Comparative studies of embryotoxic action of ethylenethiourea in rat whole embryo and embryonic cell culture

The effects of ethylenethiourea (ETU) were investigated using rat (Wistar-imamichi) embryos cultured from days 11 to 13 of gestation or cultured rat embryonic cells extracted on day 11. Malformations in cultured embryos at the concentration of 30 micrograms/ml of ETU were found in the head and tail, which were severely affected, as well as the limb and face. All embryos exposed to 150 and 300 micrograms/ml of ETU had malformed heads, tails, limbs, and facial configurations. Protein contents of the cultured embryos were decreased dose-dependently at the concentrations ranging from 30 to 300 micrograms/ml. In the histological studies of the cultured embryos with ETU, thinner neuroepithelium in head was observed. In the embryonic cells extracted on day 11 of gestation, ETU dose-dependently inhibited the differentiation of midbrain (MB) cells into neurons and that of limb bud (LB) cells into chondrocytes at the concentrations ranging from 30 to 600 micrograms/ml of ETU. The concentrations of ETU that inhibited the production of differentiated foci by 50% (IC50) were 170 micrograms/ml in LB cells of day 11, and greater than 600 micrograms/ml in LB cells on day 12 of development. Therefore, differentiation of MB cells was more sensitive to ETU than the differentiation of LB cells. These results indicated that there was a reasonable correlation of ETU induced changes in cultured whole embryos and embryonic cells.     

Growth and differentiation of fetal rat limb buds transplanted in athymic (nude) mice

Limb buds of day 14 rat fetuses were cut into pieces and transplanted into the subcutaneous tissue of athymic (nude) mice. In day 14 fetal limbs, mesenchymal cells have begun to condense to form cartilaginous anlage, but no cartilage has been formed. Within 7 days after grafting, masses of hyaline cartilage developed. Numerous osteoblasts appeared, and new bone formation began by 14 days. By 20 days, osteoclasts appeared, and the formation of bone trabeculae and marrow cavities progressed. The cytological characteristics of chondrocytes, osteoblasts and osteoclasts were essentially the same as those seen in vivo. Many grafts developed into long bones, having the diaphysis and epiphysis. The mode of chondrogenesis and osteogenesis in the grafts was histologically similar to the corresponding process in vivo, although the differentiation was slower in the grafted limbs. Since the grafted limb buds showed remarkable growth and tissue differentiation for at least several weeks, this heterotransplantation system would be of potential use for the study of bone formation and resorption as well as for developmental toxicological studies.     

In vitro teratogenicity of ethylenethiourea in the rat

We have demonstrated that ethylenethiourea (ETU) is a potent teratogen to the rat embryo developing in vitro. Sprague Dawley rat embryos were explanted on gestation day 10 and cultured for 48 hours in the presence of 40-200 micrograms/ml ETU. This resulted in a dose-related inhibition of growth and differentiation as assessed by crown-rump length, protein and DNA content, and somite number and in an increase in the frequency of abnormalities. A variety of anomalies was produced, including fluid accumulation in the brain (hydrocephalus), decreased mandibular size, decreased telencephalon size, abnormal dorsiflexion, as well as subectodermal blisters on the tail and limb buds and maxilla. Frank malformations have been observed at these same sites--hydrocephalus, brachygnathia, kyphosis, limb and tail defects, cleft palate--in the term fetus in vivo. The presence of abnormal fluid accumulation in the embryos--distended neural tube and subectodermal blisters--suggesting that the osmotic environment of the embryo had been altered by ETU exposure. Osmolality of the exocoelomic fluid (ECF) surrounding the embryo was measured after 48 hours of exposure to a concentration of ETU that caused nearly a 100% incidence of subectodermal blisters. ECF osmolality was found to be significantly lower than that of control embryos. Lowered osmolality would cause water to move out of the ECF, presumably causing the observed fluid accumulation in the embryo. It is speculated that altered osmotic balance and localized edema in the embryo are contributory steps in the formation of defects after ETU exposure.     

Lectin teratogenesis: defects produced by concanavalin A in fetal rabbits.

Concanavalin A (con A) is teratogenic to rabbit embryos during gestational days 12--15. Intracoelomic injections of 40 microliter con A solution (4 microgram/microliter) were performed on rabbit embryos during gestational days 10--15. Control embryos received either 40 microliter of saline, sham injection or no treatment. Con A caused increased fetal resorptions on days 10 and 11, but malformation levels did not differ from controls. On days 12--15, con A produced craniofacial, trunk and limb anomalies. The highest percentage of malformation occurred on day 14. The defects were classified into four groups: (1) malformations of limbs including paw and digital dysplasias as well as fusions of the limbs to the head or body wall; (2) "closure" defects such as umbilical hernia, encephalocoele, exencephaly or ectopia cordis; (3) "contracture" defects such as club paws, extended knees, or clenched digits, which exhibited normal osseous and cartilaginous skeletons; and (4) miscellaneous, non-specific anomalies including fused or dysplastic sternebrae or ribs. Histologic analysis of selected 12-day embryos 4 to 18 hours post-injection was performed to ascertain potential sites of teratogenic action. At 12 hours ectodermal necrosis was observed in the limb buds adjacent to the apical ectodermal ridge. By 18 hours, the ectoderm had eroded, exposing the basal lamina to the amniotic fluid. Focal areas of mesenchymal necrosis were observed in association with the ectodermal erosion. The potential roles of amniocentesis and limb bud repair in the genesis of the malformations are discussed.     

"Chemical surgery" as an approach to study morphogenetic events in embryonic mouse limb

Cytosine arabinoside (Ara-C) or retinoic acid (RA) was injected into pregnant mice in doses which induce a high incidence of limb defects. Within 4 hr of the treatment, extensive cell death was observed in the embryonic limb buds. However, the location of necrotic cells and the eventual limb defects were different for the two chemicals. Ara-C killed cells in those regions of the limb which were undergoing active proliferation. RA, on the other hand, had no effect on actively dividing cells but was lethal to cells of chondrogenic lineage at stages when their proliferation rate had fallen 7- to 10-fold below the original rate. In all cases, an excellent correlation between the location of dead cells (as seen 4 hr after drug treatment) and the eventual bony defects (as seen in the term fetuses) was observed. The unique properties of Ara-C and RA have been exploited in determining the relative levels of cytodifferentiation in the embryonic mouse limb buds. It is concluded that in the limbs of early 11th day mouse embryos (comparable to chick stage 19–20), differentiation of future skeletal elements has not yet begun. However, by the 12th day (comparable to chick stage 23), cell populations destined to form most of the future cartilages (except for digits) have already been established.     

Histological changes induced in developing limb buds of C57BL mouse embryos submitted in utero to the combined influence of acetazolamide and cadmium sulphate

Microscopic defects in limb buds of C57BL mouse embryos after the combined teratogenic action of acetazolamide plus cadmium sulphate administered on day 9 of gestation were studied in serial sections. Postaxial deficiencies observed in 12-15-day embryos and affecting preferentially the right forelimbs were classified in nine morphological types according to increasing amounts of missing parts. Type X defect consists of a nearly complete amelia in which all four limbs are represented only by the girdle and proximal end of the stylopod. Type XI abnormality appears as an intermediate reduction affecting the area of digit IV. In addition to modifications of the forelimb bud shape detected from the 10-day stage onwards, observations made 24 and 48 hr after treatment confirmed that the postaxial defects result from an absolute lack of postaxial mesoderm occurring without cell necrosis as a consequence of a postaxial shortening of the apical ectodermal ridge (aer). In 10-day embryos, the latter appears shortened and hypertrophied; it is later fragmented into alternate thick and thin portions in 11-day affected limb buds. These ectodermal changes might account for the genesis of all types of defects observed. Untreated 9-day embryos with 12-25 pairs of somites display a number of asymmetries between their right and left forelimb territories: Until the 19-somite stage, the vascular supply to that area is provided exclusively by the umbilical vein, which is larger on the right side; the initial amount of somatopleural limb mesoderm is greater in the right rudiment and the genesis of its aer is slightly protracted as compared to the left one. These asymmetries might contribute to the right side predominance of the forelimb defects induced by acetazolamide and cadmium.     

A teratoproteomics analysis: heat shock protein 70 is upregulated in mouse forelimb bud by methoxyacetic acid treatment

BACKGROUND: Methoxyacetic acid (MAA) causes fetal limb abnormalities when the substance is administrated on gestation day (GD) 11 in mice. Limb abnormalities are caused mainly by extensive cell death in the mesoderm of the limb plate. This investigation focused on identifying a protein that is linked with mouse limb teratogenicity. METHODS: A single dose of MAA at 10 mmol/kg body weight was administered by gavage on GD 11; controls were administered vehicle only. Dams were killed by cervical dislocation 4 hr after treatment and forelimb buds were isolated from both the control and treated embryos. Proteins in forelimb buds GD 11 + 4 hr were precipitated out using 40-60% ammonium sulfate and were then analyzed by 2D SDS-PAGE. Excised protein spots were identified by mass spectrometry and amino acid internal sequence analysis. Identified protein was further confirmed by Western blotting. RESULTS: Two-dimensional gel analysis indicated that 1 protein spot of 81.7 kDa/pI 7.3 was overexpressed, and the protein matched heat shock protein 70 (HSP70; accession no. P08109, SwissProt). CONCLUSIONS: The results suggest that MAA, when administered to pregnant mice, upregulates HSP70 in the forelimb buds.     

Locomotory behavior of limb bud cells : Effect of excess vitamin A in vivo and in vitro

Limb buds excised from 11th to 12th day mouse embryos were cut at the junction of the shaft and autopod to produce proximal and distal segments respectively. The ectodermal covering of each segment was surgically removed and the core of mesenchymal tissue was diced into small fragments. Proximal and distal fragments were cultured on separate Falcon plastic flasks in a fluid medium consisting of Hams F 12 and fetal calf serum. The fragments attached and began to spread on the surface of the flask within 12 h after seeding. The morphology and rate of movement of the cells from the fragment were observed at 12, 36, and 60 h in culture. The cells of control proximal fragments were bipolar in outline for most of the 3-day culture period, while the cells obtained from distal segments changed from bipolar to stellate by the 2nd day of culture. The bipolar outline seemed to be a reliable indicator of cells that actively move in culture. The rates of migration were calculated and showed that the bipolar proximal cells were more motile than cells from distal limb areas. When previously untreated cells were cultured in medium containing 10 IU vitamin A acetate/ml both shape and motility were affected. The cells became stellate in outline by the end of the 1st day in culture. The rate of movement of the treated cells of both proximal and distal culture fragments was much below control levels. When embryos were treated in utero on day with vitamin A acid (retinoic acid) and limb fragments prepared and cultured as described above, the cells exhibited a stellate shape and a decrease in migration tendencies during the first 12 h after seeding. By the end of the 3-day culture period the apparent recovery from retinoic acid treatment was demonstrated in both the morphology and the increased rate of movement of the cells. These results indicate that a difference between proximal and distal control cell migratory rates exists which, if manifest in the developing mouse limb bud, may play a role in the attainment of proper limb shape. Vitamin A seems capable of impairing those properties of cells necessary for cell movement which might be a factor involved in the production of the limb defects observed after maternal hypervitaminosis A in the mouse.     

Distribution of polarizing activity and potential for limb formation in mouse and chick embryos and possible relationships to polydactyly

A central feature of the tetrapod body plan is that two pairs of limbs develop at specific positions along the head-to-tail axis. However, the potential to form limbs in chick embryos is more widespread. This could have implications for understanding the basis of limb abnormalities. Here we extend the analysis to mouse embryos and examine systematically the potential of tissues in different regions outside the limbs to contribute to limb structures. We show that the ability of ectoderm to form an apical ridge in response to FGF4 in both mouse and chick embryos exists throughout the flank as does ability of mesenchyme to provide a polarizing region signal. In addition, neck tissue has weak polarizing activity. We show, in chick embryos, that polarizing activity of tissues correlates with the ability either to express Shh or to induce Shh expression. We also show that cells from chick tail can give rise to limb structures. Taken together these observations suggest that naturally occurring polydactyly could involve recruitment of cells from regions adjacent to the limb buds. We show that cells from neck, flank and tail can migrate into limb buds in response to FGF4, which mimics extension of the apical ectodermal ridge. Furthermore, when we apply simultaneously a polarizing signal and a limb induction signal to early chick flank, this leads to limb duplications.     

Studies of the role of ischemia/reperfusion and superoxide anion radical production in the teratogenicity of cocaine.

The administration of multiple doses of cocaine on a single day during late gestation is teratogenic in rats in which hind limb ectrodactyly is a major finding (Webster and Brown-Woodman, '90). We have previously hypothesized that these limb malformations result from the generation of reactive oxygen species during the process of ischemia/reperfusion in vivo. In order to study the direct effects of cocaine versus the aberrant oxygenation it may induce, we have developed a system for culturing rat embryos between days 14 and 15 of gestation. Growth and development of cultured embryos are comparable to that of in vivo controls. Exposure to normoxia (95% O2) with or without cocaine failed to induce limb malformations and exposure to a single long period of hypoxia (20% O2) only reduced limb growth in the anterior-posterior axis. By contrast, embryos receiving multiple brief exposures to hypoxia developed a significant incidence of hind limb ectrodactyly that appeared indistinguishable from that induced by cocaine in vivo. By incubating day 14 embryos in a nitroblue tetrazolium derivative, 1-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide (MTT), it was shown that superoxide anion radical appears in the digital rays following two episodes of reperfusion. Little reaction product was seen under the other conditions. Finally, mitochondrial electron transport particles prepared from teratogenically sensitive limb buds spontaneously "leak" electrons to form superoxide anion radical whereas those from insensitive heart fail to do so. We propose that cocaine and other exposures that can transiently reduce conceptual oxygenation during late gestation are teratogenic by virtue of their capacity to induce ischemia/reperfusion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Retinoic-acid-induced limb-reduction defects: perturbation of zones of programmed cell death as a pathogenetic mechanism

Pregnant C57Bl/6J mice were treated with 100 mg/kg body weight of all-trans retinoic acid in sesame oil on day 11.0 of gestation. Among the live fetuses harvested on day 18 of gestation, 100% had mesomelic defects of the limbs as determined by gross examination and skeletal staining. Control fetuses treated with sesame oil had no observable limb malformations. Some treated and control embryos were harvested 12 hr after treatment and examined for patterns of cell death by using the supravital stain Nile blue sulphate and methylene-blue- and acid-fuchsin-stained histological sections. Retinoic-acid-induced cell death in the core of the limb was always associated with the zones of programmed cell death as seen in control embryos of comparable stages. This, in concert with previous studies demonstrating excessive cell death in regions of programmed cell death that correlated with subsequent malformations, leads us to conclude that the pathogenesis of mesomelic malformations has a primary association with the phenomenon of programmed cell death.     

The teratogenic mechanism of 6-aminonicotinamide on limb formation of chick embryos: abnormalities in the biosynthesis of glycosaminoglycans and proteoglycans in micromelia

After a dose of 10 micrograms of 6-aminonicotinamide (6-AN) was administered to day-4- chick embryo in ovo, micromelia was obviously observed in the hind limbs of 7-day chick embryos. We examined the teratogenic mechanism of 6-AN by using the normal or micromelial hind limbs (buds) from day 5 to day 7, with special attention to the biosynthesis of glycosaminoglycan (GAG) and proteoglycan as an index of limb chondrogenesis. The present study provides evidence for abnormalities in the levels of GAG or proteoglycan biosynthesis in the micromelial hind limbs (buds). 1) Both [35S]sulfate and [3H]glucosamine incorporation into GAG per 10 limbs or mg DNA of the micromelia were inhibited, suggesting a decrease of GAG synthesis. 2) The micromelial limbs synthesized low-sulfated chondroitin sulfate (chondroitin) as judged by the 35S/3H ratio, the proportion of unsulfated disaccharide (delta Di-0S), and the result of cellulose acetate electrophoresis, although there were no significant differences in the approximate molecular size of 35S-chondroitin sulfates synthesized between the normal and micromelial limbs. 3) PAPS-synthesizing activity in the micromelial limbs was markedly inhibited, and this may result in the production of low-sulfated proteoglycan. 4) The transition from mesenchymal- to cartilage-specific proteoglycan synthesis did not appear in the micromelial limbs as judged by the sedimentation profiles. 5) 6-AN caused marked reductions in the oxygen consumption and ATP level of the micromelial limbs, thereby causing the defect in PAPS formation. We suggest that these 6-AN-induced sequential molecular defects (the reduction of respiratory activity, ATP and PAPS level, and concomitant interference with GAG and proteoglycan biosynthesis) in the limbs (buds) during the critical period of limb morphogenesis must be major factors resulting in the cartilage growth retardation or disorder, i.e., micromelia.     

The development of hormonal responses of cultured embryonic chick limb mesenchymal cells

Cells obtained from stage 24 chick limb buds were cultured and assayed for their ability to respond to exogenously supplied parathyroid hormone (PTH) as monitored by analysis of cellular cyclic AMP (cAMP). After 3–4 days in culture, these cells developed a striking responsiveness to the hormone; 20 -to 50-fold elevations in cAMP were routinely observed upon exposure to 10^?8, M hormone for 2 min. This response was greatest in cells initially plated at low densities (1 × 10⁶ cells/35-mm dish) and was inversely correlated to the amount of cartilage which developed in such cultures. Cells obtained from limbs of stages 23–26 embryos developed a similar responsiveness to PTH after 3–4 days in culture, but cells obtained from limbs of stage 22 embryos showed no such responsiveness even after 6 days in culture. A response to calcitonin also was noted in cultures of stage 24 limb mesenchymal cells after 4–5 days in culture, but this was of much smaller magnitude than the PTH response. Of 12 other hormones tested, only β agonists elicited any cAMP response in the cultered stage 24 limb mesenchymal cells. Although cells initially plated at a high density and grown for 8 days in culture show no response to PTH, the presence of PTH-responsive cells in such cultures could be demonstrated by sequential digestion with collagenase and replating the extracellular matrix-free cells released by this treatment. Such replated cells then exhibited a responsiveness to PTH. Thus, the responsiveness of cultured limb mesenchymal cells depends on the developmental stage of the starting limb mesenchyme, the phenotypes which develop, and physical factors such as accessibility to exogenously supplied hormone.     

Nerve growth factor in skeletal tissues of the embryonic chick

Summary This study demonstrates, via immunohistochemistry and bioassay, the presence of NGF in embryonic bone and cartilage of the chick. Embryos were killed on days 6–9 of incubation at 12 h intervals, and on days 10–18 at 24 h intervals. Paraffin-embedded sections of hind limbs or buds were immunostained with a polyclonal antibody against NGF and the biotin-avidin-horseradish peroxidase technique. Immunostaining was positive in both bone and cartilage, with cartilage staining more intensely. For bioassay, bones from the hind limbs of 9- and 12-day embryos were fast-frozen, lyophilized, and homogenized with Medium 199 (M199). Dorsal root ganglia from 8-day embryos were cultured for 24–36 h with rooster plasma, M199, and varying concentrations of bone homogenate. Significant neurite outgrowth was seen, with the greatest response elicited by 12-day bone homogenate. Addition of anti-NGF to the cultures abolished neurite outgrowth. The results indicate that NGF is present in cartilage and bone of the chick embryo; it may determine the density of sympathetic innervation to the developing skeletal tissues.     

Formation of cartilage in organ-cultured leg buds of chick embryo

When the leg buds from chick embryos at stages 17-23 were cultured as organ cultures in F12 medium, which contained chick serum and an extract of chick embryos, leg cartilage structures developed that included pelvic girdle, femur, tibiofibula, and tarsometatarsus. The proportion of explants with definite distal elements increased when the leg buds from later embryos were used. Supplementation with chick serum was essential. These results suggest that the pattern of formation of limbs in chick embryos can be studied in organ culture.     

Effects of cytosine arabinoside on in vivo and in vitro mouse limb development

Summary When pregnant mice were exposed to 40 mg per kg of cytosine arabinoside (ara-C) on days 10 to 12 of gestation, adactylous limbs with large, distally located blisters were found when the fetuses were examined on day 18. Embryonic limbs exposed transplacentally under identical conditions and explanted to culture exhibited the same morphological abnormality as did limbs exposed directly in culture to 0.1 to 1 μg per ml of ara-C. Two noncytotoxic analogues of ara-C, uridine arabinoside (ara-U) and hypoxanthine arabinoside (ara-HX), had no influence on morphological differentiation of limbs in vitro. Ara-C alone caused a dose-related decrease in uptake of³H-thymidine and³⁵SO₄ in cultured limb buds. Production of this morphologically distinct malformation in vitro will allow detailed biochemical investigations on the effect of ara-C limb ectodermal-mesenchymal interactions. Supported by NIH Postdoctoral Fellowship No. CM02660. Supported by NIEHS Predoctoral Fellowship No. ES00127. Supported by NIEHS Toxicology Training Grant No. ES00127.     

Lectin teratogenesis. II: Demonstration of increased binding of concanavalin A to limb buds of rabbit embryos during the teratogenically sensitive period

The plant lectin concanavalin A (con A) causes malformations of rabbit embryos when 160 micrograms (in 40 microliter) are injected into the exocoelom on gestational days 12-15 but does not cause malformations on days 10-11. The purpose of this study was to investigate the mechanism for increased susceptibility of day 12-15 embryos to con A teratogenicity. Light microscopy of day 11 embryos 15-20 hr after treatment with con A revealed no observable difference from controls. Day 13 embryos at similar times exhibited limb buds with large areas that were denuded of ectoderm. Concurrent addition of alpha-methyl-D-mannoside (alpha MM), a specific inhibitor of con A, to the injection solution of day 13 embryos resulted in limb buds that appeared normal. The regions of con A binding to day 11 and day 13 embryos were visualized through epifluorescent microscopy of untreated embryos stained with fluorescein-labelled con A. Day 11 embryos exhibited moderate fluorescence on the surface of limb buds and the pericardial region. Day 13 embryos exhibited strong fluorescence of limb bud surfaces; the pericardial region remained moderately fluorescent. Addition of alpha MM to the incubation medium resulted in no fluorescence above background. Visualization of con A receptors was accomplished by ultrastructural analysis of forelimb buds stained with ferritin-labelled con A. Ferritin label was observed only on the surfaces of the ectoderm and was sparse over all regions of day 11 limb buds. In contrast, ferritin label was moderately heavy in all regions of the day 13 limb buds. No labelling occurred when the ferritin-labelled con A was preincubated with alpha MM. These observations indicate that the number of exposed con A receptors on limb buds of teratogenically sensitive embryos (day 13) is increased, compared with the number of exposed receptors on limb buds of younger, insensitive (day 11) embryos. The increased number of exposed con A receptors on limb buds during the teratogenically sensitive period provides not only increased binding of the lectin to sensitive embryos but also a potential mechanism for the anomalous attachment of distal regions of the limb buds to the body wall.     

Studies on the mechanism of trypan blue teratogenicity in the rat developing in vivo and in vitro

Trypan blue is a potent teratogen in vivo and in vitro in the rat. Many of the abnormalities produced by trypan blue--including swollen neural tube and pericardium, subectodermal blisters, hematomas, and generalized edema--may result from altered fluid balance in and around the embryo. The present study demonstrates relationships between changes in the fluid environment around the embryo and appearance of anomalies. Rat embryos were exposed in utero or in vitro to trypan blue during the early period of organogenesis. Both exposures resulted in defects that are typical of trypan blue treatment. Osmolality of exocoelomic fluid (ECF) was measured on gestation day 10 in vivo and day 12 in vitro, both after 48 hr of exposure to trypan blue. In both cases ECF osmolality was significantly lower than controls. This was correlated with the presence of edema-related anomalies in the embryo. On gestation day 11 in vivo, three days after maternal injection of trypan blue, ECF osmolalities were significantly higher than controls; however, there was tremendous variability in this parameter in day 11 treated embryos, and some had ECF osmolalities below the control range. Increased frequency of abnormalities was correlated with abnormal ECF osmolality, below and above the control range. Trypan blue probably exerts its teratogenic effects by disturbing the function of the visceral yolk sac. The movements of an amino acid and a monosaccharide across the visceral yolk sac were measured on gestation day 12 embryos in vitro. This aspect of yolk sac function was not altered by trypan blue exposure. Ultrastructure of the visceral yolk sac was observed after trypan blue exposure in vivo and in vitro. Endodermal cells in trypan blue-treated yolk sacs contained fewer large, electron dense lysosomes than controls. These were replaced by numerous small vacuoles, which may contain trypan blue. Trypan blue causes osmotic changes in the rat embryo in vivo and in vitro. These changes are correlated with embryonic malformations. Alterations in yolk sac ultrastructure indicate that trypan blue affects the function of this membrane.     

Morphological alterations in the developing fetal rat limb due to maternal injection of chlorambucil

On day 14 of pregnancy, rats were injected i.p. with 9.5 mg/kg of chlorambucil. At term, all the fetuses were stunted and had obvious skeletal malformations. From days 15-20 of gestation there was a steady progression of cell death and histologic derangement in long bone formation. This began on day 15, the day following exposure to chlorambucil, with extensive cell death of chondroblasts in the long bone primordia. By day 16, dead or dying cells were located in the cartilage model and became associated with a higher than normal matrix to cell ratio. In day 17 limbs, many cells of the cartilage model were irregular in size and shape so that the normally precise cellular arrangement was lacking. On day 18, periosteal and enchondrial calcification was delayed and scanty. The fibular hemimelia observed in all drug-treated term fetuses stained with alizarin appeared to result from lack of development of the proximal half of the cartilage model. The observed alterations, particularly bowing of the ulna, in the teratogen-treated fetuses appeared to result primarily from specific cell death and formation of aberrant cell types but abnormal cell products may also play a role.