Possible role of the T antigen in inducing chromosome aberrations in SV40 virus-transformed cells

A possible role of the simian virus 40 T antigen in chromosome damages in transformed cells was examined. Two lines of Golden hamster embryonal fibroblasts, transformed by SV40 tsA30 and ts239 mutants (He30 and He239, respectively), were incubated at nonpermissive (40.5-41 degrees C) or permissive (33 degrees C) temperatures. Chromosome aberrations were registered in either subline after 3, 6, 9 and 12 weeks of cultivation under the above conditions. In the both cell lines kept at 33 degrees the frequency of aberrant metaphases and the number of chromosome breaks per cell increased drastically by week 3 of cultivation, and such a state was preserved up to week 12. The frequency of aberrant metaphases in cells cultivated at 41 degrees was maintained at the constant level (He239) or at slightly higher than that in the original culture (He30). The sublines He239, originally incubated at 33 or 40.5 degrees, were then shifted to 40.5 and 33 degrees, respectively. As a result the number of chromosome aberrations either decreased (33----40.5 degrees) or increased (40.5----33 degrees) as early as on day 2, and these patterns were stabilized at the level corresponding to the new conditions. We assayed the induction of DNA breaks in cells, grown at the permissive or nonpermissive temperatures, by using DNA sedimentation in the alkaline sucrose gradient. The DNA sedimentation peaks of cells cultured at 37 and 41 degrees coincided, whereas the DNA of cells cultured at 33 degrees was represented by shorter fragments.     

Accumulation of heat shock protein 72 (hsp 72) in postimplantation rat embryos after exposure to various periods of hyperthermia (40 degrees -43 degrees C) in vitro: evidence that heat shock protein 72 is a biomarker of heat-induced embryotoxicity.

A monoclonal antibody to the 72 kDa heat shock protein and Western blot analysis were used to determine the induction, accumulation and turnover of hsp 72 after day 10 rat embryos were exposed to elevated temperatures (40 degrees-43 degrees C) for various lengths of time (2.5 minutes to 18 hours). Embryos exposed to temperatures that exceed the normal culture temperature (37 degrees C) by 4 degrees C or more for as little as 2.5 minutes (43 degrees C) or 15 minutes (41, 42 degrees C) synthesized and accumulated detectable amounts of heat-inducible hsp 72. Hsp 72 could not be detected by Western blot analysis of proteins from embryos cultured at 40 degrees C or below. Once induced, hsp 72 can be detected in embryos for 24-48 hours after they are removed from the hyperthermic conditions and returned to normothermic conditions. Our results also indicate that hsp 72 is induced by all hyperthermic exposures that induce alterations in rat embryo growth and development; therefore, hsp 72 is a potential biomarker for heat-induced embryotoxicity.     

Effects of acute exposures to elevated temperatures on rat embryo growth and development in vitro

Day 10 rat embryos (8-12 somites) cultured in vitro were exposed to elevated temperatures (41-43 degrees C) for varying lengths of time. A 15-minute exposure to a temperature of 43 degrees C (109.4 degrees F) was sufficient to produce malformed embryos when observed on day 11. Longer exposures at this temperature produce higher incidences of malformed embryos and also more severely affected embryos. Temperatures of 42 degrees C (107.6 degrees F) or 41 degrees C (105.8 degrees F) also produced malformed embryos, but the required length of exposure was increased compared to 43 degrees C. The minimal length of exposure at 42 degrees C was 60 minutes, while at 41 degrees C it was increased to 4 hours. The central nervous system was particularly sensitive to increased temperatures, and embryos exposed to "teratogenic doses" of hyperthermia exhibited primarily microcephaly and microphthalmia. In addition, histological analyses revealed that at 4.5 hours after a 30-minute exposure to 43 degrees C, necrotic debris was prevalent in the neuroepithelium, less prevalent in the surrounding mesenchyme and surface ectoderm, and absent in the tissues of the heart.     

Sensitivity to chilling of medaka (Oryzias latipes) embryos at various developmental stages

As an essential step toward cryopreservation of fish embryos, we examined the chilling sensitivity of medaka (Oryzias latipes) embryos at various developmental stages. Embryos at the 2-4 cell, 8-16 cell, morula, blastula, and early gastrula stages were suspended in Hanks solution. They were chilled to various temperatures (usually 0 degrees C), kept for various periods (usually 20 min), then cultured for up to 14 d to determine survival (assessed by the ability to hatch). Embryos at the 2-4 cell stage were the most sensitive to chilling to 0 degrees C, but sensitivity decreased as development proceeded. The survival rate of 2-4 cell embryos was affected after 2 min of chilling at 0 degrees C; although the rate decreased gradually as the duration of chilling increased, 38% of them still survived after 40 min of chilling. Embryos at the 2-4 cell stage were sensitive to chilling at 0 or -5 degrees C, but much less sensitive at 5 or 10 degrees C. The survival rate of 2-4 cell embryos subjected to repeated rapid cooling and warming was similar to that of those kept chilled. When early gastrula embryos were preserved at 0 or 5 degrees C, the hatching rate did not decrease after 12 and 24h of chilling, respectively, but then decreased gradually as storage was prolonged; however, 3-10% of the embryos hatched even after storage for 10 d. In conclusion, although later-stage medaka embryos would be suitable for cryopreservation (from the perspective of chilling sensitivity), chilling injury may not be serious in earlier stage embryos.     

Heat shock-induced apoptosis in preimplantation bovine embryos is a developmentally regulated phenomenon

Apoptosis is a form of cell death that can function to eliminate cells damaged by environmental stress. One stress that can compromise embryonic development is elevated temperature (i.e., heat shock). For the current studies, we hypothesized that heat shock induces apoptosis in bovine embryos in a developmentally regulated manner. Studies were performed to 1) determine whether heat shock can induce apoptosis in preimplantation embryos, 2) test whether heat-induced apoptosis is developmentally regulated, 3) evaluate whether heat shock-induced changes in caspase activity parallel patterns of apoptosis, and 4) ascertain whether exposure to a mild heat shock can protect embryos from heat-induced apoptosis. As determined by TUNEL reaction, exposure of bovine embryos > or =16 cells on Day 5 after insemination to 41 or 42 degrees C for 9 h increased the percentage of cells undergoing apoptosis. In addition, there was a duration-dependent increase in the proportion of blastomeres that were apoptotic when embryos were exposed to temperatures of 40 or 41 degrees C, which are more characteristic of temperatures experienced by heat-stressed cows. Heat shock also increased caspase activity in Day 5 embryos. However, heat shock did not induce apoptosis in 2- or 4-cell embryos, nor did it increase caspase activity in 2-cell embryos. The apoptotic response of 8- to 16-cell-stage bovine embryos to heat shock depended upon the day after insemination that heat shock occurred. When 8- to 16-cell embryos were collected on Day 3 after insemination, heat shock of 41 degrees C for 9 h did not induce apoptosis. In contrast, when 8- to 16-cell embryos were collected on Day 4 after insemination and exposed to heat shock, there was an increase in the percentage of cells undergoing apoptosis. Exposure of 8- to 16-cell embryos at Day 4 to a mild heat shock of 40 degrees C for 80 min blocked the apoptotic response to a subsequent, more-severe heat shock of 41 degrees C for 9 h. In conclusion, apoptosis is a developmentally acquired phenomenon that occurs in embryos exposed to elevated temperature, and it can be prevented by induced thermotolerance.     

The effects of temperature upon the electrophysiological properties of Tetrahymena pyriformis-NT1

Cells of Tetrahymena pyriformis--NT1 were cultured at 38 degrees C (Tg 38 degrees C) and 20 degrees C (Tg 20 degrees C) and their properties investigated over the range 0-40 degrees C. Tg 20 degrees C cells were viable in the range 3-33 degrees C and changes in their properties were readily reversible between 10 degrees C and 30 degrees C. Tg 38 degrees cells were viable in the range 40-10 degrees C and their property changes were immediately reversible in the range 40-23 degrees C. The I-V relations of Tg 38 degrees C cells showed increased excitability as the cells were cooled from 40 degrees C. At 10 degrees C there was a considerable loss of excitability and slope resistance. Cooling Tg 20 degrees C cells from 20 degrees C gave a similar pattern, although over a narrower temperature range. Warming Tg 20 degrees C Tetrahymena above 20 degrees C led to a progressive loss of excitability and the cells were markedly less viable above 35 degrees C. Within physiological limits the regenerative spike magnitude, repolarization time, time to peak and input resistance increased as temperature was lowered, whereas resting potential was diminished. When compared at their growth temperatures and most intermediate temperatures, the value of the various parameters monitored were generally different for the two cultures. The Q10 value for resting potential changes of Tg 20 degrees C cells about 20 degrees C was 1.20. As in T. vorax this was significantly (P less than 0.01) greater than that predicted for a diffusion potential and suggested that T. pyriformis--NT1 may have an electrogenic pump component in its membrane potential.     

Embryonic development in superovulated dairy cattle exposed to elevated ambient temperatures between Days 1 to 7 post insemination

Holstein heifers (n = 29) were used to determine whether thermal stress during the first 7 d of embryonic development may increase the incidence of embryonic abnormalities in dairy cattle. Heifers were acclimated to environmental chambers at 20 degrees C for 9 d and superovulated with follicle stimulating hormone-pituitary (FSH-P; 40 mg total), beginning on Days 9 to 11 of the estrous cycle. Prostaglandin F(2)alpha (Lutalyse; 50 mg total) was administered on Day 3 of FSH-P. Heifers were inseminated artificially at estrus and then maintained at either thermal neutrality (20 degrees C) or under hyperthermic conditions (daily exposure up to 16 h at 30 degrees C and 8 h at 42 degrees C) for 7 d beginning at 30 h after the onset of estrus. On Day 7 post estrus, embryos were recovered nonsurgically and evaluated morphologically for stage of development and quality. The distribution of embryos classified as normal, abnormal, retarded or as unfertilized ova, differed (P<0.001) between heat stress and thermoneutral treatments. Only 20.7% of 82 embryos recovered from stressed heifers were normal compared with 51.5% of 68 embryos from thermoneutral animals. Stressed heifers had a higher incidence of abnormal and retarded embryos with degenerate nonviable blastomeres. Responses indicated that thermal stress from 30 h after the onset of estrus to Day 7 post estrus increases the incidence of abnormal and retarded embryos in superovulated heifers.     

Alterations in ultrastructural morphology of two-cell bovine embryos produced in vitro and in vivo following a physiologically relevant heat shock

Exposure of cultured preimplantation embryos to temperatures similar to those experienced by heat-stressed cows inhibits subsequent development. In this study, the effects of heat shock on the ultrastructure of two-cell bovine embryos were examined to determine mechanisms for inhibition of development. Two-cell embryos produced in vitro were harvested at approximately 28 h postinsemination and cultured for 6 h at one of three temperatures: 38.5 degrees C (cow body temperature), 41.0 degrees C (characteristic temperature for heat-stressed cows), or 43.0 degrees C (severe heat shock). Ultrastructural examinations revealed that both heat shocks resulted in the movement of organelles towards the center of the blastomere. In addition, heat shock increased the percentage of mitochondria exhibiting a swollen morphology. Distance between the membranes comprising the nuclear envelope was increased but only when embryos were treated at 43.0 degrees C. To determine whether ultrastructural responses to heat shock in culture were similar for embryos produced in vitro and in vivo, two-cell embryos were collected from superovulated Angus cows 48 h postinsemination and treated ex vivo for 6 h at 38.5 degrees C or 41.0 degrees C. Again, heat shock caused an increase in number of swollen mitochondria and movement of organelles away from the periphery of the blastomere. Exposure of two-cell bovine embryos to physiologically relevant elevated temperatures causes disruption in ultrastructural morphology that is inimical to development. The observation that overall morphology and response to heat was similar for embryos produced in vitro and in vivo implies that the former can be a good model for understanding embryonic responses to heat shock.     

The effect of hyperthermia in vitro on vitality of rabbit preimplantation embryos

The aim of our study was to test the influence of short exposure (6 h) of preimplantation rabbit embryos to elevated temperatures (41.5 degrees C or 42.5 degrees C) in vitro on their developmental capacity. Fertilized eggs recovered from female oviducts at the pronuclear stage (19 hpc) were cultured at standard temperature (37.5 degrees C) until the morula stage (72 hpc). Afterwards, the embryos were divided into two groups, cultured for 6 h either at hyperthermic (41.5 degrees C or 42.5 degrees C) or standard temperature (control 37.5 degrees C), post-incubated overnight (16-20 h) at 37.5 degrees C and then evaluated for developmental stages, apoptosis (TUNEL), proliferation (cell number), actin cytoskeleton and presence of heat-shock proteins Hsp70. It was observed that hyperthermia at 41.5 degrees C did not alter progression of embryos to higher preimplantation stages (expanded and hatching/hatched blastocysts), rate of apoptosis, total cell number of blastocysts and structure of actin filament compared to 37.5 degrees C. Western-blotting revealed the presence of heat stress-induced 72 kDa fraction of Hsp70 proteins in granulosa cells (exposed to 41 degrees C) and embryos (exposed to 41.5 degrees C). Following the elevation of temperature to 42.5 degrees C embryo development was dramatically compromised. The embryos were arrested at the morula or early blastocyst stage, showed an increased rate of apoptosis and decreased total cell number compared to control. The structure of actin filaments in most of blastomeres was damaged and such blastomeres often contained apoptotic nuclei. In this group a presence of heat-stress-induced fraction of Hsp70 proteins had not been confirmed. This is the first report demonstrating a threshold of thermotolerance of rabbit preimplantation embryos to hyperthermic exposure in vitro. A detrimental effect of higher temperature on the embryo is probably associated with the loss of their ability to produce Hsp70 de novo, which leads to cytoskeleton alterations and enhanced apoptosis.     

Vascular abnormalities due to hyperthermia in chick embryos

Intraembryonic vascular abnormalities were studied in chick embryos exposed to temperatures 3 degrees C and 4 degrees C above normal temperature (38 degrees C) from the beginning of incubation. The average duration of hyperthermia was 54 and 53 hours, respectively. Immediately after exposure, the embryos were examined with FITC-Dextran microangiography in vivo. Following hyperthermia various abnormalities in the heart, ventral aortae, aortic arches, omphalomesenteric arteries, and the distal dorsal aortae frequently occurred. There were also significant microvascular changes in the head, in the lateral and caudal parts of the embryos, and in the pellucid area of the yolk sac. In another series incubation at 41 degrees C, hyperthermia of 3 degrees C during the first 3 days of development produced several extraembryonic vascular abnormalities. These included duplication and abnormal branching of the cranial vitelline vein, absence or abnormal course of the omphalomesenteric vessels, aneurysmatic dilatation or abnormal course of the caudal vitelline vein, and aneurysmatic dilatation or occlusion of the abdominal venous sinus. Most frequent findings were blind, congested, and dilated microvascular segments in the pellucid area, commonly associated with an irregular microvascular pattern and perivascular swelling. The abnormalities described are assumed to be caused by the direct effects of hyperthermia upon the developing vessels resulting in microvascular insufficiencies, pathological leakage, and perivascular oedema. Such disturbances may have serious consequences for embryonic vascular development and microcirculation, which in turn may have adverse effects on further embryonic growth and development.     

Effect of rapid addition and dilution of dimethyl sulfoxide on the viability of frozen-thawed rabbit morulae

The aim of the present study was to examine effects of altering thawing conditions and procedure of addition and dilution of Me2SO on the viability of frozen-thawed rabbit morulae. Five hundred and sixty two rabbit morulae were cooled from room temperature to -80 degrees C at 1 degree C/min in the presence of 1.5 M dimethyl sulfoxide (Me2SO) using a programmable liquid nitrogen vapor freezing machine with an automatic seeding device, cooled rapidly, and stored in liquid nitrogen. When Me2SO was added in a single step, the frozen embryos were thawed in ambient air at 40 degrees C/min and Me2SO was diluted in a single step, 99 of 107 (93%) embryos cultured for 48 hr and 12 of 32 (38%) embryos transferred to 6 recipients developed to expanding blastocysts and viable fetuses, respectively. When Me2SO was added in a single step and the frozen embryos were thawed at the same rate and transferred directly without removal of Me2SO to culture media or oviducts of 8 recipients, 67 of 75 (89%) embryos cultured and 12 of 40 (30%) embryos transferred developed to expanding blastocysts and viable fetuses, respectively. There were no significant differences between these survival rates and survival rates obtained by conventional method, i.e., frozen embryos were thawed at 4 degrees C/min by interrupted slow method and Me2SO was added and diluted in a stepwise manner.     

Metabolic responses of chicken embryos to graded, prolonged alterations in ambient temperature

1. Chicken embryos aged 12, 16, 18 and 20 (externally pipped) days of incubation were exposed to graded reductions (2 degrees C) in ambient temperature from 38 to 28 degrees C, exposure to each temperature lasting up to 9 hr. 2. Oxygen uptake was measured first at 38 degrees C and then in the quasi-equilibrium state at lowered temperatures. The temperature coefficient (Q10) was calculated for each egg. 3. For mild cooling (32 degrees C), the Q10 in 18-day-old embryos was about 1.5, while 12- and 16-day-old embryos had a Q10 value of about 2, indicating that a feeble homeothermic metabolic response to cooling appears in late prenatal embryos. It became more marked in externally pipped embryos and further augmented in hatchlings.     

Survival of frozen mouse embryos after rapid thawing from -196 degrees C.

The effect of the rate of rewarming on the survival of 8-cell mouse embryos and blastocysts was examined. The samples were slowly cooled (0.3--0.6 degrees C/min) in 1.5 M-DMSO to temperatures between -10 and -80 degrees C before direct transfer to liquid nitrogen (-196 degrees C). Embryos survived rapid thawing (275--500 degrees C/min) only when slow cooling was terminated at relatively high subzero temperatures (-10 to -50 degrees C). The highest levels of survival in vitro of rapidly thawed 8-cell embryos were obtained after transfer to -196 degrees C from -35 and -40 degrees C (72 to 88%) and of rapidly thawed blastocysts after transfer from -25 to -50 degrees C (69 to 74%). By contrast, for embryos to survive slow thawing (8 to 20 degrees C/min) slow cooling to lower subzero temperatures (-60 degrees C and below) was required before transfer to -196 degrees C. The results indicate that embryos transferred to -196 degrees C from high subzero temperatures contain sufficient intracellular ice to damage them during slow warming but to permit survival after rapid warming. Survival of embryos after rapid dilution of DMSO at room temperature was similar to that after slow (stepwise) dilution at 0 degrees C. There was no difference between the viability of rapidly and slowly thawed embryos after transfer to pseudopregnant foster mothers. It is concluded that the behaviour of mammalian embryos subjected to the stresses of freezing and thawing is similar to that of other mammalian cells. A simpler and quicker method for the preservation of mouse embryos is described.     

Heat shock and thermotolerance during early rat embryo development

Effects of heat shock on the development of early pre-somite embryos have been studied using cultured rat embryos. The results illustrate the sensitivity of the developing head and brain to elevated temperatures prior to neural tube closure and the capacity of embryos to acquire thermotolerance. Embryos exposed briefly to an elevated temperature (43 degrees C for 7.5 min) developed severe craniofacial defects including microphthalmia, microcephaly, gross reduction of the forebrain region, and open neural tubes. In contrast, a nonteratogenic heat shock (42 degrees C for 10 min) caused embryos to acquire thermotolerance during a 15-min recovery period at 38.5 degrees C. Acquired thermotolerance was effective in protecting embryos from a subsequent more severe heat treatment which would have been teratogenic in an unprotected embryo. Recovering embryos mounted a heat shock response as evidenced by the induction of a 71 kilodalton heat shock protein. Activation of the heat shock response was not a teratogenic event in the developing embryo.     

Deep freezing of sheep embryos.

Sheep embryos, collected 1-8 days after oestrus, were placed in Dulbecco's phosphate-buffered saline medium (PBS). After treatment, the viability of the embryos was tested by temporary transfer to ligated rabbit oviducts. In Exp. 1, Days 5-8 embryos survived for at least 15 min at 0 degrees C in the presence of 1-5 M-DMSO. In Exp. 2, 12/14 Days 5-8 embryos survived after being frozen in 1-5 M-DMSO at 0-3 degrees C/min to temperatures ranging between-15 degrees and -60 degrees C and then thawed at 12 degrees C/min. In Exp. 3, Days 5-8 embryos were frozen in 1-5 M-DMSO at 0-3 degrees C/min to below-65 degrees C before being transferred to liquid nitrogen (-196 degrees C), and stored for 12 hr to 1 month. The embryos were thawed at 3 degrees C/min, 12 degrees C/MIN or 360 degrees C/min and, after transfer to rabbit oviducts, 0/4, 10/36 and 1/4, respectively, developed normally. The 11 embryos which were considered normal when recovered from the rabbit oviducts plus 1 slightly retarded embryo were transferred to 7 recipient ewes. Four ewes subsequently lambed, producing 5 lambs. In addition, 8 embryos were transferred to 4 ewes directly after thawing. Three of these ewes subsequently lambed, producing 3 lambs.     

Effect of elevated temperatures on human lymphocyte chromosomes

The influence of elevated temperatures (38-41 degrees C) on chromosomes of human lymphocytes on different phases of the cell cycle was studied. A high thermosensitivity of chromosomes was demonstrated during (S + G2)-phases of the cell cycle. There was a significant increase in the number of aberrant cells at t greater than 38.5%. The main types of chromosome aberrations were chromatid and chromosome deletions. Cells with 3-5 aberrations and induction of chromosome aberrations due to breaks in the centromere region were noticed at high temperatures (40-41 degrees).     

Modification of actions of heat shock on development and apoptosis of cultured preimplantation bovine embryos by oxygen concentration and dithiothreitol

Preimplantation embryos exposed to elevated temperatures have reduced developmental competence. The involvement of reactive oxygen species in these effects has been controversial. Here we tested hypotheses that (1) heat shock effects on development and apoptosis would be greater when embryos were cultured in a high oxygen environment (air; oxygen concentration = approximately 20.95%, v/v) than in a low oxygen environment (5% oxygen) and (2) that these effects would be reversed by addition of the antioxidant dithiothreitol (DTT). Heat shock of 41 degrees C for 9 hr reduced development of two-cell embryos and Day 5 embryos to the blastocyst stage embryos when in high oxygen. There was no effect of heat shock on development when embryos were in low oxygen. Furthermore, induction of TUNEL-positive cells in Day 5 embryos by heat shock only occurred when embryos were in high oxygen. Addition of DTT to two-cell embryos either did not reduce effects of a heat shock of 41 degrees C for 15 hr on development or caused slight protection only. In contrast, treatment of Day 5 embryos with DTT reduced effects of heat shock on development and apoptosis. In summary, oxygen tension was shown to be a major determinant of the effects of heat shock on development and apoptosis in preimplantation bovine embryos. Protective effects of the antioxidant DTT were stage specific and more pronounced at later stages of development.     

Insulin-like growth factor-I as a survival factor for the bovine preimplantation embryo exposed to heat shock

Insulin-like growth factor-I (IGF-I) is a survival factor for preimplantation mammalian embryos exposed to stress. One stress that compromises preimplantation embryonic development is elevated temperature (i.e., heat shock). Using bovine embryos produced in vitro as a model, it was hypothesized that IGF-I would protect preimplantation embryos by reducing the effects of heat shock on total cell number, the proportion of blastomeres that undergo apoptosis, and the percentage of embryos developing to the blastocyst stage. In experiment 1, embryos were cultured with or without IGF-I; on Day 5 after insemination, embryos >or=16 cells were cultured at 38.5 degrees C for 24 h or were subjected to 41 degrees C for 9 h followed by 38.5 degrees C for 15 h. Heat shock reduced the total cell number at 24 h after initiation of heat shock and increased the percentage of blastomeres that were apoptotic. Effects of heat shock were less for IGF-I-treated embryos. Experiment 2 was conducted similarly except that embryos were allowed to develop to Day 8 after insemination. The percentage reduction in blastocyst development for heat-shocked embryos compared with those maintained at 38.5 degrees C was less for embryos cultured with IGF-I than for control embryos. Heat shock reduced the total cell number in blastocysts and increased the percentage of blastomeres that were apoptotic, whereas IGF-I-treated embryos had increased total cell number and a reduced percentage of apoptosis. Taken together, these results demonstrate that IGF-I can serve as a survival factor for preimplantation bovine embryos exposed to heat shock by reducing the effects of heat shock on development and apoptosis.     

Prevention of spinal neural tube defects in the mouse embryo by growth retardation during neurulation

Homozygous mutant curly tail mouse embryos developing spinal neural tube defects (NTD) exhibit a cell-type-specific abnormality of cell proliferation that affects the gut endoderm and notochord but not the neuroepithelium. We suggested that spinal NTD in these embryos may result from the imbalance of cell proliferation rates between affected and unaffected cell types. In order to test this hypothesis, curly tail embryos were subjected to influences that retard growth in vivo and in vitro. The expectation was that growth of unaffected rapidly growing cell types would be reduced to a greater extent than affected slowly growing cell types, thus counteracting the genetically determined imbalance of cell proliferation rates and leading to normalization of spinal neurulation. Food deprivation of pregnant females for 48 h prior to the stage of posterior neuropore closure reduced the overall incidence of spinal NTD and almost completely prevented open spina bifida, the most severe form of spinal NTD in curly tail mice. Analysis of embryos earlier in gestation showed that growth retardation acts by reducing the incidence of delayed neuropore closure. Culture of embryos at 40.5 degrees C for 15-23 h from day 10 of gestation, like food deprivation in vivo, also produced growth retardation and led to normalization of posterior neuropore closure. Labelling of embryos in vitro with [3H]thymidine for 1 h at the end of the culture period showed that the labelling index is reduced to a greater extent in the neuroepithelium than in other cell types in growth-retarded embryos compared with controls cultured at 38 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Heat-shock induced tolerance to the embryotoxic effects of hyperthermia and cadmium in mouse embryos in vitro

Mammalian embryos growing in vitro are harmed by short elevations in the culture temperature. However, a relatively mild hyperthermic exposure can induce thermotolerance, a transient state of resistance to the effects of a subsequent heat exposure. The present study examines the induction of tolerance to heat and cross-tolerance to another teratogen, cadmium, in day 8 CD-1 mouse embryos in vitro. The ability of a mild heat pretreatment (5 min at 43 degrees C) to partially protect embryos against an embryotoxic heat exposure (20 min at 43 degrees C) was demonstrated. The frequency of death was reduced from 43% to 20%, abnormal branchial arches from 44% to 13.2%, and retarded turning from 22% to 5% in pretreated embryos. Other malformations, such as small forebrains and microphthalmia, were not affected, and the rate of exencephaly was significantly increased. The same heat pretreatment (5 min at 43 degrees C) was also found to reduce the damaging effects of a subsequent exposure to 1.75 microM cadmium. In the absence of pretreatment, cadmium caused 55% embryo deaths and 87% malformations, but prior heat exposure caused significant reductions in these frequencies to 29% and 55%. The total morphological score was higher in the pretreated group, as were the measurements of the yolk sac diameter, crown-rump length, and head length. Thus, embryos that have developed resistance to hyperthermia are also partially protected against the harmful effects of a second teratogen, cadmium. The response of the embryo to elevated temperatures may be involved in the development of tolerance to a variety of stresses.