Browsing by Author "Mullen, Rachel D."

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    Cell-specific actions of a human LHX3 gene enhancer during pituitary and spinal cord development
    (The Endocrine Society, 2013-12) Park, Soyoung; Mullen, Rachel D.; Rhodes, Simon J.; Department of Biology, School of Science
    The LIM class of homeodomain protein 3 (LHX3) transcription factor is essential for pituitary gland and nervous system development in mammals. In humans, mutations in the LHX3 gene underlie complex pediatric syndromes featuring deficits in anterior pituitary hormones and defects in the nervous system. The mechanisms that control temporal and spatial expression of the LHX3 gene are poorly understood. The proximal promoters of the human LHX3 gene are insufficient to guide expression in vivo and downstream elements including a conserved enhancer region appear to play a role in tissue-specific expression in the pituitary and nervous system. Here we characterized the activity of this downstream enhancer region in regulating gene expression at the cellular level during development. Human LHX3 enhancer-driven Cre reporter transgenic mice were generated to facilitate studies of enhancer actions. The downstream LHX3 enhancer primarily guides gene transcription in α-glycoprotein subunit -expressing cells secreting the TSHβ, LHβ, or FSHβ hormones and expressing the GATA2 and steroidogenic factor 1 transcription factors. In the developing nervous system, the enhancer serves as a targeting module active in V2a interneurons. These results demonstrate that the downstream LHX3 enhancer is important in specific endocrine and neural cell types but also indicate that additional regulatory elements are likely involved in LHX3 gene expression. Furthermore, these studies revealed significant gonadotrope cell heterogeneity during pituitary development, providing insights into the cellular physiology of this key reproductive regulatory cell. The human LHX3 enhancer-driven Cre reporter transgenic mice also provide a valuable tool for further developmental studies of cell determination and differentiation in the pituitary and nervous system.
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    In Vivo Analysis of Human LHX3 Gene Regulation
    (2011-02) Mullen, Rachel D.; Rhodes, Simon J.; Herring, B. Paul; Skalnik, David Gordon; Thurmond, Debbie C.; Walvoord, Emily C.
    LHX3 is a transcription factor important in pituitary and nervous system development. Patients with mutations in coding regions of the gene have combined pituitary hormone deficiency (CPHD) that causes growth, fertility, and metabolic problems. Promoter and intronic elements of LHX3 important for basal gene expression in vitro have been identified, but the key regulatory elements necessary for in vivo expression were unknown. With these studies, I sought to elucidate how LHX3 gene expression is regulated in vivo. Based on sequence conservation between species in non-coding regions, I identified a 7.9 kilobase (kb) region 3' of the human LHX3 gene as a potential regulatory element. In a beta galactosidase transgenic mouse model, this region directed spatial and temporal expression to the developing pituitary gland and spinal cord in a pattern consistent with endogenous LHX3 expression. Using a systematic series of deletions, I found that the conserved region contains multiple nervous system enhancers and a minimal 180 base pair (bp) enhancer that direct expression to both the pituitary and spinal cord in transgenic mice. Within this minimal enhancer, TAAT/ATTA sequences that are characteristic of homeodomain protein binding sites are required to direct expression. I performed DNA binding experiments and chromatin immunoprecipitation assays to reveal that the ISL1 and PITX1 proteins specifically recognize these elements in vitro and in vivo. Based on in vivo mutational analyses, two tandem ISL1 binding sites are required for enhancer activity in the pituitary and spine and a PITX1 binding site is required for spatial patterning of gene expression in the pituitary. Additional experiments demonstrated that these three elements cannot alone direct gene expression, suggesting a combination of factors is required for enhancer activity. This study reveals that the key regulatory elements guiding developmental regulation of the human LHX3 gene lie in this conserved downstream region. Further, this work implicates ISL1 as a new transcriptional regulator of LHX3 and describes a possible mechanism for the regulation of LHX3 by a known upstream factor, PITX1. Identification of important regulatory regions will also enable genetic screening in candidate CPHD patients and will thereby facilitate patient treatment and genetic counseling.