Genomic imprinting of a placental lactogen gene in Peromyscus

The mammalian genome contains over 30 genes whose expression is dependent upon their parent-of-origin. Of these imprinted genes the majority are involved in regulating the rate of fetal growth. In this report we show that in the deer mouse Peromyscusthe placental lactogen-1-variant ( pPl1-v) gene is paternally expressed throughout fetal development, whereas the linked and closely related pPl1gene is expressed in a biallelic manner. Neither the more distantly related pPl2Agene, nor the Mus Pl1gene displays any preferential expression of the paternal allele, suggesting that the acquisition of imprinting of pPl1-v is a relatively recent event in evolution. Although pPl1 expression is temporally mis-regulated in the dysplastic placentae of hybrids between two Peromyscus species, its over-expression cannot account for the aberrant phenotypes of these placentae. We argue that the species-specific imprinting of pPl1-v, encoding a growth factor that regulates nutrient transfer from mothers to their offspring, is consistent with the parent-offspring conflict model that has been proposed to explain the evolution of genomic imprinting.

CTCF mediates methylation-sensitive enhancer-blocking activity at the H19/Igf2 locus

The Insulin-like growth factor 2 (Igf2) and H19 genes are imprinted, resulting in silencing of the maternal and paternal alleles, respectively. This event is dependent upon an imprinted-control region two kilobases upstream of H19 (refs 1, 2). On the paternal chromosome this element is methylated and required for the silencing of H19 (refs 2-4). On the maternal chromosome the region is unmethylated and required for silencing of the Igf2 gene 90 kilobases upstream. We have proposed that the unmethylated imprinted-control region acts as a chromatin boundary that blocks the interaction of Igf2 with enhancers that lie 3' of H19 (refs 5, 6). This enhancer-blocking activity would then be lost when the region was methylated, thereby allowing expression of Igf2 paternally. Here we show, using transgenic mice and tissue culture, that the unmethylated imprinted-control regions from mouse and human H19 exhibit enhancer-blocking activity. Furthermore, we show that CTCF, a zinc finger protein implicated in vertebrate boundary function, binds to several sites in the unmethylated imprinted-control region that are essential for enhancer blocking. Consistent with our model, CTCF binding is abolished by DNA methylation. This is the first example, to our knowledge, of a regulated chromatin boundary in vertebrates.

Allelic expression of IGF2 in marsupials and birds

Genomic imprinting, the parent-of-origin- specific expression of genes, has been observed in a variety of eutherian mammals. One gene that has been shown to be imprinted in all eutherians examined is the IGF2 gene. This gene encodes a potent fetal-specific growth factor that is expressed almost exclusively from the paternal chromosome. Several other imprinted genes in the IGF2 pathway are imprinted as well, suggesting that IGF2 is a focal point for the selective pressure leading to imprinted gene expression. This observation is in keeping with a proposal that imprinting arose as the result of a genetic conflict between parents over the allocation of maternal resources to the embryo. One prediction of this model is that imprinting exists in species in which there is at least some contribution of maternal resources to the embryo, and in which polyandry is observed. To test this prediction the allelic expression of the IGF2 gene was examined in two noneutherian species. The IGF2 gene was shown to be expressed in a paternal-specific manner identical to that in eutherians in Monodelphis domestica, a placental South American opossum. In contrast, the IGF2 gene is biallelic in expression in chickens, which are oviparous, and make no postfertilization contribution of maternal resources to the offspring.

The temporal requirement for endothelin receptor-B signalling during neural crest development

Endothelin receptor B (EDNRB) is a G-protein-coupled receptor with seven transmembrane domains which is required for the development of melanocytes and enteric neurons. Mice that are homozygous for a null mutation in the Ednrb gene are almost completely white and die as juveniles from megacolon. To determine when EDNRB signalling is required during embryogenesis, we have exploited the tetracycline-inducible system to generate strains of mice in which the endogenous Ednrb locus is under the control of the tetracycline-dependant transactivators tTa or rtTA. By using this system to express Ednrb at different stages of embryogenesis, we have determined that EDNRB is required during a restricted period of neural crest development between embryonic days 10 and 12.5. Moreover, our results imply that EDNRB is required for the migration of both melanoblasts and enteric neuroblasts.

Genomic imprinting is disrupted in interspecific Peromyscus hybrids

Genomic imprinting, the unequal expression of gene alleles on the basis of parent of origin, is a major exception to mendelian laws of inheritance. By maintaining one allele of a gene in a silent state, imprinted genes discard the advantages of diploidy, and for this reason the rationale for the evolution of imprinting has been debated. One explanation is the parent-offspring conflict model, which proposes that imprinting arose in polyandrous mammals as the result of a parental conflict over the allocation of maternal resources to embryos. This theory predicts that there should be no selection for imprinting in a monogamous species. Crosses between the monogamous rodent species Peromyscus polionotus and the polyandrous Peromyscus maniculatus yield progeny with parent-of-origin growth defects that could be explained if imprinting was absent in the monogamous species. We find, however, that imprinting is maintained in P. polionotus, but there is widespread disruption of imprinting in the hybrids. We suggest that the signals governing genomic imprinting are rapidly evolving and that disruptions in the process may contribute to mammalian speciation.

Gold nanoelectrodes of varied size: transition to molecule-like charging

A transition from metal-like double-layer capacitive charging to redox-like charging was observed in electrochemical ensemble Coulomb staircase experiments on solutions of gold nanoparticles of varied core size. The monodisperse gold nanoparticles are stabilized by short-chain alkanethiolate monolayers and have 8 to 38 kilodaltons core mass (1.1 to 1.9 nanometers in diameter). Larger cores display Coulomb staircase responses consistent with double-layer charging of metal-electrolyte interfaces, whereas smaller core nanoparticles exhibit redox chemical character, including a large central gap. The change in behavior is consistent with new near-infrared spectroscopic data showing an emerging gap between the highest occupied and lowest unoccupied orbitals of 0.4 to 0.9 electron volt.

Location of enhancers is essential for the imprinting of H19 and Igf2 genes

Genomic imprinting is the process in mammals by which gamete-specific epigenetic modifications establish the differential expression of the two alleles of a gene. The tightly linked H19 and Igf2 genes are expressed in tissues of endodermal and mesodermal origin, with H19 expressed from the maternal chromosome and Igf2 expressed from the paternal chromosome. A model has been proposed to explain the reciprocal imprinting of these genes; in this model, expression of the genes is governed by competition between their promoters for a common set of enhancers. An extra set of enhancers might be predicted to relieve the competition, thereby eliminating imprinting. Here we tested this prediction by generating mice with a duplication of the endoderm-specific enhancers. The normally silent Igf2 gene on the maternal chromosome was expressed in liver, consistent with relief from competition. We then generated a maternal chromosome containing a single set of enhancers located equidistant from 1gf2 and H19; the direction of the imprint was reversed. Thus, the location of the enhancers determines the outcome of competition in liver, and the strength of the H19 promoter is not sufficient to silence Igf2.

Genomic imprinting in mice: its function and mechanism

Genomic imprinting is an epigenetic phenomenon by which the two parental alleles of a gene are differentially expressed. Although the function of genomic imprinting is not clear, it has been proposed that it evolved in mammals to regulate intrauterine growth. This proposal is consistent with experiments that were designed to reveal the mechanism and impact of genomic imprinting in a region of mouse chromosome 7 that contains four imprinted genes: Mash-2 (a transcription factor) and H19 (a noncoding RNA) are maternally expressed, whereas Insulin-2 (Ins-2) and Insulin-like growth factor 2 (Igf-2) are paternally expressed. Two targeted disruptions at the locus were generated in mice; these support the hypothesis that the function of the H19 gene is to set up the imprinting of both Igf-2 and Ins-2. H19 transcription on the maternal chromosome precludes transcription of the other two genes by a mechanism that involves competition for a common set of enhancers. On the paternal chromosome the H19 gene is silenced by DNA methylation, thus permitting the use of enhancers by the other genes.

An enhancer deletion affects both H19 and Igf2 expression

The distal end of mouse Chromosome 7 contains four tightly linked genes whose expression is dependent on their parental inheritance. Mash-2 and H19 are expressed exclusively from the maternal chromosome, whereas Insulin-2 (Ins-2) and Insulin-like growth factor 2 (Igf2) are paternally expressed. The identical expression during development of the 3'-most genes in the cluster, Igf2 and H19, led to the proposal that their imprinting was mechanistically linked through a common set of transcriptional regulatory elements. To test this hypothesis, a targeted deletion of two endoderm-specific enhancers that lie 3' of H19 was generated by homologous recombination in embryonic stem cells. Inheritance of the enhancer deletion through the maternal lineage led to a loss of H19 gene expression in cells of endodermal origin, including cells in the liver, gut, kidney, and lung. Paternal inheritance led to a very similar loss in the expression of Igf2 RNA in the same tissues. These results establish that H19 and Igf2 utilize the same endoderm enhancers, but on different parental chromosomes. Mice inheriting the enhancer deletion from fathers were 80% of normal size, reflecting a partial loss-of-function of Igf2. The reduction was uniformly observed in a number of internal organs, indicating that insulin-like growth factor II (IGFII), the product of Igf2, acts systemically in mice to affect prenatal growth. A modest decline in Ins-2 RNA was observed in the yolk sac. In contrast Mash-2, which is expressed in spongiotrophoblast cells of the placenta, was unaffected by the enhancer deletion.

Disruption of imprinting caused by deletion of the H19 gene region in mice

The imprinted H19 gene, which encodes an untranslated RNA, lies at the end of a cluster of imprinted genes in the mouse. Imprinting of the insulin-2 and insulin-like growth factor 2 genes, which lie about 100 kilobases upstream of H19, can be disrupted by maternal inheritance of a targeted deletion of the H19 gene and its flanking sequence. Animals inheriting the H19 mutation from their mothers are 27% heavier than those inheriting it from their fathers. Paternal inheritance of the disruption has no effect, which presumably reflects the normally silent state of the paternal gene. The somatic overgrowth of heterozygotes for the maternal deletion is attributed to a gain of function of insulin-like growth factor 2, rather than a loss of function of H19.

A paternal-specific methylation imprint marks the alleles of the mouse H19 gene

Imprinting, the differential expression of the two alleles of a gene based on their parental origin, requires that the alleles be distinguished or marked. A candidate for the differentiating mark is DNA methylation. The maternally expressed H19 gene is hypermethylated on the inactive paternal allele in somatic tissues and sperm, but to serve as the mark that designates the imprint, differential methylation must also be present in the gametes and the pre-implantation embryo. We now show that the pattern of differential methylation in the 5' portion of H19 is established in the gametes and a subset is maintained in the pre-implantation embryo. That subset is sufficient to confer monoallelic expression to the gene in blastocysts. We propose that paternal-specific methylation of the far 5' region is the mark that distinguishes the two alleles of H19.

The product of the H19 gene may function as an RNA

The mouse H19 gene was identified as an abundant hepatic fetal-specific mRNA under the transcriptional control of a trans-acting locus termed raf. The protein this gene encoded was not apparent from an analysis of its nucleotide sequence, since the mRNA contained multiple translation termination signals in all three reading frames. As a means of assessing which of the 35 small open reading frames might be important to the function of the gene, the human H19 gene was cloned and sequenced. Comparison of the two homologs revealed no conserved open reading frame. Cellular fractionation showed that H19 RNA is cytoplasmic but not associated with the translational machinery. Instead, it is located in a particle with a sedimentation coefficient of approximately 28S. Despite the fact that it is transcribed by RNA polymerase II and is spliced and polyadenylated, we suggest that the H19 RNA is not a classical mRNA. Instead, the product of this unusual gene may be an RNA molecule.

Tissue-specific transcription of the mouse alpha-fetoprotein gene promoter is dependent on HNF-1

Previous work identified four upstream cis-acting elements required for tissue-specific expression of the alpha-fetoprotein (AFP) gene: three distal enhancers and a promoter. To further define the role of the promoter in regulating AFP gene expression, segments of the region were tested for the ability to direct transcription of a reporter gene in transient expression assay. Experiments showed that the region within 250 base pairs of the start of transcription was sufficient to confer liver-specific transcription. DNase I footprinting and band shift assays indicated that the region between -130 and -100 was recognized by two factors, one of which was highly sequence specific and found only in hepatoma cells. Competition assays suggested that the liver-specific binding activity was HNF-1, previously identified by its binding to other liver-specific promoters. Mutation of the HNF-1 recognition site at -120 resulted in a significant reduction in transcription in transfection assays, suggesting a biological role for HNF-1 in the regulation of AFP expression.

Two regulatory domains flank the mouse H19 gene

The mouse H19 gene was identified by virtue of its coordinate regulation with the mouse alpha-fetoprotein gene. Both genes are expressed in the fetal liver, gut, and visceral endoderm of the yolk sac and are repressed shortly after birth in the liver and gut. They are both under the control of two trans-acting loci: raf, which affects the adult basal levels of the two mRNAs, and Rif, which affects their inducibility during liver regeneration. One crucial difference between the two genes is the activation of the H19 gene in mesoderm derivatives, skeletal and cardiac muscle. As a strategy for explaining both the similarities and differences in their modes of expression, the regulatory domains responsible for the expression of the H19 gene in liver were identified by transiently introducing the gene into a human hepatoma cell line. Two regions necessary for high-level expression of the gene could be identified, a promoter-proximal domain immediately preceding the start of transcription and an enhancer domain which lies between 5 and 6.5 kilobases 3' of the polyadenylation site. The 3' domain consists of two separable enhancer elements, each of which exhibits the properties of tissue-specific enhancers. Nucleotide sequence comparisons between the two H19 and three alpha-fetoprotein enhancers revealed limited similarities which are candidates for binding of common regulatory factors. Sequences which lie 3' of the gene are also required for the expression of the H19 gene following differentiation of teratocarcinoma cells into visceral endoderm.

Fine-structure mapping of the three mouse alpha-fetoprotein gene enhancers

Multiple cellular enhancers have been identified previously in the 5'-flanking region of the mouse alpha-fetoprotein gene by transient expression assay. In this report the enhancers have been localized to three regions 200 to 300 base pairs in length at 2.5, 5.0, and 6.5 kilobases of DNA upstream of the transcriptional start site. Nucleotide sequence analysis of the three enhancers revealed areas of homology among them, the most significant of which were two regions of 10 and 18 nucleotides in length. Two of the enhancers were analyzed in detail and shown to be composed of multiple nonidentical domains, none of which was sufficient for full enhancer activity; rather, they acted in an additive fashion in generating the full activity of the enhancer. The tissue-specific activity of the enhancer at -2.5 kilobases was assessed by comparing the activities of subdomains in liver- and non-liver-derived cell lines and was found to be the result of both positive elements within the enhancer and at least one negative element to its 5' end. In contrast, the tissue specificity of the enhancer at -5.0 kilobases was maintained when the minimal essential region was tested alone. The nucleotide sequence similarities, as well as the differences among the enhancers, may explain their differing biological activities both in tissue culture and in vivo.

alpha-Fetoprotein and albumin genes are in tandem in the mouse genome

The urine alpha-fetoprotein (AFP) and serum albumin genes most probably arose in evolution as the consequence of a duplication of a common ancestral gene. They have both been previously mapped to chromosome 5 in the mouse. We now have evidence that these genes are closely linked. By using a unique copy DNA probe derived from previously cloned AFP 5' flanking DNA, a recombinant DNA phage has been isolated, from a bacteriophage DNA library, that contains sequences flanking the 5' end of the AFP gene and the 3' end of the albumin gene. Restriction endonuclease mapping and DNA sequence determination of the recombinant phage and comparison to total genomic DNA confirmed that the genes are in tandem, 13.5 kilobase pairs apart, with the albumin gene to the 5' side of the AFP gene. Thus, they are transcribed from the same strand of DNA.

Murine alpha-fetoprotein and albumin: two evolutionarily linked proteins encoded on the same mouse chromosome

Several lines of evidence suggest a close functional relationship and a common evolutionary origin for alpha-fetoprotein and albumin. In the mouse, breeding studies have previously allowed the assignment of the albumin gene to chromosome 5. To test the possible linkage of alpha-fetoprotein and albumin, five somatic cell hybrids containing various combinations of mouse chromosomes, together with a constant set of hamster chromosomes, were tested for the presence of both genes using DNA restriction mapping techniques. Two of the five hybrids possessed both genes, and the other three lacked both. The only mouse chromosome present in the positive lines and absent from the negative ones was number 5, allowing the assignment of both genes to this chromosome.

The evolution of alpha-fetoprotein and albumin. II. The structures of the alpha-fetoprotein and albumin genes in the mouse

The murine alpha-fetoprotein (AFP) and albumin genes have been cloned from genomic libraries derived from Balb/c DNA. By restriction endonuclease mapping and electron microscopy, we have shown that both genes are organized similarly into 15 coding segments interrupted by 14 intervening sequences. The sizes of the corresponding coding segments in each gene are identical, lending support to the hypothesis that the two genes, were derived from a common ancestral gene. However, no nucleotide homology between coding segments was observed. Both the sizes and the nucleotide sequence of flanking and intervening sequences have diverged significantly as well. Two regions of the AFP gene, 925 base pairs in the 5' flanking DNA and 180 base pairs in the third intervening sequence, hybridized to the same region of DNA in the third intervening sequence of albumin. The 180-base pair homologies within each gene are present in opposite orientation relative to the direction of transcription, and are associated with reiterated DNA. Thus, it is unlikely that they represent true sequence conservation. An examination of the sizes of the coding segments in each gene reveals a thrice repeated domain, consisting of 4 coding segments. We propose that these correspond to the three domains observed in several mammalian albumins, and in murine AFP.