Effect of oxidative stress on development and DNA damage in in-vitro cultured bovine embryos by comet assay

The correlation of oxidative stress on development and DNA damage in bovine embryos was investigated by the comet assay (single-cell microgel electrophoresis), an effective technique for detecting single-strand DNA breakage. After in vitro maturation and fertilization, one-cell stage embryos without cumulus cells were cultured for 8 days in SOF medium containing amino acids plus 5% FCS under low (5%) and atmospheric (20% ) oxygen concentration. After 8 days of culture, the extent of blastocyst formation was significantly decreased (P<0.001) when embryos were cultured under 20% oxygen concentration (5.8 +/- 2.4%) when compared to embryos cultured under 5% oxygen concentration (35.1 +/- 6.7%). At the day 3 of development, DNA damage of individual embryos cultured under 5% or 20% oxygen concentration was measured by the comet assay, which entails microgel electrophoresis that can readily detect damaged DNA. After measuring the DNA damage in individual embryos by the comet assay, the length (149.9 +/- 15.3 microm) of the migrating DNA fragment that is indicative of damaged DNA was significantly increased (P<0.001) in the embryos cultured under 20% oxygen concentration when compared to embryos cultured in 5% oxygen concentration (42.3 +/- 7 microm). The length of damaged DNA in more than 50% of embryos was less than 50 microm. when embryos were cultured under 5% oxygen concentration. In contrast, the distribution of damaged DNA shifted to the more damaged extent when embryos were cultured under 20% oxygen concentration. These results demonstrate that the retardation in bovine embryo development than in likely due oxidative stress as a consequence of the higher atmospheric oxygen concentration is positively correlated with an increase in the extent of DNA damage. Moreover, these results demonstrate that the comet assay is a useful method to evaluate embryo culture conditions.     

Regulation of gene expression in bovine blastocysts in response to oxygen and the iron chelator desferrioxamine

Low (2%) oxygen conditions during postcompaction culture of bovine blastocysts improve embryo quality and are associated with small increases in the expression of glucose transporter 1 (SLC2A1), anaphase promoting complex (ANAPC1), and myotrophin (MTPN), suggesting a role for oxygen in the regulation of embryo development, mediated through oxygen-sensitive gene expression. However, bovine embryos, to at least the blastocyst stage, lack detectable levels of the key regulator of oxygen-sensitive gene expression, hypoxia-inducible 1 alpha (HIF1A), while the less well-characterized HIF2 alpha protein is readily detectable. Here we report that other key HIF1 regulated genes are not significantly altered in their expression pattern in bovine blastocysts in response to reduced oxygen concentrations postcompaction-with the exception of lactate dehydrogenase A (LDHA), which was significantly increased following 2% oxygen culture. Antioxidant enzymes have been suggested as potential HIF2 target genes, but their expression was not altered following low-oxygen culture in the bovine blastocyst. The addition of desferrioxamine (an iron chelator and inducer of HIF-regulated gene expression) during postcompaction stages significantly increased SLC2A1, LDHA, inducible nitric oxide synthase (NOS2A), and MTPN gene expression in bovine blastocysts, although development to the blastocyst stage was not significantly affected. These results further suggest that expression of genes, known to be regulated by oxygen via HIF-1 in somatic cells, is not influenced by oxygen during preimplantation postcompaction bovine embryo development. Oxygen-regulated expression of LDHA and SLC2A1 in bovine blastocysts suggests that regulation of these genes may be mediated by HIF2. Furthermore, the effect of a reduced-oxygen environment on gene expression can be mimicked in vitro through the use of desferrioxamine. These results further support our data that the bovine blastocyst stage embryo is unique in its responsiveness to oxygen compared with somatic cells, in that the lack of HIF1-mediated gene expression reduces the overall response to low (physiological) oxygen environments, which appear to favor development.     

Developmental responses of 2-cell embryos to oxygen tension and bovine serum albumin in Wistar rats.

To improve rat embryo culture conditions, responses of Wistar 2-cell embryos from 2 breeders to oxygen tension (5 vs 20%) and bovine serum albumin (BSA) (0 vs 3 mg/ml) were examined using rat 1-cell embryo culture medium (mR1ECM). Supplementation of 3 mg/ml BSA significantly stimulated and accelerated development to the blastocyst and expanded blastocyst stages during 72 and 96 h culture, while reduced oxygen tension stimulated cell division. Fetus development after transfer of blastocysts obtained from 72 h culture under 5% O2 with BSA was significantly higher than those cultured under atmospheric oxygen without BSA. However, the nuclear numbers of in vitro cultured blastocysts and fetus development after embryo transfer were still significantly lower than in vivo developed blastocysts, indicating the current culture condition is still suboptimal.     

Substrate utilization in porcine embryos cultured in NCSU23 and G1.2/G2.2 sequential culture media

Embryo metabolism is an indicator of viability and, therefore, efficiency of the culture medium. Currently, little is known regarding porcine embryo metabolism. The objective of our study was to evaluate glucose and pyruvate uptake and lactate production in porcine embryos cultured in two different media systems. Oocytes were matured and fertilized according to standard protocols. Embryos were allocated randomly into two culture treatments, NCSU23 medium or G1.2/G2.2 sequential culture media 6-8 h post-insemination (hpi). Embryo substrate utilization was measured at the two-cell (24-30 hpi), 8-cell (80 hpi), morula (120 hpi), and blastocyst (144 hpi) stages using ultramicrofluorimetry. Glucose uptake was higher (P < 0.05) in two-cell embryos cultured in G1.2 than in NCSU23 medium (4.54 +/- 0.71, 2.16 +/- 0.87 pmol/embryo/h, respectively). Embryos cultured in G1.2/G2.2 produced significantly more lactate than those in NCSU23 at the eight-cell stage (9.41 +/- 0.71, 4.42 +/- 0.95 pmol/embryo/hr, respectively) as well as the morula stage (11.03 +/- 2.31, 6.29 +/- 0.77 pmol/embryo/hr, respectively). Pyruvate uptake was higher (P < 0.05) in morula cultured in G1.2/G2.2 versus NCSU23 (22.59 +/- 3.92, 11.29 +/- 1.57 pmol/embryo/h, respectively). Lactate production was greater (P < 0.05) in blastocysts cultured in G1.2/G2.2 (38.13 +/- 15.94 pmol/embryo/h) than blastocysts cultured in NCSU23 (8.46 +/- 2.38 pmol/embryo/h). Pyruvate uptake was also greater in blastocysts cultured in G1.2/G2.2 (24.3 +/- 11.04) than those in NCSU23 (11.30 +/- 2.70). When cultured in NCSU23 medium, two- and eight-cell embryos utilized less glucose than morulae and blastocysts, and two-cell embryos produced less lactate than blastocysts (P < 0.05). In G1.2/G2.2 media, two-cells took up less pyruvate than morulae or blastocysts, while blastocysts produced more lactate and utilized more glucose than two-cell, eight-cell and morula stage embryos (P < 0.05). As in other species, glycolysis appears to be the primary metabolic pathway in post-compaction stage porcine embryos. Culture medium composition affects not only substrate uptake, but also metabolic pathways by which these substrates are utilized in porcine embryos at several developmental stages.     

Development, molecular composition and freeze tolerance of bovine embryos cultured in TCM-199 supplemented with hyaluronan

Hyaluronan (HA) is glycosaminoglycan that is present from the start of embryonic development and its role and concentration increases with embryo development. The objective of this study was to evaluate if the presence of HA in TCM-199 culture medium had an effect on the development and quality of bovine embryos. There was no effect of HA on the total number of zygotes developing to blastocysts on day 7, however more expanded and hatched blastocyst stages were observed on days 8 and 9 in the group supplemented with HA (p<0.05). Following freeze/thawing, significantly more (p<0.05) embryos cultured in medium supplemented with HA hatched than those cultured in TCM-199 alone or those with BSA. Medium supplemented with HA and BSA significantly increased the level of expression of glucose metabolism Glut-1 gene and embryo compaction Cx43 gene (p<0.05), and had no effect on Glut-5 and IGF-II expression. In addition, HA presence in culture decreased the level of expression of apoptosis Bax and oxidative stress SOX genes (p<0.05). There was significant difference in total number of nuclei between TCM-199 medium only and the remaining media containing BSA or HA plus BSA, between which there was no difference. In summary, our results indicate that the addition of high molecular weight HA to TCM-199 medium that contains BSA on day 4 of culture improved embryo development to hatching and hatched blastocysts and the quality of produced embryos, which were superior to embryos cultured without HA addition.     

Relative developmental abilities of hamster 2- and 8-cell embryos cultured in hamster embryo culture medium-1 and -2

The relative developmental abilities of hamster 2- and 8-cell embryos in culture were compared using two versions of hamster embryo culture medium (HECM). These media differed primarily in the number of amino acids present, i.e., 20 amino acids in HECM-1 and four amino acids in HECM-2. When 2-cell embryos were cultured for 24 h, the percentages of greater than or equal to 4-cell embryos obtained in both HECM-1 and HECM-2 were comparable (congruent to 93%); at the end of 48 h, the proportion of greater than or equal to 8-cell embryos obtained in HECM-1 (82.5%) was significantly (P less than or equal to 0.001) more than that obtained in HECM-2 (67.9%). Interchange of media, after 24 h culture, did not enhance the ability of cultured 2-cell embryos to become blastocysts. When 8-cell embryos were cultured for 18 h in HECM-1 and -2, there was no appreciable difference in the proportion of total blastocysts formed (89-91%). However, there were significantly (P less than or equal to 0.001) more late blastocysts in HECM-2 than in HECM-1 (68.2% vs. 38.4%). Embryo development from 2- and 8-cell stages was compared in media that differed by the presence and absence of phenol red and penicillin-G. There was no difference in embryo development when these compounds were present or absent. Similarly, the difference in pyruvate concentration between HECM-1 and -2 (0.5 and 0.2 mM, respectively) did not affect embryo development.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of oxygen toxicity on early development of mouse embryos.

To examine the effects of oxygen toxicity on embryonic development, mouse pronuclear embryos were cultured under low oxygen conditions with or without superoxide dismutase (SOD), and the blastulation rate was compared with that of embryos cultured under standard conditions. The blastulation rate of mouse pronuclear embryos cultured under standard conditions was only 1.5% (2/131). This rate was increased significantly, to 28.5% (43/151), when the embryos were cultured under low oxygen conditions; and to 31.0% (35/113) when SOD (500 micrograms/ml) was added to the medium under standard conditions; the rate was increased to 75.2% (115/153) when the embryos were cultured under low oxygen conditions in the presence of SOD. The minimum effective concentration of SOD in the culture medium was 50 micrograms/ml under conditions of 5% O2. The blastulation rate was significantly decreased after 1-hr exposure of pronuclear embryos to room atmospheric oxygen concentration (20% O2), and subsequent culture under 5% O2 with SOD did not result in an improved blastulation rate. Culture with SOD under 5% O2 promoted the development of two-cell stage embryos to the blastocyst stage. When two-cell stage embryos were collected 48 hr after hCG and cultured for 66 hr, their blastulation rate was similar to that of embryos collected from mice 114 hr after hCG. These results suggested that embryonic development in vitro is greatly affected by atmospheric oxygen throughout the early embryonic stages and that this harmful effect can be prevented by culturing embryos under low oxygen conditions and in the presence of SOD.     

Disruption of mitochondrial malate-aspartate shuttle activity in mouse blastocysts impairs viability and fetal growth

The nutrient requirements and metabolic pathways used by the developing embryo transition from predominantly pyruvate during early cleavage stages to glucose at the blastocyst; however, the complexities involved in the regulation of metabolism at different developmental stages are not clear. The aims of this study were to examine the role of the malate-aspartate shuttle (MAS) in nutrient metabolism pathways in the developing mouse blastocyst and the consequences of impaired metabolism on embryo viability and fetal and placental growth. Eight-cell-stage mouse embryos were cultured in the presence of the MAS inhibitor amino-oxyacetate, with or without pyruvate as an energy substrate in the media. When the MAS was inhibited, the rate of glycolysis and lactate production was significantly elevated and glucose uptake reduced, relative to control cultured embryos in the presence of pyruvate. Despite these changes in embryo metabolism, this did not influence development to the blastocyst stage, but it did reduce the number of inner cell mass and trophectoderm cells. When these embryos were transferred to psuedopregnant females, inhibition of the MAS significantly reduced the proportion of embryos that implanted and developed into fetuses on Day 18 of pregnancy. Finally, fetal growth was reduced while placental weight was maintained, leading to a decreased fetal:placental weight ratio relative to control embryos. These results suggest that impaired metabolism of glucose in the blastocyst via the MAS alters the ability of the embryos to implant and form a pregnancy and leads to reduced fetal weight, likely via altered placental development and function.     

Development, freezability and amino acid consumption of bovine embryos cultured in synthetic oviductal fluid (SOF) medium containing amino acids at oviductal or uterine-fluid concentrations

In this study, we examined the development, freezability and amino acid consumption of in vitro produced bovine embryos cultured in a chemically defined medium (SOF+polyvinyl alcohol), supplemented with 24 amino acids at concentrations measured in bovine oviductal or uterine fluid. Amino acids at concentrations in oviductal fluid tested by Elhanssan (EOAA) significantly improved development to the hatched blastocyst stage, compared to Sigma amino acid solutions BME and MEM (SAA). Amino acids at concentrations in uterine fluid tested by Li (LUAA) were not compared to SAA, and development in LUAA was not significantly different from development in EOAA. Amino acids at concentrations in uterine fluid tested by Elhanssan (EUAA) significantly reduced cleavage rate and blocked further embryo development. When the IVF embryos were cultured in EOAA for 48, 72, 96, or 120 h and then transferred to LUAA, blastocyst and hatched blastocyst rates were not significantly affected. The freezability of blastocysts cultured in EOAA for the first 72 h and then moved to LUAA was improved compared to that in SAA. During the 1-8-cell stages, embryos secreted all 23 amino acids (total, 6,368 pmol/embryo). During the 8-cell to morula stages, embryos continued to secrete 21 amino acids (total, 2,495 pmol/embryo), meanwhile embryos began to absorb Arg (70 pmol/embryo) and Gln (18 pmol/embryo). After the morula stage, embryos began to absorb 15 amino acids including Glu, Gly, Arg, and Gln (total, 2,742 pmol/embryo) and secreted eight amino acids (total, 1,616 pmol/embryo). Embryos absorbed only Arg (183 pmol/embryo) and secreted the other 22 amino acids (total, 3,697 pmol/embryo) when the culture medium was not changed during the entire culture period (zygote to blastocyst).     

The Metabolomic Profile of Spent Culture Media from Day-3 Human Embryos Cultured under Low Oxygen Tension

Despite efforts made to improve the in vitro embryo culture conditions used during assisted reproduction procedures, human embryos must adapt to different in vitro oxygen concentrations and the new metabolic milieu provided by the diverse culture media used for such protocols. It has been shown that the embryo culture environment can affect not only cellular metabolism, but also gene expression in different species of mammalian embryos. Therefore we wanted to compare the metabolic footprint left by human cleavage-stage embryos under two types of oxygen atmospheric culture conditions (6% and 20% O₂). The spent culture media from 39 transferred and implanted embryos from a total of 22 patients undergoing egg donation treatment was analyzed; 23 embryos came from 13 patients in the 6% oxygen concentration group, and 16 embryos from 9 patients were used in the 20% oxygen concentration group. The multivariate statistics we used in our analysis showed that human cleavage-stage embryos grown under both types of oxygen concentration left a similar metabolic fingerprint. We failed to observe any change in the net depletion or release of relevant analytes, such as glucose and especially fatty acids, by human cleavage-stage embryos under either type of culture condition. Therefore it seems that low oxygen tension during embryo culture does not alter the global metabolism of human cleavage-stage embryos.     

Intracytoplasmic glutathione concentration and the role of beta-mercaptoethanol in preimplantation development of bovine embryos

In vitro-matured/in vitro-fertilized bovine oocytes were cultured on cumulus cell layers in a serum-free medium (bovine embryo culture medium; BECM) supplemented with 3 mg/ml fatty acid-free BSA. The intracytoplasmic glutathione concentration of embryos was found to change significantly (P < 0.008) during the preimplantation stages, beginning to increase at the 9- to 16-cell stage (20.7 pM/embryo) and reaching the highest (P < 0.03) level at the hatched-blastocyst stage (36.7 pM/embryo). A significantly (P < 0.06) lower concentration of glutathione was obtained at the 2- to 8-cell stage (7.1 pM/embryo) than at any other stage. When inseminated oocytes were cultured in BECM supplemented with different concentrations of beta-mercaptoethanol (2-ME) to promote glutathione synthesis, higher (P < 0.05) percentages of embryos developed to the 9- to 16-cell, morula and blastocyst stages at 96, 144 and 192 h post insemination, following the addition of 6.25 and 12.5 microM than after no supplementation with 2-ME. However, when 16-cell embryos were cultured in BECM supplemented with 6.25 and 12.5 microM of 2-ME, blastocyst formation was not significantly (P > 0.9) increased. When the combined effects of 2-ME and/or cumulus cells were compared in a 2 x 2 factorial design, there was a significant (P < 0.03) effect of 2-ME on the development of oocytes to blastocysts. The presence of cumulus cells significantly (P < 0.001) affected development after the fourth cleavage (morula compaction and blastocyst formation), but there was no significant (P > 0.11) interaction between 2-ME and cumulus cells. In conclusion, intracytoplasmic glutathione concentration of bovine embryos derived from in vitro-culture increases during preimplantation development. The glutathione synthesis promoter 2-ME exerts its embryotropic role on the development before the fourth cleavage, thus yielding an improvement in blastocyst formation.     

Promoting effect of beta-mercaptoethanol on in vitro development under oxidative stress and cystine uptake of bovine embryos

The effects of beta-mercaptoethanol (beta-ME) on in vitro development under oxidative stress and cystine uptake of bovine embryos were investigated. Bovine 1-cell embryos obtained by in vitro fertilization were cultured in TCM-199 or synthetic oviductal fluid (SOF) in 20% O(2) supplemented with beta-ME. Addition of beta-ME significantly (P < 0.01) promoted embryo development when cultured in both TCM-199 and SOF under high levels of O(2), to almost the same rates when they were cultured in 5% O(2). To investigate whether the growth-promoting effect of beta-ME was related to cystine uptake, which is an important amino acid for intracellular glutathione (GSH) synthesis, 1-cell, 8-cell, morula, and blastocyst stage embryos were incubated in cystine, cysteine-free TCM-199 containing radioisotope-labeled cystine supplemented with or without beta-ME. It was found that cystine uptake was consistently low in each embryo stage incubated without beta-ME. In contrast, addition of beta-ME significantly (P < 0.05 to 0.0001) promoted cystine uptake in each stage of embryo development. This increase of cystine uptake by beta-ME was significantly inhibited by supplementation of buthionine sulfoximine, a specific inhibitor of GSH biosynthesis (P < 0.0001). High-performance liquid chromatography (HPLC) analysis clearly revealed a decrease of cystine in culture medium after supplementation by beta-ME, thereby forming another peak. HPLC analysis also showed the incorporated cystine by supplementation of beta-ME was possibly metabolized for GSH synthesis in the embryos. These results indicate that beta-ME has a protective effect in embryo development against oxidative stress and that the effect of beta-ME is associated with the promotion of cystine uptake of low availability in embryos.     

小鼠胚胎体外发育培养基中氨基酸含量变化

通过检测哺乳动物早期胚胎体外发育过程中可以消耗或生成某些氨基酸的含量,可以了解胚胎的发育潜能。利用反相高效液相色谱法(RP-HPLC)检测KSOMaa培养基中17种氨基酸含量的变化,了解昆明小白鼠(Mus musculus)植入前胚胎体外培养过程中氨基酸含量的变化,旨在寻找一种能有效支持昆明小鼠胚胎体外发育的培养基氨基酸组成,优化小鼠胚胎体外培养体系。将180枚原核胚分为9组,体外培养至囊胚,分别于胚胎发育不同时期取样做高效液相色谱分析。这些氨基酸在胚胎发育不同时期的培养基中含量变化可分为5种类型:①在2细胞期增加但在4细胞期、8～16细胞期减少,囊胚期又增加的氨基酸(甘氨酸、亮氨酸、苏氨酸、缬氨酸、苯丙氨酸、酪氨酸);②在胚胎发育各个时期均下降(谷氨酸、甲硫氨酸、精氨酸、组氨酸);③在胚胎发育各个时期均增加(丝氨酸、赖氨酸、丙氨酸);④2细胞期含量减少而在其他时期持续增加(天冬氨酸、脯氨酸、色氨酸);⑤囊胚期减少,其他时期都有增加(异亮氨酸)。     

Assessment of embryo potential by visual and metabolic evaluation

Morphological evaluation of embryos is essential to the success of embryo transfer procedures and is presumed to reflect embryo metabolic activity. To investigate this assumption, correlations between morphological and metabolic parameters were determined for cultured murine morulae. After 18 h (n = 47) or 36 h (n = 48) of culture in M16, the developmental rate and quality (poor or good) of embryos were estimated, and, then, either their (14)C-glucose utilization or (35)s-methionine uptake and incorporation were measured. Retarded developing, or poor-quality embryos had lower mean glucose utilization, uptake and incorporation rates than normally developing or good-quality embryos (P < 0.05). After 18 h of culture, an association was found between developmental rate and metabolic activity, but this was not evident after 36 h of culture. Similarly, an association was found between embryo quality and metabolic activity. As expected, poor embryo quality was indicative of low metabolism throughout the culture period, but good quality did not necessarily indicate normal metabolic activity. Thus, morphological parameters do not always reflect metabolic competence, and some functional defects were not detectable by visual evaluation alone. Measuring metabolic parameters could complement visual evaluation for a better selection of embryos prior to transfer.     

Energy status and its control on embryogenesis of legumes. Embryo photosynthesis contributes to oxygen supply and is coupled to biosynthetic fluxes

Legume seeds are heterotrophic and dependent on mitochondrial respiration. Due to the limited diffusional gas exchange, embryos grow in an environment of low oxygen. O(2) levels within embryo tissues were measured using microsensors and are lowest in early stages and during night, up to 0.4% of atmospheric O(2) concentration (1.1 micro M). Embryo respiration was more strongly inhibited by low O(2) during earlier than later stages. ATP content and adenylate energy charge were lowest in young embryos, whereas ethanol emission and alcohol dehydrogenase activity were high, indicating restricted ATP synthesis and fermentative metabolism. In vitro and in vivo experiments further revealed that embryo metabolism is O(2) limited. During maturation, ATP levels increased and fermentative metabolism disappeared. This indicates that embryos become adapted to the low O(2) and can adjust its energy state on a higher level. Embryos become green and photosynthetically active during differentiation. Photosynthetic O(2) production elevated the internal level up to approximately 50% of atmospheric O(2) concentration (135 micro M). Upon light conditions, embryos partitioned approximately 3-fold more [(14)C]sucrose into starch. The light-dependent increase of starch synthesis was developmentally regulated. However, steady-state levels of nucleotides, free amino acids, sugars, and glycolytic intermediates did not change upon light or dark conditions. Maturing embryos responded to low O(2) supply by adjusting metabolic fluxes rather than the steady-state levels of metabolites. We conclude that embryogenic photosynthesis increases biosynthetic fluxes probably by providing O(2) and energy that is readily used for biosynthesis and respiration.     

Effects of oxygen tension and humidity on the preimplantation development of mouse embryos produced by in vitro fertilization: analysis using a non-humidifying incubator with time-lapse cinematography

To examine the effects of oxygen tension and humidity on early embryonic development, the preimplantation development of mouse embryos produced by in vitro fertilization was assessed by time-lapse cinematography to evaluate morphokinetic development with higher precision. Zygotes were produced from spermatozoa and oocytes from ICR mice and cultured in KSOM under low or high oxygen tension in a non-humidified incubator with time-lapse cinematography (CCM-iBIS). The developmental rates of embryos to the 4-cell and blastocyst stages under lower oxygen tension in CCM-iBIS were significantly higher than those under higher oxygen tension in CCM-iBIS. Ninety-six hours after insemination, a large number of embryos cultured under low oxygen tension developed to the hatching blastocyst stage. Embryonic development was more synchronized under lower oxygen tension. Non-humidified cultures did not affect embryonic development. On average, mouse embryos cultured at lower oxygen tension reached 2-cell at 18 h, 3-cell at 39 h, 4-cell at 40 h, initiation of compaction at 58 h, morula at 69 h, and blastocyst at 82 h after insemination. In conclusion, lower oxygen tension better supports preimplantation development of mouse embryos fertilized in vitro, and non-humidified culture conditions do not influence the embryonic development in vitro.     

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.