William J. Scott

Targeted disruption of the murine Nhe1 locus induces ataxia, growth retardation, and seizures.

In most cells, the ubiquitously expressed Na+/H+exchanger isoform 1 (NHE1) is thought to be a primary regulator of pH homeostasis, cell volume regulation, and the proliferative response to growth factor stimulation. To study the function of NHE1 during embryogenesis when these cellular processes are very active, we targeted the Nhe1 gene by replacing the sequence encoding transmembrane domains 6 and 7 with the neomycin resistance gene. NHE activity assays on isolated acinar cells indicated that the targeted allele is functionally null. Although the absence of NHE1 is compatible with embryogenesis, Nhe1 homozygous mutants (-/-) exhibit a decreased rate of postnatal growth that is first evident at 2 wk of age. At this time, Nhe1 -/- animals also begin to exhibit ataxia and epileptic-like seizures. Approximately 67% of the -/- mutants die before weaning. Postmortem examinations frequently revealed an accumulation of a waxy particulate material inside the ears, around the eyes and chin, and on the ventral surface of the paws. Histological analysis of adult tissues revealed a thickening of the lamina propria and a slightly atrophic glandular mucosa in the stomach.

R-spondin 2 is required for normal laryngeal-tracheal, lung and limb morphogenesis.

Herein, we demonstrate that Lrp6-mediated R-spondin 2 signaling through the canonical Wnt pathway is required for normal morphogenesis of the respiratory tract and limbs. We show that the footless insertional mutation creates a severe hypomorphic R-spondin 2 allele (Rspo2Tg). The predicted protein encoded by Rspo2Tg neither bound the cell surface nor activated the canonical Wnt signaling reporter TOPFLASH. Rspo2 activation of TOPFLASH was dependent upon the second EGF-like repeat of Lrp6. Rspo2Tg/Tg mice had severe malformations of laryngeal-tracheal cartilages, limbs and palate, and lung hypoplasia consistent with sites of Rspo2 expression. Rspo2Tg/Tg lung defects were associated with reduced branching, a reduction in TOPGAL reporter activity, and reduced expression of the downstream Wnt target Irx3. Interbreeding the Rspo2Tg and Lrp6- alleles resulted in more severe defects consisting of marked lung hypoplasia and absence of tracheal-bronchial rings, laryngeal structures and all limb skeletal elements.

Sp8 is crucial for limb outgrowth and neuropore closure

In this report we describe the developmental expression and function of Sp8, a member of the Sp family of zinc finger transcription factors, and provide evidence that the legless transgene insertional mutant is a hypomorphic allele of the Sp8 gene. Sp8 is expressed during embryogenesis in the forming apical ectodermal ridge (AER), restricted regions of the central nervous system, and tail bud. Targeted deletion of the Sp8 gene gives a striking phenotype, with severe truncation of both forelimbs and hindlimbs, absent tail, as well as defects in anterior and posterior neuropore closure leading to exencephaly and spina bifida. Outgrowth of the limb depends on formation of the AER, a signaling center that forms at the limb bud apex. In Sp8 mutants, the AER precursor cells are induced and initially express multiple appropriate marker genes, but expression of these genes is not maintained and progression to a mature AER is blocked. These observations indicate that Sp8 functions downstream of Wnt3, Fgf10, and Bmpr1a in the signaling cascade that mediates AER formation.

Low teratogenicity of 13-cis-retinoic acid (isotretinoin) in the mouse corresponds to low embryo concentrations during organogenesis: comparison to the all-trans isomer

13-cis-Retinoic acid (isotretinoin) is teratogenic in man at therapeutic doses (0.5-1.5 mg/kg body wt), but only marginally teratogenic in the mouse at exceedingly high doses (greater than 100 mg/kg). On the other hand, the isomer all-trans-retinoic acid (tretinoin) is teratogenic in the mouse at dose levels which are 10 times lower than those for the 13-cis isomer. We have therefore studied whether the greatly different teratogenic potencies of these two compounds in the mouse are the result of differences in their transplacental kinetics. Following a single oral dose of 100 mg all-trans- or 13-cis-retinoic acid per kg body wt, concentrations of the parent drugs, of the C-13 isomerization products, as well as of their 4-oxo metabolites were determined in maternal plasma and embryo at two sensitive stages of organogenesis, i.e., Days 9 or 11 of gestation. All-trans-retinoic acid and its 4-oxo metabolite were transferred to the embryo to a much greater extent (embryo/maternal plasma concentration ratios, approximately 0.4) than the 13-cis-retinoic acid and its 4-oxo metabolite (embryo/maternal plasma concentration ratios, approximately 0.02). Embryo concentrations of all-trans-retinoic acid on Day 9 of gestation exceeded those on Day 11, whereas the embryo levels of 13-cis-retinoic acid were minimal at both gestational stages. The concentration of the 4-oxo metabolite of all-trans-retinoic acid was generally lower than that of the parent drug, whereas the level of the 4-oxo metabolite of the 13-cis-retinoic acid was comparable with or even higher than that of the parent compound. Concentrations of the C-13 isomerization products in maternal plasma were less than 20% of corresponding parent drug levels. However, due to the different extent of transfer of the two isomers, the concentration of all-trans-retinoic acid in the embryo exceeded that of the cis isomer even after administration of 13-cis-retinoic acid. Our results indicate that the low teratogenicity of 13-cis-retinoic acid in the mouse is the result of minimal placental transfer of this compound and of its 4-oxo metabolite, which contrast sharply with extensive placental transfer and high teratogenicity of the corresponding isomers with the all-trans configuration.

A physiologically based kinetic model of rat and mouse gestation : disposition of a weak acid

A physiologically based toxicokinetic model of gestation in the rat and mouse has been developed. The model is superimposed on the normal growth curve for nonpregnant females. It describes the entire gestation period including the period of organogenesis. The model consists of uterus, mammary tissue, maternal fat, kidney, liver, other well-perfused maternal tissues, and other poorly perfused maternal tissues, embryo/fetal tissues, and yolk sac and chorioallantoic placentas. It takes into account the growth of maternal tissues such as uterus, mammary glands, fat, and liver during pregnancy, as well as growth of the conceptus. The gestation model is based on published values of organ volumes and blood flows for the rat throughout pregnancy. It is scaled to the mouse using conventional scaling procedures. Its descriptive utility has been examined with the test chemical 5,5-dimethyloxazolidine-2,4-dione (DMO), a weak acid that is not bound measurably in plasma or tissues and is eliminated by excretion in the urine. Concentrations of DMO were monitored in maternal rat and embryo plasma and in homogenates of maternal rat muscle and whole embryo after ip administration at 9:00 AM on Day 13 of gestation. On the basis that distribution of DMO is determined solely by its pK and the pHs of body fluids, pH and excretion rate values were estimated by visual optimization of model predictions to the concentration profile. Successful prediction of concentrations of DMO in the same tissues of pregnant mice after its ip administration at 9:00 AM on Day 10 or 11 of gestation required only adjustment for pHs of mouse body fluids.

Endogenous electric current is associated with normal development of the vertebrate limb

A steady ionic current is driven out of both developing and regenerating amphibian limbs. In the developing limbs of anurans and urodeles, focal outwardly directed current (0.5–2 μA/cm2) predicts the location of mesenchyme accumulations producing the early bud. Here, we report measurements of a similar outwardly directed ionic current associated with the development of the limb bud in the mouse and chick embryo by using a noninvasive, self‐referencing electrode for the measurement of extracellular current. In both the mouse and chick embryo, flank currents were usually inwardly directed — the direction of Na+ uptake by ectoderm. Outward currents associated with the mouse limb bud ranged from 0.04–10.8 μA/cm2. Mouse limb bud and flank currents were similar to those measured in amphibian larvae, because they were reversibly collapsed and/or reversed by application of 30 μM amiloride, a Na+ channel blocker. Unlike the amphibian embryos, flank ectoderm adjacent to the mouse limb bud in the anterior/posterior axis was usually associated with outwardly directed ionic current. This raises the possibility of a different, or changing, gradient of extracellular voltage experienced by mesenchyme cells in this plane of development than that observed in other regions of the limb bud. In the chick flank caudal to the somites, a striking reversal of the inwardly directed flank currents to very large (∼100 μA/cm2) outwardly directed currents occurred three developmental stages before limb bud formation. We tested the relevance of this outwardly directed ionic current to limb formation in the chick embryo by reversing it by using an artificially applied “countercurrent” pulled through a microelectrode inserted just beneath the caudal ectoderm of the embryo. This application was performed for approximately 6 hr 2.5–3 developmental stages before hindlimb bud formation. This method resulted in abnormal limb formation by the tenth day of gestation in some embryos, whereas all control embryos developed normally. These data suggest an early physiological control of limb development.

The loss of ventral ectoderm identity correlates with the inability to form an AER in the legless hindlimb bud.

We have characterized the early stages of murine hindlimb morphogenesis in the legless (lgl)mutant and non-mutant littermates. Initially the entire ventral ectoderm expresses many genetic markers characteristic of the AER (en-1, fgf-8, msx-2, dlx-2, cd44, and cx-43). Subsequently, the expression domain of most of these genes is restricted to the thickened ectoderm of the disto-ventral limb margin prior to forming an AER. In lgl, the expression of these genes is initiated but not maintained and the disto-ventral marginal ectoderm does not thicken. In contrast, Wnt7a expression is initiated and maintained in the dorsal ectoderm. The limb mesenchyme of lgl and non-mutant embryos initially expresses lmx-1b and fgf-10 uniformly. As the ventro-distal marginal ectoderm thickens, lmx-1b is progressively dorsally restricted in non-mutants but continues to be expressed ventrally in lgl hindlimb buds. These data suggest that establishment of a dorso-ventral ectodermal interface is not sufficient for AER formation and that restriction of lmx-1b to the dorsal mesenchyme is coordinately linked to AER formation.

Effects of 2-methoxyethanol on fetal development, postnatal behavior, and embryonic intracellular pH of rats

The industrial solvent 2-methoxyethanol (2ME) is a reproductive and developmental toxicant when administered by inhalation, gavage, and IP injection. The present research established that this solvent can produce teratogenicity in rats when administered in liquid diet. Groups of 10 Sprague-Dawley rats were given various percentages of 2ME in liquid diet on gestation days 7-18. Day 20 fetuses were examined for visceral or skeletal malformations. Concentrations above 0.025% 2ME (approximately 73 mg/kg/day) produced total embryo-mortality. Cardiovascular malformations were produced at lower levels. The teratogenic no-effect level was 0.006% 2ME (16 mg/kg). In a second experiment, groups of 12 Sprague-Dawley rats were given 0, 0.006 and 0.012% of 2ME as above. Litters were culled to 8 pups, and tested for auditory and tactile startle and conditioned lick suppression, and for performance in figure-8 activity and the Cincinnati water maze on postnatal days 48-65. The high dose of 2ME produced approximately 50% mortality in the offspring and increased the number of errors in the Cincinnati maze. No other behavioral effects were observed at either dose. An interaction study was conducted to determine if simultaneous exposure to 2ME and ethanol would reduce the teratogenicity of 2ME, but no reduction was observed. The hypothesis that 2ME acts by altering embryonic intracellular pH was tested by injecting 0.33 ml/kg of 2ME into rats on gestation day 13, and determining embryonic intracellular pH at 2, 4, 8, and 24 hours thereafter. There was an increase in pH at 4 hours, but not at later time points. Another group of rats was given 2ME along with amiloride, which blocks the sodium/hydrogen antiporter. The combined 2ME-amiloride exposure produced an incidence of cardiovascular malformations in fetuses twice that of 2ME alone. These studies confirmed the structural teratogenicity of 2ME even when given in liquid diet, as it was given for the first time in the present study. At nonteratogenic doses, developmental toxicity (e.g., postnatal deaths) persisted, but only limited evidence of behavioral teratogenicity was observed. The pH data are consistent with the concept that 2ME may alter embryonic intracellular pH at critical stages of organogenesis.

Disrupting the establishment of polarizing activity by teratogen exposure

Between days 9.5 and 10, the forelimb buds of developing murine embryos progress from stage 1 which are just beginning to express shh and whose posterior mesoderm has only weak polarizing activity to stage 2 limbs with a distinguishable shh expression domain and full polarizing activity. We find that exposure on day 9.5 to teratogens that induce the loss of posterior skeletal elements disrupts the polarizing activity of the stage 2 postaxial mesoderm and polarizing activity is not subsequently restored. The ontogeny of expression of the mesodermal markers shh, ptc, bmp2, and hoxd-12 and 13, as well as the ectodermal markers wnt7a, fgf4, fgf8, cx43, and p21 occurred normally in day 9.5 teratogen-exposed limb buds. At stage 3, the treated limb apical ectodermal ridge usually possessed no detectable abnormalities, but with continued outgrowth postaxial deficiencies became evident. Recombining control, stage matched limb bud ectoderm with treated mesoderm prior to ZPA grafting restored the duplicating activity of treated ZPA tissue. We conclude that in addition to shh an early ectoderm-dependent signal is required for the establishment of the mouse ZPA and that this factor is dependent on the posterior ectoderm.

Valproate-induced limb malformations in mice associated with reduction of intracellular pH.

Valproic acid (VPA) is a commonly used antiepileptic agent that recently has been found useful in the treatment of affective disorders and prophylaxis of migraine. VPA induces congenital malformations, especially spina bifida, in the offspring of women treated with this agent during early pregnancy. The mechanism by which VPA induces abnormal development remains unknown despite many studies in experimental animals in which VPA causes malformations similar to those seen in human infants. Because of its chemical structure as a weak organic acid and its capability to induce postaxial forelimb ectrodactyly in C57BL/6 mice, we postulated that VPA acts to perturb limb morphogenesis by reducing embryonic intracellular pH (pHi). We administered VPA, 200 to 400 mg/kg, to C57BL/6 mice on day 9 of gestation. A dose-dependent incidence of postaxial forelimb ectrodactyly was observed. Forelimb bud pHi was estimated by computer-assisted image analysis from the transplacental distribution of 14C-DMO. At the highest doses, 300 and 400 mg/kg, a decrease of pHi of 0.2 to 0.3 pH units was observed uniformly throughout the limb bud 1 h after VPA treatment. None of these changes were seen after treatment with 2-en VPA, a nonteratogenic analog of VPA. Furthermore, the capability of VPA to induce postaxial forelimb ectrodactyly was greatly enhanced by coadministration of agents that inhibit pHi regulatory processes. These data support the hypothesis that VPA-induced postaxial ectrodactyly in murine fetuses can be attributed to reduction in limb bud pHi.