Effects of oestradiol and progesterone on the metabolism of [U-14C]glucose by mouse morulae and early blastocysts in vitro

The addition of progesterone (10(-7) to 10(-5) M) and/or oestradiol (10(-10) M) during 24-h chase culture of pulse-labelled morulae-early blastocysts did not affect the degradation of radiolabelled glycogen or other biochemical fractions. The presence of a high concentration of progesterone (10(-5) M) during 5-h pulse culture significantly inhibited incorporation of substrate carbon from [U-14C]glucose into both the acid-soluble and acid-insoluble glycogen fractions, but had no effect on non-glycogen fractions. Catabolic utilization of glucose as estimated by the rate of carbon dioxide and lactate production was not affected by the presence of progesterone (10(-7) to 10(-5) M), oestradiol (10(-10) to 10(-8) M) or a combination of both. The results indicate that ovarian steroids at expected physiological concentrations do not directly influence embryonic energy metabolism.     

Differential effects of p-nitrophenyl-D-xylosides on mouse blastocysts and uterine epithelial cells

A number of studies have implicated glycoconjugates in cell recognition events associated with implantation of mammalian blastocysts into the uterus. We have found that p-nitrophenyl-D-xylosides inhibit mouse embryo attachment and outgrowth on monolayers of uterine epithelial cells when cocultured in vitro. Inhibition of attachment and trophoblast formation by alpha- and beta-xylosides was observed in embryos cultured on tissue culture plastic in serum containing medium or on monolayers of epithelial cells. The biochemical basis for this inhibition has been investigated. Consistent with their accepted mode of action, beta- but not alpha-D-xylosides greatly stimulated glycosaminoglycan chain production by uterine epithelial cells and likewise reduced proteoglycan assembly. In contrast, both alpha- and beta-anomers selectively inhibited embryo attachment and outgrowth without stimulating glycosaminoglycan chain production by embryos. The inhibitory effect of the xylosides on embryos was reversible and did not require concentrations that reduced the rate of protein synthesis. Both alpha- and beta-D-xylosides inhibited the synthesis of proteoglycans including heparan sulfate as well as certain other glycoconjugates by embryos. Collectively, these data indicate that proper assembly of glycoconjugates, including proteoglycans, is required for implantation-related processes, although the inhibition of embryo outgrowth by xylosides may be by an as yet uncharacterized mechanism.     

Effects of cryopreservation on glucose metabolism and survival of bovine morulae and blastocysts derived in vitro or in vivo

Bovine morulae and blastocysts were either produced in vitro through maturation, fertilization and culture of immature oocytes recovered from slaughterhouse-derived ovaries, collected in vivo or obtained after 24 h in vitro culture of in vivo collected embryos. The morulae and blastocysts were classified into four categories of embryo quality and two stages of embryonic development. Embryos were frozen by a controlled freezing method using 10% glycerol as a cryoprotectant. The ability of individual embryos to withstand freeze/thawing was measured immediately before and after cryopreservation by changes in CO2 production from (U-14C)glucose during a 2 h incubation period in a non-invasive closed system immediately before and after cryopreservation. Post-thaw survival was assessed by development in vitro during a 48 h culture period. Survival rates and oxidative metabolism after freeze/thawing were similar in embryos of the two developmental stages. However, after freeze/thawing, the rate of CO2 production of in vitro produced embryos was reduced to one half of their pre-freeze levels and was associated with poor survival rates. In vivo collected embryos had a significantly better tolerance to freezing and higher survival rates. However, when in vivo embryos were exposed to in vitro culture conditions, the rates of CO2 production and survival were significantly reduced. Pre-freeze embryo quality affected post-thaw in vitro development and metabolic activity markedly in embryos produced in vitro or pre-exposed to in vitro culture conditions. While there was no relationship between pre-freeze levels of CO2 production and post-thaw in vitro embryo development, all embryos which developed in vitro after freezing/thawing retained at least 58% of the pre-freeze levels of CO2 production regardless of their origin. Results of the present study indicate that embryos produced in vitro or pre-exposed to in vitro culture conditions are more sensitive to cryo-injury. This sensitivity is affected by embryo quality and is similarly reflected at the biochemical level. Determination of oxidative metabolism offers a feasibility for selection of viable morulae/blastocysts after freezing/thawing.     

Conversion of pregnenolone to progesterone by mouse morulae and blastocysts

When mouse morulae, early blastocysts and implanting blastocysts were cultured with tritiated pregnenolone, tritiated progesterone and its metabolites, 5 alpha-pregnan-3,20-dione and 3 alpha-hydroxy-5 alpha-pregnan-20-one, were isolated from the medium. It appears that mouse embryos can make progesterone from pregnenolone and the progesterone is quickly metabolized into various metabolites. These abilities increase with development. It is suggested that the mouse embryo can make progesterone and may regulate its own progesterone level for optimal development.     

Assessment of metabolism of equine morulae and blastocysts

Nutrient uptakes and metabolite production by equine morula and blastocyst stage embryos were determined by non-invasive microfluorometry. Equine morula took up equal amounts of both pyruvate and glucose. However, at the early blastocyst there was a small increase in glucose uptake and, by the expanded blastocyst stage, glucose was the predominant nutrient. Expanded blastocysts took up five times more glucose than pyruvate. Expanded blastocysts exhibited an exponential increase in glucose uptake and lactate production with respect to both diameter and surface area. As less than 50% of the glucose was accounted for by lactate production, the equine blastocyst appears to have a significant capacity to oxidize glucose. Embryos with a higher morphological grade consumed more nutrients than those with a poorer morphology. However, there was a large range in nutrient consumption within the highest grade blastocysts. This suggests that nutrient uptake may be useful as a viability marker of equine blastocysts.     

Heparan sulfate proteoglycan synthesis and metabolism by mouse uterine epithelial cells cultured in vitro

Characterization and metabolism of heparan sulfate glycosaminoglycans and proteoglycans (HSPGs) synthesized by primary cultures of mouse uterine epithelial cells are reported. HSPGs were detected in both the medium and in the cell-associated fraction, whereas glycosaminoglycans containing little or no protein (free glycosaminoglycans) were found primarily in the cell-associated fraction. The cell-associated HSPGs were relatively large (Kav = 0.1 on Superose 12), had a buoyant density in cesium chloride gradients of 1.45-1.55 g/ml, and contained heparan sulfate chains that fell into two size classes, exhibiting Kav values on Superose 12 of 0.2-0.5 and 0.7-0.8, respectively. The free glycosaminoglycan chains displayed a Kav on Superose 12 of 0.6-0.7. The secreted HSPGs were smaller (median Kav on Superose 12 of 0.28) than the cell-associated HSPGs. More than 90% of the cell-associated HSPGs contained hydrophobic portions, as evidenced by their ability to bind to octyl-Sepharose. In contrast, only 10-15% of the secreted HSPGs bound to octyl-Sepharose. HSPGs were detected at both apical and basal cell surfaces/extracellular matrices by indirect immunofluorescence in vitro and in utero and by accessibility to external proteases in vitro. It was estimated that 60-70% of the total cell-associated HSPGs were exposed at the cell surface. The HSPGs released from the cell surface by proteases were slightly smaller than the intact HSPGs and lacked the hydrophobic properties of the latter. These observations suggested that the cell surface HSPGs contain a small, hydrophobic domain that functions in the attachment of HSPGs to cells. The free glycosaminoglycans appeared to be primarily intracellular and were not secreted. The cell-associated HSPGs turned over rapidly (t1/2 = 1.5 h) and appeared to be the precursors to the free glycosaminoglycans. Metabolic turnover of the free glycosaminoglycan pool was a relatively slow process (t1/2 = 10-12 h).(ABSTRACT TRUNCATED AT 400 WORDS)     

Whole protein uptake and metabolism by mouse blastocysts

Preimplantation mouse embryos take up whole 125I-labelled BSA from their environment. In blastocysts this uptake was temperature-sensitive and reversibly inhibited by trypan blue: properties consistent with an endocytotic mechanism. The uptake kinetics indicate that a saturable component predominates at low protein concentrations, but a non-saturable component is the major uptake route at higher concentrations. This suggests that BSA is pinocytosed probably bound to the membrane and dissolved in the bulk solvent phase. The rate of uptake, equivalent to about 5 pl/min/blastocyst was similar to that reported for non-saturable glycine uptake. In blastocysts the protein is degraded to acid-soluble products. At reported genital tract fluid protein concentrations this would represent a significant contribution to the embryonic pool of fixed nitrogen.     

Implantation and invasiveness of mouse blastocysts on uterine monolayers

We have utilized monolayers of mouse uterine cells as a substratum for blastocyst implantation in vitro. In this system, blastocysts attach, and trophoblast cells initially grow out in an invasive manner, displacing the cells of the monolayer. A similar phenomenon is observed when any of a number of established cell types constitute the monolayer. After 5 to 6 days in culture, trophoblast cells lose their invasive capacity, although viability is unaffected. These events appear to be analogous to those taking place during implantation in utero or in ectopic sites. After treatment with dextran-norit, progesterone and estrogen can no longer be detected in fetal calf serum by a sensitive radioimmunoassay. Nevertheless, blastocysts can implant normally in medium supplemented with treated serum, indicating the likelihood that, unlike implantation in vivo, progesterone and estrogen are not required for the analogous event in vitro.     

A model for implantation: coculture of blastocysts and uterine endometrium in mice

One of the limitations in embryo implantation research is the lack of an available in vitro model that faithfully replicates embryo-uterine interactions. In previous studies, embryos were cultured on a monolayer of either uterine epithelial cells or extracellular matrix substratum on which embryos could adhere and outgrow. However, these models failed to display embryonic invasion, primarily because of the shortage of critical structural and molecular supports that are available in vivo. In the present study, we used intact mouse uterine endometrium collected on Day 4 of pregnancy and placed in contact with blastocysts to initiate coculture experiments in a defined medium at the air-liquid interface. The culture medium was composed of Ham F-12/Dulbecco modified Eagle medium (1:1), 30% fetal calf serum, 63.5 nmol/L of progesterone, 7.14 nmol/L of estradiol-17beta, 100 mug/ml of insulin, and 20 ng/ml of epidermal growth factor, whereas the incubation condition was mixed air of 50% oxygen, 5% carbon dioxide, and 45% nitrogen with a humidity of greater than 90% at 37 degrees C. Our observations from 24 h of culture clearly demonstrated that embryos were capable of attachment to the uterine endometrium and displayed partial invasion into the endometrial stroma. Interestingly, no outgrowth of trophoblasts on the surface of uterine endometrium was seen, but embryos exhibited a pole-specific attachment. Overall, this model is capable of demonstrating a true invasion of embryo within the endometrial stroma and may be suitable in studies related to early embryo implantation.     

Effects of prostaglandins E-2 and F-2 alpha on the metabolism of [U-14C]glucose by mouse morulae-early blastocysts in vitro

During 5-h culture in the presence of radioactive glucose, PGE-2 (10 micrograms/ml) significantly inhibited incorporation of glucose into the acid-soluble glycogen pool. PGE-2 at 1 and 10 micrograms/ml and PGF-2 alpha at 1 microgram but not 10 micrograms/ml stimulated incorporation of glucose into non-glycogen macromolecules during culture. However, the utilization of acid-soluble glycogen and other biochemical pools was not affected by the presence of PGs in the medium during 24-h chase culture of pulse-labelled embryos. Carbon dioxide production was significantly suppressed in the presence of PGs but accumulation of lactate was not affected. The results indicate that PGE-2 and PGF-2 alpha, in physiological concentrations, directly influence the metabolism of glucose by preimplantation embryos.     

Estrogen induces N-linked glycoprotein expression by immature mouse uterine epithelial cells

Characterization of complex glycoconjugates and the effects of estrogen on their expression in immature mouse uterine epithelial cells are reported. The secreted fraction contained nonanionic, O-linked lactosaminoglycan (LAG)-bearing proteins of Mr 30,000-40,000 as well as anionic, O-linked, LAG-bearing glycoproteins with very high apparent molecular weight (greater than 670K). Heparan sulfate (HS) proteoglycans and HS linked to little or no protein were found in the secreted fraction as well. A very similar array of glycoconjugates was found in the nonhydrophobic fraction of cell-associated macromolecules. In addition, the hydrophobic cell-associated fraction contained nonanionic, LAG-bearing glycoproteins of approximately 250K, anionic LAG-bearing glycoproteins distributing over a wide range of molecular weights, and HS proteoglycans with median molecular weights of approximately 250K. In contrast to the glycoproteins produced by their mature counterparts, virtually all glycoproteins produced by immature cells were O-linked. Estrogen treatment of immature mice caused uterine epithelial cells to secrete anionic, high molecular weight (greater than 670K) N-linked glycoproteins as a major product. These estrogen-responsive glycoproteins did not appear to contain LAGs. Estrogen treatment also markedly decreased the proportion of all hydrophobic glycoconjugates in the cell-associated fraction. Collectively, these observations indicate that one aspect of the estrogen-induced maturation of uterine epithelial cells is the stimulation of N-linked glycoprotein synthesis and secretion. Furthermore, stimulation of N-linked glycoprotein synthesis by itself is insufficient to support N-linked LAG glycoprotein production.     

Quantification of epithelial cells in coculture with fibroblasts by fluorescence image analysis

BACKGROUND: To demonstrate that senescent fibroblasts stimulate the proliferation and neoplastic transformation of premalignant epithelial cells (Krtolica et al.: Proc Natl Acad Sci USA 98:12072-12077, 2001), we developed methods to quantify the proliferation of epithelial cells cocultured with fibroblasts. METHODS: We stained epithelial-fibroblast cocultures with the fluorescent DNA-intercalating dye 4,6-diamidino-2-phenylindole (DAPI), or expressed green fluorescent protein (GFP) in the epithelial cells, and then cultured them with fibroblasts. The cocultures were photographed under an inverted microscope with appropriate filters, and the fluorescent images were captured with a digital camera. We modified an image analysis program to selectively recognize the smaller, more intensely fluorescent epithelial cell nuclei in DAPI-stained cultures and used the program to quantify areas with DAPI fluorescence generated by epithelial nuclei or GFP fluorescence generated by epithelial cells in each field. RESULTS: Analysis of the image areas with DAPI and GFP fluorescences produced nearly identical quantification of epithelial cells in coculture with fibroblasts. We confirmed these results by manual counting. In addition, GFP labeling permitted kinetic studies of the same coculture over multiple time points. CONCLUSIONS: The image analysis-based quantification method we describe here is an easy and reliable way to monitor cells in coculture and should be useful for a variety of cell biological studies.     

Successful production of piglets derived from vitrified morulae and early blastocysts using a microdroplet method

This study was conducted to determine the efficiency of vitrification using the microdroplet (MD) method for early stage porcine embryos. Embryos at compacted morulae to early blastocyst stage were vitrified in a vitrification solution containing 40% (v/v) ethylene glycol, 0.6M sucrose and 2% (w/v) polyethylene glycol in M2 (ESP) without any pretreatment. The equilibration and dilution were carried out in third and fourth steps, respectively, at 38 degrees C. The survivability of the cryopreserved embryos was assessed for both in vitro culture (Experiment 1) and by embryo transfer (Experiment 2). In Experiment 1, the embryos were vitrified within a microdroplet or 0.25 ml straw (ST) and fresh embryos were used as a control group. The survival rates after 24h culture in the MD, ST and control groups were 21/23, 14/20 and 20/20, respectively. The hatching rates of the embryos after 48 h incubation were 14/23, 4/20 and 16/20, respectively. In Experiment 2, 171 vitrified embryos were transferred to 5 recipient gilts, and 17 healthy piglets were produced from 2 recipients (3 recipients aborted) in Group 1. In Group 2, 81 vitrified embryos and 16 fresh embryos in total were transferred to 4 recipient gilts, and 10 healthy piglets from the vitrified embryos were produced from 3 recipients. These results indicated that porcine embryos of compacted morulae to early blastocyst stage can survive cryopreservation using the microdroplet method without any special intracellular manipulation or treatment.     

Early embryonic development in vitro by coculture with oviductal epithelial cells in pigs

This experiment was designed to evaluate the ability of three different somatic cell cultures to promote development of early cleavage stage pig embryos. A total of 245 2-cell, 4-cell, 8-cell, and 16-cell pig embryos were cocultured for 5 days with porcine oviductal epithelial cells (POEC), porcine fetal fibroblast monolayer (PEF), a combined POEC and PEF coculture system (PEF-POEC), or Dulbecco's Modified Eagle Medium alone (DMEM). Embryos were collected at slaughter from the reproductive tracts of superovulated prepubertal gilts. Embryos were recovered, evaluated, and randomly placed in one of the four treatment groups. POEC were recovered from oviductal flushes, washed, and placed in 24-well plates. PEF were obtained from 30-day to 60-day fetuses and established in culture. Finally, PEF-POEC consisted of a confluent monolayer of PEF in the bottom of 24-well plates also containing a Costar semipermeable membrane chamber with POEC in it. Embryos were evaluated every 24 h to determine stage of development. More (p less than 0.05) embryos developed to blastocysts in POEC (70% and 54%, respectively) and PEF-POEC (67% and 61%, respectively), than in either DMEM (16% and 2%, respectively) or PEF (27% and 23%, respectively). However, development of embryos did not differ (p less than 0.05) for POEC and PEF-POEC. These data indicate the presence of a primary culture of POEC promotes in vitro development of early cleavage stage pig embryos.     

Effects of hyperketonemia on mouse embryonic and fetal glucose metabolism in vitro

The ketone body beta-hydroxybutyrate (B-OHB) has been shown to be teratogenic to early-somite mouse embryos, although the mechanism responsible for these defects has not been determined. In an attempt to define this mechanism, the present study investigated the normal pattern of both glucose and B-OHB utilization in the developing embryo and fetus. Furthermore, the metabolic interaction of these two substrates, i.e., the potential for B-OHB to inhibit glycolysis, was studied. All studies compared early and late embryonic periods of development as well as fetal stages. The results show that the early embryo relies almost exclusively on glycolysis for energy metabolism and suggests that there is an increasing importance of the Krebs cycle with increasing gestational age. Similarly, the early embryo has a low capacity to metabolize B-OHB, whereas later gestational stages display a greater rate of utilization. Finally, there appears to be no inhibition of glycolysis by B-OHB (via so-called "substrate interactions") during early embryonic stages. However, the compound significantly inhibits glycolysis during later embryonic and fetal stages. These studies suggest that the teratogenicity of B-OHB in the early embryo is not due to its effects on modulating glycolysis, although this mechanism may be operating at later periods of gestation.