James B. LaBorde

Leukoencephalomalacia and hemorrhage in the brain of rabbits gavaged with mycotoxin fumonisin B1.

Two of five pregnant rabbits gavaged with purified fumonisin B1 at 1.75 mg/kg/day died, one after 9 and one after 13 doses. Microscopic examination revealed focal small hemorrhages in cerebral white matter in both animals, with malacia and hemorrhage also present in the hippocampus of one. The lesions were bilateral. Both animals also had marked degeneration of renal tubule epithelium and of hepatocytes. Apoptosis was the dominant degenerative change in kidney and liver. Fumonisin is known to cause leukoencephalomalacia and hemorrhage in equines, but CNS changes associated with exposure to fumonisins apparently have not been reported in other species. This preliminary observation in rabbits is reported to alert other investigators of a potential model of the disease in equines, as well as for investigation of potential mechanisms of toxicity to the CNS.

Renal Effects of Fumonisin Mycotoxins in Animals

Fumonisins are mycotoxins produced worldwide by Fusarium fungi, principally F. moniliforme. The fungus is present in virtually all harvested com, but the toxins produced are variable. The toxins, especially fumonisin B1, cause mild to fatal diseases in animals, with peculiar species specificity for the dominant signs of toxicity. The mechanism of toxicity is poorly understood, but it appears to be related to interference with sphingolipid biosynthesis in multiple organs. Whereas brain, lung, and liver are well-known target organs, toxic effects on the kidney are also widespread and have only recently begun to be characterized. Increased urine volume and decreased osmolality are early changes associated with the toxin, as are increased excretions of high-and low-molecular-weight proteins. Enzymuria in vivo, reduced ion transport in vitro, and elevation of free sphinganine in renal tissue and in urine are present. An increase in serum creatinine and blood urea nitrogen and histopathologic change in renal tubules occur later and at higher doses. The morphologic change principally affects the junction of cortex and medulla and includes prominent apoptosis of epithelial cells of proximal convoluted tubules. Nephrotoxicity has been reported in several species, and in rats and rabbits, the kidney appears to be the most sensitive target organ.

Prenatal dexamethasone exposure in rats : effects of dose, age at exposure, and drug-induced hypophagia on malformations and fetal organ weights

Glucocorticoids cause stunting and cleft palate in rodents. The aim of this study is to identify fetal organs and developmental periods sensitive to stunting induced by maternal exposure to dexamethasone (DEX). DEX (0.2 or 0.4 mg/kg) or saline was given sc to pregnant CD albino rats on Gestation Days (GD) 9-14 or 14-19. On GD 20 dams were euthanized. Fetuses were weighed and examined for cleft palate. Eight fetuses/litter were randomly selected, and weights were obtained. Fetal skeletons were examined for abnormalities, and long bone measurements were taken. A dose-related decrease in maternal and fetal body weights occurred at both exposure periods. Developmental stage-specific malformations were noted in the high-dose group on GD 9-14 (cleft palate) and on GD 14-19 (wavy ribs). A dose-response in stunting occurred in all organs except cerebellum in at least one exposure period. Across both exposure periods the brain, heart, testes, and long bones were relatively resistant to DEX. Sensitive organs included thymus, spleen, adrenals, lungs, liver, and kidneys. DEX substantially reduced maternal food intake and increased water intake in some dams. Pair-feeding experiments suggested that the hypophagic effect of DEX was not responsible for the noted malformations and had little impact on growth stunting. The present findings have identified fetal organs, skeletal regions, and developmental periods sensitive to DEX exposure.

Gestational retinoic acid exposure: a sensitive period for effects on neonatal mortality and cerebellar development.

This is the first in a series of studies investigating the developmental stage-specific neurobehavioral effects of all-trans retinoic acid (RA) exposure. Because high doses of this compound are known to be lethal to the developing organism, we first conducted a dose-response study to identify RA doses that produce low enough levels of gestational/postnatal mortality to make a behavioral analysis possible in survivors. Secondarily, at doses found to produce sufficient survivors on PND 28, effects on body and regional brain weights were examined. Finally, at these doses, effects on somatic malformations were evaluated. Four separate exposure periods were analyzed: gestational days (GD) 8 through 10, 11 through 13, 14 through 16, or postnatal days (PND) 3 through 5. In the postnatal exposure period rat pups were injected (s.c.) with three consecutive daily doses of 0, 5, 10, or 20 mg/kg RA on PND 3 through 5. This postnatal exposure had no detectable effect on survival, body or brain weight. In contrast, there was a marked sensitivity to RA in the GD 11-13 group. Many pups from dams given 10 mg/kg RA PO on GD 11-13 were found dead in the cage on the day of birth, and all surviving pups died within 4 days of birth. Examination of milkbands revealed no evidence of effective suckling in these short-term survivors. The same 10 mg/kg dose at GD 8-10 or GD 14-16 produced much lower mortality and pups appeared to suckle normally. To produce adequate PND 28 survival in the GD 11-13 group, it was necessary to reduce dosage to 2.5 mg/kg daily. Even this lower exposure produced effects on PND 28 body and brain weight, significantly lowering weights of body (84% of control), whole brain (94%), and cerebellum (90%). Cerebellar weight was also depressed as percent of whole brain weight, suggesting an effect focused specifically on this region. RA at 10 or 12.5 mg/kg over GD 14-16 also reduced cerebellar weight (92% and 91% of control, respectively). Thus, exposure on GD 14-16 had effects similar to those seen at GD 11-13, but only at considerably higher doses. In contrast, exposure to RA on GD 8-10 did not affect whole body or brain weight, and of eight brain regions examined, only brain stem weight was reduced (91% of control). The GD 8-10 exposure also differed substantially from later exposures in that it was the only treatment to produce substantial malformations, including exencephaly, eye and skeletal defects. We conclude that gestational exposure to RA produces lethality and regional brain stunting that is dose and developmental stage specific, with a pronounced sensitive period on GD 11-13. In contrast, the GD 8-10 period is most sensitive for production of malformations, albeit at somewhat higher doses.

Effects of fumonisin B1 in pregnant rats. Part 2

The developmental toxicity of purified fumonisin B1 (FB1), a mycotoxin from the common corn fungus Fusarium moniliforme, was examined in Charles River rats. Pregnant rats were dosed orally on gestation days 3-16 at 0, 6.25, 12.5, 25 or 50 mg FB1/kg body weight/day. FB1 was not teratogenic at the doses tested. At 50 mg/kg, maternal toxicity (inappetence, emaciation, lethargy, death, resorption of entire litters) and foetal toxicity (increased number of late deaths, decreased foetal body weight, decreased crown rump length, increased incidence of hydrocephalus, increased incidence of skeletal anomalies) were seen. The foetal toxicity observed at 50 mg/kg may be related to maternal toxicity. Histopathological evaluation of tissues from dams of control and all treated groups revealed dose-related toxic changes in kidney and liver tissues. Acute toxic tubular nephrosis was seen in kidneys from all treated groups. Hepatocellular cytoplasmic alteration and individual cellular necrosis of the liver was seen in the two high-dose groups. Sphinganine (Sa) and sphingosine (So) were measured in day-17 adult and foetal tissues. Dose related increases in Sa/So ratios were seen in maternal liver, kidney, serum and brain, but there was no effect on foetal liver, kidney and brain. These data suggest that FB1 does not cross the placenta and further suggest that the observed foetal toxicity is a secondary response to maternal toxicity.

Developmental toxicity of 2,4,5-trichlorophenoxyacetic acid (2,4,5-T). I. Multireplicated dose-response studies in four inbred strains and one outbred stock of mice.

A large-scaled multireplicated developmental toxicity study was conducted in various strains/stocks of mice with the herbicide, 2,4,5-trichlorophenoxyacetic acid (2,4,5-T), by gavage on Gestational Days 6 through 14. The most important attributes of the study design were replicated test groups, a minimum of four dose levels per replicate, use of multiple stocks/strains of animals to obtain an estimate of the range in sensitivities due to genotype, complete pathological evaluation of maternal animals, and histopathological as well as teratological evaluation of the fetuses. Developmental toxicity was observed at doses below those producing discernible or measurable maternal toxicity. Regression and/or probit analyses were conducted to determine whether a dose-response relationship existed. Reduced fetal weight and increased incidence of cleft palate and embryolethality were the most significant prenatal effects of 2,4,5-T exposure observed in this study. Each strain/stock exhibited a dose-related decrease in fetal weight with the CD-1 mice having the steepest slope and the A/J mice having the shallowest slope. There was a striking similarity among the slopes of the dose-response curves for the various strains/stocks. The mean incidence of embryolethality in the A/J strain was significantly greater than that of the other strains or stocks. There was substantial variation among replicates within strains. The use of the replicated study design was logistically necessary due to the magnitude of the study and it also served to increase the statistical power of the study.

Retinoic acid-induced stress protein synthesis in the mouse

We have previously demonstrated that stress proteins (SPs) are synthesized in tissues in which malformations are later observed following treatment with the developmental toxicant, retinoic acid (RA), on day 11 of gestation (GD 11). These proteins were not synthesized in tissues which did not present with malformations near partuition. The purpose of the present investigation was to determine if this correlation between early SP synthesis and later malformation was present at other times during gestation. CD-1 strain mice were dosed orally with corn oil or 100 mg/kg body weight RA on GD 10 or 13. Some of the mice in each group were given an intraperitoneal injection of 3H-leucine to label embryonic protein synthesis one hour after dosing with RA. These animals were sacrificed 1.5 hour later, and embryonic protein synthesis was determined by two-dimensional gel electrophoresis followed by autoradiography. Other animals in each group were sacrificed on day 17 of gestation, and fetuses were examined for the presence of malformations. Following treatment with RA on day 10 of gestation, malformations were observed in the forelimbs, the hindlimbs and the tail; heart defects were not observed. SPs of 20-25,000 and 90,000 relative molecular mass (Mr) were synthesized in the forelimb bud and tail; in addition, a second low molecular weight (20-25,000) and a 84,000 Mr SPs were synthesized in forelimb buds. No SPs were synthesized in the hindlimb bud or the heart. Following RA treatment on GD 13, cleft palate was observed in 58% of fetuses; no other malformations were found. Proteins of 34,000, 84,000 and 90,000 Mr were synthesized in craniofacial tissue; SPs were not observed in forelimb bud, hindlimb bud, heart or tail tissues at this time. Therefore, it appears that there may be a correlation between tissue-specific SP synthesis early in organogenesis and the presence of a malformation later in gestation.

Retinoic acid acts during peri-implantational development to alter axial and brain formation

All-trans retinoid acid (RA) induces a stereotypic spectrum of stage-specific malformations in vertebrate conceptuses. The present work evaluated the anatomic and biochemical effects of exposure to RA in mouse embryos at a peri-implantational stage of development – gestational day (GD) 5. The RA receptors (RARs) βand γ, the retinoid X receptors (RXRs) α and β, and the cellular retinoid acid binding proteins (CRABPs) I and II were detected by RT-PCR in both control and treated individual GD 5 decidua/embryo complexes 3 h after RA injection, indicating the presence of the mRNAs coding for the proteins that mediate the effects of RA. In contrast, the RAR α mRNA was detected in some but not all decidua/embryo complexes, both control and treated, suggesting that its expression is initiated at approximately GD 5, while RXR γ mRNA was not detected. Examination of the control and RA-exposed embryos on GD 10, 12, or 17 showed that greater than 50% of the RA-exposed embryos were adversely affected, many with defects found only after serial histopathological examination. The malformations were localized primarily in the central nervous system, the branchial arches, and their derivatives. These terata included excessive folding and elevation of the neural tube floor plate, exencephaly (with detachment of the cephalic neuroepithelium and rarefied cephalic mesenchyme), persistent patency of Rathke’s pouch, small trigeminal ganglia, neural diverticula (chiefly from the spinal cord), and/or various optic and otic defects. Unexpectedly, limb reduplications were not apparent in RA-exposed fetuses. Those litters examined on GD 17 had a high percentage of resorbed or malformed implantations, and the few apparently normal fetuses were developmentally delayed with repect to bone ossification. These data confirm that the development of neural- and neural crest-derived structures are severely disrupted by RA exposure prior to initial specification of the neural plate and suggest that many of the proteins that regulate RA signaling are available in early vertebrate embryos at this developmental stage.

Minimal effects from developmental exposure to St. John's wort (Hypericum perforatum) in Sprague-Dawley rats.

Increasing widespread use of St. Johns Wort (SJW, Hypericum perforatum) has led to concerns about its use in pregnant women. Behavioral and physiological alterations resulting from developmental treatment were investigated in Sprague-Dawley rats exposed to diets containing 0, 180, 900, 1800 or 4500 ppm SJW beginning on gestational day 3 and ending at offspring weaning on postnatal day (PND) 21. These dietary doses span 125 times the recommended human dose. Post-weaning behavioral assessments of male and female offspring included: open field activity, acoustic startle, performance of complex and Morris water mazes, and activity in an elevated plus-maze. There were no SJW effects on maternal weight gain or duration of gestation; offspring body weights were similar to controls from PND 2 through PND 56 after which, some treated groups weighed significantly less than the controls. There were no SJW-related behavioral alterations on any measure. Whole and regional brain weights of offspring at adulthood indicated no significant effects of SJW. These results indicate that there are few neurobehavioral alterations resulting from developmental SJW treatment in rats.

Behavioral teratology and dominant lethal evaluation of nitrous oxide exposure in rats

Epidemiological studies have suggested that spontaneous abortion may be increased in medical personnel following the sort of chronic low-level exposure to the anesthetic gas nitrous oxide (N2O) seen in surgical or dental operatories. These results are supported by some, but not all, animal studies, and results are less well established at low exposure levels. Behavioral effects in exposed animal offspring have also been observed, but again not in all studies. To further examine this problem, we conducted the present experiments. Adult male or female rats were exposed to trace concentrations of N2O (0%, 0.1%, 0.5%, or 1.0% in air) for 6 h daily either throughout gestation (females) or for 9 weeks (males). Offspring from treated adults were subjected to an extensive behavioral test battery. There were no clear dose-response effects on any of eight behavioural tests for any offspring. Maternal and offspring weights were normal from conception through adulthood. Additionally, we studied effects of N2O on male fertility by mating treated males with untreated females and examining uterine contents. There was no evidence for a substantial decline in fertility of exposed males, although there was a small dose-related trend for resorptions to increase and live births to decrease with increasing paternal N2O exposure. There results suggest that there is little alteration in male or female fertility following chronic exposure to low levels of N2O. There are also no significant long-term behavioral alterations in offspring exposed gestationally to trace levels of N2O via dam or sire.