Annual Recurrence of the Critically Endangered Bowmouth Guitarfish (Rhina ancylostomus) in Djibouti Waters.

The bowmouth guitarfish (Rhina ancylostomus) is among the most endangered of marine vertebrates, and evidence of severe declines and localized extinctions has been reported. Yet its life history and ecology suffer from a lack of scientific attention due to the scarcity and unpredictable movements of the species. By collecting opportunistic records from 2015 to 2023 during diving activities, this study describes for the first time the occurrence of a predictable aggregation of R. ancylostomus in the Gulf of Tadjoura (Djibouti). These data provide a key record of this species in the area, whose presence is strongly associated with sandy seabeds and corals at approximately 35 m depth. Based on the opportunistic sightings of R. ancylostomus during diving activity, Ras Eiro and Ras Korali appear to be the currently known core habitats for this species and may serve as breeding or feeding grounds. Overall, our data show that the Gulf of Tadjoura is a globally important conservation hotspot, and therefore its protection should be prioritized.

Mercury Concentrations in Whale Shark (Rhincodon typus) Embryo Muscle Tissue.

Mercury (Hg) is known to be maternally transferred during embryonic development in sharks; however, Hg concentrations in embryos of filter feeding shark species have not previously been reported. This study measured the total Hg (THg) concentration in muscle tissue of 27 embryos taken from a pregnant whale shark (Rhincodon typus) landed in Taiwan in 1995 and the mean THg concentration compared to the mean muscle THg concentration in embryos from other shark species. The mean (± standard deviation) THg concentration in whale shark embryos was 0.0762 ± 0.0163 µg/g dry weight (0.0224 ± 0.0054 µg/g wet weight). There was no relationship between muscle THg concentration and body length and no significant difference in THg concentration between male and female embryos (p > 0.05). Whale shark embryos have the lowest reported muscle THg concentrations compared to literature values for muscle THg concentrations for embryos from other shark species.

The mouse Jhy gene regulates ependymal cell differentiation and ciliogenesis.

During the first postnatal week of mouse development, radial glial cells lining the ventricles of the brain differentiate into ependymal cells, undergoing a morphological change from pseudostratified cuboidal cells to a flattened monolayer. Concomitant with this change, multiple motile cilia are generated and aligned on each nascent ependymal cell. Proper ependymal cell development is crucial to forming the brain tissue:CSF barrier, and to the establishment of ciliary CSF flow, but the mechanisms that regulate this differentiation event are poorly understood. The JhylacZ mouse line carries an insertional mutation in the Jhy gene (formerly 4931429I11Rik), and homozygous JhylacZ/lacZ mice develop a rapidly progressive juvenile hydrocephalus, with defects in ependymal cilia morphology and ultrastructure. Here we show that beyond just defective motile cilia, JhylacZ/lacZ mice display abnormal ependymal cell differentiation. Ventricular ependyma in JhylacZ/lacZ mice retain an unorganized and multi-layered morphology, representative of undifferentiated ependymal (radial glial) cells, and they show altered expression of differentiation markers. Most JhylacZ/lacZ ependymal cells do eventually acquire some differentiated ependymal characteristics, suggesting a delay, rather than a block, in the differentiation process, but ciliogenesis remains perturbed. JhylacZ/lacZ ependymal cells also manifest disruptions in adherens junction formation, with altered N-cadherin localization, and have defects in the polarized organization of the apical motile cilia that do form. Functional studies showed that cilia of JhylacZ/lacZ mice have severely reduced motility, a potential cause for the development of hydrocephalus. This work shows that JHY does not only control ciliogenesis, but is a crucial component of the ependymal differentiation process, with ciliary defects likely a consequence of altered ependymal differentiation.

Behavioral and physiological characterization of PKC-dependent phosphorylation in the Grin2a∆PKC mouse.

Activity-dependent plasticity in NMDA receptor-containing synapses can be regulated by phosphorylation of serines and tyrosines in the C-terminal domain of the receptor subunits by various kinases. We have previously identified S1291/S1312 as important sites for PKC phosphorylation; while Y1292/Y1312 are the sites indirectly phosphorylated by PKC via Src kinase. In the oocyte expression system, mutation of those Serine sites to Alanine (that cannot be phosphorylated) in the GluN2A subunit, resulted in a decreased PKC stimulated current enhancement through the receptors compared to wild-type NMDA receptors. To investigate the behavioral and physiological significance of those PKC-mediated phosphorylation sites in vivo, the Grin2a∆PKC mouse expressing GluN2A with four mutated amino acids: S1291A, S1312A, Y1292F and Y1387F was generated using homologous recombination. The Grin2a∆PKC mice exhibit reduced anxiety in the open field test, light dark emergence test, and elevated plus maze. The mutant mice show reduced alternation in a Y maze spontaneous alternation task and a in a non-reinforced T maze alternation task. Interestingly, when the mutant mice were exposed to novel environments, there was no increase in context-induced Fos levels in hippocampal CA1 and CA3 compared to home-cage Fos levels, while the Fos increased in the WT mice in CA1, CA3 and DG. When the SC-CA1 synapses in slices from mutant mice were stimulated using a theta-burst protocol, there was no impairment in LTP. Overall, these results suggest that at least one of those PKC-mediated phosphorylation sites regulates NMDAR-mediated signaling that modulates anxiety.

Developmental expression of estrogen receptor beta in the brain of prairie voles (Microtus ochrogaster).

Here, for the first time, the expression of estrogen receptor beta (ERß) is characterized in the brains of the highly prosocial prairie vole (Microtus ochrogaster). ERß immunoreactivity was compared in weanlings (postnatal Day 21) and adult males and females. The results indicate several major findings. First, unlike ERα, ERß expression is not sexually dimorphic. Second, the adult pattern of ERß-IR is established at the time of weaning, as there were no age-dependent effects on distribution. Finally, ERß does not appear to be as widely distributed in voles compared with rats and mice. High levels of ERß-IR were observed in several regions/nuclei within the medial pre-optic area, ventrolateral pre-optic nuclei, and in the hypothalamus, especially in the paraventricular and supraoptic nuclei. The visualization of ERß in prairie voles is important as the socially monogamous prairie vole functions as a human relevant model system for studying the expression of social behavior and social deficit disorders. Future studies will now be able to determine the effect of treatments on the expression and/or development of ERß in this highly social species.

Disruption of the mouse Jhy gene causes abnormal ciliary microtubule patterning and juvenile hydrocephalus.

Congenital hydrocephalus, the accumulation of excess cerebrospinal fluid (CSF) in the ventricles of the brain, affects one of every 1000 children born today, making it one of the most common human developmental disorders. Genetic causes of hydrocephalus are poorly understood in humans, but animal models suggest a broad genetic program underlying the regulation of CSF balance. In this study, the random integration of a transgene into the mouse genome led to the development of an early onset and rapidly progressive hydrocephalus. Juvenile hydrocephalus transgenic mice (Jhy(lacZ)) inherit communicating hydrocephalus in an autosomal recessive fashion with dilation of the lateral ventricles observed as early as postnatal day 1.5. Ventricular dilation increases in severity over time, becoming fatal at 4-8 weeks of age. The ependymal cilia lining the lateral ventricles are morphologically abnormal and reduced in number in Jhy(lacZ/lacZ) brains, and ultrastructural analysis revealed disorganization of the expected 9+2 microtubule pattern. Rather, the majority of Jhy(lacZ/lacZ) cilia develop axonemes with 9+0 or 8+2 microtubule structures. Disruption of an unstudied gene, 4931429I11Rik (now named Jhy) appears to underlie the hydrocephalus of Jhy(lacZ/lacZ) mice, and the Jhy transcript and protein are decreased in Jhy(lacZ/lacZ) mice. Partial phenotypic rescue was achieved in Jhy(lacZ/lacZ) mice by the introduction of a bacterial artificial chromosome (BAC) carrying 60-70% of the JHY protein coding sequence. Jhy is evolutionarily conserved from humans to basal vertebrates, but the predicted JHY protein lacks identifiable functional domains. Ongoing studies are directed at uncovering the physiological function of JHY and its role in CSF homeostasis.

Conditional deletions refine the embryonic requirement for Dlk1.

Numerous studies have implicated Delta-like 1 (DLK1), a transmembrane protein that shares homology with Notch ligands, in embryonic growth and differentiation. Dlk1 expression is widespread, though not ubiquitous, during early development, but is confined to a few specific cell types in adults. Adult Dlk1-expressing tissues include the Insulin-producing ß-cells of the pancreas and the Growth hormone-producing somatotrophs of the pituitary gland. Previously generated Dlk1 null mice (Dlk1(Sul-pat)), display a partially penetrant neonatal lethality and a complex pattern of developmental and adult phenotypes. Here we describe the generation of a conditional Dlk1 mouse line (Dlk1(flox)) to facilitate cell type-specific deletion of the Dlk1 gene, providing a powerful system to explore each aspect of the Dlk1 null phenotype. Four tissue-specific Cre mouse lines were used to produce individual Dlk1 deletions in pancreatic ß-cells, pituitary somatotrophs and the endothelial cells of the embryo and placenta, key candidates for the Dlk1 phenotype. Contrary to expectations, all of these conditional mice were fully viable, and none recapitulated any aspect of the Dlk1(Sul-pat) null mice. Dlk1 expression is therefore not essential for the normal development of ß-cells, somatotrophs and endothelial cells, and the tissues responsible for the Dlk1 null phenotype remain to be identified. Dlk1(flox) mice will continue to provide an important tool for further research into the function of Dlk1.

Identification of imprinting regulators at the Meg3 differentially methylated region.

Genomic imprinting at the Delta-like 1 (Dlk1)-Maternally expressed gene 3 (Meg3) locus is regulated by the Meg3 differentially methylated region (DMR), but the mechanism by which this DMR acts is unknown. The goal of this study was to analyze the Meg3 DMR during imprinting establishment and maintenance for the presence of histone modifications and trans-acting DNA binding proteins using chromatin immunoprecipitation. In embryonic stem (ES) cells, where Meg3 is biallelically expressed, the DMR showed variable DNA methylation, with biallelic methylation at one region but paternal allele-specific methylation at another. All histone modifications detected at the Meg3 DMR of ES cells were biallelic. In embryonic day 12.5 (e12.5) embryos, where Meg3 is maternally expressed, the paternal Meg3 DMR was methylated, and activating histone modifications were specific to the maternal DMR. DNA-binding proteins that represent potential regulatory factors were identified in both ES cells and embryos.

Localizing transcriptional regulatory elements at the mouse Dlk1 locus.

Much effort has focused recently on determining the mechanisms that control the allele-specific expression of genes subject to genomic imprinting, yet imprinting regulation is only one aspect of configuring appropriate expression of these genes. Imprinting control mechanisms must interact with those regulating the tissue-specific expression pattern of each imprinted gene in a cluster. Proper expression of the imprinted Delta-like 1 (Dlk1)-Maternally expressed gene 3 (Meg3) gene pair is required for normal fetal development in mammals, yet the mechanisms that control tissue-specific expression of these genes are unknown. We have used a combination of in vivo and in vitro expression assays to localize cis-regulatory elements that may regulate Dlk1 expression in the mouse embryo. A bacterial artificial chromosome transgene encompassing the Dlk1 gene and 77 kb of flanking sequence conferred expression in most endogenous Dlk1-expressing tissues. In combination with previous transgenic data, these experiments localize the majority of Dlk1 cis-regulatory elements to a 41 kb region upstream of the gene. Cross-species sequence conservation was used to further define potential regulatory elements, several of which functioned as enhancers in a luciferase expression assay. Two of these elements were able to drive expression of a lacZ reporter transgene in Dlk1-expressing tissues in the mouse embryo. The sequence proximal to Dlk1 therefore contains at least two discrete regions that may regulate tissue-specificity of Dlk1 expression.

Dlk1 is necessary for proper skeletal muscle development and regeneration.

Delta-like 1homolog (Dlk1) is an imprinted gene encoding a transmembrane protein whose increased expression has been associated with muscle hypertrophy in animal models. However, the mechanisms by which Dlk1 regulates skeletal muscle plasticity remain unknown. Here we combine conditional gene knockout and over-expression analyses to investigate the role of Dlk1 in mouse muscle development, regeneration and myogenic stem cells (satellite cells). Genetic ablation of Dlk1 in the myogenic lineage resulted in reduced body weight and skeletal muscle mass due to reductions in myofiber numbers and myosin heavy chain IIB gene expression. In addition, muscle-specific Dlk1 ablation led to postnatal growth retardation and impaired muscle regeneration, associated with augmented myogenic inhibitory signaling mediated by NF-κB and inflammatory cytokines. To examine the role of Dlk1 in satellite cells, we analyzed the proliferation, self-renewal and differentiation of satellite cells cultured on their native host myofibers. We showed that ablation of Dlk1 inhibits the expression of the myogenic regulatory transcription factor MyoD, and facilitated the self-renewal of activated satellite cells. Conversely, Dlk1 over-expression inhibited the proliferation and enhanced differentiation of cultured myoblasts. As Dlk1 is expressed at low levels in satellite cells but its expression rapidly increases upon myogenic differentiation in vitro and in regenerating muscles in vivo, our results suggest a model in which Dlk1 expressed by nascent or regenerating myofibers non-cell autonomously promotes the differentiation of their neighbor satellite cells and therefore leads to muscle hypertrophy.

Imprinting analysis in the Acrodysplasia region of mouse chromosome 12.

The insertional mouse mutation Adp (Acrodysplasia) confers a parent-of-origin developmental phenotype, with animals inheriting the mutation from their father showing skeletal abnormalities, whereas those inheriting the mutation from their mother are normal. This parental-specific phenotype, along with mapping of the insertion to a region of chromosome 12 proposed to contain imprinted genes, suggested that disruption of genomic imprinting might underlie the Adp phenotype. Genomic imprinting is the process by which autosomal genes are epigenetically silenced on one of the two parental alleles; imprinting mutation phenotypes manifest after inheritance from one parent but not the other. Imprinted genes typically occur in dense clusters that contain few non-imprinted genes and therefore representative genes from the Adp critical region could be assayed to identify any imprinted domains. None of the genes analysed were found to be imprinted, however, suggesting that other explanations for the Adp phenotype must be considered.

Low genetic differentiation across three major ocean populations of the whale shark, Rhincodon typus.

BACKGROUND: Whale sharks are a declining species for which little biological data is available. While these animals are protected in many parts of their range, they are fished legally and illegally in some countries. Baseline biological and ecological data are needed to allow the formulation of an effective conservation plan for whale sharks. It is not known, for example, whether the whale shark is represented by a single worldwide panmictic population or by numerous, reproductively isolated populations. Genetic analysis of population structure is one essential component of the baseline data required for whale shark conservation. METHODOLOGY/PRINCIPAL FINDINGS: We have identified 8 polymorphic microsatellites in the whale shark and used these markers to assess genetic variation and population structure in a panel of whale sharks covering a broad geographic region. This is the first record of microsatellite loci in the whale shark, which displayed an average of 9 alleles per locus and mean H(o) = 0.66 and H(e) = 0.69. All but one of the eight loci meet the expectations of Hardy-Weinberg equilibrium. Analysis of these loci in whale sharks representing three major portions of their range, the Pacific (P), Caribbean (C), and Indian (I) Oceans, determined that there is little population differentiation between animals sampled in different geographic regions, indicating historical gene flow between populations. F(ST) values for inter-ocean comparisons were low (PxC = 0.0387, CxI = 0.0296 and PxI = -0.0022), and only CxI approached statistical significance (p = 0.0495). CONCLUSIONS/SIGNIFICANCE: We have shown only low levels of genetic differentiation between geographically distinct whale shark populations. Existing satellite tracking data have revealed both regional and long-range migration of whale sharks throughout their range, which supports the finding of gene flow between populations. Whale sharks traverse geographic and political boundaries during their life history and interbreed with animals from distant populations; conservation efforts must therefore target international protection for this species.

Novel imprinted transcripts from the Dlk1-Gtl2 intergenic region, Mico1 and Mico1os, show circadian oscillations.

Most of the known imprinted genes are assembled into clusters that share common imprinting control regions (ICRs). Non-coding transcripts are often associated with ICRs and implicated in imprinting regulation. We undertook a systematic search for transcripts originating from the Dlk1-Gtl2 intergenic region that contains the ICR for the chromosome 12 imprinted cluster and identified two overlapping transcripts expressed from opposite strands exclusively from the maternal chromosome. These novel imprinted transcripts most likely represent non-coding RNAs and are located telomeric to the IG DMR, extending the proximal boundary of the region of maternal-specific transcription. Their expression is tissue-specific and shows diurnal and circadian oscillations.Therefore, we named these novel transcripts maternal intergenic circadian oscillating 1 (Mico1) and Mico1, opposite strand (Mico1os).

Coordinated diurnal regulation of genes from the Dlk1-Dio3 imprinted domain: implications for regulation of clusters of non-paralogous genes.

The functioning of the genome is tightly related to its architecture. Therefore, understanding the relationship between different regulatory mechanisms and the organization of chromosomal domains is essential for understanding genome regulation. The majority of imprinted genes are assembled into clusters, share common regulatory elements, and, hence, represent an attractive model for studies of regulation of clusters of non-paralogous genes. Here, we investigated the relationship between genomic imprinting and diurnal regulation of genes from the imprinted domain of mouse chromosome 12. We compared gene expression patterns in C57BL/6 mice and congenic mice that carry the imprinted region from a Mus musculus molossinus strain MOLF/Ei. In the C57BL/6 mice, a putative enhancer/oscillator regulated the expression of only Mico1/Mico1os, whereas in the congenic mice its influence was spread onto Rtl1as, Dio3 and Dio3os, i.e. the distal part of the imprinted domain, resulting in coordinated diurnal variation in expression of five genes. Using additional congenic strains we determined that in C57BL/6 the effect of the putative enhancer/oscillator was attenuated by a linked dominant trans-acting factor located in the distal portion of chromosome 12. Our data demonstrate that (i) in adult organs, mRNA levels of several imprinted genes vary during the day, (ii) genetic variation may remove constraints on the influence of an enhancer and lead to spreading of its effect onto neighboring genes, thereby generating genotype-dependent expression patterns and (iii) different regulatory mechanisms within the same domain act independently and do not seem to interfere with each other.

Oxytocin selectively increases ERalpha mRNA in the neonatal hypothalamus and hippocampus of female prairie voles.

During neonatal development exogenous oxytocin increases ERalpha immunoreactivity in the hypothalamus of female prairie voles. The purpose of this study was to determine if the increase in ERalpha is associated with an increase in ERalpha mRNA expression and to determine if the effect is specific to ER subtype or if oxytocin also influences ERbeta mRNA expression. On the day of birth female prairie vole pups were treated with oxytocin, an oxytocin antagonist, or saline. Brains were collected and RT-PCR was used to determine the effect of treatment on ER mRNA production in the hypothalamus, hippocampus, and cortex. Within 2h of treatment oxytocin significantly increased ERalpha mRNA expression in the hypothalamus and hippocampus, but not the cortex, while inhibiting the effects of endogenous oxytocin reduced the expression of ERalpha mRNA in the hippocampus. Neonatal treatment did not affect the expression of ERbetamRNA. The results demonstrate that the effects of oxytocin treatment are region and ER subtype specific and that during the neonatal period oxytocin can affect the expression of ERalpha by altering message production. The regional specific changes in ERalpha mRNA expression in females are consistent with studies examining the behavioral and physiological effects of neonatal manipulation of oxytocin in females.

Allele-specific histone modifications regulate expression of the Dlk1-Gtl2 imprinted domain.

Dlk1 and Gtl2 are reciprocally expressed imprinted genes located on mouse chromosome 12. The Dlk1-Gtl2 locus carries three differentially methylated regions (DMRs), which are methylated only on the paternal allele. Of these, the intergenic (IG) DMR, located 12 kb upstream of Gtl2, is required for proper imprinting of linked genes on the maternal chromosome, while the Gtl2 DMR, located across the promoter of the Gtl2 gene, is implicated in imprinting on both parental chromosomes. In addition to DNA methylation, modification of histone proteins is also an important regulator of imprinted gene expression. Chromatin immunoprecipitation was therefore used to examine the pattern of histone modifications across the IG and Gtl2 DMRs. The data show maternal-specific histone acetylation at the Gtl2 DMR, but not at the IG DMR. In contrast, only low levels of histone methylation were observed throughout the region, and there was no difference between the two parental alleles. An existing mouse line carrying a deletion/insertion upstream of Gtl2 is unable to imprint the Dlk1-Gtl2 locus properly and demonstrates loss of allele-specific methylation at the Gtl2 DMR. Further analysis of these animals now shows that the loss of allele-specific methylation is accompanied by increased paternal histone acetylation at the Gtl2 DMR, with the activated paternal allele adopting a maternal acetylation pattern. These data indicate that interactions between DNA methylation and histone acetylation are involved in regulating the imprinting of the Dlk1-Gtl2 locus.

Loss of imprinting at the Dlk1-Gtl2 locus caused by insertional mutagenesis in the Gtl2 5' region.

BACKGROUND: The Dlk1 and Gtl2 genes define a region of mouse chromosome 12 that is subject to genomic imprinting, the parental allele-specific expression of a gene. Although imprinted genes play important roles in growth and development, the mechanisms by which imprinting is established and maintained are poorly understood. Differentially methylated regions (DMRs), which carry methylation on only one parental allele, are involved in imprinting control at many loci. The Dlk1-Gtl2 region contains three known DMRs, the Dlk1 DMR in the 3' region of Dlk1, the intergenic DMR 15 kb upstream of Gtl2, and the Gtl2 DMR at the Gtl2 promoter. Three mouse models are analyzed here that provide new information about the regulation of Dlk1-Gtl2 imprinting. RESULTS: A previously existing insertional mutation (Gtl2lacZ), and a targeted deletion in which the Gtl2 upstream region was replaced by a Neo cassette (Gtl2Delta5'Neo), display partial lethality and dwarfism upon paternal inheritance. Molecular characterization shows that both mutations cause loss of imprinting and changes in expression of the Dlk1, Gtl2 and Meg8/Rian genes. Dlk1 levels are decreased upon paternal inheritance of either mutation, suggesting Dlk1 may be causative for the lethality and dwarfism. Loss of imprinting on the paternal chromosome in both Gtl2lacZ and Gtl2Delta5'Neo mice is accompanied by the loss of paternal-specific Gtl2 DMR methylation, while maternal loss of imprinting suggests a previously unknown regulatory role for the maternal Gtl2 DMR. Unexpectedly, when the Neo gene is excised, Gtl2Delta5' animals are of normal size, imprinting is unchanged and the Gtl2 DMR is properly methylated. The exogenous DNA sequences integrated upstream of Gtl2 are therefore responsible for the growth and imprinting effects. CONCLUSION: These data provide further evidence for the coregulation of the imprinted Dlk1 and Gtl2 genes, and support a role for Dlk1 as an important neonatal growth factor. The ability of the Gtl2lacZ and Gtl2Delta5'Neo mutations to cause long-range changes in imprinting and gene expression suggest that regional imprinting regulatory elements may lie in proximity to the integration site.

Dlk1 expression marks developing endothelium and sites of branching morphogenesis in the mouse embryo and placenta.

The protein product of the Delta-like 1 (Dlk1) gene belongs to the Delta-Notch family of signaling molecules, proteins involved in cell fate determination in many tissues during development. The DLK1 protein is believed to function as a growth factor, maintaining the proliferative state of undifferentiated cells, and is usually down-regulated as immature cells differentiate. The expression pattern of the DLK1 protein has been described in certain human tissues; however, Dlk1 expression is not well understood in the mouse, the most tractable mammalian genetic model system. To better understand the role of Dlk1 in embryonic development, the tissue-specific expression pattern of Dlk1 mRNA during mouse embryogenesis was analyzed by in situ hybridization. In embryonic day 12.5 (e12.5) embryos, high levels of Dlk1 were found in the developing pituitary, pancreas, lung, adrenal, and many mesodermally derived tissues. Strikingly, Dlk1 expression also marks the growing branches of organs that develop through the process of branching morphogenesis. At e16.5, Dlk1 expression is down-regulated in most tissues but remains in the pituitary, the adrenal gland, and in skeletal muscle. In the placenta, expression of Dlk1 is detected in endothelial cells lining the fetal blood vessels of the labyrinth. This pattern is distinct from that seen in the human placenta and suggests a role for Dlk1 in regulating maternal-fetal interactions.

Expression of a modified H19 RNA does not cause embryonic lethality in mice.

The imprinted H19 gene produces a noncoding RNA of unknown function. Targeted and transgenic mouse mutations have shown that this RNA can be deleted and overexpressed without adverse effect. Yet one mutation of the H19 gene displayed an embryonic lethal phenotype in the mouse--the expression of an RNA modified by a short insertion near the 5' end of the transcript (H19(Xba) allele). Expression of this RNA in transgenic mice conferred lethality at day 14 of development. The potential for this mutant to elucidate the function of the H19 RNA supported further investigation of the H19(Xba) phenotype. Since all H19(Xba) transgenic founders died as embryos, an experiment was designed to generate H19(Xba)-expressing mice that could be maintained as an established line. This strategy took advantage of the maternal-specific expression of H19, passing an H19(Xba) knockin allele silently through males and transferring it to females only to generate animals for study. Surprisingly, H19(Xba) knockin mice are fully viable, whether the H19(Xba) allele is inherited paternally or maternally. Experiments to reproduce the original transgene-based lethality were also performed and yielded live-born transgene-expressing animals. These data demonstrate that, contrary to published reports, expression of the H19(Xba) RNA does not cause embryonic lethality in mice.

A 178-kb BAC transgene imprints the mouse Gtl2 gene and localizes tissue-specific regulatory elements.

The regulation of genomic imprinting, the allele-specific expression of an autosomal gene, is complex and poorly understood. Imprinted genes are organized in clusters, where cis-acting regulatory elements are believed to interact to control multiple genes. We have used BAC transgenesis in the mouse to begin to delineate the region of DNA required for proper expression and imprinting of the mouse Delta-like1 (Dlk1) and Gene-trap locus2 (Gtl2) imprinted genes. We demonstrate that the Gtl2 gene is expressed from a BAC transgene in mouse embryo and placenta only upon maternal inheritance, as is the endogenous Gtl2 gene. Gtl2 is therefore properly imprinted on the BAC in an ectopic chromosomal location and must carry with it all necessary imprinting regulatory elements. Furthermore, we show that the BAC Gtl2 gene is expressed at levels approaching those of the endogenous gene only in the brain of adult animals, not in other sites of endogenous expression such as the pituitary, adrenal, and skeletal muscle. These data localize the enhancer(s) for brain Gtl2 expression, but not those for other tissues, to the DNA contained within the BAC clone. As the Dlk1 gene is not expressed from the BAC in any tissues, it must require additional elements that are different from those necessary for Gtl2 expression. Our data refine the interval for future investigation of Gtl2 imprinting and provide evidence for distinct regulation of the linked Dlk1 and Gtl2 genes.