ABCG1 has a critical role in mediating cholesterol efflux to HDL and preventing cellular lipid accumulation.

Here we demonstrate that the ABC transporter ABCG1 plays a critical role in lipid homeostasis by controlling both tissue lipid levels and the efflux of cellular cholesterol to HDL. Targeted disruption of Abcg1 in mice has no effect on plasma lipids but results in massive accumulation of both neutral lipids and phospholipids in hepatocytes and in macrophages within multiple tissues following administration of a high-fat and -cholesterol diet. In contrast, overexpression of human ABCG1 protects murine tissues from dietary fat-induced lipid accumulation. Finally, we show that cholesterol efflux to HDL specifically requires ABCG1, whereas efflux to apoA1 requires ABCA1. These studies identify Abcg1 as a key gene involved in both cholesterol efflux to HDL and in tissue lipid homeostasis.

LXRs; oxysterol-activated nuclear receptors that regulate genes controlling lipid homeostasis.

The Liver X Receptors (LXR alpha, NR1H3; LXR beta, NR1H2) encode highly homologous transcription factors that are members of the nuclear receptor superfamily of proteins. Both LXR alpha and LXR beta form heterodimers with the obligate partner 9-cis retinoic acid receptor alpha (RXR alpha; NR2B1). LXR/RXR heterodimers function as sensors for cellular oxysterols and, when activated by these agonists, increase the expression of genes that control sterol and fatty acid metabolism/homeostasis. These conclusions are based on studies that: (i) identified oxysterols as the natural ligands for both LXR alpha and LXR beta; (ii) identified target genes that are activated by LXR/RXR; (iii) generated mice that were deficient in LXR alpha, LXR beta or both LXR alpha and LXR beta; (iv) identified synthetic LXR ligands that were extremely potent in vivo; and (v) demonstrated significant alterations in cholesterol and fatty acid homeostasis in animals in which LXR had been either activated or deleted. These findings suggest that synthetic LXR ligands may prove useful in the treatment of certain dyslipidemias. In this review, we summarize the current status of this rapidly moving area with a special emphasis on the potential for pharmacological intervention.

Expression and regulation of multiple murine ATP-binding cassette transporter G1 mRNAs/isoforms that stimulate cellular cholesterol efflux to high density lipoprotein.

The murine Abcg1 gene is reported to consist of 15 exons that encode a single mRNA (herein referred to as Abcg1-a) and protein. We now demonstrate that (i) the murine gene contains two additional coding exons downstream of exon 1, (ii) transcription involves the use of multiple promoters, and (iii) the RNA undergoes alternative splicing reactions. As a result, three mRNAs are expressed that encode three putative protein isoforms that differ at their amino terminus. ABCG1 transcripts are induced in vivo in multiple tissues in response to the liver X receptor ligand T0901317. Identification and characterization of four liver X receptor response elements in the intron downstream of exon 2 provides a mechanism by which this induction occurs. Importantly, cholesterol efflux to high density lipoprotein was stimulated following transfection of Hek293 cells with plasmids encoding individual ABCG1 isoforms. In situ hybridization studies in embryonic day 11.5-15.5 mouse embryos revealed strong expression of ABCG1 transcripts in the olfactory epithelium, hind brain, eye, and dorsal root ganglia. The relatively high levels of expression in neuronal tissues and the eye suggest that ABCG1-dependent cholesterol efflux may be critical for normal neuronal function in addition to its role in macrophages.

Binding of the AVR4 elicitor of Cladosporium fulvum to chitotriose units is facilitated by positive allosteric protein-protein interactions: the chitin-binding site of AVR4 represents a novel binding site on the folding scaffold shared between the invertebrate and the plant chitin-binding domain.

The attack of fungal cell walls by plant chitinases is an important plant defense response to fungal infection. Anti-fungal activity of plant chitinases is largely restricted to chitinases that contain a noncatalytic, plant-specific chitin-binding domain (ChBD) (also called Hevein domain). Current data confirm that the race-specific elicitor AVR4 of the tomato pathogen Cladosporium fulvum can protect fungi against plant chitinases, which is based on the presence of a novel type of ChBD in AVR4 that was first identified in invertebrates. Although these two classes of ChBDs (Hevein and invertebrate) are sequentially unrelated, they share structural homology. Here, we show that the chitin-binding sites of these two classes of ChBDs have different topologies and characteristics. The K(D), DeltaH, and DeltaS values obtained for the interaction between AVR4 and chito-oligomers are comparable with those obtained for Hevein. However, the binding site of AVR4 is larger than that of Hevein, i.e. AVR4 interacts strictly with chitotriose, whereas Hevein can also interact with the monomer N-acetylglucosamine. Moreover, binding of additional AVR4 molecules to chitin occurs through positive cooperative protein-protein interactions. By this mechanism AVR4 is likely to effectively shield chitin on the fungal cell wall, preventing the cell wall from being degraded by plant chitinases.