TRPM2 channel deficiency prevents delayed cytosolic Zn2+ accumulation and CA1 pyramidal neuronal death after transient global ischemia.

Transient ischemia is a leading cause of cognitive dysfunction. Postischemic ROS generation and an increase in the cytosolic Zn(2+) level ([Zn(2+)]c) are critical in delayed CA1 pyramidal neuronal death, but the underlying mechanisms are not fully understood. Here we investigated the role of ROS-sensitive TRPM2 (transient receptor potential melastatin-related 2) channel. Using in vivo and in vitro models of ischemia-reperfusion, we showed that genetic knockout of TRPM2 strongly prohibited the delayed increase in the [Zn(2+)]c, ROS generation, CA1 pyramidal neuronal death and postischemic memory impairment. Time-lapse imaging revealed that TRPM2 deficiency had no effect on the ischemia-induced increase in the [Zn(2+)]c but abolished the cytosolic Zn(2+) accumulation during reperfusion as well as ROS-elicited increases in the [Zn(2+)]c. These results provide the first evidence to show a critical role for TRPM2 channel activation during reperfusion in the delayed increase in the [Zn(2+)]c and CA1 pyramidal neuronal death and identify TRPM2 as a key molecule signaling ROS generation to postischemic brain injury.

Human menopausal and pregnant mare serum gonadotrophins in murine superovulation regimens for transgenic applications.

Superovulation is a fundamental procedure for generating transgenic rodents. While various methods exist, zygote yield/quality remain suboptimal, making these techniques open to refinement. All require a follicle stimulating and a luteinising effect. The former can be induced by pregnant mare serum gonadotrophin (PMSG) or other compounds like human menopausal gonadotrophin (HMG). While HMG can double zygote yield compared to PMSG, no study has compared their effects on embryo quality. Embryo yield could also be increased with PMSG: timing administration at estrus may further improve follicular recruitment. This study compared: (i) the efficacy of HMG/PMSG for producing viable embryos for microinjection; and (ii) the effect of HMG/PMSG administration at estrus on embryo yield. Whitten effect-induced estrous C57/Bl6xCBA F(1) hybrid mice were superovulated as follows: PMSG (day 1; 5 IU intraperitoneally) or HMG (days 1 and 2; 1 IU intramuscularly); all received human chorionic gonadotrophin (hCG) on day 3 (5 IU, intraperitoneally). Zygotes were retrieved following mating, morphologically assessed and microinjected with innocuous ZhAT1R construct (expressing LacZ reporter and human angiotensin II type 1 receptor) before transfer to pseudopregnant recipients. Pups were tested for the transgene by Southern blot. Neither HMG nor PMSG proved superior in improving embryo yield, morphology and short-term post-microinjection survival. However, HMG group micromanipulated embryos all failed to establish a pregnancy/generate transgenic pups, unlike their PMSG counterparts. While HMG can be used for superovulation, it appears to increase embryo vulnerability to the long-term effects of microinjection. Furthermore, the embryo yields associated with HMG can be replicated by timing PMSG injection to coincide with Whitten effect-induced estrus.

Imprinted expression of neuronatin from modified BAC transgenes reveals regulation by distinct and distant enhancers.

Neuronatin (Nnat) is an imprinted gene that is expressed exclusively from the paternal allele while the maternal allele is silent and methylated. The Nnat locus exhibits some unique features compared with other imprinted domains. Unlike the majority of imprinted genes, which are organised in clusters and coordinately regulated, Nnat does not appear to be closely linked to other imprinted genes. Also unusually, Nnat is located within an 8-kb intron of the Bc10 gene, which generates a biallelically expressed, antisense transcript. A similar organisation is conserved at the human NNAT locus on chromosome 20. Nnat expression is first detected at E8.5 in rhombomeres 3 and 5, and subsequently, expression is widespread within postmitotic neuronal tissues. Using modified BAC transgenes, we show that imprinted expression of Nnat at ectopic sites requires, at most, an 80-kb region around the gene. Furthermore, reporter transgenes reveal distinct and dispersed cis-regulatory elements that direct tissue-specific expression and these are predominantly upstream of the region that confers allele-specific expression.

Distant cis-elements regulate imprinted expression of the mouse p57( Kip2) (Cdkn1c) gene: implications for the human disorder, Beckwith--Wiedemann syndrome.

Complex phenotypes and genotypes characterize the human disease, Beckwith--Wiedemann syndrome (BWS). Genetic and epigenetic mutations are found in five different genes which all lie within a 1 Mb imprinted domain on human chromosome 11p15. Only two of these genes, p57(KIP2) (CDKN1C) and IGF2, are likely to be functionally involved in this disease. The presence of the additional mutations therefore suggests a role for the regulation of these two genes by distant cis-elements. The mouse Igf2 gene is regulated by enhancers and imprinting elements which lie >120 kb downstream of its promoter. Here we show that key elements for expression of the mouse p57(Kip2) (Cdkn1c) gene also lie at a distance. Enhancers for expression within skeletal muscle and cartilage lie >25 kb downstream of the gene. In addition, we find no evidence for allele-specific expression of p57(Kip2) (Cdkn1c) from our bacterial artificial chromosome transgenes that span 315 kb around the locus. This suggests that a key imprinting element for p57(Kip2) (Cdkn1c) also lies at a distance. Therefore, BWS in humans may result from disruption of appropriate expression of the p57(KIP2) (CDKN1C) gene through mutations that occur at a substantial distance from the gene.

A transgenic approach to studying imprinted genes: modified BACs and PACs.

The advantages of using large genomic clones in the analysis of imprinted genes is described in Chapter 4 with particular reference to yeast artificial chromosomes (YACs). These contain on average 500-600 kb of DNA but can be much larger (>1 Mb). YACS are propagated in yeast and are therefore amenable to genetic modification by homologous recombination, and there are now many examples of their use to generate transgenic mice. This chapter describes a relatively new strategy for using large genomic clones that relies on Escherichia coli-based systems.

Production of YAC transgenic mice by pronuclear injection.

The production of transgenic mice using small DNA constructs has been widely used for many years to investigate the regulation of gene activity. Small plasmid-based constructs (less than 20 kb) have been favored for a number of reasons, particularly the ease with which they can be manipulated and purified in large quantities. While this approach is powerful, there are some problems associated with the size of these transgenes. In particular, many of these small transgenes do not reproduce accurately the expression seen from the endogenous gene. For some genes the regulatory elements that control activity are located at a distance from the promoter and can be omitted from the transgene. These may be enhancers, repressors, boundary elements, or even locus control regions (LCRs), which are responsible for maintaining the correct spatial and temporal expression patterns of a number of genes, such as the globin clusters in mouse and humans (1). More important, small transgenes are susceptible to position effects from the chromatin environment in which they integrate, which often results in either ectopic expression (from trapping of nearby enhancers for other genes) or suppression of gene activity. Finally, small transgenes usually integrate in a multicopy tandem arrangement that does not accurately reflect the situation seen at the endogenous locus.

A skeletal muscle-specific mouse Igf2 repressor lies 40 kb downstream of the gene.

Igf2 and H19 are closely linked and reciprocally expressed genes on distal chromosome 7 in the mouse. We have previously shown that a 130 kb YAC transgene contains multiple tissue-specific enhancers for expression of both genes during embryogenesis. The YAC also contains all the crucial elements responsible for initiating and maintaining appropriate parent-of-origin-specific expression of these genes at ectopic sites, with expression of Igf2 after paternal inheritance and of H19 after maternal inheritance. Located centrally between Igf2 and H19 are two prominent DNaseI hypersensitive sites, and two stretches of sequence that are conserved between mouse and human. In this study, we have deleted, from the transgene, a one kb part of the intergenic region that contains the hypersensitive sites and one of the homologous stretches. We demonstrate that this deletion results in loss of maternal Igf2 repression in skeletal muscle cells, most strikingly in the tongue, late in embryogenesis. We propose that the intergenic region functions as a tissue-specific repressor element, forming an integral part of the complex regulatory mechanism that controls monoallelic gene expression in this domain.

Deletion of a silencer element disrupts H19 imprinting independently of a DNA methylation epigenetic switch.

The H19 imprinted gene is silenced when paternally inherited and active only when inherited maternally. This is thought to involve a cis-acting control region upstream of H19 that is responsible for regulating a number of functions including DNA methylation, asynchronous replication of parental chromosomes and an insulator. Here we report on the function of a 1.2 kb upstream element in the mouse, which was previously shown to function as a bi-directional silencer in Drosophila. The cre-loxP-mediated targeted deletion of the 1.2 kb region had no effect on the maternal allele. However, there was loss of silencing of the paternal allele in many endodermal and other tissues. The pattern of expression was very similar to the expression pattern conferred by the enhancer elements downstream of H19. We could not detect an effect on the expression of the neighbouring imprinted Igf2 gene, suggesting that the proposed boundary element insulating this gene from the downstream enhancers was unaffected. Despite derepression of the paternal H19 allele, the deletion surprisingly did not affect the differential DNA methylation of the locus, which displayed an appropriate epigenetic switch in the parental germlines. Furthermore, the characteristic asynchronous pattern of DNA replication at H19 was also not disrupted by the deletion, suggesting that the sequences that mediate this were also intact. The silencer is therefore part of a complex cis-regulatory region upstream of the H19 gene and acts specifically to ensure the repression of the paternal allele, without a predominant effect on the epigenetic switch in the germline.

Appropriate expression of the mouse H19 gene utilises three or more distinct enhancer regions spread over more than 130 kb.

H19 and Igf2 are closely linked, reciprocally imprinted genes which lie on distal chromosome 7 in the mouse. Data suggests that common elements are used for expression and imprinting of both genes, and simple models have been proposed based on the presence of a single set of enhancers located downstream of H19. In this study we have investigated the H19 expression pattern from a 130 kb YAC transgene, which imprints H19 appropriately at ectopic loci. However, we show that while enhancers for expression in many cell types are present on the YAC, those for expression in mesodermal components of the heart, kidney, lung and thymus are located at a greater distance. Based on the available evidence, we conclude that regulation of H19 is complex, requiring contribution from at least three different sets of cell-type specific enhancers. Thus, the mechanism of reciprocal imprinting of H19 and Igf2 utilises different regulatory elements in different cell types during mouse development.

A silencer element identified in Drosophila is required for imprinting of H19 reporter transgenes in mice.

The H19 gene is subject to genomic imprinting because it is methylated and repressed after paternal inheritance and is unmethylated and expressed after maternal inheritance. We recently identified a 1.1-kb control element in the upstream region of the H19 gene that functions as a cis-acting silencer element in Drosophila. Here we investigate the function of this element in mice. We demonstrate that both H19-lacZ and H19-PLAP reporter transgenes can undergo imprinting with repression and hypermethylation after paternal transmission at many integration sites. However, transgenes that were deleted for the 1.1-kb silencer element showed loss of paternal repression, but they did not show marked changes in the paternal methylation of the remaining upstream region. This study demonstrates that the 1.1-kb control element identified in Drosophila is required to silence paternally transmitted H19 minitransgenes in mice.

Imprinting and gene silencing in mice and Drosophila.

H19 and Igf2 are located within a large imprinting domain that confers monoallelic silencing of parental alleles. The silent paternal allele of H19 is hypermethylated and relatively resistant to nucleases. Using a 130 kb yeast artificial chromosome clone, appropriate imprinting of both H19 and Igf2 was observed at single insert loci in transgenic mice. Imprinting was also observed for H19-lacZ transgenes containing 4 kb of upstream sequence, but only at multicopy loci. The H19 RNA is therefore not essential for imprinting. When the H19-lacZ transgene was introduced into Drosophila, a 1.2 kb region was identified within the 4 kb upstream flank that functioned as a bi-directional silencer. This cis element is located within a region that is apparently necessary for imprinting in mice. These studies suggest an evolutionarily conserved mechanism for gene silencing in Drosophila and imprinting in mice. We propose a new model for imprinting of H19 and Igf2 in mice in which silencing of H19 is the default state, and activation of the maternal allele requires a specific activator element.

Mechanism of imprinting on mouse distal chromosome 7.

Genomic imprinting is an epigenetic mode of gene regulation that results in expression of the autosomal 'imprinted' genes from only a single allele, determined exclusively by parental origin. To date over 20 imprinted genes have been identified in mouse and man and these appear to lie in clusters in restricted regions on a subset of chromosomes. This may be a critical feature of imprinting suggesting a domain-type mode of regulation. Imprinted domains are replicated asynchronously, show sex-specific meiotic recombination frequencies and have CpG-rich regions that are differentially methylated, often associated with the imprinted genes themselves. Mouse distal chromosome 7 is one such domain, containing at least nine imprinted genes spanning over 1 Mb of DNA. For the maternally expressed p57Kip2 gene, passage through the female germline is essential to generate the active state, whereas passage through the male germline is needed to force the maternally expressed H19 gene into an inactive state. It is therefore possible that the mouse distal chromosome 7 imprinted domain is actually composed of two or more independently regulated subdomains.

Imprinting of Igf2 and H19 from a 130 kb YAC transgene.

A stringent test for imprint control elements is to examine their function at ectopic loci in transgenic experiments. Igf2 and H19 are part of a larger imprinting region and as a first step, we examined these reciprocally imprinted genes in transgenic experiments using a 130 kb YAC clone. After paternal inheritance, H19 was appropriately repressed and Igf2 was expressed, irrespective of copy number or genetic background. After maternal inheritance H19 was consistently expressed, albeit with some variability. The levels of H19 expression per copy of the transgene inversely correlated with Igf2 (-lacZ) expression in cis. The consistent imprinting of H19 from this YAC contrasts with the previously described imprinting of mini-H19 transgenes, which only occurs at multi-copy loci, is inconsistent, and is prone to genetic background effects. We propose a novel model in which silencing of the H19 gene is the default state and its activation after maternal inheritance is the key mechanistic event for imprinting in this region. In addition, in situ analysis of the Igf2-lacZ reporter indicates that additional mesoderm-specific enhancers are present within the YAC clone. No obvious phenotype was detected from the excess gene dosage of H19.

Clonal analysis of the late flowering fca mutant of Arabidopsis thaliana: cell fate and cell autonomy.

Plants that are homozygous for the fca mutation bolt and flower later than wild-type (FCA) plants. The mutation has little or no effect on the fate map of the dry seed, except that the central cells give rise to further rosette leaves instead of the bolting stem, cauling leaves and inflorescence. The large and variable sectors affecting the late rosette leaves of fca plants were used to generate an abstract frequency-distance fate map of vegetative growth. The map relates the initiation of leaves in the plant apex to their final arrangements. The map was found to be a shallow dome with phyllotaxy superimposed on its surface. X-irradiation was used to provoke loss of the FCA allele from cells in heterozygous seeds. The resulting fca sectors had no effect on the plant phenotype. Even when L2 and L3 cells at the centre of the meristem could not produce the FCA gene product, bolting and flowering was unaffected. The genotypically fca mutant tissue was incorporated into phenotypically normal stems, cauline leaves and flowers. Possible reasons for the non-autonomous behaviour of the trait are discussed.