Clay J L, Ammann R R, Gomer R H
Howard Hughes Medical Institute, Rice University, Houston, Texas 77251-1892, USA.
Dev Biol. 1995 Dec;172(2):665-74. doi: 10.1006/dbio.1995.8045.
Dictyostelium discoideum is a simple eukaryote that lives as an amoeba until starvation triggers aggregation. The aggregate forms a slug which then develops into a fruiting body with two main cell types, stalk and spore cells. Two mechanisms have been proposed to explain cell-type differentiation. Studies using expression of the ecmA gene as a prestalk cell marker indicated that gradients of morphogens determine cell fate in the slug. However, studies using dyes or the cysteine proteinase 2 (CP2) gene product as a prestalk cell marker indicated that cell autonomous factors such as cell-cycle phase at the time of starvation cause an initial choice of cell fate. To help resolve these differences, we have used transformed cells containing the promoter of the prestalk gene ecmA fused to beta-galactosidase (Jermyn and Williams, 1991) to study the differentiation of Dictyostelium cells at low cell density, at which cell-to-cell interactions and morphogen gradients are minimal. We find that under all conditions of low cell density in which express ion the ecmA fusion gene occurs, it is invariably detected in less than 25% of the cells from a clonal population. This suggests that a cell-autonomous mechanism is involved in ecmA expression. We then used double-labeled immunofluorescence to examine the ontogeny of the CP2-positive and the ecmA-positive cells. In developing aggregates, 9 to 12% of the cells are CP2-positive from 12 to 24 hr of development. The ecmA-positive cells are first detected at 16 hr as a subset of the CP2-positive cells and then increase in number. At approximately 20 hr, the CP2-positive cells and the ecmA-positive cells are almost completely overlapping sets. By late development, all of the CP2-positive cells are ecmA-positive and an additional 10% of the CP2-negative cells are also ecmA-positive. This indicates that up to 20 hr development, ecmA is expressed only in CP2-positive cells. The data thus suggest that cell-cycle phase at the time of starvation causes an initial choice of cell type and that during later development other factors influence cell fate.
盘基网柄菌是一种简单的真核生物,在饥饿引发聚集之前,它以变形虫的形式生存。聚集物形成一个蛞蝓体,然后发育成一个具有两种主要细胞类型(柄细胞和孢子细胞)的子实体。已经提出了两种机制来解释细胞类型的分化。使用ecmA基因的表达作为前柄细胞标记的研究表明,形态发生素梯度决定了蛞蝓体中的细胞命运。然而,使用染料或半胱氨酸蛋白酶2(CP2)基因产物作为前柄细胞标记的研究表明,诸如饥饿时的细胞周期阶段等细胞自主因素导致了细胞命运的初始选择。为了帮助解决这些差异,我们使用了含有与β-半乳糖苷酶融合的前柄基因ecmA启动子的转化细胞(Jermyn和Williams,1991)来研究低细胞密度下盘基网柄菌细胞的分化,在这种情况下细胞间相互作用和形态发生素梯度最小。我们发现,在所有低细胞密度条件下,只要ecmA融合基因发生表达,在克隆群体中总是在不到25%的细胞中检测到它。这表明细胞自主机制参与了ecmA的表达。然后我们使用双标记免疫荧光来检查CP2阳性细胞和ecmA阳性细胞的个体发育。在发育中的聚集体中,从发育的12至24小时,9%至12%的细胞是CP2阳性。ecmA阳性细胞在16小时时首次被检测到,是CP2阳性细胞的一个子集,然后数量增加。在大约20小时时,CP2阳性细胞和ecmA阳性细胞几乎完全重叠。到发育后期,所有CP2阳性细胞都是ecmA阳性,另外10%的CP2阴性细胞也是ecmA阳性。这表明在发育到20小时之前,ecmA仅在CP2阳性细胞中表达。因此,数据表明饥饿时的细胞周期阶段导致了细胞类型的初始选择,并且在后期发育过程中其他因素影响细胞命运。
