H1 histone subtypes and subtype synthesis switches of normal and delobed embryos of Ilyanassa obsoleta.

Histone H1 subtype complexity and H1 histone subtype synthesis switches were characterized during the development of normal embryos of the mud snail Ilyanassa obsoleta. The effect of the removal of the third polar lobe on the normal H1 pattern of synthesis was then investigated in the delobed embryo to determine if classical polar lobe effects are accompanied by a perturbation of these patterns. SDS-gel electrophoresis and fluorography of radiolabeled 5% perchloric acid-soluble nuclear extracts resolved six H1 proteins designated bands 1-6. Bands 1-5 migrate as a cluster of individual bands with similar mobilities. Band 6 has a substantially slower mobility. The synthesis of band 6 is predominant during the first 6 hr post-trefoil. During cleavage and gastrulation bands 1 and 2 are predominant while band 3, 4, and 5 become predominant during organogenesis. In addition, it has been found that removal of the polar lobe delays the off-switch of the early bands 6, 1, and 2 and the on-switch of the late bands 3, 4, and 5. This must result in a different H1 composition in the chromatin of the two embryo types. Cell number data of normal and delobed embryos reveal that the delay in subtype synthesis switching is not caused by an overall delay of cell division in the delobed embryo. However, the data indicate that a subpopulation of cells may not divide, or may divide late, in the delayed embryo. The data also suggest that the D cell lineage may be involved in the control of histone synthesis switching in the A, B, and C cell lineages.

Lack of correlation between loss of anchorage-independent growth and levels of transformation-specific p53 protein in retinoic acid-treated F9 embryonal carcinoma cells.

It has been shown that differentiated derivatives of retinoic acid (RA)-treated F9 embryonal carcinoma cells become non-malignant. In the present study it is asked whether this loss of malignancy is due to cellular differentiation. Because the ability of cells to grow in suspension correlates with in vivo tumorigenicity, we determined the time course of the loss of this property, after RA treatment, with relation to the differentiation to parietal endoderm and the acquisition of normalcy in several common transformation-specific properties of F9 cells. Our results show that pretreatment with RA for 24 h caused 80% inhibition of anchorage-independent growth in F9 cells, and this inhibition reached its highest level (98%) after pretreatment with RA for 48 h and longer. However, all other observed transformation-related properties, and the levels of plasminogen activator (marker for parietal endoderm) remained unaltered at this early post-treatment stage. These observations suggest that the loss of malignancy is a relatively early event in the biochemical pathways involved in the RA-induced differentiation of F9 cells. Furthermore, our data show that the presence of elevated levels of p53 alone may not be sufficient to maintain the anchorage-independent growth and the rapid proliferation of F9 cells.

Stage-specific switches in histone synthesis during embryogenesis of the sea urchin.

Histones H2A and H2B of the sea urchin embryo have been resolved by new methods into components that are synthesized at different stages of development. One form of H2A and one form of H2B are synthesized only during the period from fertilization to the blastula stage. Subsequently, two other types of H2A and H2B molecules are synthesized. In addition, a histonelike protein was detected which is synthesized only from fertilization until the 16-cell stage when the synthesis of still another H2A-like protein begins. None of the late-appearing forms are derived from histone polypeptide chains synthesized earlier in development. Since the early components do not disappear after their synthesis stops, these modulations of histone synthesis lead to an increase in histone multiplicity, concomitant with the beginning of cell diversification and a decrease in cell division rate.