Noggin null allele mice exhibit a microform of holoprosencephaly.

Holoprosencephaly (HPE) is a heterogeneous craniofacial and neural developmental anomaly characterized in its most severe form by the failure of the forebrain to divide. In humans, HPE is associated with disruption of Sonic hedgehog and Nodal signaling pathways, but the role of other signaling pathways has not yet been determined. In this study, we analyzed mice which, due to the lack of the Bmp antagonist Noggin, exhibit elevated Bmp signaling. Noggin(-/-) mice exhibited a solitary median maxillary incisor that developed from a single dental placode, early midfacial narrowing as well as abnormalities in the developing hyoid bone, pituitary gland and vomeronasal organ. In Noggin(-/-) mice, the expression domains of Shh, as well as the Shh target genes Ptch1 and Gli1, were reduced in the frontonasal region at key stages of early facial development. Using E10.5 facial cultures, we show that excessive BMP4 results in reduced Fgf8 and Ptch1 expression. These data suggest that increased Bmp signaling in Noggin(-/-) mice results in downregulation of the hedgehog pathway at a critical stage when the midline craniofacial structures are developing, which leads to a phenotype consistent with a microform of HPE.

Loss of short dystrophin isoform Dp71 in olfactory ensheathing cells causes vomeronasal nerve defasciculation in mouse olfactory system.

The Duchenne muscular dystrophy (DMD) gene encodes dystrophin, which is a protein defective in DMD patients, as well as a number of shorter isoforms, which have been shown to be expressed in various non-muscle, primarily neural, tissues. As of yet, the physiological function of the various dystrophin isoforms is not fully understood. In the present study, we investigated the neurological phenotype that arises in the DMD-null mice, where expression of all dystrophin isoforms had been disrupted. We demonstrate that vomeronasal axons in the DMD-null mice are defasciculated, and some of the defasciculated vomeronasal axons aberrantly entered into the main olfactory bulb, which indicates that the product(s) of the DMD gene plays an important role in vomeronasal nerve organization. Through western blot and immunofluorescence analyses, we determined that the dystrophin isoform Dp71 was exclusively expressed in the mouse olfactory system: mainly in the olfactory ensheathing cells (OECs), an olfactory system-specific glia cell that ensheaths fascicles of the olfactory nerve. In the OECs, Dp71 was co-localized with beta-dystroglycan, utrophin, laminin, and perlecan. Since beta-dystroglycan and perlecan expression was decreased in the OECs of DMD-null mice, we hypothesize that Dp71 expressed in the OECs participates in fasciculation of the vomeronasal nerve, most likely through interactions with extracellular matrix.

Widespread defects in the primary olfactory pathway caused by loss of Mash1 function.

MASH1, a basic helix-loop-helix transcription factor, is widely expressed by neuronal progenitors in the CNS and PNS, suggesting that it plays a role in the development of many neural regions. However, in mice lacking a functional Mash1 gene, major alterations have been reported in only a few neuronal populations; among these is a generalized loss of olfactory receptor neurons of the olfactory epithelium. Here, we use a transgenic reporter mouse line, in which the cell bodies and growing axons of subsets of central and peripheral neurons are marked by expression of a tau-lacZ reporter gene (the Tattler-4 allele), to look both more broadly and deeply at defects in the nervous system of Mash1-/- mice. In addition to the expected lack of olfactory receptor neurons in the main olfactory epithelium, developing Mash1-/-;Tattler-4+/- mice exhibited reductions in neuronal cell number in the vomeronasal organ and in the olfactory bulb; the morphology of the rostral migratory stream, which gives rise to olfactory bulb interneurons, was also abnormal. Further examination of cell proliferation, cell death, and cell type-specific markers in Mash1-/- animals uncovered parallels between the main olfactory epithelium and the vomeronasal organ in the regulation of sensory neuron development. Interestingly, this analysis also revealed that, in the olfactory epithelium of Mash1-/- animals, there is an overproduction of proliferating cells that co-express markers of both neuronal progenitors and supporting cells. This finding suggests that olfactory receptor neurons and olfactory epithelium supporting cells may share a common progenitor, and that expression of Mash1 may be an important factor in determining whether these progenitors ultimately generate neurons or glia.

Vomeronasal organ growth and development in normal and cleft lip and palate human fetuses.

As part of an ongoing investigation of normal and cleft lip and palate (CLP) fetal midfacial development, the vomeronasal organ (VNO) was examined in 35 human fetuses (26 normal and 9 CLP) ranging in age from 8 to 30 weeks postmenstrual age. All specimens were examined histologically, and a computer reconstruction technique was used to quantify lengths and volumes of right and left VNOs and anterior paraseptal cartilages (PCs). Growth curves were generated for these data and were compared between normal and cleft samples. VNOs and PCs were present in all normal fetuses, whereas VNOs were found in only 5 of 9 CLP specimens and PCs were found in 8 CLP specimens. The side of the palatal cleft in specimens with unilateral CLP was associated with PC dysmorphologies but appeared to have no influence on VNO presence or absence. Septal dysmorphologies were observed in most CLP specimens with absent or abnormal VNOs. VNO length increased in a linear fashion across ages, and VNO volume was seen to change in a logarithmic fashion. Individual CLP specimens did not differ significantly from the mean of the normal sample for VNO length or volume. PC length was seen to change in a sigmoidal fashion, and PC volume changes were best described by a logarithmic curve. In contrast to findings on the VNO, CLP specimens exhibited significantly different growth rates (line slopes) for PC length and volume compared to the normal sample. Results on the normal sample suggested that the human fetal VNO exhibits volumetric increases between the 16th and 30th weeks of development, but this increase begins later and proceeds more slowly than that of the PCs. Examination of the CLP sample suggested that the VNOs were of "normal" size for age, but may be vulnerable to septal dysmorphologies that result in altered location or disruption.