Expression of the Axd (axial defects) mutation in the mouse is insensitive to retinoic acid at low dose

The Axd mutation in the mouse acts by an unknown mechanism to cause lumbosacral open neural tube defects and a variety of tail anomalies. Retinoic acid (RA) plays a number of different physiological and developmental roles and has been shown to affect neurulation in mice and other species. Indeed, reports have shown that this biologically active compound (or its metabolites) at low dose can alter the incidence of neural tube defects (NTD) in curly-tail (ct), splotch (Sp), and delayed splotch (Spd) mice, strains that are genetically predisposed to such abnormalities. The aim of the present study was to determine if RA administered under similar conditions would affect the penetrance or expression of the Axd mutation or survival of Axd homozygotes. Axd/+ and +/+ dams were exposed to RA intraperitoneally (5 mg/kg) on D9 postcoitus. No difference in incidence or extent of neural tube defects or other axial anomalies was detected among embryos of Axd/+ dams given RA compared with those administered vehicle only. This finding is consistent with the diversity of gene-controlled steps required for neurulation and the differing sensitivities of specific mutants to rescue by extrinsic agents.     

Circletail, a new mouse mutant with severe neural tube defects: chromosomal localization and interaction with the loop-tail mutation.

Circletail (Crc) is a new mouse mutant that exhibits a severe form of neural tube defect, craniorachischisis, in which almost the entire neural tube fails to close. This phenotype is seen in very few other mutants, the best characterized of which is loop-tail (Ltap(Lp), referred to hereafter as Lp). We tested the possibility of allelism between Lp and Crc by intercrossing Lp/+ and Crc/+mice. A proportion of double heterozygotes (Lp/+,Crc/+) exhibit craniorachischisis, revealing failure of complementation. However, genetic analysis shows that Crc is not linked to the markers that flank the Lp locus and cannot, therefore, be an allele of Lp. A genome-wide scan has localized the Crc gene to a region of 8.8 cM on central chromosome 15. Partial penetrance of the craniorachischisis phenotype in Crc/+,Lp/+double heterozygotes suggests the existence of a third, unlinked genetic locus that influences the interaction between Crc and Lp.     

Maternal treatment with teratogen causes congenital malformations in mouse embryos

Heterozygotes for the tail-short (Ts) mutant gene in the Balb/c strain have minor skeletal defects and a short, kinky tail. If heterozygote Ts/+ mothers are mated with normal-tail +/+ males and are treated with teratogenic doses of trypan blue on the eighth day of pregnancy, the mutant F1 heterozygotes develop exencephaly, folded neural tube and spina bifida significantly more often than non-mutants. This is indicative of gene-teratogen interaction, with the Ts gene increasing the embryo's susceptibility to trypan blue-induced neural tube defects.     

All-or-none craniorachischisis in Loop-tail mutant mouse chimeras

Mouse embryos homozygous for the mutant gene Loop-tail (Lp) are characterized by craniorachischisis, an open neural tube extending from the midbrain to the tail. In the present study, experimental chimeric mice containing mixtures of genetically mutant (from Lp/+ x Lp/+ matings) and genetically normal cells were produced. Our aim was to determine whether a 'rescue,' phenotypic gradient, or intermediate expression (i.e. alternating areas of open and closed neural tube) would be observed in these chimeras. We report our analyses of Loop-tail mutant chimeras (n = 82) by gross examination, progeny testing and quantitative analysis of glucose phosphate isomerase (GPI) isozyme levels. An all-or-none craniorachischisis in Loop-tail mutant chimeras was observed. Two multicolored adult chimeras, without any gross evidence of a neural tube defect, were shown to be homozygous Loop-tail chimeras (Lp/Lp in equilibrium +/+) by progeny testing. These results indicate that the normal phenotype can be expressed in the presence of mutant cells. Conversely, six neonates with craniorachischisis were shown to be chimeras by GPI analyses. These results show that the full mutant phenotype can be expressed even when one-third to one-half of the cells are genotypically wild-type. This study did not determine which tissue is primarily responsible for the defective neurulation in this mutant, but suggests that a 'threshold' mechanism underlies the Loop-tail mutant phenotype. In some chimeras that threshold is not reached and the neural tube remains open, whereas in other chimeras the threshold is reached and the neural tube closes completely.     

Maternal methionine supplementation promotes the remediation of axial defects in Axd mouse neural tube mutants.

The Axd (axial defects) mouse model system (Essien et al., Teratology 42:183-194, '90) is characterized by a dominant mutation which causes posterior open neural tube defects (NTD) and a variety of tail anomalies (curly tails, or CT). Repeated backcrosses to BALB/cByJ mice have resulted in a 50% increase in Axd penetrance among neonates of heterozygous matings and loss of a correlation with maternal tail phenotype. Analysis of D12-D18 embryos from Axd/+ x Axd/+ matings indicates that soft tissues can superficially heal over some lesions from open NTD and that some curly tails can straighten (macroscopically) as gestation proceeds. Similarly, in embryos of Axd/+ x BALB crosses, there is remediation of approximately 33% of the tail flexion defects by birth. Numerous studies show that maternal nutritional status can affect the development of the neural tube and related axial structures. One nutrient of special interest is methionine, which is required for neurulation in cultured rat embryos (Coelho et al., J. Nutr. 119:1716, '89). Thus, the major question addressed by this study was whether supplemental methionine administered to Axd/+ dams crossed to Axd/+ males would alter the prenatal expression of the gene. When given IP (70 mg/kg) on D8 and D9, methionine resulted in a 41% reduction (from 29% to 17%) in the incidence of NTD in D 14 embryos (P less than 0.01).     

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. When the effects of RA on identified Sp/+ and +/+ embryos were compared, the only observed difference in their responses was in the degree of the delay in posterior neuropore (PNP) closure. At the end of the culture period, among the untreated control embryos, the Sp heterozygotes showed retardation of PNP closure compared to +/+ embryos. In addition, the RA treatment was found to have induced a greater delay in posterior neural tube closure in Sp/+ than in +/+ embryos. The basis for this difference in response to RA is presumed to be the retardation of PNP closure that is caused by the Sp gene in heterozygous form. The effects of the gene and the teratogen are additive and the gene carriers thus have greater mean PNP lengths at the end of culture. Since the length of the PNP is an indication of an embryo's likelihood of developing spina bifida, this provides an explanation for the observation that Sp/+ embryos are more sensitive to the spina bifida-causing effects of RA than are +/+ embryos.     

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. The notochordal area and cell number in the non-fused neuroepithelium region of Spd/Spd and Spd/+ embryos were significantly reduced compared to those of normal (+/+) embryos, which suggests an abnormality in notochord elongation. In the mesoderm, the mean cell number and mean ratio of cell number to area in the non-fused region were significantly lower in the Spd/Spd compared with +/+ embryos. The distance of exposed neuroepithelium above the mesoderm in the just-fused region was significantly lower in the Spd/Spd versus +/+ embryos, which may indicate an insufficient force exerted by the mesoderm during neural tube closure. Within the neuroepithelium, significantly more intercellular space was found in Spd/Spd than in +/+ embryos indicating disorganization. The basal lamina was poorly organized and the formation delayed around the neural tube in Spd/Spd and Spd/+ embryos. All together, these results suggest an early abnormality in interactions among the neuroepithelium, mesoderm, and notochord, which may lead to the delay or inhibition of neural tube closure observed in Spd/Spd mutants.     

Does the T gene determine the anteroposterior axis of a mouse embryo?

The t complex in the mouse is essential to embryonic development. The semidominant mutation, T, is embryonic lethal in homozygotes. In T/T embryos, proper morphogenetic movement is hindered, causing the number of mesodermal cells to be reduced. The other effect of T mutation is shortening of the tail in heterozygotes, T/+ and T/t. t is a series of recessive mutations in the t complex. A detailed examination of tail shortening indicated the T and t mutations to exert various effects, such as the derangement of the pattern of necrosis, fusion or duplication of the neural tube and gut. The most severely affected structure is the notochord. The t mutation augments the effect of T mutation in the formation of normal notochord. A gradient of phenotypic severity along anteroposterior axis of an embryo appeared to exist correlative to the dosage of the T gene. Should the products of the T gene be responsible for inducing mesoderm and the establishment of the anteroposterior axis of an embryo, diverse effects of the T mutation on embryogenesis can be explained collectively.     

Rescue of the neural tube defect of loop-tail mice by a BAC clone containing the Ltap gene

The mouse mutant loop-tail (Lp) is an accepted model for the study of neural tube defects (NTDs) in humans. Whereas Lp/+ heterozygotes show a mild tail defect (looped), homozygous Lp/Lp embryos show a very severe form of NTD, with a completely open neural tube from the hindbrain region to the caudal portion of the spinal cord (craniorachischisis). We have recently identified a positional candidate for Lp on chromosome 1, designated as Ltap. Here, we have used an in vivo complementation approach in transgenic mice to attempt to correct the looped-tail phenotype with a bacterial artificial chromosome clone (BAC280A23) that harbors a full-length copy of the Ltap gene. Genotype:phenotype correlations in Lp/+ heterozygotes carrying BAC280A23 show that this clone can rescue the looped-tail phenotype in two independent founder lines (P < 0.05 and P < 0.0001). Importantly, BAC280A23 is also observed to rescue the lethal NTD of Lp/Lp homozygotes, because several viable transgenic Lp/Lp mice could be identified and appeared normal (P < 0.05). Results from these gain-of-function transgenic animals strongly suggest that the positional candidate Ltap present in this BAC is indeed the gene that is defective in loop-tail.     

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. There is no significant increase in the resorption frequency with this treatment, indicating that the fall in the frequency of neural tube defects is not due to differential mortality of the affected fetuses. The effects of retinoic acid are time specific, with treatment at different times on day 9 having the greatest influence on either the anterior or posterior neuropore. Treatment on day 8 with the same dose of retinoic acid causes an increase in both resorptions and neural tube defects, although only the increase in the former was significant.     

Expression of a new mutation (Axd) causing axial defects in mice correlates with maternal phenotype and age

A new autosomal mutation, Axd (axial defects), is described. Axd segregates in a simple Mendelian fashion, and it is dominant with incomplete penetrance and variable expressivity. The phenotype of Axd heterozygotes ranges from a variety of tail anomalies to visibly normal tails. Approximately 12% of neonates from curly-tail (CT) F1 (Axd/+) x F1 (Axd/+) matings exhibit open neural tube defects (NTD) in the lumbosacral region and 16% have curly tails. Mean litter sizes and resorption rates comparable to wild type indicate that homozygosity for Axd is not obligately lethal. Genetic background plays a major role in Axd expression. Strains such as BALB/cByJ allow the highest penetrance of the mutation in single dose (46%), whereas, in CF-1 mice Axd is recessive. The tail phenotype of heterozygous Axd/+ dams, in part reflective of their genetic background, correlates with the incidence of NTD in F2 offspring: CT mothers produce significantly more neonates with frank NTD than normal tail mothers. At the one embryonic period examined for this study (D13/D14 post-coitus), an 85% higher incidence of total axial defects is observed than among the F2 at birth. Unchanging litter size and the relative increase in phenotypically normal offspring by birth suggest that Axd acts by delaying posterior neural tube closure. One of the most significant findings in this study is that maternal age influences the survival of Axd embryos in utero. Axd/+ dams older than 8 months yield fewer mean implants, higher resorption rates, and fewer viable embryos with axial defects than do Axd/+ dams younger than 8 months. Axd is not allelic to nor linked to the Sp (splotch) gene which also affects neurulation.     

The Developmental and Morphological Studies on the Neural and Skeletal Abnormalities in the T/btm Tailless Mice

The crosses, T /+ or T/t ^w2× btm/btm , give rise to 50% incidence of the tailless mice, development of which was investigated. No difference was seen in external appearance of the embryos at 9 days of gestation. However, some embryos showed fusion of the notochord and the neural tube at the posterior part of the body on the histological examination. The prospective tailless individuals were distinguishable from the normal littermates by the constriction of the root of the tail at 10 days of gestation. Thereafter, they showed several abnormalities such as the poor growth of the posterior part of the body, thinning of the tail and a blood blister at the tail tip or in the lumbosacral region. The abnormal embryos of 11–12 days showed severer abnormalities in the medio-dorsal area, i.e., the notochord was branched or degenerated at several places and the neural tube was distorted, duplicated or fused with the mesenchyme. All the tailless newborn young had blood blisters or red scars on the dorsal skin at the middle of the lumbosacral region.
Histologically, the spinal cord posterior to the lumbosacral level was revealed to be severely distorted or duplicated and completely devoid of the bony vertebrae, and the dorsal blood blister was found to be the meningomyelocele derived from the abnormal development of the spinal cord. Skeletal abnormalities of the tailless young were as follows. The sacral and caudal vertebrae were absent. The cervical vertebrae were mostly normal, but the thoracic and lumbar vertebrae showed several abnormalities such as fusion of the ribs, lack of the vertebral body and vertebral arch.     

Abnormalities of cells and extracellular matrix of T/T embryos

Abstract. The dominant mutation T , (Brachyury), of the T/t -complex in the mouse causes severe disorganization in neural tube, notochord, and somites in homozygotes. The use of scanning electron microscopy to investigate the relationships of cells to one another and to the extracellular matrix in the three axial organs and in the head mesenchyme reveals that cells in all areas examined are abnormal in size, shape, and arrangement in T/T embryos. Cells of T/T head mesenchyme and somites are arrayed in flat sheets of broadened cells with fewer cytoplasmic processes than those of normal littermates. The notochord is discontinuous and its surface is exposed rather than covered by a dense matrix as in the normal. Likewise the sheath of the T/T neural tube is less dense than normal. Cell size and shape are very irregular whereas normal neural tube cells are all about the same size. Extracellular matrix in T/T embryos is greatly decreased in all areas.     

Specific projections of sympathetic preganglionic neurons are not intrinsically determined by segmental origins of their cell bodies

Sympathetic preganglionic projections of the chick are segmentally specific. Neurons from the 16th cervical (C16) and the first thoracic (T1) spinal cord segments project almost exclusively in the rostral direction, while those from the fifth thoracic (T5) to the first lumbar (L1) spinal segments project almost exclusively in the caudal direction. Neurons from the intervening spinal cord segments (T2–4) project in rostral and caudal directions. There is also a tendency for rostrally located neurons in each segment to project rostrally and caudally located neurons to project caudally. To investigate whether specific projections of preganglionic neurons are intrinsically determined by segmental origins of their cell bodies, neural tube segments were transplanted or rotated in embryos at stages 19–26; these stages include times during and after preganglionic cell birth and just prior to axon outgrowth. When the T1 neural tube segment was replaced with the T5 or T7 neural tube segment, the transplanted T5 or T7 preganglionic neurons, now in the T1 position, projected rostrally. Conversely, when the T5 or T7 neural tube segment was replaced with the T1 neural tube, the transplanted T1 preganglionic neurons projected caudally. In addition, when individual T3 spinal cord segments were rotated 180° along the A-P axis, neurons which were originally in the caudal part of the segment projected rostrally, whereas neurons originally from the rostral part of the segment projected caudally. These results show that specific projections of preganglionic neurons are not intrinsically determined by segmental origins of their cell bodies. © 1998 John Wiley & Sons, Inc. J Neurobiol 35: 371–378, 1998     

Cardiac neural crest of the mouse embryo: axial level of origin, migratory pathway and cell autonomy of the splotch (Sp2H) mutant effect

A sub-population of the neural crest is known to play a crucial role in development of the cardiac outflow tract. Studies in avians have mapped the complete migratory pathways taken by 'cardiac' neural crest cells en route from the neural tube to the developing heart. A cardiac neural crest lineage is also known to exist in mammals, although detailed information on its axial level of origin and migratory pattern are lacking. We used focal cell labelling and orthotopic grafting, followed by whole embryo culture, to determine the spatio-temporal migratory pattern of cardiac neural crest in mouse embryos. Axial levels between the post-otic hindbrain and somite 4 contributed neural crest cells to the heart, with the neural tube opposite somite 2 being the most prolific source. Emigration of cardiac neural crest from the neural tube began at the 7-somite stage, with cells migrating in pathways dorsolateral to the somite, medial to the somite, and between somites. Subsequently, cardiac neural crest cells migrated through the peri-aortic mesenchyme, lateral to the pharynx, through pharyngeal arches 3, 4 and 6, and into the aortic sac. Colonisation of the outflow tract mesenchyme was detected at the 32-somite stage. Embryos homozygous for the Sp2H mutation show delayed onset of cardiac neural crest emigration, although the pathways of subsequent migration resembled wild type. The number of neural crest cells along the cardiac migratory pathway was significantly reduced in Sp2H/Sp2H embryos. To resolve current controversy over the cell autonomy of the splotch cardiac neural crest defect, we performed reciprocal grafts of premigratory neural crest between wild type and splotch embryos. Sp2H/Sp2H cells migrated normally in the +/+ environment, and +/+ cells migrated normally in the Sp2H/Sp2H environment. In contrast, retarded migration along the cardiac route occurred when either Sp2H/+ or Sp2H/Sp2H neural crest cells were grafted into the Sp2H/Sp2H environment. We conclude that the retardation of cardiac neural crest migration in splotch mutant embryos requires the genetic defect in both neural crest cells and their migratory environment.     

A role for T helper 2 cells in mediating skin fibrosis in tight-skin mice.

Mice heterozygous for the tight-skin (Tsk) mutation develop skin fibrosis. Previous studies have implicated a role for the immune system and, specifically, CD4(+) T cells, in the etiology of skin fibrosis in Tsk/+ mice. We have recently shown that the administration of neutralizing anti-IL-4 antibodies to Tsk/+ mice prevented the development of skin fibrosis in these mice. Since IL-4 is a major cytokine produced by T helper 2 (Th2) cells, we investigated the role of Th2 cells in mediating skin fibrosis in Tsk/+ mice. Previous studies have shown that the development of Th2 cells in non-Tsk mice is abrogated in mice with null mutation for either the IL-4 or the Stat6 gene. In this study we showed that the polarization of CD4(+) T cells from Tsk/+ mice toward the Th2 lineage is also dependent on a functioning IL-4 or Stat6 gene. More importantly, the development of skin fibrosis in Tsk/+ mice was abrogated by the IL4(-/-) or the Stat6(-/-) mutation. We also determined whether alteration of the TCR repertoire in Tsk/+ mice, achieved by the introduction of TCR transgenes, was able to prevent the development of skin fibrosis in Tsk/+ mice. We found that the exclusive usage of the Vbeta8.2 gene segment by T cells was sufficient to prevent skin fibrosis in Tsk/+ mice. This result suggests that the exclusive use of this Vbeta gene segment by T cells may have prevented the development of fibrosis-causing Th2 cells.     

Impact of methylenetetrahydrofolate reductase deficiency and low dietary folate on the development of neural tube defects in splotch mice

BACKGROUND: The etiology of neural tube defects (NTDs) is multifactorial, with environmental and genetic determinants. Folate supplementation prevents the majority of NTDs, and a polymorphism in methylenetetrahydrofolate reductase (MTHFR) has become recognized as a genetic risk factor. The mechanisms by which folate affects NTD development are unclear. The Splotch (Sp) mouse is a well-characterized mouse model for studying spontaneous NTDs. To assess the potential interaction between folate metabolism and the Sp mutant in NTD development, we studied mice with both Sp and Mthfr mutations, as well as the interaction between Sp and low dietary folate. METHODS: Wild-type, single Mthfr+/-mutant, single Sp/+mutant, and double mutant (Mthfr+/-, Sp/+) female mice were mated with males of the same genotype. Embryos were examined for NTDs on gestational day (GD) 13.5. To investigate the effects of folate deficiency on Sp mice, Sp/+female mice were fed a control diet (CD), a moderately folic acid-deficient diet (MFADD), or a severely folic acid-deficient diet (SFADD). They were mated with Sp/+males and the embryos were examined. RESULTS: There were no differences in the incidence or severity of NTDs in embryos from double-mutant mating pairs compared to those from single Sp mutants. Embryos from Mthfr+/-dams did not exhibit NTDs. Diets deficient in folate did not influence the incidence or severity of NTDs in embryos from Sp/+mice. CONCLUSIONS: We did not observe an interaction between Sp and Mthfr mutations, or between the Sp mutation and low dietary folate, in NTD development in Splotch mice.     

Nematospiroides dubius: susceptibility to infection and the development of resistance in hypothymic (nude) BALB/c mice.

BALB/c-nu/nu mice and their intact nu/+ littermates are equally susceptible to infection with third-stage larvae of Nematospiroides dubius. Unlike their heterozygous littermates, however, the nu/nu mice are unable to form ganulomata in the intestinal wall and become only partially resistant to rechallenge. Following two or more infections, nu/nu mice maintain a high burden of adult intestinal worms, whereas worms are lost from immune nu/+ mice. Studies in T cell-injected nu/nu mice suggest that a full complement of T cells is needed to develop maximum resistance against the infective third-stage larvae and to expel adult worms. Measurement of serum immunoglobulin levels indicate that infected nu/+ mice have very high levels of IgG1 whereas the levels of IgG2a are reduced. In infected T cell-injected nu/nu mice, IgG1 levels increase with the number of T cells injected, whereas IgG2a levels are variable but always higher than in infected nu/+ mice.     

Immunologic abnormality in NZB/NZW F1 mice. Thymus-independent occurrence of B cell abnormality and requirement for T cells in the development of autoimmune disease, as evidenced by an analysis of the athymic nude individuals

Both NZB nu/+ and NZW nu/+ mice were microbially clean by cesarean section. The (NZB x NZW)F1 hybrid (NZB/W) nu/nu mice and nu/+ littermates were then generated by mating of NZB nu/+ with NZW nu/+mice under specific pathogen-free conditions. The female NZB/W F1 nu/nu mice did not develop autoimmune kidney disease, whereas all of nu/+ female littermates mice exhibited proteinuria and died of renal failure with a 50% survival time of 35 wk. Namely, nude mice had no signs of proteinuria up to the time of their death caused by other diseases rather than glomerulonephritis, and their mean survival time was greater than 45 wk. Nude mice had also no anti-ssDNA antibody in their serum. However, splenic B cells of NZB/W nude mice exhibited hyper-responsiveness to both LPS and B151-TRF2, a T cell-derived polyclonal B cell-stimulation factor, and produced large numbers of Ig-secreting cells and anti-TNP plaque-forming cells as well as anti-ssDNA antibody comparable to the nu/+ littermate mice. Interestingly, thymus-engrafted NZB/W nude mice developed autoimmune disease exemplified by the induction of anti-ssDNA antibody and proteinuria at approximately the same time as their nu/+ littermates. These results indicate that the B cell hyper-responsiveness found in NZB/W mice is apparently determined by the T cell-independent process, and T cells are obligatorily required for the development of autoimmune disease in NZB/W mice.