Contribution of the neural cell recognition molecule NB‐3 to synapse formation between parallel fibers and Purkinje cells in mouse

The neural cell recognition molecule NB‐3, also referred to as contactin‐6, is expressed prominently in the developing nervous system after birth and its deficiency has been shown to cause impairment in motor coordination. Here, we investigated the contribution of NB‐3 to cerebellar development, focusing on lobule 3 where NB‐3 was expressed in granule cells but not in Purkinje cells. In the developing molecular layer, the neural cell recognition molecules TAG‐1, L1, and NB‐3 formed distinct expression zones from the external granule cell layer to the internal granule cell layer (IGL), respectively. The NB‐3‐immunoreactive zone did not overlap with TAG‐1‐immunoreactive zone. By contrast, the L1‐immunoreactive zone overlapped with both the TAG‐1‐ and NB‐3‐immunoreactive zones. NB‐3‐positive puncta overlapped with vesicular glutamate transporter 1, a presynaptic marker and were apposed close to metabotropic glutamate receptor 1A, a postsynaptic marker, indicating that NB‐3 is localized presynaptically at glutamatergic synapses between parallel fibers and Purkinje cells. In NB‐3 knockout mice, L1 immunoreactive signals were increased in the IGL at postnatal day (P) 5, suggesting the increase in the number of immature granule cells of the IGL. In addition, the density of parallel fiber synaptic terminals was reduced in NB‐3 knockout mice relative to wild‐type mice at P5 to P10. In parallel with these findings, caspase‐dependent cell death was significantly increased in the NB‐ 3‐deficient cerebellum at P15. Collectively, our results indicate that NB‐3 deficiency affects synapse formation during postnatal cerebellar development. © 2009 Wiley Periodicals, Inc. Develop Neurobiol, 2009     

A proteomic approach to understand MMP‐3‐driven developmental processes in the postnatal cerebellum: Chaperonin CCT6A and MAP kinase as contributing factors

Matrix metalloproteinase‐3 (MMP‐3) deficiency in mice was previously reported to result in a transiently retarded granule cell migration at postnatal day 8 (P8) and a sustained disturbed arborization of Purkinje cell dendrites from P8 on, concomitant with a delayed synapse formation between granule cells and Purkinje cells and resulting in mild deficits in motor performance in adult animals. However, the molecular mechanisms by which MMP‐3 contributes to proper development of the cerebellar cortex during the first postnatal weeks remains unknown. In this study, we used a functional proteomics approach to investigate alterations in protein expression in postnatal cerebella of wild‐type versus MMP‐3 deficient mice, and to further elucidate MMP‐3‐dependent pathways and downstream targets in vivo. At P8, two‐dimensional difference gel electrophoresis and mass spectrometry identified 20 unique proteins with a different expression between the two genotypes. Subsequent “Ingenuity Pathway Analysis” and Western blotting indicate that the chaperonin containing T‐complex polypeptide 1, subunit 6A and the MAP kinase signaling pathway play a key role in the MMP‐3‐dependent regulation of neurite outgrowth and neuronal migration in the developing brain. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 75: 1033–1048, 2015     

HP1BP3 expression determines maternal behavior and offspring survival

Maternal care is an indispensable behavioral component necessary for survival and reproductive success in mammals, and postpartum maternal behavior is mediated by an incompletely understood complex interplay of signals including effects of epigenetic regulation. We approached this issue using our recently established mice with targeted deletion of heterochromatin protein 1 binding protein 3 (HP1BP3), which we found to be a novel epigenetic repressor with critical roles in postnatal growth. Here, we report a dramatic reduction in the survival of pups born to Hp1bp3^?/? deficient mouse dams, which could be rescued by co‐fostering with wild‐type dams. Hp1bp3^?/? females failed to retrieve both their own pups and foster pups in a pup retrieval test, and showed reduced anxiety‐like behavior in the open‐field and elevated‐plus‐maze tests. In contrast, Hp1bp3^?/? females showed no deficits in behaviors often associated with impaired maternal care, including social behavior, depression, motor coordination and olfactory capability; and maintained unchanged anxiety‐associated hallmarks such as cholinergic status and brain miRNA profiles. Collectively, our results suggest a novel role for HP1BP3 in regulating maternal and anxiety‐related behavior in mice and call for exploring ways to manipulate this epigenetic process.     

Neuronal expression of macrophage colony stimulating factor in Purkinje cells and olfactory mitral cells of wild-type and cerebellar-mutant mice

Macrophage colony stimulating factor (M-CSF) is known to be the most effective growth factor for macrophage and microglial proliferation. In the brain tissue system, M-CSF is mainly produced in astrocytes and microglia, but is not known to occur in neurons. In the present paper, we examined the distribution of neurons expressing M-CSF in the mouse brain by immuno-histochemistry and in situ hybridization. We observed M-CSF immunoreactivity in both the cerebellum and the olfactory bulb. These positive cells were found to be Purkinje cells in the cerebellum, and mitral cells in the olfactory bulb. M-CSF mRNA expression was also confirmed to occur in these cells. Purkinje cells of reeler and weaver mutants showed M-CSF expression as seen in wild-type mice; however, those in the staggerer mutant did not. This expression in wild-type mice first appeared at postnatal day 7 and continued stably thereafter. When Purkinje cells were deprived of their climbing fibre innervation by inferior cerebellar pedunculotomy or by transplantation of cerebellar anlagen into the anterior eye chamber, the expression of M-CSF remained unchanged. These data indicate that expression of M-CSF in Purkinje cells is controlled by an intrinsic mechanism and could, therefore, be a new marker of postnatal development in rodent cerebella. The absence of M-CSF expression in the staggerer mutant is possibly due to developmental arrest in the early postnatal period.     

An Aberrant Cerebellar Development in Mice Lacking Matrix Metalloproteinase-3

Cell–cell and cell–matrix interactions are necessary for neuronal patterning and brain wiring during development. Matrix metalloproteinases (MMPs) are proteolytic enzymes capable of remodelling the pericellular environment and regulating signaling pathways through cleavage of a large degradome. MMPs have been suggested to affect cerebellar development, but the specific role of different MMPs in cerebellar morphogenesis remains unclear. Here, we report a role for MMP-3 in the histogenesis of the mouse cerebellar cortex. MMP-3 expression peaks during the second week of postnatal cerebellar development and is most prominently observed in Purkinje cells (PCs). In MMP-3 deficient (MMP-3^−/−) mice, a protracted granule cell (GC) tangential migration and a delayed GC radial migration results in a thicker and persistent external granular layer, a retarded arrival of GCs in the inner granular layer, and a delayed GABAergic interneuron migration. Importantly, these neuronal migration anomalies, as well as the consequent disturbed synaptogenesis on PCs, seem to be caused by an abnormal PC dendritogenesis, which results in reduced PC dendritic trees in the adult cerebellum. Of note, these developmental and adult cerebellar defects might contribute to the aberrant motor phenotype observed in MMP-3^−/− mice and suggest an involvement of MMP-3 in mouse cerebellar development.     

Aberrant neuronal connectivity in CHL1‐deficient mice is associated with altered information processing‐related immediate early gene expression

In humans, loss or alteration of the CHL1/CALL gene may contribute to mental impairment associated with the 3p‐syndrome, caused by distal deletions of the short (p) arm of chromosome 3, and schizophrenia. Mice deficient for the Close Homologue of L1 (CHL1) show aberrant connectivity of hippocampal mossy fibers and olfactory sensory axons, suggesting participation of CHL1 in the establishment of neuronal networks. Furthermore, behavioral studies showed that CHL1‐deficient mice react differently towards novel experimental environments. These data raise the hypothesis that processing of information, possibly novel versus familiar, may be altered in the absence of CHL1. To test this hypothesis, brain activities were investigated after presentation of a novel, familiar, or neutral gustatory stimulus using metabolic mapping with (¹⁴C)‐2‐deoxyglucose (2‐DG) and analysis of mRNA expression of the immediate early genes (IEGs) c‐fos and arg 3.1/arc by in situ hybridization. 2‐DG labeling revealed only small differences between CHL1‐deficient and wild‐type littermate mice. In contrast, while the specific novelty‐induced increase in c‐fos expression was maintained in most of the brain areas analyzed, c‐fos mRNA expression was similar after the novel and familiar taste in several brain areas of the CHL1‐deficient mice. Furthermore, in these mutants, arg 3.1/arc expression was slightly reduced after the novel taste and increased after the familiar taste, leading to a similar arg 3.1/arc mRNA expression after both stimuli. Our results indicate that, in contrast to controls, CHL1‐deficient mice might process novel and familiar information similarly and suggest that the altered neuronal connectivity in these mutants disturbs information processing at the molecular level. © 2003 Wiley Periodicals, Inc. J Neurobiol 57: 67–80, 2003     

Nuclear morphology of ichthyosis mutant mice as a cell marker in chimeric brain

The nuclear morphology of certain neuronal populations from the mutant mouse, ichthyosis, is distinct from wild-type strains of mice. The granule cells of the cerebellum, cochlear nucleus, and olfactory bulb in ichthyosis mice have a much greater tendency for centralized clumping of nuclear heterochromatin. In the early postnatal nervous system many cells in migratory and germinal regions of the brain also express the ichthyosis phenotype. The retention of the ichthyosis phenotype in neurons of chimeric mice is documented. The prevalent expression of the ichthyosis phenotype in postnatal migratory and germinal regions of the brain would be particularly useful for studying cell interactions in the developing brain.     

Caspr3-Deficient Mice Exhibit Low Motor Learning during the Early Phase of the Accelerated Rotarod Task

Caspr3 (Contactin-associated protein-like 3, Cntnap3) is a neural cell adhesion molecule belonging to the Caspr family. We have recently shown that Caspr3 is expressed abundantly between the first and second postnatal weeks in the mouse basal ganglia, including the striatum, external segment of the globus pallidus, subthalamic nucleus, and substantia nigra. However, its physiological role remains largely unknown. In this study, we conducted a series of behavioral analyses on Capsr3-knockout (KO) mice and equivalent wild-type (WT) mice to investigate the role of Caspr3 in brain function. No significant differences were observed in most behavioral traits between Caspr3-KO and WT mice, but we found that Caspr3-KO mice performed poorly during the early phase of the accelerated rotarod task in which latency to falling off a rod rotating with increasing velocity was examined. In the late phase, the performance of the Caspr3-KO mice caught up to the level of WT mice, suggesting that the deletion of Caspr3 caused a delay in motor learning. We then examined changes in neural activity after training on the accelerated rotarod by conducting immunohistochemistry using antibody to c-Fos, an indirect marker for neuronal activity. Experience of the accelerated rotarod task caused increases in the number of c-Fos-positive cells in the dorsal striatum, cerebellum, and motor cortex in both Caspr3-KO and WT mice, but the number of c-Fos-positive cells was significantly lower in the dorsal striatum of Caspr3-KO mice than in that of WT mice. The expression of c-Fos in the ventral striatum of Caspr3-KO and WT mice was not altered by the training. Our findings suggest that reduced activation of neural cells in the dorsal striatum in Caspr3-KO mice leads to a decline in motor learning in the accelerated rotarod task.     

Adropin Is a Brain Membrane-bound Protein Regulating Physical Activity via the NB-3/Notch Signaling Pathway in Mice

Adropin is a highly conserved polypeptide that has been suggested to act as an endocrine factor that plays important roles in metabolic regulation, insulin sensitivity, and endothelial functions. However, in this study, we provide evidence demonstrating that adropin is a plasma membrane protein expressed abundantly in the brain. Using a yeast two-hybrid screening approach, we identified NB-3/Contactin 6, a brain-specific, non-canonical, membrane-tethered Notch1 ligand, as an interaction partner of adropin. Furthermore, this interaction promotes NB3-induced activation of Notch signaling and the expression of Notch target genes. We also generated and characterized adropin knockout mice to explore the role of adropin in vivo. Adropin knockout mice exhibited decreased locomotor activity and impaired motor coordination coupled with defective synapse formation, a phenotype similar to NB-3 knockout mice. Taken together, our data suggest that adropin is a membrane-bound protein that interacts with the brain-specific Notch1 ligand NB3. It regulates physical activity and motor coordination via the NB-3/Notch signaling pathway and plays an important role in cerebellum development in mice.     

Age‐related deterioration of motor function in male and female 5xFAD mice from 3 to 16 months of age

Alzheimer's disease (AD) is a neurodegenerative disorder that leads to age‐related cognitive and sensori‐motor dysfunction. There is an increased understanding that motor dysfunction contributes to overall AD severity, and a need to ameliorate these impairments. The 5xFAD mouse develops the neuropathology, cognitive and motor impairments observed in AD, and thus may be a valuable animal model to study motor deficits in AD. Therefore, we assessed age‐related changes in motor ability of male and female 5xFAD mice from 3 to 16 months of age, using a battery of behavioral tests. At 9‐10 months, 5xFAD mice showed reduced body weight, reduced rearing in the open‐field and impaired performance on the rotarod compared to wild‐type controls. At 12‐13 months, 5xFAD mice showed reduced locomotor activity on the open‐field, and impaired balance on the balance beam. At 15‐16 months, impairments were also seen in grip strength. Although sex differences were observed at specific ages, the development of motor dysfunction was similar in male and female mice. Given the 5xFAD mouse is commonly on a C57BL/6 × SJL hybrid background, a subset of mice may be homozygous recessive for the Dysf ^im mutant allele, which leads to muscular weakness in SJL mice and may exacerbate motor dysfunction. We found small effects of Dysf ^im on motor function, suggesting that Dysf ^im contributes little to motor dysfunction in 5xFAD mice. We conclude that the 5xFAD mouse may be a useful model to study mechanisms that produce motor dysfunction in AD, and to assess the efficacy of therapeutics on ameliorating motor impairment.     

Human Umbilical Cord Mesenchymal Stem Cells Protect Against SCA3 by Modulating the Level of 70 kD Heat Shock Protein

Spinocerebellar ataxia 3 (SCA3), which is a progressive neurodegenerative disease, is currently incurable. Emerging studies have reported that human umbilical cord mesenchymal stem cells (HUC-MSCs) transplantation could be a promising therapeutic strategy for cerebellar ataxias. However, few studies have evaluated the effects of HUC-MSCs on SCA3 transgenic mouse. Thus, we investigated the effects of HUC-MSCs on SCA3 mice and the underlying mechanisms in this study. SCA3 transgenic mice received systematic administration of 2 × 10⁶ HUC-MSCs once per week for 12 continuous weeks. Motor coordination was measured blindly by open field tests and footprint tests. Immunohistochemistry and Nissl staining were applied to detect neuropathological alternations. Neurotrophic factors in the cerebellum were assessed by ELISA. We used western blotting to detect the alternations of heat shock protein 70 (HSP70), IGF-1, mutant ataxin-3, and apoptosis-associated proteins. Tunel staining was also used to detect apoptosis of affected cells. The distribution and differentiation of HUC-MSCs were determined by immunofluorescence. Our results exhibited that HUC-MSCs transplantation significantly alleviated motor impairments, corresponding to a reduction of cerebellar atrophy, preservation of neurons, decreased expression of mutant ataxin-3, and increased expression of HSP70. Implanted HUC-MSCs were mainly distributed in the cerebellum and pons with no obvious differentiation, and the expressions of IGF-1, VEGF, and NGF in the cerebellum were significantly elevated. Furthermore, with the use of HSP70 analogy quercetin injection, it demonstrated that HSP70 is involved in mutant ataxin-3 reduction. These results showed that HUC-MSCs implantation is a potential treatment for SCA3, likely through upregulating the IGF-1/HSP70 pathway and subsequently inhibiting mutant ataxin-3 toxicity.     

Early postnatal behavioral changes in the Mecp2‐308 truncation mouse model of Rett syndrome

In a mouse model of Rett syndrome (RTT) which expresses a truncated form of methyl‐CpG‐binding protein 2 (Mecp2) gene (Mecp2‐308), we performed a neurobehavioral evaluation across the life span, starting from soon after birth till adulthood. A focus was made on those developmental phases and behavioral domains which have not been previously investigated. The results evidenced subtle anomalies on postnatal days (pnds) 3 to 9 (so‐called presymptomatic phase) in spontaneous movements by hemizygous neonatal male mice. Specifically as early as pnd 3, mutant pups exhibited more intense curling and more side responses and on pnd 9 more pivoting and head rising behaviors than wild type (wt) littermates. A significant decrease in ultrasonic vocalization rate, also emerged in Mecp2‐308 pups. The same mice were also characterized by increased anxiety‐like behaviors (open‐field and zero‐maze tests) during the early symptomatic phase, in the absence of changes in cognitive passive‐avoidance task and rotarod performances. Upon the clearly symptomatic stage, 5‐month‐old Mecp2‐308 mice were also associated with reduced spontaneous home‐cage motor activity, motor coordination impairments (rotarod and dowel tests), and a more marked profile of d ‐amphetamine (10 mg/kg) released stereotyped behavioral syndrome than wt mice. Present results provide an interesting timeline of the progression of symptoms in the Mecp2‐308 model and emphasize the need for increased attention to the presymptomatic phase which may be especially informative in mouse models of human neurodevelopmental disorders. This analysis has provided evidence of precocious behavioral markers of RTT and has identified an early developmental window of opportunities on which potential therapies could be investigated.     

Mice lacking Asic3 show reduced anxiety‐like behavior on the elevated plus maze and reduced aggression

Sensing external stimulation is crucial for central processing in the brain and subsequent behavioral expression. Although sensory alteration or deprivation may result in behavioral changes, most studies related to the control of behavior have focused on central mechanisms. Here we created a sensory deficit model of mice lacking acid‐sensing ion channel 3 (Asic3^?/?) to probe behavioral alterations. ASIC3 is predominately distributed in the peripheral nervous system. RT‐PCR and immunohistochemistry used to examine the expression of Asic3 in the mouse brain showed near‐background mRNA and protein levels of ASIC3 throughout the whole brain, except for the sensory mesencephalic trigeminal nucleus. Consistent with the expression results, Asic3 knockout had no effect on synaptic plasticity of the hippocampus and the behavioral tasks of motor function, learning and memory. In anxiety behavior tasks, Asic3^?/? mice spent more time in the open arms of an elevated plus maze than did their wild‐type littermates. Asic3^?/? mice also displayed less aggressiveness toward intruders but more stereotypic repetitive behaviors during resident–intruder testing than did wild‐type littermates. Therefore, loss of ASIC3 produced behavioral changes in anxiety and aggression in mice, which suggests that ASIC3‐dependent sensory activities might relate to the central process of emotion modulation.     

Impaired Cerebellar Development in Mice Overexpressing VGF

VGF nerve growth factor inducible (VGF) is a neuropeptide precursor induced by brain-derived neurotrophic factor and nerve growth factor. VGF is increased in the prefrontal cortex and cerebrospinal fluid in schizophrenia patients. In our previous study, VGF-overexpressing mice exhibited schizophrenia-like behaviors and smaller brain weights. Brain developmental abnormality is one cause of mental illness. Research on brain development is important for discovery of pathogenesis of mental disorders. In the present study, we investigated the role of VGF on cerebellar development. We performed a histological analysis with cerebellar sections of adult and postnatal day 3 mice by Nissl staining. To investigate cerebellar development, we performed immunostaining with antibodies of immature and mature granule cell markers. To understand the mechanism underlying these histological changes, we examined MAPK, Wnt, and sonic hedgehog signaling by Western blot. Finally, we performed rotarod and footprint tests using adult mice to investigate motor function. VGF-overexpressing adult mice exhibited smaller cerebellar sagittal section area. In postnatal day 3 mice, a cerebellar sagittal section area reduction of the whole cerebellum and external granule layer and a decrease in the number of mature granule cells were found in VGF-overexpressing mice. Additionally, the number of proliferative granule cell precursors was lower in VGF-overexpressing mice. Phosphorylation of Trk and Erk1 were increased in the cerebellum of postnatal day 3 VGF-overexpressing mice. Adult VGF-overexpressing mice exhibited motor disability. All together, these findings implicate VGF in the development of cerebellar granule cells via promoting MAPK signaling and motor function in the adult stage.

     

Increased apoptosis during neonatal brain development underlies the adult behavioral deficits seen in mice lacking a functional paternally expressed gene 3 (Peg3)

Inactivation of the maternally imprinted, paternally expressed gene 3 (Peg3) induces deficits in olfactory function, sexual and maternal behaviors, oxytocin neuron number, metabolic homeostasis and growth. Peg3 is expressed in a number of developing hypothalamic and basal forebrain structures and is a component of the P53 apoptosis pathway. Peg3 inactivation in neuronal cell culture lines inhibits P53 mediated apoptosis, which is important in the early postnatal development and sexual differentiation of the brain. In this study, we investigated the effect of inactivating the Peg3 gene on the incidence of caspase 3 positive cells (a marker of apoptosis) in 4‐ and 6‐day postpartum mouse brain. Inactivating the Peg3 gene resulted in an increase in the incidence of total forebrain caspase 3 positive cells at 4 and 6 days postpartum. Increases in specific neuroanatomical regions including the bed nucleus of the stria terminalis, nucleus accumbens, caudate putamen, medial pre‐optic area, arcuate nucleus, medial amygdala, anterior cortical and posteriodorsal amygdaloid nuclei, were also observed. In wild‐type mice, sex differences in the incidence of caspase 3 positive cells in the medial amygdala, bed nucleus of the stria terminalis, nucleus accumbens, arcuate nucleus and the M2 motor cortex, were also observed. This neural sex difference was ameliorated in the Peg‐3 mutant. These findings suggest that the neuronal and behavioral deficits seen in mice lacking a functional Peg3 gene are mediated by increases in the incidence of early neonatal apoptosis in neuroanatomical regions important for reproductive behavior, olfactory and pheromonal processing, thermoregulation and reward. © 2009 Wiley Periodicals, Inc. Develop Neurobiol, 2009     

Subclass of astroglia in mouse cerebellum recognized by monoclonal antibody

A monoclonal antibody was detected that distinguishes astrocyte subclasses in mouse cerebellum. This antibody, designated anti-M1, is the product of a hybridoma that arose from the fusion of NS1 myeloma cells and splenocytes derived from a rat immunized with crude membranes from early postnatal mouse cerebella. The distribution and regulation of M1 antigen expression in vivo were examined by indirect immunofluorescence on frozen thin sections of mouse brain. M1 expression shows differing age dependencies within subpopulations of astroglia. M1 is first detectable around postnatal day 7 in white matter astrocytes and persists in this cell type throughout adulthood. By postnatal day 10, M1 is additionally detected in Bergmann glial fibers and in granule layer astrocytes. M1 expression in these latter astrocytic cell types is transient and cannot be detected after the fourth postnatal week. Cerebella of adult neurological mutant weaver mice show abnormal persistence of M1 antigen expression in Bergmann glial fibers. In monolayer cultures of early postnatal cerebella, M1 antigen is detected in a subpopulation of the glial fibrillary acidic protein positive astrocytes. M1 antigen can be detected only in fixed cultured cells which allow intracellular penetration of the antibody. The developmental regulation of M1 expression and the abnormal expression of M1 in weaver mutant cerebella suggest that M1 may be a useful marker for astroglial maturation and differentiation.