Differential brain expression pattern of Sez6 alternative splicing isoform with deleted transmembrane domain.

Seizure-related gene 6 (Sez6) is a transmembrane protein specifically localized on neuronal dendrites and responsible for dendritic branching and synapse formation. Alternative splicing produces three isoforms of Sez6 mRNAs: the dominant isoform encodes a transmembrane-type protein, whereas the two recessive isoforms encode transmembrane and secretory proteins. In the present study, to clarify the differential functions of these isoforms, the expression patterns resulting from Sez6 splicing isoforms were investigated in the mouse brain as well as in cultured neurons. The whole brains were sliced into coronal sections of 1-mm thickness, and brain areas were punched out from these coronal sections. The mRNA levels of each Sez6 isoform in the prefrontal cortex, cingulate cortex, striatum, hippocampus, and amygdala, where Sez6 expression has been reported previously, were analyzed using a qPCR technique, and primary neurons cultured under different treatment conditions were assessed in terms of increased Sez6 gene expression. Our results show that the splicing patterns of Sez6 were modulated in a brain area-specific manner. In particular, the striatum showed a characteristic splicing pattern of recessive isoforms. Moreover, neuronal activation by convulsant drug stimulation increased recessive isoforms like the dominant isoform in cultured cortical neurons at 5 or 10 days in vitro. In conclusion, alternative splicing of Sez6, as well as of other proteins expressed specifically in the brain, results in brain area-specific expression patterns. Furthermore, the alternative splicing of Sez6 may be modulated by drugs that elevate Sez6 gene expression.

Separation from a bonded partner alters neural response to inflammatory pain in monogamous rodents.

Pain experience is known to be modified by social factors, but the brain mechanisms remain unspecified. We recently established an animal model of social stress-induced hyperalgesia (SSIH) using a socially monogamous rodent, the prairie vole, in which males separated from their female partners (loss males) became anxious and displayed exacerbated inflammatory pain behaviors compared to males with partners (paired males). In the present study, to explore the neural pathways involved in SSIH, a difference in neuronal activation in pain-related brain regions, or "pain matrix", during inflammatory pain between paired and loss males was detected using Fos immunoreactivity (Fos-ir). Males were paired with a female and pair bonding was confirmed in all subjects using a partner preference test. During formalin-induced inflammatory pain, both paired and loss males showed a significant induction of Fos-ir throughout the analyzed pain matrix components compared to basal condition (without injection), and no group differences in immunoreactivity were found among the injected males in many brain regions. However, the loss males had significantly lower Fos-ir following inflammatory pain in the medial prefrontal cortex and nucleus accumbens shell than the paired males, even though base Fos-ir levels were comparable between groups. Notably, both regions with different Fos-ir are major components of the dopamine and oxytocin systems, which play critical roles in both pair bonding and pain regulation. The present results suggest the possibility that pain exacerbation by social stress emerges through alteration of signaling in social brain circuitry.

Oxytocin receptor antagonist reverses the blunting effect of pair bonding on fear learning in monogamous prairie voles.

Social relationships among spouses, family members, and friends are known to affect physical and mental health. In particular, long-lasting bonds between socio-sexual partners have profound effects on cognitive, social, emotional, and physical well-being. We have previously reported that pair bonding in monogamous prairie voles (Microtus ochrogaster) is prevented by a single prolonged stress (SPS) paradigm, which causes behavioral and endocrine symptoms resembling post-traumatic stress disorder (PTSD) patients in rats (Arai et al., 2016). Since fear memory function is crucial for anxiety-related disorders such as PTSD, we investigated the effects of pair bonding on fear learning in prairie voles. We applied an SPS paradigm to male prairie voles after the cohabitation with a male (cage-mate group) or female (pair-bonded group). The cage-mate group, but not the pair-bonded group, showed enhanced fear response in a contextual fear conditioning test following the SPS treatment. Immunohistochemical analyses revealed that cFos-positive cells in the central amygdala were increased in the pair-bonded group after the contextual fear conditioning test and that oxytocin immunoreactivity in the paraventricular nucleus of the hypothalamus was significantly higher in the pair-bonded group than the cage-mate group. This pair-bonding dependent blunting of fear memory response was confirmed by a passive avoidance test, another fear-based learning test. Interestingly, intracerebroventricular injection of an oxytocin receptor antagonist 30 min before the passive avoidance test blocked the blunting effect of pair bonding on fear learning. Thus, pair bonding between socio-sexual partners results in social buffering in the absence of the partner, blunting fear learning, which may be mediated by oxytocin signaling.

Effects of post-weaning social isolation on social behaviors and oxytocinergic activity in male and female rats.

AIMS: Post-weaning social deprivation is known to induce behavioral and neuronal alterations associated with anxiety and stress responses in adulthood. However, the effects of social deprivation on the development of sociability are poorly understood. We examined the effects of social deprivation on subsequent social behaviors and oxytocinergic activity using socially-isolated (approximately two months post-weaning) male and female rats. MAIN METHODS: The behaviors were analyzed using a social preference test and a social approach test. Immunohistochemical investigations were conducted in the paraventricular nucleus (PVN) and supraoptic nucleus (SON) to examine the effects of social isolation on oxytocinergic activity in these regions. Oxytocinergic activity was measured by quantifying the number of oxytocin neurons expressing Fos following exposure to a novel conspecific. In all of the experiments of this study, ovariectomized females were used for social stimuli. KEY FINDINGS: The behavioral results show that isolation-reared females, but not males, displayed impaired social preference and decreased social approach towards ovariectomized females, compared with the pair-reared group, suggesting low priority of processing social versus non-social stimuli and low motivation for contact with a stranger, respectively. The immunohistochemical results show that social isolation decreased both the number and the ratio of Fos-positive cells in oxytocin neurons in the PVN in females, but not in males, following exposure to ovariectomized females. In the SON, the Fos-positive ratio was decreased in isolation-reared females, but not in males, compared with the pair-reared group. SIGNIFICANCE: Post-weaning social isolation changed social behaviors and oxytocinergic activity in female rats, suggesting that in female rats post-weaning social experiences contribute to the development of sociability. These findings could impact the treatment of social dysfunction in humans.

Stimulation of brain nicotinic acetylcholine receptors activates adrenomedullary outflow via brain inducible NO synthase-mediated S-nitrosylation.

BACKGROUND AND PURPOSE: We have demonstrated that i.c.v.-administered (±)-epibatidine, a nicotinic ACh receptor (nAChR) agonist, induced secretion of noradrenaline and adrenaline (catecholamines) from the rat adrenal medulla with dihydro-ß-erythroidin (an α4ß2 nAChR antagonist)-sensitive brain mechanisms. Here, we examined central mechanisms for the (±)-epibatidine-induced responses, focusing on brain NOS and NO-mediated mechanisms, soluble GC (sGC) and protein S-nitrosylation (a posttranslational modification of protein cysteine thiol groups), in urethane-anaesthetized (1.0 g·kg-1 , i.p.) male Wistar rats. EXPERIMENTAL APPROACH: (±)-Epibatidine was i.c.v. treated after i.c.v. pretreatment with each inhibitor described below. Then, plasma catecholamines were measured electrochemically after HPLC. Immunoreactivity of S-nitrosylated cysteine (SNO-Cys) in α4 nAChR subunit (α4)-positive spinally projecting neurones in the rat hypothalamic paraventricular nucleus (PVN, a regulatory centre of adrenomedullary outflow) after i.c.v. (±)-epibatidine administration was also investigated. KEY RESULTS: (±)-Epibatidine-induced elevation of plasma catecholamines was significantly attenuated by L-NAME (non-selective NOS inhibitor), carboxy-PTIO (NO scavenger), BYK191023 [selective inducible NOS (iNOS) inhibitor] and dithiothreitol (thiol-reducing reagent), but not by 3-bromo-7-nitroindazole (selective neuronal NOS inhibitor) or ODQ (sGC inhibitor). (±)-Epibatidine increased the number of spinally projecting PVN neurones with α4- and SNO-Cys-immunoreactivities, and this increment was reduced by BYK191023. CONCLUSIONS AND IMPLICATIONS: Stimulation of brain nAChRs can induce elevation of plasma catecholamines through brain iNOS-derived NO-mediated protein S-nitrosylation in rats. Therefore, brain nAChRs (at least α4ß2 subtype) and NO might be useful targets for alleviation of catecholamines overflow induced by smoking.

Fasting or systemic des-acyl ghrelin administration to rats facilitates thermoregulatory behavior in a cold environment.

Fasted rats place their tails underneath their body trunks in the cold (tail-hiding behavior), which is a thermoregulatory behavior. The aim of the present study was to investigate the effect of fasting and des-acyl ghrelin, a hormone related to fasting, on tail-hiding behavior and neural activity in the cold. Wistar rats were divided into 'fed', '42-h fasting' and des-acyl ghrelin groups. The rats received an intraperitoneal saline or 30-µg des-acyl ghrelin injection, and were then exposed to 27 °C or 15 °C for 2-h with continuous body temperature (Tb), tail skin temperature (Ttail), and tail-hiding behavior measurements. cFos immunoreactive (cFos-IR) cells in the insula, secondary somatosensory cortex, medial preoptic nucleus, parastrial nucleus, amygdala, and lateral parabrachial nucleus were counted in four segments: seg1, 2, 3, and 4 (bregma -0.36, -1.44, -2.64, and -9.00 mm), respectively. At 15 °C, Tb and Ttail were lower in the 42-h fasting group than in the fed and des-acyl ghrelin groups, and the duration of tail-hiding behavior was longer in the 42-h fasting and des-acyl ghrelin groups than in the fed group. The onset of tail-hiding behavior more advanced in the des-acyl ghrelin group than in the fed group at 15 °C. Only at the insula in seg3 at 15 °C, the number of cFos-IR cells was greater in the 42-h fasting group than in the fed group. Both the 42-h fasting and des-acyl ghrelin groups might modulate the tail-hiding behavior of rats in a cold, and a part of the insula might be involved this response during fasting.

Partner Loss in Monogamous Rodents: Modulation of Pain and Emotional Behavior in Male Prairie Voles.

OBJECTIVE: Pain is modulated by psychosocial factors, and social stress-induced hyperalgesia is a common clinical symptom in pain disorders. To provide a new animal model for studying social modulation of pain, we examined pain behaviors in monogamous prairie voles experiencing partner loss. METHODS: After cohabitation with novel females, males (n = 79) were divided into two groups on the basis of preference test scores. Half of the males of each group were separated from their partner (loss group), whereas the other half remained paired (paired group). Thus, males from both groups experienced social isolation. Open field tests, plantar tests, and formalin tests were then conducted on males to assess anxiety and pain-related behaviors. RESULTS: Loss males showing partner preferences (n = 20) displayed a significant increase in anxiety-related behavior in the open-field test (central area/total distance: 13.65% [1.58%] for paired versus 6.45% [0.87%] for loss; p < .001), a low threshold of thermal stimulus in the plantar test (withdrawal latencies: 9.69 [0.98] seconds for paired versus 6.15 [0.75] seconds for loss; p = .037), and exacerbated pain behaviors in the formalin test (total number of lifts: 40.33 [4.46] for paired versus 54.42 [1.91] for loss; p = .042) as compared with paired males (n = 20). Thermal thresholds in the plantar test significantly correlated with anxiety-related behavior in the open-field test (r = 0.64). No such differences were observed in the males that did not display partner preferences (r = 0.15). CONCLUSIONS: Results indicate that social bonds and their disruption, but not social housing without bonding followed by isolation, modulate pain and emotion in male prairie voles. The prairie vole is a useful model for exploring the neural mechanisms by which social relationships contribute to pain and nociceptive processing in humans.

Systemic estradiol administration to ovariectomized rats facilitates thermoregulatory behavior in a cold environment.

Rats place their tails underneath their bodies in the cold (tail-hiding behavior), which is a behavioral indicator of thermoregulation. The aim of the present study was to elucidate the effect of estradiol (E2) on tail-hiding behavior and neural activity assessed by immunohistochemistry. Ovariectomized rats were implanted with a silastic tube with or without E2 underneath the dorsal skin (E2(-) and E2(+) groups), and exposed to 27°C, 16°C, and 10°C for 2h with continuous body temperature (Tb), tail skin temperature (Ttail), and behavioral measurements. cFos immunoreactive (cFos-IR) cells in the insula, secondary somatosensory cortex, medial preoptic nucleus, parastrial nucleus, amygdala, and lateral parabrachial nucleus were counted. Tb and Ttail were not different between the E2(-) and E2(+) groups. At 16°C, the duration and the onset of tail-hiding behavior in the E2(+) group were greater than that in the E2(-) group. The number of cFos-IR cells in the insula of the E2(-) group was greater than that of the E2(+) group in rats kept at 16°C. E2 might modulate tail-hiding behavior of female rats at 16°C, and the insula may be involved in the response.

Effects of aging on stress-related responses of serotonergic neurons in the dorsal raphe nucleus of male rats.

Responses to various stressors in the brain change with age. However, little is known about the neural mechanisms underlying age-dependent changes in stress responses. It is known that serotonin, a stress-related transmitter, is closely related with the regulation of stress responses in the brain and that serotonergic function is modulated by various factors, including estrogen, in both sexes. In the present study, to elucidate the effects of aging on stress responses in serotonergic neurons, we examined the expression levels of tryptophan hydroxylase (TPH; a marker of serotonergic neurons) in the dorsal, ventral and lateral parts of the dorsal raphe nucleus (DRN) in young and old intact male rats. In young males, repeated restraint stress significantly increased the number of TPH-positive cells in all subdivisions of the DRN. In contrast, the stress-induced increase in TPH expression was only observed in the ventral part of the DRN in old males. Pretreatment with an estrogen receptor ß antagonist had no effect on the number of TPH-positive cells in the dorsal and lateral DRN in young stressed males, whereas the antagonist decreased the number of TPH-positive cells in all DRN subdivisions in old stressed males. Our results suggest that the effects of repeated stress exposure on the expression of TPH in serotonergic neurons in the DRN change with age and that estrogenic effects via estrogen receptor ß on TPH expression in stressed old males differ from those in young males.

A single prolonged stress paradigm produces enduring impairments in social bonding in monogamous prairie voles.

Traumatic events such as natural disasters, violent crimes, tragic accidents, and war, can have devastating impacts on social relationships, including marital partnerships. We developed a single prolonged stress (SPS) paradigm, which consisted of restraint, forced swimming, and ether anesthesia, to establish an animal model relevant to post-traumatic stress disorder. We applied a SPS paradigm to a monogamous rodent, the prairie vole (Microtus ochrogaster) in order to determine whether a traumatic event affects the establishment of pair bonds. We did not detect effects of the SPS treatment on anhedonic or anxiety-like behavior. Sham-treated male voles huddled with their partner females, following a 6day cohabitation, for a longer duration than with a novel female, indicative of a pair bond. In contrast, SPS-treated voles indiscriminately huddled with the novel and partner females. Interestingly, the impairment of pair bonding was rescued by oral administration of paroxetine, a selective serotonin reuptake inhibitor (SSRI), after the SPS treatment. Immunohistochemical analyses revealed that oxytocin immunoreactivity (IR) was significantly decreased in the supraoptic nucleus (SON), but not in the paraventricular nucleus (PVN), 7days after SPS treatment, and recovered 14days after SPS treatment. After the presentation of a partner female, oxytocin neurons labeled with Fos IR was significantly increased in SPS-treated voles compared with sham-treated voles regardless of paroxetine administration. Our results suggest that traumatic events disturb the formation of pair bond possibly through an interaction with the serotonergic system, and that SSRIs are candidates for the treatment of social problems caused by traumatic events. Further, a vole SPS model may be useful for understanding mechanisms underlying the impairment of social bonding by traumatic events.

Possible inhibitory role of endogenous 2-arachidonoylglycerol as an endocannabinoid in (±)-epibatidine-induced activation of central adrenomedullary outflow in the rat.

We previously reported that intracerebroventricularly (i.c.v.) administered (±)-epibatidine (1, 5 or 10 nmol/animal), a nicotinic acetylcholine receptor agonist, dose-dependently induced secretion of noradrenaline and adrenaline (catecholamines) from the rat adrenal medulla by brain diacylglycerol lipase- (DGL), monoacylglycerol lipase- (MGL) and cyclooxygenase-mediated mechanisms. Diacylglycerol is hydrolyzed by DGL into 2-arachidonoylglycerol (2-AG), which is further hydrolyzed by MGL to arachidonic acid (AA), a cyclooxygenase substrate. These findings suggest that brain 2-AG-derived AA is involved in the (±)-epibatidine-induced response. This AA precursor 2-AG is also a major brain endocannabinoid, which inhibits synaptic transmission through presynaptic cannabinoid CB1 receptors. Released 2-AG into the synaptic cleft is rapidly inactivated by cellular uptake. Here, we examined a role of brain 2-AG as an endocannabinoid in the (±)-epibatidine-induced activation of central adrenomedullary outflow using anesthetized male Wistar rats. In central presence of AM251 (CB1 antagonist) (90 and 180 nmol/animal, i.c.v.), (±)-epibatidine elevated plasma catecholamines even at an ineffective dose (1 nmol/animal, i.c.v.). Central pretreatment with ACEA (CB1 agonist) (0.7 and 1.4 µmol/animal, i.c.v.), 2-AG ether (stable 2-AG analog for MGL) (0.5 and 1.0 µmol/animal, i.c.v.) or AM404 (endocannabinoid uptake inhibitor) (80 and 250 nmol/animal, i.c.v.) significantly reduced an effective dose of (±)-epibatidine- (5 nmol/animal, i.c.v.) induced elevation of plasma catecholamines, and AM251 (90 and 180 nmol/animal, i.c.v.) centrally abolished the reduction induced by 2-AG ether (1.0 µmol/animal, i.c.v.) or AM404 (250 nmol/animal, i.c.v.). Immunohistochemical studies demonstrated that (±)-epibatidine (10 nmol/animal, i.c.v.) activated DGLα-positive spinally projecting neurons in the hypothalamic paraventricular nucleus, a control center of central adrenomedullary system. These results suggest a possibility that a brain endocannabinoid, probably 2-AG, plays an inhibitory role in (±)-epibatidine-induced activation of central adrenomedullary outflow through brain CB1 receptors in the rat.

Mental retardation-related protease, motopsin (prss12), binds to the BRICHOS domain of the integral membrane protein 2a.

Motopsin (prss12), a mosaic serine protease secreted by neuronal cells, is believed to be important for cognitive function, as the loss of its function causes severe nonsyndromic mental retardation. To understand the molecular role of motopsin, we identified the integral membrane protein 2a (Itm2a) as a motopsin-interacting protein using a yeast two-hybrid system. A pull-down assay showed that the BRICHOS domain of Itm2a was essential for this interaction. Motopsin and Itm2a co-localized in COS cells and in cultured neurons when transiently expressed in these cells. Both proteins were co-immunoprecipitated from lysates of these transfected COS cells. Itm2a was strongly detected in a brain lysate prepared between postnatal day 0 and 10, during which period motopsin protein was also enriched in the brain. Immunohistochemistry detected Itm2a as patchy spots along endothelial cells of brain capillaries (which also expressed myosin II regulatory light chain [RLC]), and on glial fibrillary acidic protein (GFAP)-positive processes in the developing cerebral cortex. The data raise the possibility that secreted motopsin interacts with endothelial cells in the developing brain.

Estrogen-dependent changes in estrogen receptor-ß mRNA expression in middle-aged female rat brain.

During aging, estrogen production and circulating levels of estrogen are markedly decreased in females. Although several differences exist in the process of reproductive aging between women and female rats, the results of many studies suggest that the female rat, especially the middle-aged or aged ovariectomized female, is an important animal model of hormone loss in women. In target tissues including the brain, the actions of estrogen are mediated mainly via the alpha and beta subtypes of the estrogen receptor (ER-α and ER-ß). Estrogen treatment is known to change the expression of ER-α mRNA and protein in specific regions of the brain in middle-aged female rodents. In contrast, we do not know if estrogen regulates the expression of ER-ß in the brain at this stage of life. In the present study, we performed in situ hybridization on brain sections of ovariectomized and estrogen-treated middle-aged female rats to reveal the effects of estrogen on the expression of ER-ß throughout the brain. Our results showed that estrogen treatment decreased the number of ER-ß mRNA-positive cells in the mitral cell and external plexiform layers of the olfactory bulb, central amygdaloid nucleus, medial geniculate nucleus, posterior hypothalamic nucleus, suprachiasmatic nucleus, and reticular part of the substantia nigra. As compared to the results of previous studies of young females, our data revealed that the regions in which expression of ER-ß mRNA expression is affected by estrogen differ in middle age. These results suggest that the effects of estrogen on ER-ß expression change with age.

A mental retardation gene, motopsin/prss12, modulates cell morphology by interaction with seizure-related gene 6.

A serine protease, motopsin (prss12), plays a significant role in cognitive function and the development of the brain, since the loss of motopsin function causes severe mental retardation in humans and enhances social behavior in mice. Motopsin is activity-dependently secreted from neuronal cells, is captured around the synaptic cleft, and cleaves a proteoglycan, agrin. The multi-domain structure of motopsin, consisting of a signal peptide, a proline-rich domain, a kringle domain, three scavenger receptor cysteine-rich domains, and a protease domain at the C-terminal, suggests the interaction with other molecules through these domains. To identify a protein interacting with motopsin, we performed yeast two-hybrid screening and found that seizure-related gene 6 (sez-6), a transmembrane protein on the plasma membrane of neuronal cells, bound to the proline-rich/kringle domain of motopsin. Pull-down and immunoprecipitation analyses indicated the interaction between these proteins. Immunocytochemical and immunohistochemical analyses suggested the co-localization of motopsin and sez-6 at neuronal cells in the developmental mouse brain and at motor neurons in the anterior horn of human spinal cords. Transient expression of motopsin in neuro2a cells increased the number and length of neurites as well as the level of neurite branching. Interestingly, co-expression of sez-6 with motopsin restored the effect of motopsin at the basal level, while sez-6 expression alone showed no effects on cell morphology. Our results suggest that the interaction of motopsin and sez-6 modulates the neuronal cell morphology.

The distribution of the seizure-related gene 6 (Sez-6) protein during postnatal development of the mouse forebrain suggests multiple functions for this protein: an analysis using a new antibody.

The seizure-related gene 6 (Sez-6) encodes a transmembrane protein that is expressed in neuronal cells. A Sez-6-deficient mouse exhibits impaired spatial memory, motor deficits, and decreased anxiety levels. To understand the function of Sez-6 during the postnatal development of the forebrain, the spatiotemporal pattern of distribution of the Sez-6 protein was immunohistochemically analyzed using a new anti-Sez-6 antibody. Western blot analysis confirmed the specificity of this new antibody, and showed that the content of the Sez-6 protein in the cerebral cortex was highest during the neonatal period and decreased gradually thereafter. Immunohistochemical analysis revealed that Sez-6 immunoreactivity (IR) was detected in various brain regions, such as the hippocampus, cerebral cortex, piriform cortex, striatum, lateral amygdala, and olfactory tubercle. The expression patterns of Sez-6 in these brain regions was divided into three groups: i) in the cerebral cortex, hippocampus, and lateral amygdala, moderate-to-strong Sez-6 IR was detected in the first postnatal week and decreased gradually thereafter; ii) Sez-6 IR was not observed during the neonatal period in the striatum and the intensity of the signal increased gradually toward adulthood; and iii) strong Sez-6 IR was observed in the olfactory tubercle, regardless of the developmental stage. Furthermore, Sez-6 IR was detected in dendrites of hippocampal and cortical pyramidal neurons neonatally, whereas it localized around the soma after postnatal day 10. These spatiotemporal alterations of the regional and intracellular distribution of the Sez-6 protein suggest multiple functions for this protein during the postnatal development of the forebrain.

Neutrophil infiltration and oxidant-production in human atherosclerotic carotid plaques.

To clarify the clinical implications of neutrophils in vulnerable plaques we evaluated the function and activity of infiltrated neutrophils in an atherosclerotic plaque, focusing on oxidant production. A histopathological investigation was performed using carotid arterial samples obtained from seven patients. The atherosclerotic plaques were examined cytochemically for naphthol-ASD-chloroacetate esterase activity and oxidant-production, and immunohistochemically using N-formyl peptide receptor-like 1 (fPRL1)-, CD66b-, CD68- or p22phox-specific antibodies. The cytoplasmic fPRL1 intensity value of the neutrophils in the plaque was estimated using an activity index. Naphthol-ASD-chloroacetate esterase activity was found in cells located in the atherosclerotic plaque, indicating that the cells were neutrophils. The cytoplasmic fPRL1 intensity value of the neutrophils in the plaque decreased to approximately 60% of the intensity observed in the capillary vessels. Oxidant-production was also detected in the plaques, and both neutrophils and macrophages were observed at the corresponding oxidant-production sites. p22phox expression was also located in the same areas in which oxidant-production was observed in these plaques. We could not directly evaluate how much ROS generated from the infiltrated neutrophils contributed the plaque vulnerability followed by its rupture. However, the infiltrated neutrophils in the atherosclerotic plaques morphologically appeared activated and were actively generating oxidant, implying that neutrophils, together with macrophages, infiltrate into atherosclerotic plaques and contribute to plaque vulnerability.

Changes in calcitonin gene-related peptide expression following joint immobilization in rats.

Long-term immobilization by casting can occasionally cause pathologic pain states in the immobilized side. The underlying neurophysiological mechanisms of immobilization-related pain are not well understood. For this reason, we specifically examined changes of calcitonin gene-related peptide (CGRP) expression in the dorsal root ganglion (DRG), spinal dorsal horn and posterior nuclei (cuneate nuclei) in a long-term immobilization model following casting for 5 weeks. A plastic cast was wrapped around the right limb from the forearm to the forepaw to keep wrist joint at 90 degrees of flexion. In this model, CGRP in immobilized (ipsilateral) side was distributed in larger DRG neurons compared with contralateral side, even though the number of CGRP-immunoreactive (CGRP-IR) neurons did not differ. Spinal laminae III-V, not laminae I-II in ipsilateral side showed significantly high CGRP expression relative to contralateral side. CGRP expression in cuneate nuclei was not significantly different between ipsilateral and contralateral sides. Long-term immobilization by casting may induce phenotypic changes in CGRP expression both in DRG and spinal deep layers, and these changes are partly responsible for pathological pain states in immobilized side.

A mental retardation gene, motopsin/neurotrypsin/prss12, modulates hippocampal function and social interaction.

Motopsin is a mosaic serine protease secreted from neuronal cells in various brain regions, including the hippocampus. The loss of motopsin function causes nonsyndromic mental retardation in humans and impairs long-term memory formation in Drosophila. To understand motopsin's function in the mammalian brain, motopsin knockout (KO) mice were generated. Motopsin KO mice did not have significant deficits in memory formation, as tested using the Morris water maze, passive avoidance and Y-maze tests. A social recognition test showed that the motopsin KO mice had the ability to recognize two stimulator mice, suggesting normal social memory. In a social novelty test, motopsin KO mice spent a longer time investigating a familiar mouse than wild-type (WT) mice did. In a resident-intruder test, motopsin KO mice showed prolonged social interaction as compared with WT mice. Consistent with the behavioral deficit, spine density was significantly decreased on apical dendrites, but not on basal dendrites, of hippocampal pyramidal neurons of motopsin KO mice. In contrast, pyramidal neurons at the cingulate cortex showed normal spine density. Spatial learning and social interaction induced the phosphorylation of cAMP-responsive element-binding protein (CREB) in hippocampal neurons of WT mice, whereas the phosphorylation of CREB was markedly decreased in mutant mouse brains. Our results indicate that an extracellular protease, motopsin, preferentially affects social behaviors, and modulates the functions of hippocampal neurons.

Age-related changes in the expression of ER-beta mRNA in the female rat brain.

Estrogen is important for numerous physiological actions, most of which are mediated via the nuclear estrogen receptors (ERs), ER-alpha and ER-beta, which modulate the transcription of target genes following estrogen binding. Estrogen functions change with age. In the present study, to reveal the effects of normal aging on ER-beta expression in the brain, we examined ER-beta expression at the transcriptional level using young (10 weeks), middle-aged (12 months) and old (24 months) intact female rats. In situ hybridization using a digoxigenin-labeled RNA probe was used to assess the number of ER-beta mRNA-positive cells in each region in whole brain. ER-beta mRNA-positive cells were detected throughout the brain in young female rats and were reduced in number in the olfactory bulb, cerebral cortex, hippocampus, accumbens nucleus, part of the amygdala and raphe nucleus of middle-aged rats but did not decline further in number in aged animals. By contrast, the number of ER-beta mRNA-positive cells in the hippocampus, caudate putamen, claustrum, accumbens nucleus, substantia nigra and cerebellum was not significantly different between young and middle-aged rats but was decreased in old rats. These results indicate that the expression of ER-beta mRNA in the female rat brain is differentially modulated during aging and that the changes are region specific.

Enzymatic properties and localization of motopsin (PRSS12), a protease whose absence causes mental retardation.

Motopsin (PRSS12) is a mosaic protease expressed in the central nervous system. Truncation of the human motopsin gene causes nonsyndromic mental retardation. Understanding the enzymatic properties and localization of motopsin protein in the central nervous system will help identify the molecular mechanism by which the loss of motopsin function causes mental retardation. Recombinant motopsin showed amidolytic activity against the synthetic substrate benzyloxycarbonyl-l-phenylalanyl-l-arginine 4-methyl-coumaryl-7-amide. Motopsin activated the single-chain tissue plasminogen activator precursor and exhibited gelatinolytic activity. This enzymatic activity was inhibited by typical serine protease inhibitors such as aprotinin, leupeptin, and (4-amidinophenyl) methanesulfonyl fluoride. Immunocytochemistry using anti-motopsin IgG revealed that both human and mouse motopsin proteins were distributed in discrete puncta along the dendrites and soma as well as axons in cultured hippocampal neurons. In the limbic system, including the cingulate and hippocampal pyramidal neurons and piriform cortex, high level of motopsin protein was expressed at postnatal day 10, but a very low level at 10-week-old mice. Motopsin and tissue plasminogen activator were co-expressed in the cingulate pyramidal neurons at postnatal day 10 and were distributed along dendrites of cultured pyramidal neurons. In cranial nuclei, a moderate level of motopsin protein was detected independently on the developmental stage. Our results suggest that motopsin has multiple functions, such as axon outgrowth, arranging perineuronal environment, and maintaining neuronal plasticity, partly in coordination with other proteases including tissue plasminogen activator.