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5 Publications

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    Tjian Lab
    12/15/04 | Polybromo protein BAF180 functions in mammalian cardiac chamber maturation.
    Wang Z, Zhai W, Richardson JA, Olson EN, Meneses JJ, Firpo MT, Kang C, Skarnes WC, Tjian R
    Genes & Development. 2004 Dec 15;18(24):3106-16. doi: 10.1073/pnas.1100640108

    BAF and PBAF are two related mammalian chromatin remodeling complexes essential for gene expression and development. PBAF, but not BAF, is able to potentiate transcriptional activation in vitro mediated by nuclear receptors, such as RXRalpha, VDR, and PPARgamma. Here we show that the ablation of PBAF-specific subunit BAF180 in mouse embryos results in severe hypoplastic ventricle development and trophoblast placental defects, similar to those found in mice lacking RXRalpha and PPARgamma. Embryonic aggregation analyses reveal that in contrast to PPARgamma-deficient mice, the heart defects are likely a direct result of BAF180 ablation, rather than an indirect consequence of trophoblast placental defects. We identified potential target genes for BAF180 in heart development, such as S100A13 as well as retinoic acid (RA)-induced targets RARbeta2 and CRABPII. Importantly, BAF180 is recruited to the promoter of these target genes and BAF180 deficiency affects the RA response for CRABPII and RARbeta2. These studies reveal unique functions of PBAF in cardiac chamber maturation.

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    Tjian Lab
    07/01/04 | Distinct conformational states of nuclear receptor-bound CRSP-Med complexes.
    Taatjes DJ, Schneider-Poetsch T, Tjian R
    Nature Structural & Molecular Biology. 2004 Jul;11(7):664-71. doi: 10.1073/pnas.1100640108

    The human CRSP-Med coactivator complex is targeted by a diverse array of sequence-specific regulatory proteins. Using EM and single-particle reconstruction techniques, we recently completed a structural analysis of CRSP-Med bound to VP16 and SREBP-1a. Notably, these activators induced distinct conformational states upon binding the coactivator. Ostensibly, these different conformational states result from VP16 and SREBP-1a targeting distinct subunits in the CRSP-Med complex. To test this, we conducted a structural analysis of CRSP-Med bound to either thyroid hormone receptor (TR) or vitamin D receptor (VDR), both of which interact with the same subunit (Med220) of CRSP-Med. Structural comparison of TR- and VDR-bound complexes (at a resolution of 29 A) indeed reveals a shared conformational feature that is distinct from other known CRSP- Med structures. Importantly, this nuclear receptor-induced structural shift seems largely dependent on the movement of Med220 within the complex.

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    Tjian Lab
    06/04/04 | Structure and function of CRSP/Med2; a promoter-selective transcriptional coactivator complex.
    Taatjes DJ, Tjian R
    Molecular Cell. 2004 Jun 4;14(5):675-83. doi: 10.1073/pnas.1100640108

    The multi-subunit, human CRSP coactivator-also known as Mediator (Med)-regulates transcription by mediating signals between enhancer-bound factors (activators) and the core transcriptional machinery. Interestingly, different activators are known to bind distinct subunits within the CRSP/Med complex. We have isolated a stable, endogenous CRSP/Med complex (CRSP/Med2) that specifically lacks both the Med220 and the Med70 subunits. The three-dimensional structure of CRSP/Med2 was determined to 31 A resolution using electron microscopy and single-particle reconstruction techniques. Despite lacking both Med220 and Med70, CRSP/Med2 displays potent, activator-dependent transcriptional coactivator function in response to VP16, Sp1, and Sp1/SREBP-1a in vitro using chromatin templates. However, CRSP/Med2 is unable to potentiate activated transcription from a vitamin D receptor-responsive promoter, which requires interaction with Med220 for coactivator recruitment, whereas VDR-directed activation by CRSP/Med occurs normally. Thus, it appears that CRSP/Med may be regulated by a combinatorial assembly mechanism that allows promoter-selective function upon exchange of specific coactivator targets.

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    Tjian Lab
    05/01/04 | Regulatory diversity among metazoan co-activator complexes.
    Taatjes DJ, Marr MT, Tjian R
    Nature Reviews. Molecular Cell Biology. 2004 May;5(5):403-10. doi: 10.1073/pnas.1100640108

    Transcription is a stepwise process that involves many specialized proteins and protein complexes, all of which must work together to express a given gene in a spatially and temporally regulated manner. An integral step in this regulatory process is carried out by large, multisubunit co-activator complexes, which have diverse roles in transcriptional control. Their diversity and large size allows for many potential regulatory inputs, but how is the versatility and specificity of these co-activator complexes determined?

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    Tjian Lab
    01/13/04 | Myc-interacting protein 1 target gene profile: a link to microtubules, extracellular signal-regulated kinase, and cell growth.
    Ziegelbauer J, Wei J, Tjian R
    Proceedings of the National Academy of Sciences of the United States of America. 2004 Jan 13;101(2):458-63. doi: 10.1073/pnas.1100640108

    To study the role of the transcription factor Myc-interacting protein 1 (MIZ-1) in activating various target genes after induction with the microtubule disrupting agent T113242, we have used small interfering RNA duplexes (siRNAs) to knockdown the expression of MIZ-1. As expected, depletion of MIZ-1 resulted in the inhibition of T113242-dependent activation of the low-density lipoprotein receptor (LDLR) gene in hepatocytes. Cells transfected with MIZ-1 siRNAs also exhibited growth arrest. In addition, inhibition of the extracellular signal-regulated kinase (ERK) pathway inhibited T113242-induced nuclear accumulation of MIZ-1 and activation of LDLR. Gene expression microarray analysis under various induction conditions identified other T113242-activated genes affected by a decrease in MIZ-1 and inhibition of the ERK pathway. We also found that the accumulation of MIZ-1 in the nucleus is influenced by cell-cell contact and/or growth. Taken together, our studies suggest that MIZ-1 regulates a specific set of genes that includes LDLR and that the ERK pathway plays a role in the activation of target promoters by MIZ-1.

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