Heat-induced alterations in embryonic cytoskeletal and stress proteins precede somite malformations in rat embryos (original) (raw)
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Reproductive Toxicology, 1999
Epidemiologic studies strongly suggest that in utero exposure to hyperthermia results in developmental defects in humans. Rats, mice, guinea pigs, and other species exposed to hyperthermia also exhibit a variety of developmental defects. Studies in our laboratory have focused on exposure to hyperthermia on Gestation Day (GD) 10 of rats in vivo or in vitro. Within 24 h after in vivo or in vitro exposure, delayed or abnormal CNS, optic cup, somite, and limb development can be observed. At birth, only rib and vertebral malformations are seen after hyperthermia on GD 10, and these have been shown to be due to alterations in somite segmentation. Unsegmented somites have been thought to result from a cell-cycle block in the presomitic mesoderm, from which somites emerge individually during normal development. In the present study, DNA fragmentation (terminal deoxynucleotidyl transferase (TdT) catalyzed fluorescein-12-dUTP DNA end-labelling), indicative of apoptotic cell death, and changes in cell proliferation were examined in vitro in 37°C control and heat treated (42°C for 15 min) GD 10 CD rat embryos. Embryos were returned to 37°C culture following exposure and evaluated 5, 8, or 18 h later. A temperature-related increase in TdT labelled cells was observed in the CNS, optic vesicle, neural tube, and somites. Increased cell death in the presomitic mesoderm also was evident. Changes in cell proliferation were examined using the cell-specific abundance of proliferating cell nuclear antigen (PCNA) and the quantification of mitotic figures. In neuroectodermal cells in the region of the optic cup, a change in the abundance of PCNA was not apparent, but a marked decrease in mitotic figures was observed. A significant change in cell proliferation in somites was not detected by either method. These results suggest that acute hyperthermia disrupts embryonic development through a combination of inappropriate cell death and/or altered cell proliferation in discrete regions of the developing rat embryo. Furthermore, postnatal vertebral and rib defects following disrupted somite development may be due, in part, to abundant cell death occurring in the presomitic mesoderm.
Reorganization of Microfilaments and Microtubules by Thermal Stress in Two-Cell Bovine Embryos
Biology of Reproduction, 2004
Two-cell bovine embryos become arrested in development when exposed to a physiologically relevant heat shock. One of the major ultrastructural modifications caused by heat shock is translocation of organelles toward the center of the blastomere. The objective of the present study was to determine if heatshock-induced movement of organelles is a result of cytoskeletal rearrangement. Two-cell bovine embryos were cultured at 38.5؇C (homeothermic temperature of the cow), 41.0؇C (physiologically relevant heat shock), or 43.0؇C (severe heat shock) for 6 h in the presence of either vehicle, latrunculin B (a microfilament depolymerizer), rhizoxin (a microtubule depolymerizer), or paclitaxel (a microtubule stabilizer). Heat shock caused a rearrangement of actin-containing filaments as detected by staining with phalloidin. Moreover, latrunculin B reduced the heat-shock-induced movement of organelles at 41.0؇C but not at 43.0؇C. In contrast, movement of organelles caused by heat shock was inhibited by rhizoxin at both temperatures. Furthermore, rhizoxin, but not latrunculin B, reduced the swelling of mitochondria caused by heat shock. Paclitaxel, while causing major changes in ultrastructure, did not prevent the movement of organelles or mitochondrial swelling. It is concluded that heat shock disrupts microtubule and microfilaments in the two-cell bovine embryo and that these changes are responsible for movement of organelles away from the periphery. In addition, intact microtubules are a requirement for heat-shock-induced swelling of mitochondria. Differences in response to rhizoxin and paclitaxel are interpreted to mean that deformation of microtubules can occur through a mechanism independent of microtubule depolymerization. embryo, early development, heat shock, in vitro fertilization
Biology of Reproduction, 2003
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. Twocell embryos produced in vitro were harvested at ϳ28 h postinsemination and cultured for 6 h at one of three temperatures: 38.5؇C (cow body temperature), 41.0؇C (characteristic temperature for heat-stressed cows), or 43.0؇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؇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؇C or 41.0؇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. embryo, environment
Induction of hsp72 in heat-treated rat embryos: A tissue-specific response
Teratology, 1995
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.
Developmental Dynamics, 1992
Heat shock causes partial disruption of the segmentation pattern during somitogenesis in Xenopus as well as in other vertebrates. However, X e m p u s undergoes a different type of somite formation than that of most vertebrates: Somites are formed by rotation of cell blocks out of the paraxial mesoderm. We attempted to determine whether or not the segmentation disorder following heat shock is caused by an altered pattern of fibronectin and/or laminin, that could then effect the rotation of cell blocks. Therefore, we carried out heat shock experiments and analyzed the distribution of both ECM proteins in correlation to the position of somitic cells.
2017
Gene expression is required in all steps of embryonic development and therefore heat stress is known to reduce developmental competence after direct exposure of oocytes and embryos to different conditions of heat shock, by decreasing protein synthesis. Moreover, as in somatic cells, the heat stress befuddles the integration of RNA and posttranscrip‐ tional modification of RNA, the assumption was that during meiotic maturation heat shock may mutate RNA within oocytes, with the possibility of altering the surround‐ ing cumulus cells, causing, thus, reductions in development. Heat shock proteins (HSP) are among the first proteins produced during embryonic development and are crucial to cell function. The HSP70 (HSPA14 gene) is an important part of the cell’s machinery for folding, unfolding, transport, localization of proteins and differentiation, regulation of the embryonic cell cycle and helping to protect cells from stress. Therefore, HSPA14 is an apoptotic gene induced by heat shoc...
Hyperthermia in the chick embryo: HSP and possible mechanisms of developmental defects
The International journal of developmental biology, 1998
Although hyperthermia is an established teratogen in all species studied and the cellular heat shock response is well known, the mechanisms of developmental deviation remain obscure. We have used a chick model system in which fertilized eggs containing embryos at presomite and/or early somite stages (HH 4-10) were exposed to 45 degrees C for 180 min. Six hours following treatment we did not observe any overt morphological disturbance, but at twelve hours following exposure (when controls reached HH 11-13) embryos exposed at late streak stages (HH 4-6) exhibited severe malformation of the head. Embryos exposed later (HH 6-9) manifested spina bifida at the thoracic and lumbosacral levels. Mirror image heart looping was also observed in 20% of these embryos. Paraxial mesoderm was apparently unaffected. Changes in cell proliferation and induced cell death preceded morphological changes. We used acridine orange and confocal laser microscopy to demonstrate that hyperthermia induced cell d...
Stress for Stress Tolerance? A Fundamentally New Approach in Mammalian Embryology
Biology of Reproduction, 2010
In vitro culture, storage, and manipulation of gametes and embryos require meticulously adjusted conditions to avoid or minimize the harmful effects of uncontrolled stress. However, recent work indicates that a well-defined and properly applied stress may induce general adaptation and increase tolerance to various in vitro procedures. The aim of this review is to summarize reports on the effects of stress on gametes and embryos of several species. Treatment with sublethal doses of high hydrostatic pressure (HHP), or osmotic, heat, or oxidative stress resulted in increased morphological survival, fertilizing ability, or developmental potential after various in vitro or in vivo procedures. HHP treatment of spermatozoa, oocytes, embryos, and embryonic stem cells increased fertilizing ability, developmental competence, and differentiation and improved results after cryopreservation, parthenogenetic activation, intracytoplasmic sperm injection, and somatic cell nuclear transfer. Osmotic stress of oocytes resulted in higher developmental rates after cryopreservation, parthenogenetic activation, and somatic cell nuclear transfer. Heat shock was reported to increase developmental competence of parthenogenetically activated oocytes. Although cellular and subcellular mechanisms supposedly contributing to these processes require further research, the new principle, i.e., to improve the stress tolerance by a defined sublethal stress, may outline a completely new strategy in mammalian embryology, as well as cryopreservation of other cells and tissues with remarkable theoretical and practical consequences. embryo, hydrostatic pressure, ovum, sperm, stress
Reproduction, 2005
Meiotic maturation in mammalian oocytes is a complex process which involves extensive rearrangement of microtubules, actin filaments and chromosomes. Since cytoskeletal elements are sensitive to disruption by heat shock, a series of experiments were performed to determine whether physiologically relevant heat shock disrupts the progression of the oocyte through meiosis, fertilization and zygote formation. Cumulus–oocyte complexes were cultured at 38.5, 40.0 or 41.0 °C for the first 12 h of maturation. Incubation during the last 10 h of maturation and 18 h after fertilization was at 38.5 °C and in 5% (v/v) CO2 for both treatments. Examination of the cytoskeleton and the chromosome organization in matured oocytes revealed that oocytes matured at 38.5°C were mostly at metaphase II (MII) stage, while the majority of heat-shocked oocytes were blocked at the first metaphase (MI), first anaphase or first telophase stages. A subset of heat-shocked oocytes possessed misshapen MI spindles wit...