Studies of frog oviducal jelly secretion. II. Cytology of secretory cycle

Hormonal regulation of RNA synthesis and specific gene expression in Xenopus oviduct cells in primary culture

The studies described in this report were carried out as a first step towards the elucidation of mechanisms underlying the tissue specificity of regulation of gene expression by estrogen. Using a procedure established earlier in our laboratory for primary culture of Xenopus hepatocytes, we have characterized how estradiol-17 beta and progesterone affect the rate of synthesis of total RNA and that of accumulation of two oviduct-specific mRNAs in Xenopus oviduct cells in primary culture. In cells that had recovered from 'culture shock' 3 days after they were plated out, both hormones had only a slight or no effect on the overall rate of labelling of newly synthesized RNA over 24 h. Cloned cDNA probes for two mRNAs, termed 7F and 6G and specifying as yet unknown proteins expressed in the oviduct and not in the liver, were used to quantify the two mRNAs. The levels of both mRNAs declined for the first 2 days in culture after which they were stabilized. When added to the oviduct cell cultures 3 days after they were plated out, estradiol increased the steady-state concentration (relative to total RNA) of 7F and 6G mRNAs by 3- to 7-fold after 60-80 h, but with different time-course and dose-response kinetics for the two messages. The antiestrogen tamoxifen also exerted different degrees of antagonist effect on the estrogen-induced accumulation of 7F and 6G mRNAs. Although the protein products of these two oviduct-specific mRNAs have not yet been characterized, these studies set the stage for comparing the regulation by estrogen of their genes with that of vitellogenin genes in primary cultures of Xenopus oviduct cells and hepatocytes.

Arylsulphatase activity in the oviduct of the frog Rana esculenta. I. Oestradiol-induced changes following ovariectomy and hypophysectomy

The effects of oestradiol treatment on arylsulphatase activity in the frog oviduct are reported. Oestradiol-induced changes were also investigated in ovariectomized and hypophysectomized animals. Under all the experimental conditions, hormonal treatment causes an increase in enzyme activity. This can be observed biochemically and also histochemically on frozen sections. Hypotheses are advanced to explain fluctuations in arylsulphatase activity.

Egg envelopes in vertebrates

As the material presented in this chapter was being collated, our existing perceptions about the basic similarities of vertebrate (and indeed most, if not all, invertebrate) egg envelopes became increasingly strengthened. Perhaps without exception, all vertebrate and invertebrate eggs acquire a "vitelline" envelope. Interestingly, its filamentous ultrastructure and chemical composition--basically protein and carbohydrate--is similar in all species as is its permeability to large molecules. Furthermore, many (if not all) of its functions are shared among the animal phyla as is its potential to become altered at the time of fertilization and, in its altered state, to provide a new set of modi operandi. It provides sperm receptors that are generally species specific and helps prevent polyspermy; it protects the developing embryo yet yields at the time of hatching. In most vertebrate eggs (including some mammals), a jelly or albumen coat is added to the vitelline envelope. These components may vary immensely in thickness, but again their basic chemical composition is common to all. The functions of these envelopes, while perhaps somewhat less clear than those of the vitelline envelope, are related to species-specific fertilization and to embryonic protection. Albumen serves a nutritional role--most clearly shown in the birds. Finally, the shell membrane and shell present in diverse groups contribute additional adaptations for embryo protection. Vertebrate egg envelopes, then, are basically similar; the modifications, including the addition of shell membranes and shells in some groups, reflect adaptations to differing reproductive strategies and to the environmental exigencies with which the egg must cope. With the growth of our understanding about the structure, chemistry, function, and evolution of egg envelopes new questions will continually be formulated. Many will be the same as those asked years ago but they will be answered with newer techniques and with greater insight.