MicroRNAs in metabolism and metabolic diseases.

Aberrant cholesterol/lipid homeostasis is linked to a number of diseases prevalent in the developed world, including metabolic syndrome, type II diabetes, and cardiovascular disease. We have previously uncovered gene regulatory mechanisms of the sterol regulatory element-binding protein (SREBP) family of transcription factors, which control the expression of genes involved in cholesterol and lipid biosynthesis and uptake. Intriguingly, we recently discovered conserved microRNAs (miR-33a/b) embedded within intronic sequences of the human SREBF genes that act in a concerted manner with their host gene products to regulate cholesterol/lipid homeostasis. Indeed, miR-33a/b control the levels of ATP-binding cassette (ABC) transporter ABCA1, a cholesterol efflux pump critical for high-density lipoprotein (HDL) synthesis and reverse cholesterol transport from peripheral tissues. Importantly, antisense inhibition of miR-33 in mice results in elevated HDL and decreased atherosclerosis. Interestingly, miR-33a/b also act in the fatty acid/lipid homeostasis pathway by controlling the fatty acid ß-oxidation genes carnitine O-octanoyltransferase (CROT), hydroxyacyl-coenzyme A-dehydrogenase (HADHB), and carnitine palmitoyltransferase 1A (CPT1A), as well as the energy sensor AMP-activated protein kinase (AMPKα1), the NAD(+)-dependent sirtuin SIRT6, and the insulin signaling intermediate IRS2, key regulators of glucose and lipid metabolism. These results have revealed a highly integrated microRNA (miRNA)-host gene circuit governing cholesterol/lipid metabolism and energy homeostasis in mammals that may have important therapeutic implications for the treatment of cardiometabolic disorders.

SIRT6 in DNA repair, metabolism and ageing.

Ageing, or increased mortality with time, coupled with physiologic decline, is a nearly universal yet poorly understood biological phenomenon. Studies in model organisms suggest that two conserved pathways modulate longevity: DNA damage repair and Insulin/Igf1-like signalling. In addition, homologs of yeast Sir2--the sirtuins--regulate lifespan in diverse organisms. Here, we focus on one particular sirtuin, SIRT6. Mice lacking SIRT6 develop a degenerative disorder that in some respects mimics models of accelerated ageing [Cell (2006) 124:315]. We discuss how sirtuins in general and SIRT6 specifically relate to other evolutionarily conserved pathways affecting ageing, and how SIRT6 might function to ensure organismal homeostasis and normal lifespan.

Asynchronous replication and allelic exclusion in the immune system.

The development of mature B cells involves a series of molecular decisions which culminate in the expression of a single light-chain and heavy-chain antigen receptor on the cell surface. There are two alleles for each receptor locus, so the ultimate choice of one receptor type must involve a process of allelic exclusion. One way to do this is with a feedback mechanism that downregulates rearrangement after the generation of a productive receptor molecule, but recent work suggests that monoallelic epigenetic changes may also take place even before rearrangement. To better understand the basis for distinguishing between alleles, we have analysed DNA replication timing. Here we show that all of the B-cell-receptor loci (mu, kappa and lambda) and the TCRbeta locus replicate asynchronously. This pattern, which is established randomly in each cell early in development and maintained by cloning, represents an epigenetic mark for allelic exclusion, because it is almost always the early-replicating allele which is initially selected to undergo rearrangement in B cells. These results indicate that allelic exclusion in the immune system may be very similar to the process of X chromosome inactivation.

Developmental regulation of DNA replication timing at the human beta globin locus.

The human beta globin locus replicates late in most cell types, but becomes early replicating in erythroid cells. Using FISH to map DNA replication timing around the endogenous beta globin locus and by applying a genetic approach in transgenic mice, we have demonstrated that both the late and early replication states are controlled by regulatory elements within the locus control region. These results also show that the pattern of replication timing is set up by mechanisms that work independently of gene transcription.

The imprinting box of the Prader-Willi/Angelman syndrome domain.

A subset of mammalian genes is monoallelically expressed in a parent-of-origin manner. These genes are subject to an imprinting process that epigenetically marks alleles according to their parental origin during gametogenesis. Imprinted genes can be organized in clusters as exemplified by the 2-Mb domain on human chromosome 15q11-q13 and its mouse orthologue on chromosome 7c (ref. 1). Loss of this 2-Mb domain on the paternal or maternal allele results in two neurogenetic disorders, Prader-Willi syndrome (PWS) or Angelman syndrome (AS), respectively. Microdeletions on the paternal allele share a 4.3-kb short region of overlap (SRO), which includes the SNRPN promoter/exon1, cause PWS and silence paternally expressed genes. Microdeletions on the maternal allele share a 0.88-kb SRO located 35 kb upstream to the SNRPN promoter, cause AS and alleviate repression of genes on the maternal allele. Individuals carrying both AS and PWS deletions on the paternal allele show a PWS phenotype and genotype. These observations suggest that cis elements within the AS-SRO and PWS-SRO constitute an imprinting box that regulates the entire domain on both chromosomes. Here we show that a minitransgene composed of a 200-bp Snrpn promoter/exon1 and a 1-kb sequence located approximately 35 kb upstream to the SNRPN promoter confer imprinting as judged by differential methylation, parent-of-origin-specific transcription and asynchronous replication.

DNA demethylation: turning genes on.

The regulation of eukaryotic gene expression is a complicated process involving the interaction of a large number of transacting factors with specific cis-regulatory elements. DNA methylation plays a role in this scheme by acting in cis to modulate protein-DNA interactions. Several lines of evidence indicate that methylation serves to silence transcription, mainly through indirect mechanisms involving the assembly of repressive nucleoprotein complexes. DNA demethylation is mostly an active enzymatic process, controlled by cis regulatory elements which provide binding sites for trans demethylation factors. In the immune system DNA methylation plays multiple roles, such as regulating both gene expression and gene rearrangement

Kappa chain monoallelic demethylation and the establishment of allelic exclusion.

Allelic exclusion in kappa light-chain synthesis is thought to result from a feedback mechanism by which the expression of a functional kappa light chain on the surface of the B cell leads to an intracellular signal that down-regulates the V(D)J recombinase, thus precluding rearrangement of the other allele. Whereas such a feedback mechanism clearly plays a role in the maintenance of allelic exclusion, here we provide evidence suggesting that the initial establishment of allelic exclusion involves differential availability of the two kappa alleles for rearrangement. Analysis of kappa+ B-cell populations and of individual kappa+ B cells that have rearranged only one allele demonstrates that in these cells, critical sites on the rearranged allele are unmethylated, whereas the nonrearranged allele remains methylated. This pattern is apparently generated by demethylation that is initiated at the small pre-B cell stage, on a single allele, in a process that occurs prior to rearrangement and requires the presence in cis of both the intronic and 3' kappa enhancers. Taken together with data demonstrating that undermethylation is required for rearrangement, these results indicate that demethylation may actually underly the process of allelic exclusion by directing the initial choice of a single kappa allele for rearrangement.

A role for nuclear NF-kappaB in B-cell-specific demethylation of the Igkappa locus.

The immunoglobulin kappa gene is specifically demethylated during B-cell maturation in a process which utilizes discrete cis-acting modules such as the intronic kappa enhancer element and the matrix attachment region (MAR). While any MAR sequence is sufficient for this reaction, mutation analysis indicates that tissue specificity is mediated by kappaB binding sequences within the kappa intronic enhancer. The plasmacytoma cell line S107 lacks kappaB binding activity and fails to demethylate the kappa locus. However, B-cell specific demethylation is restored by the introduction of an active kappaB binding protein gene relB. This represents the first demonstration of a trans-acting factor involved in cell-type-specific demethylation, and suggests that the same protein-DNA recognition system used for transcription may also contribute to the earlier developmental events that bring about activation of the kappa locus.