The dynamic embryonic expression of germ cell nuclear factor (GCNF), an orphan nuclear receptor, suggests that it may play an important role during early development. To determine the physiological role of GCNF, we have generated a targeted mutation of the GCNF gene in mice. Germ line mutation of the GCNF gene proves that the orphan nuclear receptor is essential for embryonic survival and normal development. GCNF ؊/؊ embryos cannot survive beyond 10.5 days postcoitum (dpc), probably due to cardiovascular failure. Prior to death, GCNF ؊/؊ embryos suffer significant defects in posterior development. Unlike GCNF ؉/؉ embryos, GCNF ؊/؊ embryos do not turn and remain in a lordotic position, the majority of the neural tube remains open, and the hindgut fails to close. GCNF ؊/؊ embryos also suffer serious defects in trunk development, specifically in somitogenesis, which terminates by 8.75 dpc. The maximum number of somites in GCNF ؊/؊ embryos is 13 instead of 25 as in the GCNF ؉/؉ embryos. Interestingly, the tailbud of GCNF ؊/؊ embryos develops ectopically outside the yolk sac. Indeed, alterations in expression of multiple marker genes were identified in the posterior of GCNF ؊/؊ embryos, including the primitive streak, the node, and the presomitic mesoderm. These results suggest that GCNF is required for maintenance of somitogenesis and posterior development and is essential for embryonic survival. These results suggest that GCNF regulates a novel and critical developmental pathway involved in normal anteroposterior development.
At least one member of the TGF-beta family, TGF-beta 1, has been previously shown to inhibit the anchorage-independent growth of some human breast cancer cell lines (Knabbe et al., 1987; Arteaga et al., 1988). Members of the TGF-beta family might, therefore, provide new strategies for breast cancer therapy. We have studied the inhibitory effects of TGF-beta 1 and TGF-beta 2 on the anchorage-independent growth of the oestrogen receptor-negative cell lines MDA-MB-231, SK-BR-3, Hs578T, MDA-MB-468, and MDA-MB-468-S4 (an MDA-MB-468 clone not growth inhibited by EGF) and the estrogen receptor-positive cell lines MCF7, ZR-75-1, T-47D. TGF-beta 1 and TGF-beta 2 caused a 75-90% growth inhibition of MDA-MB-231, SK-BR-3, Hs578T, and MDA-MB-468 cells and a 50% growth inhibition of ZR-75-1 and early passage (less than 100) MCF7 cells. T-47D cells responded to TGF-beta only in serum-free conditions in the presence of IGF-1 or EGF. The growth of MDA-MB-468-S4 cells and late passage (greater than 500) MCF7 cells was not inhibited by TGF-beta 1 or TGF-beta 2. TGF-beta-sensitive MCF7 and MDA-MB-231 cells did not respond to Muellerian inhibiting substance (MIS), a TGF-beta-related polypeptide. TGF-beta 1 or TGF-beta 2 were mutually competitive for receptor binding with a similar affinity (Kd 25-130 pM, 1,000-13,000 sites per cell). To determine the time course of the TGF-beta effect, an anchorage-dependent growth assay was carried out using MDA-MB-231 cells. Growth inhibition occurred at 6 days, and cell-cycle changes were seen 12 hr after the addition of TGF-beta. Cells accumulated in the G1 phase and were thus inhibited from entering the S-phase. These data indicate that TGF-beta is a potent growth inhibitor in most breast cancer cell lines and provide a basis for studying TGF-beta effects in vivo.
The thyroid hormone (T3) receptor (TR) variant TR alpha 2 is abundant in brain but does not bind T3 because of its unique C terminus. The only known function of TR alpha 2, inhibition of TR-dependent transactivation, involves competition for T3 response elements. Paradoxically, in vitro-translated TR alpha 2 bound poorly to these sites. We report here that dephosphorylation of TR alpha 2 restored its DNA binding. Mutation of C-terminal serine residues to alanine (TR alpha 2-SA) was equally effective. The C terminus of TR alpha 2 was phosphorylated in a human cell line, whereas that of TR alpha 2-SA was not. Conversely, TR alpha 2-SA was a much better inhibitor of T3 action than was wild-type TR alpha 2. The dominant negative activity of TR alpha 2-SA was less than stoichiometric with TR concentration, possibly because it was unable to heterodimerize with retinoid X receptor, which enhances the binding of other TRs. Purified casein kinase II as well as a reticulocyte casein kinase II-like activity phosphorylated TR alpha 2 on serines 474 and 475. Mutation of these two residues to alanine was sufficient to restore DNA binding. Thus, DNA binding by TR alpha 2 is regulated by phosphorylation at a site distant from the DNA-binding domain. The increased dominant negative activity of a nonphosphorylatable form of TR alpha 2 suggests that phosphorylation may provide a rapid, T3-independent mechanism for cell-specific modulation of the expression of T3-responsive genes.
Among the processes contributing to the progressive acquisition of the highly malignant phenotype in breast cancer are ovarian-independent growth, antioestrogen resistance and increased metastatic potential. We have previously observed that increased invasiveness and development of ovarian-independent growth occur independently. In an attempt to define the inter-relationships between these processes further, we have compared the phenotypes of ovarian-independent, invasive and antioestrogen-resistant sublines of the ovarian-dependent human breast cancer cell line MCF-7. Cells acquiring ovarian-independent growth can retain sensitivity to anti-oestrogens. One clone of MCF-7 cells selected for stable antioestrogen resistance has become non-tumorigenic but its invasive potential remains unaltered. Thus, acquisition of some characteristics of the progressed phenotype can occur independently. This phenomenon of independent parameters in phenotypic progression could partly explain the considerable intra- and intertumour heterogeneity characteristic of breast tumours.
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