Atbf1 Regulates Pubertal Mammary Gland Development Likely by Inhibiting the Pro-Proliferative Function of Estrogen-ER Signaling

ATBF1 is a candidate tumor suppressor that interacts with estrogen receptor (ER) to inhibit the function of estrogen-ER signaling in gene regulation and cell proliferation control in human breast cancer cells. We therefore tested whether Atbf1 and its interaction with ER modulate the development of pubertal mammary gland, where estrogen is the predominant steroid hormone. In an in vitro model of cell differentiation, i.e., MCF10A cells cultured in Matrigel, ATBF1 expression was significantly increased, and knockdown of ATBF1 inhibited acinus formation. During mouse mammary gland development, Atbf1 was expressed at varying levels at different stages, with higher levels during puberty, lower during pregnancy, and the highest during lactation. Knockout of Atbf1 at the onset of puberty enhanced ductal elongation and bifurcation and promoted cell proliferation in both ducts and terminal end buds of pubertal mammary glands. Enhanced cell proliferation primarily occurred in ER-positive cells and was accompanied by increased expression of ER target genes. Furthermore, inactivation of Atbf1 reduced the expression of basal cell markers (CK5, CK14 and CD44) but not luminal cell markers. These findings indicate that Atbf1 plays a role in the development of pubertal mammary gland likely by modulating the function of estrogen-ER signaling in luminal cells and by modulating gene expression in basal cells.     

Heterozygous deletion of Atbf1 by the Cre‐loxP system in mice causes preweaning mortality

ATBF1 is a large nuclear protein that contains multiple zinc‐finger motifs and four homeodomains. In mammals, ATBF1 regulates differentiation, and its mutation and/or downregulation is involved in tumorigenesis in several organs. To gain more insight into the physiological functions of ATBF1, we generated and validated a conditional allele of mouse Atbf1 in which exons 7 and 8 were flanked by loxP sites (Atbf1^flox). Germline deletion of a single Atbf1 allele was achieved by breeding to EIIa‐cre transgenic mice, and Atbf1 heterozygous mice displayed reduced body weight, preweaning mortality, increased cell proliferation, and attenuated cytokeratin 18 expression, indicating haploinsufficiency of Atbf1. Floxed Atbf1 mice will help us understand such biological processes as neuronal differentiation and tumorigenesis. genesis 1–9, 2012. © 2012 Wiley Periodicals, Inc.     

ATBF1异构体的选择性表达及其抑癌作用的分子机制

ATBF1(AT motif binding factor 1)基因是一个新发现的抑癌基因,其表达产物是目前发现的分子量最大的转录调节因子,它能和甲胎蛋白（alpha fetoprotein, AFP）基因增强子AT富聚区结合,调节AFP的转录.ATBF1基因表达过程中,由于转录本mRNA的选择性剪接,可产生ATBF1-A和ATBF1-B两种异构体,这两种异构体对AFP表达的调节具有相互对抗作用.ATBF1-A是ATBF1基因的主要表达形式,其能抑制癌细胞生长,而ATBF1-B则能促进癌细胞增殖.本文分析ATBF1异构体如何调控AFP表达及其作用的多样性,阐述ATBF1表达下调对肿瘤细胞生长和侵袭产生的影响;探讨ATBF1异构体抑癌作用的可能机制和选择性应用ATBF1异构体治疗肿瘤的科学意义.     

ATBF1研究综述

AT模体结合因子1(ATBF1)是一个新发现的抑癌基因,从人肝癌细胞HuH-7中分离得到。ATBF1可与甲胎蛋白基因增强子中AT富含原件结合,其表达产物是目前发现的分子量最大的转录调节因子。ATBF1基因表达过程中,通过选择性剪接产生ATBF1-A和ATBF1-B两种mRNA,这两种mRNA对AFP表达的调节具有相互对抗作用。ATBF1-A是ATBF1基因的主要表达形式,能抑制癌细胞生长;而ATBF1-B则能促进癌细胞增殖。ATBF1作为抑癌基因,为肿瘤的治疗带来新希望,但目前学术界对ATBF1的研究仍然有限。本文重点对ATBF1在神经系统、乳腺癌、胃癌、肝癌、结直肠癌以及其他肿瘤中的研究作综述,以期进一步明确ATBF1的抑癌机制。     

Additive Effect of Zfhx3/Atbf1 and Pten Deletion on Mouse Prostatic Tumorigenesis

The phosphatase and tensin homolog(PTEN) and the zinc finger homeobox 3(ZFHX3)/AT-motif binding factor 1(ATBF1) genes have been established as tumor suppressor genes in prostate cancer by their frequent deletions and mutations in human prostate cancer and by the formation of mouse prostatic intraepithelial neoplasia(mPIN) or tumor by their deletions in mouse prostates.However,whether ZFHX3/ATBF1 deletion together with PTEN deletion facilitates prostatic tumorigenesis is unknown.In this study,we simultaneously deleted both genes in mouse prostatic epithelia and performed histological and molecular analyses.While deletion of one Pten allele alone caused low-grade(LG) mPIN as previously reported,concurrent deletion of 2fla3/Atbf1 promoted the progression to high-grade(HG)mPIN or early carcinoma.Zfhx3/Atbf1 and Pten deletions together increased cell proliferation,disrupted the smooth muscle layer between epithelium and stroma,and increased the number of apoptotic cells.Deletion of both genes also accelerated the activation of Akt and Erk1/2 oncoproteins.These results suggest an additive effect of ZFHX3/ATBF1 and PTEN deletions on the development and progression of prostate neoplasia.     

Homeotic factor ATBF1 induces the cell cycle arrest associated with neuronal differentiation

The present study aimed to elucidate the function of AT motif-binding factor 1 (ATBF1) during neurogenesis in the developing brain and in primary cultures of neuroepithelial cells and cell lines (Neuro 2A and P19 cells). Here, we show that ATBF1 is expressed in the differentiating field in association with the neuronal differentiation markers beta-tubulin and MAP2 in the day E14.5 embryo rat brain, suggesting that it promotes neuronal differentiation. In support of this, we show that ATBF1 suppresses nestin expression, a neural stem cell marker, and activates the promoter of Neurod1 gene, a marker for neuronal differentiation. Furthermore, we show that in Neuro 2A cells, overexpressed ATBF1 localizes predominantly in the nucleus and causes cell cycle arrest. In P19 cells, which formed embryonic bodies in the floating condition, ATBF1 is mainly cytoplasmic and has no effect on the cell cycle. However, the cell cycle was arrested when ATBF1 became nuclear after transfer of P19 cells onto adhesive surfaces or in isolated single cells. The nuclear localization of ATBF1 was suppressed by treatment with caffeine, an inhibitor of PI(3)K-related kinase activity of ataxa-telangiectasia mutated (ATM) gene product. The cytoplasmic localization of ATBF1 in floating/nonadherent cells is due to CRM1-dependent nuclear export of ATBF1. Moreover, in the embryonic brain ATBF1 was expressed in the cytoplasm of proliferating stem cells on the ventricular zone, where cells are present at high density and interact through cell-to-cell contact. Conversely, in the differentiating field, where cell density is low and extracellular matrix is dense, the cell-to-matrix interaction triggered nuclear localization of ATBF1, resulting in the cell cycle arrest. We propose that ATBF1 plays an important role in the nucleus by organizing the neuronal differentiation associated with the cell cycle arrest.     

Purification and identification of a protein kinase activity modulated by ionizing radiation

ATBF1 was first discovered as a suppressor of AFP expression in hepatocytes. It is present in brain, adult liver, lung, and gastro-intestinal tract. Recently, it has been reported that ATBF1 regulates myoblastic differentiation and interacts with v-Myb in regulation of its transactivation. Using the yeast two-hybrid system, we searched for protein-protein interactions to uncover new functions for ATBF1. We present here experimental evidence that ATBF1 is a new regulatory factor for STAT3-mediated signal transduction through its interaction with PIAS3. PIAS3 was thus identified as an ATBF1-binding protein. In co-transfection experiments, the full-length ATBF1 was found to form complexes with PIAS3 in Hep G2 cells. In the luciferase assay, ATBF1 was found to have no influence on STAT3 signaling induced by IL-6 stimulation, but it did synergistically enhance PIAS3 inhibition of activated STAT3. In conclusion, ATBF1 can suppress the IL-6-mediated cellular response by acting together with PIAS3.