Effect of high concentrations of glucose on differentiation of rat trophoblast cells in vitro.

AIMS/HYPOTHESIS: Previous studies have shown that diabetic placentas are characterized by structural and biochemical anomalies, including defects in the differentiation of trophoblasts. In this study, the Rcho-1 cell line was used to investigate the impact of high glucose concentrations on different markers of differentiation of rat trophoblast cells in giant cells (endoreduplication, invasive phenotype and endocrine phenotype). MATERIALS: Rcho-1 cells were incubated for 12 days in medium supplemented with different concentrations of glucose and 10% horse serum to optimize differentiation. The cells were examined for the proportion of nuclei showing signs of apoptosis. The effect of high glucose was investigated on the endoreduplication process, on invasive phenotype (secretion of gelatinase B) and on endocrine phenotype (expression of placental lactogen I (PL-I) and II (PL-II) and progesterone secretion). RESULTS: Apoptosis was not induced by high glucose in Rcho-1. The number of cells was higher in the cultures exposed to high glucose (p<0.05) and their nuclei contained more DNA compared with control cells (p<0.001), while their nuclear size was smaller (p<0.001). Gelatinase B secretion increased during differentiation but no difference was found when gelatinase B secretion from trophoblasts exposed to high glucose was compared with the control cells. Rcho-1 cell cultures showed an increase in PL-I and PL-II mRNA expressions during differentiation and which was not affected by high glucose. Progesterone secretion increased during differentiation in control cultures. However, this increase was abolished when trophoblasts were cultured in high glucose. CONCLUSIONS/INTERPRETATION: Our data suggest that high glucose influences the endoreduplication process and the steroidogenesis during differentiation of rattrophoblasts.

Impact of adding 5.5 mM glucose to SOF medium on the development, metabolism and quality of in vitro produced bovine embryos from the morula to the blastocyst stage.

Although toxic for early stages of embryo development, glucose is a physiological metabolic substrate at the morula and blastocyst stages. We evaluated the effect of adding 5.5 mM glucose from the morula stage on bovine blastocyst development and quality. In vitro matured and fertilised bovine oocytes were cultured in modified Synthetic Oviduct Fluid medium containing 5% fetal calf serum, but without added glucose, up to day 5 post-insemination (pi). Morulae were selected and further cultured in the presence or absence of 5.5 mM glucose. Blastocyst and hatched blastocyst rates were recorded. Oxygen, glucose and pyruvate uptakes as well as lactate release were evaluated. The quality of the resulting blastocysts was evaluated by the cell allocation to the inner cell mass (ICM) and trophectoderm (TE) and by the apoptotic index. Adding glucose increased the blastocyst rate at day 8 pi (80% vs 65%) but had no impact on hatching rate (25% vs 28%). A 22% decrease in oxygen uptake was observed in the presence of glucose, concomitant with an increase in lactate release, although no change was observed in pyruvate uptake. A slight decrease in blastocyst cell number was observed at day 7 in the presence of glucose while neither the ICM/TE cell ratio nor the apoptotic index were affected. In conclusion, adding 5.5 mM glucose from the morula stage has a limited impact on blastocyst rate and quality although important modifications were observed in embryo metabolism. It remains to be determined whether those modifications could influence embryo viability after transfer.

Increased cell death in mouse blastocysts exposed to high D-glucose in vitro: implications of an oxidative stress and alterations in glucose metabolism.

AIMS/HYPOTHESIS: Signs of apoptosis have been observed in rodent blastocysts exposed to high d-glucose concentrations in vitro. The mechanism underlying the detrimental influence of glucose remains to be identified. It has been postulated that high d-glucose concentrations induced oxidative stress in rat post-implantation embryos in vitro. A decreased glucose uptake has also been implicated in the embryotoxicity of glucose in pre-implantation mouse embryos. We examined whether the high incidence of cell death in high d-glucose-treated embryos was associated with a disrupted redox status and with alterations in glucose transport and metabolism. METHODS: After blastocysts were incubated in different concentrations of d-glucose for 24 h, they were examined for the proportion of nuclei showing signs of chromatin degradation using the TUNEL technique, for the generation of reactive oxygen species and for the mitochondrial membrane potential using specific fluoroprobes and the confocal microscopy. Glucose transport and metabolism were assessed using radiolabelled 3-O-methylglucose and glucose, respectively. RESULTS: Compared to the control blastocysts, high d-glucose-treated embryos showed a higher incidence of TUNEL-positive nuclei and reactive oxygen species generation principally in the inner cell mass cells. Decreased glucose transport and glycolytic activity but unmodified pentose phosphate pathway activity were detected in these embryos. CONCLUSION/INTERPRETATION: Incubation in high d-glucose concentrations in vitro increased cell death, induced oxidative stress and decreased glucose transport and metabolism in mouse blastocysts. As only glycolysis was affected, however, we suggest that metabolic inhibition occurred downstream glucose transport and glucose-6-phosphate formation.

Decreased expression of fibroblast growth factor-4 and associated dysregulation of trophoblast differentiation in mouse blastocysts exposed to high D-glucose in vitro.

AIMS/HYPOTHESIS: Paracrine interactions are thought to operate between the inner cell mass and trophectoderm cell lineages to co-ordinate their expansion and differentiation during embryo implantation. We aimed to determine whether hyperglycaemia could interfere with this regulatory process. METHODS: Mouse blastocysts were pre-exposed to either control or high concentrations of d-glucose for 24 h in vitro and tested for their ability to attach and spread over a fibronectin-coated culture substrate. Quantitative immunocytochemistry was done on blastocysts to assess the protein expression of Fibroblast Growth Factor-4, a growth factor preferentially produced by the inner cell mass and thought to restrict trophectoderm differentiation into giant trophoblasts. Experiments were then done combining the pre-exposure to high D-glucose with the addition of recombinant fibroblast growth factor-4. RESULTS: Compared with control blastocysts, high D-glucose pre-treated embryos were found to form 18 % larger trophoblast outgrowths. These blastocysts also showed a 30 % reduction in the expression of fibroblast growth factor-4 protein by inner cell mass cells as they were outgrowing. The trophoblast surface area per outgrowth and the trophoblast nuclear area were corrected when the addition of recombinant fibroblast growth factor-4 was combined with the pre-exposure to high D-glucose. CONCLUSION/INTERPRETATION: The data suggests that trophectoderm differentiation is impaired by high D-glucose and that this effect is secondary to a deficiency in fibroblast growth factor-4 protein in the inner cell mass. These observations add a novel perspective to the study of the peri-implantation embryopathy associated with maternal diabetes

Control of trophectoderm differentiation by inner cell mass-derived fibroblast growth factor-4 in mouse blastocysts and corrective effect of FGF-4 on high glucose-induced trophoblast disruption.

Previous studies have suggested that fibroblast growth factor-4 (FGF-4) may be a paracrine signal used by inner cell mass (ICM) cells to maintain adjacent trophectoderm (TE) cells in an undifferentiated state. In the present work, immunocytochemical analysis of mouse blastocysts confirmed that FGF-4 was predominantly detected in the ICM before and after spreading over a fibronectin-coated culture substrate. Addition of human recombinant FGF-4 did not influence morphological progression, cell allocation and proliferation in ICM and TE lineages or mitosis and karyorhexis frequencies during blastocyst expansion. Addition of FGF-4 to outgrowing blastocysts, in contrast, induced a significant decrease in the surface of the trophoblast outgrowths formed by the TE cells and in the proportion of giant trophoblasts per outgrowth. The fact that blastocysts display excessive trophoblast expansion and spreading over their culture substrate upon pre-exposure to high concentrations of glucose in vitro was used to further assess the regulatory effect of FGF-4. Addition of FGF-4 was indeed found to fully neutralize the disruptive impact of high glucose on trophoblast outgrowths. Altogether, our data indicate that ICM-derived FGF-4 participates actively in the regulation of trophoblast development.

Vascular endothelial growth factor and placenta growth factor concentrations in Down's syndrome and control pregnancies.

Vascular endothelial growth factor (VEGF) and placenta growth factor (PLGF) are considered to play important roles in angiogenesis and vascular permeability during placental development. Since trisomy 21 placentae show trophoblastic hypoplasia and hypovascularity, we investigated PLGF and VEGF synthesis in Down's syndrome pregnancies. Maternal serum was collected from 102 euploid and 24 trisomy 21 pregnancies between 15 and 20 weeks gestation and tested for these two factors by enzyme-linked immunosorbent assays. Protein extracts from 15 normal and six trisomy 21 placentae were also tested. VEGF was not detected in maternal serum, while PLGF increased significantly with gestational age. Serum PLGF, transformed as a multiple of the gestational age median (MoM), in Down's syndrome pregnancies was significantly lower than in euploid controls (mean 0.67 +/- 0.043 MoM versus 1.00 +/- 0.047 MoM, analysis of variance F = 11.605, P < 0.001 ). Both VEGF and PLGF were detected in placental protein extracts without variation according to gestational age. Down's syndrome placentae had significantly less PLGF compared to normal placentae (Mann-Whitney, P < 0.05 ) but no difference was observed in placental VEGF content (Mann-Whitney, P = 0.94 ). Considering the biological properties of PLGF, this decrease may provide new insights into the mechanism(s) leading to the structural and functional anomalies described in trisomy 21 placentae.

Dysregulation of the cytokine network in the uterus of the diabetic rat.

Insulin-dependent (type I) diabetes is an auto-immune disorder that produces secondary complications in numerous non-immunological systems. Changes in the synthesis and action pattern of several cytokines have been associated with the development of these alterations. Based on the clinical facts that the pregnant and non-pregnant functions of the reproductive system are also disrupted by diabetes, our laboratory has decided to concentrate its research activities on the hypothesis that cytokines may be implicated in the uteropathy and embryopathy associated with the metabolic disorder. This review article summarizes our major findings concerning the synthesis of TNF-alpha and IL-1beta in the uterus of diabetic rats, and in cultures of rodent uterine cells upon their exposure to high concentrations of glucose. The paper also reviews evidence that both the peri-implanting embryo and the epithelial cell layer lining the uterine lumen are targets for the deleterious influence of excess TNF-alpha. If confirmed in the uterus of diabetic patients, these observations may explain how cytokines contribute to the dysregulation of crucial reproductive events like menstruation and embryo implantation in humans.

Inhibin subunits mRNA expression level in human placenta from normal and Down's syndrome pregnancies.

In order to study the mechanisms leading to increased inhibin A and activin A in maternal serum with advancing gestation and increased inhibin A in Down's syndrome pregnancy, the mRNA expression level of inhibin and activin subunits was quantitatively studied in human placenta using Northern blot and semiquantitative RT-PCR analysis. The corresponding protein level was also determined by specific ELISAs for inhibin A, inhibin B, activin A and inhibin pro alphaC in placental extracts. Normal placenta (n=27) showed a slight significant increase in alpha and betaA subunit mRNA levels in term pregnancy, with no change of the corresponding protein level. Placenta from Down's syndrome pregnancies (n=6) did not differ from controls in either mRNA expression or corresponding protein levels. In conclusion, there is a dissociation between inhibin and activin subunit mRNA levels and the corresponding protein levels in maternal serum, and Down's syndrome inhibin A increase is not explained by mRNA expression upregulation. In an additional study, ovarian cortex tissue from term pregnancies (n=3) were examined. Only the alpha subunit mRNA was expressed, at a higher level than in the placenta, suggesting that ovary could be a source of inhibin pro alphaC during pregnancy.

Identification of caspase-3 and caspase-activated deoxyribonuclease in rat blastocysts and their implication in the induction of chromatin degradation (but not nuclear fragmentation) by high glucose.

Previous investigations have shown that maternal diabetes impairs rodent embryo development during the earliest phase of gestation. Exposure to high concentrations of glucose before implantation results in a decrease in the number of cells per embryo and in a concomitant increase in two nuclear markers of apoptosis, chromatin degradation and nuclear fragmentation. In the present study, we show that two intracellular effectors of apoptosis, caspase-3 and caspase-activated deoxyribonuclease (CAD), are involved in the embryotoxicity of high glucose. Using reverse transcription-polymerase chain reaction and immunocytochemistry, we first demonstrated that these two effectors were expressed in rat blastocysts. The two effectors were detected in all the cells of the blastocysts and the immuno-signals were excluded from the nuclei. Rat blastocysts were incubated for 24 h in either 6 mM or 28 mM glucose in the presence or absence of specific inhibitors (DEVD-CHO [10 microM] against caspase-3 and aurin [1 microM] against CAD). After incubation, blastocysts were examined for the proportion of nuclei showing signs of chromatin degradation or nuclear fragmentation. Addition of DEVD-CHO or aurin was found to inhibit the increase in chromatin degradation induced by high glucose. None of these two inhibitors prevented the increase in nuclear fragmentation triggered by excess glucose. Our data indicate that chromatin degradation and nuclear fragmentation are two nuclear damages that are induced separately by high glucose in rat blastocysts. Chromatin degradation is apparently mediated by the activation of caspase-3 and CAD.

Expression and role of Bcl-2 in rat blastocysts exposed to high D-glucose.

Bcl-2 mRNA expression was detected in rat blastocysts by in situ hybridization. The distribution of mRNA expression was rather heterogenous, with approximately 2% of high-expressing cells. In vitro exposure to 28 mmol/l D-glucose for 24 h resulted in a significant increase in the proportion of these cells compared with control embryos in either 6 mmol/l D-glucose or 28 mmol/l D+L-glucose. Heterogeneity in the expression of Bcl-2 was also observed at the protein level by immunocytochemistry. Exposure to 28 mmol/l D-glucose significantly increased the incidence of chromatin degradation (karyolysis) and nuclear fragmentation (karyorhexis), two nuclear markers of apoptosis in rat blastocysts. When two different antisense oligodeoxynucleotides designed to block Bcl-2 expression were added to 28 mmol/1 D-glucose, the incidence of karyolysis (but not karyorhexis) was increased compared with embryos in 28 mmol/l D-glucose alone. These data suggest that Bcl-2 is involved in the protective response against the induction of karyolysis in blastocysts on their exposure to high concentrations of D-glucose in vitro, whereas karyorhexis appears to result from the activation of an intracellular pathway that is independent of Bcl-2.

Activation of nuclear factor kappaB and induction of apoptosis by tumor necrosis factor-alpha in the mouse uterine epithelial WEG-1 cell line.

In order to better understand how tumor necrosis factor (TNF)-alpha may contribute to the local regulation of uterine cell death, cultures of mouse uterine epithelial WEG-1 cells were exposed to TNF-alpha and observed at different time intervals. Earliest decrease in cell viability was observed after 31 h of exposure to 50 ng/ml mouse TNF-alpha and was associated with the expression of several markers of apoptosis. Treatment with human TNF-alpha or addition of a neutralizing antibody against TNF-alpha receptor protein 80 to mouse TNF-alpha resulted in attenuated induction of apoptosis, suggesting that coengagement of the two TNF-alpha receptor types is required for maximal impact. Ceramide analogs failed to replicate the effect of TNF-alpha and the stress-activated protein kinase signaling pathway was not activated by the cytokine. Treatment with mouse TNF-alpha resulted in an increase in nuclear factor (NF)kappaB activity that receded after 24 h. The impact of human TNF-alpha on NFkappaB activation was more moderate. Addition of either one of three different inhibitors of NFkappaB (SN50, PDTC, and A771726) to mouse TNF-alpha sensitized WEG-1 cells to the toxicity of the cytokine. Our data suggest that WEG-1 cells initiate their response to TNF-alpha with an increase in NFkappaB activation that may have transiently biased these cells toward cell death resistance.

Inhibin and activin production and subunit expression in human placental cells cultured in vitro.

Inhibins and activins are dimeric proteins, with each subunit being one of three related protein subunits (alpha, betaA or betaB). The mRNA levels of these subunits were studied quantitatively during in-vitro differentiation of human cytotrophoblast cells into syncytium, using Northern blot analysis and semi-quantitative reverse transcription-polymerase chain reaction (RT-PCR) analysis. The corresponding protein concentrations were determined by specific enzyme-linked immunosorbent assays for inhibin A, B, pro alphaC and activin A in cellular protein extracts and culture medium (n = 5). Immunofluorescence studies showed syncytium formation after 48 h. The alpha subunit was present before plating and increased at 48 h (P<0.001) while the betaA subunit was weak before plating and increased at 24 h. The betaB subunit was not detected. With respect to corresponding protein synthesis, inhibin A (alpha + betaA) had risen after 48 h in cellular protein extract and after 72 h in culture medium, while activin A (betaA + betaB) was detected after 24 h, with no significant variations in culture medium. There was a good correlation between inhibin A and alpha subunit expression (r = 0.736, P<0.001), as well as between activin A and betaA subunit expression (r = 0.755, P<0.001). This study showed that mRNA expression parallels protein synthesis of inhibin and activin in trophoblast cells. Inhibin A synthesis appears to be dependent on alpha subunit mRNA expression, rather than on the betaA subunit which controls activin A synthesis. This study has also shown that isolated cytotrophoblast cells do not produce dimeric inhibin. However, during the transformation of cytotrophoblast cells into syncytium, betaA subunit mRNA expression may be an indicator of cell aggregation, while alpha subunit mRNA expression may be an indicator of cell fusion.

The human blastocyst regulates endometrial epithelial apoptosis in embryonic adhesion.

The implanting blastocyst must appose and adhere to the endometrial epithelium and, subsequently, invade it. Locally regulated uterine epithelial apoptosis induced by the embryo is a crucial step of the epithelial invasion in rodents. To address the physiological relevance of this process in humans, we investigated the effect of single human blastocysts on the regulation of apoptosis in cultured human endometrial epithelial cells (hEEC) in both apposition and adhesion phases of implantation. Here, we report a co-ordinated embryonic regulation of hEEC apoptosis. In the apposition phase, the presence of a blastocyst rescues hEEC from the apoptotic pathway. However, when the human blastocyst adheres to the hEEC monolayer, it induces a paracrine apoptotic reaction. Fas ligand (Fas-L) was present at the embryonic trophoectoderm. Fas was localized at the apical cell surface of hEEC, and flow cytometry revealed that 60% of hEEC express Fas. Neutralizing adhesion assays revealed that the Fas/Fas-L death system may be an important mechanism to cross the epithelial barrier, which is crucial for embryonic adhesion, and the manipulation of this system could have potential clinical implications as an interceptive mechanism.

Peri-implantation embryopathy induced by maternal diabetes.

Almost 10 years ago, it was proposed that the packaging of all devices and supplies used by diabetic patients for routine care should carry this warning label: 'Poor control of diabetes may cause birth defects. See your physician before becoming pregnant'. The present article reviews the evidence supporting the hypothesis that in mouse and rat experimental models, maternal pre-conceptional diabetes induces severe developmental alterations in embryos before and at implantation. The review (i) summarizes observations on embryos exposed to maternal diabetes in utero, (ii) summarizes data obtained by culturing embryos in vitro in the presence of high concentrations of D-glucose, (iii) discusses the possibility that alterations in the release of cytokines and growth factors by uterine cells contribute to early embryopathy and (iv) summarizes the evidence that apoptosis, a process of normal embryonic development, may be disrupted in blastocysts exposed to diabetic conditions in vivo and in vitro.

Apoptosis in rodent peri-implantation embryos: differential susceptibility of inner cell mass and trophectoderm cell lineages--a review.

Inner cell mass (ICM) and trophectoderm cell lineages diverge early in cleavage in response to a complex combination of cellular and molecular determinative events. The resulting differences in metabolic requirements, cell positioning and micro-environments are considered as some of the major causes underlying the differential sensitivity of ICM and trophectoderm cell lines to embryotoxic agents. In most instances, ICM cells appear less resistant to disruption than trophectoderm cells, and past observations suggest that over-stimulation of apoptosis is probably one of the mechanisms leading to selective ICM depletion at the blastocyst stage. Disproportionate deficiency in this lineage below a certain threshold level may then prevent the ICM core from providing sufficient prefetal stem cells during gastrulation and from sending regulatory signals to the trophectoderm, leading to compromised post-implantation development. The aim of this review article is to discuss the above observations and to show the value of the impact of hyperglycaemia on blastocyst metabolism and development as an exciting model for further studies.

Interleukin 1beta mediates the effect of high D-glucose on the secretion of TNF-alpha by mouse uterine epithelial cells.

Previous observations have shown that tumour necrosis factor alpha (TNF-alpha) synthesis is increased in the uterus of diabetic rats and that the epithelial layer lining the uterine lumen is the major site of TNF-alpha over-production. In the present study, TNF-alpha secretion was found to be stimulated by high D-glucose levels in primary cultures of mouse uterine luminal cells but not in cultures of the mouse uterine epithelial WEG-1 cell line. Experiments were performed to investigate the possibility that non-epithelial cells may mediate the influence of high D-glucose on TNF-alpha production by uterine epithelial cells. Immunocytochemical analysis revealed the reproducible presence of a small proportion of macrophages in primary cultures. Macrophages of the RAW 264.7 cell line were found to secrete more interleukin (IL)-1beta (but not TNF-alpha) when cultured in high D-glucose. TNF-alpha production in WEG-1 cells was increased upon exposure to IL-1beta and both protein kinase-C and tyrosine kinase pathways appeared to be involved in TNF-alpha stimulation. Addition of IL-1 receptor antagonist to primary cultures partially abrogated the effect of high D-glucose. Since WEG-1 cells do not produce IL-1beta, the data lend support to the hypothesis that uterine epithelial cells synthesize high levels of TNF-alpha in response to hyperglycaemia via an increase in IL-1beta secretion by stromal macrophages.

Apoptosis at the time of embryo implantation in mouse and rat.

The aim of this review is to summarize the information currently available regarding the occurrence of apoptosis in the developing embryo and in the receptive uterus during the peri-implantation period of gestation. Cell death is detected in the inner cell mass of late pre-implantation embryos as the result of an eliminative process that helps trim the embryonic cell lineages of surplus or dysfunctional stem cells. Cell death is also detected in the epiblastic core of early post-implantation embryos, where the process is implicated in the formation of the pro-amniotic cavity. On the maternal side, uterine epithelial cells situated around the attachment site undergo cell death during the initial phase of implantation in order to facilitate embryo anchorage and access to maternal blood supply. Uterine stromal cells closest to the implantation chamber first transform into decidual cells and then commit suicide to make room for the rapidly growing embryo. Although apoptosis is well recognized as a crucial determinant of successful peri-implantation development, our understanding of the cellular and molecular mechanisms regulating this process clearly lags behind the comprehension of cell death control in other systems.

Tumor necrosis factor alpha decreases the viability of mouse blastocysts in vitro and in vivo.

Mouse blastocysts were exposed for 24 h to various concentrations of recombinant mouse tumor necrosis factor alpha (TNFalpha) and observed for their capacity to implant in vitro on a fibronectin-coated substrate or to develop in vivo after their transfer into surrogate females. Compared with findings in control blastocysts, exposure to TNFalpha resulted in a significant reduction in the average number of cells in the inner cell mass (ICM) lineage. This effect was associated with a significant increase in the frequency of cells identified as engaged in apoptosis by means of the terminal deoxynucleotidyl transferase-mediated dUTP nick end-labeling technique. No difference was found in the incidence of nuclear fragmentation between control and TNFalpha-exposed blastocysts. When TNFalpha-pretreated blastocysts were allowed to implant in vitro, significantly fewer embryos were able to maintain a structured ICM cluster at the center of the trophectoderm outgrowth. Although no difference was found in the average surface area of the outgrowths, implants derived from TNFalpha-treated blastocysts contained significantly fewer nuclei than implants from control embryos. After transfer into recipient mice, TNFalpha-pretreated blastocysts implanted at about the same rate as control embryos, but a significantly higher rate of resorption was found among fetuses after exposure to the cytokine. In addition, the weight of the surviving fetuses was significantly lower than for control fetuses. These data indicate that the impact of TNFalpha on blastocysts is specifically aimed at the ICM lineage and that TNFalpha decreases the ability of embryos to differentiate into fetuses after implantation.

Modulation of paracetamol metabolism by Kupffer cells: a study on rat liver slices.

Recent studies support the hypothesis that non parenchymal cells (mainly macrophages) may play a role in the metabolism and cellular effects of paracetamol. In order to investigate this hypothesis, male Wistar rats were intravenously injected with either 7.5 mg/kg gadolinium chloride (Gd+) or NaCl 0.9% (Gd-). The treatment with GdCl3 decreased the number and the function of Kupffer cells in liver tissue, as assessed by the histological examination of the liver after colloidal carbon injection in the portal vein. Precision-cut liver slices (PCLS) were prepared from both groups of rats and cultured for 8h in Waymouth's medium in the presence and absence of 5 mM paracetamol. Interestingly, PCLS obtained from Gd+ rats exhibited a lower release of tumor necrosis factor (TNF-alpha) and a better viability than PCLS from control (Gd-) rats. Incubation with paracetamol led to a decreased glycogen level in liver slices from Gd+ or Gd-, without modifying neither liver morphology nor ATP level nor LDH release. A higher proportion of paracetamol glucuronide, was secreted from the slices obtained from Gd+ rats. These data suggest that Kupffer cells could affect the viability of PCLS in culture and are involved in the regulation of phase II metabolism in the adjacent hepatocytes. We propose that PCLS in culture is a suitable model to elucidate the biochemical mechanism underlying the modulation of metabolism occurring through hepatocytes-Kupffer cells interactions.

Impact of tumor necrosis factor alpha on mouse embryonic stem cells.

Previous studies have shown the adverse impact of the cytokine tumor necrosis factor alpha (TNFalpha) on the development of the inner cell mass in mouse blastocysts. In the present study, two embryonic stem (ES) cell lines were used to further investigate the action of TNFalpha. The expression of TNFalpha receptors in ES cells was tested by reverse transcription-polymerase chain reaction and Northern blot analysis. Transcripts encoding the two distinct receptor isoforms were detected in these cells. Using different approaches, our data showed a TNFalpha dose-dependent decrease in the number of ES cells after 24 h of exposure. Simultaneous blocking of the two receptors with antagonist antibodies was needed to completely abrogate the inhibitory effect of the cytokine. Extensive DNA nicks (visualized by the terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick end-labeling [TUNEL] method), but not nuclear fragmentation, was found with a higher incidence in ES cells exposed to TNFalpha. The possibility that TNFalpha may stimulate ES cell differentiation was investigated with a test based on the expression of alkaline phosphatase. The results indicated that TNFalpha cannot over-ride the negative control exerted by leukemia inhibitory factor on differentiation. The opposite possibility, that TNFalpha blocks differentiation, was tested in suspended medium drops. In this system, TNFalpha was found to decrease the ability of ES cells to differentiate into embryoid bodies. In addition, expression of Rex-1, a marker gene for undifferentiated ES cells, was increased in ES cells exposed to TNFalpha. Thus our data support the hypothesis that TNFalpha is a significant (negative) effector of proliferation and differentiation in inner cell mass-derived ES cells.