Protein synthesis by the milk gland and fat body of the tsetse fly,Glossina pallidipes

The patterns of protein synthesis by the milk gland and the fat body of female Glossinapallidipes during the pregnancy cycle were studied by incubation with [³⁵S]methionine both in vivo and in vitro. The pattern of protein synthesis by the milk gland changed with the stage of the larva in the uterus. Very little synthesis occurred in the milk gland until the first instar larva hatched. Then four proteins (13, 16, 24 and 72 kDa) were prominently synthesized. As the larva matured, the synthesis of 19, 38, 40 and 72 kDa proteins increased, whereas that of the 13 and 24 kDa proteins decreased. Just before larviposition, only the 16 and 72 kDa proteins were still being synthesized. The milk gland secreted into the medium primarily the 13, 16, 19 and 72 kDa proteins, all of which were found in the larval gut after a 5 hr pulse of labeled methionine in vivo. During most of the pregnancy cycle protein synthesis in the fat body was low compared to that of the milk gland and only small amounts of several low molecular weight proteins (less than or equal to 16 kDa) were released into the medium. But when a large third instar larva was present in the uterus, the fat body synthesized and secreted a 72 kDa and a 15–17 kDa complex of proteins.     

Haemolymph ecdysteroid levels in female tsetse fly Glossina fuscipes (Diptera) during the first reproductive cycle: A comparison between virgin and mated females

The fluctuations in haemolymph ecdysteroid levels were recorded by radioimmunoassay during the first two ovarian cycles of the tsetse fly, Glossina fuscipes. During the first ovarian cycle, the patterns of ecdysteroid levels are similar in virgin and mated females. In virgins, the first oöcyte is not ovulated and ecdysteroid levels during the second vitellogenesis remain low. In mated females, vitellogenesis of the second oöcyte is concomitant with growth of the first larva in the mother's uterus and ecdysteroid levels are higher than during the first cycle. Two ecdysteroid increases were recorded in mated females and not in virgins. One coincides with vitellogenesis of the second oöcyte and the other occurs at the end of pregnancy and finishes after larviposition. The roles of ecdysteroids in the regulation of vitellogenesis, ovulation, pregnancy and larviposition are discussed.     

Progesterone induction of the uterine milk proteins: major secretory proteins of sheep endometrium

Progesterone induction of the uterine milk proteins (UTMP), the major secretory products of the ovine uterus during pregnancy, was studied in ovariectomized ewes given physiological levels of progesterone for 0, 2, 6, 14, or 30 days. Western blotting of uterine flushes and of endometrial explant culture medium, endometrial RNA analyses on dot and Northern blots, and immunocytochemistry performed on uterine tissue sections demonstrated the presence of low levels of UTMP mRNA and UTMP protein after 6 days of progesterone therapy, and increasing levels of UTMP production and secretion after 14 days. Highest activity was observed at Day 30. The induction of the UTMP progressed from small amounts of antigen present in the supranuclear region of a few epithelial cells in deep and middle-depth regions of uterine glands in the Day 6 progesterone-treatment group to large amounts detected in epithelial cells spread throughout the length of the glands in later groups. UTMP production was also identified in the uteri of intact ewes at Day 16 (but not earlier) of the estrous cycle and during early pregnancy (Days 14 to 22). Production of a protein similar to the UTMP was also noted in the uterus of a pregnant cow. The UTMP provide a good model of a progesterone-responsive secretory protein in a mammal whose synthesis is increased gradually over a period of weeks.     

A hormone from the uterus of the tsetse fly,Glossina morsitans,stimulates parturition and abortion

Unlike most insects, the tsetse female gives birth to a single, fully grown larva at the culmination of each pregnancy cycle. The expulsion of the larva is regulated by a hormone present in rich abundance within the female's uterus. The hormone elicits parturition when injected into neck-ligated females at late stages of pregnancy and abortion when injected at earlier stages. We refer to this highly active material (0.043 uterus equivalents stimulates parturition in 50% of the females) as parturition hormone. Injection of the active extract, which appears to be a peptide or small protein, initiates the series of blood pressure pulsations and uterine contractions normally associated with parturition. The discovery that a uterus extract from the flesh fly also elicits parturition in tsetse suggests that this hormone may be widely distributed in insects.     

Autoradiographic study of protein synthesis in abdominal tissues of Glossina austeni

Protein synthesis at various times during the pregnancy cycle of G. austeni was determined by autoradiographic measurement of the incorporation of H³-leucine and H³-tyrosine into the cells of the fat body, oenocytes, milk gland and epidermis. The rate of utilization of these molecules is such that the labelled pool in the haemolymph is depleted before 0.5 hr after injection. The incorporation of both amino acids into fat body and oenocytes is high at eclosion and just after larviposition, with the incorporation of tyrosine by the oenocytes being much higher than that in the fat body. The same pattern of incorporation is observed in the epidermal cells. Label also appears in the endocuticle during the first 10 days of adult life. Except during the first 4 days following emergence, the incorporation of the two amino acids into the milk gland is very high, with periods of less intense protein synthesis at about the time of larviposition. The milk gland represents a highly efficient secretory system, with a t₅₀ of less than 30 min.     

Interrelationship of glycogen metabolism and lactose synthesis in mammary epithelial cells of mice.

Glycogen metabolism in mammary epithelial cells was investigated (i) by studying the conversion of glucose into glycogen and other cellular products in these cells from virgin, pregnant and lactating mice and (ii) by assaying the enzymes directly involved with glycogen metabolism. We find that: (1) mammary epithelial cells synthesized glycogen at rates up to over 60% that of the whole gland; (2) the rate of this synthesis was modulated greatly during the reproductive cycle, reaching a peak in late pregnancy and decreasing rapidly at parturition, when abundant synthesis of lactose was initiated; (3) glycogen synthase and phosphorylase activities reflected this modulation in glycogen metabolism; (4) lactose synthesis reached a plateau during late pregnancy, even though lactose synthase is reported to increase in the mouse mammary gland at this time. We propose that glycogen synthesis restricts lactose synthesis during late pregnancy by competing successfully for the shared UDP-glucose pool. The physiological advantage of glycogen accumulation during late pregnancy is discussed.     

Uterine blood supply as a main factor involved in the regulation of the estrous cycle--a new theory

The paper presents a new theory on the physiological mechanism of initiation of luteolysis, function of endometrial cells and protection of corpus luteum. This theory is based on previous studies published by the authors and their coworkers on the retrograde transfer of PGF2alpha in the uterine broad ligament vasculature during the estrous cycle, early pregnancy and pseudopregnancy. The studies were focused on cyclic changes in uterine blood supply and the apoptosis of endometrial cells. Moreover, the results of many other authors are cited. The statements of the theory are as follows: 1. The initiation of luteolysis is a consequence of regressive changes in the endometrium which are due to the reduction of the uterine blood supply below the level necessary to provide for the extended needs of active endometrium. 2. During the luteal phase, both a considerable increase in uterine weight and a decrease in blood flow through the uterine artery, resulting from increasing progesterone concentration, reduce the uterine blood supply. In comparison to the volume of blood flowing to the porcine uterus during the estrus period, only 30-40% of the blood volume is determined on day 12 of the estrous cycle. The uterine weight at that time is 40-60% larger than that in the early luteal phase. Thus, due to the considerable constriction of uterine blood vessels, there is a discrepancy between the requirement for oxygen and other factors transported by blood and the possibility of supplying the uterus with these substances. After reaching the threshold of uterine blood supply level, which in pigs takes place around day 12 of the estrous cycle, regressive changes and PGF2alpha release from endometrial cells occurs. 3. Estrogens and progesterone are the major factors affecting blood flow in vessels supplying the uterus. The factors that modulate, complement and support vasodilation and vasoconstriction are: PGE2, LH, oxytocin, cytokines, neurotransmitters and other local blood flow regulators. In some animal species these modulators, especially those of embryonic origin, may be crucial for the status of uterine vasculature. 4. During early pregnancy, the action of embryo signals (estrogens, cytokines), endometrial PGE2 as well as LH results in the relaxation of the uterine artery (pigs: day 12) and, consequently, in an increase in uterine blood supply. This reaction of the maternal recognition of pregnancy effectively prevents regressive changes in well developed endometrial cells to occur. 5. Local uptake and retrograde transfer of PGF2alpha into the uterine lumen during early pregnancy protects corpus luteum from PGF2alpha luteolytic action. 6. During the period of regressive changes resulting from the limited uterine blood supply, endometrial cells restrain PGF2alpha synthesis. They are, however, still capable of releasing prostaglandin when uterine blood supply is improved after the embryo appears in the uterus. This potential capability for PGF2alpha synthesis was demonstrated in in vitro studies when endometrial cells collected during its regressive phase were incubated in medium and stimulated by LH and oxytocin. 7. Prostaglandin F2alpha pulses in venous blood flowing from the uterus do not confirm pulsatile secretion of PGF2alpha. The pulses may result from the pulsatile excretion of PGF2alpha with venous blood according to the rhythmic uterine contractions associated with oxytocin secretion. 8. The results supporting this concept are presented and discussed in due course. The critique of Bazer and Thatcher's theory on exocrine versus endocrine secretion of prostaglandin F2alpha during the estrous cycle is also depicted.     

Uterine epithelial-sperm interaction, endometrial cycle and sperm storage in the terminal zone of the oviducal gland in the placental smoothhound, Mustelus canis.

The fate of spermatozoa deposited within the female reproductive tract has been described in the smoothhound, Mustelus canis. Evidence of uterine epithelial-sperm interaction is presented, as well as documentation of sperm storage specifically in the terminal zone of the oviducal gland. Sperm fate is correlated with morphology of the endometrial cycle and specificity of storage in the oviducal gland. The endometrium of M. canis undergoes dramatic tissue remodeling associated with gestation. In females harboring fertilized ova or preimplantation yolk-reliant embryos, the uterine epithelium is simple cuboidal with mucous droplets for lubrication. The presence of the embryo elicits a response from the uterus, which becomes modified for nutrient and respiratory exchange into vascular uterine attachment sites that abut the distal aspect of the yolk sac. Areas of the uterus adjacent to the uterine attachment sites are termed paraplacental sites. Uterine attachment sites are simple squamous while the paraplacental epithelium is simple columnar. Paraplacental cells have basal metachromatic vesicles and a dense array of apical cytoplasmic filaments. Immediately postpartum the uterine attachment sites, now termed uterine or placental scars, begin to remodel to a mucous epithelium for the next gestational cycle. Paraplacental cells slough off the apical filamentous portion, and sperm become embedded in the epithelium. Bundled sperm occur throughout gestation in the terminal zone of the oviducal gland. Sperm are not embedded in the terminal zone epithelium as in the uterus. Following sperm release from the uterus, the paraplacental epithelium reverts to a mucous epithelium for the next reproductive cycle. Fertilization is presumed to occur in the anterior oviduct above the oviducal gland. The physiological mechanisms that mediate sperm-uterus attachment, release, and storage in the terminal zone of the oviducal gland are currently under investigation.     

Simulating uterine contraction by using an electro-chemo-mechanical model

Contractions of uterine smooth muscle cells consist of a chain of physiological processes. These contractions provide the required force to expel the fetus from the uterus. The inclusion of these physiological processes is, therefore, imperative when studying uterine contractions. In this study, an electro-chemo-mechanical model to replicate the excitation, activation, and contraction of uterine smooth muscle cells is developed. The presented modeling strategy enables efficient integration of knowledge about physiological processes at the cellular level to the organ level. The model is implemented in a three-dimensional finite element setting to simulate uterus contraction during labor in response to electrical discharges generated by pacemaker cells and propagated within the myometrium via gap junctions. Important clinical factors, such as uterine electrical activity and intrauterine pressure, are predicted using this simulation. The predictions are in agreement with clinically measured data reported in the literature. A parameter study is also carried out to investigate the impact of physiologically related parameters on the uterine contractility.     

Uterine and placental prostaglandins and their modulation of oxytocin sensitivity and contractility in the parturient uterus

The parturient uterus develops a markedly enhanced sensitivity to the uterotonic action of oxytocin (OT). The mechanism leading to this enhanced OT sensitivity is not known. Our previous work suggested that prostaglandins (PGs) may be involved. To define the relationship between OT sensitivity and uterine PG production, we measured uterine sensitivity to OT by a quantitative dose-response procedure in rats on Days 19, 20, 21 and 22 of pregnancy and monitored uterine and placental tissue concentrations of PGF2 alpha and PGE2. In addition, we determined the effects of inhibition of endogenous PG synthesis on OT sensitivity and uterine contractility. We found that both OT sensitivity and spontaneous contractility are positively related to uterine PGF2 alpha production. An abrupt increase in OT sensitivity was observed on Days 21 and 22 of pregnancy. The increase in OT sensitivity was coincidental with the marked increase in PGF2 alpha production in the uterus on Days 21 and 22 of pregnancy. Suppression of in vivo PG synthesis caused a reduction in both spontaneous uterine contractility and OT-induced contractions. Uterine PGE2 concentrations and release were 3-5 times lower than PGF2 alpha. There were no significant fluctuations of uterine PGE2 concentration measured on these last 4 days of gestation. Placental PG levels were also found not to be related to uterine contractility. Placental PGE2 levels were higher than PGF2 alpha and may play a regulatory role in placental perfusion. However, placental PGs did not vary with gestational age.     

Histomorphometrical and proliferative aspects of placenta and uterus of the collared peccary (Tayassu tajacu)

The histomorphometric and proliferative characteristics of the collared peccary (Tayassu tajacu) placenta and uterus were analyzed. The material was examined by standard histological techniques and histochemistry (PAS, Perls and Alcian Blue pH 0.5 and 2.5%) and the cellular proliferation by AgNORs and flow cytometry. All the analyzed morphometric variables differed between pregnant and non-pregnant uteri in the luteal phase using the Dunnet test. Height and gland diameter of uterine glands increased linearly during pregnancy, with an intense positive PAS and Perls reaction in all stages. The cells with more than seven AgNORs per nuclei and the cells in the G2M cell cycle phase in the maternal tissue also increased after 70 days of pregnancy. The uteroplacental ridges had a linear increase in size with two distinct areas, base and top, with uterine epithelium and trophoblastic cells changing their morphology following the placental ridge development. Flow cytometry analysis showed the percentage of cells in each cell cycle phase with a quadratic behavior for stages G2/M in the maternal tissue, suggesting an increase in proliferative capacity of maternal tissue after 65 days of pregnancy. The same quadratic effect was observed in the G0/G1 phase in both maternal and fetal tissues. Cells in apoptosis showed cubic behavior in both tissues. The morphometric and cellular dynamic aspects observed in this study have not been previously described and they extend our knowledge of functions relating to maternal-fetal dynamics in this species.     

Conceptus-mediated integrity of endometrial epithelial cells and maintenance of relaxin synthesis in pregnant rabbits: effects of unilateral oviduct ligation

A previous study indicated rabbit endometrial relaxin synthesis is stimulated by blastocyst (Lee VH, Fields PA, Biol Reprod 1990; 40:737-745). To evaluate this hypothesis, unilateral oviduct ligations were placed (A) at the oviduct isthmus on Day 1 post-copulation and (B), in a separate group of rabbits, at the infundibulum before copulation. Blastocysts migrate into and implant in the uterine horn contralateral to the ligated oviduct only (conceptus-bearing uterus). The uterine horn ipsilateral to the ligated oviduct will be referred to as the non-conceptus-bearing uterus. Uteri and ovaries were removed on Days 4-28 of pregnancy and were evaluated for relaxin using guinea pig anti-porcine relaxin serum and avidin-biotin light microscopy immunohistochemistry. Results were identical for both models. Blastocysts first attach to the antimesometrial uterine surface by Day 7 post-copulation. Implantation on the mesometrial surface occurs on Days 8-11. Relaxin was observed in antimesometrial endometrial glands of both conceptus and non-conceptus-bearing uteri on Days 4-7 of pregnancy. Beyond Day 7, relaxin was observed in antimesometrial and mesometrial endometrial glandular and luminal epithelial cells at implantation sites of the conceptus-bearing uterus only. Relaxin was not found between implantation sites. Endometrial epithelial cells of the non-conceptus-bearing uterus were regressing by Day 9. These data indicate a conceptus-mediated maintenance of endometrial epithelial cells. Furthermore, the data suggest a paracrine maintenance of epithelial cell integrity and relaxin synthesis since these parameters are preserved only in the conceptus-bearing uterus. Cell-cell communication between conceptus and endometrium appears to be specific since endometrium between implantation sites does not contain relaxin. Uterine tissue from pseudopregnant rabbits (Days 1-16) was evaluated. Relaxin was observed in the antimesometrial glands on Day 7 only. Like the endometrium in the ligation model, endometrial epithelial cells of the pseudopregnant rabbit uterus were regressing by Day 9. These results indicate that pregnancy is not required for, but may enhance, relaxin synthesis. In addition, endometrial epithelial cells regress in the absence of pregnancy. Regression of endometrial epithelial cells on Day 9 suggests that maternal recognition of pregnancy occurs during the preimplantation period (Days 4-8).     

Synthesis of 'decidualization-associated protein' in tissues of the rat uterus and placenta during pregnancy.

The synthesis of a soluble protein (referred to as 'decidualization-associated protein', DAP), has been examined in uterine and placental tissues of rats during pregnancy by means of polyacrylamide gel electrophoretic analysis of [3H]leucine-labelled soluble proteins. No synthesis of the protein was detected in non-implantation regions of the uterus. In implantation site tissue, no synthesis was detected on Days 6 or 7 of pregnancy. Only slight synthesis was present in the endometrium on Day 8, but synthesis rose rapidly from Days 9 to 12 in both the endometrium and myometrium although differences in the rates of increase were observed. Synthesis fell from Day 12 to 14 in both tissues. Synthesis by the myometrium was entirely localized in the mesometrial region, which contains the metrial gland. After Day 12, when the endometrium is represented by the chorioallantoic placenta, synthesis was examined in the labyrinthine and the decidua basalis/basal zone placenta tissues. No synthesis of 'DAP' was detected in the labyrinthine placenta from Day 16 of pregnancy. Synthesis observed in the decidua basalis/basal zone placenta fell dramatically from Day 14 to 20. The pattern of synthesis of 'DAP' during pregnancy suggests a role in the establishment of the chorioallantoic placenta and metrial gland in the rat.     

The differentiation of the decidua and the distribution of metrial gland cells in the pregnant mouse uterus

Summary A study was made with the light microscope of the cellular changes involved in the formation of the decidua in the pregnant mouse uterus up to day 11 of pregnancy. The differentiation sequence was similar to that found by previous workers but the morphology and development of the basal zone is described in more detail. In addition, the morphology of glycogen rich cells in an area termed the lateral decidual zone is described. The distribution of granulated metrial gland cells and their precursors is described. These cells are first found in the uterine stroma before the blastocyst has implanted. Later they occur in the decidua and in the circular smooth muscle zone beneath the mesometrial triangle prior to the formation of the metrial gland. Granulated metrial gland cells are also found in the maternal blood spaces of the implantation site.     

Immunohistochemical detection of androgen receptors in the canine uterus throughout the estrus cycle

Serum androgen levels in the bitch increase during proestrus and remain elevated until metestrus. To find out whether androgens can have a direct impact on the canine uterus, androgen receptors (AR) were identified immunohistochemically in uterine tissue. Androgen receptor distribution in the uterine horns, body and cervix was described during different cycle stages, during pregnancy and in the postpartum period. Nuclear staining for AR was observed in cells of the surface epithelium, glandular ducts, basal glands and stroma of the endometrium, and in myometrial smooth muscle cells. In addition, cytoplasmic staining was observed in epithelial cells from proestrus to early metestrus, when the cells were secretory active, and in stroma cells during pregnancy, suggesting a role for androgens in decidualization. During pregnancy and in the postpartum period nuclear staining for AR was nearly absent. During the estrus cycle stroma cells stained with higher intensities for AR than epithelial cells, supporting the idea that stroma cells mediate some effects of steroid hormones on epithelial cells in the genital tract. In contrast with earlier findings on estrogen receptor-alpha and progesterone receptors, no significant changes in androgen receptor expression were observed during the estrus cycle. Few correlations were found between the staining for AR and serum levels of the sex steroids. The present findings suggest that there is a basal expression of AR in the canine uterus throughout the estrus cycle that may not be influenced by sex steroid hormones.     

Variation in thickness and protein content of the cuticle of the female of Glossina austeni

The thickness and total protein content of the ventral abdominal cuticle of the female tsetse, Glossina austeni, increase during the early part of each pregnancy cycle, reaching a maximum at approximately 2 days after ovulation. They decrease thereafter, and reach a minimum value just before larviposition. Virgin females do not exhibit a cycle of protein content or thickness in the cuticle. Preliminary data on the incorporation of [³H]tyrosine or [³H]leucine into the water-soluble proteins of the ventral abdominal cuticle at the time of the second larviposition suggest that there is rapid turnover of protein in the cuticle at this time. These observations are consistent with the net storage of protein in the cuticle during the early part of pregnancy cycle followed by a net depletion of that store as the nutritional demands of the rapidly growing larva in utero exceed the capacity of the ingested blood meals to supply them.     

Neuroendocrine stimulation of uterine gland protein synthesis in the tsetse fly, Glossina morsitans

ABSTRACT. The uterine gland of the tsetse fly Glossina morsitans morsitans Westw. synthesizes a secretion which nourishes the developing larva in the uterus. Aqueous extracts of the brain have been shown to stimulate the synthesis of the protein and amino acid components of this secretion from L- [U-¹⁴C]leucine by uterine gland tubules in vivo and in vitro. A linear dose response relationship was demonstrated in vitro with extract concentrations ranging from 1 × 10^-4 to 1 × 10^-2 brains μl^-1. The maximum response, a > 300% increase in the rate of protein and amino acid synthesis, was achieved with as little as 1 × 10^-2 brains μl^-1 The concentration of active factor(s) in the brain declined during a single interlarval period coincident with the period of release of secretion associated with larval growth. The stimulatory activity in brain extracts was destroyed by proteolytic enzymes indicating that it is probably a protein or peptide. Results suggest that the active factor(s) is a hormone responsible for the stimulation of uterine gland protein synthesis essential for larval nutrition.