Mechanism of chalaza formation in quail eggs

The present study was conducted to determine the mechanism of chalaza formation in eggs of the Japanese quail Coturnix japonica and to determine the production site of chalaza materials in the oviduct. Electrophoretic profiles of the chalaza materials showed six bands of 480, 320, 210, 180, 96, and 58 kDa following Coomassie Blue staining and one band of 600 kDa after immunoblotting. An antiserum was produced against the 180-kDa band. This antiserum and an antiserum generated against the 600-kDa protein were used as probes to detect chalaza materials. Immunofluorescent and immunoelectron-microscopic observations revealed that chalazae and chalaziferous layers overlaid to approximately 40 μm upon the vitelline membrane of the ovum were composed of the same materials as those produced by both types of secretory cells in the luminal and glandular epithelia at the infundibulum. We propose that the mechanism of chalaza formation is as follows: (1) chalazae first appear as fine filaments at the presumptive sharp and blunt ends of the ovum at the infundibulum; (2) these filaments are twisted into a lead fiber while the ovum is rotating and descending in the magnum; (3) at the posterior end of the magnum, the lead fiber is anchored to the thick egg white and lifted outward with the chalaziferous sublayers when the inner egg white is liquefied by absorbing water; (4) the lead fiber and chalaziferous sublayers are twisted further into the chalaza in the uterus.     

Smooth muscle of the quail oviduct functions as a stretch receptor during ovum transport

The present experiments were conducted to test the hypothesis that ovum transport in the quail oviduct is regulated by a time-dependent, stretch-mediated feedback cycle which alters the frequency of contractions. According to this hypothesis, a ligature preventing the forward movement of ovum should reverse the direction of the feedback cycle and an artificial ovum should be transported like the normal ovum. When the ligature was placed in the borderline between magnum and isthmus, it caused the reversal of transport direction after a delay of several minutes. Once the direction had changed, it persisted until the ovum was expulsed through the fimbrial end or until a second reversal was caused by either a second ligature or a minor mechanical impediment at the proximal end of the magnum. The ovum was transported between the ligatures at the mean speed of 1.7 +/- 0.17 mm/min (n = 7) until the ovum broke. An artificial ovum placed in the proximal magnum from which the natural ovum had been removed, was transported like the natural ova. Myoelectrical activity recorded with suction electrodes was statistically similar in both types of experiments and the direction of the frequency gradient changed when the transport direction was reversed. The frequency of the electrical activity of oviductal smooth muscle was significantly higher behind the ovum than in its front whether ova were transported in the direction of shell gland or infundibulum; in the segment maximally stretched by the ovum the activity was significantly lower than in other segments. These observations confirmed the hypothesis and suggest that the quail oviduct functions like a stretch receptor.     

Studies on sex-organ development. Prenatal effect of oestrogenic hormone on tubular-gland cell morphogenesis and ovalbumin-gene expression in the chick Müllerian duct.

The effects of diethylstilboestrol on morphogenesis and cyto-differentiation of the chick-embryo left Müllerian duct were examined. Embryos were treated at different stages of development with maximal-responsive doses of diethylstilboestrol over a 5-day interval. The shell gland and magnum regions of the Müllerian duct were then assayed for growth and histological morphogenesis. The results were correlated with diethylstilboestrol-induced ovalbumin-gene expression as measured by ovalbumin-mRNA (mRNAov) accumulation and the relative rate of ovalbumin synthesis. Treatment of the embryo from day 10 to day 15 of incubation induces morphogenesis of tubular-gland cells in the Müllerian-duct magnum. Although these cells constitute 10% of the total cell population and contain an average of 8000 molecules of mRNAov per cell, ovalbumin synthesis is only 0.85% of total magnum protein synthesis. The Müllerian-duct magnum of embryos treated from day 13 to day 18 of incubation contains about 30% tubular-gland cells, which have accumulated an average of 7000 molecules of mRNAov per cell, but ovalbumin synthesis is only 3.25% of total magnum protein synthesis. The Müllerian-duct magnum of embryos treated from day 16 to day 21 of incubation contains about 50% tubular-gland cells, which have accumulated an average of 6500 mRNAov molecules per cell, and ovalbumin synthesis is 10% of total magnum protein synthesis. Oestrogen responsiveness develops simultaneously in the Müllerian-duct magnum and shell-gland regions. Compared with the rate of diethylstilboestrol-induced oviduct growth, the relative rate of diethylstilboestrol-induced Müllerian-duct growth increases with embryonic age, from 20-fold lower in the 10-day embryo to only 3-fold lower in the 16-day embryo. All results are discussed in comparison with the responses to oestrogen of the immature chick oviduct, and in terms of the ontogeny of hormone-competent epithelial and stromal components of the Müllerian duct. It is concluded that the development of oestrogenic competence in the embryonic Müllerian duct is a multiphasic phenomenon. A dramatic increase in hormone responsiveness in the Müllerian duct occurs between days 10 and 16 of development, and a less dramatic final maturation of oestrogen responsiveness occurs between day 16 of development and 1 week after hatching.     

Functional differences in protein synthesis between rat liver tRNA and tRNA from Novikoff hepatoma.

Synthesis of ovalbumin in fragmented oviduct magnum explants of immature, estrogen-stimulated chicks has been studied in the presence of exogenous tRNA. tRAN from Novikoff hepatoma specifically inhibited ovalbumin synthesis, determined by precipitation with antisera. In addition, the major protein(s) synthesized in the presence of hepatoma tRNA had higher electrophoretic mobility than ovalbumin, as shown by sodium dodecyl sulfate polyacrylamide gel electrophoresis. tRNAs from rat liver, rooster liver, and hen oviduct did not affect ovalbumin synthesis, although oviduct tRNA is stimulatory during the earlier stages of estrogen stimulation.     

INTERACTION OF ESTROGEN AND PROGESTERONE IN CHICK OVIDUCT DEVELOPMENT : III. Tubular Gland Cell Cytodifferentiation

Administration of estrogen (E) to immature chicks triggers the cytodifferentiation of tubular gland cells in the magnum portion of the oviduct epithelium; these cells synthesize the major egg-white protein, ovalbumin. Electron microscopy and immunoprecipitation of ovalbumin from oviduct explants labeled with radioactive amino acids in tissue culture were used to follow and measure the degree of tubular gland cell cytodifferentiation. Ovalbumin is undetectable in the unstimulated chick oviduct and in oviducts of chicks treated with progesterone (P) for up to 5 days. Ovalbumin synthesis is first detected 24 hr after E administration, and by 5 days it accounts for 35% of the soluble protein being synthesized. Tubular gland cells begin to synthesize ovalbumin before gland formation which commences after 36 hr of E treatment. When E + P are administered together there is initially a synergistic effect on ovalbumin synthesis, however, after 2 days ovalbumin synthesis slows and by 5 days there is only 1/20th as much ovalbumin per magnum as in the E-treated controls. Whereas the magnum wet weight doubles about every 21 hr with E alone, growth stops after 3 days of E + P treatment. Histological and ultrastructural observations show that the partially differentiated tubular gland cells resulting from E + P treatment never invade the stroma and form definitive glands, as they would with E alone. Instead, these cells appear to transform into other cell types—some with cilia and some with unusual flocculent granules. We present a model of tubular gland cell cytodifferentiation and suggest that a distinct protodifferentiated stage exists. P appears to interfere with the normal transition from the protodifferentiated state to the mature tubular gland cell.     

Ultrastructural changes in the oviduct of the laying hen during the laying cycle

The ultrastructural changes occurring in the fully functional oviduct of Isa Brown laying hens were studied during various stages of the laying cycle. Hens were killed at different positions of the egg in the oviduct. The oviduct was lined by ciliated and non-ciliated cells (also referred to as granular cells). The granular cells in the infundibulum contributed to secretion during egg formation, whereas ciliated cells showed little evidence of secretion. Ultrastructural changes were recorded in the granular and glandular cells of the distal infundibulum. In the magnum, the surface ultrastructure revealed glandular openings associated with the ciliated and granular cells. Cyclic changes were recorded in the glandular cells of the magnum. With respect to the three observed types of glands, the structure of gland type A and C cells varied at different egg positions in the oviduct, whereas type B cells represented a different type of gland cell containing amorphous secretory granules. The surface epithelium of the isthmus was also lined by mitochondrial cells. Two types of glandular cell (types 1 and 2) were recorded in the isthmus during the laying cycle. Intracisternal granules were found in type 2 cells of the isthmus. A predominance of glycogen particles occurred in the tubular shell gland. The granular cells in the shell gland contain many vacuoles. During egg formation, these vacuoles regressed following the formation of extensive rough endoplasmic reticulum; the reverse also occurred. The disintegrated material found in the vacuoles may have been derived from the disintegrating granules. The Physiology Teaching Unit, University of New England, provided financial support to K. Chousalkar for this study.     

Commitment of chick oviduct tubular gland cells to produce ovalbumin mRNA during hormonal withdrawal and restimulation

Acute withdrawal of estrogen from chicks leads to a precipitous decline in egg white protein synthesis and egg white mRNAs in the oviduct. In this paper we explore the biochemical basis of this phenomenon as well as the capacity of the "withdrawn" tubular gland cells to be restimulated with steroid hormones. During withdrawal, the decline in ovalbumin mRNA was closely correlated with the decline in nuclear estrogen receptors. Within 2-3 d of estrogen removal a withdrawn state was established and then maintained, as defined by a 1,000-fold-lower level of ovalbumin mRNA and a 20-fold-lower level of nuclear estrogen receptors, relative to the estrogen-stimulated state. The number of active forms I and II RNA polymerases declined by 50% during this time. Histological examination of oviduct sections and cell suspensions, combined with measurements of DNA content, revealed that tubular gland cells persisted as a constant proportion of the cell population for 3 d after estrogen removal. Despite a 1,000-fold decrease in the content of ovalbumin mRNA, the ovalbumin gene remained preferentially sensitive to digestion by DNase I. When 3-d-withdrawn oviducts were restimulated with either estrogen or progesterone, in situ hybridization revealed that greater than or equal to 98% of the tubular gland cells contained ovalbumin mRNA. Induction by a suboptimal concentration of estrogen was correlated with a lower concentration of ovalbumin mRNA in all cells rather than fewer responsive cells.     

Estrogen-like effects of combined dexamethasone and tamoxifen in the chick oviduct

The effects of dexamethasone alone on withdrawn chick oviduct weight, DNA, protein content and progesterone receptor concentration were barely detectable, whereas ovalbumin and conalbumin synthesis were increased. When dexamethasone and tamoxifen were combined, a marked increase of total proteins, including egg white proteins, DNA and wet weight occurred. Progesterone receptor also was increased. The most striking result was the stimulation of DNA polymerase-α activity by combined dexamethasone and tamoxifen, whereas either compound was completely ineffective.     

Cell-specific and temporal aspects of gene expression in the chicken oviduct at different stages of the laying cycle

Egg formation and embryonic development occur as the yolk passes through the magnum, isthmus, and shell gland of the oviduct before oviposition in hens. The present study identified candidate genes associated with secretory function of the chicken oviduct after ovulation and contributing to egg formation and oviposition. Hens (n = 5 per time point) were euthanized to recover the reproductive tract when the egg was in the magnum (3 h after ovulation) and the shell gland (20 h after ovulation). Total RNA was extracted from each segment of the oviducts and subjected to Affymetrix chicken GeneChip analysis. Quantitative PCR and in situ hybridization analyses of selected genes confirmed the validity of the gene expression patterns detected using microarray analysis. In particular, ACP1, CALB1, CYP26A1, PENK, RCAN1 and SPP1 expression increased significantly in the shell gland between 3 h and 20 h postovulation, whereas only RCNA1 expression increased significantly in the magnum between 3 h and 20 h postovulation. Results of the high-throughput analysis revealed cell-specific and temporal changes in gene expression in the oviduct at 3 h and 20 h postovulation in laying hens provide novel insight into changes at the molecular and cellular levels of candidate genes related to formation of the egg and oviposition.     

Involvement of osteopontin in egg shell formation in the laying chicken

Expression of the osteopontin (OPN) gene in the oviduct of the laying hen was studied. It was detected only in the egg shell gland (ESG), where massive calcification occurs. No OPN gene expression was detected in any other part of the oviduct, such as the magnum and isthmus. The OPN gene was expressed in a circadian fashion during the daily egg cycle only during the period of egg shell calcification. No OPN gene expression was detected in the ESG of a pre-laying hen before the onset of reproduction, or after forced removal of the egg close to its entrance into the ESG. OPN was found to be synthesized by the epithelial cells of the ESG lining the lumen. Upon synthesis, OPN is immediately secreted out of cells and accumulates in the egg shell. These findings demonstrate for the first time temporal and spatial association of OPN with egg shell calcification. OPN, which was found to be part of the organic matrix of the egg shell, may play an important role in egg shell calcification.     

Human alkaline phosphatase expression and secretion into chicken eggs after in vivo gene electroporation in the oviduct of laying hens

In vivo gene electroporation was used to examine whether or not a recombinant protein is synthesized in the chicken oviduct and subsequently secreted into eggs. A plasmid DNA containing a secretion form of the human alkaline phosphatase gene was injected into mucosa of the chicken magnum. Immediately, in vivo gene electroporation was conducted. The human alkaline phosphatase activity in the oviduct mucosa increased and reached its peak at 2 days posttransfection, followed by a sharp decrease to a negligible level at 4 days posttransfection. In the egg white, the alkaline phosphatase activity showed a similar change to that in the magnum mucosa except for a delay of 4 days. The present results imply that in vivo gene electroporation method in the oviduct may serve as a rapid production system of recombinant proteins into chicken eggs.     

Effects of serial hormone treatments on egg white protein synthesis. Further evidence of translational regulation

The administration of either progesterone or estrogen to withdrawn chicks several hours after a first dose of estrogen affected ovalbumin synthesis differently than its mRNA levels [S. S. Seaver (1981) J. steroid Biochem. 14, 949-957]. This suggested that the hormones were regulating the translation of ovalbumin directly. In this paper we report that serial hormone treatments also affect the rates of synthesis of two other egg white proteins, conalbumin and ovomucoid. When progesterone was administered 4 h after estrogen, conalbumin synthesis decreased. When either progesterone or a second dose of estrogen was administered 12 h after the first dose of estrogen, conalbumin synthesis increased. Serial hormone treatments did not always affect all three proteins similarly. At later times, administering progesterone after estrogen decreased ovomucoid synthesis but did not affect conalbumin or ovalbumin synthesis. To determine if the serial hormone treatments affect egg white protein mRNA's in a similar way, changes in ovalbumin and conalbumin mRNA levels were quantified in a rabbit reticulocyte cell-free translation system and were compared to changes in ovalbumin and conalbumin synthesis as measured in chick oviduct tissue minces. When serial hormone treatments were 12 h apart, ovalbumin and conalbumin synthesis was 50-300% higher than that predicted by the changes in ovalbumin or conalbumin mRNA levels. This is further evidence that translation of both conalbumin mRNA and ovalbumin mRNA is directly regulated by steroid hormones.     

Seasonal changes in the oviduct of the pied myna (Aves: Sturnidae)

Study of the oviduct of the pied myna (Sturnus contra contra) throughout the year reveals that oviductal weight, length, surface epithelial height and glycogen content are low during August to January (nonbreeding phase), partially increase during February to April (pre-breeding phase), maximally increase in May (breeding phase) and decrease in June and July (post-breeding phase). In the nesting cycle, there is greatest growth in all the regions of the oviduct from early nest-building to the egg-laying period and this is followed by rapid involution during incubation and nestling periods. Some notable features in the oviduct of the pied myna are described: 1) All five regions of the oviduct (infundibulum, magnum, isthmus, uterus, and vagina) are clearly distinguishable when studied from serial sections of the oviduct even during the nonbreeding phase of the annual ovarian cycle. 2) There is a strong correlation between initiation of tubular gland formation and the onset of nestbuilding activity. 3) The distal part of the magnum is differentiated into a 'mucous region' having well developed basal nonciliated cells. 4) A sixth zone can be identified between the magnum and isthmus. Sperm hostlike glands exist at the cranial end of the zone. 5) Several circular epithelial invaginations are evident in the intermucosal folds and their size decreases in centripetal order in the vagina. 6) The pattern and degree of regression are different in various regions of the oviduct. A close synchrony between ovarian and oviducal cycles is indicated in the pied myna (Sturnus contra contra).     

Periplasmic secretion of native ovalbumin without signal cleavage in Escherichia coli

In Escherichia coli cells carrying wild-type ovalbumin cDNA, some of the recombinant protein was secreted into the periplasmic space. In contrast, a signal-region mutant form of ovalbumin (deletion, Gly1 to Ala39) was not detected in the periplasm despite being synthesized at the same level as the wild-type protein. Chemical and spectroscopic analyses showed that periplasmic ovalbumin assumes a conformation indistinguishable from that of native egg white ovalbumin. We concluded that a process resembling the secretion of ovalbumin process in the oviduct occurs also in bacteria.     

The induction of ovalbumin and conalbumin mRNA by estrogen and progesterone in chick oviduct explant cultures

Estrogen pretreated chick oviduct tissue can be restimulated in vitro by physiological concentrations of estrogen and progesterone. The rates of synthesis of the major egg white proteins, ovalbumin and conalbumin, as well as the cellular levels of their respective mRNAs, increase after characteristic lag periods; this confirms previously reported results in vivo and demonstrates that both the lag phenomena and the mRNA induction are a function of the direct interaction of steroids with oviduct cells.The antagonistic action of progesterone on an estrogen-mediated induction of conalbumin mRNA also occurs in vitro, and the kinetics of this response are examined. Progesterone terminates the estradiol-induced accumulation of conalbumin mRNA within 30 min after addition to the medium; progesterone alone or in combination with estrogen, however, is capable of inducing conalbumin mRNA after a 4 hr lag period. The temporary nature of this antagonism and the fact that it does not occur with ovalbumin induction indicate the complexity of the oviduct's response to steroids.The role of protein synthesis in the induction of both ovalbumin and conalbumin was examined by including protein synthesis inhibitors in the culture medium. Puromycin, cycloheximide, emetine, pactamycin and high salt all block the induction of both ovalbumin and conalbumin mRNA when added together with either estrogen or progesterone. The effect of puromycin is reversible. After the drug is removed from the medium, the mRNA accumulation begins with the same characteristic lag period seen when no inhibitors are added. When given 2 hr after estrogen, puromycin stops the accumulation of conalbumin mRNA within 30 min, whereas cycloheximide and emetine allow the mRNA to accumulate for another 2 hr before causing complete inhibition. There is no effect of protein synthesis inhibitors on the number of estrogen receptors localized in the nucleus. The data suggest a direct link between protein synthesis and the steroid-induced accumulation of specific mRNAs in this system.     

Determination of ciliary polarity precedes differentiation in the epithelial cells of quail oviduct.

In quail oviduct epithelium, as in all metazoan and protozoan ciliated cells, cilia beat in a coordinated cycle. They are arranged in a polarized pattern oriented according to the anteroposterior axis of the oviduct and are most likely responsible for transport of the ovum and egg white proteins from the infundibulum toward the uterus. Orientation of ciliary beating is related to that of the basal bodies, indicated by the location of the lateral basal foot, which points in the direction of the active stroke of ciliary beating. This arrangement of the ciliary cortex occurs as the ultimate step in ciliogenesis and following the oviduct development. Cilia first develop in a random orientation and reorient later, simultaneously with the development of the cortical cytoskeleton. In order to know when the final orientation of basal bodies and cilia is determined in the course of oviduct development, microsurgical reversal of a segment of the immature oviduct was performed. Then, after hormone-induced development and ciliogenesis, ciliary orientation was examined in the inverted segment and in normal parts of the ciliated epithelium. In the inverted segment, orientation was reversed, as shown by a video recording of the direction of effective flow produced by beating cilia, by the three-dimensional bending forms of cilia immobilized during the beating cycle and screened by scanning electron microscopy, and by the position of basal body appendages as seen in thin sections by transmission electron microscopy. These results demonstrate that basal body and ciliary orientation are irreversibly determined prior to development by an endogenous signal present early in the cells of the immature oviduct, transmitted to daughter cells during the proliferative phase and expressed at the end of ciliogenesis.