A putative transcription factor with seven zinc-finger motifs identified in the developing suprachiasmatic nucleus by the differential display PCR method

CXCL14 enhances insulin-dependent glucose uptake in adipocytes and is related to high-fat diet-induced obesity

Accumulating evidence suggests an association between obesity and adipose tissue inflammation. Chemokines are involved in the regulation of inflammation status. Chemokine (C-X-C motif) ligand 14 (CXCL14) is known to be a chemoattractant for monocyte and dendritic cells. Recently, it was reported that CXCL14-deficient mice show resistance to high-fat diet-induced obesity. In this study, we identified CXCL14 as a growth hormone (GH)-induced gene in HepG2 hepatoma cells. Substantial in vivo expression of CXCL14 was detected in the adipose tissue and liver. Its expression and secretion were strikingly increased by insulin administration and high-fat diet. Intriguingly, incubation of 3T3-L1 adipocytes with CXCL14 stimulated insulin-dependent glucose uptake. Further, this effect was associated with enhanced insulin signaling. CXCL14 enhanced the insulin-induced tyrosine phosphorylation of insulin receptors and insulin receptor substrate-1. These results suggest that CXCL14 plays a causal role in high-fat diet-induced obesity.

Gene expression profiling reveals multiple novel intrinsic and extrinsic factors associated with axonal regeneration failure

In contrast to the regeneration-competent peripheral nervous system (PNS), lesions of nerve tracts within the central nervous system (CNS) lead to chronically impaired neuronal connections. We have analysed changes in gene expression patterns occurring as a consequence of postcommissural fornix transection at a time when spontaneous axonal growth has ceased at the lesion site. This was done in order to describe both extrinsic and intrinsic determinants of regeneration failure. Using a genomic approach we have identified a number of so far undetected factors such as bamacan and semaphorin 6B, which relate to chronic axonal growth arrest and therefore are promising candidates for lesion-induced axonal growth inhibitors. In addition, we observed that within the subiculum, where the fornix axons originate, neuronal Oct-6 was induced and NG2 was down-regulated, indicating that axotomized neurons as well as glial cells react at the level of gene expression to remote axotomy.

A P element with a novel fusion of reporters identifies regular, a C2H2 zinc-finger gene downstream of the circadian clock

Elucidating the mechanisms that link the circadian pacemaker to the timing of behaviors it controls is one of the greatest challenges in circadian biology. We report the generation of a P element, Pluc+, containing a novel reporter fusion. Our fusion reporter capitalizes on the use of luciferase bioluminescence to easily analyze temporal expression as well as the strength of myc epitopes and GFP to identify spatial expression. Using Pluc+ we have identified and characterized a novel C2H2 zinc-finger gene, regular (rgr), that cycles circadianly in phase with period (per) gene expression, but shifts to light-dark regulation in Clk(Jrk) mutant flies. By following myc expression of the Pluc+ reporter, we demonstrate that Rgr is expressed in a discrete number of neurons in the brain which overlap with axons expressing pigment-dispersing factor.

Rhythmic expression of ROR beta mRNA in the mice suprachiasmatic nucleus

The expression of the brain rich orphan nuclear receptor ROR beta (retinoid-related orphan receptor beta) was investigated in the mouse brain by in situ hybridization using antisense cRNA probe. Positive ROR beta mRNA signals were detected in various parts of the brain with high expression in the suprachiasmatic nucleus (SCN). In the SCN, ROR beta mRNA signals showed a peak at early daytime (ZT/CT4) and a trough at early nighttime (ZT/CT16) in both light-dark and constant dark conditions. Light exposure at subjective night did not alter the expression level. These findings suggest that ROR beta is a new member of a transcription factor possibly related to the circadian pacemaking system.

Theileria annulata: identification, by differential mRNA display, of modulated host and parasite gene expression in cell lines that are competent or attenuated for differentiation to the merozoite

To identify both host and parasite genes that show altered expression during differentiation of Theileria annulata from the macroschizont to the merozoite stage of the life cycle, the RNA profiles of two T. annulata-infected clonal cell lines (D7 and D7B12) with the same genetic background have been compared by RNA display. In the cloned cell line D7, T. annulata differentiates from the macroschizont to the merozoite at 41 degrees C, whereas in the cell line D7B12, which was derived by recloning D7, the parasite does not differentiate. Therefore, genes that show altered expression levels in either clone could be modulated by the differentiation event and are possible candidates for regulators of this process. Differential display was carried out initially on RNA extracted from D7 and D7B12 macroschizont-infected cells cultured at 37 degrees C and secondly on RNA extracted from the two cell lines incubated at 41 degrees C to induce differentiation to the merozoite. The first procedure identified 29 cDNA fragments that displayed altered levels between D7 and D7B12, 9 of which were confirmed to be differentially expressed by Northern blot analysis. Of these 9 gene fragments, 8 were found to be of host origin, while 1 was parasite derived. The second RNA display analysis identified 14 transcripts that showed altered levels during a differentiation time course, of which 6 were confirmed to be differentially expressed between D7B12 cells and differentiating D7 cells by Northern blot analysis. Of these 6 gene fragments, 1 was of host and 5 were of parasite origin. The parasite genes either showed levels of RNA consistent with constitutive gene expression or, in one case, a genuine upregulation of mRNA associated with the differentiation process.