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Limb Phenotypes (limb + phenotype)

Distribution by Scientific Domains
Life Sciences100%

Selected Abstracts

A hypermorphic mouse Gli3 allele results in a polydactylous limb phenotype

DEVELOPMENTAL DYNAMICS, Issue 3 2007
Chengbing Wang
Abstract Gli3 protein processing to generate the Gli3 repressor is mediated by proteasome and inhibited by Hedgehog signaling. The Gli3 repressor concentration is graded along the anterior,posterior axis of the developing vertebrate limb due to posteriorly restricted Sonic hedgehog expression. In this study, we created a small deletion at the Gli3 locus (Gli3,68), which causes a half reduction in the Gli3 repressor levels and a slightly increased activity of full-length mutant protein in the limb. Mice homozygous for Gli3,68 develop one to two extra partial digits in the anterior of the limb, while mice carrying one copy of the Gli3,68 allele die soon after birth and display seven digits. These phenotypes are more severe than those found in mice lacking one wild-type Gli3 allele. The expression of dHand, Hoxd12, and Hoxd13 is anteriorly expanded in the limb, even though no up-regulation of Gli1 and Ptc RNA expression is detected. These findings suggest that a decrease in the Gli3 repressor level in combination with an increase in Gli3 full-length activity results in more severe digit patterning abnormalities than those caused by a loss of one wild-type Gli3 allele. Developmental Dynamics 236:769,776, 2007. © 2007 Wiley-Liss, Inc. [source]

Loss of the Tg737 protein results in skeletal patterning defects

DEVELOPMENTAL DYNAMICS, Issue 1 2003
Qihong Zhang
Abstract Tg737 mutant mice exhibit pathologic conditions in numerous tissues along with skeletal patterning defects. Herein, we characterize the skeletal pathologic conditions and confirm a role for Tg737 in skeletal patterning through transgenic rescue. Analyses were conducted in both the hypomorphic Tg737orpk allele that results in duplication of digit one and in the null Tg737,2-3,Gal allele that is an embryonic lethal mutation exhibiting eight digits per limb. In early limb buds, Tg737 expression is detected throughout the mesenchyme becoming concentrated in precartilage condensations at later stages. In situ analyses indicate that the Tg737orpk mutant limb defects are not associated with changes in expression of Shh, Ihh, HoxD11,13, Patched, BMPs, or Glis. Likewise, in Tg737,2-3,Gal mutant embryos, there was no change in Shh expression. However, in both alleles, Fgf4 was ectopically expressed on the anterior apical ectodermal ridge. Collectively, the data argue for a dosage effect of Tg737 on the limb phenotypes and that the polydactyly is independent of Shh misexpression. Developmental Dynamics 227:78,90, 2003. © 2003 Wiley-Liss, Inc. [source]

SALL1 truncated protein expression in Townes-Brocks syndrome leads to ectopic expression of downstream genes,,

HUMAN MUTATION, Issue 9 2008
Susan M. Kiefer
Abstract Mutations in SALL1 lead to the dominant multiorgan congenital anomalies that define Townes-Brocks syndrome (TBS). The majority of these mutations result in premature termination codons that would be predicted to trigger nonsense-mediated decay (NMD) of mutant mRNA and cause haploinsufficiency. Our previous studies using a gene targeted mouse model (Sall1- ,Zn) suggested that TBS phenotypes are due to expression of a truncated mutant protein, not haploinsufficiency. In this report, we strengthen this hypothesis by showing that expression of the mutant protein alone in transgenic mice is sufficient to cause limb phenotypes that are characteristic of TBS patients. We prove that the same pathogenetic mechanism elucidated in mice is occurring in humans by demonstrating that truncated SALL1 protein is expressed in cells derived from a TBS patient. TBS mutant protein is capable of dominant negative activity that results in ectopic activation of two downstream genes, Nppa and Shox2, in the developing heart and limb. We propose a model for the pathogenesis of TBS in which truncated Sall1 protein causes derepression of Sall-responsive target genes. Hum Mutat 0,1,8, 2008. Published 2008 Wiley-Liss, Inc. [source]

A twisted hand: bHLH protein phosphorylation and dimerization regulate limb development

BIOESSAYS, Issue 11 2005
Juanliang Cai
Saethre-Chotzen syndrome (SCS), a human autosomal dominant condition with limb defects and craniosynostosis, is caused by haploinsufficiency of TWIST1, a basic helix,loop,helix (bHLH) transcription factor. Until recently, the molecular pathogenesis of the limb defects in SCS has not been well understood. Now, Firulli et al.1 show in mouse and chick that ectopic expression of a related bHLH protein, Hand2, results in phenocopies of the limb defects caused by Twist1 loss-of-function mutations. These two proteins interact in a dosage-dependent antagonistic manner, and both can be regulated through phosphorylation at conserved helix I amino acid residues. These findings provide an important link between the misregulation of Twist1 dimerization and the limb phenotypes observed in SCS. BioEssays 27:1102,1106, 2005. © 2005 Wiley Periodicals, Inc. [source]