Epithelial-mesenchymal transition (EMT) and mesenchymal-epithelial transition (MET) highlight crucial steps during embryogenesis and tumorigenesis. Induction of dramatic changes in gene expression and cell features is reflected by modulation of Cdh1 (E-cadherin) expression. We show that Cdh1 activity during MET is governed by two enhancers at +7.8 kb and at +11.5 kb within intron 2 that are activated by binding of Grhl3 and Hnf4α, respectively. Recruitment of Grhl3 and Hnf4α to the enhancers is crucial for activating Cdh1 and accomplishing MET in non-tumorigenic mouse mammary gland cells (NMuMG). Moreover, the two enhancers cooperate via Grhl3 and Hnf4α binding, induction of DNA-looping and clustering at the promoter to orchestrate E-cadherin re-expression. Our results provide novel insights into the cellular mechanisms whereby cells respond to MET signals and re-establish an epithelial phenotype by enhancer cooperativity. A general importance of our findings including MET-mediated colonization of metastasizing tumor cells is suggested.
Embryonic stem (ES) cell pluripotency and induced pluripotent stem (iPS) cell generation is dependent on a core transcriptional network and proper cell-cell adhesion mediated by E-cadherin (E-cad). Whereas E-cad is associated with pluripotency, N-cadherin (N-cad) expression is correlated with differentiation into mesodermal and neuroectodermal lineages. We investigated whether E-cad harbors unique molecular features in establishing or maintaining pluripotency. By using a gene replacement knock-in (ki) approach to express N-cadherin (N-cad) or E-cad/N-cad chimeric cadherins under the control of the E-cad locus, we show that all E-cad-depleted ki/ki ES cells are maintained in an undifferentiated state. Surprisingly, these cells retained key features of pluripotency, such as Nanog expression and full differentiation capacity in vitro and in vivo, whereas E-cad knockout (ko) ES cells irreversibly lost most of these features. Moreover, our results indicate that E-cad mediated adhesion is essential for iPS cell generation, since E-cad depleted fibroblasts were not reprogrammed. In contrast, N-cad efficiently supports somatic reprogramming similar to E-cad, and permits initiation of the crucial initial step of mesenchymal-epithelial transition. Thus, we show that cell adhesion and a robust pluripotent phenotype are ultimately connected. Since N-cad properly compensates for loss of E-cad, no specific 'cadherin code' is required.
The function of sodium iodide symporter (Na + /I À symporter, or NIS) in mammary epithelial cells is essential for the accumulation of I À in milk; the newborn's first source of I À for thyroid hormone synthesis. Furthermore, increased mammary gland NIS expression has previously been shown in human breast cancer. Several hormones and factors including all-trans-retinoic acid (tRA) regulate the expression of NIS. In this study, using breast cancer cell lines, we established that tRA-responsive NIS expression is confined to estrogen receptor-a (ERa) positive cells and we investigated the role of ERa in the regulation of NIS expression. We showed that the suppression of endogenous ERa by RNA interference downregulates NIS expression in ERa positive mammary cells. Besides, in an ERa negative cell line, reintroduction of ERa resulted in the expression of NIS in a ligand-independent manner. We also identified a novel estrogen-responsive element in the promoter region of NIS that specifically binds ERa and mediates ERa-dependent activation of transcription. Our results indicate that unliganded ERa (apo-ERa) contributes to the regulation of NIS gene expression. In mammary gland lactocytes, sodium/iodide (Na + /I À ) symport via NIS is required to secrete I À in mother's milk [1]. I À in milk is used by the newborn in thyroid hormone biosynthesis, and thus it plays an essential role in post-natal development of skeletal muscles, nervous system, and lungs [2]. In vivo experiments in mice have previously demonstrated that in normal physiology, NIS expression is strictly linked to mammary development in gestation, and to lactation [1]. Non-lactating mammary gland tissue in female mice does not express NIS unless animals receive subcutaneous oxytocin treatments for three consecutive days. On the other hand, a similar treatment in ovariectomized mice is not sufficient for NIS upregulation. In these surgically treated animals, administration of 17-b-estradiol (E2) together with oxytocin is essential for functional expression of NIS. The fact that E2 treatment was only essential in ovariectomized animals, whereas lactogenic hormones were sufficient for functional NIS expression in surgically untreated mice, suggested that ovary functions and endogenous estrogens are essential in upregulating NIS expression [1]. Unlike in non-lactating mammary gland tissue, in transgenic mice bearing experimental breast cancers triggered by Erb-B2/neu and ras oncogenes, functional expression of NIS significantly increases [1]. In the same study, human breast cancer specimens were also analyzed, and an increased NIS expression was detected in human invasive breast cancer and ductal carcinoma in situ, as compared to no expression of NIS in healthy breast samples obtained from reductive mammoplasty operations [1].Recent studies with an ERa+ mammary cell line model, MCF-7, have led to the identification of additional hormones or ligands that control transcriptional regulation of NIS. In this cell line, the symporter gene was shown to be indu...
The epithelial to mesenchymal transition (EMT) and the mesenchymal to epithelial transition (MET) are two critical biological processes that are involved in both physiological events such as embryogenesis and development and also pathological events such as tumorigenesis. They present with dramatic changes in cellular morphology and gene expression exhibiting acute changes in E-cadherin expression. Despite the comprehensive understanding of EMT, the regulation of MET is far from being understood. To find novel regulators of MET, we hypothesized that such factors would correlate with Cdh1 expression. Bioinformatics examination of several expression profiles suggested Elf3 as a strong candidate. Depletion of Elf3 at the onset of MET severely impaired the progression to the epithelial state. This MET defect was explained, in part, by the absence of E-cadherin at the plasma membrane. Moreover, during MET, ELF3 interacts with the Grhl3 promoter and activates its expression. Our findings present novel insights into the regulation of MET and reveal ELF3 as an indispensable guardian of the epithelial state. A better understanding of MET will, eventually, lead to better management of metastatic cancers.
Cytokinetic abscission is the cellular process leading to physical separation of two postmitotic sister cells by severing the intercellular bridge. The most noticeable structural component of the intercellular bridge is a transient organelle termed as midbody, localized at a central region marking the site of abscission. Despite its major role in completion of cytokinesis, our understanding of spatiotemporal regulation of midbody assembly is limited. Here, we report the first characterization of coiled-coil domain-containing protein-124 (Ccdc124), a eukaryotic protein conserved from fungi-to-man, which we identified as a novel centrosomal and midbody protein. Knockdown of Ccdc124 in human HeLa cells leads to accumulation of enlarged and multinucleated cells; however, centrosome maturation was not affected. We found that Ccdc124 interacts with the Ras-guanine nucleotide exchange factor 1B (RasGEF1B), establishing a functional link between cytokinesis and activation of localized Rap2 signaling at the midbody. Our data indicate that Ccdc124 is a novel factor operating both for proper progression of late cytokinetic stages in eukaryotes, and for establishment of Rap2 signaling dependent cellular functions proximal to the abscission site.
BackgroundBreast cancer is a remarkably heterogeneous disease. Luminal, basal-like, “normal-like”, and ERBB2+ subgroups were identified and were shown to have different prognoses. The mechanisms underlying this heterogeneity are poorly understood. In our study, we explored the role of cellular differentiation and senescence as a potential cause of heterogeneity.Methodology/Principal FindingsA panel of breast cancer cell lines, isogenic clones, and breast tumors were used. Based on their ability to generate senescent progeny under low-density clonogenic conditions, we classified breast cancer cell lines as senescent cell progenitor (SCP) and immortal cell progenitor (ICP) subtypes. All SCP cell lines expressed estrogen receptor (ER). Loss of ER expression combined with the accumulation of p21Cip1 correlated with senescence in these cell lines. p21Cip1 knockdown, estrogen-mediated ER activation or ectopic ER overexpression protected cells against senescence. In contrast, tamoxifen triggered a robust senescence response. As ER expression has been linked to luminal differentiation, we compared the differentiation status of SCP and ICP cell lines using stem/progenitor, luminal, and myoepithelial markers. The SCP cells produced CD24+ or ER+ luminal-like and ASMA+ myoepithelial-like progeny, in addition to CD44+ stem/progenitor-like cells. In contrast, ICP cell lines acted as differentiation-defective stem/progenitor cells. Some ICP cell lines generated only CD44+/CD24-/ER-/ASMA- progenitor/stem-like cells, and others also produced CD24+/ER- luminal-like, but not ASMA+ myoepithelial-like cells. Furthermore, gene expression profiles clustered SCP cell lines with luminal A and “normal-like” tumors, and ICP cell lines with luminal B and basal-like tumors. The ICP cells displayed higher tumorigenicity in immunodeficient mice.Conclusions/SignificanceLuminal A and “normal-like” breast cancer cell lines were able to generate luminal-like and myoepithelial-like progeny undergoing senescence arrest. In contrast, luminal B/basal-like cell lines acted as stem/progenitor cells with defective differentiation capacities. Our findings suggest that the malignancy of breast tumors is directly correlated with stem/progenitor phenotypes and poor differentiation potential.
Activity of the sodium/iodide symporter (NIS) in lactating breast is essential for iodide (I–) accumulation in milk. Significant NIS upregulation was also reported in breast cancer, indicating a potential use of radioiodide treatment. All-trans-retinoic acid (tRA) is a potent ligand that enhances NIS expression in a subset of breast cancer cell lines and in experimental breast cancer models. Indirect tRA stimulation of NIS in breast cancer cells is very well documented; however, direct upregulation by tRA-activated nuclear receptors has not been identified yet. Aiming to uncover cis-acting elements directly regulating NIS expression, we screened evolutionary-conserved non-coding genomic sequences for responsiveness to tRA in MCF-7. Here, we report that a potent enhancer in the first intron of NIS mediates direct regulation by tRA-stimulated nuclear receptors. In vitro as well as in vivo DNA–protein interaction assays revealed direct association between retinoic acid receptor-α (RARα) and retinoid-X-receptor (RXR) with this enhancer. Moreover, using chromatin immunoprecipitation (ChIP) we uncovered early events of NIS transcription in response to tRA, which require the interaction of several novel intronic tRA responsive elements. These findings indicate a complex interplay between nuclear receptors, RNA Pol-II and multiple intronic RAREs in NIS gene, and they establish a novel mechanistic model for tRA-induced gene transcription.
Heterozygous germ-line variants of DNA mismatch repair (MMR) genes predispose individuals to hereditary non-polyposis colorectal cancer. Several independent reports have shown that individuals constitutionally homozygous for MMR allelic variants develop early onset hematological malignancies often associated to features of neurofibromatosis type 1 (NF1) syndrome. The genetic mechanism of NF1 associated to MMR gene deficiency is not fully known. We report here that a child with this form of NF1 displays a heterozygous NF1 gene mutation (c.3721C>T), in addition to a homozygous MLH1 gene mutation (c.676C>T) leading to a truncated MLH1 protein (p.R226X). The parents did not display NF1 features nor the NF1 mutation. This new NF1 gene mutation is recurrent and predicts a truncated neurofibromin (p.R1241X) lacking its GTPase activating function, as well as all C-terminally located functional domains. Our findings suggest that NF1 disease observed in individuals homozygous for deleterious MMR variants may be due to a concomitant NF1 gene mutation. The presence of both homozygous MLH1 and heterozygous NF1 mutation in the child studied here also provides a mechanistic explanation for early onset malignancies that are observed in affected individuals. It also provides a model for cooperation between genetic alterations in human carcinogenesis.
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