Teratogen-induced activation of caspase-6 and caspase-7 in early postimplantation mouse embryos.

BACKGROUND: Previous work has shown that teratogens such as hyperthermia (HS), 4-hydroperoxycyclophosphamide (4CP), and staurosporine (ST) induce cell death in day 9 mouse embryos by activating the mitochondrial apoptotic pathway. Key to the activation of this pathway is the activation of a caspase cascade involving the cleavage-induced activation of an initiator procaspase, caspase-9, and the downstream effector procaspase, caspase-3. For example, procaspase-3, an inactive proenzyme of 32 kDa is cleaved by activated caspase-9 to generate a large subunit of approximately 17 kDa and a small subunit of approximately 10 kDa. In turn, caspase-3 is known to target a variety of cellular proteins for proteolytic cleavage as part of the process by which dying cells are eliminated. Previous work has also shown that neuroepithelial cells are sensitive to teratogen-induced activation of this pathway and subsequent cell death whereas cells of the heart are resistant. Although caspase-3 is a key effector caspase activated by teratogens, two other effector caspases, caspase-6 and caspase-7, are known; however, their role in teratogen-induced cell death is unknown. METHODS: Because cleavage-induced generation of specific subunits is the most specific assay for activation of caspases, we have used antibodies that recognize the procaspase and one of its active subunits and a Western blot approach to assess the activation of caspase-6 and caspase-7 in day 9 mouse embryos (or heads, hearts and trunks isolated from whole embryos) exposed to HS, 4CP, and ST. To probe the relationship between teratogen-induced activation of caspase-9/caspase-3 and the activation of caspase-6/caspase-7, we used a mitochondrial-free embryo lysate with or without the addition of cytochrome c, recombinant active caspase-3, or recombinant active caspase-9. RESULTS: Western blot analyses show that these three teratogens, HS, 4CP, and ST, induce the activation of procaspase-6 (appearance of the 13 kDa subunit, p13) and caspase-7 (appearance of the 19 kDa subunit, p19) in day 9 mouse embryos. In vitro studies showed that both caspase-6 and caspase-7 could be activated by the addition of cytochrome c to a lysate prepared from untreated embryos. In addition, caspase-6 could be activated by the addition of either recombinant caspase-3 or caspase-9 to a lysate prepared from untreated embryos. In contrast, caspase-7 could be activated by addition of recombinant caspase-3 but only minimally by recombinant caspase-9. Like caspase-9/caspase-3, caspase-6 and caspase-7 were not activated in hearts isolated from embryos exposed to these three teratogens. CONCLUSIONS: HS, 4CP and ST induce the cleavage-dependent activation of caspase-6 and caspase-7 in day 9 mouse embryos. Results using DEVD-CHO, a caspase-3 inhibitor, suggest that teratogen-induced activation of caspase-6 is mediated by caspase-3. In addition, our data suggest that caspase-7 is activated primarily by caspase-3; however, we cannot rule out the possibility that this caspase is also activated by caspase-9. Finally, we also show that teratogen-induced activation of caspase-6 and caspase-7 are blocked in the heart, a tissue resistant to teratogen-induced cell death.

Co-localization of active caspase-3 and DNA fragmentation (TUNEL) in normal and hyperthermia-induced abnormal mouse development.

BACKGROUND: Previous work has shown that caspase-3 activation and DNA fragmentation, two hallmarks of apoptosis, are induced in day 9 mouse embryos exposed to hyperthermia (43 degrees C); however, the methods used to assess caspase-3 activation (Western blot) and DNA fragmentation (gel electrophoresis) did not allow these apoptotic events to be localized to specific cells within the embryo. METHODS: To co-localize active caspase-3 and DNA fragmentation to specific cells, we used paraffin sections of day 13 mouse limb buds, sections of control and hyperthermia-treated day 9 mouse embryos, and sequential immunohistochemical staining for caspase-3 and TUNEL staining for DNA fragmentation. We used a primary rabbit antibody specific for the active, p17 subunit of caspase-3 and a goat anti-rabbit secondary antibody conjugated to Alexa 594 fluorochrome (red fluorescence) to localize active caspase-3. To co-localize DNA fragmentation, we subsequently processed the same sections by the TUNEL method using fluorescein-labeled dUTP (green fluorescence). RESULTS: Using this dual labeling approach, we show that active caspase-3 (caspase-3 positive) and DNA fragmentation (TUNEL positive) occur in a sub-population of interdigital mesenchyme cells of day 13 mouse limb buds. Using the same approach, we detected a small number of caspase-3 positive and TUNEL-positive cells in the central nervous system and in the mesenchyme of the first branchial arch of untreated day 9 mouse embryos. The number of caspase-3 and TUNEL-positive cells are greatly increased 5 hr after a brief exposure to hyperthermia (43 degrees C, 13 min). Caspase-3 and TUNEL-positive cells were most abundant in the neuroepithelium of the developing central nervous system, mesenchyme of the first pharyngeal arch, and somitic mesoderm. In contrast, the heart, mesencephalic mesenchyme, and the visceral yolk sac contained few, if any, caspase-3 and TUNEL-positive cells. CONCLUSIONS: This is the first demonstration that activation of caspase-3 and DNA fragmentation co-localize in cells programmed to die in the interdigital mesenchyme of day 13 limb buds and in the neuroepithelium and branchial arch mesenchyme of day 9 mouse embryos. Similarly, our results represent the first co-localization of teratogen-induced activation of caspase-3 and DNA fragmentation in specific cells of early postimplantation mouse embryos, and confirm that cells of the developing central nervous system are acutely sensitive to the cell death-inducing potential of hyperthermia, whereas cells of the heart are resistant. Finally, we show for the first time that, like cells of the heart, cells of the mesencephalic mesenchyme and the visceral yolk sac are also resistant to hyperthermia-induced apoptosis.

Teratogen-induced activation of ERK, JNK, and p38 MAP kinases in early postimplantation murine embryos.

BACKGROUND: Although many teratogens are known to activate apoptotic pathways culminating in abnormal development, little is known about how the embryo transduces a teratogenic exposure into specific responses. Signal reception and transduction are regulated by a number of signal transduction pathways, including the extracellular signal-regulated protein kinases (ERKs), c-Jun N-terminal kinases (JNKs) and the stress-activated protein kinase, p38. METHODS: To analyze the effects of teratogens on MAP kinases, we used whole embryo culture, Western blot analyses, and antibodies recognizing inactive or active MAP kinases, or both. RESULTS: We show that heat shock (HS) induces a rapid, strong, but transient activation of ERK, JNK, and p38 with maximal activation occurring within 30 min of the heat shock. By contrast, cyclophosphamide (CP) and staurosporine (ST) failed to activate ERK or JNK during the time period studied (7. 5 hr). ST and CP did induce a low but reproducible activation of p38 beginning at around 3 hr and 5 hr, respectively, after the initiation of exposure. Previous work has shown that heat shock induces elevated cell death in the embryo, primarily in the developing neuroepithelium, but not in the embryonic heart. Thus, we also compared the activation of these three MAP kinase pathways in heads, hearts, and trunks isolated from day 9 embryos exposed to 43 degrees C for 15 min. The results show that ERK, JNK, and p38 are activated in heads, hearts, and trunks. CONCLUSIONS: Our results show that day 9 embryos do activate MAP kinase signaling pathways in response to teratogenic exposures; however, activation of a particular pathway does not appear to be required for teratogen-induced apoptosis.

Cytochrome c release from mitochondria of early postimplantation murine embryos exposed to 4-hydroperoxycyclophosphamide, heat shock, and staurosporine.

Cell death is an early and common event in the pathogenesis associated with the abnormal development induced by a variety of teratogens. Previously, we showed that the cell death induced in day 9 mouse embryos by three teratogens, hyperthermia (HS), 4-hydroperoxycyclophosphamide (4-CP), and sodium arsenite (As), is apoptotic in nature involving the activation of caspase-3, cleavage of poly(ADP-ribose) polymerase (PARP), and DNA fragmentation. We now show that HS, 4-CP, and staurosporine (ST) induce the release of cytochrome c from mitochondria with kinetics suggesting a causal relationship with the activation of caspase-3 and caspase-2. This causal relationship is supported by data showing that procaspase-3 and -2 can be activated in vitro by the addition of cytochrome c to a S-100 fraction prepared from control day 9 embryos. Together, these data support the notion that these three teratogens induce changes in embryonic mitochondria resulting in the release of cytochrome c and the subsequent activation of caspase-9, the upstream activator of caspase-3. Previously, we also showed that cells within the day 9 mouse embryo are differentially sensitive/resistant to the cell death-inducing potential of HS, 4-CP, and As. The most dramatic example of this differential sensitivity is the complete resistance of heart cells, characterized by the lack of caspase-3 activation, PARP cleavage, and DNA fragmentation. We now show that this block in the terminal phase of the apoptotic pathway in heart cells is associated with a lack of teratogen-induced release of cytochrome c. Together, our data indicate that mitochondria play a pivotal role in cell death during the early phases of teratogenesis.

Heat shock protein 70 (Hsp70) protects postimplantation murine embryos from the embryolethal effects of hyperthermia.

Previous work has shown that there is a positive correlation between the induction of Hsp70 and its transient nuclear localization and the acquisition and loss of induced thermotolerance in postimplantation rat embryos. To determine whether Hsp70 is sufficient to induce thermotolerance in postimplantation mammalian embryos, we used a transgenic mouse in which the normally strictly inducible Hsp70 is constitutively expressed in the embryo under the control of a beta-actin promoter. Day 8.0 mouse embryos heterozygous for the Hsp70 transgene were not protected from the embryotoxic effects of hyperthermia (43 degrees C); however, homozygous embryos, expressing approximately twice as much Hsp70 as heterozygous embryos, were partially protected (increased embryo viability) from the embryolethal effects of hyperthermia. Although the viability of transgenic embryos was significantly increased compared with that of nontransgenic embryos, this protection did not extend to embryo growth and development. To determine whether the failure to achieve a more robust protection was related to the expression of insufficient Hsp70 in transgenic embryos, we undertook experiments to determine whether the level of Hsp70 correlated with the level of thermotolerance induced by various lengths of a 41 degrees C heat shock. A 41 degrees C, 5-minute heat shock failed to induce Hsp70 or thermotolerance, a 41 degrees C, 15-minute heat shock induced Hsp70 and a significant level of thermotolerance, while a 41 degrees C, 60-minute heat shock induced an even higher level of Hsp70 as well as a higher level of thermotolerance. Quantitation of Hsp70 levels indicated that thermotolerance was associated with levels of Hsp70 of 820 pg/microg embryo protein or greater. Subsequent quantitation of the amount of Hsp70 expressed in homozygous transgenic embryos indicated a level of 577 pg/microg embryo protein, that is, a level below that associated with induced thermotolerance. Overall, results presented indicate that Hsp70 does play a direct role in the induction of thermotolerance in postimplantation mouse embryos; however, the level of thermotolerance is dependent on the level of Hsp70 expressed.

Teratogen-induced cell death in postimplantation mouse embryos: differential tissue sensitivity and hallmarks of apoptosis.

Teratogen-induced cell death is a common event in the pathogenesis associated with tissues destined to be malformed. Although the importance of this cell death is recognized, little information is available concerning the biochemistry of teratogen-induced cell death. We show that three teratogens, hyperthermia, cyclophosphamide and sodium arsenite induce an increase in cell death in day 9.0 mouse embryos with concurrent induction of DNA fragmentation, activation of caspase-3 and the cleavage of poly (ADP-ribose) polymerase (PARP). Teratogen-induced cell death is also selective, i. e., some cells within a tissue die while others survive. In addition, cells within some tissues die when exposed to teratogens while cells in other tissues are relatively resistant to teratogen-induced cell death. An example of the latter selectivity is seen in the cells of the developing heart, which are resistant to the cytotoxic potential of many teratogens. We show that the absence of cell death in the heart is accompanied by the complete lack of DNA fragmentation, activtion of caspase-3 and the cleavage of PARP.

Induction of thermotolerance in early postimplantation rat embryos is associated with increased resistance to hyperthermia-induced apoptosis.

Previously we reported that hyperthermia (43 degrees C) induces cell death in neurulation stage rat embryos as part of the pathogenesis culminating in abnormal growth and development. We now show that hyperthermia-induced cell death occurs by a process termed apoptosis. DNA fragmentation, a hallmark of apoptosis, was noted as early as 2.5 hr after embryos were exposed to 43 degrees C. A smaller but significant increase in DNA fragmentation was also observed in embryos exposed to 42 degrees C, but only at the 5 hr time point. In control embryos, TUNEL-positive apoptotic bodies were consistently observed in the neuroepithelium at the point of neural tube closure and in the optic stalk. In embryos exposed to 43 degrees C, the number of TUNEL-positive apoptotic bodies was significantly increased. Using both gel electrophoresis and TUNEL, we also show that the induction of thermotolerance is associated with a significant reduction in DNA fragmentation. Together our results show that specific programmed cell death and hyperthermia-induced cell death correlate with internucleosomal DNA fragmentation characteristic of apoptosis. Finally, we show that the induction of thermotolerance in rat embryos is associated with a significant reduction in internucleosomal DNA fragmentation and associated apoptosis.

Constitutive synthesis of heat shock protein (72 kD) in human peripheral blood mononuclear cells: implications for use as a clinical test of recent thermal stress.

There is no clinical laboratory marker to enhance the diagnosis of recent thermal stress in humans. The 72 kD heat shock protein, HSP 72, which is rapidly synthesized after heat stress could be useful in the diagnosis of illnesses associated with heat stress. In humans HSP, 72 is rapidly synthesized after thermal stress; however, conflicting data suggest it may also undergo low level constitutive synthesis. If HSP 72 is constitutively synthesized, a semi-quantitative test will be necessary to detect recent heat stress; if not, a qualitative test would be sufficient, peripheral blood mononuclear cells were chosen for this investigation because they can be isolated from a small sample (clinically acceptable) of blood. Following heat stress Western analysis and autoradiography of one- and two-dimensional electrophoresis samples demonstrated low levels of HSP 72 in unstressed cells. HSP 72 increased with heat stress, and remained elevated for up to 48 h. HSP 72 mRNA was detectable in small amounts in nonheat stressed cells. Heat stress increased HSP 72 mRNA 1 and 2 h after stress and remained elevated for 6 h. HSP 72 persists long enough to be potentially useful as a diagnostic probe of recent heat injury; however, a semi-quantitative assay will be necessary.

Induction of Hsp72 and transient nuclear localization of Hsp73 and Hsp72 correlate with the acquisition and loss of thermotolerance in postimplantation rat embryos.

A number of cell culture studies have indicated that there is a positive correlation between the induction and decay of thermotolerance and the kinetics of Hsp72 expression. In this study, we have demonstrated that, in gestational day 10 embryos, induction and decay of thermotolerance occur over an 8 hr period. To test the hypothesis that there is a correlation between loss of thermotolerance and the decline of Hsp72 or Hsp73 gene products over time, expression levels of both Hsp72 and constitutively expressed Hsp73 mRNAs and proteins were examined at several time points following exposure to a thermotolerance-inducing exposure of 42 degrees C. Our results indicated that Hsp72 mRNA was strongly induced 1 hr after exposure but no longer detectable by 8 hr. Although our Western blot results indicated that Hsp72 protein was present beyond 8 hr after exposure, Northern blot analysis showed that Hsp72 mRNA was no longer present 5 hr after exposure to 42 degrees C. The latter finding indicates that no new Hsp72 can be synthesized at this time point and beyond. Although there was very little or no induction of Hsp73, immunohistochemical analysis revealed a dramatic, transient shift in intracellular localization of Hsp73 protein, as well as Hsp72. Under non-stress conditions, Hsp73 was cytoplasmically localized but localization was largely nuclear 1 hr after exposure, when thermotolerance was demonstrable. Hsp73 and Hsp72 proteins were no longer localized in the nucleus by 8 hr, when thermotolerance was no longer detectable. Thus, the induction of Hsp72 and the transient nuclear localization of both Hsp72 and Hsp73 correlate with the kinetics of thermotolerance in the postimplantation rat embryo.

Molecular/cellular biology of the heat stress response and its role in agent-induced teratogenesis.

Available data indicate that heat shock proteins act as chaperones under non-stress conditions by assisting in: (1) the folding of newly synthesized proteins, (2) the intracellular translocation of proteins, and (3) the function of other proteins. As we gain additional information concerning cellular physiology, we may find that heat shock proteins play a key role in many additional cellular functions. When cells experience thermal or chemical stress, heat shock proteins take on a new role, conserved from bacteria to humans, of protecting cells from the detrimental effects of stress. This latter role takes on added significance for the embryo in which the developmental program must be read linearly, with little opportunity to cycle backward to complete a missed segment of the program. Although circumstantial evidence clearly implicates heat shock proteins in protecting embryos from thermal stress, definitive evidence is still lacking. The challenge for the future is to obtain such definitive data. Ideally, such information will lead to new therapeutic paradigms that will afford protection to the human embryo/fetus exposed to thermal/chemical stress.

Induction of heat shock protein 27 in rat embryos exposed to hyperthermia.

Previously we reported that eight proteins were reproducibly induced in postimplantation rat embryos exposed to a brief heat shock (43 degrees C, 15 min). The major heat-inducible rat embryo protein has now been identified as heat shock protein 72 (Hsp 72). In addition, the induction of Hsp 72 is temporally correlated with induction of thermotolerance. One of the other rat embryo proteins previously shown to be induced by elevated temperature is a heat shock protein of approximately 27 kilodaltons (Hsp 27). In this report we show that this protein is recognized by an antibody directed against a conserved peptide sequence of Hsp 27. Unlike Hsp 72, Hsp 27 is constitutively expressed in the rat embryo in the absence of any thermal stress; however, the level of Hsp 27 is increased approximately 2-3-fold after thermal stress (43 degrees C, 10 min). Immunohistochemical analysis revealed that the constitutively expressed Hsp 27 is localized primarily to cells of the heart, cells that are uniquely resistant to the cytotoxic effects of hyperthermia. After thermal stress, Hsp 27 is expressed in all tissues of the embryo. Finally, our data show that Hsp 27 exists in the rat embryo as three major isoforms indicative of different phosphorylation states. Furthermore, most Hsp 27 in the heart is phosphorylated, whereas in the rest of the embryo, nonphosporylated Hsp 27 predominates. After thermal stress, levels of phosphorylated isoforms increase dramatically in nonheart tissues of the embryo. Together, these results suggest that Hsp 27 may play a role in the development of thermotolerance in the postimplantation mammalian embryo.

Prospects for the development of validated screening tests that measure developmental toxicity potential: view of one skeptic.

Humans are exposed to a variety of potential developmental toxicants. This fact, combined with the knowledge that human development can be disrupted by "environmental" agents, has led to the development of methods designed to identify potential developmental toxicants. Currently, the principal method used to screen drugs and chemicals that are potential human developmental toxicants is the segment II study (i.e., a study in which prospective drugs and chemicals are tested in pregnant animals). Because of the cost and time involved in such studies and the pressure to reduce the number of animals used in such testing, alternative methods for developmental toxicity testing have been sought. This has resulted in a number of in vitro tests whose aim is to screen large numbers of agents quickly and inexpensively. Although numerous in vitro tests of developmental toxicity have been developed during the last 15 years, no one system or combination of tests have been validated for the purpose intended. Nonetheless, two systems--the limb bud/CNS micromass, and the chick embryo neural retina cell culture (CERC)--continue to be advanced as viable in vitro developmental toxicology tests. The purpose of this commentary is to evaluate the prospects for the development of an in vitro test system(s) that can screen the universe of drugs and chemicals and reliably identify those that require further study and those that do not. The conclusion of this investigator is that the prospects for validating such in vitro tests are not promising. This conclusion is based primarily on the lack of basic knowledge regarding the relevance of end points assayed in the micromass and CERC test systems to those end points known or thought to be critical for normal development.

Apoptosis induced in cultured rat embryos by intra-amniotically microinjected sodium nitroprusside.

Previously, we reported that massive cell death was induced in the mesencephalic area of cultured rat embryos after embryos of gestational day 10.5 were intra-amniotically microinjected with sodium nitroprusside (SNP, 800 microM) and cultured for 24 hr at 37 degrees C. The massive cell death apparently was the result of NO-mediated embryotoxicity. Damage was concentration dependent and tissue specific. In follow-up studies, we now report evidence that NO generated from SNP induces apoptosis in organogenesis stage cultured rat embryos. Nile blue sulfate (NBS) staining suggested that microinjections of 400 microM SNP induced apoptosis in the mesencephalic area. Since we observed no massive cell death ("white caps") at this concentration, it appeared that early stages of apoptosis preceded "white cap" formation. At 800 microM SNP, total disintegration of cell bodies was evident and may have resulted from later stages of aoptosis or necrosis, or both. The "white caps" per se, an accumulation of disintegrated cell bodies, did not stain with NBS, probably due to total loss of cell integrity and resultant coagulation. The majority of the coagulated dead cells in the "white caps" were heavily stained with 3,3'-diaminobenzidine via in situ 3' end-labeling with terminal transferase. However, it is now known that NO can damage DNA directly and that in situ 3' end-labeling by terminal transferase detects not only apoptosis but also random DNA breakage. Increased 3' end-labeling and a "DNA ladder" were detectable within 5-10 hr after exposure of day 10.5 embryos to 400 or 800 microM of microinjected SNP. Some smear background was also observed in the "ladder." Rostral aspects of embryos exhibited more prominent indices of apoptosis than caudal regions. The results suggested that microinjections of SNP into the amniotic fluid of day 10.5 cultured rat embryos induces NO-mediated cell death in the mesencephalic and rhombencephalic regions by the process of apoptosis or of both apoptosis and necrosis, depending on the timing, concentration, and stage of gestation.

Clusterin expression during programmed and teratogen-induced cell death in the postimplantation rat embryo.

Clusterin appears to play a role in multiple cellular processes including reproductive cell function, lipid transport, complement regulation, and endocrine secretion. In addition, clusterin has been shown to be associated with both developmental and induced cell death. We have used immunohistochemistry and in situ hybridization to study the relationship between clusterin expression, normal programmed cell death (PCD) in the developing rat limb bud, and abnormal cell death induced by hyperthermia in day 11 rat embryos. Immunohistochemical localization of clusterin in day 14-16 limb buds showed that the most intense immunostaining was associated with the condensing mesenchyme of the developing digit, a tissue exhibiting low levels of PCD. Moreover, areas of digital cell death, confined to future interphalangeal spaces, were devoid of clusterin immunostaining. Clusterin immunostaining was also observed in the interdigital mesenchyme and partially overlapped the cell death that occurs in this tissue during the early development of the digits. Although clusterin immunostaining overlaps areas of interdigital cell death, most apoptotic cells in the interdigital mesenchyme and underlying the surface ectoderm were not associated with clusterin immunostaining. We also examined the expression of clusterin in day 11 rat embryos exposed to 43 degrees C, an exposure that induces extensive cell death primarily in the developing neuroepithelium. In control embryos cultured at 37 degrees C, clusterin mRNA and protein were expressed at high levels in the heart, a tissue that is completely resistant to the cytotoxic effects of hyperthermia. Within 2.5 hr after an exposure of 43 degrees C, clusterin mRNA showed a dramatic induction in the prosencephalic mesenchyme and only a modest induction in the prosencephalic neuroepithelium.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of osteopontin in the head process late in gastrulation in the rat.

Osteopontin (OPN) is a secreted, glycosylated phosphoprotein. Previous studies have implicated OPN in calcification/decalcification and inflammation. We became interested in developmental expression of OPN because of our previous findings that suggest OPN may play a role in formation of new vascular layers after injury, and because of our observation of developmental regulation in vascular smooth muscle cells. While OPN was expressed at low levels in vessels, only late in development, examination of very early expression patterns revealed a surprising finding. OPN was expressed exclusively in the head process, on day 9.0 late in gastrulation in the rat. In vitro studies of vascular smooth muscle cells have previously demonstrated that OPN promotes cell adhesion and migration. It is suggested that OPN may promote migration of cells, during gastrulation, via integrins which may be present in the head process or overlying ectoderm.

Programmed cell death and N-acetoxy-2-acetylaminofluorene-induced apoptosis in the rat embryo.

N-acetoxy-2-acetylaminofluorene (N-Ac-AAF) is an alkylating agent that forms DNA adducts at C-8 in guanine and causes single strand breaks. It has previously been shown to be embryotoxic, but the mechanisms by which it causes abnormal development have not been investigated. Previous studies have indicated that other DNA alkylating agents cause cell death during embryonic development although the types of cell death were not characterized. Using a whole embryo culture system, gestation day 10 rat embryos were exposed to several concentrations (5, 50, and 200 micrograms/ml) of N-Ac-AAF. At several time points after exposure was begun (5, 10, and 24 hours), the embryos were removed from culture and examined to identify location, type and quantity of cell death, relative to programmed cell death observed in control embryos. Vital staining with Nile blue sulphate revealed that the location of N-Ac-AAF-induced cell death included the forebrain region, tail, and areas of programmed cell death. Examination of tissue sections from both control and treated embryos indicated that the location of apoptotic cell death revealed by in situ DNA nick end-labelling was generally consistent with the cell death pattern observed by vital staining of whole embryos. Agarose gel analyses indicated that all concentrations of N-Ac-AAF caused DNA fragmentation, and quantification demonstrated a dose response. Examination of treated embryos (50 and 200 micrograms/ml) by transmission electron microscopy revealed that, by 5 hours after exposure, cells with classic, ultrastructural features of apoptosis were present. In conclusion, multiple methods have all indicated that, regardless of exposure level, apoptosis was the predominant form of cell death. Because apoptosis also occurs in developmental cell death, it is possible that apoptosis induced by N-Ac-AAF is due to an alteration in cell fate via premature or ectopic induction of the cell death program.

Staurosporine does not prevent adrenergic-induced situs inversus, but causes a unique syndrome of defects in rat embryos grown in culture.

Staurosporine, an alkaloid isolated from Streptomyces species, is commonly used as a protein kinase C (PKC) inhibitor in animal investigations. In the present study, we used this compound to determine whether alpha 1-adrenergic stimulation-induced situs inversus in rats is mediated by PKC. Embryos were explanted at 8 A.M. on day 9 of gestation. Those with a neural groove but with no visible neural folds (Stage 11a) were selected and were cultured in medium containing various concentrations of staurosporine with or without 50 microM of phenylephrine, an alpha 1-adrenergic agonist. At 10 A.M. on day 11 of gestation, embryos were examined for situs inversus and other abnormalities. Staurosporine, tested at 0.0001, 0.001, 0.01, 0.1, 0.375, and 0.5 microM (lethal concentration), did not block phenylephrine-induced situs inversus at any concentration. However, staurosporine alone produced situs inversus at concentrations above 0.1 microM. At 0.5 and 1.0 microM, staurosporine also caused cyst-like lesions projecting dorsally from the mesencephalon that we named "mesencephalic vesicles" and the formation of secondary somites. To confirm and further examine these unique effects of staurosporine both grossly and histologically, we conducted additional experiments using staurosporine from another source. Embryos were explanted between 6 A.M. and 9 P.M. on day 9 of gestation and were placed in one of the following groups according to their stage of development: 10b, 11a, 11b, 11c, 12/s1-2, 12/s3-4, and 12/s5-6. Embryos were then cultured with various concentrations of staurosporine. Those cultured from Stage 11a exhibited similar lesions to those seen in the initial experiment but at somewhat higher concentrations of staurosporine. Embryos cultured from Stage 10b showed a similar pattern of lesions as seen at Stage 11a, except that higher concentrations of staurosporine were required to cause mesencephalic vesicles and secondary somites formation. Embryos cultured from Stage 11b showed similar effects to those cultured from younger stages except that maximum incidences of situs inversus were much lower. Those cultured from Stage 11c showed similar dose-response to those cultured from Stage 11b except that the incidence of secondary somites formation was much higher. In addition, in approximately 40% (n = 25) of embryos treated with greater than 1.0 microM of staurosporine, the growing end of the allantois did not reach the chorion and remained unattached in the exocoelomic cavity.(ABSTRACT TRUNCATED AT 400 WORDS)

From gastrulation to neurulation: transition in retinoic acid sensitivity identifies distinct stages of neural patterning in the rat.

Early neural development is a multistep process with morphologically distinct stages; however, the molecular events that underlie morphologic development are poorly understood. Retinoic acid (RA) was chosen as a teratogen to perturb development because this endogenous molecule is thought to play an integral role in normal neuraxis formation in many vertebrate species. We have examined the effects of RA on early neural patterning in the rat at three morphologically distinct stages: late streak, foregut pocket, and early somite. In this model exogenous RA exposure during mid-gastrulation (late streak stage) leads to severe disruption of anterior neural development as determined by morphologic and molecular (Engrailed [En] gene expression) markers. This disruption in anterior neural development is associated with excessive cell death in the hindbrain posterior to the En expression domain. In contrast, at the time the neural folds begin to elevate (foregut pocket stage) there is a dramatic reduction in the sensitivity of anterior neural development to exogenous RA as reflected by En expression and cell death patterns. These results suggest that we have identified a major transition in the development of the anterior neuraxis that is reflected in a transition in sensitivity to RA. This transition in sensitivity demonstrates that the fundamental patterning mechanisms that separate fore- and midbrain from hindbrain occurs very early in neurogenesis.