Ltap, a mammalian homolog of Drosophila Strabismus/Van Gogh, is altered in the mouse neural tube mutant Loop-tail.

Neural tube defects (NTDs) such as spina bifida and anencephaly are common congenital malformations in humans (1/1,000 births) that result from failure of the neural tube to close during embryogenesis. The etiology of NTDs is complex, with both genetic and environmental contributions; the genetic component has been extensively studied with mouse models. Loop-tail (Lp) is a semidominant mutation on mouse chromosome 1 (ref. 4). In the two known Lp alleles (Lp, Lpm1Jus), heterozygous mice exhibit a characteristic looped tail, and homozygous embryos show a completely open neural tube in the hindbrain and spinal region, a condition similar to the severe craniorachischisis defect in humans. Morphological and neural patterning studies indicate a role for the Lp gene product in controlling early morphogenesis and patterning of both axial midline structures and the developing neural plate. The 0.6-cM/0.7-megabase (Mb) Lp interval is delineated proximally by D1Mit113/Apoa2/Fcer1g and distally by Fcer1a/D1Mit149/Spna1 and contains a minimum of 17 transcription units. One of these genes, Ltap, encodes a homolog of Drosophila Strabismus/Van Gogh (Stbm/Vang), a component of the frizzled/dishevelled tissue polarity pathway. Ltap is expressed broadly in the neuroectoderm throughout early neurogenesis and is altered in two independent Lp alleles, identifying this gene as a strong candidate for Lp.

Kibar Z ，Vogan KJ ，Groulx N ，Justice MJ ，Underhill DA ，Gros P ... -  《NATURE GENETICS》

Developmental basis of severe neural tube defects in the loop-tail (Lp) mutant mouse: use of microsatellite DNA markers to identify embryonic genotype.

Mouse embryos homozygous for the mutation loop-tail (Lp) develop lethal defects in which the neural tube remains open from the hindbrain to the caudal extremity, a condition that closely resembles the human malformation craniorachischisis. Heterozygotes develop tail defects and occasional spina bifida, but are generally viable. In order to study the early development of these defects, it is necessary to determine the genotype of embryos at stages prior to the first appearance of the morphological abnormalities. We used a microsatellite DNA sequence, Crp, that is closely linked to the Lp locus and which segregates polymorphic variants in matings between Lp/+ mice, thus permitting identification of embryos of Lp/Lp, Lp/+ and +/+ genotypes. We found that the severe phenotype craniorachischisis is present at 9.5 and 10.5 days of gestation only in Lp/Lp embryos in utero, whereas Lp/+ and +/+ littermates show neural tube closure throughout most of the body axis. The open neural tube phenotype also develops in Lp/Lp embryos growing in whole embryo culture. A small proportion of Lp/+ embryos were found to develop this phenotype in vitro, but only when culture conditions were suboptimal. Analysis of 8.5-day embryos revealed that the initial defect in Lp/Lp embryos is failure to initiate neural tube closure at the cervical/hindbrain boundary when the embryo has 6-7 somites. Thereafter, the neural tube remains open throughout the body axis, with the exception of the midbrain and forebrain where neural tube closure is initiated independently. Closure at the midbrain/forebrain boundary does not appear to be defective in Lp/Lp embryos. Heterozygous Lp/+ embryos initiate neural tube closure at the cervical/hindbrain boundary with a slight delay compared with +/+ littermates. Moreover, at 10.5 days of gestation, Lp/+ embryos undergo delayed closure of the posterior neuropore. Thus, Lp/+ embryos are defective in several aspects of the neurulation process. The pattern of delayed neuropore closure in Lp/+ embryos resembles that caused by the ct and Sp mutations and is likely to be responsible for the development of tail defects (i.e., looped tails) and spina bifida in Lp/+ mice. The use of microsatellite markers to determine the genotype of mutant embryos has general application: microsatellites are widespread throughout the mouse genome, so that informative sequences are likely to be available with close linkage to the majority of mutant genes. Moreover, polymorphisms can be detected using the polymerase chain reaction, making it possible to determine the genotype of very early embryos when only small amounts of material are available.

Copp AJ ，Checiu I ，Henson JN 《DEVELOPMENTAL BIOLOGY》

Physical delineation of a 700-kb region overlapping the Looptail mutation on mouse chromosome 1.

The mouse looptail (Lp) mutation is an established model for neural tube defects with homozygous Lp embryos showing an open neural tube from the caudal midbrain to the tip of the tail. Heterozygous Lp mice are characterized by a "looped-tail" and wobbly head movements. The Lp gene has been mapped to a 0.6-cM interval on mouse chromosome 1 delineated by two clusters of markers, Fcer1gamma/Usf1/D1Mit113/D1Wsu1 on the proximal side and Fcer1alpha/Spna1/D1Mit149 distally. In the present study, we have created a high-resolution physical map of the Lp genetic interval that is based on long-range restriction mapping by PFGE, fluorescence in situ hybridization analysis of interphase nuclei and extended chromatid fibers, and the assembly of a cloned contig. This contig consists of 25 independent and overlapping BAC clones and 3 YAC clones. The combined analysis indicates that the 0.6-cM genetic interval for Lp corresponds to a minimal physical interval of 700 kb that is delineated by D1Mit113 proximally (two crossovers) and Fcer1alpha distally (one crossover). The overall gene order and intergene distances for the region were determined to be D1Mit113-<150 kb-Nhlh1-250 kb-Atp1alpha2-280 kb-Fcer1alpha. Partial sequencing of BAC clones from the contig yielded 42 new STS markers for this region of mouse chromosome 1. Sequence analysis of the BAC clones and assignment of ESTs from the human transcript map to the cloned contig allowed the placement of four new transcription units within this region: Pc326, Kiaa0253, and Pea15 were positioned in the Nhlh1/Atp1alpha2 nonrecombinant interval, while Girk3 was located distal to Atp1alpha2.

Underhill DA ，Mullick A ，Groulx N ，Beatty BG ，Gros P ... -  《GENOMICS》

Identification of a new chemically induced allele (Lp(m1Jus)) at the loop-tail locus: morphology, histology, and genetic mapping.

Loop-tail (Lp) is a semidominant mutation that affects neurulation in mice. Heterozygous animals are characterized by a looped-tail appearance (pig tail) and wobbly head movements while homozygous embryos exhibit a neural tube closure defect that extends from the caudal midbrain to the tip of the tail. The Lp gene has been finely mapped to the distal part of chromosome 1, and a positional cloning strategy has been initiated to isolate the defective gene. This study represents the characterization of a new Lp allele (Lp(m1Jus)) induced by N-ethyl-N-nitrosurea mutagenesis. Lp(m1Jus)/+ mice have a looped-tail appearance, and both Lp(m1Jus)/Lp(m1Jus) homozygotes and Lp/Lp(m1Jus) compound heterozygotes fail to initiate neural tube closure along most of the embryonic axis. These data indicate that the Lp(m1Jus) allele causes a neural tube defect and overall phenotype similar to that of the original Lp allele. Segregation analysis of 90 (Lp(m1Jus)/+ x C57BL/6J)F(1) x C57BL/6J looped-tail mice with seven markers that define the Lp genetic map (D1Mit455/D1Mit146/D1Mit148/D1Mit270-1 cM-D1Mit113-0.4 cM-Lp-0.2 cM-D1Mit149-0.8 cM-D1Mit115) showed significant linkage between Lp(m1Jus) and all loci analyzed (P < 0.0001). Eight crossovers were detected with the proximal cluster of D1Mit455, D1Mit146, D1Mit148, and D1Mit270, indicating a recombination rate higher than expected in this region, and a single recombinant was encountered with the distal markers D1Mit149 and D1Mit115. Based on these phenotypic and genetic data, Lp(m1Jus) is most likely allelic to Lp, thereby representing a valuable additional tool for the positional cloning of the Lp gene and its subsequent molecular characterization.

Kibar Z ，Underhill DA ，Canonne-Hergaux F ，Gauthier S ，Justice MJ ，Gros P ... -  《GENOMICS》

Severe neural tube defects in the loop-tail mouse result from mutation of Lpp1, a novel gene involved in floor plate specification.

Neural tube defects (NTD) are clinically important congenital malformations whose molecular mechanisms are poorly understood. The loop-tail (Lp) mutant mouse provides a model for the most severe NTD, craniorachischisis, in which the brain and spinal cord remain open. During a positional cloning approach, we have identified a mutation in a novel gene, Lpp1, in the Lp mouse, providing a strong candidate for the genetic causation of craniorachischisis in LP: Lpp1 encodes a protein of 521 amino acids, with four transmembrane domains related to the Drosophila protein strabismus/van gogh (vang). The human orthologue, LPP1, shares 89% identity with the mouse gene at the nucleotide level and 99% identity at the amino acid level. Lpp1 is expressed in the ventral part of the developing neural tube, but is excluded from the floor plate where Sonic hedgehog (Shh) is expressed. Embryos lacking Shh express Lpp1 throughout the ventral neural tube, suggesting negative regulation of Lpp1 by SHH: Our findings suggest that the mutual interaction between Lpp1 and Shh may define the lateral boundary of floor plate differentiation. Loss of Lpp1 function disrupts neurulation by permitting more extensive floor plate induction by Shh, thereby inhibiting midline bending of the neural plate during initiation of neurulation.

Murdoch JN ，Doudney K ，Paternotte C ，Copp AJ ，Stanier P ... -  《HUMAN MOLECULAR GENETICS》