Early experience effects upon cortical dendrites: a proposed model for development

Postnatal development of dendrites of relay neurons in the lateral geniculate nucleus of the marmoset (Callithrix jacchus): a quantitative Golgi study

Dendrites of multipolar relay neurons in the lateral geniculate nucleus of the marmoset (Callithrix jacchus), at various ages from birth to adulthood, were studied in rapid Golgi preparations. The dendrites were analyzed by means of three-dimensional computer reconstructions and decomposed into intermediate and terminal segments, both of which were further classified according to their centrifugal order. Measurements were made of the number of segments per dendrite, the total length of dendrites, and the mean length of intermediate and terminal segments. In adult marmosets, there are four stem dendrites on average per neuron, and each dendrite divides into a mean of 14 segments. Between birth and 6 weeks of age, the mean dendritic length doubles, mainly because of changes in terminal segments. There is a significant decrease in dendritic length into adulthood. The total number of stem dendrites does not change after birth, but during the first postnatal week dendrites lose distal segments, after which there is a significant increase in the number of segments of orders 3 to 7. The mean length of intermediate segments does not change with age, nor with order, whereas the length of terminal segments increases from 50 to 120 microns from birth to 6 weeks of age, and then decreases to the adult value of 80 microns. In conclusion, during the period of most rapid visual development, important morphological changes occur in geniculate relay-cell dendrites, involving essentially terminal segments. These observations correlate well with changes of geniculate volume and neuronal density.

Effects of prenatal ethanol exposure on dendritic spines of layer V pyramidal neurons in the somatosensory cortex of the rat

The number of dendritic spines on consecutive segments from the cell body along the 400-600 micron proximal region of the apical dendrites of layer V pyramidal neurons, impregnated with the rapid Golgi method, in the somatosensory cortex was counted in ethanol-treated rats during gestation (25% ethanol in drinking water representing 30-35% of the total caloric intake) and in age-matched controls at postnatal ages 4, 15, 30 and 90 days. Although the mean values were lower in ethanol-treated rats than in controls during the first fortnight of postnatal life, significantly lower numbers of spines were observed only in the 15-day-old rat (Student's t-test, P less than 0.01-0.001). Spines with long, thin pedicles were characteristically encountered in ethanol-treated and controls aged 4 days; this sort of spine also predominated in ethanol-treated rats aged 15 days, but not in age-matched controls. The decrease in number and the abnormal morphology of spines was no longer present in ethanol-treated rats aged 30 and 90 days. These data suggest that impaired maturation of dendritic spines on cortical pyramidal cells, followed by recovery of the altered parameters at the end of the first postnatal month, occurs in the offspring of ethanol-treated rats during gestation.

Endogenous opioids regulate dendritic growth and spine formation in developing rat brain

Continuous blockade of endogenous opioid-opioid receptor interaction by opioid antagonists from birth to day 10 increased neuronal maturation in the rat brain. The lengths of oblique dendrites of pyramidal cells in the cerebral cortex and basilar dendrites of the hippocampus were increased from controls by 136 and 51%, respectively, whereas the concentrations of spines in these cells were increased 183 and 69%, respectively. Total dendritic length of spiny branches of cerebellar Purkinje neurons was 65% greater than controls, and spine concentration of granule cells in the dentate gyrus was increased by 76%. Thus, endogenous opioids exert a remarkable influence on the timetable and magnitude of dendritic elaboration and spine formation, and serve as an important trophic influence in the regulation of neuro-ontogeny.

Auditory imprinting leads to differential 2-deoxyglucose uptake and dendritic spine loss in the chick rostral forebrain

Newly hatched chicks of the domestic fowl (White Leghorn) were imprinted to an acoustic stimulus (Group I: 400 Hz, 3 bursts per s, Group II: 900 Hz, 2 bursts per s) and tested in a straight runway with loudspeakers behind two opposite goal boxes. Those chicks were considered imprinted which headed for the imprinting stimulus in an approach test and subsequently preferred it to a new stimulus (imprinting stimulus of the other group) in a simultaneous discrimination test. On day 7 after hatching (after the sensitive phase) imprinted chicks and naive controls were injected with 2-[14C]deoxyglucose (2DG) and exposed to the imprinting stimulus. Autoradiographic analysis of their brains revealed 3 well demarcated areas of increased 2DG accumulation in the rostral forebrain of imprinted chicks compared to controls: HAD in the rostral Wulst; MNH, an auditory area in the rostromedial neostriatum and hyperstriatum ventrale; LNH in the rostrolateral neostriatum and hyperstriatum ventrale. Analysis of these brain areas in 7-day-old acoustically imprinted and control animals with the Golgi-Cox method revealed a highly significant reduction of spine frequency of a large neostriatal neuron type in MNH of imprinted chicks. An additional Golgi-Cox analysis was carried out with chicks imprinted on a broody hen, i.e. on the whole spectrum of natural stimuli. In that group spine frequency of the same neuron type was between that of acoustically imprinted and control animals. A hypothesis of filial imprinting is presented which considers spine loss as a crucial mechanism.

Behavioral activity and active avoidance learning and retention in rats neonatally exposed to painful stimuli

Twice daily for the first 15 days after birth, rats from the same litters were either placed for 5 sec on a hot plate (55 degrees C) (treated group), or on a plate maintained at body temperature (38 degrees C) (manipulated group). Controls were left undisturbed. When 90 days old, they were studied for pain threshold, open-field behavior, and two-way active avoidance learning and retention. Weight gain, pain threshold, open-field behavior, and active avoidance retention were not significantly different in the three groups. On the other hand, the rate of two-way active avoidance learning was significantly greater in treated rats. These results suggest that repeated neonatal exposure to painful stimuli, in rats raised under otherwise normal conditions, improves later active avoidance performance. The most likely mechanisms are discussed.

Developmental abnormalities of medullary "respiratory centers" in sudden infant death syndrome

Dendritic development and gliosis in the medullary magnocellular reticular nucleus and solitary and dorsal vagal nuclei of 15 cases with sudden infant death syndrome (SIDS) and 23 control subjects were compared using morphometric Golgi and immunohistochemical methods. Developmental delay of the normal diminution of dendritic spines was found in the magnocellular reticular nucleus and/or vagal nuclei of 50 to 80% of SIDS infants. Astrocytes reactive with antisera to glial fibrillary acidic protein also increased in those regions, although dendritic spine density was inconsistent with the presence of astrogliosis in 20 to 40% of the cases. This delayed neuronal maturation of dendritic spines suggests there are immature neural respiratory control mechanisms in SIDS.

Differential rearing effects on rat visual cortex synapses. I. Synaptic and neuronal density and synapses per neuron

The bulk of the evidence indicating that different experiences can lead to differences in synapse numbers involves inference from measures of postsynaptic surface (spines and dendrites) in Golgi impregnated tissue. The capriciousness of Golgi impregnation and the absence of direct evidence regarding changes in afferents mandate confirmation of synapse changes by electron microscopy. We calculated the ratio of synapses per neuron in layers I-IV of occipital cortex of rats reared in complex (EC), social (SC), or isolated (IC) environments. Synaptic density estimates were derived from electron micrographs of osmium-uranyl-lead stained tissue and neuronal density estimates were derived from toluidine blue stained semithin sections using stereological methods which correct for group differences in the sizes of synapses and neuronal nuclei. The ratio of these densities, synapses per neuron, was highest in complex environment rats, intermediate in socially reared rats and lowest in isolates, in accordance with predictions from prior Golgi studies. The bulk of the differences were attributable to neuronal density, which was highest in IC rats and lowest in ECs. Synaptic density did not differ statistically across groups. These results indicate, at least within this area and paradigm, that differences in dendritic measures in Golgi impregnated tissue reflect differences in the number of synapses per neuron.

Age-related changes in the subiculum of Macaca mulatta: dendritic branching pattern

The dendritic branching pattern was studied in the subiculum of nine Macaca mulatta from 7 to 28 years of age. Morphometric analysis of pyramidal neurons revealed significant age-related differences at various designated branch orders in both the centrifugal and centripetal ordering methods. There was continued branching and growth of the apical dendrites in adulthood. Basal dendrites did not show any added complexity, but rather showed continued growth of existing terminal branches. The three oldest animals showed a preferential loss of whole terminal branches on the apical portion of the dendritic tree, whereas shortening of existing terminal branches was the characteristic feature of the basal dendrites. Data obtained from the subiculum provide quantitative evidence indicating the considerable potential for dendritic plasticity beyond the early developmental stages and eventual loss of dendritic complexity in the old M. mulatta.

Overstimulation, occipital/somesthetic cerebral cortical depth, and cortical asymmetry in mice

It was hypothesized on theoretical grounds that sensory multidimensional overstimulation (stress) during development might not yield increased cerebral cortical depth, as has been found for enriched rearing conditions. We found that such overstimuliation in growing mice resulted in a low occipital/somesthetic cortical depth ratio in comparison to EC-stimulated mice (EC, enriched conditions). It is unclear whether this is due to small occipital or large somesthetic cortical depth. Principal-component analytic techniques indicate a complicated interaction during development involving sex, environmental condition, and cortical asymmetry.

Sex differences in the effects of early experience on the development of behavioral and brain asymmetries in rats

The influence of early experience (preweaning handling) on the development of several postural/motor asymmetries (side bias in an open field, turn preference in a T-maze, amphetamine-induced rotational behavior, tail pinch-induced asymmetries) and the lateralization of brain dopamine was studied in adult male and female rats. In many cases the adult patterns of behavioral and brain asymmetries were modified by early handling in a sexually dimorphic manner. In addition, the direction of postural/motor asymmetries was very much task-dependent, especially in females. We conclude that: early experience may modify the development of behavioral and brain asymmetries; sex differences in asymmetries are very common; early handling may affect males and females differently; and different measures of postural/motor asymmetries may reflect different and multiple brain asymmetries.

Effect of early locomotor training on evoked potentials and structural organization of visual cortex dendrites of rats during ontogeny

The effect of early locomotor training (running in a squirrel cage from an age of 1 month for 3-6 months) on evoked potentials of the rat visual cortex during ontogeny was investigated. It was established that intensified proprioceptive afferentation causes a statistically significant reduction of both the latent periods and the recovery cycles of excitability of primary responses of the visual cortex to paired light flashes, whereupon the increase in functional activity is more pronounced with respect to the indices of the excitability recovery cycle than with respect to the latent periods or primary responses. The indicated functional changes correlate with the quantitative increase in the density of dendritic spines on neurons of the visual cortex of both layer V, which are primarily the integrative-triggering apparatus of the cortex, and of the complex of layers II + III, which are primarily associative with respect to their functional significance.

Systems analysis of the integrative activity of the neuron (1974)

This article is aimed at revising the traditional concept of neuronal activity based on pre-eminence of transmembrane potentials and "electric summation" on the neuron surface. It presents a historical survey of the emergence of the prevailing concept on propagation of potentials along conductive structures and reveals the psychological situation that determined the transfer of this concept to dendrites and the neuronal soma. Structural and biophysical properties of the neuron which do not permit information propagation along the neuronal membrane without crude distortion are critically discussed in detail.

Faulty development of cortical neurons in the Snell dwarf cerebrum

In the Snell dwarf motor cortex, area 6 of Caviness, the cell number, the stratification of neurons and the portion of layer-widths were absolutely identical to those of the controls. By means of the Golgi-Cox method modified by Ramon-Moliner, however, the pyramidal neuron was found to have small perikarya, short primary dendrites with sparse branchings, and a low spine density on the dendrites. The corpus callosum of the dwarf contained a reduced number of fibers compared to that of the controls, and the staining for myelin basic protein revealed a considerable reduction of positive-fibers of radiation in this area. The content of Thy-1 antigen in the cerebrum, cerebellum and brainstem, was significantly lower than that of controls, but the monoamine content was normal in the cerebrum and brainstem. From these results, it appears that the Snell dwarf cerebrum shows retarded neuronal growth; a reduction in size of neurons, an underdevelopment of axons and dendrites, and a retarded maturation of spine, in addition to arrested glial proliferation. At present, it is unclear which hormone deficient in these mutants, growth hormone or thyroxine, is the essential potentiator for neuronal growth.

Imprinting and cortical plasticity: a comparative review

Results of research on imprinting and developmental neurobiology of the visual cortex are compared to evaluate the evidence for or against a frequently hypothesized linkage of the two phenomena. The comparison reveals striking similarities. In both paradigms a sensitive period exists. Once this sensitive period is over, the storage of early influences from the environment remains stable throughout life. Storage of "natural" stimuli is facilitated by a certain preorganisation of the receiving brain areas. It is stated that the two phenomena are not directly linked, but are two expressions of a developmental process, which may be common for the organisation of the connectivity of single cells as well as for complex neuronal networks as they are likely to be involved in imprinting. This process is basically self-organizing, but can be influenced by superimposed controls. Differences of the stability of storage of external influences might be explained by the difference in the overall amount of morphological alterations, which is large in the young and small in the adult animal. This holds for both the modifiability in the visual cortex and imprinting.

Basic aspects of development and maturation of the brain: embryological contributions to neuroendocrinology

The interpretation of studies on the development of neuroendocrine function presupposes a thorough knowledge of the complementary phenomena of morphogenesis and histogenesis of the brain. A short analysis of the morphogenesis of the diencephalic floor is given. The pituitary Anlage can be identified early in the neural plate stage. The hypophysis cerebri appears to be a key structure in the morphogenesis of both the head and the brain. The spatiotemporal pattern of histogenesis within the brain can be analysed by a study of the proliferative activity of the neuroepithelial matrix cell layer; a heterochrony of matrix (ventricular) layer mitotic activity and of mantle (intermediate) layer differentiation can be demonstrated. The process of neuron differentiation shows an articulate sequence of phenomena, among them migration, axon growth, dendrite growth, synapse formation and myelination. Dendritogenesis and the development of synapses in a particular area are strongly influenced by the ingrowth of axon nerve terminals from elsewhere. A number of structures observed in the developing central nervous system are only temporary phenomena that go into regression during subsequent stages; dendrites and synapses especially show a high degree of plasticity. Cell death occurs as a normal concomitant of development. Monoaminergic neuron systems originate early and show a positive histofluorescence shortly afterwards; their target areas are retarded as far as differentiation is concerned. The development of these target regions probably is influenced by the monoaminergic cells. The monoaminergic neurons are not subject to feedback regulation for some time, because of the typical late development of the dendritic receptive apparatus in these cells. Steroid receptors may play a role in the development of intersexual dimorphism of the brain. Probably a modulation of neurotransmitter synthesis is the intermediate between steroid receptor stimulation and a change in synaptogenesis in the target area of the neuron. Neuropeptide systems appear to possess a distribution beyond the limits of the hypophysiotropic area. The early presence of some of the neuropeptides within the embryonic brain suggests a role in histogenesis that is different from the usually presumed neurotransmitter or neuromodulator function of the neuropeptides.

Effects of postoperative environments following dorsal hippocampal lesions on dendritic branching and spines in rat occipital cortex

Male Long-Evans rats sustained bilateral dorsal hippocampal lesions or were sham-operated when 31 days old. They were reared thereafter in either an 'enriched' (EC) or an 'impoverished' (IC) environment for one month. The effects of lesion and rearing conditions were measured on dendritic branching and spines in layer V pyramidal cells of area 17 by using a concentric ring analysis and by counting the number of spines on 50 micron segments of basilar dendrites. Hippocampal lesions significantly decreased the branching and the number of spines in both EC and IC rats. In contrast to what was observed in most behavioral studies, in which the effects of the postoperative environment were even larger in animals with lesions than in control animals, the present experiment showed that the cytological measures were affected by postoperative rearing conditions only in sham-operated rats (EC greater than IC). It is suggested, therefore, that the morphologic processes underlying the effects of the environment on behavioral recovery after hippocampal lesions can hardly be located in layer V pyramidal cells of area 17, which is considered as one of the most sensitive to environment in intact animals.

Dendritic spine loss and enlargement during maturation of the speech control system in the mynah bird (Gracula religiosa)

Three types of neurons were identified in Golgi-Cox preparations of the telencephalic nucleus HVc of the mynah bird with the Sholl method. In a comparison of birds of 10 weeks and speech-trained birds of one year of age a reduction of dendritic spine density and an enlargement of the remaining spines was found in a large isopolar cell type. These findings are interpreted in terms of the mynah's shrinking potential with age to imitate new sounds and the stabilization of the acquired repertoire.

Lateralized effects of monocular training on dendritic branching in adult split-brain rats

A number of experimental approaches have indicated differential interneuronal connectivity following differential experience during both development and adulthood. In Golgi preparations, prolonged maze training was reported to alter dendritic branching of distal apical dendrites of Layer IV and V pyramidal neurons in adult rat occipital cortex. To determine the specificity of this effect to direct involvement in the visual aspects of training, the effects of monocular maze training, using a split-brain procedure and opaque contact occluders, was examined in the present study. Rats were maze trained with unilateral or alternating monocular occlusion, while nontrained rats with unilateral or alternating monocular occlusion were handled briefly and given water reward. There was no within-animal effect of fixed occluder position in non-trained controls. In unilaterally-occluded trained rats, Layer V pyramidal neurons in occipital cortex opposite the open eye had greater oblique dendritic length in the distal region of the apical dendrite than did those opposite the occluded eye. Similarly, rats trained with alternating occlusion had greater distal apical oblique dendritic length in Layer V occipital pyramidal neurons than did nontrained controls. This indicates that morphological sequelae of training are concentrated in areas processing information associated with visual aspects of the training and renders unlikely general metabolic or hormonal causation of such effects.

Plasticity of dendritic spine formation: a state-dependent stochastic process

This study proposes that plasticity of dendritic spine formation may be modeled as distribution patterns imbedded in a spine length-dependent and density-dependent stochastic process. Modeling the jewel fish tectal interneuron revealed a critical 10-36 micron region where spine length plasticity was predicted to be most detectable. This hypothesis was tested by comparing neurons sampled from jewel fish reared for 4 years in a crowded environment (1 fish/5.64 l) with uncrowded controls (1 fish/25 l). The interaction between fish groups and the location of spine length differences was significant (p less than 0.01) within the basal 10-30 micron dendritic segment. Spine head widths were also significantly smaller (p less than 0.01) in the crowded fish over the entire dendrite. These findings suggest two modes of neuronal plasticity: (1) plasticity of spine length during formation, and (2) plasticity in spine head width after the spine is formed.

Effects of environmental complexity and deprivation on brain anatomy and histology: a review

During the last 20 years the anatomical plasticity of the brain in response to sensory stimulation has been clearly demonstrated. This paper reviews the effects of environments rich in sensory stimulation versus those which are stimulus poor. Effects have been noted at all levels from the gross anatomical to the electromicroscopic. As compared to their stimulus-deprived counterparts, animals reared in complex environments tend to display greater cerebral weight and length and cortical depth. The greatest effects occur in the occipital cortex where histological studies have revealed expanded neuron perikaryonal and nuclear size and dendritic branching, more dendritic spines, alterations in synaptic numbers and morphology, and greater numbers of neuroglia. Different cortical areas and layers respond to different degrees. Some responses have also been noted in the underlying hippocampus, particularly in the dentate gyrus. The emerging data present a picture of a dynamic, plastic brain adapting homeostatically to the demands of its environment.

The relationship between dendritic growth of cortical neurons and the ontogeny of conditioned and unconditioned reflex control

Suppression of an infantile reflex (circling behavior) to electric shock in a straight-alley escape problem increased as a function of age and trials in male Swiss-Webster mice trained at 7, 9, or 11 days of age and retested 24 h later. Twenty-four hours retention of prior training, indicated by the superior performance of trained subjects relative to yoked-shock and age controls, was not evident until 9 days of age. Analyses of Golgi--Cox preparations of parieto-temporo-preoccipital cortices, taken immediately following testing, revealed that behavioral development was paralleled by age-related changes in apical, oblique, and basilar dendritic networks and number of apical dendritic spines of layer V pyramidal cells. Correlations between behavioral and histological measures, indicated no consistent association of retention capacity with any of the physiological measures. However, basilar dendritic growth was significantly correlated with unconditioned reflex control as well as initial learning ability.

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.

Determinants of cell shape and orientation: a comparative Golgi analysis of cell-axon interrelationships in the developing neocortex of normal and reeler mice

Patterns of dendritic development in the neocortex of normal and reeler E15-17 mouse embryos are studied in Golgi impregnations. Interactions between dendrites and axon-rich strata appear to be critical determinants of dendritic morphology in both genotypes. Firstly, axon-dendrite proximity appears to stimulate dendritic sprouting, elongation and branching. Secondly, the position of the axon-rich strata with respect to the differentiating cell appears to determine the direction of dendritic growth and thereby the ultimate configuration of the dendritic arbor. With regard to specific cell configurations, a multipolar form is generated when the cell is embedded in an axon-rich zone. A monopolar or bipolar configuration is achieved when the cell lies in the axon-poor cortical plate and addresses and axon-rich stratum with one or both radially extended migratory processes. Such variations in the configuration of neurons with polar dendritic systems may be observed uniquely in the mutant cortex because axon-rich zones are stratified anomalously at multiple levels in the cortical plate. As a consequence, polar dendritic systems develop from either the superior, the inferior or both somatic poles of postmigratory cells. Pyramidal cells may, therefore, develop a normal upright or an abnormal "upside-down" disposition. Regardless of the orientation of the polar dendritic system, the axon emerges from the inferior aspect of the cell suggesting that there has been no rotation of the original migratory axis of the cell.

Effects of early visual and complex stimulation on learning, brain biochemistry, and electrophysiology

A complex stimulation regimen (visual, auditory, and somesthetic-kinesthetic with forced movements, 30 times for 30 min each within 14 days) increased significantly the amplitudes of visual cortical evoked potentials (EPs) in adult rats if applied during the second postnatal fortnight. The EP increase after stimulation during the first 14 days after birth was not significant. Visual stimulation alone was compared with complex stimulation (visual plus forced movements) during the 2nd postnatal fortnight. More specific local changes in the visual cortex were revealed in brain biochemistry (lower DNA concentration, more RNA and protein per cell) and cortical electrogenesis (enhanced visual EPs) after visual stimulation alone, whereas complex stimulation induced more diffuse changes and rather profoundly influenced higher nervous functions (viz., memory retrieval - improved 24-h). Involvement of both specific and nonspecific mechanisms in the aftereffects of early stimulation is indicated.

Behavioral and physiological effects of early handling and early malnutrition in rats

This experiment employed a 2 x 2 design in which the nutritional and early stimulation conditions of rat pups were manipulated during the 1st 3 weeks of postnatal life. Animals were observed in various open field activities at 22, 23, 29, 36, and 50 days of age, and killed at 55 days of age for neurochemical analysis. Early handling decreased the behavioral differences due to malnutrition and resulted in fewer, but larger cells in rat forebrain for both well-nourished and malnourished groups.

Social experience affects the development of dendritic spines and branches on tectal interneurons in the jewel fish

African jewel fish reared with eyeless cave fish, but without visual-tactile contact with conspecifics, exhibit hyperresponsive behavior after release in community aquaria. Because the optic tectum might be affected by these restraints on visual experience, unreleased members of the same social isolate group were compared histologically with controls reared in community aquaria. Using the rapid Golgi method, we counted dendritic spines and branches on pyriform interneurons between 402 and 529 days of age. As compared with isolates, control group interneurons exhibited significantly more spines and primary branches on apical dendrites in deep tectal layers. Our focus is the relation between experiential differences in rearing conditions and synaptic changes in the deep tectal layers.

A Golgi study of the early postnatal development of the visual cortex of the hooded rat

Although neuroanatomical plasticity has been demonstrated in the rat visual cortex, no systematic data on the dendritic development of the area are available. In the present study, the visual cortex of hooded rats at 1, 3, 5, 7, 10 and 15 postnatal days of age (P1-P15) was impregnated with the rapid Golgi method. The cortex was divided into the superficial layers, II-IV, and the middle layer V. At P1, pyramidal neurons had apical shafts and the beginning of the apical terminal arch. Analysis of both basilar and oblique dendritic number showed that pyramidal neurons of the middle layer developed more quickly than those in the superficial layers. The number of lower order basilar dendritic branches reached asymptote over the examined time period, whereas the higher order branches were still increasing in number but at a decelerating rate by P15. Dendrites at all ages exhibited varicosities which were especially prominent on the thin dendritic branches of the earlier ages. Some thin, filamentous processes, termed protospines, were found on dendrites and cell bodies at P1 to P5. They seemed to decrease by P7, when a few mature spines appeared. Spines increased in number on days P10 and P15. A comparison of the data from this study with quantified Golgi studies in adult rats indicates that by P10 and P15 the number of basilar branches is in the range seen in the adult.

Spine stems on tectal interneurons in jewel fish are shortened by social stimulation

Spined pyriform interneurons in community-reared jewel fish have more dendritic branches and spines in the deep tectal layers than those in isolates reared without visual-tactile contact with conspecifics. Furthermore, in the same dendritic loci in which the community-reared fish had more spines, the spine stems were shorter. The findings suggest that social stimulation induces localized formation of spines, which swell with synaptic activation. Shortening of the spine stem through elongated swelling of the spine head is likely to alter synaptic effectiveness through changes in electrotonic conductance.

The development of sexual behavior in the rat: role of preadult nutrition and environmental conditions

Rats were subjected to pre- and postnatal undernutrition by restricting the food intake of their mothers (U); another group of rats was normally fed (N). Each nutrition group was divided into 3 subgroups by varying the degree of environmental stimulation: animals in the Max group were stimulated by handling and enriched rearing conditions; the Min group rats were subjected to social isolation; rats in the control condition (C) were raised under ordinary laboratory conditions. The onset of sexual activity was not affected in the U-C male rats, but was delayed in both U-Min and N-Min rats. Although no difference existed in the age of puberty between the N-Max and N-C animals, the U-Max rats displayed an advancement of puberty by 7 days in comparison to the U-C rats. Undernutrition did not affect female sexual maturation; however the Max condition delayed this process in both nutrition groups.

A Golgi analysis of caudate neurons in rats exposed to carbon monoxide

Interneurons of the caudate nucleus have been reported in the literature to respond to deafferentation by reduction in dendritic spines. In the studies reported here, caudate interneurons have been examined using the Golgi technique and increased numbers of spines were found in adult rats exposed to carbon monoxide as neonates. The development of spines on the caudate neurons was delayed for several days after an acute anoxic episode in 5-day-old rats exposed to carbon monoxide to the point of respiratory arrest. By the time the rats were 6 weeks old the caudate neurons had recovered to the point where they had essentially normal numbers of spines. At later ages (2- and 7-months old) the number of spines was greater in rats exposed perinatally to carbon monoxide than in control rats of the same age. The development of abnormal numbers of spines coincided with the time of recovery of rats from behavioral hyperactivity induced by carbon monoxide. The increased spines on the caudate neurons of the adult rats (7-months old) can be explained as a compensatory response to increased afferent flow to the caudate during the period of juvenile hyperactivity which reaches a peak at 6 weeks of age. It is proposed that the return to normal activity in the adult may be a consequence of increased activity of the caudate nucleus.

Response of the three main types of glial cells of cortex and corpus callosum in rats handled during suckling or exposed to enriched, control and impoverished environments following weaning

The cell populations of the occipital cortex were examined in young rats subjected to different sensory experiences. In one series recently weaned animals were reared in enriched, impoverished or control environments. The enriched environment was obtained by keeping the animals among "toys" and other rats; the impoverished environment, by rearing the animals one per cage in a darkened, quiet room; and the control environment, by housing the animals three per cage under usual animal room conditions. Six recently weaned rats were kept in each environment for 30 days and ten, for 80 days. In a second series suckling rats were handled daily. Handling consisted of touching, holding and rubbing rat pups for 15 minutes per day during the first ten days after birth; twelve rats were studied, six handled and six unhandled controls. In the two series, the animals were sacrificed under anesthesia by perfusion with mixed aldehydes. Semithin epon sections of occipital cortex were stained with toluidine blue; neurons and the three main types of glia were enumerated. In addition, the thickness of the cortex was measured and the glial cells of corpus callosum counted in the animals exposed to the three environments for 80 days. Under the influence of the enriched environment, the occipital cortex enlarged, the number of oligodendrocytes increased over the controls by 27-33% in the 30- and 80-day groups and the number of astrocytes, by 13% in the 80-day group. Within the cortex, only certain layers showed the increase in glial numbers. In the corpus callosum, however, the numbers of glial cells did not differ from those in controls. In the animals exposed to the impoverished environment, neither the size of the cortex nor the number of oligodendrocytes and astrocytes differed from controls. The animals subjected to handling also showed evidence of cortical enlargement, but the only significant change in glial cells was a 12% increase in astrocytes. It is concluded that handling and enrichment produce changes in anatomical indices of neural function including depth of cortex and numbers of glial cells. The glial response was specific to the type.of manipulation since astrocytes were predominantly affected by handling and oligodendrocytes, by enrichment. The effect of handling on astrocytes may be attributed to the stimulation being applied at a time of astrocyte proliferation, whereas the effect of enriched environment on oligodendrocytes occurred at a time of active production of these cells. The differences in cell numbers were explained by changes in the rate of cell population growth; since the impoverished did not differ from the control animals, the changes probably consisted of growth acceleration in the enriched animals rather than diminution in the impoverished ones.

Hypothermia causes adult-like retention deficits of prior learning in infant mice

Nine-day-old S-W mice receiving deep body hypothermia or hyperthermia immediately after escape training were retested 1 or 24 hr later. Results indicated that hypothermia impaired 24-hr retention but had no effect upon 1-hr memory. Hyperthermia had no effect, with the mice demonstrating retention of the escape response at both retest intervals. In Experiment 2, administration of hypothermia or hyperthermia 23 hr after original training had no effect upon memory nor did either treatment produce motoric deficits upon retest 1 hr following thermal exposure. Experiment 3 indicated that hypothermia administered immediately after training produced retention deficits directly related to amount of body temperature reduction following hypothermia. These data are similar to those obtained with adult mice and suggest that memory processes occurring in 9-day-old mice may represent the onset of functioning of processes underlying adult long-term memory.