastic cells) is not affected.

Sensitivity of several cell systems to acrylamide

Chick spinal ganglia, chick muscle cells combined with mouse spinal cord explants, C1300 neuroblastoma cells, Chinese hamster ovary cells and newborn rat cerebral cells were exposed to various concentrations of acrylamide in culture. Four morphological and 1 electrophysiological parameters were applied in order to score toxic effects. It appeared that the neurite formation of rat cerebral neurons was the most sensitive criterion showing an effect at 10(-7) M acrylamide.

Exercise during development induces an increase in Purkinje cell dendritic tree size

Mice allowed to exercise during the late postnatal period had Purkinje cells with larger dendritic trees and greater numbers of spines than littermates whose physical activity was severly restricted. These changes in Purkinje cells were accompanied by a selective reduction in the thickness of the cerebellar molecular layer. The data provide evidence for cerebellar plasticity during late development and demonstrate that physical activity can modify the development of Purkinje cell dendrites.

Morphogenesis and physiogenesis of the retino-tectal connection in the chicken. II. The retino-tectal synapses

The preceding paper (Eager 1976) was concerned with the development of retinal ganglion cells and the maturation of photoreceptors. Here we discuss the formation of retino-tectal synapses as studied in terms of both morphology and physiology. The early response characteristics of the first and second postsynaptic tectal cells were also studied. The first retino-tectal synapses, sparse in number, were found with the electron microscope on the eleventh day of incubation. Strict criteria for their identification were employed. At the same stage postsynaptic potentials could be recorded for the first time. These potentials could be recognized as postsynaptic by the application of various techniques: combined ortho- and antidromic stimulation, variation of stimulus intensities, surface mapping, field potential profiles, and application of double shocks of varying intervals. From day twelve onward single unit recordings were also possible and confirmed these results. We were able to establish that morphological criteria for recognition of optic nerve synapses are also criteria for when they start to function. Tectal cells first respond with long-lasting repetitive discharges. Only a few days later the response burst has become shorter and is followed by post-excitatory inhibition. When retino-tectal synapses start to function the excitation is not confined to the superficial tectal cells, but reaches deeper neurons which are possibly tectal output cells. The results of this and the preceding paper (Eager 1976) indicate that the development of the retino-tectal connection in the chicken differs from that in the frog in several fundamental respects.

Circulation and turnover of synaptic vesicle membrane in cultured fetal mammalian spinal cord neurons

Intact neurons in cultures of fetal rodent spinal cord explants show stimulation-dependent uptake of horseradish peroxidase (HRP) into many small vesicles and occasional tubules and multivesicular bodies (MVB) at presynaptic terminals. Presynaptic terminals were allowed to take up HRP during 1 h of strychnine-enhanced stimulation of synaptic transmitter release and then "chased" in tracer-free medium either with strychnine or with 10 mM Mg++ which depresses transmitter release. Tracer-containing vesicles are lost from terminals under both chase conditions; the loss is more rapid (4-8 h) with strychnine than with 10 mM Mg++ (8-16 h). There is a parallel decrease in the numbers of labeled MVB's at terminals. Loss of tracer with 10 mM Mg++ does not appear to be due to the membrane rearrangements (exocytosis coupled to endocytosis) that presumably lead to initial tracer uptake; terminals exposed to HRP and Mg++ for up to 16 h show little tracer uptake into vesicles. Nor is the decrease likely to the due to loss of HRP enzyme activity; HRP is very stable in solution. During the chases there is a striking accumulation of HRP in perikarya that is far more extensive in cultures initially exposed to tracer with strychnine than 10 mM Mg++ regardless of chase conditions. Much of the tracer ends up in large dense bodies. These findings suggest that synaptic vesicle membrane turnover involves retrograde axonal transport of membrane to neuronal perikarya for further processing, including lysosomal degradation. The more rapid (4-8 h) loss of tracer-containing vesicles with strychnine may reflect vesicle membrane reutilization for exocytosis.

Anti-synaptic antibody in allergic encephalomyelitis. II. The synapse-blocking effects in tissue culture of demyelinating sera from experimental allergic encephalomyelitis

It has been suggested that demyelination cannot account for all of the observed clinical symptoms of multiple sclerosis (MS), in particular the rapidity of onset and remission of the disease, and attention has been focussed on the role of the synapse in 'demyelinating diseases'. In the present paper we have attempted to resolve the fundamental question of the site of action of a demyelinating disease, experimental allergic encephalomyelitis (EAE), by the use of cultures of neonatal rat cerebellum. Electrophysiological and morphological development in these cultures run hand-in-hand, and in the first few days in vitro there is a 4-5 day period when synapses are both seen ultrastructurally and known to be functioning but before the onset of myelination. The serum from guinea pigs with EAE was added to these cultures at different stages during their development and the morphological and electrophysiological effects observed. An abolitionary effect on the bioelectric activity of the culture was only observed when the serum was added to mature, myelinated cultures. Also the same active sera had no effect on synaptic activity before myelination had occurred. We conclude that the synaptic blocking effect occurs only when myelin is destroyed.