Neuron-restrictive silencer factor functions to suppress Sp1-mediated transactivation of human secretin receptor gene.

In the present study, a functional neuron restrictive silencer element (NRSE) was initially identified in the 5' flanking region (-83 to -67, relative to ATG) of human secretin receptor (hSCTR) gene by promoter assays coupled with scanning mutation analyses. The interaction of neuron restrictive silencer factor (NRSF) with this motif was later indicated via gel mobility shift and ChIP assays. The silencing activity of NRSF was confirmed by over-expression and also by shRNA knock-down of endogenous NRSF. These studies showed an inverse relationship between the expression levels of NRSF and hSCTR in the cells. As hSCTR gene was previously shown to be controlled by two GC-boxes which are regulated by the ratio of Sp1 to Sp3, in the present study, the functional interactions of NRSF and Sp proteins to regulate hSCTR gene was investigated. By co-immunoprecipitation assays, we found that NRSF could be co-precipitated with Sp1 as well as Sp3 in PANC-1 cells. Interestingly, co-expressions of these factors showed that NRSF could suppress Sp1-mediated, but not Sp3-mediated, transactivation of hSCTR. Taken together, we propose here that the down-regulatory effects of NRSF on hSCTR gene expression are mediated via its suppression on Sp1-mediated transactivation.

The estrogen-related receptor alpha upregulates secretin expressions in response to hypertonicity and angiotensin II stimulation.

Osmoregulation via maintenance of water and salt homeostasis is a vital process. In the brain, a functional secretin (SCT) and secretin receptor (SCTR) axis has recently been shown to mediate central actions of angiotensin II (ANGII), including initiation of water intake and stimulation of vasopressin (VP) expression and release. In this report, we provide evidence that estrogen-related receptor α (ERRα, NR3B1), a transcription factor mainly involved in metabolism, acts as an upstream activator of the SCT gene. In vitro studies using mouse hypothalamic cell line N-42 show that ERRα upregulates SCT promoter and gene expression. More importantly, knockdown of endogenous ERRα abolishes SCT promoter activation in response to hypertonic and ANGII stimulations. In mouse brain, ERRα coexpresses with SCT in various osmoregulatory brain regions, including the lamina terminalis and the paraventricular nucleus of the hypothalamus, and its expression is induced by hyperosmotic and ANGII treatments. Based on our data, we propose that both the upregulation of ERRα and/or the increased binding of ERRα to the mouse SCT promoter are two possible mechanisms for the elevated SCT expression upon hyperosmolality and central ANGII stimulation.

Secretin and body fluid homeostasis.

Body fluid homeostasis is critical for the survival of living organisms and hence is tightly controlled. From initial studies on the effects of secretin (SCT) on renal water reabsorption in the 1940s and recent investigations of its role in cardiovascular and neuroendocrine functions, it has now become increasingly clear that this peptide is an integral component of the homeostatic processes that maintain body fluid balance. This review, containing some of our recent findings of centrally expressed SCT on water intake, focuses on the actions of SCT in influencing the physiological, neuroendocrine, and cardiovascular processes that subserve body fluid homeostasis.

An indispensable role of secretin in mediating the osmoregulatory functions of angiotensin II.

Fluid balance is critical to life and hence is tightly controlled in the body. Angiotensin II (ANGII), one of the most important components of this regulatory system, is recognized as a dipsogenic hormone that stimulates vasopressin (VP) expression and release. However, detailed mechanisms regarding how ANGII brings about these changes are not fully understood. In the present study, we show initially that the osmoregulatory functions of secretin (SCT) in the brain are similar to those of ANGII in mice and, more important, we discovered the role of SCT as the link between ANGII and its downstream effects. This was substantiated by the use of two knockout mice, SCTR(-/-) and SCT(-/-), in which we show the absence of an intact SCT/secretin receptor (SCTR) axis resulted in an abolishment or much reduced ANGII osmoregulatory functions. By immunohistochemical staining and in situ hybridization, the proteins and transcripts of SCT and its receptor are found in the paraventricular nucleus (PVN) and lamina terminalis. We propose that SCT produced in the circumventricular organs is transported and released in the PVN to stimulate vasopressin expression and release. In summary, our findings identify SCT and SCTR as novel elements of the ANGII osmoregulatory pathway in maintaining fluid balance in the body.

Regulation of RASSF1A in nasopharyngeal cells and its response to UV irradiation.

RASSF1A, which is frequently found inactivated in human cancers, is revealed as a tumor suppressor gene in nasopharyngeal carcinoma (NPC). Using RASSF1A-expressing (NP69 and HK-1) and non-RASSF1A-expressing (C666-1) cell models, the transcriptional regulation of RASSF1A was studied. By deletion analysis of 3.1 kb of 5' flanking region, the core promoter of RASSF1A was identified in the region between -431 and -1 upstream of the translation start site. Sequence analysis of this core promoter revealed several putative transcription factor binding sties. Using NP69 cells and by block replacement mutagenesis, the presence of three functional GC-boxes were identified, to which by competitive and supershift electrophoretic mobility shift assays (EMSA), the in vitro bindings of Sp1 and Sp3 were suggested. The in vivo functions of Sp-proteins in regulating RASSF1A gene were then investigated by overexpression studies; among the tested Sp-proteins, Sp1 or Sp3, but not Sp4, was able to augment promoter activities. More interestingly, co-expression of Sp1 and Sp3 could synergistically enhance RASSF1A promoter function. UV irradiation induces oxidation stresses and hence is routinely used to investigate expressions of oncogenes and tumor suppressors. In this report, upon UV irradiation, the RASSF1A promoter activity and endogenous transcript levels were found to be reduced. By chromatin immunoprecipitation (ChIP) and EMSA, we demonstrated that the binding of Sp1 and Sp3 onto -431 to -202 were significantly reduced after UV irradiation. This UV-mediated effect on RASSF1A promoter, as shown by specific inhibitors that interrupt cellular pathways, is MEK1-, but not JNK-dependent. In summary, our data provided a simple model to explain the potential development of NPC, via silencing of the tumor suppressor RASSF1A by reduced bindings of activators Sp1 and Sp3 onto the GC-boxes in the core promoter of the gene.

Gonadotropin-releasing hormone: regulation of the GnRH gene.

As the key regulator of reproduction, gonadotropin-releasing hormone (GnRH) is released by neurons in the hypothalamus, and transported via the hypothalamo-hypophyseal portal circulation to the anterior pituitary to trigger gonadotropin release for gonadal steroidogenesis and gametogenesis. To achieve appropriate reproductive function, mammals have precise regulatory mechanisms; one of these is the control of GnRH synthesis and release. In the past, the scarcity of GnRH neurons and their widespread distribution in the brain hindered the study of GnRH gene expression. Until recently, the development of GnRH-expressing cell lines with properties similar to those of in vivo GnRH neurons and also transgenic mice facilitated GnRH gene regulation research. This minireview provides a summary of the molecular mechanisms for the control of GnRH-I and GnRH-II gene expression. These include basal transcription regulation, which involves essential cis-acting elements in the GnRH-I and GnRH-II promoters and interacting transcription factors, and also feedback control by gonadotropins and gonadal sex steroids. Other physiological stimuli, e.g. insulin and melatonin, will also be discussed.

Identification of repressor element 1 in secretin/PACAP/VIP genes.

Repressor element 1 (RE-1) is a negative, cis-acting regulatory element that interacts with the transcription factor RE-1-silencing transcription factor (REST). REST represses gene expression by two repressor domains that recruit other factors including mSin3 and CoREST. RE-1 has been identified in an increasing number of neuronal-specific genes, and recently, functional REST sites have also been discovered in VIP and PACAP genes. In the present article, we demonstrated for the first time that RE-1 sites are present in the 5' flanking regions of several secretin/PACAP/VIP genes by in silico analysis. This observation suggests that RE-1/REST is a common negative regulatory pathway of this peptide family.