R.W. Cameron Dingle scite author profile

The ␣-fetoprotein (AFP) and H19 genes are transcribed at high levels in the mammalian fetal liver but are rapidly repressed postnatally. This repression in the liver is controlled, at least in part, by the Afr1 gene. Afr1 was defined >25 years ago when BALB͞cJ mice were found to have 5-to 20-fold higher adult serum AFP levels compared with all other mouse strains; subsequent studies showed that this elevation was due to higher Afp expression in the liver. H19, which has become a model for genomic imprinting, was identified initially in a screen for Afr1-regulated genes. The BALB͞cJ allele (Afr1 b ) is recessive to the wild-type allele (Afr1 a ), consistent with the idea that Afr1 functions as a repressor. By high-resolution mapping, we identified a gene that maps to the Afr1 interval on chromosome 15 and encodes a putative zinc fingers and homeoboxes (ZHX) protein. In BALB͞cJ mice, this gene contains a murine endogenous retrovirus within its first intron and produces predominantly an aberrant transcript that no longer encodes a functional protein. Liver-specific overexpression of a Zhx2 transgene restores wild-type H19 repression on a BALB͞cJ background, confirming that this gene is responsible for hereditary persistence of Afp and H19 in the livers of BALB͞cJ mice. Thus we have identified a genetically defined transcription factor that is involved in developmental gene silencing in mammals. We present a model to explain the liver-specific phenotype in BALB͞cJ mice, even though Afr1 is a ubiquitously expressed gene.development ͉ genetics ͉ positional cloning

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Role of the xenobiotic receptor in inflammatory bowel disease

Arsenescu

Zhong

et al. 2011

Inflammatory Bowel Diseases

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Background Gene-environment interplay modulates Inflammatory Bowel Diseases [IBD]. Dioxin-like compounds can activate the Aryl Hydrocarbon Receptor [AhR] and alter macrophage function as well as T cell polarization. We hypothesized that attenuation of the AhR signaling pathway will ameliorate colitis in a murine model of IBD. Design DSS colitis was induced in C57BL/6 AhR null mice [AhR −/−], heterozygous mice [AhR−/+], and their wild type [WT] littermates. Clinical and morphopathological parameters were used to compare the groups. Patients: AhR pathway activation was analyzed in biopsy specimens from 25 IBD patients and 15 healthy controls. Results AhR −/− mice died before the end of the treatment. However, AhR −/+ mice exhibited decreased disease activity compared to WT mice. The AhR −/+ mice expressed less proinflammatory cytokines such as TNFα (6.1 versus 15.7 fold increase) and IL17 (23.7 versus 67.9 fold increase) and increased antiinflammatory IL-10 (2.3 fold increase) compared with the AhR+/+ mice in the colon. Colonic macrophage infiltration was attenuated in the AhR −/+ group. AhR and its downstream targets were significantly upregulated in IBD patients versus control (CYP1A1 – 19.9, and IL8-10 fold increase). Conclusion Attenuation of the AhR receptor expression resulted in a protective effect during DSS-induced colitis, while the absence of AhR exacerbated the disease. Abnormal AhR pathway activation in the intestinal mucosa of IBD patients may promote chronic inflammation. Modulation of AhR signaling pathway via the diet, cessation of smoking or administration of AhR antagonists could be viable strategies for the treatment of IBD.

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Development of Novel CH223191-Based Antagonists of the Aryl Hydrocarbon Receptor

Choi¹,

Lee²,

Dingle³

et al. 2011

Mol Pharmacol

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Aryl hydrocarbon receptor (AHR) is a ligand-activated transcription factor that regulates genes involved in drug/xenobiotic metabolism, cell cycle progression, cell fate determination, immune function, and inflammatory response. Increasing evidence that AHR plays a role in the pathophysiology of a number of human disease states is driving the need for improved pharmacological tools to be used for understanding the in vivo impact of AHR modulation. In this study, we have characterized and used structure-activity relationship analyses of a newly synthesized library of derivatives of the potent AHR antagonist 2-methyl-2H-pyrazole-3-carboxylic acid (2-methyl-4-o-tolylazo-phenyl)-amide (CH223191). Initial screening of these compounds revealed that those bearing groups with strong electronegativity at the R1 position (i.e., CHD-5, CHD-11, and CHD-12) versus those that are more electron-poor at this position (i.e., CHD-7 and CHD-8) elicited the most potent AHR antagonistic properties. The ability of these derivatives to inhibit agonist (2,3,7,8-tetrachlorodibenzo-p-dioxin) binding, nuclear translocation of AHR, and agonist-induced enzyme activity also were determined and support the initial findings. Furthermore, CH223191, but not CHD-5, CHD-11, or CHD-12, was found to exhibit AHR-independent proproliferative properties. These results contribute to our understanding of the structural requirements of potent AHR antagonists and the development of effective pharmacological tools to be used for studying the pathophysiological role of AHR.

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B-cell and plasma-cell splicing differences: A potential role in regulated immunoglobulin RNA processing

Bruce¹,

Dingle²,

Peterson³

2003

RNA

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The immunoglobulin µ pre-mRNA is alternatively processed at its 3 end by competing splice and cleavage-polyadenylation reactions to generate mRNAs encoding the membrane-associated or secreted forms of the IgM protein, respectively. The relative use of the competing processing pathways varies during B-lymphocyte development, and it has been established previously that cleavage-polyadenylation activity is higher in plasma cells, which secrete IgM, than in B cells, which produce membraneassociated IgM. To determine whether RNA-splicing activity varies during B-lymphocyte development to contribute to µ RNA-processing regulation, we first demonstrate that µ pre-mRNA processing is sensitive to artificial changes in the splice environment by coexpressing SR proteins with the µ gene. To explore differences between the splice environments of B cells and plasma cells, we analyzed the splicing patterns from two different chimeric non-Ig genes that can be alternatively spliced but have no competing cleavage-polyadenylation reaction. The ratio of intact exon splicing to cryptic splice site use from one chimeric gene differs between several B-cell and several plasma-cell lines. Also, the amount of spliced RNA is higher in B-cell than plasma-cell lines from a set of genes whose splicing is dependent on a functional exonic splice enhancer. Thus, there is clear difference between the B-cell and plasma-cell splicing environments. We propose that both general cleavage-polyadenylation and general splice activities are modulated during B-lymphocyte development to ensure proper regulation of the alternative µ RNA processing pathways.

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