Meiotic maturation in Xenopus oocytes: a link between the cessation of protein secretion and the polarized disappearance of Golgi apparati

We have studied the relationship between the timing of the late meiotic events that occur during progesterone-induced oocyte maturation, and intracellular protein transport. We have monitored the secretion of chick oviduct proteins from Xenopus laevis oocytes microinjected with polyadenylated mRNA and found that chick ovalbumin and lysozyme are not secreted during the second meiotic metaphase, in contrast to the earlier prophase stage. Maturation had no detectable effect on the glycosylation of ovalbumin, whereas it affected the glycosylation of chick ovomucoid. As maturation proceeded, the Golgi apparati disappeared in a polarized fashion, beginning in the vegetal half. This disappearance coincided temporally and spatially with that of the nuclear envelope. We speculate that Golgi apparatus disappearance and the block in secretion are causally related.     

Purification and translation of ovalbumin,conalbumin, ovomucoid and lysozyme messenger RNA

Messenger RNAs for 4 egg white proteins (ovalbumin, conalbumin, ovomucoid and lysozyme) were assayed in a cell-free, protein-synthesizing system derived from rabbit reticulocytes. Each of these messengers was purified about 33-fold from hen oviduct polysomal RNA using oligo(dT) cellulose. The apparent minimal translational efficiencies varied from 22 translations for each ovalbumin mRNA to less than 1 for lysozyme mRNA. These messengers are not polycistronic with each other since they have distinct sedimentation values of: lysozyme, 8.5S; ovomucoid, 11S; ovalbumin, 15S; and conalbumin 18S. Several aspects of this system indicate that it will be valuable for dissecting the fine control of mRNA metabolism.     

The influence of topology and glycosylation on the fate of heterologous secretory proteins made in Xenopus oocytes

Secretory proteins made in Xenopus laevis oocytes under the direction of heterologous messenger RNA are modified, topologically segregated and exported. Thus the oocyte may serve as a useful surrogate secretory system and we have studied some of the factors governing access to the export pathway. Unglycosylated chicken ovalbumin, synthesized and trapped in the cytosol, is not secreted but glycosylated ovalbumin, found sequestered within vesicles, is exported from oocytes. However, ovalbumin, which is transferred across the endoplasmic reticulum in the presence of tunicamycin and which is indistinguishable by immunoprecipitation, by two-dimensional gel electrophoresis and by concanavalin-A--Sepharose binding from the cytosolic form, is still secreted. Guinea-pig milk proteins and human interferon are also exported from tunicamycin-treated frog cells. These observations demonstrate that access to the endoplasmic reticulum but not glycosylation is a mandatory intermediate step in secretion, and emphasize the advantages of the oocyte as a surrogate system for the study of the later events in the gene expression pathway.     

INTERACTION OF ESTROGEN AND PROGESTERONE IN CHICK OVIDUCT DEVELOPMENT : I. Antagonistic Effect of Progesterone on Estrogen-Induced Proliferation and Differentiation of Tubular Gland Cells

Daily administration of estrogen to immature female chicks results in marked oviduct growth and appearance of characteristic tubular gland cells which contain lysozyme. Although a rapid increase in total DNA and RNA content begins within 24 hr, cell specific protein, lysozyme, is first detectable after 3 days of estrogen. Progesterone administered concomitantly with estrogen antagonizes the estrogen-induced tissue growth as well as appearance of tubular gland cells and their specific products, lysozyme and ovalbumin. When the initiation of progesterone administration is delayed for progressively longer periods (days) during estrogen treatment, proportionally greater growth occurs with more lysozyme and tubular gland cells after 5 days of total treatment. Progesterone does not inhibit the estrogen-stimulated increase in uptake of α-aminoisobutyric acid and water by oviduct occurring within 24 hr or the estrogen-induced increase in total lipid, phospholipid, and phosphoprotein content of serum. The above results of progesterone antagonism can best be explained by the hypothesis that progesterone inhibits the initial proliferation of cells which become tubular gland cells but does not antagonize the subsequent cytodifferentiation leading to the synthesis of lysozyme and ovalbumin once such cell proliferation has occurred.     

Isolation of a nuclear ribonucleoprotein fraction from chick oviduct containing ovalbumin messenger RNA sequences

A method was developed for the isolation of a ribonucleoprotein fraction from chick oviduct nuclei that contains 70% of the pulse-labeled RNA. These fractions also contain about 1% of the nuclear DNA and have an average RNA to DNA ratio of about 4:1. The major nuclear RNP proteins of 32,000 M_r are present along with many additional proteins including histories. However, polysomal proteins and major oviduct cytoplasmic proteins are absent. Nuclei from fully stimulated chick oviduct contain about 3000 copies of ovalbumin messenger RNA sequences of which about 200 are in the RNP complexes: these complexes have sedimentation coefficients of 30 to 350 S and are resistant to disruption by EDTA.The level of ovalbumin mRNA sequences in these complexes reflects the overall rate of synthesis of this RNA. Withdrawal of estrogen leads to a parallel decline of nuclear estrogen receptors and ovalbumin mRNA sequences in the RNP complexes and a subsequent loss of cytoplasmic ovalbumin mRNA about three hours later. The 300-fold decrease in the level of ovalbumin mRNA sequences in these complexes and the eightfold decrease in stability of cytoplasmic ovalbumin mRNA account for the 2500-fold decrease in the level of cytoplasmic ovalbumin mRNA observed during withdrawal. Upon stimulation with estrogen, the kinetics of reappearance of ovalbumin mRNA sequences in the RNP complexes apparently accounts for the accumulation of cytoplasmic ovalbumin mRNA. Thus the nuclear RNP has some of the properties expected of nascent RNP complexes.The levels of ovalbumin and conalbumin mRNA sequences increase in the nuclear RNP with markedly different kinetics: conalbumin mRNA sequences reach half maximum by 1.5 hours, whereas ovalbumin mRNA sequences in these complexes reach half maximum at about eight hours. In the analysis in the accompanying Appendix, we show that the immediate increase of conalbumin mRNA sequences in the nuclear RNP may be accounted for by interaction of the hormone receptor complex with a single regulatory site, whereas the delayed increase of ovalbumin mRNA sequences in the RNP may be due to a requirement for interaction of the hormone receptor complex with multiple regulatory sites.     

INTERACTION OF ESTROGEN AND PROGESTERONE IN CHICK OVIDUCT DEVELOPMENT : II. Effects of Estrogen and Progesterone on Tubular Gland Cell Function

The effects of estrogen and progesterone on the function of chick oviduct tubular gland cells have been studied. Such function, as measured by the increase in specific cell products such as lysozyme and ovalbumin, requires the continuous presence of estrogen or progesterone. Withdrawal of hormone results in a rapid cessation of function and an involution of the oviduct accompanied by rapid decreases in total weight, lysozyme, and RNA. During such involution, tubular gland cells per se persist, as evidenced by a lack of comparable decrease in total DNA content and by histological demonstration of tubular gland cells. When estrogen administration is reinstituted, preexisting tubular gland cells rapidly synthesize ovalbumin and lysozyme without requiring new DNA synthesis. Administration of progesterone also stimulates the function of such cells. Furthermore, the effects of estrogen and progesterone are synergistic on the synthesis of lysozyme and ovalbumin, whereas progesterone antagonizes the estrogen-evoked formation of tubular gland cells. It is suggested that such complex interactions of estrogen and progesterone on oviduct development and function result from differences in responsiveness of the various cell types present in the tissue.     

Initiation of endogenous messenger RNA translation on hen oviduct polysomes.

The eIF-2A fraction of reticulocyte ribosomal salt wash is capable of maximally stimulating the translation of endogenous messenger RNA by hen oviduct polysomes. The factor increases the initiation of protein synthesis 2--3-fold when measured by the factor-dependent synthesis of NH2-terminal peptides. The addition to these polysomes of elongation factor, EF-1, also increases protein synthesis but at a distinctly different rate and Mg2+ concentration optimum than the eIF-2A fraction. Moreover, there is no stimulation of NH2-terminal peptide synthesis with EF-1 alone. In contrast, all the known initiation factors are required for the translation of exogenous globulin mRNA on oviduct polysomes. Reticulocyte polysomes isolated by an identical procedure to that used for oviduct polysomes or by standard methods also require all the initiation factors for the translation of either endogenous mRNA or exogenous ovalbumin mRNA. Addition of 7-methylguanosine 5'-monophosphate does not inhibit the factor-dependent stimulation of oviduct polysomes except at high concentrations (1.0 mM) indicating that the sites with which 7-methylguanosine 5'-monophosphate normally competes are already occupied. These findings suggest that the messenger RNA remains bound to the oviduct polysomes or initiation factors. Hence the addition of exogenous factors which are involved with mRNA recognition and binding to the ribosome are not required. It has been previously shown that eIF-2A is capable of binding in vitro the initiatior tRNA to an existing Ado-Urd-Gua-40 S complex and initiating protein synthesis when such a complex is present. These present studies indicate that such an initiation complex may exist within the oviduct cell on membrane-associated polysomes. Under these circumstances eIF-2A mediates binding of the initiator tRNA and initiates protein synthesis.     

Immunoadsorption of specific chicken oviduct polysomes. Isolation of ovalbumin, ovomucoid, and lysozyme messenger RNA.

The messenger RNA coding for the egg white proteins ovalbumin, ovomucoid, and lysozyme were isolated by immunoadsorption of polysomes synthesizing these proteins. Monospecific antibodies against ovalbumin, ovomucoid, and lysozyme, raised in rabbits, were reacted with chicken oviduct polysomes. The antibody-polysome complexes were isolated by immunoadsorption onto sheep anti-rabbit antibodies coupled to an insoluble matrix. The specifically bound polysomes were eluted and the mRNA was obtained by poly(U)-Sepharose chromatography. The three specific RNAs were further purified by preparative gel electrophoresis. The purity of the mRNA preparations was demonstrated by analytical gel electrophoresis, the capability to direct the synthesis of specific protein products in a wheat germ cell-free system, and by hybridization to cDNA transcribed from mRNAoa and mRNAomu. Purified mRNAoa was shown to contain less than 0.1% mRNAomu and purified mRNAomu was about 99% pure with respect to mRNAoa. Purified mRNAly was contaminated with mRNAoa to 0.34% and with mRNAomu to 2.9%.     

Effects of insulin-like growth factor-I,estrogen, glucocorticoid,and transferrin on the mRNA contents of ovalbumin and conalbumin in primary cultures of quail (Coturnix coturnix japonica) oviduct cells

The effects of estrogen, dexamethasone, insulin-like growth factor-I (IGF-I), and transferrin on the messenger RNA (mRNA) contents of ovalbumin and conalbumin in primary cultures of quail oviduct cells were investigated. In the absence of one of the above hormones or factors, a decrease in ovalbumin mRNA was prominent. In particular, removal of IGF-I and transferrin caused a significant effect. Studies using a combination of estrogen, dexamethasone, IGF-I and transferrin indicated that IGF-I cooperates with estrogen or dexamethasone and transferrin works with dexamethasone. Specifically, IGF-I enhanced ovalbumin synthesis or increased cellular ovalbumin mRNA content depending on its concentration in the medium in the presence of estrogen. However, the effects of estrogen, dexamethasone, IGF-I, and transferrin were not similarly observed with conalbumin mRNA. These results show that ovalbumin synthesis is controlled by estrogen or glucocorticoid with IGF-I or transferrin and that cellular ovalbumin mRNA content is also regulated by these hormones or transferrin. In contrast, conalbumin synthesis and cellular content of conalbumin mRNA are not affected by these hormones under the conditions of the present study.     

Analysis of the coding activity and stability of messenger RNA in Drosophila oocytes.

The coding activity of the messenger RNA in the ooplasm of late stage 14 (S14) oocytes of Drosophila melanogaster was analyzed by labeling the oocytes in vitro with [³⁵S]methionine and examining the labeled products by two-dimensional gel electrophoresis and fluorography. This analysis was done both with newly formed S14 oocytes from rapidly laying females and with S14 oocytes stored for about 10 days in females that were prevented from laying. Comparison of the fluorographs showed that the proteins labeled in the newly formed oocytes were also labeled in the stored oocytes. Thus, the coding activity of S14 oocyte messenger RNA appears to remain stable during prolonged storage in utero. The oocyte proteins synthesized during oogenesis and incorporated into S14 oocytes were labeled in vivo by injecting [³⁵S]methionine into newly eclosed females, and the S14 oocytes were removed 2 days later for gel electrophoresis and fluorography. Comparison of the fluorographs produced by the in vivo and in vitro labeling procedures showed that most of the oocyte proteins labeled in vivo were also labeled in vitro. The S14 oocytes, therefore, appear to contain messenger RNA for most of the oocyte proteins synthesized during oogenesis. There were also several additional proteins detected only in the fluorographs of the in vivo labeled oocytes; the most prominent of these were identified by immunoprecipitation tests as vitellogenin proteins of yolk granules, which are known to be synthesized outside the oocyte, in fat bodies. The occurrence of stable S14 oocyte messenger RNA for most of the oocyte proteins suggests that the synthesis of those proteins during oogenesis occurs in the developing oocytes, specified by a stable population of oocyte messenger RNA.     

Segregation of mutant ovalbumins and ovalbumin-globin fusion proteins in Xenopus oocytes: Identification of an ovalbumin signal sequence

The intramolecular signals for chicken ovalbumin secretion were examined by producing mutant proteins in Xenopus oocytes. An ovalbumin complementary DNA clone was manipulated in vitro, and constructs containing altered protein-coding sequences and either the simian virus 40 (SV40) early promoter or Herpes simplex thymidine kinase promoter, were microinjected into Xenopus laevis oocytes. The removal of the eight extreme N-terminal amino acids of ovalbumin had no effect on the segregation of ovalbumin with oocyte membranes nor on its secretion. A protein lacking amino acids 2 to 21 was sequestered in the endoplasmic reticulum but remained strongly associated with the oocyte membranes rather than being secreted. Removal of amino acids 231 to 279, a region previously reported to have membrane-insertion function, resulted in a protein that also entered the endoplasmic reticulum but was not secreted. Hybrid proteins containing at their N terminus amino acids 9 to 41 or 22 to 41 of ovalbumin fused to the complete chimpanzee α-globin polypeptide were also sequestered by oocyte membranes. We conclude that the ovalbumin “signal” seque?ce is internally located within amino acids 22 to 41, and we speculate that amino acids 9 to 21 could be important for the completion of ovalbumin translocation through membranes.