Sources of amino acids for protein synthesis during early organogenesis in the rat. I. Relative contributions of free amino acids and of proteins

Assessment of Histiotrophic Nutrition Using Fluorescent Probes

Histiotrophic nutrition is a process whereby the rodent visceral yolk sac (VYS) internalizes exogenous macromolecules, degrades them, and sends the degradation products to the embryo. Quantification and visualization of histiotrophic nutrition can be accomplished using fluorescent tracer molecules such as fluorescein isothiocyanate-conjugated albumin (FITC-albumin). The methods are simple and can provide complimentary functional and structural information in studies of the effects of embryotoxicants on visceral yolk sac function.

Mono-2-ethylhexyl phthalate (MEHP) alters histiotrophic nutrition pathways and epigenetic processes in the developing conceptus

Histiotrophic nutrition pathways (HNPs) are processes by which the organogenesis-stage conceptus obtains nutrients, amino acids, vitamins and cofactors required for protein biosynthesis and metabolic activities. Nutrients are captured from the maternal milieu as whole proteins and cargoes via receptor-mediated endocytosis in the visceral yolk sac (VYS), degraded by lysosomal proteolysis and delivered to the developing embryo (EMB). Several nutrients obtained by HNPs are required substrates for one-carbon (C1) metabolism and supply methyl groups required for epigenetic processes, including DNA and histone methylation. Increased availability of methyl donors has been associated with reduced risk for neural tube defects (NTDs). Here, we show that mono-2-ethylhexyl phthalate (MEHP) treatment (100 or 250μM) alters HNPs, C1 metabolism and epigenetic programming in the organogenesis-stage conceptus. Specifically, 3-h MEHP treatment of mouse EMBs in whole culture resulted in dose-dependent reduction of HNP activity in the conceptus. To observe nutrient consequences of decreased HNP function, C1 components and substrates and epigenetic outcomes were quantified at 24h. Treatment with 100-μM MEHP resulted in decreased dietary methyl donor concentrations, while treatment with 100- or 250-μM MEHP resulted in dose-dependent elevated C1 products and substrates. In MEHP-treated EMBs with NTDs, H3K4 methylation was significantly increased, while no effects were seen in treated VYS. DNA methylation was reduced in MEHP-treated EMB with and without NTDs. This research suggests that environmental toxicants such as MEHP decrease embryonic nutrition in a time-dependent manner and that epigenetic consequences of HNP disruption may be exacerbated in EMB with NTDs.

Amino acid starvation induced by protease inhibition produces differential alterations in redox status and the thiol proteome in organogenesis-stage rat embryos and visceral yolk sacs

The process of embryonic nutrition in rodent conceptuses during organogenesis has been shown to involve a dominant histiotrophic mechanism where essential developmental substrates and micronutrients are supplied as whole maternal proteins or cargoes associated with proteins. The histiotrophic nutrition pathways (HNP) responsible for uptake and initial processing of proteins across maternal-conceptal interfaces involve uptake via receptor mediated endocytosis and protein degradation via lysosomal proteolysis. Chemical inhibition of either process can lead to growth deficits and malformation in the embryo (EMB), but selective inhibition of either HNP component will elicit a different subset of developmental perturbations. In vitro, whole embryo culture exposure of GD10 or GD11 rat conceptuses to the natural protease inhibitor, leupeptin, leads to significant reductions in all measured embryonic growth parameters as well as a myriad of other effects. Leupeptin doses of 10 μM or 20 μM over a 26-h period (GD10-GD11) and 50 μM over a 3 h pulse period produced significant decreases in the clearance of FITC-albumin from culture media. The near complete loss of acid soluble fluorescence and increased total visceral yolk sac (VYS) protein content confirmed the selective inhibition of proteolysis. Inhibition of lysosomal proteolysis thus deprives the developing EMB of essential nutrient amino acids producing conditions akin to amino acid starvation, but may also cause direct effects on pathways critical for normal growth and differentiation. Following leupeptin exposure for 26 or 6 h, total glutathione (GSH) concentrations dropped significantly in the VYS, but only slightly in yolk sac (YSF) and amniotic (AF) fluids. Cys concentrations increased in VYS and EMB, but dropped in YSF and AF fluids. Redox potentials (Eh) for the glutathione disulfide (GSSG)/glutathione (GSH) redox couple trended significantly toward the positive, confirming the net oxidation of conceptual tissues following leupeptin treatment. Analysis of the thiol proteome showed few alterations to specific pathways mapped to the Kyoto Encyclopedia of Genes and Genomes Pathway database, but did reveal significant increases in concentrations of proteins associated with glycolysis/gluconeogenesis in the VYS and decreased concentrations proteins associated with ribosome biogenesis and function in the EMB. A subset of proteins elevated by >2-23-fold in the VYS were identified as serum (blood) proteins and represent the maternal-side proteins captured by the VYS and which are not degraded in the lysosomes as a result of leupeptin's inhibitory action. The observed constellation of proteins decreased in the EMB by leupeptin represent proteins from several adaptive pathways that are commonly altered in responses to amino acid starvation. These studies show clear differential responses to protease inhibition in VYS and EMB during organogenesis and suggest the possibility for additional roles of redox regulation, cellular adaptations and metabolic insufficiency caused by protease inhibition.

Inhibition of proteolysis in histiotrophic nutrition pathways alters DNA methylation and one-carbon metabolism in the organogenesis-stage rat conceptus

Epigenetic modifications, including DNA methylation, contribute to the transcriptional regulation of developmental genes that control growth and differentiation during embryogenesis. The methyl donor, S-adenosylmethionine (SAM), is biosynthesized from methionine and adenosine triphosphate by methionine adenosyltransferase 2a (Mat2a) in the one-carbon (C1) metabolism pathway. SAM biosynthesis requires a steady supply of nutrients, vitamins and cofactors obtained by the developing conceptus through histiotrophic nutrition pathways (HNPs). The visceral yolk sac (VYS) captures proteins and their substrate cargos by receptor-mediated endocytosis and degrades them using lysosomal proteases. We hypothesize that leupeptin, a protease inhibitor, reduces the availability of methionine and C1 substrates, restricting SAM biosynthesis and altering patterns of DNA methylation. Rat conceptuses were exposed to 50 and 100 μM leupeptin in whole embryo culture for periods of 26 h from gestational day (GD) 10 or 6 h on GD11. After 6 h on GD11, the 100-μM leupeptin treatment significantly decreased methionine in embryo (EMB) and VYS, reduced Mat2a protein levels and inhibited Mat2a specific activity, all of which produced a significant 52% reduction of SAM in the VYS. The 50- and 100-μM leupeptin treatments significantly decreased global methylation levels by 6%-9% in EMB and by 11%-15% in VYS following both 6- and 26-h exposure periods. This study demonstrates that HNP disruption alters C1 activity and significantly reduces global DNA methylation during organogenesis. Because epigenetic reprogramming is crucial for normal differentiation and growth, these findings suggest a possible mechanism through which nutrients and environmental factors may alter early developmental regulation.

Fetoplacental transport and utilization of amino acids in IUGR — a review

Amino acids have multiple functions in fetoplacental development. The supply of amino acids to the fetus involves active transport across and metabolism within the trophoblast. Transport occurs through various amino acid transport systems located on both the maternal and fetal facing membranes, many of which have now been documented to be present in rat, sheep and human placentas. The capacity of the placenta to supply amino acids to the fetus develops during pregnancy through alterations in such factors as surface area and specific time-dependent transport system expression. In intrauterine growth restriction (IUGR), placental surface area and amino acid uptakes are decreased in human and experimental animal models. In an ovine model of IUGR, produced by hyperthermia-induced placental insufficiency (PI-IUGR), umbilical oxygen and essential amino acid uptake rates are significantly reduced in the most severe cases in concert with decreased fetal growth. These changes indicate that severe IUGR is likely associated with a shift in amino acid transport capacity and metabolic pathways within the fetoplacental unit. After transport across the trophoblast in normal conditions, amino acids are actively incorporated into tissue proteins or oxidized. In the sheep IUGR fetus, however, which is hypoxic, hypoglycemic and hypoinsulinemic, there appear to be net effluxes of amino acids from the liver and skeletal muscle, suggesting changes in amino acid metabolism. Potential changes may be occurring in the insulin/IGF-I signaling pathway that includes decreased production and/or activation of specific signaling proteins leading to a reduced protein synthesis in fetal tissues. Such observations in the placental insufficiency model of IUGR indicate that the combination of decreased fetoplacental amino acid uptake and disrupted insulin/IGF signaling in liver and muscle account for decreased fetal growth in IUGR.

Rat embryo cultures for in vitro teratology

Mammalian embryos provide a particular challenge to those who wish to study developmental processes because development takes place inside the mother's body, thus limiting the investigator's ability to directly affect and observe the embryonic stages of development. Fortunately, as this unit illustrates, methods have been developed for in vitro culture of rodent embryos during early postimplantation (gestation days 9 to 11) and early fetal (gestation days 12 to 14) stages, which are the periods during which the major systems of the embryo are established. Embryos at these stages are particularly suitable for screening studies to determine the effects of teratological agents.

Placental transfer of vigabatrin (gamma-vinyl GABA) and its effect on concentration of amino acids in the embryo of TO mice

BACKGROUND

The mechanism of the teratogenicity of vigabatrin (VGB) is unknown. The objectives of this study were to determine the placental transfer of VGB and to evaluate the effect of VGB on maternal, placental, and fetal concentrations of amino acids.

METHODS

A single dose of 400 mg/kg VGB in physiological saline was administered intraperitoneally to a group of Theiler outbred (TO) mice on gestational day (GD) 10. The controls received a proportionate volume of saline. Maternal blood samples, embryos, and placentas were collected at 3.5, 6.0, and 9.0 hr after treatment and their total amino acid concentrations determined in an ion-exchange amino acid analyzer.

RESULTS

At 3.5 hr, there was a decrease in concentrations of some amino acids in the blood, placenta, and embryos of VGB-treated mice, but the decrease in methionine was most marked. gamma-aminobutyric acid (GABA) was significantly higher in the VGB group in both the embryos and the placentas at 3.5 hr but at 6.0 and 9.0 hr the differences were not significant. Vigabatrin levels were higher in the placenta than in the embryo at 3.5 hr, but at 6.0 hr there was an overlap of the VGB peak with that of tryptophan with very much lower levels than at 3.5 hr. At 9.0 hr, there was no vigabatrin peak in either the placenta or the embryo.

CONCLUSIONS

Maternal exposure to VGB results in peak levels of the drug after 3.5 hr in the placenta and embryo. Methionine concentration is most severely affected in VGB-treated mothers, placentas, and fetuses. We speculate that this deficiency could be a possible mechanism for the teratogenic effects of vigabatrin.

Characterization of mouse cathepsin R, a new member of a family of placentally expressed cysteine proteases

A new mouse cysteine protease, termed cathepsin R, has been identified. The complete nucleotide sequence of this gene was derived from a set of cDNAs generated from 15.5-day mouse placenta. Sequence analysis revealed an open reading frame encoding a 334 amino acid long polypeptide closely related to placentally expressed cathepsins P, Q, and M. RT-PCR analysis indicated that cathepsin R is only expressed in placenta and thus is a new member of the emerging family of cathepsins whose expression is regulated during mouse embryonic development. Modeling and structural analysis suggests that cathepsin R will have a restricted substrate specificity when compared to that of cathepsin L.

Effects of supplemental methionine on antiserum-induced dysmorphology in rat embryos cultured in vitro

BACKGROUND

Heterologous antiserum to the visceral yolk sac (AVYS) is teratogenic, inducing a spectrum of malformations in vivo and producing similar effects in vitro. Numerous studies support the concept that AVYS-induced malformations result from embryonic nutritional deficiency, without affecting the maternal nutritional status. This has provided a useful model with which to investigate the nutritional requirements of the early embryo, as well as the role of various nutrients in the etiology of congenital defects.

METHODS

In the current investigation, we examined the effects of methionine and other nutrients on AVYS-induced embryotoxicity in vitro. For these experiments, we cultured rat embryos (9.5 p.c) for 48 hr with AVYS and/or methionine at several concentration levels.

RESULTS

The addition of L-methionine to AVYS-exposed cultures reduced dysmorphology and open neural tube; this effect was concentration dependent. AVYS-induced dysmorphology was completely prevented at a concentration of L-methionine corresponding to 50-fold the basal serum concentration. Utilization of D-methionine, L-leucine, or folic acid (5-methyltetrahydrofolate, MTHF) instead of L-methionine had no protective effects.

CONCLUSIONS

These results suggest that, although AVYS limits the supply of all amino acids to the embryo, embryopathy largely results from a deficiency of methionine. Furthermore, although endocytosis and degradation of proteins by the VYS supplies most amino acids to the embryo, free amino acids may be compensatory when this source is reduced. These results support those of previous investigations that suggest methionine is required for normal NT closure and that methionine is a limiting nutrient for embryonic development.

Mouse cathepsin M, a placenta-specific lysosomal cysteine protease related to cathepsins L and P

The complete nucleotide sequence of a novel cathepsin cDNA derived from mouse placenta was determined and is termed cathepsin M. The predicted protein of 333 amino acid is a member of the family C1A proteases and is related to mouse cathepsins L and P. Mouse cathepsin M is highly expressed in placenta, whereas no detectable levels were found in lung, spleen, heart, brain, kidney, thymus, testicle, liver, or embryo. Phylogenic analyses of the sequences of human and mouse cathepsins show that cathepsin M is most closely related to cathepsins P and L. However, the differences are sufficiently large to indicate that the enzymes will be found in other species. This is in contrast to human cathepsins L and V, which probably resulted from a gene duplication after divergence of mammalian species.

Cathepsin Q, a novel lysosomal cysteine protease highly expressed in placenta

The complete nucleotide sequence of a novel cathepsin cDNA derived from rat placenta was determined and is termed cathepsin Q. The predicted protein of 343 amino acid is a member of the family C1A protease related to cathepsin L. Rat cathepsin Q and its mouse counterpart were found highly expressed in placenta, whereas no detectable levels were found in lung, spleen, heart, brain, kidney, thymus, testicle, liver, or embryonic tissues. It is predicted that cathepsin Q will differ in catalytic specificity to another placental-specific protease, cathepsin P, indicating that these enzymes will have unique proteolytic functions in extra-embryonic tissues.

Nutritional studies of the embryo during early organogenesis with normal embryos and embryos exhibiting yolk sac dysfunction

In 1961 we reported that heterologous kidney antiserum when injected into pregnant rats resulted in wide spectrum of congenital malformations. Further studies identified that it was the IgG component of the antiserum that was teratogenic and that complement was not necessary to produce the teratogenic effect. Labeled antibody studies demonstrated that the kidney antiserum localized in the kidney and in the visceral yolk sac (VYS) and parietal yolk sac placentas. Preparation of yolk sac (YS) antiserum proved to be more potent than the kidney antiserum. Adsorption studies with VYS and parietal yolk sac antiserum revealed that the site of the teratogenic process was located in the VYS. In vitro embryo culture experiments demonstrated that direct injection of the teratogenic antibody into the amniotic or YS cavity did not injure the embryo, thus indicating that the teratogenic antibody had to come in contact with the absorptive surface of the VYS. Collaboration with Dr. John Lloyd demonstrated that teratogenic antibody interfered with the process of pinocytosis and the delivery of amino acids (AA) to the developing embryo. Our studies into the nature of the source of AA for the embryo indicated that in some instances > 95% of the AA present in the developing embryo were derived from maternal proteins and the remainder from free AA in the maternal serum. We also demonstrated that embryonic methionine was derived primarily from the digestion of maternal serum proteins but that more of the methionine was diverted from the synthesis of embryonic proteins, supporting the view that it has important functions other than the synthesis of proteins. All these studies focus on the role of the YS in human development and whether human YS dysfunction may play a role in the pathogenesis of congenital malformations. Further studies on the delivery of AA to the embryo are warranted to determine whether certain AA are in short supply in maternal serum and place the embryo at risk if nutritional alterations in the maternal environment occurs. Furthermore, the YS may be an organ whose role might offer opportunities for pregnancy control.

Uptake of microparticles by rat visceral yolk sac

The visceral yolk sac (VYS) is responsible for a major part of the amino acid nutrition of the early post-implantation rat embryo and possibly also at the fetal stage of gestation. The mechanism involves endocytic uptake of proteins by the tissue's epithelial cells followed by intralysosomal digestion to amino acids. The amino acid so generated are used for protein synthesis in both the embryo and the VYS. Previous reports had indicated that the endocytic capacity of the VYS might be limited to exclude larger macromolecules. This study demonstrates that Percoll, which comprises 30-nm silica particles coated with polyvinylpyrrolidone (PVP), is as effectively captured by the 17.5-day rat VYS cultured in vitro as PVP itself. Uptake of 125I-labelled Percoll was progressive with time over 5 h and was inhibited by a low incubation temperature, 2,4-dinitrophenol (50 micrograms/ml), EGTA (5 mM), colchicine (10 micrograms/ml) or cytochalasin B (10 micrograms/ml). After uptake of 125I-labelled Percoll, VYSs released only 20 per cent of their radioactivity when re-incubated in fresh medium for 3 h. These data, and electron micrographs showing Percoll in intracellular vacuoles, are all consistent with uptake by endocytosis. Percoll's rate of uptake by the VYS indicates that, like 125I-labelled PVP, it enters the cell chiefly by fluid-phase pinocytosis. It is concluded that endocytosis by the VYS will efficiently capture even the largest globular proteins, and that previous indications of a relatively low size exclusion reflected the loosely coiled configuration of the synthetic polymers used in the earlier studies.

Uptake and processing of 59Fe-labelled and 125I-labelled rat transferrin by early organogenesis rat conceptuses in vitro

The delivery of iron to the early organogenesis rat embryo has been studied, using 59Fe- and 125I-labelled rat transferrin. Rat conceptuses at 9.5 days postconception were cultured for 27 or 51 h in whole rat serum. Rat transferrin labelled with 59Fe was added for the final 0.1, 0.5, 6, 24 or 48 h of culture. Radioactivity accumulated progressively in both the embryo and the visceral yolk sac. Similar results were obtained when unconjugated 59Fe3+ was added to the rat serum used as culture medium. Both acid-soluble and acid-insoluble 59Fe were substantially present in the embryo and yolk sac after all exposure periods. When conceptuses were cultured in the presence of 125I-labelled rat transferrin, acid-soluble radioactivity was progressively released into the culture medium, but accumulation into the embryo and visceral yolk sac was slight and did not change with duration of exposure to the labelled protein. Similar findings were obtained using 125I-labelled bovine serum albumin. In these experiments, there was a close correspondence between the amount of iron accumulated by the embryo and visceral yolk sac in the final 24 h of a 51-h culture and the amount of transferrin converted into acid-soluble products in the same period. Visceral yolk sacs from 17.5-day pregnant rats were explanted and cultured in the presence of 59Fe-labelled rat transferrin, 125I-labelled rat transferrin or 125I-labelled bovine serum albumin, for periods up to 3 h. Again uptake of 59Fe increased with time of incubation, and the 125I-labelled proteins were digested to acid-soluble products which were released into the culture medium. The results indicate that transferrin delivers iron for incorporation into both the embryo and the visceral yolk sac, and are consistent with a mechanism involving receptor-mediated endocytosis of iron-laden transferrin by the cells of the visceral yolk sac. The transferrin itself appears to be quantitatively degraded, following delivery of iron to the yolk sac cells, a result that differs from findings in other cell types, in which the protein is not degraded but returns to the plasma membrane to participate in further cycles of iron acquisition and delivery.

Fluorometric analysis of endocytosis and lysosomal proteolysis in the rat visceral yolk sac during whole embryo culture

Using spectrofluorimetry and fluorescence microscopy, we analyzed the uptake and degradation of fluorescein isothiocyanate-conjugated bovine serum albumin (FITC-albumin) by the rat visceral yolk sac (VYS) during whole embryo culture. Rat conceptuses exposed continuously to FITC-albumin had linear increases of both acid-soluble and acid-insoluble FITC fluorescence in the VYS. Smaller amounts of FITC fluorescence that were nearly all acid soluble accumulated in the extraembryonic fluid, while the embryo proper did not accumulate a significant amount of fluorescence. During a chase period following a pulse exposure to FITC albumin, FITC fluorescence in the VYS decreased linearly, while that in the extraembryonic fluid and culture medium increased. Addition of proteinase inhibitors to the culture medium together with FITC-albumin increased acid-insoluble FITC-fluorescence in the VYS tissue but decreased acid-soluble fluorescent degradation products in the yolk sac, extraembryonic fluid, and the culture medium. Fluorescence microscopy of yolk sacs exposed to FITC-albumin revealed that the fluorescence was localized in apical vacuoles of the yolk sac epithelium and decreased substantially during a chase period. In conceptuses exposed to proteinase inhibitors, the yolk sac epithelium had enlarged vacuoles containing FITC-fluorescence whose clearance in pulse-chase experiments was effectively blocked. Overall, these data suggest that FITC-albumin resembles 125l-albumin in its processing by the VYS and that the fluorescent protein is an attractive alternative tracer molecule for studies of the effects of embryotoxicants on yolk sac function during whole embryo culture.

Mechanisms of amino acid supply to the rat conceptus in normal and abnormal development

Using in vitro and in vivo models, we have shown that protein is an important source of amino acids from 8.5 to 17.5 d postconception, a significant portion of postimplantation development in the rat. This satisfactorily explains why inhibition of protein pinocytosis and digestion by the visceral yolk sac may lead to congenital malformations, growth retardation, and intrauterine death during organogenesis and growth retardation and death during fetal stages. In humans, this process may be just as important and possibly just as vulnerable to inhibition, but other placental or paraplacental tissues may be involved in addition to the secondary yolk sac.

Leucine sources for the rat fetus

Fetal and maternal plasma were assayed for the concentration of free leucine, acid-insoluble radioactivity and acid-soluble radioactivity at intervals after an intravenous bolus injection of [3H]leucine into anaesthetized pregnant rats at 17.5 days post-conception. The concentrations of total free leucine and of free [3H]leucine in maternal and fetal plasma were effectively unchanged from 5 to 180 min post-injection. Plasma free leucine concentrations in the fetus were five times those in the mother. The concentration of free [3H]leucine in fetal plasma was similar to that in maternal plasma. Thus the specific radioactivity of free leucine in fetal plasma is substantially lower than that in maternal plasma, indicating that a significant portion of the free leucine in plasma of the 17.5-day rat fetus comes from a source other than the free leucine in the maternal plasma. The data are consistent with a major contribution of amino acids coming from the degradation of extraembryonic protein in the yolk sac. Other possible sources of unlabelled leucine are discussed.

Pharmacokinetics of teratogenic antibodies administered to rats

The serum levels of total and visceral yolk sac (VYS)-reactive sheep IgG have been determined following injection of a teratogenic sheep anti-VYS antiserum. After intravenous injection, levels of VYS-reactive IgG fell rapidly, with 75% of the amount in the injection removed in the first 5 min, and 90% by 60 min. By contrast, 90% or more of the total sheep IgG was still present at these times. A similar difference in clearance was seen after intraperitoneal injection, although the serum levels also reflected the presence of a pool of antiserum in the peritoneum and the simultaneous influx and efflux of IgG into and from the circulation. The clearance pattern was similar in pregnant and nonpregnant rats; it is concluded that antibodies against VYS-specific antigens comprise a very small fraction of VYS-reactive antibodies in the antiserum. ELISA and Western blot analysis indicated extensive cross-specificity with antigens present in rat tissues other than the VYS. Similar teratogenic effects were observed after intravenous or intraperitoneal injection of the antiserum at 8.5 days of gestation; we conclude that the proximal effect likely begins within the period immediately after the injection. The results are also considered within the context of published reports that the VYS shows structural and functional damage for several days after intraperitoneal administration of antiserum at 8.5 days.

Cloning and expression of a rat placental cDNA encoding a novel cathepsin L-related protein

Cathepsin L is a major lysosomal cysteine protease produced by mouse placenta and fibroblasts. This study characterizes a novel cathepsin L-related mRNA expressed in rat placenta. Immunological and nucleotide screening of a rat placenta library identified six positive clones, the largest, pCLRP-9, being 924 base pairs in length. The combined sequences of all the clones contain an open reading frame of 711 nucleotides, a termination codon, a polyadenylation site, and 197 nucleotides of 3' untranslated region, but lack the 5' translation initiation codon. The pCLRP nucleotide sequence showed 60-64% identity to those of mouse, rat, and human cathepsin L. The deduced amino acid sequence of pCLRP codes for 237 amino acids, which align with the carboxy-terminal sequence of cathepsin L and has the active site residues characteristic of the cysteine protease family. Northern blot analysis showed hybridization of pCLRP with a major mRNA transcript of 1.3 kilobases expressed in placenta, but not kidney or liver. In contrast, a cDNA for mouse pro-cathepsin L hybridized with a transcript of 1.7 kilobases expressed in rat kidney, as well as placenta. During late gestation, steady-state levels of rat placental pCLRP mRNA were highest on day 18, whereas those of mouse procathepsin L were greatest on day 20 of gestation. Antiserum to mouse cathepsin L cross-reacted with four proteins of molecular weights 36,000 to 42,000 in rat placental culture medium, of which two were absent in the kidney. These data indicate that rat placenta expresses several species of cathepsin L-type proteins, which may be involved in placental function and nutrient supply.

In vitro embryotoxicity of the cysteine proteinase inhibitors benzyloxycarbonyl-phenylalanine-alanine-diazomethane (Z-Phe-Ala-CHN2) and benzyloxycarbonyl-phenylalanine-phenylalanine-diazomethane (Z-Phe-Phe-CHN2)

This study makes use of whole embryo culture to investigate the potential embryotoxicity of benzyloxycarbonyl-phenylalanine-alanine-diazomethane (Z-Phe-Ala-CHN2) and benzyloxycarbonyl-phenylalanine-phenylalanine-diazomethane (Z-Phe-Phe-CHN2), two low molecular weight, active site-directed and irreversible inhibitors of the lysosomal cysteine proteinases. Peptidyl diazomethanes are the most specific inhibitors available for lysosomal cysteine proteinases and can be hypothesized to interrupt visceral yolk sac (VYS)-mediated nutrition during early organogenesis. When added directly to the culture medium of gestational day 10-11 rat conceptuses, both compounds inhibited lysosomal cysteine proteinase activity in the VYS in a concentration-dependent fashion that correlated with the degree of embryotoxicity observed. Z-Phe-Ala-CHN2 and Z-Phe-Phe-CHN2 were also found to increase the protein content of the VYS, even though all other conceptual growth parameters decreased. This effect was dependent on the serum content of the culture medium and the exposure time. Histological examination of Z-Phe-Ala-CHN2-treated conceptuses revealed a dramatic increase in the size and number of vacuoles in the VYS endoderm epithelium, suggestive of inhibition of VYS proteolysis. At the same time, excessive cell death was observed throughout the neuroepithelium and in specific regions of the mesenchyme of the corresponding embryos. This cell death manifested morphological characteristics of apoptosis and could be detected by supravital staining with Nile Blue Sulphate. These findings provide additional evidence in support of the hypothesis that lysosomal cysteine proteinases play a critical role in VYS-mediated histiotrophic nutrition and suggest that peptidyl diazomethanes may be useful in further characterization of these enzymes. The possible direct effects of these inhibitors on embryonic cells and the relationships between interruption of VYS-mediated nutritional processes and embryonic cell death are discussed.

Pinocytosis in the rat visceral yolk sac: potential role in amino acid nutrition during the fetal period

At 9.5 to 10.5 days post-conception (p.c.) the rat embryo receives amino acids primarily by pinocytosis of maternal proteins by the visceral yolk sac (VYS) endodermal cells and their subsequent digestion in lysosomes. As this mechanism may also contribute to the nutritional support of the rapidly growing fetus later in gestation, this study determines the potential of the VYS to contribute to the amino acid needs of the rat fetus on 13.5, 15.5 and 17.5 days p.c. Wistar rats were killed on 11.5, 13.5, 15.5, 17.5 and 19.5 days p.c. and the protein content of fetuses, VYSs and serum was determined. Additional VYSs were isolated on the same days p.c. and the uptake of [14C]sucrose, a measure of fluid-phase pinocytosis, was determined. The rate of protein accretion by the fetus and the capacity of the VYS to pinocytose and digest proteins were calculated on 13.5, 15.5 and 17.5 days p.c. There was a decrease in pinocytic capacity, per mg protein, over the period of development studied but, owing to the growth of the tissue, the total capacity of the yolk sac to pinocytose and digest proteins increased from 13.5 to 17.5 days p.c. Comparison of the VYSs capacity to pinocytose and digest proteins and the rate of protein accretion by the fetus suggests that the VYS could support a significant proportion of the increase in protein content of the growing fetus. This conclusion is reinforced by the limited capacity of the maternal plasma to supply free amino acids to the fetus.(ABSTRACT TRUNCATED AT 250 WORDS)

Teratogenic and macromolecular synthesis inhibitory effects of trimethylamine on mouse embryos in culture

Trimethylamine (TMA) is an aliphatic amine, and its blood levels can increase after ingestion of certain foods, such as fish, and during disease states, such as chronic renal failure. We recently reported that TMA can inhibit fetal development in vivo and in vitro in mice. The present studies were done to find out if the inhibitory effects of TMA on embryonic development are caused by a decrease in macromolecular synthesis, using mouse embryo cultures as the experimental model. At a submaximally toxic concentration (0.75mM), TMA inhibited the growth of embryos to approximately 70% of control and caused neural-tube defects in 73% of embryos. By 42 h of culture, DNA, RNA, and protein content of TMA-treated embryos were approximately 50% of the control values. Embryotoxic effects of TMA were not caused by changes in pH and osmolarity of the culture media. The inhibitory effects of TMA on embryonic growth were time dependent and apparent at 2-4 h of culture. The inhibition of growth was accompanied by a decrease in the incorporation of tritium-labeled thymidine, uridine, and leucine into DNA, RNA, and proteins, respectively. Thiols (L- and D-cysteine, glutathione) and the antioxidant L-ascorbic acid did not cause significant antagonism of embryotoxic effects of TMA. It is concluded that TMA exerts teratogenic effects on mouse embryos in culture and inhibits their growth by reducing macromolecular synthesis; these effects may not involve glutathione depletion or generation of free radicals.

The activities of thiol proteases in the rat visceral yolk sac increase during late gestation

While the rat YVS has been shown to possess an active lysosomal proteolytic system, there are no published reports on the identity of these proteases nor on their changes in activity during the latter half of gestation. We have used specific synthetic substrates to show that cathepsins B, L and H are present in this organ from days 12.5 to 20.5 of gestation. Cathepsins B and L exhibit a marked increase in activity beginning on day 15.5 of gestation. By days 19.5-20.5, cathepsin B activity is increased tenfold over that observed on day 12.5. The activity of cathepsin L may be elevated on day 12.5, decreases more than half by day 14.5 and then increases fourfold by day 20.5. The activity of cathepsin H does not change throughout this period nor do the cathepsins exhibit marked changes in activity in the placenta during this same period or in the PYS from days 12.5 to 14.5 of gestation. These results indicate a specific increase in VYS cathepsin B and L activities late in gestation. These enzymes may be involved in meeting the nutritional needs of the embryo and/or in the degenerative changes which may occur in the VYS and PYS prior to parturition. Studies on the degradation of rat serum albumin by extracts of day 19.5 VYS indicate that cathepsin L may be the quantitatively most important protease in late gestation.

Sources of amino acids for protein synthesis during early organogenesis in the rat. 2. Exchange with amino acid and protein pools in embryo and yolk sac

Tenth-day rat conceptuses were cultured in whole rat serum containing [3H]leucine and harvested after 24 or 48 h. Hydrolysates of the acid-precipitable fraction of embryo or yolk-sac homogenates were prepared and subjected to paper chromatography. Liquid scintillation counting of the separated amino acids showed that leucine was the only amino acid with above-background radioactivity. This established that radiolabel was not transferred from leucine to other amino acids in the cultured rat conceptus. Tenth-day rat conceptuses were cultured in whole rat serum containing [3H]leucine, as above. After 19 h, some conceptuses were harvested; other conceptuses were rinsed, transferred to culture medium without [3H]leucine, and after a further 24 h of culture the embryos and yolk sacs were harvested. A comparison of the protein-associated radioactivity of embryo and yolk sac before and after culturing for the further 24-h period showed that these structures quantitatively conserve radiolabelled leucine incorporated into their proteins. Further experiments involved culturing the rat conceptus for 24 h as above but in the presence of either [3H]leucine or [3H]leucine-labelled serum proteins. After harvesting the conceptuses, the specific radioactivity of [3H]leucine was determined in the acid-soluble and acid-precipitable fractions prepared from embryo and yolk-sac homogenates. The specific radioactivity of [3H]leucine in the acid-soluble fraction of embryos or yolk sacs from conceptuses grown in the presence of radiolabelled protein was about 120 per cent of that in the culture medium, while that in the acid-precipitable fractions was about 70 per cent of that in the culture medium. By comparison, the specific radioactivity of [3H]leucine in the acid-soluble fraction of embryos and yolk sacs from conceptuses grown in the presence of free [3H]leucine was only 3-4 per cent of that in the culture medium, while that in the acid-precipitable fraction was about 1 per cent of that in the culture medium. If our data on the fate of leucine incorporated into newly synthesized proteins of the early post-implantation rat embryo can be extrapolated to the other amino acids, they suggest that once amino acids have been incorporated into newly synthesized protein in embryo or yolk sac, they are not exchanged to any detectable extent with amino acid pools outside the conceptus. The results also provide independent confirmation of our earlier conclusion that the only significant source of amino acids utilized by the 10th-day embryo is protein taken up by the yolk sac and digested intracellularly.(ABSTRACT TRUNCATED AT 400 WORDS)