Odorant receptor expression in the mouse cerebral cortex

Mammalian odorant receptors have been known to be involved not only in odorant detection but also in neuronal development of olfactory sensory neurons. We have examined a possibility of odorant receptor expression in nonolfactory neurons in the mouse. Mouse odorant receptors (M71, C6, and OR3), two of which were already shown to be functionally activated by odorants in heterologous systems, were detected by polymerase chain reactions (PCRs) from the cerebral cortex but not from other brain tissues. Degenerate PCR further suggested that other odorant receptors were also expressed in the mouse cerebral cortex. One of these receptors showed high sequence-match with a putative chick odorant receptor OR7 transiently expressed in the notochord during development. In situ hybridization detected signals for M71 and C6 receptors in the layer II cortical pyramidal neurons located in the occipital pole. In the M71-IRES-tauLacZ mouse, in which M71 expression was genetically marked with tauLacZ, X-gal staining signals were mostly localized in the layer II neurons in the occipital pole, being consistent with the in situ hybridization result. Fluorescent immunohistochemistry using anti-beta-galactosidase antibody further detected the tauLacZ signals in the same cells. X-gal staining began at P3, peaked at P8, and continued to adults, although signals gradually decreased. These data showed that at least a few odorant receptors are expressed not only in olfactory sensory neurons but also in pyramidal neurons in the cerebral cortex, possibly playing an important role either in chemical detection of exogenous or endogenous ligands or in a developmental process such as axon guidance and target recognition.     

Expression of the transcription factor Zfp191 during embryonic development in the mouse

The human zinc finger protein 191 (ZNF191) is a Krüppel-like protein and can specifically interact with the widespread TCAT motif which constitutes the HUMTH01 microsatellite in the tyrosine hydroxylase (TH) gene (encoding the rate-limiting enzyme in the synthesis of catecholamines). Allelic variations of HUMTH01 are known to have a quantitative silencing effect on TH gene expression and to correlate with quantitative and qualitative changes in the binding by ZNF191. This factor has been isolated from bone marrow and promyelocytic leukemia cell lines indicating that ZNF191 also plays a role in hematopoiesis. Thus, ZNF191 could participate in the regulation of several genes implicated in different functions. Moreover, mice that are deficient in Zfp191, the murine homologue of ZNF191, have been shown to be severely retarded in development and to die approximately at embryonic day 7.5. In order to gain further insight into its biological functions, we have analysed the localisation of Zfp191 throughout mouse development. Expression was detected early during embryogenesis in ectodermal, endodermal, mesodermal and extra-embryonic tissues. In particular, Zfp191 was observed in the developing central nervous system. Interestingly, its expression levels were prominent in areas of proliferation such as the subventricular zone. Zfp191 expression pattern during development can account for the phenotypic features of Zfp191(-/-) embryos.     

Functional nicotinic acetylcholine receptor expression in stem and progenitor cells of the early embryonic mouse cerebral cortex.

The adult cerebral cortex contains nicotinic acetylcholine (ACh) receptors vital to cortical function. However, little is known about the assembly of embryonic nicotinic receptor subunits into functional receptors or whether they play an active role in cortical development. We now report evidence of functional nicotinic acetylcholine receptor channels in fetal mouse cerebral cortex as early as embryonic day 10 (E10), when the cortex consists of dividing stem and progenitor cells. Patch-clamp electrophysiological measurements indicate that nicotine and ACh evoke sizable inward currents characteristic of nicotinic receptors, that are strongly rectifying with a reversal potential near 0 mV. Three different nicotinic agonists, ACh, nicotine, and dimethylphenylpiperazinium, evoked cytosolic Ca(2+) signals. Agonist-evoked Ca(2+) signals and electrophysiological responses were found in greater than 70% of all E10-E11 cells tested and were blocked by nicotinic receptor antagonists. The Ca(2+) response to nicotinic agonists was markedly prolonged in cells from early embryonic stages relative to later stages of development. alpha3, alpha4, and alpha7 receptor subunit proteins were detected immunocytochemically in cortical cells from E10 to birth. The incidence of each subunit declined with embryonic age, suggesting a role in early development. We discuss the possible function of nicotinic receptors in early cortical development and their role as a target for nicotine in the developmental pathologies associated with the fetal tobacco syndrome.     

Complex and dynamic expression of cadherins in the embryonic marmoset cerebral cortex

Cadherin is a cell adhesion molecule widely expressed in the nervous system. Previously, we analyzed the expression of nine classic cadherins (Cdh4, Cdh6, Cdh7, Cdh8, Cdh9, Cdh10, Cdh11, Cdh12, and Cdh20) and T‐cadherin (Cdh13) in the developing postnatal common marmoset (Callithrix jacchus) brain, and found differential expressions between mice and marmosets. In this study, to explore primate‐specific cadherin expression at the embryonic stage, we extensively analyzed the expression of these cadherins in the developing embryonic marmoset brain. Each cadherin showed differential spatial and temporal expression and exhibited temporally complicated expression. Furthermore, the expression of some cadherins differed from that in rodent brains, even at the embryonic stage. These results suggest the possibility that the differential expressions of diverse cadherins are involved in primate specific cortical development, from the prenatal to postnatal period.     

Imprinted methylation and its effect on expression of the mouse Zfp127 gene.

The Zfp127 gene is located on mouse chromosome 7 in an imprinted region that is homologous to the 2-Mb Prader-Willi and Angelman Syndromes region on human chromosome 15q11-q13. Here, we show that the gene is differentially methylated, the maternal allele being methylated and the paternal allele being unmethylated. This maternal methylation is established promptly after fertilization prior to syngamy. We also provide data that demonstrate the significance of methylation in the paternal expression of the gene. The expression of the Zfp127 gene in methyltransferase-deficient mice is significantly higher, suggesting that the gene is biallelically expressed in these mice. The data presented here will help to understand the mechanism by which the monoallelic expression of the entire 2-Mb Prader-Willi and Angelman Syndrome region is regulated.     

Cellular migration patterns in the developing mouse cerebral cortex

The migration patterns of embryonic mouse cortical cells were investigated using a replication-incompetent retrovirus vector (BAG). The lateral ventricles of embryonic day 12 mouse embryos were infected with BAG and brains were harvested 2, 3, 4 and 6 days after infection. The location and morphology of all infected cortical cells were recorded from serial sections of entire brains, which were then reconstructed in three dimensions. Examination of the distribution of labelled cells revealed that there were migration patterns characteristic of each medial-lateral domain of the cortex. In the medial and dorsal areas, migration was often radial, although tangential spread increased with survival time, in large part due to ramification of cells in the intermediate zone. In the dorsolateral and lateral areas of the cortex, radial migration was generally not observed. Rather, variable extents of tangential migration occurred, and often resulted in wide separation of cells in the cortical plate. Almost all of the cellular dispersion occurred in the intermediate zone, although a modest degree of dispersion also occurred within the cortical plate itself. Most dispersion occurred in the mediolateral plane, with relatively little dispersion along the anteroposterior axis. Though characteristic migration patterns could be defined, wide variability in the extents of radial migration and tangential separation of cells was seen. The patterns of migration paralleled the distribution of radial glial fibers in all areas, and are most likely a reflection of the role of this network in supporting the migration of cortical neurons. The extent and variability of cellular dispersion supports a lineage-independent mechanism of cortical column ontogenesis.     

Organizing principles of astrocytic nanoarchitecture in the mouse cerebral cortex

1. Download : Download high-res image (336KB)
2. Download : Download full-size image

     

ZFPIP/Zfp462 is involved in P19 cell pluripotency and in their neuronal fate

The nuclear zinc finger protein ZFPIP/Zfp462 is an important factor involved in cell division during the early embryonic development of vertebrates. In pluripotent P19 cells, ZFPIP/Zfp462 takes part in cell proliferation, likely via its role in maintaining chromatin structure. To further define the function of ZFPIP/Zfp462 in the mechanisms of pluripotency and cell differentiation, we constructed a stable P19 cell line in which ZFPIP/Zfp462 knockdown is inducible.We report that ZFPIP/Zfp462 was vital for mitosis and self-renewal in pluripotent P19 cells. Its depletion induced substantial decreases in the expression of the pluripotency genes Nanog, Oct4 and Sox2 and was associated with the transient expression of specific neuronal differentiation markers. We also demonstrated that ZFPIP/Zfp462 expression appears to be unnecessary after neuronal differentiation is induced in P19 cells.Taken together, our results strongly suggest that ZFPIP/Zfp462 is a key chromatin factor involved in maintaining P19 pluripotency and in the early mechanisms of neural differentiation but that it is dispensable in differentiated P19 cells.     

Radial glia regulate Cajal-Retzius cell positioning in the early embryonic cerebral cortex

The organization of neocortex, along its radial axis, into a six-layered structure is one of the most exquisite features of the brain. Because of their strategic localization in the marginal zone, and their expression of reelin, a signal that controls spatial ordering of cortical layers, Cajal–Retzius (C-R) cells play a crucial role in cortical patterning along this axis. Yet, it remains less well understood how C-R cell targeting itself is regulated. At the onset of corticogenesis when C-R cells first arrive in the cortex via tangential migration, radial glia (RG) are the main cell type present. This suggests that RG may play a role in C-R cell localization. To test this, we used genetic approaches to perturb RG scaffold during early corticogenesis. We found that disrupting RG endfoot adhesion to basal lamina consistently results in C-R cell displacement. These displacements do not appear to result from primary defects in neural progenitor cell proliferation, deficits in the meninges or basement membrane, or cell autonomous defects in C-R cells. Instead, they show close temporal and spatial correlation with RG endfoot retraction. Moreover, ablation of RG via cell cycle blockade similarly results in local displacement of C-R cells. These lines of evidence thus indicate that, during early corticogenesis, RG play a primary role in regulating spatial targeting of C-R cells. Since RG are also neural progenitors as well as neuronal migration scaffolds, these findings suggest that, during nervous system development, neuroepithelial stem cells may not only be responsible for generating a diverse array of neuronal cell types and facilitating their radial migration. They may also, through regulating the placement of guidepost cells, coordinate spatial patterning of the nervous system along its radial axis.     

Demonstration of an intercellular substance in mouse cerebral cortex

Summary Specimens of mouse cerebral cortex were preserved by freezing and drying and treated in vacuo with osmium tetroxide vapors. In the neuropil of the molecular layer dense, osmiophilic laminae, presumably plasma membranes of immediately adjacent cell processes, were found to be separated by an intercellular space, which appeared relatively electron lucent in unstained sections. In sections stained with uranyl acetate an intercellular substance was demonstrated, the visualized density of which was reduced when staining was accomplished at low pH. These reactions suggest the presence of a non-lipid, anionic intercellular substance which may contain acid mucopolysaccharide.This work was supported by U.S.P.H.S. Research Grants NB 05175, NB 07044 and Career Development Award 1K3 NB 4929.     

Differential expression of microRNAs in mouse embryonic bladder

MicroRNAs (miRNAs) are involved in several biological processes including development, differentiation and proliferation. Analysis of miRNA expression patterns in the process of embryogenesis may have substantial value in determining the mechanism of embryonic bladder development as well as for eventual therapeutic intervention. The miRNA expression profiles are distinct among the cellular types and embryonic stages as demonstrated by microarray technology and validated by quantitative real-time RT-PCR approach. Remarkably, the miRNA expression patterns suggested that unique miRNAs from epithelial and submucosal areas are responsible for mesenchymal cellular differentiation, especially regarding bladder smooth muscle cells. Our data show that miRNA expression patterns are unique in particular cell types of mouse bladder at specific developmental stages, reflecting the apparent lineage and differentiation status within the embryonic bladder. The identification of unique miRNAs expression before and after smooth muscle differentiation in site-specific area of the bladder indicates their roles in embryogenesis and may aid in future clinical intervention.     

早期小鼠胚胎发育的基因表达

受精是新个体发育的时 -空点 ,从一个形态单纯的单细胞受精卵发育成能独立生活的个体动物 ,形态上出现一系列的变化 ,而更重要的是基因表达。基因组是机体内惟一确定的 ,为所有各类细胞共同拥有 ,但基因组内各个基因表达的选择性和程度随时间、位置和环境条件的不同而发生改变 (严云勤等 ,2 0 0 2 ;胡静等 ,2 0 0 1;范衡宇等 ,2 0 0 1)。个体的发育和分化、内环境的稳定性、对外界刺激的应答、细胞循环的调节、衰老和程序化细胞死亡等正常的发育过程以及疾病的病理学过程 ,包括癌症的病理学过程 ,无论是由一个基因的突变引起的或是由于多基…     

CTGF expression during mouse embryonic development

Connective tissue growth factor (CTGF) is a potent fibroblast mitogen and angiogenic factor which plays an important role in wound healing, cancerogenesis and fibrotic and vascular disease. Here we explored the regulation and the cellular site of the mRNA synthesis for this growth factor in the developing mouse embryo by in situ hybridisation. Strong and persistent CTGF gene expression was limited to three types of tissue: the vascular endothelium, particularly the high-pressure part of the cardiovascular system, condensed connective tissue around bone and cartilage, and maturing layer VII neurons in the cerebral cortex. With few exceptions (late tooth bud, neuroepithelium) epithelial tissue was negative. Very transient but strong expression was observed early during formation of cartilage, in late stages during perichondral ossification, on cerebral neuroepithelium, and in several discrete stages of tooth formation, on mesenchymal precursors of odontoblasts condensing on inner dental epithelium, and later on apposing regions of ameloblast and odontoblast epithelium. Altogether, the current study suggests that CTGF performs a dual role: a continuous function in the cardiovascular system, bone and cartilage-associated mesenchyme and maturing layer VII neurons, but also a more transient function associated with the formation of cartilage, bone, tooth and cerebral nerve cells.     

Effect of rabies virus infection on the expression of parvalbumin, calbindin and calretinin in mouse cerebral cortex

Some clinical features of rabies and experimental evidence from cell culture and laboratory animals suggest impairment of gabaergic neurotransmission. Several types of gabaergic neurons occur in the cerebral cortex. They can be identified by three neuronal markers: the calcium binding proteins (CaBPs) parvalbumin (PV), calbindin (CB) and calretinin (CR). Rabies virus spreads throughout the cerebral cortex; however, rabies cytopathic effects on gabaergic neurons are unknown. The expression of calcium-binding proteins (CaBPs) parvalbumin (PV), calbindin (CB) and calretinin (CR) was studied in the frontal cortex of mice. The effect of gabaergic neurons was evaluated immunohistochemically. The distribution patterns of CaBPs in normal mice and in mice infected with 'fixed' or 'street' rabies virus were compared. PV was found in multipolar neurons located in all cortical layers except layer I, and in pericellular clusters of terminal knobs surrounding the soma of pyramidal neurons. CB-immunoreactivity was distributed in two cortical bands. One was composed of round neurons enclosed by a heavily labeled neuropil; this band corresponds to supragranular layers II and III. The other was a weakly stained band of neuropil which contained scattered multipolar CB-ir neurons; this corresponds to infragranular layers V and VI. The CR-ir neurons were bipolar fusiform cells located in all layers of cortex, but concentrated in layers II and III. A feature common to samples infected with both types of viruses was a more intense immunoreactivity to PV in contrast to normal samples. The infection with 'street' virus did not cause additional changes in the expression of CaBPs. However, the infection with 'fixed' virus produced a remarkable reduction of CB-immunoreactivity demonstrated by the loss of CB-ir neurons and low neuropil stain in the frontal cortex. In addition, the size of CR-ir neurons in the cingulate cortex was decreased.