Influence of genetic background and media components on the development of mouse embryos in vitro

One-cell embryos from some inbred and random-bred mice, but not those derived from certain F1 hybrids, suffer from a block during in vitro development known as the two-cell block. This two-cell block can be overcome by removing glucose or inorganic phosphate from the culture system or by altering the ratio of other medium components such as sodium, potassium, or bicarbonate. This issue is made more complex by the fact that the rate of development is different for each strain of mouse and this rate of development is invariably slowed under in vitro culture conditions. This study investigated the role of glucose and inorganic phosphate, individually or in combination, in relation to the two-cell block, and rate of development in vitro of two random-bred strains (CF-1 and CD-1) and an F2 hybrid derived from a nonblocking F1 hybrid cross (C57B1/6NCr × C3H/HeNCr). Results were compared with in vivo data for each strain, and between media. There was a significant difference in the rate of preimplantation development in vivo of the three strains chosen, which was mirrored in vitro, regardless of the medium. The two random-bred strains suffered from a glucose-related two-cell block which was primarily mediated by inorganic phosphate. Inorganic phosphate was detrimental to embryo development regardless of strain or the presence of glucose. Although glucose, in the absence of inorganic phosphate, resulted in some blocking in development in the inbred strains initially, its presence in media was associated with increased rates of development at later stages in embryos that did not block. Glucose, but not inorganic phosphate, was beneficial but not essential to the development of the F2 embryos. The results of this study demonstrated that mouse embryos from different strains have differential rates of development in vivo and in vitro, and different sensitivities to glucose and inorganic phosphate. The two-cell block was primarily induced in the combined presence of glucose and inorganic phosphate. Glucose was beneficial in the absence of inorganic phosphate, and inorganic phosphate was detrimental to the rate of in vitro development. © 1996 Wiley-Liss Inc.     

Nuclear accumulation of cyclin B1 in mouse two-cell embryos is controlled by the activation of Cdc2

In the present study, the sequential expression and cellular localization of cyclin B1 was examined in two-cell mouse embryos to elucidate the mechanism of the two-cell block. One-cell embryos derived from in vitro fertilization were cultured with oviductal tissue (nonblocking condition) or without oviductal tissue (blocking condition) to establish the experimental conditions in which the embryos either overcome the two-cell block or do not. The amount of cyclin B1 gradually increased through the second cell cycle (through S to G2 phase). However, the difference was not observed between culture conditions. This showed that even embryos exhibiting the two-cell block normally synthesize cyclin B1 through the cell cycle. Cyclin B1 in embryos cultured under nonblocking condition accumulates in the nucleus during the transition from the G2 to the M phase, whereas that in embryos cultured in blocking condition localizes in the cytoplasm throughout the cell cycle. These data indicate that two-cell embryos cultured in blocking condition are able to normally synthesize cyclin B1 but have defects in nuclear accumulation of the protein. However, when two-cell blocked embryos were treated with okadaic acid, an activator of Cdc2 kinase, part of cyclin B1 in the embryos translocated into the nucleus. Moreover, treatment with butyrolactone I, a specific inhibitor of Cdc2 kinase, inhibits nuclear translocation of cyclin B1 in those embryos. These results suggest that Cdc2 kinase regulates the nuclear accumulation of cyclin B1 in mouse two-cell embryos.     

The dynamic provision of different energy substrates improves development of one-cell random-bred mouse embryos in vitro.

Preliminary observations showed that one-cell embryos from random-bred MF1 mice avoid cleavage arrest at the two-cell stage ('in vitro two-cell block') when cultured in modified M16 culture medium containing lactate and pyruvate but lacking glucose. The roles of lactate, pyruvate and glucose during preimplantation development of embryos from random-bred mice in vitro were therefore examined. When all three substrates were present continuously during culture, one-cell embryos arrested at the two- to four-cell stages. Improved development to the morula stage after 96 h in culture was obtained in media containing pyruvate alone, lactate and pyruvate, pyruvate and glucose, lactate pyruvate and glucose for the first 24 h, and medium containing lactate and pyruvate for the remaining 72 h. In a second experiment, embryos were cultured in medium containing pyruvate alone, lactate and pyruvate or pyruvate and glucose for the first 24 h, and lactate plus pyruvate medium for the second 24 h. Subsequent transfer to medium containing lactate, pyruvate and glucose supported the morula to blastocyst transition. These results show that developmental arrest in vitro can be overcome by changing the combination of energy substrates at different stages of preimplantation development.     

Analysis of specific factors generating 2-cell block in AKR mouse embryos

The phenomenon of the developmental arrest at the 2-cell stage of 1-cell embryos from some mouse strains during in vitro culture is known as the 2-cell block. We investigated the specific factors involved in the 2-cell block of AKR embryos by means of a modified culture system, the production of reconstructed embryos by pronuclear exchange and a cross experiment. In a culture medium with phosphate, 94.6% of 1-cell embryos from the C57BL mouse strain developed to the blastocyst stage, but 95.7% of embryos from the AKR mouse strain showed 2-cell block. Phosphate-free culture medium rescued the 2-cell block of AKR embryos and accelerated the first cell cycle of the embryos. Co-culture with BRL cells and a BRL-conditioned medium fractionated below 30 kDa also rescued the 2-cell block of AKR embryos. Examinations of in vitro development of reconstructed embryos and of embryos from F1 females between AKR and C57BL strains clearly demonstrated that the AKR cytoplast caused the 2-cell block. In the backcrossed female progeny between (AKR x C57BL) F1 males and AKR females, about three-quarters of the embryos were of the 2-cell blocking phenotype and about one-quarter were of the non-blocking phenotype. These results suggest that two genes are responsible for the 2-cell block of AKR embryos.     

Hypoxanthine causes a 2-cell block in random-bred mouse embryos

Ham's F-10, a chemically defined, complex culture medium, commonly used for in vitro fertilization of human as well as animal oocytes, blocked development at the 2-cell stage of greater than 92% of embryos from random-bred Swiss mice (CD-1), but did not block development of embryos from hybrid-inbred mice (BDF1). In contrast, BWW, a simple, modified Kreb's-Ringer bicarbonate medium, supported development to blastocysts of 85% and 100% of 2-cell embryos from CD1 and BDF1 females, respectively. As little as 15% (v/v) Ham's F-10 added to the BWW blocked the development of the random-bred embryos. Supplementing the BWW with Ham's F-10 components revealed that hypoxanthine (6-30 microM) was responsible for the developmental block to the random-bred embryos. The hypoxanthine block was partially (40%) reversed by adding the chelating agent, ethylenediaminetetraacetic acid. Breeding experiments showed that the hypoxanthine sensitivity of embryos from CD-1 mothers was not affected by the paternal genome.     

Delay of ZGA initiation occurred in 2-cell blocked mouse embryos

One-cell mouse embryos from KM strain and B6C3F1 strain were cultured in M16 medium, in which2-cell block generally occurs. Embryos of KM strain exhibited 2-cell block, whereas B6C3F1 embryos,which are regarded as a nonblocking strain, proceeded to the 4-cell stage in our culture condition. It is oftenassumed that the block of early development is due to the failure of zygotic gene activation (ZGA) in culturedembryos. In this study we examined protein synthesis patterns by two-dimensional gel electrophoresis of[35^S] methionine radiolabeled 2-cell embryos. Embryos from the blocking strain and the nonblocking strainwere compared in their development both in vitro and in vivo. The detection of TRC expression, a markerof ZGA, at 42 h post hCG in KM embryos developed in vitro suggested that ZGA was also initiated even inthe 2-cell arrested embryos. Nevertheless, a significant delay of ZGA was observed in KM strain as comparedwith normally developed B6C3F1 embryos. At the very beginning of major ZGA as early as 36 h post hCG,TRC has already been expressed in B6C3F1 embryos developed in vitro and KM embryos developed in vivo.But for 2-cell blocked KM embryos, TRC was still not detectable even at 38 h post hCG. These evidences suggest that 2-cell-blocked embryos do initiate ZGA, and that 2-cell block phenomenon is due not to the disability in initiating ZGA, but to a delay of ZGA.     

Changes in the distribution of mitochondria in mouse embryos blocked at the two-cell stage

Changes in the distribution of mitochondria in the two-cell mouse embryos preceding the developmental arrest in vitro, caused by a genetically determined "two-cell block in vitro" or genisteine treatment, were examined vitally using the mitochondrial-specific probe rhodamine 123 and conventional fluorescence microscopy. In the former case, serious disturbances in the localization of mitochondria appeared already from the middle of two-cell stage, long before the time corresponding to the 2nd cleavage division. Comparison of the behavior of mitochondria in the embryos successfully developing between the one- and two-cell stages and that in the embryos that ceased to cleave suggests that the developmental arrest was accompanied by aggregation of the mitochondria into clusters. There are many such clusters unlike in the cytoplasm of normally developing embryos. Intracellular localization of clusters observed in the genisteine-treated embryos differed radically from that observed in the embryos blocked in vitro at the two-cell stage.     

Role of glucose in mouse preimplantation embryo development

Mouse preimplantation embryos consume pyruvate preferentially during the early developmental stages, before glucose becomes the predominant energy substrate in the blastocyst. To investigate the importance of the switch to glucose utilization at the later developmental stages, mouse embryos from F1 hybrid mice (CBA/Ca × C57BL/6) were cultured from the one-and two-cell stages (22 and 46 h post hCG, respectively) for 5 days in a modified medium, M16, containing 0.33 mM pyruvate and 5 or 23 mM D+L-lactate, in the presence and absence of 1 mM glucose (M16+G and M16-G, respectively). Nutrient uptakes were also determined over this time. Some embryos cultured in M16-G were transferred to M16+G at 94 or 118 h post hCG. Embryos cultured from the two-cell stage in M16+G exhibited the characteristic fall in pyruvate consumption between the morula and the blastocyst stage; those cultured from the two-cell stage in M16-G compensated for the lack of glucose by consuming increasing amounts of pyruvate, from 2.78 pmol/embryo/h at 58 h post hCG to 5.21 pmol/embryo/h at 154 h post hCG. However, the percentage of embryos developing to the blastocyst stage, the hatching rate, and blastocyst cell numbers (50.6 ± 2.5 [28] vs. 105 ± 3.8 [37]) were all lower in this group. When exposed to glucose at 94 or 118 h post hCG, embryos cultured from the two-cell stage in M16-G readily consumed glucose in preference to pyruvate, although the characteristic fall in pyruvate consumption was not observed. One-cell embryos cultured continuously in M16-G were only able to develop to the morula stage, after which time they degenerated. In these embryos pyruvate was readily consumed between 22 and 94 h post hCG, before falling from 2.77 pmol/embryo/h at 83 h post hCG to 0.045 pmol/embryo/h at 130 h post hCG. Transfer of these embryos to M16+G at 94 and 118 h post hCG did not support development to the hatching blastocyst stage. The results show that mouse preimplantation embryos from F1 hybrid mice (CBA/Ca × C57BL/6) need only be exposed to glucose for less than 24 h between 22 and 94 h post hCG in order to develop from the morula to the blastocyst stage in vitro. However, the exposure time needs to be increased to between 24 and 72 h in order that blastocyst cell numbers reach control levels. The importance of glucose before the morula stage may relate to the need to synthesize glycogen for later use. If the obligatory requirement for glucose is fulfilled, embryos are able to utilize pyruvate in the absence of glucose at the later stages of development. These results show that the mouse preimplantation embryo can, to some extent, adapt metabolically to changes in its external environment. © 1995 Wiley-Liss, Inc.     

Effects of glucose, glutamine, ethylenediaminetetraacetic acid and oxygen tension on the concentration of reactive oxygen species and on development of the mouse preimplantation embryo in vitro.

Analysis over the first 48 h of development in vitro from the one-cell stage to the early four-cell stage indicated that (i) ethylenediaminetetraacetic acid (EDTA) exerts the major beneficial effect on culture to the blastocyst stage of F1 and MF1 embryos, (ii) glutamine assists development of MF1, but not F1, embryos to the blastocyst stage and probably functions as part of a metabolic response to oxidative damage to mitochondria and (iii) exposure to glucose at some time during early cleavage is essential for full development to blastocysts. None of the culture conditions examined affected significantly the increase in concentration of reactive oxygen species in late two-cell embryos in vitro, although F1 embryos in vitro often had lower peroxide concentrations than MF1 embryos. A decline in oxygen tension from 20 to 50% had no consistent effect on culture to the blastocyst stage or production of reactive oxygen species. Aminooxyacetate, an inhibitor of transaminase activity, prevented non-blocking embryos from developing beyond G2 of the second cell cycle. It is concluded that the chelation of transitional metals provides the most effective method of overcoming the block to development in vitro.     

Insulin-related peptides and the two-cell block to development in pre-implantation mouse embryos

Abstract. In many mammalian embryos development in vitro is arrested after the first zygotic division, a phenomenon known as the two-cell block. In the mouse several strains exhibit a two-cell block to further development and it was the purpose of this investigation to determine whether the inability of embryos to progress through the block was due to lack of insulin or insulin-like growth factors (IGFs) in the medium. Several factors have been implicated in the two-cell block, amongst which oxidative stress, glucose and missing maternal factors have been examined to date. Because of their anabolic and anti-apoptotic properties, IGFs are good candidates for such missing maternal factors. Using MF1 strain mice and M16 medium we have examined the effects of IGF-I, II and insulin on the two-cell block. No effects were discernable at concentrations known to support development of non-blocking embryos and we conclude that the IGFs and insulin may be excluded as critical factors in the two-cell block under the culture conditions used.     

Development of mouse embryos in vitro is affected by strain and culture medium

One-cell and two-cell embryos from three random-bred strains of mice–CF1, Dub:(ICR), and CFW (Swiss-Webster)–were cultured to the blastocyst stage in Spindle's, Earle's, Ham's F10, Whittingham's T6, or Hoppe and Pitts' medium. CFW embryos were more successful than CF1 and Dub:(ICR) embryos in developing to the blastocyst stage in all five media. Dub:(ICR) and CFW two-cell embryos showed the best development in Spindle's, Whittingham's T6, and Hoppe and Pitts', whereas CF1 two-cell embryos were most successful in developing in Hoppe and Pitts' medium. Similar results were obtained with one-cell embryos, although fewer developed to the blastocyst stage, and T6 rather than Hoppe and Pitts' medium sustained the best development of CF1 one-cell embryos. For all strains, the least successful development was in Ham's F10, but CFW embryos did show good development in this medium. In addition to the effects of various media on mouse embryo development, our results indicate that the strain of mouse used for the bioassay of media is of critical importance. Random-bred CFW (Swiss-Webster) mice are as suitable as a hybrid strain for this purpose.     

Dynamics of morphofunctional organization and developmental potential of mouse embryos in the state of "two-cell block in vitro"

Vital observation in combination with electron microscopy and immunocytochemistry was used for studying structural organization and developmental potential of BALB/c mouse embryos after cleavage cessation at a two cell stage caused by the "two-cell block in vitro" phenomenon. Modification of structure and viability of embryos was followed for 2 days from the time of cleavage arrest. Several hours before cleavage arrest, changes in mitochondrian distribution were noticed in embryos, no other disturbances in structural organization of blastomeres being obvious. Embryos, whose development was arrested for 24 h, remained viable and demonstrated some morphological changes similar to those seen in normally developing embryos of the same age. Towards the end of a 48 h block period some embryos died, the surviving embryos remained morphologically intact and metabolically active. At the same time, the nuclei of the latter frequently displayed chromatin condensation near the nuclear membrane, which is similar to the pattern of chromatin reorganization in the nuclei of early apoptotic cells. Our results support a concept on the "two-cell block in vitro" phenomenon as a specific functional state of embryos, and well compare with data on a partial realization by blocked embryos of the developmental program.     

Characterization of developmental arrest in early bovine embryos cultured in vitro

The susceptibility of early bovine embryos to developmental arrest ("blocking") in vitro was examined. Embryos, obtained from superovulated donors, were cultured in vitro in Ham's F10 culture medium or in vivo in sheep oviducts. Treatments were terminated on Day 7 post-donor estrus (estrus = day 0), and the embryos were evaluated for development. Experiment 1 tested whether the 8- to 16-cell block was reversible. One- to two-cell embryos were cultured in vitro to the 8-cell stage (2 d), then in vivo for 3 d; controls were cultured in vitro or in vivo for 5 d. Forty-two percent (19 45 ) of in vivo controls developed normally; none (0 55 ; 0%) of the in vitro controls cleaved past the 9- to 16-cell stage. Only 4% (2 48 ) of the embryos cultured to eight cells in vitro developed normally after culture in sheep oviducts, indicating that the block was irreversible. Irreversibility was not caused by overt cell death, since 33 33 (100%) of blocked embryos responded positively to fluorescien diacetate vital staining. Experiment 2 tested the effect of in vitro exposure at specific cell stages on subsequent in vivo development. Embryos at the 1- to 2-, 3- to 4-, 5- to 8- and 9- to 16-cell stages were assigned randomly to one of the following treatments: in vivo culture; in vitro culture; or 24 h in vitro culture, followed by in vivo culture. Subsequent in vivo development was affected by 24 h of in vitro culture (P<0.05) only in 3- to 4-cell embryos (11 41 , 27% vs 22 41 , 54% for in vivo controls). We conclude that 1) the block is a manifestation of in vitro exposure during the four- to eight-cell stage, and 2) the block, while irreversible, is not the result of overt embryonic death.     

Genetic and epigenetic factors affecting blastomere fragmentation in two-cell stage mouse embryos

We report here that mouse embryos can exhibit a significant incidence of blastomere fragmentation at the two-cell stage. The incidence of this is influenced by both the maternal and paternal genotype. Embryos from C57BL/6 mothers exhibit a very low incidence of fragmentation at the two-cell stage in crosses involving males of C57BL/6, DBA/2, AKR/J, or SJL strains but exhibit a significantly increased incidence of fragmentation in crosses involving C3H/HeJ males. Increased fragmentation is seen in embryos from C3H/HeJ females crossed with C57BL/6 males but not with C3H/HeJ males. Embryos obtained from reciprocal (C57BL/6 x C3H/HeJ) F1 hybrid females also exhibit an increased incidence of fragmentation at the two-cell stage when the hybrid females are mated to either C57BL/6 or C3H/HeJ males. Interestingly, the results differ significantly between reciprocal F1 hybrid females, indicating a parental origin effect, possibly a result of either genomic imprinting or differences in mitochondrial origin. We conclude that the incidence of blastomere fragmentation at the two-cell stage in the mouse is under the control of more than one genetic locus. We also conclude that blastomere fragmentation is affected by both parental genotypes. These results are relevant to understanding the genetic control blastomere fragmentation, which may contribute to evolutionary processes, affect the success of procedures such as cloning, and affect the outcome of assisted reproduction techniques.     

Changes in the distribution of mitochondria in mouse embryos blocked at the two-cell stage

Changes in the distribution of mitochondria in the two-cell mouse embryos preceding the developmental arrest in vitro, caused by a genetically determined two-cell block in vitro or genisteine treatment, were examined vitally using the mitochondrial-specific probe rhodamine 123 and conventional fluorescence microscopy. In the former case, serious disturbances in the localization of mitochondria appeared already from the middle of two-cell stage, long before the time corresponding to the 2nd cleavage division. Comparison of the behavior of mitochondria in the embryos successfully developing between the one- and two-cell stages and that in the embryos that ceased to cleave suggests that the developmental arrest was accompanied by aggregation of the mitochondria into clusters. There are many such clusters unlike in the cytoplasm of normally developing embryos. Intracellular localization of clusters observed in the genisteine-treated embryos differed radically from that observed in the embryos blocked in vitro at the two-cell stage.Translated from Ontogenez, Vol. 36, No. 1, 2005, pp. 51–60.Original Russian Text Copyright © 2005 by Bogolyubova.     

Two-cell block to development of cultured hamster embryos is caused by phosphate and glucose

The failure of hamster 2-cell embryos to develop in vitro (2-cell block) was examined with experiments in which concentrations of glucose and phosphate in the culture medium were varied. Embryos were cultured in a protein-free modified Tyrode's solution that normally contains 5.0 mM glucose and 0.35 mM sodium dihydrogen phosphate. In the presence of 0.35 mM phosphate but without glucose, 23% of 2-cell embryos reached the 4-cell stage or further after culture for 1 day and 27% after 2 days. Glucose inhibited embryo development even at 0.1 mM (4% development to greater than or equal to 4-cells after culture for 2 days); there was no dose-related inhibition above this glucose concentration. In a second experiment, phosphate levels were varied in the absence of glucose. Phosphate was highly inhibitory to development, with 97% of 2-cell embryos reaching the 4-cell stage or further after culture for 1 day in the absence of phosphate compared to 9-21% in the presence of 0.1-1.05 mM phosphate. After culture for 2 days, 26% of embryos reached the 8-cell stage or further when phosphate was absent compared to 0% development to 8-cells with 0.1 mM phosphate or higher. In a factorial experiment, phosphate blocked development when glucose was present or absent, whereas glucose did not block embryo development in the absence of phosphate. However, 2-deoxyglucose (a non-metabolizable analogue of glucose) inhibited embryo development in the absence of phosphate. These data show that the in vitro block to development of hamster 2-cell embryos is caused at least in part by glucose and/or phosphate. Deletion of these compounds from the culture medium eliminates the 2-cell block to development in virtually all embryos, and approximately 25-75% of embryos develop to the 8-cell or morula stages in vitro. The observations provide a possible explanation for the 2-cell and 4-cell blocks that occur in conventional culture media: stimulation of glycolysis by glucose and/or phosphate may result in inefficient adenosine triphosphate (ATP) production. The data indicate marked dissimilarities in the regulation of in vitro development of early cleavage stage hamster embryos compared with embryos of inbred mice, since the latter have an inactive glycolytic pathway prior to the 8-cell stage of development and will grow from 1-cell to blastocyst with both phosphate and glucose in the culture medium.     

Hypoxanthine-maintained two-cell block in mouse embryos: dependence on glucose and effect of hypoxanthine phosphoribosyltransferase inhibitors

The culture conditions under which hypoxanthine maintains a two-cell block in preimplantation mouse embryos were assessed. Hypoxanthine prevented embryo development past the two-cell stage at concentrations as low as 30 nM, and this inhibitory activity required the presence of D-glucose. The action of hypoxanthine plus D-glucose was reversed by glutamine and higher lactate. D-mannose substituted for D-glucose in supporting the inhibitory action of hypoxanthine, but L-glucose, D-fructose, and 2-deoxyglucose were much less effective. Other purine derivatives such as inosine and adenosine, but not xanthosine or uric acid, also blocked development at the two-cell stage at a concentration of 30 microM, and guanosine was inhibitory at higher doses. Assays of hypoxanthine phosphoribosyltransferase (HPRT) activity in lysates of four-cell embryos determined that the drugs 6-mercapto-9-(tetrahydro-2-furyl)-purine (MPTF) and 6-mercaptopurine (6-MP), but not 6-azauridine (6-AzaU), prevented salvage of hypoxanthine. In addition, MPTF and 6-MP produced a significant two-cell block, which did not depend upon the presence of hypoxanthine or D-glucose; whereas 6-AzaU was without effect. When embryos were cultured 2 days in the presence or absence of D-glucose, hypoxanthine salvage was significantly reduced in lysates of four-cell embryos exposed to D-glucose. D-glucose had no effect when added directly to the assay mixture. These data demonstrate that the ability of hypoxanthine to block embryo development at the two-cell stage depends on the presence of D-glucose or other glycolyzable sugars and suggest that inhibition of the purine salvage pathway promotes the two-cell block.     

Developmental changes in inhibitory effects of arsenic and heat shock on growth of pre-implantation bovine embryos

Although sensitive to various disrupters, pre-implantation embryos possess some cellular cytoprotective mechanisms that allow continued survival in the face of a deleterious environment. For stresses such as heat shock, embryonic resistance increases as development proceeds. Present objectives were to determine whether (1) arsenic compromises development of pre-implantation bovine embryos, (2) developmental changes in embryonic resistance to arsenic mimic those seen for resistance to heat shock, and (3) developmental patterns in induction of apoptosis by arsenic are correlated with similar changes in resistance of embryos to inhibitory effects of arsenic on development. Bovine embryos produced by in vitro fertilization were exposed at the two-cell stage or at day 5 after insemination (embryos > or = 16-cells in number) to either sodium arsenite (0, 1, 5, or 10 microM) or heat shock (exposure to 41 degrees C for 0, 3, 4.5, 6, or 9 hr). Arsenic induced apoptosis and increased group 2 caspase activity for embryos at the > or = 16-cell stage, but not for embryos at the two-cell stage. In contrast to these developmental changes in apoptosis responses, exposure to arsenic reduced cell number 24 hr after exposure for both two-cell embryos and embryos > or = 16-cells. Similarly, the percentage of embryos that developed to the blastocyst stage at day 8 after fertilization was reduced by arsenic exposure at both stages of development. Heat shock, conversely, reduced development to the blastocyst stage when applied at the two-cell stage, but not when applied to embryos > or = 16-cells at day 5 after insemination. In conclusion, arsenic can compromise development of bovine pre-implantation embryos, the temporal window of sensitivity of embryos to arsenic is wider than for heat shock, and cellular cytoprotective responses that embryos acquire for thermal resistance are not sufficient to cause increased embryonic resistance to arsenic exposure. It is likely that despite common cellular pathologies caused by arsenic and heat shock, arsenic acts to reduce development in part through biochemical pathways not activated by heat shock. Moreover, the embryo does not acquire significant resistance to these perturbations within the time frame in development examined.