Toward an understanding of the gene-specific and global logic of inducible gene transcription.

Virtually all living organisms have evolved mechanisms to adapt to their environment by sensing environmental stresses and inducing the transcription of appropriate sets of response genes in a coordinated fashion. In the vertebrate immune system, the highly selective response to an environmental stimulus, often an invading microorganism, plays an especially important role in regulating the activities of, and interactions among, the many cell types involved in innate and adaptive immunity. It is now widely appreciated that the selective response to a stimulus requires the concerted action of signal transduction pathways, transcription factors, and chromatin structure. Many proteins and pathways that help to regulate a response have been characterized. However, our understanding of the gene-specific and global logic through which a highly selective response is elicited has only recently begun to emerge.

A unifying model for the selective regulation of inducible transcription by CpG islands and nucleosome remodeling.

We describe a broad mechanistic framework for the transcriptional induction of mammalian primary response genes by Toll-like receptors and other stimuli. One major class of primary response genes is characterized by CpG-island promoters, which facilitate promiscuous induction from constitutively active chromatin without a requirement for SWI/SNF nucleosome remodeling complexes. The low nucleosome occupancy at promoters in this class can be attributed to the assembly of CpG islands into unstable nucleosomes, which may lead to SWI/SNF independence. Another major class consists of non-CpG-island promoters that assemble into stable nucleosomes, resulting in SWI/SNF dependence and a requirement for transcription factors that promote selective nucleosome remodeling. Some stimuli, including serum and tumor necrosis factor-alpha, exhibit a strong bias toward activation of SWI/SNF-independent CpG-island genes. In contrast, interferon-beta is strongly biased toward SWI/SNF-dependent non-CpG-island genes. By activating a diverse set of transcription factors, Toll-like receptors induce both classes and others for an optimal response to microbial pathogens.

Class-specific regulation of pro-inflammatory genes by MyD88 pathways and IkappaBzeta.

Toll-like receptors trigger the induction of primary response genes via MyD88-mediated activation of NF-kappaB and other transcription factors. These factors then act in concert with primary response gene products to induce secondary response genes. Although the MyD88 pathway is important for the expression of both primary and secondary response genes, we show that the recruitment of NF-kappaB, RNA polymerase, and the TATA-binding protein is MyD88-dependent only at secondary response genes. This selective dependence correlates with the fact that MyD88 is required for nucleosome remodeling and histone H3K4 trimethylation at secondary response promoters, whereas rapidly induced primary response promoters are assembled into poised MyD88-independent chromatin structures. At a subset of secondary response promoters, IkappaBzeta was identified as a selective regulator of H3K4 trimethylation and preinitiation complex assembly after nucleosome remodeling. These mechanistic distinctions advance our understanding of the diverse molecular cascades that underlie the differential regulation of pro-inflammatory genes.

Pursuing gene regulation 'logic' via RNA interference and chromatin immunoprecipitation.

RNA interference and chromatin immunoprecipitation are now firmly established as useful methods for studying mechanisms of gene regulation in vivo. Their combined use can help elucidate gene regulation 'logic' by aiding in target gene identification for transcription factors and chromatin-modifying complexes.

Selective and antagonistic functions of SWI/SNF and Mi-2beta nucleosome remodeling complexes during an inflammatory response.

Studies of mammalian genes activated in response to an acute stimulus have suggested diverse mechanisms through which chromatin structure and nucleosome remodeling events contribute to inducible gene transcription. However, because of this diversity, the logical organization of the genome with respect to nucleosome remodeling and gene induction has remained obscure. Numerous proinflammatory genes are rapidly induced in macrophages in response to microbial infection. Here, we show that in lipopolysaccharide-stimulated macrophages, the catalytic BRG1/BRM subunits of the SWI/SNF class of ATP-dependent nucleosome remodeling complexes are consistently required for the activation of secondary response genes and primary response genes induced with delayed kinetics, but not for rapidly induced primary response genes. Surprisingly, a Mi-2beta complex was selectively recruited along with the SWI/SNF complexes to the control regions of secondary response and delayed primary response genes, with the Mi-2beta complex acting antagonistically to limit the induction of these gene classes. SWI/SNF and Mi-2beta complexes influenced cell size in a similarly antagonistic manner. These results provide insight into the differential contributions of nucleosome remodeling complexes to the rapid induction of defined classes of mammalian genes and reveal a robust anti-inflammatory function of Mi-2beta.