The nuclear receptor PPARß/δ programs muscle glucose metabolism in cooperation with AMPK and MEF2.

To identify new gene regulatory pathways controlling skeletal muscle energy metabolism, comparative studies were conducted on muscle-specific transgenic mouse lines expressing the nuclear receptors peroxisome proliferator-activated receptor α (PPARα; muscle creatine kinase [MCK]-PPARα) or PPARß/δ (MCK-PPARß/δ). MCK-PPARß/δ mice are known to have enhanced exercise performance, whereas MCK-PPARα mice perform at low levels. Transcriptional profiling revealed that the lactate dehydrogenase b (Ldhb)/Ldha gene expression ratio is increased in MCK-PPARß/δ muscle, an isoenzyme shift that diverts pyruvate into the mitochondrion for the final steps of glucose oxidation. PPARß/δ gain- and loss-of-function studies in skeletal myotubes demonstrated that PPARß/δ, but not PPARα, interacts with the exercise-inducible kinase AMP-activated protein kinase (AMPK) to synergistically activate Ldhb gene transcription by cooperating with myocyte enhancer factor 2A (MEF2A) in a PPARß/δ ligand-independent manner. MCK-PPARß/δ muscle was shown to have high glycogen stores, increased levels of GLUT4, and augmented capacity for mitochondrial pyruvate oxidation, suggesting a broad reprogramming of glucose utilization pathways. Lastly, exercise studies demonstrated that MCK-PPARß/δ mice persistently oxidized glucose compared with nontransgenic controls, while exhibiting supranormal performance. These results identify a transcriptional regulatory mechanism that increases capacity for muscle glucose utilization in a pattern that resembles the effects of exercise training.

Temporal and developmental requirements for the Prader-Willi imprinting center.

Imprinted gene expression associated with Prader-Willi syndrome (PWS) and Angelman syndrome (AS) is controlled by two imprinting centers (ICs), the PWS-IC and the AS-IC. The PWS-IC operates in cis to activate transcription of genes that are expressed exclusively from the paternal allele. We have created a conditional allele of the PWS-IC to investigate its developmental activity. Deletion of the paternal PWS-IC in the embryo before implantation abolishes expression of the paternal-only genes in the neonatal brain. Surprisingly, deletion of the PWS-IC in early brain progenitors does not affect the subsequent imprinted status of PWS/AS genes in the newborn brain. These results indicate that the PWS-IC functions to protect the paternal epigenotype at the epiblast stage of development but is dispensable thereafter.

Transcription is required to establish maternal imprinting at the Prader-Willi syndrome and Angelman syndrome locus.

The Prader-Willi syndrome (PWS [MIM 17620]) and Angelman syndrome (AS [MIM 105830]) locus is controlled by a bipartite imprinting center (IC) consisting of the PWS-IC and the AS-IC. The most widely accepted model of IC function proposes that the PWS-IC activates gene expression from the paternal allele, while the AS-IC acts to epigenetically inactivate the PWS-IC on the maternal allele, thus silencing the paternally expressed genes. Gene order and imprinting patterns at the PWS/AS locus are well conserved from human to mouse; however, a murine AS-IC has yet to be identified. We investigated a potential regulatory role for transcription from the Snrpn alternative upstream exons in silencing the maternal allele using a murine transgene containing Snrpn and three upstream exons. This transgene displayed appropriate imprinted expression and epigenetic marks, demonstrating the presence of a functional AS-IC. Transcription of the upstream exons from the endogenous locus correlates with imprint establishment in oocytes, and this upstream exon expression pattern was conserved on the transgene. A transgene bearing targeted deletions of each of the three upstream exons exhibited loss of imprinting upon maternal transmission. These results support a model in which transcription from the Snrpn upstream exons directs the maternal imprint at the PWS-IC.

A new deletion refines the boundaries of the murine Prader-Willi syndrome imprinting center.

The human chromosomal 15q11-15q13 region is subject to both maternal and paternal genomic imprinting. Absence of paternal gene expression from this region results in Prader-Willi syndrome (PWS), while absence of maternal gene expression leads to Angelman syndrome. Transcription of paternally expressed genes in the region depends upon an imprinting center termed the PWS-IC. Imprinting defects in PWS can be caused by microdeletions and the smallest commonly deleted region indicates that the PWS-IC lies within a region of 4.3 kb. The function and location of the PWS-IC is evolutionarily conserved, but delineation of the PWS-IC in mouse has proven difficult. The first targeted mutation of the PWS-IC, a deletion of 35 kb spanning Snrpn exon 1, exhibited a complete PWS-IC deletion phenotype. Pups inheriting this mutation paternally showed a complete loss of paternal gene expression and died neonatally. A reported deletion of 4.8 kb showed only a reduction in paternal gene expression and incomplete penetrance of neonatal lethality, suggesting that some PWS-IC function had been retained. Here, we report that a 6 kb deletion spanning Snrpn exon 1 exhibits a complete PWS-IC deletion phenotype. Pups inheriting this mutation paternally lack detectable expression of all PWS genes and paternal silencing of Ube3a, exhibit maternal DNA methylation imprints at Ndn and Mkrn3 and suffer failure to thrive leading to a fully penetrant neonatal lethality.

Atp10a, a gene adjacent to the PWS/AS gene cluster, is not imprinted in mouse and is insensitive to the PWS-IC.

Mutations affecting a cluster of coordinately regulated imprinted genes located at 15q11-q13 underlie both Prader-Willi syndrome (PWS) and Angelman syndrome (AS). Disruption of the predominately maternally expressed UBE3A locus is sufficient to meet diagnostic criteria for AS. However, AS patients with a deletion of the entire PWS/AS locus often have more severe traits than patients with point mutations in UBE3A suggesting that other genes contribute to the syndrome. ATP10A resides 200 kb telomeric to UBE3A and is of uncertain imprinted status. An initial report indicated bialleleic expression of the murine Atp10a in all tissues, but a subsequent report suggests that Atp10a is predominantly maternally expressed in the hippocampus and olfactory bulb. To resolve this discrepancy, we investigated Atp10a allelic expression in the brain, DNA methylation status, and sensitivity to mutations of the PWS imprinting center, an element required for imprinted gene expression in the region. We report that Atp10a is biallelically expressed in both the newborn and adult brain, and Atp10a allelic expression is insensitive to deletion or mutation of the PWS imprinting center. The CpG island associated with Atp10a is hypomethylated, a result consistent with the notion that Atp10a is not an imprinted gene.

Immunomagnetic purification of murine primordial germ cells.

Primordial germ cells (PGCs) play essential roles in both reproduction and development. In this chapter, we describe a method used in our laboratory for the immunopurification of PGCs from the mouse embryo. After dissection and disruption of the fetal gonad, PGCs are identified by a monoclonal antibody recognizing an epitope characteristic of pluripotent stem cells. After reaction with a paramagnetic bead-linked secondary antibody, the cell mixture is applied to a strong magnetic field. PGCs are recovered by release from the magnetic field. Purity is assessed by the alkaline phosphatase activity inherent to PGCs.