Brief daily binocular vision prevents monocular deprivation effects in visual cortex

Even short periods of early monocular deprivation result in reduced cortical representation and visual acuity of the deprived eye. However, we have shown recently that the dramatic deprivation effects on vision can be prevented entirely if the animal receives a brief period of concordant binocular vision each day. We examine here the extent to which the cortical deprivation effects can be counteracted by daily periods of normal experience. Cats received variable daily regimens of monocular deprivation (by wearing a mask) and binocular vision. We subsequently assessed visual cortex function with optical imaging of intrinsic signals and visually evoked potential recordings. Regardless of the overall length of visual experience, daily binocular vision for as little as 30 min, but no less, allowed normal ocular dominance and visual responses to be maintained despite several times longer periods of deprivation. Thus, the absolute amount of daily binocular vision rather than its relative share of the daily exposure determined the outcome. When 30 min of binocular exposure was broken up into two 15-min blocks flanking the deprivation period, ocular dominance resembled that of animals with only 15 min of binocular vision, suggesting that binocular experience must be continuous to be most effective. Our results demonstrate that normal experience is clearly more efficacious in maintaining normal functional architecture of the visual cortex than abnormal experience is in altering it. The beneficial effects of very short periods of binocular vision may prevent any long-term effects (amblyopia) from brief periods of compromised vision through injury or infection during development.     

Monocular deprivation enhances the nuclear signalling of extracellular signal-regulated kinase in the developing visual cortex

Monocular deprivation (MD) of vision leads to a loss of cortical response to the deprived eye in the early postnatal period (ocular dominance plasticity). The activity of several signal molecules, including extracellular signal-regulated kinase (ERK), has been reported as playing a crucial role in the ocular dominance plasticity. Although pharmacological inhibition of ERK disturbed the ocular dominance plasticity, it remains to be elucidated how the ERK activity is modulated by MD. We herein report the effects of MD on ERK activation in the visual cortex of young and adult rats. Phosphorylated ERK (pERK)-immunopositive cells are mainly distributed in layers II/III of the visual cortex. Following MD, we found a significant decrease in the density of pERK-immunopositive cells in the cortex receiving deprived-eye inputs in both young and adult animals. The amount of pERK protein also decreased in the input-deprived cortex as revealed by Western blotting. Regarding the subcellular localization of pERK, we found a significant increase in the pERK-immunopositive nucleus following MD in young animals. In these animals, the amount of pERK protein in the nuclear fraction of cortical tissue was significantly increased. No up-regulation of the nuclear pERK was observed in adults or following binocular deprivation. These findings suggest that ERK activation may therefore be regulated by different mechanisms between young and adult animals, and MD during the developing period may thus specifically up-regulate the nuclear signalling of ERK.     

Reversal of the physiological effects of monocular deprivation in adult dark-reared cats

If kittens are dark-reared for 4 months and subsequently monocularly sutured, cells in area 17 become dominated by the experienced eye. We now find that the effects of monocular deprivation in adult dark-reared cats can be reversed by suturing the experienced eye and allowing the cat to use the deprived eye, an effect that has previously been shown only in young kittens. The presence of continuous or nearly continuous visual experience during infancy is required for the critical period to exhaust itself--brief periods of visual experience will not suffice.     

Blockade of NMDA-receptors prevents ocularity changes in kitten visual cortex after reversed monocular deprivation

We investigated in the striate cortex of kittens whether the recovery from the effects of monocular deprivation that occurs after reverse occlusion requires activation of N-methyl-D-aspartate (NMDA) receptors. The right eye of 3-4-week-old kittens was closed by lid suture for one week. Subsequently this eye was reopened and the left eyelid sutured closed for another week. During this second week, the NMDA-receptor antagonist, 2-amino-5-phosphonovaleric acid (APV), was infused from an osmotic minipump into the left visual cortex (50 nmol/h), while the right visual cortex was infused only with vehicle solution (saline) as control. At the end of the second week, the ocular dominance of striate cortical neurons was assessed with single unit recording. In the control hemispheres, the large majority of neurons was dominated by the newly opened eye, while in the APV-treated hemispheres most neurons were still dominated by the newly deprived eye. In addition, neurons in the APV-treated hemispheres were less responsive and showed a reduction of orientation tuning. These data confirm that chronic blockade of cortical NMDA-receptors disrupts the disconnection of deprived pathways after monocular deprivation and reduces both responsiveness and orientation selectivity of cortical neurons. In addition they indicate that blockade of NMDA-receptors prevents also vision-dependent recovery of deprived pathways after reverse occlusion.     

A switch from inter‐ocular to inter‐hemispheric suppression following monocular deprivation in the rat visual cortex

Binocularity is a key property of primary visual cortex (V1) neurons that is widely used to study synaptic integration in the brain and plastic mechanisms following an altered visual experience. However, it is not clear how the inputs from the two eyes converge onto binocular neurons, and how their interaction is modified by an unbalanced visual drive. Here, using visual evoked potentials recorded in the juvenile rat V1, we report evidence for a suppressive mechanism by which contralateral eye activity inhibits responses from the ipsilateral eye. Accordingly, we found a lack of additivity of the responses evoked independently by the two eyes in the V1, and acute silencing of the contralateral eye resulted in the enhancement of ipsilateral eye responses in cortical neurons. We reverted the relative cortical strength of the two eyes by suturing the contralateral eye shut [monocular deprivation (MD)]. After 7 days of MD, there was a loss of interocular suppression mediated by the contralateral, deprived eye, and weak inputs from the closed eye were functionally inhibited by interhemispheric callosal pathways. We conclude that interocular suppressive mechanisms play a crucial role in shaping normal binocularity in visual cortical neurons, and a switch from interocular to interhemispheric suppression represents a key step in the ocular dominance changes induced by MD. These data have important implications for a deeper understanding of the key mechanisms that underlie activity‐dependent rearrangements of cortical circuits following alteration of sensory experience.     

Neonatal capsaicin treatment modulates experience‐dependent plasticity in the rat barrel cortex

Previous studies have reported that capsaicin‐induced C‐fiber depletion results in expansion of low threshold somatosensory mechanoreceptive fields. Here we used this paradigm to investigate its effect on experience‐dependent plasticity in the barrel cortex of rats. All but the D2 vibrissa were first plucked on postnatal day 0 (P0), P5, or P8, and kept plucked for a period of 30 days before being allowed to regrow for 7–9 days prior to the recording session. To assess receptive field characteristics the spared D2 principal whisker (PW) and the deprived D1 adjacent whisker (AW) were moved either singly or in concert, neuronal responses being recorded in layers IV and V of the D2 barrel. In vehicle‐treated rats, PW‐evoked ON responses (layer IV) were increased only in those animals that first had their vibrissae plucked on P0, whereas AW‐evoked ON responses (layers IV and V) were decreased in the P0, P5, and P8 groups. In the capsaicin‐treated animals, PW‐evoked ON responses (layer IV) were increased in all three groups, but no decrease was recorded in the AW‐evoked ON (layers IV and V) responses. In the vehicle‐ and capsaicin‐treated animals, the greatest decrease in inhibitory interactions was observed in the P5 and P0 groups, respectively. These findings indicate that, following the induction of experience‐dependent plasticity, the resultant changes in excitatory and integrative circuits can be further influenced by C‐fiber depletion. J. Comp. Neurol. 518:3427–3438, 2010. © 2010 Wiley‐Liss, Inc.     

NGF prevents the changes induced by monocular deprivation during the critical period in rats

Photic evoked responses were recorded from the striate cortex of Long-Evans hooded intact, monocular visual deprivation (MD) and MD treated with NGF rats. The averaged visual evoked responses (AVER) were obtained from both hemispheres and provided comparison after binocular photic stimuli between the contralateral and the ipsilateral striate cortex with relation to the MD eye. One month of monocular visual deprivation at the critical period of development resulted in marked reduction of the amplitudes of AVER components as compared to the control recordings (P < 0.001). These changes of the AVER could be prevented by NGF infusion to lateral ventricle at the dosage of 2.0–2.4 μg/day for four weeks during the monocular deprivation. In conclusion, the change of AVER amplitudes induced by monocular visual deprivation during the critical period of development can be prevented by NGF infusion to lateral ventricle.     

Down-regulation of β-adrenergic receptor following long-term monocular deprivation in cat visual cortex

To examine how adrenergic receptor binding is modified by experimental manipulation of sensory afferent, we carried out binding experiments (membrane fraction and in vitro autoradiography) for both ₂- and β-adrenergic receptors in the brain of cats which had been deprived of vision in one eye. In the cerebral cortex of control animals, β-adrenergic receptor (β-AR) binding was found to be higher in the occipital regions than in other regions, while ₂-AR binding was relatively uniform. Monocular deprivation throughout the postnatal sensitive period (1–7 month of age) significantly decreased β-AR binding in the visual cortex and lateral geniculate nucleus. Scatchard plot analysis in the visual cortex showed ca. 50% reduction in B_max and little change in K_d No significant difference was found in ₂-AR binding following monocular deprivation. Similar extent of down-regulation in β-AR binding was confirmed in all layers of visual cortex using autoradiography.     

Layer- and cell-type-specific subthreshold and suprathreshold effects of long-term monocular deprivation in rat visual cortex

Connectivity and dendritic properties are determinants of plasticity that are layer and cell-type specific in the neocortex. However, the impact of experience-dependent plasticity at the level of synaptic inputs and spike outputs remains unclear along vertical cortical microcircuits. Here I compared subthreshold and suprathreshold sensitivity to prolonged monocular deprivation (MD) in rat binocular visual cortex in layer 4 and layer 2/3 pyramids (4Ps and 2/3Ps) and in thick-tufted and nontufted layer 5 pyramids (5TPs and 5NPs), which innervate different extracortical targets. In normal rats, 5TPs and 2/3Ps are the most binocular in terms of synaptic inputs, and 5NPs are the least. Spike responses of all 5TPs were highly binocular, whereas those of 2/3Ps were dominated by either the contralateral or ipsilateral eye. MD dramatically shifted the ocular preference of 2/3Ps and 4Ps, mostly by depressing deprived-eye inputs. Plasticity was profoundly different in layer 5. The subthreshold ocular preference shift was sevenfold smaller in 5TPs because of smaller depression of deprived inputs combined with a generalized loss of responsiveness, and was undetectable in 5NPs. Despite their modest ocular dominance change, spike responses of 5TPs consistently lost their typically high binocularity during MD. The comparison of MD effects on 2/3Ps and 5TPs, the main affected output cells of vertical microcircuits, indicated that subthreshold plasticity is not uniquely determined by the initial degree of input binocularity. The data raise the question of whether 5TPs are driven solely by 2/3Ps during MD. The different suprathreshold plasticity of the two cell populations could underlie distinct functional deficits in amblyopia.     

Immunocytochemical Localization of trkA Receptors in Chemically Identified Subgroups of Adult Rat Sensory Neurons

Immunocytochemistry has been used to examine the location of trkA, the high-affinity receptor for nerve growth factor, in adult rat dorsal root ganglia, trigeminal ganglia and spinal cord. TrkA immunoreactivity was observed in small and medium sized ganglion cells and in the dorsal horn of the spinal cord. In lumbar L4 and L5 ganglia trkA-immunoreactive cells constitute 40% of dorsal root ganglion cells and range in size from 15 to 45 μm in diameter. Double labelling using markers for various dorsal root ganglion subpopulations revealed that virtually all (92%) trkA-immunoreactive cells express calcitonin gene-related peptide (CGRP) immunoreactivity. In contrast only 4 and 13% of trkA-immunoreactive cells are labelled by the monoclonal antibody LA4 or the lectin Griffonia simplicifolia IB4, markers for small non-peptide-containing cells. Eighteen percent of trkA-immunoreactive cells belong to the 'large light'subpopulation, identified by their strong immunostaining by the neurofilament antibody RT97. TrkA immunoreactivity in the dorsal horn is heaviest in laminae I and II outer, has a similar distribution to CGRP, and is depleted by dorsal rhizotomy. Our results show that trkA-expressing cells in dorsal root ganglia correspond almost exactly with the CGRP, peptide-producing population. The receptor is present not only on cell bodies but also on central terminals. Non-peptide-containing small cells, which constitute 30% of dorsal root ganglion cells, are not trkA-immunoreactive and therefore most probably are functionally independent of nerve growth factor.     

N-methyl-D-aspartate subunit R1 involvement in the postnatal organization of the primary visual cortex of Callithrix jacchus

It has been demonstrated that the primary visual cortex is highly sensitive to manipulations of the visual environment during a specific, early, postdevelopmental period: the critical period. Pharmacological studies have shown that N-methyl-D-aspartate (NMDA) receptors are involved in the plasticity of the visual cortex just as they are involved in the induction of long-term potentiation (LTP), another activity-dependent form of plasticity. The setting up of synaptic connectivity in the neocortex may rely on LTP-like mechanisms. By using immunohistochemistry techniques, we tested the hypothesis of the role of subunit R1 of NMDA (NMDAR1) receptors in the thalamocortical afferent segregation into ocular-dominance columns in the New World monkey, Callithrix jacchus. We employed early and short (2 weeks) monocular-deprivation periods at different ages of postnatal development (17, 46, 67, 107, and 188 postnatal days). We observed heterogeneous distribution of NMDAR1 in the layer IVC receiving the thalamic inputs if the deprivation was realized between the ages of 46 and 107 days. Layers IVCα and IVCβ were involved differently as a function of the deprivation age. The striped pattern lost its differential intensity with the postnatal age. These results are compared with the ocular-dominance pattern evolution described in other works on this primate. They provide evidence of the NMDAR1 role in the modular organization, within time limits, during the postnatal development of the primary visual cortex. J. Comp. Neurol. 386:260–276, 1997. © 1997 Wiley-Liss, Inc.     

Recovery from the anatomical effects of long‐term monocular deprivation in cat lateral geniculate nucleus

Monocular deprivation (MD) imposed early in postnatal life elicits profound structural and functional abnormalities throughout the primary visual pathway. The ability of MD to modify neurons within the visual system is restricted to a so‐called critical period that, for cats, peaks at about one postnatal month and declines thereafter so that by about 3 months of age MD has little effect. Recovery from the consequences of MD likewise adheres to a critical period that ends by about 3 months of age, after which the effects of deprivation are thought to be permanent and without capacity for reversal. The attenuation of plasticity beyond early development is a formidable obstacle for conventional therapies to stimulate recovery from protracted visual deprivation. In the current study we examined the efficacy of dark exposure and retinal inactivation with tetrodotoxin to promote anatomical recovery in the dorsal lateral geniculate nuclues (dLGN) from long‐term MD started at the peak of the critical period. Whereas 10 days of dark exposure or binocular retinal inactivation were not better at promoting recovery than conventional treatment with reverse occlusion, inactivation of only the non‐deprived (fellow) eye for 10 days produced a complete restoration of neuron soma size, and also reversed the significant loss of neurofilament protein within originally deprived dLGN layers. These results reveal a capacity for neural plasticity and recovery that is larger than anything previously observed following protracted MD in cat, and they highlight a possibility for alternative therapies applied at ages thought to be recalcitrant to recovery.     

TrkB-like immunoreactivity is present on geniculocortical afferents in layer IV of kitten primary visual cortex.

Exogenous administration of the neurotrophins brain-derived neurotrophic factor (BDNF) or neurotrophin-4/5 (NT-4/5), or blockade of their endogenous actions, have been reported to affect the anatomic organization and physiological responses of neurons in developing mammalian primary visual cortex. Experimental alteration of levels of these neurotrophic factors can also influence the morphology of the geniculocortical afferents that project from the lateral geniculate nucleus (LGN) to primary visual cortex. BDNF and NT-4/5 are ligands of the TrkB tyrosine kinase receptor. Although multiple populations of cortical neurons express TrkB, it is not known whether geniculocortical afferents express this receptor on their axon branches in visual cortex. We have anatomically labeled geniculocortical afferents of postnatal day 40 kittens with the anterograde neuronal tracer Phaseolus vulgaris leucoagglutinin (PHA-L) and performed double-label immunofluorescence with a panel of anti-TrkB antibodies. Confocal microscopy and object-based colocalization analysis were used to measure levels of TrkB-like immunoreactivity (IR) on geniculocortical afferents in layer IV of primary visual cortex. By using a conservative analysis involving a comparison of measured colocalization with the amount of colocalization expected based on random overlap of TrkB puncta and PHA-L--labeled afferents, 3 of 5 anti-TrkB antibodies tested showed significant colocalization with the geniculocortical axons. Results for the other two antibodies were indeterminate. The indices obtained for colocalization of TrkB and geniculocortical afferents were also compared with the equivalent index obtained for GAD65, a protein that has a similar overall expression pattern to that of TrkB but is not expressed on geniculocortical axons. This analysis indicated that TrkB was present on geniculocortical axons for all five TrkB antibodies tested. TrkB-like IR was also observed on neuronal somata in the LGN. These results indicate that TrkB receptors on geniculocortical afferents are potential mediators of the actions of BDNF and NT-4/5 in developing visual cortex.     

Reversal of the behavioural effects of monocular deprivation as a function of age in the kitten

In order to evaluate the role played by chronological age or maturation in the decline of cortical plasticity during the critical period, kittens were given equal periods of monocular visual experience with each eye, separated by periods of dark-rearing. Experience with one eye was given at the same age in all animals (days 26–36), whereas the age at onset of reversal experience varied across animals. Monocular visual acuities were used as a behavioural index of sensitivity to reverse suturing. Our results demonstrate that sensitivity to reversal varies as a function of age alone when amount of visual experience is held constant. The size and direction of the interocular differences in visual acuity indicate that sensitivity declines steadily throughout the critical period. If reversal occurred on or before day 57, the initially deprived eye was able to gain superiority over the initially exposed eye. By 14 weeks of age the effects of reversal were     

Susceptibility to monocular deprivation following immersion in darkness either late into or beyond the critical period

An extended duration of darkness starting near the time of birth preserves immature neuronal characteristics and prolongs the accentuated plasticity observed in young animals. Brief periods of complete darkness have emerged as an effective means of restoring a high capacity for neural plasticity and of promoting recovery from the effects of monocular deprivation (MD). We examined whether 10 days of darkness imposed in adulthood or beyond the peak of the critical period could rejuvenate the ability of MD to reduce the size of neuron somata within deprived layers of the cat dorsal lateral geniculate nucleus (dLGN). For adult cats subjected to 10 days of darkness before 7 days of MD, we observed no alteration in neuron size or neurofilament labeling within the dLGN. At 12 weeks of age, MD that followed immediately after 10 days of darkness produced an enhanced reduction of neuron soma size within deprived dLGN layers. For this age we observed that 10 days of darkness also enhanced the loss of neurofilament protein within deprived dLGN layers. These results indicate that, although 10 days of darkness in adulthood does not enhance the susceptibility to 7 days of MD, darkness imposed near the trailing edge of the critical period can restore a heightened susceptibility to MD more typical of an earlier developmental stage. The loss of neurofilament in juveniles exposed to darkness prior to MD suggests that the enhanced capacity for structural plasticity is partially rooted in the ability of darkness to modulate molecules that inhibit plasticity. J. Comp. Neurol. 524:2643–2653, 2016. © 2016 Wiley Periodicals, Inc.     

TrkA immunoreactive neurones in the rat spinal cord

We report the presence in rat spinal cord of a novel neuronal system expressing tyrosine kinase receptor (trkA), the high affinity receptor for nerve growth factor (NGF). TrkA immunoreactive cell bodies were observed in the intermediate grey matter of the spinal cord and were classified into three main groups: central canal cells located dorsolateral to the aqueduct, partition cells located between lamina X, and the lateral border of the intermediate grey, and a morphologically heterogeneous group which included large cells located near the lateral border. In situ hybridization confirmed that cells in all these areas express trkA mRNA. Combined immunofluorescence and retrograde Fluoro-Gold labelling was used to further characterise the projections and neurotransmitter profile of the trkA cells. Although often located in the vicinity of preganglionic cell groups, trkA immunoreactive cells are not themselves preganglionic. Rather, the central canal and partition cells belong to a neurochemically complex cholinergic propriospinal system. Many partition cells coexpress trkA, choline acetyltransferase (ChAT), the low affinity neurotrophin receptor, p75, and nicotinamide adenine dinucleotide phosphate-diaphorase (NADPH-d). In contrast, trkA immunoreactive central canal cells express ChAT, but do not express p75 and only a subpopulation express NADPH-d. The large trkA immunoreactive cells located on the lateral border do not express ChAT. TrkA immunoreactive fibres were also present and were located in the dorsal horn, in the dorsal columns, and in a bundle ventral to the aqueduct. However, double labelling revealed that the trkA immunoreactive fibres are not intrinsic but are primary afferent in origin and coexpress p75. The location of this novel trkA neuronal system is consistent with it having a role in the segmental integration of autonomic outflow. NGF could affect this system by modulating neuronal phenotype and/or synaptic efficacy. J. Comp. Neurol. 385:441–455, 1997. © 1997 Wiley-Liss, Inc.     

Dexamethasone induces TrkA and p75NTR immunoreactivity in the cerebral cortex and hippocampus

Nerve growth factor (NGF) plays a crucial role in synaptic plasticity during brain development and adulthood by activating a dual receptor system composed of TrkA and p75 (p75NTR) receptors. Exogenous NGF modulates the expression of both receptors. Little is known about the ability of endogenous NGF to regulate the expression of these receptors in basal forebrain cholinergic terminals. The ability of glucocorticoids to increase NGF expression in the hippocampus prompted us to investigate whether the synthetic glucocorticoid dexamethasone (DEX) increases TrkA and p75NTR expression in NGF-target cholinergic neurons in developing rats. We first examined the effect of DEX on NGF mRNA by in situ hybridization. DEX given systemically (0.5 mg/kg, sc) for 1 week to 7-day-old rats elicited an increase in NGF mRNA levels in the dentate gyrus of the hippocampus and superficial layers II and III of the cerebral cortex. Immunohistochemical analysis of p75NTR and TrkA levels revealed a dramatic increase in p75NTR immunoreactivity (IR) in both basal forebrain and hippocampus and TrkA IR in the hippocampus. Interestingly, in DEX-treated rats more axonal terminals were immunopositive for p75NTR in the hippocampus and cortex, suggesting an increase in p75NTR IR in cell bodies as well as in terminals. Our data indicate that the endogenously produced NGF elicits biological changes similar to those of the exogenously delivered NGF. We suggest that glucocorticoids might regulate and coordinate cholinergic neuronal maturation by increasing the biosynthesis of NGF.