Relationship between abnormal somite development and axial skeletal defects in rats following heat exposure

Influence of hyperthermal regimes on experimental teratoma development in vitro

We screened for the impact of hyperthermal regimes varying in the cumulative equivalent minutes at 43°C (CEM43°C) and media composition on tumour development using an original teratoma in vitro model. Rat embryos (three germ layers) were microsurgically isolated and cultivated at the air‐liquid interface. During a two week period, ectodermal, mesodermal and endodermal derivatives developed within trilaminar teratomas. Controls were grown at 37°C. Overall growth was measured, and teratoma survival and differentiation were histologically assessed. Cell proliferation was stereologically quantified by the volume density of Proliferating Cell Nuclear Antigen. Hyperthermia of 42°C, applied for 15 minutes after plating (CEM43°C 3.75 minutes), diminished cell proliferation (P ˂ .0001) and enhanced differentiation of both myotubes (P ˂ .01) and cylindrical epithelium (P ˂ .05). Hyperthermia of 43°C applied each day for 30 minutes during the first week (CEM43°C 210 minutes) impaired overall growth (P ˂ .01) and diminished cell proliferation (P ˂ .0001). Long‐term hyperthermia of 40.5°C applied for two weeks (CEM43°C 630 minutes) significantly impaired survival (P ˂ .005). Long‐term hyperthermia of 40.5°C applied from the second day when differentiation of tissues begins (CEM43°C 585 minutes) impaired survival (P ˂ .0001), overall growth (P ˂ .01) and cartilage differentiation (P ˂ .05). No teratomas survived extreme regimes: 43°C for 24 hours (CEM43°C 1440 minutes), hyperthermia in the scant serum‐free medium (CEM43°C 630 minutes) or treatment with an anti‐HSP70 antibody before long‐term hyperthermia 40.5°C from the second day (CEM43°C 585 minutes). This in vitro research provided novel insights into the impact of hyperthermia on the development of experimental teratomas from their undifferentiated sources and are thus of potential interest for future therapeutic strategies in corresponding in vivo models.

Understanding the somitogenesis clock: what's missing?

The segmentation of vertebrate embryos depends on a complex genetic network that generates highly dynamic gene expression. Many of the elements of the network have been identified, but their interaction and their influence on segmentation remain poorly understood. A few mathematical models have been proposed to explain the dynamics of subsets of the network, but the mechanistic bases remain controversial. This review focuses on outstanding problems with the generation of somitogenesis clock oscillations, and the ways they could regulate segmentation. Proposals that oscillations are generated by a negative feedback loop formed by Lunatic fringe and Notch signaling are weighed against a model based on positive feedback, and the experimental basis for models of simple negative feedback involving Her/Hes genes or Wnt targets is evaluated. Differences are then made explicit between the many 'clock and wavefront' model variants that have been proposed to explain how the clock regulates segmentation. An understanding of the somitogenesis clock will require addressing experimentally the many questions that arise from the study of simple models.

Histological, histochemical and electron microscopic changes of the placenta induced by maternal exposure to hyperthermia in the rat

Both clinical and experimental investigations have shown that maternal hyperthermia during critical stages of embryo development can induce malformations in the offspring. Studies of the effect of heat stress on the placental functions are limited to the ewes, but that on microscopic structure is unknown. In the present study, rats were exposed to 41 or 42 degrees C for 1 h on gestation day (GD) 9. The controls were sham treated. Fetuses and placentas were collected on GD 20. Intrauterine growth retardation (IUGR) and several craniofacial malformations were observed in the fetuses of the heat-treated group. The placentas of the 42 degrees C group were significantly lighter in weight than those of the control. Light microscopy (LM) revealed thickening, hyalinization and occasional lymphocytic infiltration of the decidua basalis. Giant cells were prominent and glycogen cells had degenerated, leaving behind large cysts in the basal (spongy) zone. Best's carmine stain with or without diastase indicated the reduction in number and degeneration of glycogen cells and cyst formation. The labyrinthine zone was relatively thin in comparison to that of the controls. Perivascular fibrosis and paucity of vascularization were other features of the placentas of the hyperthermia group. Electron microscopy (EM) revealed lipid droplet accumulation in the trophoblast, the presence of myelin bodies and an increased production of collagen in the basal zone. Perivascular fibrosis appeared to have contributed to placental barrier thickening. EM also revealed accumulation of glycogen and lipid droplets in the trophoblasts and fibrin secretion into the extracellular space of the labyrinthine zone. These data suggest that placental pathology possibly contributes to fetal growth retardation in maternally heat-stressed rat fetuses.

Effects of hyperthermia and boric acid on skeletal development in rat embryos

BACKGROUND

The individual effects of boric acid (BA) and hyperthermia on the development of the axial skeleton have been reported previously. Both cause an increased incidence of axial skeletal defects including a decrease in the total number of ribs and vertebrae. Because of the similarity in the effects of the two agents, we examined their interaction when given in combination to pregnant rats on gestational day (GD) 10.

METHODS

Dams were treated on GD 10 with BA (0, 250, or 500 mg/kg) and hyperthermia (37, 41, or 42 degrees C) and allowed to deliver their pups. Doses of BA were based on results from a dose-finding study. Litters were evaluated on postnatal days (PND) 1 and 3 for number, gender, and weight of pups. On PND3, pups were examined externally and viscerally, and double-stained for skeletal evaluation.

RESULTS

A dose-dependent, statistically significant increase in fetal skeletal defects was seen on PND 3 with BA or hyperthermia alone with even greater effects when given in combination. Defects included rib and vertebral fusions, split vertebral centra in the thoracic and lumbar areas, and a decrease in the total number of ribs and vertebrae.

CONCLUSIONS

The increased incidence of skeletal defects resulting from combined exposure to hyperthermia and BA was additive for segmentation defects and synergistic for the reduction in numbers of vertebrae.

Stage-specific homeotic vertebral transformations in mouse fetuses induced by maternal hyperthermia during somitogenesis

To investigate the heat shock effects upon somitogenesis and specification of the vertebral identity, pregnant ICR mice were briefly exposed to 42 degrees C or 43 degrees C at E7.5, E8.5, or E9.5 (noon of the plug day = E0.5). Heat treatment induced embryonic day-specific vertebral transformations whose frequency and severity were dependent on the temperature elevation. Following a heat treatment at E8.5, the vertebral identity of T6 through S1 was shifted anteriorly by one or two segments (posterior transformations). Such shifts were found in more than one-third of the fetuses heat-stressed at 42 degrees C, and in over 90% of those exposed to 43 degrees C. When heated at E7.5, the anterior boundary of vertebral transformations was shifted cranially to cervical levels (C1-C7), and when heated at E9.5, it was shifted caudally to the lower thoracic and lumbar levels (T13-L4). Examination of Hox gene expression domains by in situ hybridization showed that the anterior boundaries of Hoxa-5, Hoxa-7, Hoxc-8, and Hoxc-9 expression domains in the paraxial mesoderm were shifted cranially by one somite segment in embryos heated at E7.5, as compared with the corresponding levels of their expression in control embryos. Such cranial shifts were found for Hoxa-7, Hoxc-8 and Hoxc-9, but not for Hoxa-5, in embryos heated at E8.0. In embryos heated at E8.5, only the expression domains for Hoxc-8 and Hoxc-9 were found to be shifted. The observed stage-specific vertebral transformations and shifts of the Hox gene expression domains were consistent with the temporal colinearity and posterior predominance of Hox gene expression during development. Further histological and cytochemical analyses revealed that heat-induced vertebral transformations may not be a result of induced cell death, but heat-induced transient arrest of cell proliferation and somitogenesis could result in altered expression of Hox genes and subsequently produce vertebral transformations.

Teratogenic and lethal effects of long-term hyperthermia and hypothermia in the chick embryo

The teratogenic effect of maternal hyperthermia is well known in laboratory animals and is presumed to exist also in humans. The aim of our study was to describe the embryotoxic effect of long-term higher and lower incubation temperatures on the chick embryo. Chick embryos were incubated within days 1 to 9 at 12 different incubation temperatures ranging from 31 to 42 degrees C. On the basis of our results, we estimated that there are three upper and lower critical thresholds of the incubation temperature: the first thresholds are 31 and 42 degrees C, at which all embryos died; the second thresholds are 32 and 41 degrees C, at which all living embryos were malformed; the third thresholds are 33 and 40 degrees C, at which some of the living embryos were without structural malformations, but their weight was shifted down and up with lower and higher temperature, respectively. The incubation temperature of 37 to 38 degrees C was optimal. Typical malformations detected on day 9 of incubation were microphthalmia, gastroschisis, caudal regression syndrome, and hyperlordosis, all of which occurred in dead embryos several times more frequently than in living embryos. CNS malformations were only sporadically present on day 9, as most of specimens bearing CNS defects died during the first days of incubation.

Induction of hsp72 in heat-treated rat embryos: a tissue-specific response

Previous studies have demonstrated that heat exposure on gestation day 10 (GD10) resulted in disrupted somite development in rat embryos 24 hr after exposure and in thoracic skeletal malformations in neonatal rats examined 3 days postpartum. The production of abnormal somites was correlated with the location of skeletal elements that developed from the affected somites. Heat has also been shown to induce changes in genetic expression whereby new proteins are synthesized and the expression of constituent proteins may be repressed. In the present study, heat-induced alterations in protein synthesis during rat organogenesis that may be associated with previously observed malformation was investigated. GD10 rat embryos were exposed in utero to a heat treatment previously demonstrated to produce skeletal malformations; maternal core temperature was raised and maintained at 42-42.4 degrees C for 5 min. In addition, explanted GD10 embryos were cultured in vitro and exposed to temperatures of 42-42.5 degrees C for 15 min. At various times postexposure, embryos were labeled with 35S-methionine and processed for SDS-PAGE. In both in vivo and in vitro heat-treated embryos, a transient enhanced de novo synthesis of 70- and 90-kD proteins was observed 1-8 hr after exposure. Actinomycin D studies were conducted to determine whether transcription of new mRNA was required for the enhanced synthesis of the 70- and 90-kD proteins in heat-treated embryos. Results from these studies demonstrated that the expression of these proteins was transcriptionally regulated. The 70-kD protein was identified, using Western blot analysis, as a eukaryotic inducible stress protein (hsp72), and the presence of this protein was detected between 2 and 27 hr post-treatment. Immunohistochemical results indicated that following heat shock, hsp72 accumulates in the neuroectodermal tissues of the embryos. The data demonstrate that although heat-induced expression and accumulation of the hsp72 precedes aberrant somite morphology, the lack of hsp72 accumulation in the somite mesoderm may explain the sensitivity of this tissue to heat.