Esx1 is an X-chromosome-imprinted regulator of placental development and fetal growth.

In marsupials and mice, the paternally derived X chromosome is preferentially inactivated in the placental tissues of female embryos. We show here that the X-linked homeobox gene Esx1 (refs 5,6), whose expression is restricted to extraembryonic tissues, is a chromosomally imprinted regulator of placental morphogenesis and trophoblast differentiation. Heterozygous female mice that inherited a mutant Esx1 allele from their father developed normally. Heterozygous females that inherited the Esx1 mutation from their mother, however, were born 20% smaller than normal and are identical in phenotype to hemizygous mutant males and homozygous mutant females. Although Esx1 mutant embryos were initially comparable in size with controls at 13.5 days post coitum (dpc), their placentas were significantly larger. Defects in the morphogenesis of the labyrinthine layer were observed as early as 11.5 dpc. Subsequently, vascularization abnormalities developed at the maternal-fetal interface, causing fetal growth retardation. These results identify Esx1 as the first essential X-chromosome-imprinted regulator of placental development that influences fetal growth, and may aid our understanding human placental insufficiency syndromes.

Prenatal folic acid treatment suppresses acrania and meroanencephaly in mice mutant for the Cart1 homeobox gene.

The paired-class homeobox-containing gene, Cart1, is expressed in forebrain mesenchyme, branchial arches, limb buds and cartilages during embryogenesis. Here, we show that Cart1-homozygous mutant mice are born alive with acrania and meroanencephaly but die soon after birth-a phenotype that strikingly resembles a corresponding human syndrome caused by a neural tube closure defect. Developmental studies suggest that Cart1 is required for forebrain mesenchyme survival and that its absence disrupts cranial neural tube morphogenesis by blocking the initiation of closure in the midbrain region that ultimately leads to the generation of lethal craniofacial defects. Prenatal treatment of Cart1 homozygous mutants with folic acid suppresses the development of the acrania/meroanencephaly phenotype.

Requirement for Wnt3 in vertebrate axis formation.

Several studies have implicated Wnt signalling in primary axis formation during vertebrate embryogenesis, yet no Wnt protein has been shown to be essential for this process. In the mouse, primitive streak formation is the first overt morphological sign of the anterior-posterior axis. Here we show that Wnt3 is expressed before gastrulation in the proximal epiblast of the egg cylinder, then is restricted to the posterior proximal epiblast and its associated visceral endoderm and subsequently to the primitive streak and mesoderm. Wnt3-/- mice develop a normal egg cylinder but do not form a primitive streak, mesoderm or node. The epiblast continues to proliferate in an undifferentiated state that lacks anterior-posterior neural patterning, but anterior visceral endoderm markers are expressed and correctly positioned. Our results suggest that regional patterning of the visceral endoderm is independent of primitive streak formation, but the subsequent establishment of anterior-posterior neural pattern in the ectoderm is dependent on derivatives of the primitive streak. These studies provide genetic proof for the requirement of Wnt3 in primary axis formation in the mouse.

Sox9 is required for cartilage formation.

Chondrogenesis results in the formation of cartilages, initial skeletal elements that can serve as templates for endochondral bone formation. Cartilage formation begins with the condensation of mesenchyme cells followed by their differentiation into chondrocytes. Although much is known about the terminal differentiation products that are expressed by chondrocytes, little is known about the factors that specify the chondrocyte lineage. SOX9 is a high-mobility-group (HMG) domain transcription factor that is expressed in chondrocytes and other tissues. In humans, SOX9 haploinsufficiency results in campomelic dysplasia, a lethal skeletal malformation syndrome, and XY sex reversal. During embryogenesis, Sox9 is expressed in all cartilage primordia and cartilages, coincident with the expression of the collagen alpha1(II) gene (Col2a1) . Sox9 is also expressed in other tissues, including the central nervous and urogenital systems. Sox9 binds to essential sequences in the Col2a1 and collagen alpha2(XI) gene (Col11a2) chondrocyte-specific enhancers and can activate these enhancers in non-chondrocytic cells. Here, Sox9 is identified as a regulator of the chondrocyte lineage. In mouse chimaeras, Sox9-/- cells are excluded from all cartilages but are present as a juxtaposed mesenchyme that does not express the chondrocyte-specific markers Col2a1, Col9a2, Col11a2 and Agc. This exclusion occurred cell autonomously at the condensing mesenchyme stage of chondrogenesis. Moreover, no cartilage developed in teratomas derived from Sox9-/- embryonic stem (ES) cells. Our results identify Sox9 as the first transcription factor that is essential for chondrocyte differentiation and cartilage formation.

Loss of Gcn5l2 leads to increased apoptosis and mesodermal defects during mouse development.

Histone acetyltransferases regulate transcription, but little is known about the role of these enzymes in developmental processes. Gcn5 (encoded by Gcn5l2) and Pcaf, mouse histone acetyltransferases, share similar sequences and enzymatic activities. Both interact with p300 and CBP (encoded by Ep300 and Crebbp, respectively), two other histone acetyltransferases that integrate multiple signalling pathways. Pcaf is thought to participate in many of the cellular processes regulated by p300/CBP (refs 2-8), but the functions of Gcn5 are unknown in mammalian cells. Here we show that the gene Pcaf is dispensable in mice. In contrast, Gcn5l2-null embryos die during embryogenesis. These embryos develop normally to 7.5 days post coitum (d.p.c.), but their growth is severely retarded by 8.5 d.p.c. and they fail to form dorsal mesoderm lineages, including chordamesoderm and paraxial mesoderm. Differentiation of extra-embryonic and cardiac mesoderm seems to be unaffected. Loss of the dorsal mesoderm lineages is due to a high incidence of apoptosis in the Gcn5l2 mutants that begins before the onset of morphological abnormality. Embryos null for both Gcn5l2 and Pcaf show even more severe defects, indicating that these histone acetyltransferases have overlapping functions during embryogenesis. Our studies are the first to demonstrate that specific acetyltransferases are required for cell survival and mesoderm formation during mammalian development.

Normal long bone growth and development in type X collagen-null mice.

To investigate the role of type X collagen in skeletal development, we have generated type X collagen-null mice. Surprisingly, mice without type X collagen were viable and fertile and had no gross abnormalities in long bone growth or development. No differences were detected between the type X collagen-null mice and controls when growth plates of both newborn and 3-week old mice were examined by histology and by immunostaining for extracellular matrix components of bone including osteopontin, osteocalcin and type II collagen. Our results suggest that type X collagen is not required for long bone development. However, mice and humans with dominant acting type X collagen mutations have bone abnormalities, suggesting that only the presence of abnormal type X collagen can modify bone growth and development.

A transgenic insertion upstream of sox9 is associated with dominant XX sex reversal in the mouse.

In most mammals, male development is triggered by the transient expression of the Y-chromosome gene, Sry, which initiates a cascade of gene interactions ultimately leading to the formation of a testis from the indifferent fetal gonad. Several genes, in particular Sox9, have a crucial role in this pathway. Despite this, the direct downstream targets of Sry and the nature of the pathway itself remain to be clearly established. We report here a new dominant insertional mutation, Odsex (Ods), in which XX mice carrying a 150-kb deletion (approximately 1 Mb upstream of Sox9) develop as sterile XX males lacking Sry. During embryogenesis, wild-type XX fetal gonads downregulate Sox9 expression, whereas XY and XX Ods/+ fetal gonads upregulate and maintain its expression. We propose that Ods has removed a long-range, gonad-specific regulatory element that mediates the repression of Sox9 expression in XX fetal gonads. This repression would normally be antagonized by Sry protein in XY embryos. Our data are consistent with Sox9 being a direct downstream target of Sry and provide genetic evidence to support a general repressor model of sex determination in mammals.

Early embryonic lethality in genetically engineered mice: diagnosis and phenotypic analysis.

Embryonic lethality is a common phenotype that occurs in mice that are homozygous for genetically engineered mutations. These phenotypes highlight the time and place that a gene is first required during embryogenesis. Early embryonic lethality (ie, before and up to mid-gestation) can be straightforward to analyze because the stage at which death occurs suggests why an embryo has failed. Here we summarize general strategies for analyzing early embryonic lethal phenotypes in genetically engineered mouse mutants.

Phenotypic characterization of epiphycan-deficient and epiphycan/biglycan double-deficient mice.

OBJECTIVE: To characterize the in vivo role epiphycan (Epn) has in cartilage development and/or maintenance. METHODS: Epn-deficient mice were generated by disrupting the Epn gene in mouse embryonic stem cells. Epn/biglycan (Bgn) double-deficient mice were produced by crossing Epn-deficient mice with Bgn-deficient mice. Whole knee joint histological sections were stained using van Gieson or Fast green/Safranin-O to analyze collagen or proteoglycan content, respectively. Microarray analysis was performed to detect gene expression changes within knee joints. RESULTS: Epn-deficient and Epn/Bgn double-deficient mice appeared normal at birth. No significant difference in body weight or femur length was detected in any animal at 1 month of age. However, 9-month Epn/Bgn double-deficient mice were significantly lighter and had shorter femurs than wild type mice, regardless of gender. Male Epn-deficient mice also had significantly shorter femurs than wild type mice at 9 months. Most of the deficient animals developed osteoarthritis (OA) with age; the onset of OA was observed earliest in Epn/Bgn double-deficient mice. Message RNA isolated from Epn/Bgn double-deficient knee joints displayed increased matrix protein expression compared with wild type mice, including other small leucine-rich proteoglycan (SLRP) members such as asporin, fibromodulin and lumican. CONCLUSION: Similar to other previously studied SLRPs, EPN plays an important role in maintaining joint integrity. However, the severity of the OA phenotype in the Epn/Bgn double-deficient mouse suggests a synergy between these two proteins. These data are the first to show a genetic interaction involving class I and class III SLRPs in vivo.

The transcription factors L-Sox5 and Sox6 are essential for cartilage formation.

L-Sox5 and Sox6 are highly identical Sry-related transcription factors coexpressed in cartilage. Whereas Sox5 and Sox6 single null mice are born with mild skeletal abnormalities, Sox5; Sox6 double null fetuses die with a severe, generalized chondrodysplasia. In these double mutants, chondroblasts poorly differentiate. They express the genes for all essential cartilage extracellular matrix components at low or undetectable levels and initiate proliferation after a long delay. All cartilages are thus extracellular matrix deficient and remain rudimentary. While chondroblasts in the center of cartilages ultimately activate prehypertrophic chondrocyte markers, epiphyseal chondroblasts ectopically activate hypertrophic chondrocyte markers. Thick intramembranous bone collars develop, but the formation of cartilage growth plates and endochondral bones is disrupted. L-Sox5 and Sox6 are thus redundant, potent enhancers of chondroblast functions, thereby essential for endochondral skeleton formation.

Human sickle hemoglobin in transgenic mice.

DNA molecules that contain the human alpha- and beta s-globin genes inserted downstream of erythroid-specific, deoxyribonuclease I super-hypersensitive sites were coinjected into fertilized mouse eggs and a transgenic mouse line was established that synthesizes human sickle hemoglobin (Hb S). These animals were bred to beta-thalassemic mice to reduce endogenous mouse globin levels. When erythrocytes from these mice were deoxygenated, greater than 90 percent of the cells displayed the same characteristic sickled shapes as erythrocytes from humans with sickle cell disease. Compared to controls the mice have decreased hematocrits, elevated reticulocyte counts, lower hemoglobin concentrations, and splenomegaly, which are all indications of the anemia associated with human sickle cell disease.

Synthesis of functional human hemoglobin in transgenic mice.

Human alpha- and beta-globin genes were separately fused downstream of two erythroid-specific deoxyribonuclease (DNase) I super-hypersensitive sites that are normally located 50 kilobases upstream of the human beta-globin gene. These two constructs were coinjected into fertilized mouse eggs, and expression was analyzed in transgenic animals that developed. Mice that had intact copies of the transgenes expressed high levels of correctly initiated human alpha- and beta-globin messenger RNA specifically in erythroid tissue. An authentic human hemoglobin was formed in adult erythrocytes that when purified had an oxygen equilibrium curve identical to the curve of native human hemoglobin A (Hb A). Thus, functional human hemoglobin can be synthesized in transgenic mice. This provides a foundation for production of mouse models of human hemoglobinopathies such as sickle cell disease.

Insulin-like growth factor I increases brain growth and central nervous system myelination in transgenic mice.

Insulin-like growth factor I (IGF-I) is a potent regulator of oligodendrocyte development and myelination in vitro, but its effect on myelination in vivo has never been tested directly. Therefore, we examined brain growth and myelination in a transgenic mouse line that overexpresses IGF-I. By postnatal day 55, when brain growth and myelination are essentially complete in normal mice, the brains of transgenic mice were 55% larger than those of controls owing to an increase in cell size and apparently in cell number. Most or all brain structures appeared to be affected. At the same time, total myelin content of the transgenic mice was 130% greater than that of controls. Oligodendrocyte number as a percentage of total cell number was not increased in the transgenic mouse brains; the increase in myelin content was primarily the result of an increase in myelin production per oligodendrocyte. These findings indicate that IGF-I is a potent inducer of brain growth and myelination in vivo.

Oncogene expression in retinal horizontal cells of transgenic mice results in a cascade of neurodegeneration.

The phenylethanolamine N-methyltransferase promoter directs the expression of the SV40 T antigen to subsets of amacrine and horizontal neurons of the retina in a line of transgenic mice. T antigen expression begins in these cells during the first postnatal week. The horizontal cells appear to develop normally for another week but then begin to die. Subsequently, most of the horizontal cells disappear from the central and mid retina, resulting in loss of the outer plexiform layer and absence of ribbon synapses between the photoreceptors and bipolar cells. Neuronal transformation occurs only in the peripheral retina. These experiments indicate that horizontal neurons are heterogeneous with respect to susceptibility to transformation and that T antigen expression in a subset of horizontal neurons can be a direct cause of neuronal cell death. Furthermore, critical interdependencies exist between horizontal neurons after retinal neurogenesis is complete.

P0 promoter directs expression of reporter and toxin genes to Schwann cells of transgenic mice.

We generated transgenic mice that specifically express foreign genes in myelinating Schwann cells. A 1.1 kb segment of 5' flanking sequence from the rat P0 gene was used to drive expression of the genes encoding human growth hormone (hGH) and bacterial diphtheria toxin A chain (DT-A). The P0-hGH mice expressed hGH in myelinating Schwann cells, but not in nonmyelinating Schwann cells, the central nervous system, or any other tissue assayed. This expression was activated on a developmental schedule comparable to that of endogenous myelin gene expression. One line of P0-DT-A mice developed a generalized hypomyelinating peripheral neuropathy, with Schwann cell deficiency apparent in newborn animals. Peripheral nerves from adult mice of this line displayed morphological alterations ranging from completely denuded axons to myelinated Schwann cells undergoing degeneration, although occasional Schwann cells were able to form apparently normal myelin sheaths. Pronounced secondary changes, including proliferation and retraction of processes, occurred in the nonmyelinating Schwann cells of these P0-DT-A mice.

Immortalized retinal neurons derived from SV40 T-antigen-induced tumors in transgenic mice.

Immortalized retinal neurons have been established in tissue culture from retinal tumors arising in transgenic mice. The mice carry the SV40 T-antigen under the control of 5' flanking sequences from the human phenylethanolamine N-methyltransferase (PNMT) gene in order to target oncogene expression to adrenergic cell types. The retinal cultures contain a proliferation population of T-antigen-positive cells with a neuronal morphology that includes formation of extensive neuritic processes. We identified the cells as amacrine-derived neurons by immunofluorescence using the cell-specific monoclonal antibodies VC1.1 and HPC-1. The cells also express all three neurofilament subunits and GAP-43. These results indicate that CNS neurons can be transformed in transgenic animals to generate cultured cells with many properties of mature neurons.

Human globin locus activation region (LAR): role in temporal control.

A region of DNA located far upstream of the human beta-globin locus is critically involved in the regulation of the beta-globin gene family. Recent experiments in transgenic mice suggest that switching from fetal to adult globin gene expression during human development results from competition among individual globin gene family members for interaction with sequences in this region. The phenotypes of patients with defined hemoglobinopathies support this hypothesis.

Expression from the transferrin gene promoter in transgenic mice.

Transferrin is an iron-binding protein that is expressed as a major product in liver and secreted into the plasma. To study the tissue-specific regulatory regions of this gene, the genomic mouse transferrin (mTf) gene was cloned and characterized by partial sequence analysis and S1 nuclease mapping of the transcriptional start site. Fusion genes containing the transferrin gene promoter and 5'-flanking sequences were ligated to the human growth hormone (hGH) gene and used to produce transgenic mice. A deletion construct containing the -581 to +50 region of the transferrin gene was sufficient to direct a high level of liver-specific expression resembling endogenous transferrin gene expression. Deletion to -139 base pairs of 5'-flanking sequence gave a construct which retained liver specificity, but the magnitude of expression decreased severalfold. These results demonstrate the presence of a liver-specific transcriptional element between -139 and +50 and suggest the presence of a distal element between -581 and -139 that can further increase expression. Surprisingly, fusion constructs containing -3 kilobase pairs (kb) of 5'-flanking sequence gave higher levels of mRNA in nonhepatic tissues than did either the -581 or -139 construct. Further studies indicated that the high levels of circulating hGH in these transgenic mice specifically induced the endogenous transferrin and albumin genes in liver and also stimulated the normally low levels of expression of the endogenous transferrin gene in brain, heart, kidney, and muscle. A mutated hGH gene that does not produce active growth hormone was fused to the -3- to +50-kb transferrin sequences to produce the -3-kb mTf-hGX construct. A liver-specific pattern of expression was observed in transgenic mice harboring the -3-kb mTf-hGX construct, and this mutated transgene was shown to be induced four- to sevenfold by either bovine or human growth hormone. These results demonstrate the presence of a growth hormone-responsive element between -3 and +50 kb in the 5'-flanking region of the mTf gene promoter.

A C/EBP-binding site in the transferrin promoter is essential for expression in the liver but not the brain of transgenic mice.

The gene for the iron-binding protein transferrin is transcribed at a high level in liver hepatocytes but is also active in several other cell types, including oligodendrocytes in the brain. Enhancer elements between bp -560 and -44 of the transferrin gene promoter specifically activated transcription from a heterologous promoter in transgenic mouse liver and brain. Within this region, a potent cis-acting element between bp -98 and -83 was found to be essential for gene activity in both cultured hepatocytes and transgenic mouse liver. The -98 to -83 element contains a CCAAT sequence and is specifically bound by a nuclear factor from mouse liver that is homologous to rat liver C/EBP (CAAT enhancer-binding protein). Point mutations within this binding site inhibit factor binding and abolish transcription in transfected hepatoma cells. When placed in the context of the 3,000-bp transferrin promoter, the C/EBP binding site mutation causes a complete loss of transcription in transgenic mouse liver; however, transgene expression in the brain of the same animals was unaffected. These results suggest a modular structure for the transferrin promoter and demonstrate that deletions or specific point mutations can be used to generate transgene promoters with an activity more restricted than that of their endogenous counterparts.

Targeted disruption of the transition protein 2 gene affects sperm chromatin structure and reduces fertility in mice.

During mammalian spermiogenesis, major restructuring of chromatin takes place. In the mouse, the histones are replaced by the transition proteins, TP1 and TP2, which are in turn replaced by the protamines, P1 and P2. To investigate the role of TP2, we generated mice with a targeted deletion of its gene, Tnp2. Spermatogenesis in Tnp2 null mice was almost normal, with testis weights and epididymal sperm counts being unaffected. The only abnormality in testicular histology was a slight increase of sperm retention in stage IX to XI tubules. Epididymal sperm from Tnp2-null mice showed an increase in abnormal tail, but not head, morphology. The mice were fertile but produced small litters. In step 12 to 16 spermatid nuclei from Tnp2-null mice, there was normal displacement of histones, a compensatory translationally regulated increase in TP1 levels, and elevated levels of precursor and partially processed forms of P2. Electron microscopy revealed abnormal focal condensations of chromatin in step 11 to 13 spermatids and progressive chromatin condensation in later spermatids, but condensation was still incomplete in epididymal sperm. Compared to that of the wild type, the sperm chromatin of these mutants was more accessible to intercalating dyes and more susceptible to acid denaturation, which is believed to indicate DNA strand breaks. We conclude that TP2 is not a critical factor for shaping of the sperm nucleus, histone displacement, initiation of chromatin condensation, binding of protamines to DNA, or fertility but that it is necessary for maintaining the normal processing of P2 and, consequently, the completion of chromatin condensation.