Mechanisms underlying rapid experience-dependent plasticity in the human visual cortex.

Visual deprivation induces a rapid increase in visual cortex excitability that may result in better consolidation of spatial memory in animals and in lower visual recognition thresholds in humans. gamma-Aminobutyric acid (GABA)ergic, N-methyl-d-aspartate (NMDA), and cholinergic receptors are thought to be involved in visual cortex plasticity in animal studies. Here, we used a pharmacological approach and found that lorazepam (which enhances GABA(A) receptor function by acting as a positive allosteric modulator), dextrometorphan (NMDA receptor antagonist), and scopolamine (muscarinic receptor antagonist) blocked rapid plastic changes associated with light deprivation. These findings suggest the involvement of GABA, NMDA, and cholinergic receptors in rapid experience-dependent plasticity in the human visual cortex.     

Mechanism underlying carbon tetrachloride-inhibited protein synthesis in liver

AIM: To study the mechanism underlying carbon tetrachloride (CCl4)-induced alterations of protein synthesis in liver. METHODS: Male Sprague-Dawley rats were given CCl4 (1 mL/100 g body weight) and 3H-leucine incorporation. Malondialdehyde (MDA) level in the liver, in vitro response of hepatocyte nuclei nucleotide triphosphatase (NTPase) to free radicals, and nuclear export of total mRNA with 3'-poly A+ were measured respectively. Survival response of HepG2 cells to CCl4 treatment was assessed by methyl thia...     

Rapid plasticity of binocular connections in developing monkey visual cortex (V1)

The basic sets of cortical connections are present at birth in the primate visual system. The maintenance and refinement of these innate connections are highly dependent on normal visual experience, and prolonged exposure to binocularly uncorrelated signals early in life severely disrupts the normal development of binocular functions. However, very little is known about how rapidly these changes in the functional organization of primate visual cortex emerge or what are the sequence and the nature of the abnormal neural events that occur immediately after experiencing binocular decorrelation. In this study, we investigated how brief periods of ocular misalignment (strabismus) at the height of the critical period alter the cortical circuits that support binocular vision. After only 3 days of optically imposed strabismus, there was a striking increase in the prevalence of V1 neurons that exhibited binocular suppression, i.e., binocular responses were weaker than monocular responses. However, the sensitivity of these neurons to interocular spatial phase disparity was not significantly altered. These contrasting results suggest that the first significant change in V1 caused by early binocular decorrelation is binocular suppression, and that this suppression originates at a site(s) beyond where binocular signals are initially combined.     

Experience-dependent functional plasticity and visual response selectivity of surviving subplate neurons in the mouse visual cortex

Subplate neurons are early-born cortical neurons that transiently form neural circuits during perinatal development and guide cortical maturation. Thereafter, most subplate neurons undergo cell death, while some survive and renew their target areas for synaptic connections. However, the functional properties of the surviving subplate neurons remain largely unknown. This study aimed to characterize the visual responses and experience-dependent functional plasticity of layer 6b (L6b) neurons, the remnants of subplate neurons, in the primary visual cortex (V1). Two-photon Ca²⁺ imaging was performed in V1 of awake juvenile mice. L6b neurons showed broader tunings for orientation, direction, and spatial frequency than did layer 2/3 (L2/3) and L6a neurons. In addition, L6b neurons showed lower matching of preferred orientation between the left and right eyes compared with other layers. Post hoc 3D immunohistochemistry confirmed that the majority of recorded L6b neurons expressed connective tissue growth factor (CTGF), a subplate neuron marker. Moreover, chronic two-photon imaging showed that L6b neurons exhibited ocular dominance (OD) plasticity by monocular deprivation during critical periods. The OD shift to the open eye depended on the response strength to the stimulation of the eye to be deprived before starting monocular deprivation. There were no significant differences in visual response selectivity prior to monocular deprivation between the OD changed and unchanged neuron groups, suggesting that OD plasticity can occur in L6b neurons showing any response features. In conclusion, our results provide strong evidence that surviving subplate neurons exhibit sensory responses and experience-dependent plasticity at a relatively late stage of cortical development.

The mammalian cerebral cortex consists of six layers, with distinct roles in information processing (1, 2). At the bottom of the neocortex, on the boundary between the gray matter and white matter, there is a thin sheet of neurons called layer 6b (L6b) (3). Layer 6b neurons are thought to be remnants of subplate neurons based on their location and cell-type marker expression (4). During prenatal and early postnatal periods, subplate neurons form transient neuronal circuits that play key roles in cortical maturation (5–7). In the embryonic cortex, subplate neurons form short-lived synapses with early immature neurons to regulate radial migration (8). During perinatal development, subplate neurons transiently receive inputs from ingrowing thalamic axons and innervate layer 4 (L4) to guide thalamic inputs to the eventual target, L4 (5, 6). Thus, the circuits formed by subplate neurons at the perinatal developmental stage are essential to establish basic neuronal circuits before starting experience-dependent refinements (5–7). Subsequently, subplate neurons largely disappear due to programmed cell death, but some survive and reside in L6b (5, 6). In the adult cortex, L6b neurons form neuronal circuits with local and long-distance neurons, which are different from those formed during early development (9–12). Therefore, surviving subplate neurons may acquire a role in information processing after remodeling of neuronal connections. A recent study using three-photon Ca²⁺ imaging demonstrated that L6b neurons show visual responses with broad orientation/direction tuning in the adult mouse primary visual cortex (V1) (13). However, comparable evidence for L6b response properties with other layer neurons in V1 is lacking (14–20). Moreover, L6b neurons have diverse morphology and molecular expression (21–24). Neurons born during subplate neurogenesis show the different expression patterns of subplate markers in postnatal L6b (4). However, the response properties in each subtype of L6b neurons remain unknown.The sensory responsiveness of cortical neurons is considerably refined by sensory experience relatively late in development, referred to as the critical period (25, 26). Previous studies have demonstrated that sensory activities before the onset of the critical period affect the arrangement of subplate neuron neurites in the barrel cortex and local subplate circuits in the auditory cortex (27, 28). However, there is no direct evidence that the sensory responses of surviving subplate neurons are modified by sensory experience during the critical period. If experience-dependent plasticity occurs in subplate neuron responses, they will contribute to the experience-dependent development of sensory functions and possibly to the functions in the mature cortex. Ocular dominance (OD) plasticity in V1 is a canonical model used to examine experience-dependent refinement of sensory responses (25, 26, 29, 30). If one eye is occluded for several days during the critical period, neurons in V1 lose their response to the deprived eye. OD plasticity is robustly preserved across species and cell types. Therefore, OD plasticity is suitable for evaluating experience-dependent plasticity in L6b neurons.This study aimed to characterize the visual responses and OD plasticity of L6b neurons in V1. Toward this goal, two-photon Ca²⁺ imaging was performed in awake juvenile mice, followed by 3D immunohistochemistry with a subplate neuronal marker, connective tissue growth factor (CTGF) (4, 31). L6b neurons showed broader tuning to visual stimuli and lower binocular matching of orientation preference than did layer 2/3 (L2/3) and L6a neurons. Chronic two-photon imaging revealed significant OD plasticity in individual L6b neurons during the critical period. Our results provide strong evidence that L6b neurons, presumed to be subplate neuron remnants, exhibit sensory responses and experience-dependent functional plasticity at a relatively late stage of cortical development.     

Steroidogenesis by the immature rhesus monkey ovary in vitro

Primates are believed to have a low level of ovarian steroidogenic activity during prepubertal development. In order to study the rate limiting factors associated with the low level of steroidogenesis, ovaries from prepubertal rhesus monkeys were quartered and incubated for 48 h at 37 C in minimum essential medium. These ovaries secreted 687 +/- 347 pg estradiol/mg ovary and 299 +/- 35 pg progesterone/mg ovary during 48 h of incubation. The addition of 100 ng luteinizing hormone (LH) or 1 mM dibutyryl (Bu)2 cAMP failed to increase significantly estradiol or progesterone secretion. Furthermore, the addition of either progesterone or androstenedione failed to augment estradiol secretion. The presence of either LH or (Bu)2 cAMP with the steroidal substrates also failed to augment estradiol secretion. In contrast, the addition of (Bu)2 cAMP with lipoprotein-derived cholesterol significantly stimulated a two-fold increase in progesterone secretion. The presence of LH in the lipoprotein-supplemented medium failed to augment progesterone secretion. These results suggest that prepubertal monkey ovaries lack the ability to respond to LH, probably due to a lack of gonadotropin receptors or failure of the receptor to stimulate cAMP synthesis. Furthermore, the failure of progesterone and androstenedione to augment estradiol secretion suggests that some cellular components needed to induce aromatase activity are not functional in the prepubertal primate ovary.     

Steroidogenesis-inducing protein promotes deoxyribonucleic acid synthesis in Leydig cells from immature rats.

A protein [steroidogenesis-inducing protein (SIP)] has been isolated from human ovarian follicular fluid and shown previously to stimulate steroidogenesis in Leydig cells, adrenal cells, and early luteal cells. Since proteins and peptides known to regulate steroidogenesis, such as gonadotropins and growth factors, also influence the growth of gonadal cells, the present study was designed to assess the effects of SIP on the synthesis of DNA by Leydig cells in vitro. Leydig cells were isolated from 10- and 20-day-old rats and cultured in serum-free medium for 48 h. The cells were then treated with the test materials for 18 h. Incorporation of [3H]thymidine into DNA was measured during the final 4 h of the culture. SIP significantly stimulated DNA synthesis in Leydig cells in a dose- and time-dependent manner, and the response to SIP was higher than that obtained with maximal concentrations of LH/hCG. The stimulatory effects of SIP were significantly enhanced when the cell cultures were preincubated in the presence of low levels of ovine LH (2 ng/ml). Cultures treated with SIP, followed by incubation with [3H]thymidine, contained 22 times as many labeled cells as control cultures, as assessed by autoradiography. The cells that were labeled were identified morphologically as Leydig cells. Insulin/insulin-like growth factor-I and/or transforming growth factor-alpha alone stimulated DNA synthesis and enhanced the effects of SIP on DNA synthesis. Dramatic changes in the morphology of cultured Leydig cells treated with SIP were observed; cells became flattened and developed extended projections which connected adjacent cells. LH/hCG, insulin, and transforming growth factor-alpha did not induce effects comparable to those of SIP on the morphology of Leydig cells. The effects of SIP on the synthesis of DNA and the morphology of Leydig cells were blocked in the presence of cycloheximide. It is concluded that SIP not only stimulates steroid production in Leydig cells, as shown previously, but also stimulates DNA synthesis and induces morphological changes in these cells. The latter properties of SIP combined with the magnitude of the responses elicited identify SIP as a unique gonadal protein.     

Estrogen and androgen regulation of protein synthesis by the immature rabbit epididymis

To obtain evidence of a physiological role for androgens and estrogens in the regulation of the epididymis of sexually immature rabbits, the effects of these hormones on [35S] methionine incorporation into epididymal proteins in vitro were examined. Two-dimensional polyacrylamide gel electrophoresis revealed that short term incubation with estradiol changed the patterns of radiolabeled proteins detected in tissue homogenates of epididymal segments from castrated rabbits compared to those in segments from castrated rabbits that were not exposed to exogenous estradiol. Most of the changes seen in corpus tissue affected proteins with a wide range of pI values and relatively high mol wt (greater than 40K). The effects on caput and cauda tissue proteins were seen over a wide pH and mol wt range. Castration abolished many of the regional differences in protein synthesis; these were restored by incubation with estradiol. Testosterone had little effect on the synthesis of tissue proteins, except for stimulation of the synthesis of a single protein (17K; pI 5.1) in all three segments and stimulation of a small group of proteins (less than 14K; pI 7.0-7.2) in the corpus. Estradiol had little effect on proteins secreted by epididymal segments. Testosterone, however, stimulated the synthesis of a number of unique proteins secreted by the caput and corpus and resulted in a pattern of radiolabeled proteins similar to that obtained with intact animals. Additional secretory proteins could be stimulated in caput, but not corpus, tissue minces from intact rabbits by exogenous testosterone. No androgen-specific synthesis of secretory proteins was detected in the cauda of either castrated or intact rabbits. Estradiol affected the synthesis of both secreted and tissue proteins in terms of influencing which epididymal segment was most active at incorporating [35S]methionine into radiolabeled proteins and which was least active. Testosterone had a similar influence on secreted proteins, but did not have any analogous effect on tissue proteins. These results indicate that testosterone and estradiol influence the synthesis of proteins by the immature rabbit epididymis and that both may, therefore, be important physiological regulators of epididymal development and/or function.     

Effects of cholecystokinin and hydrocortisone on DNA and protein synthesis in immature rat pancreas

To define the developmental pattern of the trophic effects of cholecystokinin octapeptide (CCK-8) and hydrocortisone on immature rat pancreas, we injected newborn rats, rats aged 4, 7, 11, 18, and 25 days and 3 months, and adult rats with CCK (5 and 10 micrograms/kg) in gelatin and hydrocortisone (10 mg/kg) for 3 days. Animals were killed, the pancreata were removed, and the concentrations of DNA and protein were measured and DNA and protein synthesis rates determined by incorporation of [3H]thymidine and [14C]leucine, respectively. These values were compared with those of saline-injected controls. DNA concentration was significantly increased over control at ages 2 days to adult by hydrocortisone and by CCK (10 micrograms/kg) in the adult. Protein concentration was increased on days 3-14 by hydrocortisone. DNA synthesis was increased by CCK and decreased by hydrocortisone at 3 months and adult. Protein synthesis was decreased by hydrocortisone at ages 3-14 days. Thus, each agent has its own developmental pattern with age on the rat pancreas.     

Mechanisms underlying arginine vasopressin-induced relaxation in monkey isolated coronary arteries.

OBJECTIVE: The present study was undertaken to examine whether arginine vasopressin (AVP) relaxes primate coronary artery and to analyse the mechanisms of its action in reference to endothelial nitric oxide and AVP receptor subtype. METHODS: Isometrical tension responses to AVP and desmopressin were recorded in isolated monkey coronary arteries. RESULTS: AVP (10(-9) to 10(-7) mol/l) induced a concentration-related relaxation; endothelium-denudation abolished the response. Treatment with N(G)-nitro-L-arginine, but not the D-enantiomer, abolished the endothelium-dependent relaxation, which was restored by L-arginine. Treatment with SR49059 and [Pmp1,Tyr(Me)2]-Arg8-vasopressin, selective inhibitors of V1 receptor subtype, attenuated the relaxant response to AVP, whereas the relaxation induced by sodium nitroprusside was not affected by SR49059. Desmopressin, a V2 receptor agonist, up to 10(-8) mol/l did not elicit relaxation. CONCLUSIONS: It is concluded that AVP-induced monkey coronary arterial relaxation is mediated via nitric oxide synthesized from L-arginine in association with stimulation of V1 receptor subtypes in the endothelium.     

A functional bone morphogenetic protein system in the ovary

Bone morphogenetic proteins (BMPs) comprise a large group of polypeptides in the transforming growth factor beta superfamily with essential physiological functions in morphogenesis and organogenesis in both vertebrates and invertebrates. At present, the role of BMPs in the reproductive system of any species is poorly understood. Here, we have established the existence of a functional BMP system in the ovary, replete with ligand, receptor, and novel cellular functions. In situ hybridization histochemistry identified strong mRNA labeling for BMP-4 and -7 in the theca cells and BMP receptor types IA, IB, and II in the granulosa cells and oocytes of most follicles in ovaries of normal cycling rats. To explore the paracrine function of this BMP system, we examined the effects of recombinant BMP-4 and -7 on FSH (follicle-stimulating hormone)-induced rat granulosa cytodifferentiation in serum-free medium. Both BMP-4 and -7 regulated FSH action in positive and negative ways. Specifically, physiological concentrations of the BMPs enhanced and attenuated the stimulatory action of FSH on estradiol and progesterone production, respectively. These effects were dose- and time-dependent. Furthermore, the BMPs increased granulosa cell sensitivity to FSH. Thus, BMPs have now been identified as molecules that differentially regulate FSH-dependent estradiol and progesterone production in a way that reflects steroidogenesis during the normal estrous cycle. As such, it can be hypothesized that BMPs might be the long-sought "luteinization inhibitor" in Graafian follicles during their growth and development.     

Spontaneous corticospinal axonal plasticity and functional recovery after adult central nervous system injury

Although it is believed that little recovery occurs after adult mammalian spinal cord injury, in fact significant spontaneous functional improvement commonly occurs after spinal cord injury in humans. To investigate potential mechanisms underlying spontaneous recovery, lesions of defined components of the corticospinal motor pathway were made in adult rats in the rostral cervical spinal cord or caudal medulla. Following complete lesions of the dorsal corticospinal motor pathway, which contains more than 95% of all corticospinal axons, spontaneous sprouting from the ventral corticospinal tract occurred onto medial motoneuron pools in the cervical spinal cord; this sprouting was paralleled by functional recovery. Combined lesions of both dorsal and ventral corticospinal tract components eliminated sprouting and functional recovery. In addition, functional recovery was also abolished if dorsal corticospinal tract lesions were followed 5 weeks later by ventral corticospinal tract lesions. We found extensive spontaneous structural plasticity as a mechanism correlating with functional recovery in motor systems in the adult central nervous system. Experimental enhancement of spontaneous plasticity may be useful to promote further recovery after adult central nervous system injury.     

Delayed plasticity of inhibitory neurons in developing visual cortex

During postnatal development, altered sensory experience triggers the rapid reorganization of neuronal responses and connections in sensory neocortex. This experience-dependent plasticity is disrupted by reductions of intracortical inhibition. Little is known about how the responses of inhibitory cells themselves change during plasticity. We investigated the time course of inhibitory cell plasticity in mouse primary visual cortex by using functional two-photon microscopy with single-cell resolution and genetic identification of cell type. Initially, local inhibitory and excitatory cells had similar binocular visual response properties, both favoring the contralateral eye. After 2 days of monocular visual deprivation, excitatory cell responses shifted to favor the open eye, whereas inhibitory cells continued to respond more strongly to the deprived eye. By 4 days of deprivation, inhibitory cell responses shifted to match the faster changes in their excitatory counterparts. These findings reveal a dramatic delay in inhibitory cell plasticity. A minimal linear model reveals that the delay in inhibitory cell plasticity potently accelerates Hebbian plasticity in neighboring excitatory neurons. These findings offer a network-level explanation as to how inhibition regulates the experience-dependent plasticity of neocortex.     

Statistical learning of visual transitions in monkey inferotemporal cortex

One of the most fundamental functions of the brain is to predict upcoming events on the basis of the recent past. A closely related function is to signal when a prediction has been violated. The identity of the brain regions that mediate these functions is not known. We set out to determine whether they are implemented at the level of single neurons in the visual system. We gave monkeys prolonged exposure to pairs of images presented in fixed sequence so that each leading image became a strong predictor for the corresponding trailing image. We then monitored the responses of neurons in the inferotemporal cortex to image sequences that obeyed or violated the transitional rules imposed during training. Inferotemporal neurons exhibited a transitional surprise effect, responding much more strongly to unpredicted transitions than to predicted transitions. Thus, neurons even in the visual system make experience-based predictions and react when they fail.     

Synapse elimination accompanies functional plasticity in hippocampal neurons

A critical component of nervous system development is synapse elimination during early postnatal life, a process known to depend on neuronal activity. Changes in synaptic strength in the form of long-term potentiation (LTP) and long-term depression (LTD) correlate with dendritic spine enlargement or shrinkage, respectively, but whether LTD can lead to an actual separation of the synaptic structures when the spine shrinks or is lost remains unknown. Here, we addressed this issue by using concurrent imaging and electrophysiological recording of live synapses. Slices of rat hippocampus were cultured on multielectrode arrays, and the neurons were labeled with genes encoding red or green fluorescent proteins to visualize presynaptic and postsynaptic neuronal processes, respectively. LTD-inducing stimulation led to a reduction in the synaptic green and red colocalization, and, in many cases, it induced a complete separation of the presynaptic bouton from the dendritic spine. This type of synapse loss was associated with smaller initial spine size and greater synaptic depression but not spine shrinkage during LTD. All cases of synapse separation were observed without an accompanying loss of the spine during this period. We suggest that repeated low-frequency stimulation simultaneous with LTD induction is capable of restructuring synaptic contacts. Future work with this model will be able to provide critical insight into the molecular mechanisms of activity- and experience-dependent refinement of brain circuitry during development.     

A parieto-frontal network for visual numerical information in the monkey

Recent electrophysiological studies in monkeys have implicated the prefrontal cortex (PFC) and posterior parietal cortex (PPC) in numerical judgments. The functional organization and respective contributions of these (and other) cortical areas, however, are unknown; their neural activity during numerical judgments has not been directly compared. We surveyed activity in the PPC and the anterior inferior temporal cortex while monkeys performed a visual numerosity judgment task and compared it with a population of PFC neurons. In the PPC, the proportion of numerosity-selective neurons was highest in the fundus of the intraparietal sulcus; only few numerosity-selective neurons were found in other PPC areas or the anterior inferior temporal cortex. Further, neurons in the fundus of the intraparietal sulcus responded and conveyed numerosity earlier than PFC neurons, suggesting that numerosity information flows from the PPC to the lateral PFC. This finding suggests a parieto-frontal network for numerosity in monkeys and establishes homologies between the monkey and human brain.     

Local field potential reflects perceptual suppression in monkey visual cortex

Neurophysiological and functional imaging experiments remain in apparent disagreement on the role played by the earliest stages of the visual cortex in supporting a visual percept. Here, we report electrophysiological findings that shed light on this issue. We monitored neural activity in the visual cortex of monkeys as they reported their perception of a high-contrast visual stimulus that was induced to vanish completely from perception on a subset of trials. We found that the spiking of neurons in cortical areas V1 and V2 was uncorrelated with the perceptual visibility of the target, whereas that in area V4 showed significant perception-related changes. In contrast, power changes in the lower frequency bands (particularly 9-30 Hz) of the local field potential (LFP), collected on the same trials, showed consistent and sustained perceptual modulation in all three areas. In addition, for the gamma frequency range (30-50 Hz), the responses during perceptual suppression of the target were correlated significantly with the responses to its physical removal in all areas, although the modulation magnitude was considerably higher in area V4 than in V1 and V2. These results, taken together, suggest that low-frequency LFP power in early cortical processing is more closely related to the representation of stimulus visibility than is spiking or higher frequency LFP activity.