The Drosophila blastoderm embryo has provided key insights into eukaryotic transcriptional regulatory mechanisms, in particular the integration of basic biochemical processes in a developmental setting, where differential gene expression is used to drive the developmental fate of particular cells and tissues. Our research has focused on understanding the action of transcriptional repressors in this setting, because a major portion of the pattern generation relies on a cohort of zygotically expressed gap gene repressors. In the last grant period, we have utilized biochemical, genetic, and mathematical modeling approaches to understand the mechanisms of transcriptional repressors, to identify and characterize the corepressors that interact with these proteins, and quantitatively analyze the cis-regulatory code that describes the architecture of enhancers regulated by these proteins. These studies have demonstrated for the first time that short- and long-range repressors induce qualitatively very different effects at the chromatin level, and that the same set of corepressors can elicit very different effects depending on context. Our testing and modeling of short-range repressors revealed some of these contextual effects, providing the basis for a dissection of transcriptional "grammar" that unlocks genomic regulatory information. In our next funding period, we propose three aims to 1) extend our understanding of the cis-regulatory code through analysis and modeling of endogenous enhancers, 2) discern at a genomic level the activity and importance of multiple corepressors recruited by repressors, including distinct effects wrought by the mechanistically divergent short- and long-range repressors, and 3) characterize the importance in repression of a new type of corepressor, a DEAD box RNA helicase, which we have identified as a cofactor of the Knirps protein. The impact of these integrated aims will be to provide a detailed mechanistic and systems-wide understanding of conserved transcriptional regulatory processes that are used throughout metazoan development. The insights gained from these studies will provide essential underpinnings for population and evolutionary studies of development and disease in higher eukaryotes.
This research program seeks to understand the language of gene regulation that is encoded in the DNA. By determining how the proteins that serve as off switches act to interrupt gene expression, we will be able to identify processes that underlie animal development, and discern how they are misregulated in the context of disease. Furthermore, by use of modeling approaches, we will be able to better interpret genetic mutations that disrupt the integrity of the DNA switches to which these regulatory proteins bind.
|Suleimenov, Yerzhan; Ay, Ahmet; Samee, Md Abul Hassan et al. (2013) Global parameter estimation for thermodynamic models of transcriptional regulation. Methods 62:99-108|
|Li, Li M; Arnosti, David N (2011) Long- and short-range transcriptional repressors induce distinct chromatin states on repressed genes. Curr Biol 21:406-12|
|Sayal, Rupinder; Ryu, Seuk-Min; Arnosti, David N (2011) Optimization of reporter gene architecture for quantitative measurements of gene expression in the Drosophila embryo. Fly (Austin) 5:47-52|
|Zhang, Yang W; Arnosti, David N (2011) Conserved catalytic and C-terminal regulatory domains of the C-terminal binding protein corepressor fine-tune the transcriptional response in development. Mol Cell Biol 31:375-84|
|Ay, Ahmet; Arnosti, David N (2011) Mathematical modeling of gene expression: a guide for the perplexed biologist. Crit Rev Biochem Mol Biol 46:137-51|
|Fakhouri, Walid D; Ay, Ahmet; Sayal, Rupinder et al. (2010) Deciphering a transcriptional regulatory code: modeling short-range repression in the Drosophila embryo. Mol Syst Biol 6:341|
|Payankaulam, Sandhya; Li, Li M; Arnosti, David N (2010) Transcriptional repression: conserved and evolved features. Curr Biol 20:R764-71|
|Dresch, Jacqueline M; Liu, Xiaozhou; Arnosti, David N et al. (2010) Thermodynamic modeling of transcription: sensitivity analysis differentiates biological mechanism from mathematical model-induced effects. BMC Syst Biol 4:142|
|Payankaulam, Sandhya; Arnosti, David N (2009) Groucho corepressor functions as a cofactor for the Knirps short-range transcriptional repressor. Proc Natl Acad Sci U S A 106:17314-9|
|Ay, Ahmet; Fakhouri, Walid D; Chiu, Chichia et al. (2008) Image processing and analysis for quantifying gene expression from early Drosophila embryos. Tissue Eng Part A 14:1517-26|
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