The role of the visceral yolk sac in hyperglycemia-induced embryopathies in mouse embryos in vitro.

The adverse developmental effects of hyperglycemia to rodent embryos have been shown using whole embryo culture. Although, a mechanism by which hyperglycemia-induced effects occur is unknown, recent work has focused on the visceral yolk sac as a potential target tissue. Therefore, we have evaluated the developmental effects of hyperglycemia in early head fold stage mouse embryos in vitro and assessed the histiotrophic function of the visceral yolk sac. As has been previously shown in rodents, hyperglycemia produced neural tube closure defects in a concentration dependent manner at 33, 50, and 67 mM glucose using a 44 h exposure period. However, exposure times between 6 and 12 h were sufficient to alter embryonic development when the glucose concentration was 50 or 67 mM. In contrast, early somite stage embryos (4-6 somite stage) appear to be less sensitive to dysmorphogenesis and a 48 h exposure to 67 mM glucose but not 33 or 50 mM also produced neural tube defects. Hyperglycemia (67 mM) did not alter the uptake of 35S-methionine and 35S-cysteine-labeled hemoglobin (35S-Hb) in the visceral yolk sac (VYS) in early headfold staged embryos. However, the accumulation of 35S in the embryo was reduced by 16-18% at glucose concentrations of 50 or 67 mM during the last 12 h of a 44 h exposure period. No effect on VYS uptake or embryonic accumulation of 35S-labeled products was observed at shorter exposure periods (12-24 and 24-36 h).(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of lithium carbonate on mouse and rat embryos in vitro

Lithium is effective in the treatment of manic-depressive psychosis but is suspected to be a developmental toxicant in humans. It is a developmental toxicant in mice and rats in vivo, but at human therapeutic serum levels of 0.6-1.6 meq/L, rats appear to be more sensitive to the effects of the drug than do mice. The species susceptibility to lithium-induced defects was evaluated by using a rodent whole embryo culture system employing mouse and rat embryos treated at comparable developmental stages. Mouse embryos were cultured on gestational days 8-10, and rat embryos were cultured on gestational days 10-12. Care was taken to insure that all embryos had 10 +/- 2 somite pairs at the beginning of the culture period. Embryos were cultured for 44 hours in rat serum to which lithium was added to attain final drug concentrations of 0.6, 1.2, 1.8, 2.4, or 5.0 meq/L. Control embryos were treated with distilled water, which served as the vehicle. In rats, lithium induced significant decreases in various parameters at 1.8, 2.4, and 5.0 meq/L; no malformations were observed in rats of this stage. In mice, significant decreases occurred at 2.4 and 5.0 meq/L, and embryos treated at the highest concentration had a significantly increased frequency of open neural tubes. Rat embryos were also cultured with lithium on gestational days 9-11. The lowest dose producing developmental toxicity at this stage was 0.6 meq/L. Open neural tubes were present among younger rat embryos; however, this defect occurred in all groups, including the control group.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphate induced developmental arrest of hamster two-cell embryos is associated with disrupted ionic homeostasis.

Culture of hamster embryos with 0.35 mM inorganic phosphate results in developmental arrest at the 2-cell stage. These arrested 2-cell embryos were found to have significantly elevated levels of both intracellular pH and intracellular free calcium. Culture of 2-cell embryos with both glucose and phosphate did not further alter intracellular ionic homeostasis. Developmental arrest of 2-cell embryos was dependent on the concentration of phosphate used. Culture with 1.25 microM phosphate did not alter development, while concentrations of 2.5 microM and 5.0 microM resulted in a percentage of embryos arresting development at the 2-cell stage. Analysis of intracellular levels of pH and calcium after culture with different phosphate concentrations revealed a significant negative correlation between intracellular calcium levels and development beyond the 2-cell stage. There was no correlation between the increase in intracellular pH and embryo development in the presence of phosphate. The increase in intracellular calcium levels after culture with phosphate appears to be derived from intracellular pools, as preventing the influx of extracellular calcium did not alter development beyond the 2-cell stage. Therefore, it is apparent that a disruption in ionic homeostasis is associated with developmental arrest of hamster embryos cultured with phosphate.     

Nerve growth factor induces neural differentiation in undifferentiated cell of early chick embryos

Nerve growth factor (NGF) induced differentiation in postnodal pieces (PNPs) of stage 4 chick embryos. This induction was highly selective for neural tissue; no other structures developed in the NGF-treated PNPs. Furthermore, the number of PNPs showing neural differentiation was dependent on the concentration of NGF, but there was no correlation between the concentration of NGF (5-100 ng/ml) and extent of neuralization. The neural inducing capacity of NGF could be abolished by anti-NGF antibody. NGF-induced neural differentiation was accompanied by elevated intracellular levels of cyclic AMP. Exogenous cyclic AMP (175 micrograms/ml) was able to stimulate neural differentiation but, unlike NGF, induced other structures (e.g., notochord and pulsatile tissue). Overall results suggest that cells from chick embryos at developmental stages much earlier than previously thought are responsive to NGF and NGF or a a closely related substance may serve as a neural inducer in the chick embryo.     

Potassium current activated by intracellular sodium in quail trigeminal ganglion neurons

Whole-cell voltage clamp and single-channel recordings were performed on cultured trigeminal ganglion neurons from quail embryos in order to study a sodium-activated potassium current (KNa). When KNa was activated by a step depolarization in voltage clamp, there was a proportionality between KNa and INa at all voltages between the threshold of INa and ENa. Single-channel recordings indicated that KNa could be activated already by 12 mM intracellular sodium and was almost fully activated at 50 mM sodium. 100 mM lithium, 100 mM choline, or 5 microM calcium did not activate KNa. The relationship between the probability for the channel to be open (Po) vs. the sodium concentration and the relationship of KNa open time-distributions vs. the sodium concentration suggest that two to three sodium ions bind cooperatively before KNa channels open. KNa channels were sensitive to depolarization; at 12 mM sodium, a 42-mV depolarization caused an e-fold increase in Po. Under physiological conditions, the conductance of the KNa channel was 50 pS. This conductance increased to 174 pS when the intra- and extracellular potassium concentrations were 75 and 150 mM, respectively.     

Inhibitors of choline uptake and metabolism cause developmental abnormalities in neurulating mouse embryos.

BACKGROUND: Choline is an essential nutrient in methylation, acetylcholine and phospholipid biosynthesis, and in cell signaling. The demand by an embryo or fetus for choline may place a pregnant woman and, subsequently, the developing conceptus at risk for choline deficiency. METHODS: To determine whether a disruption in choline uptake and metabolism results in developmental abnormalities, early somite staged mouse embryos were exposed in vitro to either an inhibitor of choline uptake and metabolism, 2-dimethylaminoethanol (DMAE), or an inhibitor of phosphatidylcholine synthesis, 1-O-octadecyl-2-O-methyl-rac-glycero-3-phosphocholine (ET-18-OCH(3)). Cell death following inhibitor exposure was investigated with LysoTracker Red and histology. RESULTS: Embryos exposed to 250-750 microM DMAE for 26 hr developed craniofacial hypoplasia and open neural tube defects in the forebrain, midbrain, and hindbrain regions. Embryos exposed to 125-275 microM ET-18-OCH(3) exhibited similar defects or expansion of the brain vesicles. ET-18-OCH(3)-affected embryos also had a distended neural tube at the posterior neuropore. Embryonic growth was reduced in embryos treated with either DMAE (375, 500, and 750 microM) or ET-18-OCH(3) (200 and 275 microM). Whole mount staining with LysoTracker Red and histological sections showed increased areas of cell death in embryos treated with 275 microM ET-18-OCH(3) for 6 hr, but there was no evidence of cell death in DMAE-exposed embryos. CONCLUSIONS: Inhibition of choline uptake and metabolism during neurulation results in growth retardation and developmental defects that affect the neural tube and face.     

Autonomous muscle cell differentiation in partial ascidian embryos according to the newly verified cell lineages

Recent analysis of cell lineages in ascidian embryos by the intracellular injection of a tracer enzyme has clearly demonstrated that muscle cells are derived not only from the B4.1-cell pair of the eight-cell stage embryo, as has hitherto been believed, but also from both the b4.2- and A4.1-cell pairs (H. Nishida and N. Satoh, 1983, Dev. Biol.99, 382–394). In order to reexamine the developmental autonomy in muscle lineage cells, the B4.1 pair was isolated from the eight-cell stage embryo. The progeny cells of the B4.1 pair, as well as those of the six other blastomeres, were then allowed to develop in isolation into partial embryos. Autonomous muscle cell differentiation not only in partial embryos originating from the B4.1 cells but also in those from the six other blastomeres was substantiated by (a) occurrence of localized histospecific muscle acetylcholinesterase and (b) development of myofibrils. These results support the validity of the recent cell lineage study and confirmed the self-differentiation potency of muscle lineage cells in ascidian embryos according to the newly verified cell lineages.     

Mesodermal expression of integrin α5β1 regulates neural crest development and cardiovascular morphogenesis

Integrin α5-null embryos die in mid-gestation from severe defects in cardiovascular morphogenesis, which stem from defective development of the neural crest, heart and vasculature. To investigate the role of integrin α5β1 in cardiovascular development, we used the Mesp1^Cre knock-in strain of mice to ablate integrin α5 in the anterior mesoderm, which gives rise to all of the cardiac and many of the vascular and muscle lineages in the anterior portion of the embryo. Surprisingly, we found that mutant embryos displayed numerous defects related to the abnormal development of the neural crest such as cleft palate, ventricular septal defect, abnormal development of hypoglossal nerves, and defective remodeling of the aortic arch arteries. We found that defects in arch artery remodeling stem from the role of mesodermal integrin α5β1 in neural crest proliferation and differentiation into vascular smooth muscle cells, while proliferation of pharyngeal mesoderm and differentiation of mesodermal derivatives into vascular smooth muscle cells was not defective. Taken together our studies demonstrate a requisite role for mesodermal integrin α5β1 in signaling between the mesoderm and the neural crest, thereby regulating neural crest-dependent morphogenesis of essential embryonic structures.     

In vitro analysis of glucose metabolism and embryonic growth in postimplantation rat embryos

The glucose metabolism and embryonic development of rat embryos during organogenesis was studied using embryo culture. Glucose uptake and embryonic growth and differentiation of 10.5-day explants (embryos + membranes) were limited by the decreasing glucose concentration, but not the increasing concentration of metabolites, in the culture media during the second 24 h of a 48 h culture. No such limitations were found on the embryonic development of 9.5-day explants during a 48 h culture although glucose uptake was slightly reduced at very low concentrations of glucose. From the head-fold stage to the 25-somite stage of development, glucose uptake was characteristic of the stage of development of the embryo and not the time it had been in culture. Embryonic growth of 9.5-day explants was similar to that previously observed in vivo. Glucose uptake by 9.5-day explants was dependent on the surface area of the yolk sac and was independent of the glucose concentration in the culture media (within the range of 9.4 to 2.5 mM). The proportion of glucose converted to lactate was 100% during the first 42h of culture then fell to about 50% during the final 6h. The protein contents of both the extraembryonic membranes and the embryo were dependent on the glucose uptake.     

Mechanisms of spontaneous relaxation of smooth muscle (guinea pig taenia coli) depolarized in a hyperkalemic medium]

Experiments were performed on isolated strips of guinea pig taenia coli by the double sucrose-gap method. The artificial node was depolarized with potassium solution (from 120 to 167.7 mM KCl). When the bathing solution contained 0.4 mM Ca and the temperature was equal to 25 degrees C then potassium contracture was followed by fast relaxation. The muscular tone changed slightly during rectangular pulse of hyperpolarizing current, after switching off the current muscle generated a transient contractile response. The amplitude of such off-responses increased in some range with increasing in strength and duration of conditioning current. Treatment of muscle with compound D-600 resulted in a reduction of muscular tone and elimination of off-responses. The addition of Na ions to potassium solution (substitution of 47.7 mM KCl with the same quantity of NaCl) reduced muscular tone and enhanced the relaxation after off-responses. In sodium-free potassium solution each off-response was followed by increasing muscular tone but when the bathing solution contained Na ions this increase of the tone was not observed. The data obtained strongly suggest that the spontaneous relaxation of smooth muscle which was contracted in K-solution resulted from: 1) inactivation of calcium channels of surface membrane, 2) sequastration of Ca ions by intracellular storange sites, 3) extrusion of Ca in extracellular space (in part by means of Na-Ca exchange diffusion).     

Cell lineage analysis of neural induction: origins of cells forming the induced nervous system

Horseradish peroxidase (HRP) was used as an intracellular lineage tracer in two experiments designed to reveal the sites of origin of cells that formed the duplicate embryo which developed in relation to an organizer grafted in the ventral marginal zone (VMZ) of Xenopus laevis embryos. In the first experiment a dorsal blastoporal lip fully labeled with HRP was grafted in the VMZ of an unlabeled embryo at the beginning of gastrulation. This resulted in development of a second embryo in which labeled cells, of graft origin, formed the notochord, and parts of the somites, endoderm, and neural tube. The second experiment was designed to show the sites of origin of the host's cells that formed parts of the induced embryo. HRP was injected into individual blastomeres in a series of Xenopus embryos at the 32-cell stage and each embryo received an unlabeled organizer graft in the VMZ at the beginning of gastrulation. In these embryos the lineages that contributed to the host's primary neural tube did not contribute any cells to the induced neural tube. All the cells in the induced neural tube which originated from the host were descendants of ventral blastomeres that did not contribute to the neural tube normally. This shows that the second neural tube is formed as a result of the action of the organizer on cells in its immediate vicinity which would not normally have entered neural pathways of differentiation.     

Acetoacetate and beta-D-hydroxybutyrate as energy substrates during early bovine embryo development in vitro

We examined the effects of acetoacetate and other metabolic products of fatty acid oxidation on early bovine embryo development. In vitro produced bovine zygotes were cultured in modified-synthetic oviduct fluid medium supplemented with acetoacetate, acetoacetate derivatives, acetyl CoA precursors and lithium chloride. Acetoacetate and all acetoacetate derivatives, with the exception of the ethyl ester, supported in vitro development up to the hatched blastocyst stage at rates similar to that of controls supplemented with lactate/pyruvate. The optimal concentration of acetoacetate in supporting embryo development was 3.6 mM; addition of 1.8 and 3.6 mM lithium chloride did not significantly affect embryo development, while 7.2 mM was inhibitory. Hatched blastocysts cultured with 3.6 mM acetoacetate contained a similar number of cells as the lactate/pyruvate control group. It can be concluded that in vitro produced bovine embryos can develop using ketone bodies as energy substrates, which could be derived in vivo from endogenous lipids.     

Regulatory properties of 14-day embryo and adult hen skeletal muscle AMP deaminase

Chromatography on phosphocellulose column revealed changes in the elution profile of 14 day-old chicken embryo and adult hen skeletal muscle AMP deaminase. In the presence of 5 mM potassium the enzyme from embryo muscle exhibited a sigmoid-shaped plot of the reaction rate versus substrate concentration. The increase of KCl concentration up to 100 mM diminished distinctly sigmoidicity of the plot. Micromolar concentrations of ADP or ATP activated, whereas GTP at the same concentrations inhibited the embryo and hen skeletal muscle AMP deaminase while 5 mM KCl was present in the incubation medium. 100 mM potassium concentration diminished the effect of ADP and ATP but not of GTP. Palmitoyl-CoA inhibited strongly the embryo skeletal muscle adenylate deaminase but had no effect on the activity of the hen enzyme. Alanine inhibited only the adult hen enzyme. The embryo and hen AMP deaminase differed also in the specificity to adenylate analogues and exhibited a different dAMP/AMP ratio. The data presented indicate that kinetic and regulatory properties of the two developmental forms of AMP deaminase are different.     

Stage-specific nitrogen metabolism in developing carrot somatic embryos

The physiology of individual somatic embryo developmental stages otDaucus carota L. was examined by in vivo nuclear magnetic resonance (NMR) spectroscopy, amino acid analysis and ¹⁴C-labeling. ¹⁵N NMR spectroscopy was used to examine the uptake and incorporation of ¹⁵N isotopically labeled inorganic nitrogen sources. NMR spectra of proembryogenic masses (PEMs) contained resonances for histidine, amino sugars, glutamine, arginine, urea, alanine. α-amino nitrogen, serine, aliphatic amines and several unknowns. Similar resonances were found in various embryo developmental stages. However, resonances for arginine and aliphatic amines peaked during globular and torpedo stages and substantially decreased in germinating stage embryos. The dominant resonances observed in non-embryogenic cells and germinating embryos were glutamine and α-amino nitrogen. Amino acid analysis of the various embryo stages showed that glutamate, glutamine and arginine were the major contributors to the soluble amino acid profiles. During development, glutamate and glutamine continued to increase in concentration whereas arginine and its related metabolites (i.e. ornithine and y-aminobutyric acid [GABA]) were biphasic; increasing in globular and torpedo stage embryos and decreasing in germinating embryos. Carbon-14 labeling indicated that labeled glutamine pools in non-embryogenic and germinating embryos were greatest compared to other embryo stages, whereas labeled GABA pools were greatest in globular and torpedo stage embryos. Taken together, these data indicate that the physiology of each embryo developmental stage is distinct. They also suggest that during somatic embryo development, a switch takes place in metabolism whereby the glutamine synthetase/glutamate synthase (GS/GOGAT) pathway is predominant in non-embryogenic cells and germinating stage embryos. Furthermore, during early to mid-embryo development (PEMs, globular and torpedo stage embryos), metabolism utilizing the omithine cycle is enhanced and predominant.     

Muscle cell differentiation in ascidian embryos analysed with a tissue-specific monoclonal antibody

Utilizing a muscle-specific monoclonal antibody (Mu-2) as a probe, we analysed developmental mechanisms involved in muscle cell differentiation in ascidian embryos. The antigen recognized by Mu-2 was a single polypeptide with a relative molecular mass of about 220 X 10(3). It first appeared at the early tailbud stage and continued to be expressed until the swimming larva stage. There were distinct and separate puromycin and actinomycin D sensitivity periods during the occurrence of the antigen, suggesting the new synthesis of the polypeptide by developing muscle cells. Embryos that had been permanently arrested with aphidicolin in the early cleavage stages up to the 32-cell stage did not express the antigen. DNA replications may be required for the antigen expression. Embryos that had been arrested with cytochalasin B in the 8-cell and later stages developed the antigen, and the number and position of the arrested blastomeres exhibiting the differentiation marker almost corresponded to those of the B4.1-line muscle lineage. Furthermore, in quarter embryos developed from each blastomere pair isolated from the 8-cell embryo, all the B4.1 as well as a part of b4.2 partial embryos expressed the antigen, while the a4.2 and A4.1 partial embryos did not show the antigen expression. These results may provide further support for the existence of cytoplasmic determinants for muscle cell differentiation in this mosaic egg.     

Regional variations in the tightness of the ectodermal epithelium in the developing chick embryo: a study using ion-sensitive microelectrodes

In 2-day-old avian embryos there is a rosto-caudal gradient of interstitial pH (Gillespie and McHanwell: Cell Tissue Res., 247:445-451, '87). Neither the developmental significance nor the basic cellular mechanisms underlying this phenomenon has been studied. The present paper provides information about the interstitial potassium and calcium ion concentrations and the movement of these ions across the ectodermal epithelium. The data suggests a possible explanation for the longitudinal pH gradient in the embryo. The concentrations of potassium and calcium ions in the interstitial spaces were measured with ion-sensitive and conventional microelectrodes. In embryos bathed in solution containing 1 mM potassium, the potassium concentration in the region of the mesencephalon was 5.1 +/- 0.7 mM while in the region of the unsegmented mesoderm it was significantly lower at 3.3 +/- 0.4 mM (mean +/- S.E., n = 16). If embryos are exposed to extra-embryonic solutions containing 30 mM potassium, the K+ concentration in the mesencephalon is 13.0 +/- 0.8 mM and higher at 15.4 +/- 1.2 mM in the unsegmented mesoderm (n = 12). In embryos bathed in solutions containing 0.1 mM calcium, the interstitial calcium was found to be 1.1 +/- 0.52 mM in the mesencephalon and 0.42 +/- 0.19 mM in the unsegmented mesoderm (n = 3). In comparison, embryos bathed in solution containing 10 mM calcium had 1.9 +/- 0.2 mM rostrally compared to 3.71 +/- 0.63 mM caudally (n = 10). Thus it is possible to generate intra-embryonic ion gradients dependent upon the extra-embryonic ion concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Temporal and spatial expression of TGF-beta2 in chicken somites during early embryonic development

A multifunctional growth and differentiation factor TGF-beta is expressed at various developmental stages, and its principle role may be involvement in organogenesis. The present study was performed to evaluate the temporal and spatial expression of TGF-beta2 mRNA in developing somites of chicken embryos during their early developmental periods. TGF-betas were expressed in various tissues of the whole embryo obtained at stage 26 (5 days of incubation) as revealed by whole-mount in situ hybridization. TGF-beta2 mRNA was predominantly expressed in somites as well as the head, branchial arch, wing buds, and leg buds. TGF-beta2 mRNA first appeared in the rostral somites on E4, and its expression sites expanded to the middle range of somites at stage 26. At stages 29-31 (6-7 days), expression in the rostral somites disappeared, and it appeared in the caudal somites. TGF-beta2 expression was also analyzed in sections of the embryo by in situ hybridization. The expression sites of TGF-beta2 were clearly observed in the myotomal somite tips as well as the neural tube. RT-PCR analysis showed that TGF-beta2 expression was very low in the blastocyte stage embryo and thereafter increased linearly in the whole trunk until stage 26. These data indicate that TGF-beta2 may be a regulatory factor participating in the somitogenesis of chicken embryos.     

Presence of serotonin in early chick embryos

With biochemical analysis and with autoradiography based on injection of 5-[3H]hydroxytryptophan, it was possible to demonstrate the presence of serotonin (5-hydroxytryptamine) in early chick embryos as early as the pre-streak stage. The biochemical analysis which covered the early developmental period (0.5-6 days of incubation) revealed an elevated concentration of serotonin at gastrulation; from then it stayed at a lower and fairly even level. Autoradiographs of embryos at the pre-streak stage, the primitive streak stage, the head fold stage and the 4-6 somites stage indicated the presence of serotonin in intracellular yolk granules and in cell nuclei. Moreover, the amine appeared associated with microfilaments and microtubules, particularly in developing neural cells. Notably the elevated concentration of serotonin at gastrulation, but also the intracellular distribution of the amine during early organogenesis, indicates a prominent role for it in cell-shape changes and morphogenesis in the early chick embryo.