Genetic determinants of teratogen-induced abnormal development in mouse and rat embryos in vitro.

The response of an embryo to a teratogenic treatment is often critically dependent on its genetic makeup. However, in conventional in vivo studies of gene-teratogen interactions it may be difficult to distinguish between the effects of genes that are carried by the embryo and those that are carried by the mother. It is likewise not easy to determine whether an observed interaction is between a particular gene and the parent compound administered, or whether it is with a metabolite that has been generated by the maternal system.

DNA methyltransferase in normal and Dnmtn/Dnmtn mouse embryos.

The mouse genome experiences a large decrease in net 5-methylcytosine between fertilization and implantation; de novo methylation brings 5-methylcytosine to adult somatic cell levels between implantation and gastrulation. Very little is known of the regulation of demethylation or de novo methylation. Levels of the one known form of DNA methyltransferase are very high in early embryos, but the enzyme is localized to the cytoplasm during most of preimplantation development.

Nhlh1, a basic helix-loop-helix transcription factor, is very tightly linked to the mouse looptail (Lp) mutation.

Looptail (Lp) is a mutation on the distal portion of mouse Chromosome (Chr) 1 that affects neurulation in mouse and is phenotypically expressed by appearance of an open neural tube along the entire antero-posterior axis of the embryo (craniorachischisis). Nhlh1, a member of the basic helix-loop-helix family of transcription factors, is expressed in the developing neural tube in structures affected by the Lp mutation and has been regionally assigned to the distal part of mouse Chr 1. Using a large panel of looptail animals from an (Lp/+ x SWR/J)F1 x SWR/J segregating backcross progeny, we have determined that Nhlh1 maps very close to Lp, with no recombinant detected in 500 informative animals tested; both map within a 0.

High-resolution linkage map in the vicinity of the Lp locus.

Looptail (Lp) is a mutation that profoundly affects neurulation in mouse and is characterized by craniorachischisis, an open neural tube extending from the midbrain to the tail in embryos homozygous for the mutation. Lp maps to the distal portion of mouse chromosome 1, and as part of a positional cloning approach, we have generated a high-resolution linkage map of the Lp chromosomal region. For this, we have carried out extensive segregation analysis in a total of 706 backcross mice informative for Lp and derived from two crosses, (Lp/+ x SJL/J)F1 x SJL/J and (Lp/+ x SWR/J) F1 x SWR/J.

Early sialylation on N-CAM in splotch neural tube defect mouse embryos.

The splotch (Sp) mutant mouse is a model for neural tube defects and Waardenburg syndrome type I. The neural tube defects that arise in Sp, which include spina bifida and exencephaly, are thought to be caused by a change in the timing of the cellular events which are taking place during neurulation. Cell adhesion molecules are strongly implicated in a variety of cell-cell interactions throughout development, thus the neural cell adhesion molecule (N-CAM) may play a role in neural tube formation and closure.

The splotch-delayed (Spd) mouse mutant carries a point mutation within the paired box of the Pax-3 gene.

The splotch (Sp) mouse mutant displays defects in neural crest cell migration and neural tube closure and serves as a model for the study of spina bifida, exencephaly, and Waardenburg syndrome type I in humans. Recently, we have described alterations in the Pax-3 gene for the radiation-induced Spr and Sp2H alleles and for the original, spontaneously arising Sp allele. Another allele that arose spontaneously at the Sp locus, termed splotch-delayed (Spd), shows a less severe phenotype than the other Sp alleles, including the delayed death of homozygous embryos.

A mutation within intron 3 of the Pax-3 gene produces aberrantly spliced mRNA transcripts in the splotch (Sp) mouse mutant.

The splotch (Sp) mouse mutant displays defects in neural tube closure in the form of exencephaly and spina bifida. Recently, mutations in the Pax-3 gene have been described in the radiation-induced Spr and Sp2H alleles. This led us to examine the integrity of the Pax-3 gene and its cellular mRNA transcript in the original, spontaneously arising Sp allele.

Morphometric analysis of heterozygote dancer mice predisposed to 6-aminonicotinamide-induced cleft lip.

Mid-facial development is an extremely complex process involving coordinated events and precise timing. Cleft lip (CL) may result from the failed fusion of the lateral and medial nasal processes in the developing embryo. It has been postulated that spontaneous CL in the A/J strain of mice may be due to a predisposing face shape (Trasler, '68).

Segregation analysis reveals tight genetic linkage between the spontaneously arising neural tube defect gene splotch (Sp) and Pax-3 in an intraspecific mouse backcross.

Concurrent research has recently characterized Sp2H, a radiation induced mutation at the splotch (Sp) locus, and found alterations in the murine paired box gene, Pax-3, in homozygous Sp2H DNA. It was proposed that Sp and Pax-3 are the same gene. This report presents additional genetic evidence in support of this finding through linkage studies.

N-CAM alterations in splotch neural tube defect mouse embryos.

The splotch (Sp) mouse is a model for both neurulation defects and defects in neural crest cell (NCC) derivatives. Since neurulation and NCC emigration from the neural tube occur at similar times in development, we suggest that these two events share a mechanism that, if disrupted, leads to malformations in both developmental pathways. Previous studies have shown that the underlying defect in these mutants may involve a mechanism that alters cellular organization and communication.

Immunohistochemical localization of chondroitin and heparan sulfate proteoglycans in pre-spina bifida splotch mouse embryos.

The splotch (Sp) mutation on mouse chromosome I is a genetic model for the neural tube defects spina bifida and exencephaly. Embryos carrying Sp or its allele splotch-delayed (Spd), have been shown to have delays in neural tube closure, and neural crest cell emigration, as well as a reduction in extracellular space around the neural tube. Pre-spina bifida Sp and Spd embryos have abnormalities of notochord, mesoderm and neuroepithelial development.

Abnormalities of neural tube formation in pre-spina bifida splotch-delayed mouse embryos.

The splotch-delayed homozygous mutant (Spd/Spd) develops spina bifida with or without exencephaly, has spinal ganglia abnormalities, and delays in posterior neuropore closure and neural crest cell emigration. The heterozygote (Spd/+) has a pigmentation defect, and occasionally neural tube defects. To investigate the underlying mechanisms, we compared the neuroepithelium in the posterior neuropore region of cytogenetically identified 15-18 somite pair Spd/Spd, Spd/+, and +/+ mouse embryos by transmission electron and light microscopy.

Delayed neural crest cell emigration from Sp and Spd mouse neural tube explants.

Splotch (Sp) and splotch-delayed (Spd) are allelic mutations on chromosome 1 of the mouse. Embryos homozygous for either allele have neural tube defects (NTDs) and deficiencies in neural crest cell (NCC) derived structures. The fact that Spd mouse mutants sometimes have deficiencies in NCC derivatives in the absence of an NTD led to the hypothesis that neurulation and the release of NCCs may depend on a regulatory event that is common to both processes.

Spinal ganglia reduction in the splotch-delayed mouse neural tube defect mutant.

Splotch and splotch-delayed mutants have anomalies in certain neural crest cell derivatives as well as neural tube defects. A genetic marker was used to identify mutant, heterozygote, and wild-type embryos within a litter, which enabled us to make intergenotypic comparisons. Histological studies of the lumbosacral region of day 15 and day 16 embryos indicated that the splotch-delayed mutant had similar but less severe defects in spinal ganglion development than those reported for splotch (Auerbach: Journal of Experimental Zoology 127:305-329, 1954).

Interaction between the splotch mutation and retinoic acid in mouse neural tube defects in vitro.

The interaction between the splotch gene (Sp) and all-trans retinoic acid (RA) was investigated using cytogenetically marked Sp/+ and +/+ mouse embryos cultured in the presence of RA. Retinoic acid retarded the development of and had a teratogenic effect on mouse embryos in culture. In particular, RA had seemingly opposite effects on the posterior neural tube, inducing abnormally early fusion in some embryos and causing a dose-dependent delay in others.

Histological comparison of the effects of the splotch gene and retinoic acid on the closure of the mouse neural tube.

The splotch gene (Sp) and all-trans retinoic acid (RA) interact to cause spina bifida in mouse embryos. To investigate the mechanisms of action of the two, the spinal regions of Sp homozygotes, RA-treated wild-type, and control wild-type embryos were examined histologically by light microscopy on day 9 of gestation. The mean numbers of cells per section in the neural tube, mesoderm, and notochord were determined, along with the percentages of mitotic and pyknotic nuclei and the numbers of migrating neural crest cells.

Retinoic acid-induced selective mortality of splotch-delayed mouse neural tube defect mutants.

The allelic loci splotch (Sp) and splotch-delayed (Spd) cause neural tube defects (NTDs) in mice homozygous for either of these genes. The polymorphic enzyme isocitrate dehydrogenase (Idh-1) in conjunction with a recombination suppressor was used as a genetic marker to identify embryos homozygous for these alleles. A split dose of all-trans retinoic acid (RA) totalling 5.

A chromosome marker for the early detection of mouse embryos carrying the neural tube defect mutation splotch.

A major problem in the study of neural tube defects caused by the splotch (Sp) gene in the mouse has been the identification of gene carriers or potentially affected embryos at an early stage of development, since the gene's effects become visible only late in gestation or after birth. To aid in the identification of Sp carriers, we have developed a technique using a Robertsonian translocation as a marker for this gene. The accuracy of identification is reduced by crossing-over between the Sp locus and the centromere but, because of crossover suppression in the particular cross used, there was only 23.

Reduction in the frequency of neural tube defects in splotch mice by retinoic acid.

In the homozygous state, the splotch (Sp) gene causes spina bifida and exencephaly. Close to 25% of the embryos from Sp/ + X Sp/+ litters are affected. The frequency of these defects is significantly reduced by maternal treatment with 5 mg/kg retinoic acid on day 9 of gestation.

Left cleft lip predominance and genetic similarities of L line and CL/Fr strain mice.

Newborn litters of the L line and CL/Fr and A/JFr strains were examined, and sex, frequency and type of cleft lip (left, right or bilateral) were recorded. Embryos and fetuses from crosses between these strains and line were collected on days 13 to 16 of gestation, and frequency and type of cleft lip recorded. Overall cleft frequencies in L X CL/Fr, CL/Fr X L, and CL/Fr X A/JFr crosses (female stated first) were similar, while in A/JFr X L (10.

Gene-teratogen interaction and its morphological basis in retinoic acid-induced mouse spina bifida.

Homozygotes for the splotch (Sp) mutation in the mouse have spina bifida, whereas the heterozygotes have a white belly spot but otherwise appear normal. Spina bifida can be induced by maternal treatment with retinoic acid. Female SWV strain mice were treated intraperitoneally with retinoic acid suspended in peanut oil 8 days/12 hours after they had been mated to either Sp/+ or +/+ males.

Increased susceptibility to 6-aminonicotinamide-induced cleft lip of heterozygote Dancer mice.

Dancer heterozygotes (Dc/+) very rarely have cleft lip and show a dancing behaviour due to inner ear defects while homozygotes (Dc/Dc) have cleft lip. Males of the two genotypes Dc/+ and +/+ were mated to C3H strain and R stock females and Dc/+ males to Dc/+ females. On day 10/8 of gestation females were treated with 6-aminonicotinamide (6AN) at either 19 mg/kg or 28.

Early morphological abnormalities in splotch mouse embryos and predisposition to gene- and retinoic acid-induced neural tube defects.

Genetic and environmental factors contribute to an individual's neural tube defect liability. In the mouse, the gene mutation Splotch (Sp) causes a pigmentation defect in heterozygotes while homozygotes have spina bifida +/- exencephaly. Splotch homozygotes, heterozygotes, and wild-type embryos were examined for somite number, anterior neuropore closure, and posterior neuropore length.