Early mouse embryos produce and release factors with transforming growth factor activity

Summary Previous studies have shown that extracts from mouse embryos at mid and late stages of development contain factors that exhibit transforming growth factor activity. The work reported here demonstrates that cultured mouse embryos at significantly earlier stages of development produce and release factors that exhibit the characteristic property of transforming growth factors. Specifically, the data demonstrate that embryos cultured from the blastocyst stage in serum-containing medium or in serum-free medium release factors that promote the anchorage-independent growth of normal rat kidney fibroblasts. It is shown that these factors are produced and released by cells derived from the inner cell mass and by trophoblasts. The precise developmental stage when production of these factors first begins has not been determined but our findings suggest that these factors are produced by cell types associated with early postimplatation embryos. This work was supported by the Laboratory of Viral Carcinogenesis at the National Cancer Institute and by grants from the National Cancer Institute (CA-36727) and the University of Nebraska Medical Center (22-271-732). Editor's Statement This paper presents evidence that, in an in vitro assay system, early embryonic cells are capable of both synthesizing and secreting TGF-like growth factors, implicating the production of these factors in the events of early development. David W. Barnes     

Density-induced down regulation of epidermal growth factor receptors

Summary Previous studies have shown that cell density can regulate the binding of several growth factors. To determine whether cell density exerts a uniform effect on the expression of epidermal growth factor (EGF) receptors, seven cell lines were examined in detail. For each cell line, EGF binding was found to decrease as cell density increases. Scatchard analysis of the binding data reveals that decreases in EGF binding are due to reductions in the number of cell surface EGF receptors. The only apparent exception is the effect of cell density on the binding of EGF to A-431 cells. For these cells, increases in cell density lead to two effects: decreases in the number of high affinity EGF receptors and increases in the total number of EGF receptors. In addition to the effects of cell density on EGF receptors, it was determined that increases in cell density can coordinately down-regulate receptors for as many as four different growth factors. Overall, the findings described in this report for EGF and those previously described for transforming growth factor type-β (TGF-β) and fibroblast growth factor (FGF) demonstrate the existence of a common mechanism for down-regulating growth factor receptors. This work was supported by grants from the Nebraska Department of Health (89-51), the National Cancer Institute (Laboratory Research Center Support Grant, CA36727), and the American Cancer Society (Core Grant ACS SIG-16). EDITOR'S STATEMENT The paper by Rizzino et al. demonstrates that receptor number decreases as a function of cell density. This may represent a mechanism by which cell proliferation is reduced as cell density increases.     

Synchronization of drosophila cells in culture

Summary We synchronized Drosophila cell lines (Schneider's line 2 and K_c) by allowing the cells to enter the stationary phase of growth and then diluting them into fresh culture medium. The cells of both cell lines entered S phase, after an 8- to 14-hr delay, in a state of partial synchrony; 60 to 80% of the cell population accumulated in S phase. Measurements of the cell cycle phases of Schneider's line 2 cells (S=14 to 16 hr; G₂=6 to 8 hr; M=0.4 hr) were similar to those of K_c cells. This work was performed under the auspices of the U.S. Energy Research and Development Administration. A.R. was supported by an NIH post-doctoral fellowship, No. CA01060.     

Synchronization of Drosophila cells in culture.

We synchronized Drosophila cell lines (Schneider's line 2 and Kc) by allowing the cells to enter the stationary phase of growth and then diluting them into fresh culture medium. The cells of both cell lines entered S phase, after an 8- to 14-hr delay, in a state of partial synchrony; 60 to 80% of the cell population accumulated in S phase. Measurements of the cell cycle phases of Schneider's line 2 cells (S = 14 to 16 hr; G2 = 6 to 8 hr; M = 0.4 hr) were similar to those of Kc cells.     

The effects of laminin on the growth and differentiation of embryonal carcinoma cells in defined media

In this paper we have examined the growth and differentiation of the embryonal carcinoma cell line, F₉, in the defined medium EM-3 at low density. We show that the growth of F₉ and their differentiated cells (F₉-diff) in EM-3 is strongly density dependent. At low cell densities the growth of both cell types is severely limited and most of the cells do not survive. Although this poses a problem for working with F₉ and F₉-diff in EM-3, it provides a convenient assay for identifying molecules that support their growth at low density. Using this assay, we have determined that laminin, a newly isolated glycoprotein of basement membranes, significantly improves the growth and short-term survival of both F₉ and F₉-diff. However, addition of laminin to EM-3 is insufficient to promote the clonal growth of these cell types. Our findings also indicate that laminin promotes the attachment of F₉ and F₉-diff in defined media. On the basis of our results, we propose an attachment function for laminin during the early stages of mammalian development.     

Development and differentiation of mouse blastocysts in serum-free medium

Numerous studies have shown that the in vitro development and differentiation of mouse blastocysts require serum, but the number and nature of serum factors involved remains unclear. In this article, we describe a culture medium, EM-2, containing as a source of protein only commercially purified bovine serum albumin (BSA) and fetuin. This medium supports hatching, attachment and outgrowth of mouse blastocysts. Although attachment and outgrowth are delayed in EM-2 medium 12–15 and 5–8 h, respectively, these events occur at frequencies comparable to those observed in serum-containing media. Trophoblast cells are capable of differentiating in this medium: they synthesize Δ⁵,3β-hydroxysteroid dehydrogenase and their nuclei become polyploid. The inner cell mass also appears to differentiate to some extent in EM-2 medium as evidenced by the appearance of cells with characteristics of parietal endoderm. The fetuin factor is necessary at least for trophoblast outgrowth and the albumin factor is required for the survival and/or growth of the inner cell mass. It is, however, not evident from these studies whether the serum fractions used are actually involved in the induction of differentiation, or whether the early differentiative steps in the mouse blastocyst are preprogrammed and require for expression only a normal cellular metabolic rate.