Regulation of translation of ovalbumin messenger RNA by estrogens and progesterone in oviduct of withdrawn chicks.

In the oviduct of chicks withdrawn from previous treatment with estrogens, no ovalbumin synthesis can be detected, although there are a limited number of ovalbumin mRNA sequences. These sequences are predominately associated with membrane-bound ribosomes. However, the size of the polysomes is small compared to those from the laying hen, suggesting that the inability to detect ovalbumin synthesis is the result of inefficient initiation of ovalbumin synthesis. When the rate of peptide chain elongation is reduced by treatment of chicks with cycloheximide, there is an increase in the average size of polysomes and a shift of ovalbumin mRNA sequences from small to large-sized polysomes. Readministration of estrogen to withdrawn chicks results in a time-dependent shift of monosomes to polysomes and a proportional shift of ovalbumin mRNA sequences between the two fractions, indicating that estrogen stimulates the rate of initiation of all mRNA species in the oviduct to essentially the same extent. In contrast, progesterone administration results in a preferential shift of ovalbumin mRNA relative to total RNA, suggesting a preferential effect of progesterone on initiation of protein synthesis with ovalbumin mRNA.

Steroid-induced early protein synthesis in rat uterus and prostate.

An early 'induced protein', after exposure of the rat uterus to estradiol, is detected among the soluble proteins with a double-labelling technique and electrophoretic fractionation. Efforts have been directed to establish the subcellular distribution of the induced protein, since such a protein, observable 1 h after hormone administration, may play an important role in the subsequent amplified responses, especially in terms of RNA synthesis. Moreover such an early discrete induced protein was sought in a comparable system responding to another hormone, namely prostate and seminal vesicles under androgens. The induced protein was not found in uterine nuclei of 21-day-old rats after 1 h of estradiol action in vivo and 1 h of tissue incubation with labelled leucine. This negative result summarizes a search among different nuclear protein fractions using various procedures; nor was induced protein observed in mitochondrial and microsomal pellets. Contrary to these negative findings, slight changes of histone labelling were observed under the experimental conditions used to demonstrate induced protein. In addition histone acetylation was increased after 1 h of estradiol action in vivo and 15 min tissue labelling in vitro with radioactive acetate. Furthermore, an increase in total protein synthesis between 0 and 2 h after estradiol action was observed, the relative increase of incorporation of radioactive leucine into protein of estradiol-treated vs non-stimulated uteri being corrected for variations of the acid-soluble radioactive leucine pool. Attempts to obtain an early and discrete induced protein with androgens in prostate and seminal vesicles of immature or castrated rats after different times of exposure to testosterone, androstanolone and estradiol have been unsuccessful. The contribution of both negative and positive findings in steroid-induced early protein synthesis is discussed in the context of the current knowledge of hormone action.

Induction of ovalbumin mRNA sequences by estrogen and progesterone in chick oviduct as measured by hybridization to complementary DNA.

A complementary DNA synthesized from ovalbumin mRNA was used in hybridization experiments to study the early effect of estrogen and progesterone on the accumulation of ovalbumin mRNA sequences in the chick oviduct. Chicks treated with estrogen withdrawn from the hormone maintain a steady level of 60 molecules of ovalbumin mRNA per tubular gland cell, at least 80% of which are localized in the cytoplasm. After estrogen administration, there is a 3- to 4-hour lag before a rapid increase in the number of ovalbumin mRNA sequences and a parallel increase in ovalbumin synthesis. Progesterone causes a more rapid increase in both ovalbumin mRNA sequences and ovalbumin synthesis with a lag period of only 90 min. The hybridization results demonstrate that both estrogen and pregesterone affect the amount of ovalbumin mRNA per cell. The 3-hour lag period seen with estrogen appears to be caused by some event after the binding of the estrogen receptor to chromatin but prior to change in the rate of transcription of the ovalbumin gene.