Malformation of incisor teeth in Grem2⁻/⁻ mice.

GREMLIN 2 (GREM2)--formerly, protein related to Dan and cerberus (PRDC)-is a potent antagonist of the bone morphogenetic proteins 2 and 4, but little else in known about its functions. We found that Grem2(-/-) mice developed small deformed mandibular and maxillary incisors, indicating that GREMLIN2 is required for normal tooth morphogenesis. Although DEXA scans suggested that bone mineral density might be increased in Grem2(-/-) mice, histology did not reveal any evident bone phenotype. Grem2(-/-) mice did not display any other notable phenotypes evaluated in a high-throughput screening process that encompassed a range of immunologic, metabolic, ophthalmic, and behavioral parameters. Our findings indicate that Grem2 can be added to the growing list of genes that affect tooth development in mice.

Ocular albinism and hypopigmentation defects in Slc24a5-/- mice.

As part of a high-throughput mutagenesis and phenotyping process designed to discover novel drug targets, we generated and characterized mice with a targeted mutation in Slc24a5, a gene encoding a putative cation exchanger. Upon macroscopic examination, Slc24a5-/- mice were viable, fertile, and indistinguishable by coat color from their heterozygous and wild-type litter mates. Ophthalmoscopic examination revealed diffuse retinal hypopigmentation, and a histologic examination of the eye confirmed the presence of moderate-to-marked hypopigmentation of the retinal pigmented epithelium (RPE), ciliary body, and iris pigment epithelium (IPE). Hypopigmentation was most severe in the anterior layer cells of the IPE, where melanosomes were smaller, paler, and more indistinct than those of the anterior stroma and posterior IPE. The pigment granules of the posterior IPE appeared to be nearly as dark as those in stromal melanocytes; however, both cell layers were thinner and paler than corresponding layers in wild-type mice. Ultrastructural analysis of the RPE, IPE, and ciliary body pigmented cells confirmed that mutation of Slc24a5 results in marked hypopigmentation of melanosomes in optic cup-derived pigmented neuroepithelium in the eyes. Milder reductions in melanosome size and pigmentation were noted in neural crest-derived melanocytes. The severe hypopigmentation of neuroepithelium-derived cells in the eyes resulted in a novel form of ocular albinism in Slc24a5-/- mice. Our findings suggest that SLC24A5 may be a candidate gene for some forms of ocular albinism and for the BEY1/EYCL2 locus previously associated with central brown eye color in humans.

4S neuroblastoma: the long-term outcome.

BACKGROUND: Stage 4S neuroblastoma is associated with a high rate of spontaneous maturation and involution, with survival rates of 70-90%. There is little long-term follow-up data describing the disease status or late effects. The aim of this study was to assess the clinical outcome and imaging findings in long-term survivors of 4S neuroblastoma. METHODS: The patient population was identified from a single centre over 26 years. Twenty-five of 31 consecutive patients were long-term survivors. Five died from disease progression and one from cerebral palsy related complications. All survivors underwent clinical examination. Abdominal ultrasound scanning, liver function tests, hepatitis viral screen, and urinary catecholamines were performed. RESULTS: The mean age at diagnosis was 8 +/- 9 weeks with a mean age when studied of 11 years and 10 months +/- 8 years. Twenty of 25 had no significant clinical findings, three had disease associated clinical abnormalities (neurological, multiple subcutaneous nodules). Three patients had treatment related effects (small testes, urethral stricture, radiation induced soft tissue hypoplasia, post-surgical Horners syndrome). Persistant adrenal enlargement and calcification was noted in three patients. Twelve patients had abnormal liver ultrasound findings ranging from mildly coarse echotexture to structural changes without evidence of hepatic dysfunction or infection. Treatment did not correlate with abnormal hepatic ultrasound findings. CONCLUSIONS: The majority of long-term survivors of stage 4S neuroblastoma have no clinically or radiologically significant sequelae but do have residual abnormalities. These findings have implications for subsequent management of unrelated medical conditions in this patient group.

Knock-out mouse for Canavan disease: a model for gene transfer to the central nervous system.

BACKGROUND: Canavan disease (CD) is an autosomal recessive leukodystrophy characterized by deficiency of aspartoacylase (ASPA) and increased levels of N-acetylaspartic acid (NAA) in brain and body fluids, severe mental retardation and early death. Gene therapy has been attempted in a number of children with CD. The lack of an animal model has been a limiting factor in developing vectors for the treatment of CD. This paper reports the successful creation of a knock-out mouse for Canavan disease that can be used for gene transfer. METHODS: Genomic library lambda knock-out shuttle (lambdaKOS) was screened and a specific pKOS/Aspa clone was isolated and used to create a plasmid with 10 base pair (bp) deletion of exon four of the murine aspa. Following linearization, the plasmid was electroporated to ES cells. Correctly targeted ES clones were identified following positive and negative selection and confirmed by Southern analysis. Chimeras were generated by injection of ES cells to blastocysts. Germ line transmission was achieved by the birth of heterozygous mice as confirmed by Southern analysis. RESULTS: Heterozygous mice born following these experiments have no overt phenotype. The homozygous mice display neurological impairment, macrocephaly, generalized white matter disease, deficient ASPA activity and high levels of NAA in urine. Magnetic resonance imaging (MRI) and spectroscopy (MRS) of the brain of the homozygous mice show white matter changes characteristic of Canavan disease and elevated NAA levels. CONCLUSION: The newly created ASPA deficient mouse establishes an important animal model of Canavan disease. This model should be useful for developing gene transfer vectors to treat Canavan disease. Vectors for the central nervous system (CNS) and modulation of NAA levels in the brain should further add to the understanding of the pathophysiology of Canavan disease. Data generated from this animal model will be useful for developing strategies for gene therapy in other neurodegenerative diseases.

Analysis of ku80-mutant mice and cells with deficient levels of p53.

Absence of Ku80 results in increased sensitivity to ionizing radiation, defective lymphocyte development, early onset of an age-related phenotype, and premature replicative senescence. Here we investigate the role of p53 on the phenotype of ku80-mutant mice and cells. Reducing levels of p53 increased the cancer incidence for ku80(-/-) mice. About 20% of ku80(-/-) p53(+/-) mice developed a broad spectrum of cancer by 40 weeks and all ku80(-/-) p53(-/-) mice developed pro-B-cell lymphoma by 16 weeks. Reducing levels of p53 rescued populations of ku80(-/-) cells from replicative senescence by enabling spontaneous immortalization. The double-mutant cells are impaired for the G(1)/S checkpoint due to the p53 mutation and are hypersensitive to gamma-radiation and reactive oxygen species due to the Ku80 mutation. These data show that replicative senescence is caused by a p53-dependent cell cycle response to damaged DNA in ku80(-/-) cells and that p53 is essential for preventing very early onset of pro-B-cell lymphoma in ku80(-/-) mice.

Mouse Gli1 mutants are viable but have defects in SHH signaling in combination with a Gli2 mutation.

The secreted factor Sonic hedgehog (SHH) is both required for and sufficient to induce multiple developmental processes, including ventralization of the CNS, branching morphogenesis of the lungs and anteroposterior patterning of the limbs. Based on analogy to the Drosophila Hh pathway, the multiple GLI transcription factors in vertebrates are likely to both transduce SHH signaling and repress Shh transcription. In order to discriminate between overlapping versus unique requirements for the three Gli genes in mice, we have produced a Gli1 mutant and analyzed the phenotypes of Gli1/Gli2 and Gli1/3 double mutants. Gli3(xt) mutants have polydactyly and dorsal CNS defects associated with ectopic Shh expression, indicating GLI3 plays a role in repressing Shh. In contrast, Gli2 mutants have five digits, but lack a floorplate, indicating that it is required to transduce SHH signaling in some tissues. Remarkably, mice homozygous for a Gli1(zfd )mutation that deletes the exons encoding the DNA-binding domain are viable and appear normal. Transgenic mice expressing a GLI1 protein lacking the zinc fingers can not induce SHH targets in the dorsal brain, indicating that the Gli1(zfd )allele contains a hypomorphic or null mutation. Interestingly, Gli1(zfd/zfd);Gli2(zfd/+), but not Gli1(zfd/zfd);Gli3(zfd/+) double mutants have a severe phenotype; most Gli1(zfd/zfd);Gli2(zfd/+) mice die soon after birth and all have multiple defects including a variable loss of ventral spinal cord cells and smaller lungs that are similar to, but less extreme than, Gli2(zfd/zfd) mutants. Gli1/Gli2 double homozygous mutants have more extreme CNS and lung defects than Gli1(zfd/zfd);Gli2(zfd/+) mutants, however, in contrast to Shh mutants, ventrolateral neurons develop in the CNS and the limbs have 5 digits with an extra postaxial nubbin. These studies demonstrate that the zinc-finger DNA-binding domain of GLI1 protein is not required for SHH signaling in mouse. Furthermore, Gli1 and Gli2, but not Gli1 and Gli3, have extensive overlapping functions that are likely downstream of SHH signaling.

Gli2 is required for induction of floor plate and adjacent cells, but not most ventral neurons in the mouse central nervous system.

Induction of the floor plate at the ventral midline of the neural tube is one of the earliest events in the establishment of dorsoventral (d/v) polarity in the vertebrate central nervous system (CNS). The secreted molecule, Sonic hedgehog, has been shown to be both necessary and sufficient for this induction. In vertebrates, several downstream components of this signalling pathway have been identified, including members of the Gli transcription factor family. In this study, we have examined d/v patterning of the CNS in Gli2 mouse mutants. We have found that the floor plate throughout the midbrain, hindbrain and spinal cord does not form in Gli2 homozygotes. Despite this, motoneurons and ventral interneurons form in their normal d/v positions at 9.5 to 12.5 days postcoitum (dpc). However, cells that are generated in the region flanking the floor plate, including dopaminergic and serotonergic neurons, were greatly reduced in number or absent in Gli2 homozygous embryos. These results suggest that early signals derived from the notochord can be sufficient for establishing the basic d/v domains of cell differentiation in the ventral spinal cord and hindbrain. Interestingly, the notochord in Gli2 mutants does not regress ventrally after 10.5 dpc, as in normal embryos. Finally, the spinal cord of Gli1/Gli2 zinc-finger-deletion double homozygous mutants appeared similar to Gli2 homozygotes, indicating that neither gene is required downstream of Shh for the early development of ventral cell fates outside the ventral midline.

Gli1 is a target of Sonic hedgehog that induces ventral neural tube development.

The vertebrate zinc finger genes of the Gli family are homologs of the Drosophila gene cubitus interruptus. In frog embryos, Gli1 is expressed transiently in the prospective floor plate during gastrulation and in cells lateral to the midline during late gastrula and neurula stages. In contrast, Gli2 and Gli3 are absent from the neural plate midline with Gli2 expressed widely and Gli3 in a graded fashion with highest levels in lateral regions. In mouse embryos, the three Gli genes show a similar pattern of expression in the neural tube but are coexpressed throughout the early neural plate. Because Gli1 is the only Gli gene expressed in prospective floor plate cells of frog embryos, we have investigated a possible involvement of this gene in ventral neural tube development. Here we show that Shh signaling activates Gli1 transcription and that widespread expression of endogenous frog or human glioma Gli1, but not Gli3, in developing frog embryos results in the ectopic differentiation of floor plate cells and ventral neurons within the neural tube. Floor-plate-inducing ability is retained when cytoplasmic Gli1 proteins are forced into the nucleus or are fused to the VP16 transactivating domain. Thus, our results identify Gli1 as a midline target of Shh and suggest that it mediates the induction of floor plate cells and ventral neurons by Shh acting as a transcriptional regulator.

Identification, subcellular localization, and developmental studies of oleosins in the anther of Brassica napus.

mRNAs encoding putative oleosins have been detected in the tapetum of developing anthers in Brassica and Arabidopsis, but the authentic proteins have not been previously documented. Antibodies against a synthetic 15-residue polypeptide that represents a portion of the putative tapetum oleosins encoded by two cloned Brassica napus genes were raised. Using these antibodies for immunoblotting after SDS-PAGE of the sporophytic extracts of B. napus developing anthers, two oleosins of approximately 48 and 45 kDa were detected. These two oleosins were judged to be the putative oleosins encoded by cloned Brassica genes because of their identical N-terminal sequences. The two oleosins were present in the anthers only during the developmental stage when the tapetum cells were packed with organelles. A fraction of lowdensity organelles was isolated from the developing anthers by flotation centrifugation. The fraction contained plastoglobule-filled plastids and lipid-containing particles. The structures of these two isolated organelles were similar to those in situ in the tapetum cells. Of subcellular fractions of the anther homogenate, the two oleosins were present exclusively in the low-density organelle fraction. They were absent in the surface fractions of the developing microspores and the mature pollen, although fragmented oleosin molecules were earlier reported to be present on the pollen. By immunocytochemistry, immunogold particles were found largely on the periphery of the plastoglobuli inside the plastids in the tapetum cells. The antibodies also detected oleosins on the surface of storage oil bodies inside the maturing microspores. Apparently, the gametophytic microspore oil-body oleosins share common epitopes at the generally non-conserved C-terminal domain with the sporophytic tapetum oleosins.

Expression of the mouse Gli and Ptc genes is adjacent to embryonic sources of hedgehog signals suggesting a conservation of pathways between flies and mice.

The three mouse Gli genes are putative transcription factors which are the homologs of cubitus interruptus (ci) in Drosophila. Along with the gene patched (Ptc), ci has been implicated in the hedgehog (Hh) signal transduction pathway. To assess the role of Gli in embryogenesis, we compared its expression with that of Ptc and Hh family members in mouse. We found that Gli and Ptc are expressed in similar domains in diverse regions of the developing mouse embryo and these regions are adjacent to Hh signals. We also show that Gli is expressed ectopically along with Ptc and Shh in Strong's luxoid mutant mice. These results are consistent with conservation of the Hh signal transduction pathway in mice with Gli potentially mediating Hh signaling in multiple regions of the developing embryo.

Isolation and characterization of neutral-lipid-containing organelles and globuli-filled plastids from Brassica napus tapetum.

The monolayer tapetum cells of the maturing flowers of Brassica napus contain abundant subcellular globuli-filled plastids and special lipid particles, both enriched with lipids that are supposed to be discharged and deposited onto the surface of adjacent maturing pollen. We separated the two organelles by flotation density gradient centrifugation and identified them by electron microscopy. The globuli-filled plastids had a morphology similar to those described in other plant species and tissues. They had an equilibrium density of 1.02 g/cm(3) and contained neutral esters and unique polypeptides. The lipid particles contained patches of osmiophilic materials situated among densely packed vesicles and did not have an enclosing membrane. They exhibited osmotic properties, presumably exerted by the individual vesicles. They had an equilibrium density of 1.05 g/cm(3) and possessed triacylglycerols and unique polypeptides. Several of these polypeptides were identified, by their N-terminal sequences or antibody cross-reactivity, as oleosins, proteins known to be associated with seed storage oil bodies. The morphological and biochemical characteristics of the lipid particles indicate that they are novel organelles in eukaryotes that have not been previously isolated and studied. After lysis of the tapetum cells at a late stage of floral development, only the major plastid neutral ester was recovered, whereas the other abundant lipids and proteins of the two tapetum organelles were present in fragmented forms or absent on the pollen surface.

Oleosin genes in maize kernels having diverse oil contents are constitutively expressed independent of oil contents. Size and shape of intracellular oil bodies are determined by the oleosins/oils ratio.

In seeds, the subcellular storage oil bodies have a matrix of oils (triacylglycerols) surrounded by a layer of phospholipids embedded with abundant structural proteins called oleosins. We used two maize (Zea mays L.) strains having diverse kernel (seed) oil contents to study the effects of varying the oil and oleosin contents on the structure of the oil bodies. Illinois High Oils (IHO, 15% w/w oils) and Illinois Low Oils (ILO, 0.5%) maize kernels were the products of breeding for diverse oil contents for about 100 generations. In both maize strains, although the genes for oil synthesis had apparently been modified drastically, the genes encoding oleosins appeared to be unaltered, as revealed by Southern blot analyses of the three oleosin genes and sodium dodecyl sulfate-polyacrylamide gel electrophoresis with immunoblotting of the oleosins. In addition, both strains contained the same three oleosin isoforms of a defined proportion, and both accumulated oils and oleosins coordinately. Oleosins in both strains were restricted to the oil bodies, as shown by analyses of the various subcellular fractions separated by sucrose-density-gradient centrifugation. Electron microscopy of the embryos and the isolated organelles revealed that the oil bodies in IHO were larger and had a spherical shape, whereas those in ILO were smaller and had irregular shapes. We conclude that in seeds, oleosin genes are expressed independent of the oil contents, and the size and shape of the oil bodies are dictated by the ratio of oils to oleosins synthesized during seed maturation. The extensive breeding for diverse oil contents has not altered the apparent mechanism of oil-body synthesis and the occurrence of hetero-dimer or -multimer of oleosin isoforms on the oil bodies.

Independent regulation of adipose tissue-specificity and obesity response of the adipsin promoter in transgenic mice.

Transcription of the adipocyte-specific adipsin gene is dramatically reduced in the adipose tissue of a number of genetically and chemically-induced obese rodents. To map the region of the adipsin gene that confers this response to obesity, transgenic mice were made containing -114, -250, -400, -700, and -938 base pairs (bp) to +35 bp of the promoter linked to the bacterial chloramphenicol acetyltransferase gene. Transgenic mice containing as few as 114 bp of the adipsin promoter had high levels of chloramphenicol acetyltransferase activity in adipose tissue. However, only those mice with 938 bp of the adipsin upstream regulatory region showed suppression of expression in adipose tissue in mice that were induced to become obese with monosodium glutamate. Using gel retardation assays, we showed that a 56-bp fragment of DNA mapping between -687 and -743 bp upstream from the start of adipsin expression was bound by protein factors in nuclear extracts prepared from adipose tissue. There was much greater retardation of this fragment with nuclear extracts prepared from adipose tissue of lean versus obese mice. These results indicate that a tissue-specific transcription factor(s) that regulates adipsin expression is less active in the adipose tissue of obese animals.

Expression of three mouse homologs of the Drosophila segment polarity gene cubitus interruptus, Gli, Gli-2, and Gli-3, in ectoderm- and mesoderm-derived tissues suggests multiple roles during postimplantation development.

Three mouse genes, Gli, Gli-2, and Gli-3, which share a similar zinc finger domain with the products of the Drosophila segment polarity gene cubitus interruptus and the Caenorhabditis elegans sex-determining gene tra-1 were cloned and characterized. The expression patterns during postimplantation development of the three genes were analyzed by Northern blot, whole-mount, and section in situ hybridizations. Expression was first detected during gastrulation in both the ectoderm and mesoderm. Later in development, their expression became more restricted in various ectoderm- and mesoderm-derived tissues and was not detectable after completion of organogenesis. Interestingly, in the developing neural tube, Gli showed a narrow ventral domain of expression, whereas Gli-2 and Gli-3 showed a broad and dorsally restricted domain. Expression of these three Gli genes in various ectoderm- and mesoderm-derived tissues suggests that they play multiple roles during postimplantation development. Consistent with this hypothesis, a naturally occurring Gli-3 mutation, the mouse extra-toes mutant; shows defects in both mesoderm- and ectoderm-derived tissues.

Identification of a fat cell enhancer: analysis of requirements for adipose tissue-specific gene expression.

The molecular basis for adipose-specific gene expression is not known. To approach the problem of adipocyte gene expression, we have analyzed in detail the capacity of the 5'-flanking region of the adipocyte P2 (aP2) gene to direct cell-type specific gene expression. Although the proximal promoter containing AP-1 and C/EBP binding sites is capable of directing differentiation-dependent gene expression in cultured adipocytes, these constructs are essentially inactive in the tissues of transgenic mice. We found that -5.4 kb of the 5'-flanking region were required to direct heterologous gene (chloramphenicol acetyl transferase; CAT) expression to the adipose tissue of transgenic mice. By deletion analysis, we identified a 520 bp enhancer at -5.4 kb of the aP2 gene. We show that this enhancer can direct high levels of gene expression specifically to the adipose tissue of transgenic mice. This enhancer also functions in a differentiation-dependent manner in cultured adipocytes and cannot be transactivated in preadipocytes by C/EBP. Molecular analysis indicates that several cis- and trans- acting acting elements, though not C/EBP, contribute to the specificity and potency of this enhancer.

A fat-specific enhancer is the primary determinant of gene expression for adipocyte P2 in vivo.

The murine gene for adipocyte P2 encodes an adipocyte-specific member of the family of intracellular lipid binding proteins. The region upstream from the start of transcription of this gene has been found to contain binding sites for the transcription factors c-jun/c-fos and C/EBP (CCAAT/enhancer binding protein) and several short sequence elements found in other adipocyte gene promoters, termed fat-specific elements. To identify DNA sequences that were responsible for the high level of transcription of the gene for adipocyte P2 in vivo, we made a series of transgenic mice containing 168 base pairs (bp), 247 bp, 1.7 kilobases (kb), and 5.4 kb of 5' flanking sequence linked to the bacterial gene chloramphenicol acetyltransferase. Although plasmids containing only 168 bp of 5' sequence including the C/EBP and AP-1 (activation protein 1) binding sites were expressed well in cultured adipocytes, high levels of chloramphenicol acetyltransferase activity in the adipose tissue of transgenic mice were not observed until the 5' flanking region was extended to kb -54. An enhancer mapping between kb -4.9 and kb -5.4 upstream from the start of transcription was identified by transfection of further deletions into cultured adipocytes. This enhancer, when linked to a bp -63 promoter fragment from the gene for adipocyte P2, directed very high level chloramphenicol acetyltransferase expression specifically to adipose tissue in transgenic mice. These results identify a functional adipose-specific enhancer and indicate that it is the major determinant of tissue specificity of the gene for adipocyte P2. These results also demonstrate that the proximal-promoter binding sites for AP-1 and C/EBP are not sufficient or necessary to give adipose-tissue-specific expression in vivo, though they may play an important role in the response of this promoter to glucocorticoids.

Obesity-linked regulation of the adipsin gene promoter in transgenic mice.

The mouse adipsin gene encodes a member of the serine protease family that is expressed predominantly in adipose tissue and is secreted into the bloodstream. Adipsin expression is sharply down-regulated in several models of genetic and acquired obesity, representing the first example of an adipocyte gene whose expression is greatly altered in this disorder. In this study, we have asked whether a DNA fragment from the adipsin gene can direct tissue-specific expression of a heterologous gene and mediate the suppression of this expression in genetic and chemically induced obesity. Transgenic mice have been constructed with 950 bases of DNA from the 5' flanking region of the adipsin gene linked to the bacterial chloramphenicol acetyltransferase (CAT) gene in a mouse strain bearing a recessive obesity gene (diabetes, db). By crossing db/+ transgenic mice with nontransgenic db/+ mice, we obtained progeny that allowed a direct comparison of CAT expression in the tissues of lean and obese littermates. The lean mice express CAT activity predominantly in adipose tissue, while the obese mice show a marked reduction in CAT expression relative to the lean controls. When similar experiments are performed with an adipsin-CAT fusion gene containing a heterologous AKV (AKR mouse leukemia virus) enhancer, the tissue specificity of CAT expression in lean mice is broadened to include the thymus, spleen, brain, and other tissues; down-regulation occurs in all of these tissues in mice homozygous for the obesity gene or in mice that have been injected with monosodium glutamate (MSG), which induces obesity. These results indicate that 950 bases of the 5' flanking region of the adipsin gene carry information that specifies both expression in adipose tissue and a response to a gene or chemical that induces obesity. These results also suggest that the trans-acting factors that are regulated aberrantly in these forms of obesity are not restricted to adipose tissue and could play a role in obesity-linked dysfunctions observed in other tissues as well.