Brca1 deficiency results in early embryonic lethality characterized by neuroepithelial abnormalities.

The breast and ovarian cancer susceptibility gene, BRCA1, has been cloned and shown to encode a zinc-finger protein of unknown function. Mutations in BRCA1 account for at least 80% of families with both breast and ovarian cancer, as well as some non-familial sporadic ovarian cancers. The loss of wild-type BRCA1 in tumours of individuals carrying one nonfunctional BRCA1 allele suggests that BRCA1 encodes a tumour suppressor that may inhibit the proliferation of mammary epithelial cells. To examine the role of BRCA1 in normal tissue growth and differentiation, and to generate a potential model for the cancer susceptibility associated with loss of BRCA1 function, we have created a mouse line carrying a mutation in one Brca1 allele. Analysis of mice homozygous for the mutant allele indicate that Brca1 is critical for normal development, as these mice died in utero between 10 and 13 days of gestation (E10-E13). Abnormalities in Brca1-deficient embryos were most evident in the neural tube, with 40% of the embryos presenting with varying degrees of spina bifida and anencephaly. In addition, the neuroepithelium in Brca1-deficient embryos appeared disorganized, with signs of both rapid proliferation and excessive cell death.

Fetal alcohol syndrome: embryogenesis in a mouse model.

When two small doses of ethanol were administered to pregnant mice during the gastrulation stage of embryogenesis, the embryos developed craniofacial malformations closely resembling those seen in the human fetal alcohol syndrome. Striking histological changes appeared in the developing brain (neuroectoderm) within 24 hours of exposure. Decreased development of the neural plate and its derivatives apparently accounts for the craniofacial malformations. The critical exposure period is equivalent to the third week in human pregnancy.

7-Dehydrocholesterol-dependent proteolysis of HMG-CoA reductase suppresses sterol biosynthesis in a mouse model of Smith-Lemli-Opitz/RSH syndrome.

Smith-Lemli-Opitz/RSH syndrome (SLOS), a relatively common birth-defect mental-retardation syndrome, is caused by mutations in DHCR7, whose product catalyzes an obligate step in cholesterol biosynthesis, the conversion of 7-dehydrocholesterol to cholesterol. A null mutation in the murine Dhcr7 causes an identical biochemical defect to that seen in SLOS, including markedly reduced tissue cholesterol and total sterol levels, and 30- to 40-fold elevated concentrations of 7-dehydrocholesterol. Prenatal lethality was not noted, but newborn homozygotes breathed with difficulty, did not suckle, and died soon after birth with immature lungs, enlarged bladders, and, frequently, cleft palates. Despite reduced sterol concentrations in Dhcr7(-/-) mice, mRNA levels for 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, the rate-controlling enzyme for sterol biosynthesis, the LDL receptor, and SREBP-2 appeared neither elevated nor repressed. In contrast to mRNA, protein levels and activities of HMG-CoA reductase were markedly reduced. Consistent with this finding, 7-dehydrocholesterol accelerates proteolysis of HMG-CoA reductase while sparing other key proteins. These results demonstrate that in mice without Dhcr7 activity, accumulated 7-dehydrocholesterol suppresses sterol biosynthesis posttranslationally. This effect might exacerbate abnormal development in SLOS by increasing the fetal cholesterol deficiency.

Ontogeny of cholinergic neurons in the mouse forebrain.

The development of cholinergic neurons in the mouse forebrain was studied by immunocytochemistry with a monoclonal antibody to choline acetyltransferase (ChAT), the rate-limiting enzyme for acetylcholine synthesis. Since this antibody stained dividing cells in ventricular germinal zones as well as differentiating neurons, likely routes of migration could be inferred on the basis of the location of immunoreactive (IR) cells at different gestational ages. Germinal zones for cholinergic cells were observed in all ventricular zones of the forebrain with the ventral zones generating the earliest cells by gestational day 13.5 (GD13.5). On GD14, ChAT IR cells were visible in the germinal zones of the eye, olfactory ventricle, anterior horn, and dorsolateral aspect of the lateral ventricle, lateral ganglionic eminence, ventro- and dorsolateral third ventricle, and in the pineal anlage (epiphysis). ChAT IR neurons continued to develop in these and additional germinal zones on GD15, including the medial, dorsal, and dorsomedial walls of the lateral ventricle, and the medial and dorsal ganglionic eminence. On GD16, ChAT IR neurons were located in the prelimbic, pyriform, and parietal cortices and the lamina terminalis, and a cluster of IR cells was observed in the ventricular zone of the caudatopallial angle. On GD17-18, neurons in the anterior olfactory nucleus, olfactory tubercle, horizontal and vertical nucleus of the diagonal band, and medial septal nucleus stained more darkly and were multipolar, whereas immature bipolar neurons appeared to continue their migration into the hippocampus and along major fiber tracts, such as the corpus callosum, external capsule, fornix and anterior commissure. This study provides a comprehensive view of the zones of origin, probable routes of migration, and final destination of cholinergic neurons in the mouse forebrain.

Laminin and fibronectin in retinoid-induced keratolenticular dysgenesis.

Acute embryonic exposure to isotretinoin during gastrulation (gestational day 7) in the mouse results in delay or failure of separation of the lens vesicle from the surface ectoderm. During normal lens vesicle detachment, laminin is localized within the lens, keratolenticular stalk and adjacent surface ectoderm. The mesenchyme surrounding the stalk stains positively for fibronectin. In contrast, isotretinoin-exposed embryos at the same stage of gestation exhibit reduced staining for both extracellular matrix components. Persistent keratolenticular attachment observed later in gestation in the exposed embryos is associated with increased production of laminin by the keratolenticular stalk and anterior lens epithelium. A delay in the sequence of production of extracellular matrix may be causally associated with persistence of the keratolenticular stalk.

Programmed cell death in extraocular muscle tendon/sclera precursors.

PURPOSE: This study was designed to examine the occurrence of natural cell death in the periocular mesenchyme of mouse embryos. METHODS: Vital staining with LysoTracker Red and Nile blue sulfate as well as terminal nick end labeling (TUNEL) were utilized to identify apoptotic cell death in whole and histologicaly sectioned gestational day 10.5 to 14 mouse embryos. Laser scanning confocal microscopy was used to provide a three dimensional representation of the cell death pattern. Immunohistochemical staining for neural crest and myoblast populations was utilized to indicate the cell population undergoing apoptosis. RESULTS: Programmed cell death was evident in the developing rectus muscle tendons/sclera on gestational days 11 through 12.5 (corresponding to the weeks 5-6 of human development). Although each of these peripheral periocular condensations has readily apparent amounts of apoptosis, the pattern of cell death varied among them. Cell death was most apparent in the superior rectus tendon primordium, while that for the lateral rectus had the least evidence of apoptosis. CONCLUSIONS: Although apoptosis was readily evident in the periocular mesenchyme in distinct regions located medial and distal to the developing rectus muscles, programmed cell death in these sites has not previously been reported. New imaging techniques coupled with stains that evidence apoptotic cell death have made it possible to define this tissue as a prominent region of programmed cell death. Although neuronal tissues, including particular regions of the developing eye, are well recognized as sites of programmed cell death, description of this phenomenon in the extraocular tendon/sclera precursors is novel.

Experimental fetal alcohol syndrome: proposed pathogenic basis for a variety of associated facial and brain anomalies.

Acute teratogenic exposure of C57Bl/6J mouse embryos to ethanol in vivo results, within 12 hours of initial insult, in excessive cell death in selected cell populations. The patterns of excessive cell death observed following exposure of gestational day 8 embryos (late presomite--approximately 5 somite pair stages) vary somewhat temporospatially, but primarily involve the cell populations at the rim of the anterior neural plate. The cell death patterns appear to be pathogenically correlated with subsequently observed malformations including exencephaly (anencephaly), arhinencephaly, pituitary dysplasia, bilateral or unilateral cleft lip, maxillary hypoplasia, and median facial deficiencies and clefts. The association of these brain and facial malformations in this model, and perhaps in humans, may be accounted for by early insult to the selected cell populations identified in the current investigation.

Pathogenesis of craniofacial and body wall malformations induced by ochratoxin A in mice.

Ochratoxin A (OA), a mycotoxin commonly found in soils and on moldy food such as cereal grains, is a potent teratogen. The present investigation was designed to examine the teratogenicity of OA administered acutely at early post-implantation stages in mice, with particular emphasis on the pathogenetic basis of induced malformations. Maternal OA administration on gestational day (GD) 7 or 8 resulted in excessive amounts of cell death in selected cell populations. After a single dose of 2-4 mg/kg, excessive cell death was notable within 6 hours, and persisted to 36 hours post-treatment. As observed in GD 14 or 18 fetuses, the spectrum of induced craniofacial malformations included exencephaly, midfacial clefting, cleft lip, as well as hypotelorism, and synophthalmia associated with holoprosencephaly. Body wall defects involved either the abdominal wall alone, or in combination with the thoracic wall, resulting in partial or complete exposure of the viscera. Potential mechanisms for OA-induced selective cell killing are discussed.

Interference with gastrulation during the third week of pregnancy as a cause of some facial abnormalities and CNS defects.

During the third week of pregnancy the human embryo undergoes a major developmental process, gastrulation, during which the two-layered embryo is converted into a three-layered embryo. At the same time, the upper epiblast layer is induced to form the neural plate. Evidence is presented which suggests that interference with this process by genetic, physical, or chemical agents can cause a range of CNS abnormalities and facial abnormalities, including those described as characteristic of the FAS.

Pathogenesis of malformations in a rodent model for Smith-Lemli-Opitz syndrome.

The fact that Smith-Lemli-Opitz syndrome (SLOS), a syndrome comprising major malformations involving a number of organ systems, results from an abnormality in cholesterol biosynthesis, was discovered only recently. Utilizing a drug (BM 15.766) to inhibit the same step in cholesterol biosynthesis as is abnormal in those affected with SLOS, we have developed a rat model that presents with abnormalities observed as early as gestational day 12 that appear to be consistent with some of those subsequent malformations that comprise the human syndrome. Abnormalities of the brain and face include deficiency in the midline region of the upper face, narrowing of the forebrain hemispheres and of the cerebral aqueduct, and deficiency in the developing lower jaw. Associated pathogenesis, as observed on gestational day 11 in histological sections and with scanning electron microscopy, involves abnormal cell populations at the rim of the developing forebrain and in the alar plate of the lower midbrain and hind-brain. The affected cells appear abnormally rounded up, having apparently lost their normal cell contacts. The potential basis for the selective vulnerability of this cell population and the impact of its vulnerability relative to subsequent dysmorphogenesis is discussed.

Mandibulofacial dysostosis (Treacher Collins syndrome): a new proposal for its pathogenesis.

Acute exposure to 400 mg/kg 13-cis retinoic acid (13-cis RA, isotretinoin, Accutane) on the ninth day postfertilization in mice (a time that corresponds to the fourth week postfertilization in humans) results in malformations that characterize mandibulofacial dysostosis (MFD, Treacher Collins syndrome). Deficiencies in the infraorbital region and in the mandibular ramus and condyle, abnormalities of the secondary palate, and external ear malformations were observed. Light and scanning electron microscopic analyses of affected embryos illustrate that within 12 hours of maternal 13-cis RA treatment, markedly excessive (possibly premature) cell death occurs in regions where some of the cells are normally destined to undergo programmed cell death. Previous studies with retinoids have shown that they labilize lysosomal membranes and expand and strengthen regions of programmed cell death. Of particular interest for this study was cell death occurring in the dorsal (proximal) aspects of the maxillary and mandibular prominences of the first visceral arch, the second visceral arch, and the first visceral cleft, areas that correspond to the locations of the first and second arch ectodermal ("ganglionic") placodes and first closing membrane, respectively. The derivatives of this region are those that are severely affected in MFD. As described in previous reports from this laboratory, 13-cis RA is known to interfere with neural crest cells, resulting in major craniofacial malformations. However, the exposure times involved were earlier than those described herein. It is hypothesized that effects on the first and second arch ectodermal placodal cells at a time following the release from the neural folds of neural crest cells into the developing cranial region are of great significance in the pathogenesis of MFD. This is in contrast to the prevailing hypothesis that these malformations are the direct result of a primary interference with neural crest cells.

Limb, genital, CNS, and facial malformations result from gene/environment-induced cholesterol deficiency: further evidence for a link to sonic hedgehog.

Low cholesterol levels produced by treating cholesterol deficient mutant mice with a cholesterol synthesis inhibitor (BM 15.766) between days 4 to 7 of pregnancy resulted in malformations consistent with those in the Smith-Lemli-Opitz syndrome (SLOS). Facial anomalies in mildly affected gestational day 12 mouse embryos included a small nose and long upper lip; in more severely affected embryos, the facial and forebrain anomalies are representative of holoprosencephaly. Additionally, abnormalities of the mid- and hind-brain were observed and included stenosis of the cerebral aqueduct at the level of the isthmus and apparent absence of the organ progenitor for the cerebellar vermis. Although not previously directly linked to cholesterol deficiency in experimental animals, limb and external genital defects were a notable outcome in this multifactorially-based cholesterol deficiency model. The results of this study provide new evidence supporting an important role for cholesterol in early embryonic development, provide additional support for the hypothesis that this role may involve the function of specific gene products, such as sonic hedgehog (shh) signaling protein, and provide a description of the pathogenesis of some of the characteristic malformations in SLOS.

Fetal alcohol syndrome. Eye malformations in a mouse model.

Acute maternal ethanol administration on gestational day 7 (gastrulation stage) in C57Bl/6J mice results in a spectrum of ocular malformations. A deficiency in the anterior neural plate observable within 24 hours of exposure results in corresponding defects in the optic sulcus and subsequent optic vesicle. Deficiency in the size of the lens vesicle induced by a small optic vesicle is demonstrable as microphakia in older embryos. Delayed detachment of the lens vesicle from the surface ectoderm manifests in the live offspring as progressive corneal opacification and vascularization related to defects in corneal endothelium and Descemet's membrane. Anterior segment dysgenesis results in persistent iridocorneal adhesions, dyscoria, and abnormal formation of the anterior chamber. In contrast, ethanol exposure on day 8 of gestation did not result in eye malformations. Thus, it appears that many of the ocular abnormalities associated with fetal alcohol syndrome may result from an acute insult to the optic primordia during a very specific period that corresponds to the third week after fertilization in the human.

Postulated mechanisms underlying the development of neural tube defects. Insights from in vitro and in vivo studies.

In recent years, use of animal models has resulted in acquisition of a significant amount of new information regarding normal and abnormal neural tube development. Studies of mutant and of teratogen-exposed mice are complementary, with each providing insights that promise to advance our understanding of the other. Analysis of teratogen-exposed embryos is best suited for identifying susceptible developmental stages and vulnerable populations. Advances in molecular genetics, with the ability to identify gene products, their cell/tissue location, and, potentially, to understand their function, will make naturally occurring as well as man-made mutants invaluable for understanding the heterogeneous mechanisms that underly NTDs.

The development of stereociliary bundles in the cochlear duct of chick embryos.

The differentiation of hair cell stereociliary bundles was investigated during early stages of embryonic development in the chick cochlear duct. The ultrastructural characteristics of the differentiating stereocilia and the position of the hair cells at the time of their differentiation were determined with scanning (SEM) and transmission (TEM) electron microscopy. Stereocilia were first identifiable with SEM as early as embryonic day 6 (stage 29) in only the distal region of the basilar papilla. By embryonic day 7.5 (stage 32) stereocilia were detected with both SEM and TEM on hair cells located in the distal two-thirds of the basilar papilla. Stereociliary bundles were recognizable throughout the entire basilar papilla by embryonic day 9 (stage 35). At this stage the hair cells exhibited a distal-to-proximal gradient in the cell surface area and the number of stereocilia on each hair cell. These results suggest that there is a distal-to-proximal wave of hair cell differentiation which occurs at a very early time period in the development of the chick cochlea. Both the timing and the direction of the stereociliary differentiation contrast with previous ultrastructural reports of avian hair cell development, yet compare favorably with the patterns of functional development in the auditory system.

Patterns of ethanol-induced cell death in the developing nervous system of mice; neural fold states through the time of anterior neural tube closure.

Vital staining and routine histological analyses of mouse embryos 12 h after acute maternal ethanol administration (2.9 g/kg) illustrated that selected neuronal cell populations are killed. At the time of treatment, embryos had 5-15 somite pairs, corresponding to the developmental stages occurring in humans during the fourth week of post-fertilization; i.e. when neural folds are present and neural tube fusion begins. Affected cell populations in embryos having 6-26 somite pairs (up to the stage of anterior neuropore closure) were in discrete locations in the alar and basal plates of the rhombencephalon, in the otic placode/vesicle, and in the regions of the epibranchial placodes, olfactory placodes and trigeminal ganglion. The potential basis for the vulnerability of these cell populations to ethanol-induced cell death is discussed. Our understanding of the scope of ethanol-induced CNS damage is dependent upon further defining ethanol-sensitive cell populations at all stages of CNS development.

Brain malformations in prenatal mice following acute maternal ethanol administration.

Acute maternal ethanol administration (two i.p. injections of 2.9 g ethanol/kg maternal body wt) to C57B1/6J mice during gastrulation stages of embryogenesis (gestational day 7) induces a spectrum of brain and facial malformations characteristic of those seen in the human Fetal Alcohol Syndrome. Scanning electron microscopic and light microscopic analyses of the brains of embryos of gestational days 11-14 demonstrate ventro-medial forebrain deficiencies of varying degrees of severity in affected specimens. Even at the mild end of the spectrum, reductions in the size of the septal nuclei and the shape of the third ventricle are observed. As the severity of the effect increases, the septal nuclei disappear altogether, resulting in midline fusion of the corpora striata (basal ganglia). In such cases, the third ventricle is totally absent anteriorly (preoptic area) and significantly narrowed at more posterior levels, adjacent to the ventromedial nuclei. In addition, the hippocampal primordium is absent at levels which include the corpora striata, and septation of the cerebral cortex is incomplete. More posteriorly, at the level of the posterior commissure, the hippocampal primordium is present, but greatly reduced in size, and the entire brain is distinctly narrower in width. Still further posteriorly, at levels of the metencephalon which include the tectum and cerebellar plate, the cerebral aqueduct is significantly expanded, fusion of midline (raphe) structures is incomplete and the cerebellar plate does not extend as far medially as it does normally. Interestingly, these abnormalities are analogous to those observed in the holoprosencephaly series of malformations. The results of the present study support our hypothesis that severe forms of the Fetal Alcohol Syndrome mimic certain aspects of the holoprosencephaly spectrum, and indicate that special attention should be paid to possible deficiencies in the septal nuclei and basal ganglia of children born to women who abuse alcohol. The fact that gross brain malformations can be induced in this animal model at a time corresponding to the third week of human gestation (a time when most women remain unaware of pregnancy) is of significance in terms of the possible prevention of alcohol-induced birth defects and mental deficiency in man.

Development of neurotransmitter systems in the mouse embryo following acute ethanol exposure: a histological and immunocytochemical study.

Acute maternal ethanol administration to C57B1/6J mice on gestational day 7 (GD7) results in facial and brain abnormalities similar to those reported in human fetal alcohol syndrome (FAS). Using this model, we assessed the damage to brain structures using histological methods and changes in developing neurotransmitter systems with immunocytochemistry. Cholinergic neurons in the forebrain were stained with a monoclonal antibody to choline acetyltransferase (ChAT). Catecholaminergic neurons in the midbrain and serotoninergic neurons in the hindbrain were stained with polyclonal antisera to tyrosine hydroxylase (TH) and serotonin (5-HT), respectively. Forebrain deficiencies, including loss of midline structures (olfactory bulbs, midline septation, medial septal area) and deficits in lateral and dorsal regions (neostriatum and cerebral cortex) were found in both GD14 embryos and GD18 fetuses. In severely affected offspring, complete loss of the septal region resulted in conjoined lateral ventricles and a reduction in the thickness of the ventricular zone surrounding the single ventricle, as well as a severe loss of ChAT neurons which would normally be located in this territory. However, no consistent changes were seen in the distribution or size of TH or 5-HT neuronal cell groups in the midbrain and hindbrain. These differences in effects on specific neurotransmitter systems reflect the fact that the forebrain is most severely affected by early ethanol administration, whereas the hindbrain is relatively spared. Such differential effects could produce an imbalance in developing neurotransmitter systems in the embryonic and fetal brain, which could explain some of the functional deficits observed in children with FAS.

Abnormal serotonergic development in a mouse model for the Smith-Lemli-Opitz syndrome: implications for autism.

The Smith-Lemli-Opitz syndrome (SLOS) is a malformation/mental retardation syndrome resulting from an inborn error in 3beta-hydroxysteroid Delta7-reductase (DHCR7), the terminal enzyme required for cholesterol biosynthesis. Using a targeting strategy designed to virtually eliminate Dhcr7 activity, we have created a SLOS mouse model that exhibits commissural deficiencies, hippocampal abnormalities, and hypermorphic development of serotonin (5-HT) neurons. The latter is of particular interest with respect to current evidence that serotonin plays a significant role in autism spectrum disorders and the recent clinical observation that 50% of SLOS patients present with autistic behavior. Immunohistochemical analyses have revealed a 306% increase in the area of 5-HT immunoreactivity (5-HT IR) in the hindbrains of mutant (Dhcr7-/-) mice as compared to age-matched wild type animals. Amount of 5-HT IR was measured as total area of IR per histological section. Additionally, a regional increase as high as 15-fold was observed for the most lateral sagittal hindbrain sections. In Dhcr7-/- mice, an expansion of 5-HT IR into the ventricular zone and floor plate region was observed. In addition, the rostral and caudal raphe groups exhibited a radial expansion in Dhcr7-/- mice, with 5-HT IR cells present in locations not seen in wild type mice. This increase in 5-HT IR appears to represent an increase in total number of 5-HT neurons and fibers. These observations may help explain the behavioral phenotype seen in SLOS, and provide clues for future therapeutic interventions that utilize pharmacological modulation of the serotonergic system.