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Gli3 Genes (gli3 + gene)

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Life Sciences100%

Selected Abstracts

Birth defects caused by mutations in human GLI3 and mouse Gli3 genes

CONGENITAL ANOMALIES, Issue 1 2010
Ichiro Naruse
ABSTRACT GLI3 is the gene responsible for Greig cephalopolysyndactyly syndrome (GCPS), Pallister,Hall syndrome (PHS) and Postaxial polydactyly type-A (PAP-A). Genetic polydactyly mice such as Pdn/Pdn (Polydactyly Nagoya), XtH/XtH (Extra toes) and XtJ/XtJ (Extra toes Jackson) are the mouse homolog of GCPS, and Gli3tmlUrtt/Gli3tmlUrt is produced as the mouse homolog of PHS. In the present review, relationships between mutation points of GLI3 and Gli3, and resulting phenotypes in humans and mice are described. It has been confirmed that mutation in the upstream or within the zinc finger domain of the GLI3 gene induces GCPS; that in the post-zinc finger region including the protease cleavage site induces PHS; and that in the downstream of the GLI3 gene induces PAP-A. A mimicking phenomenon was observed in the mouse homolog. Therefore, human GLI3 and mouse Gli3 genes have a common structure, and it is suggested here that mutations in the same functional regions produce similar phenotypes in human and mice. The most important issue might be that GCPS and PHS exhibit an autosomal dominant trait, but mouse homologs, such as Pdn/Pdn, XtH/XtH, XtJ/XtJ and Gli3tmlUrt/Gli3tmlUrt, are autosomal recessive traits in the manifestation of similar phenotypes to human diseases. It is discussed here how the reduced amounts of the GLI3 protein, or truncated mutant GLI3 protein, disrupt development of the limbs, head and face. [source]

Phenotypic differences in the brains and limbs of mutant mice caused by differences of Gli3 gene expression levels

CONGENITAL ANOMALIES, Issue 2 2001
Ichiro Naruse
ABSTRACT, The genetic polydactyly/arhinencephaly mouse, Pdn/Pdn, exhibits severe polydactyly both in the fore-and hindlimbs, agenesis of the olfactory bulbs, corpus callosum, anterior commissure, and hydrocephalus. A candidate gene for the Pdn mouse has been speculated to be Gli3, because Pdn has been considered to be an allele of Xt whose responsible gene has been clarified to be Gli3. Recently, it has been cleared that retro-transposons are inserted into nitron 3, upstream of zinc finger domain, of the Gli3 gene in the Pdn mouse, resulting to the severe suppression of Gli3 gene expression in Pdn/Pdn embryos. Meanwhile, XtJ/XtJ mice exhibit more severe polydactyly than that of Pdn/Pdn. Arhinencephaly and microholoprosencephaly including agenesis of the olfactory bulbs, corpus callosum, anterior commissure, hippocampal commissure, habenular commissure, and posterior commissure, and moreover, the cerebral cortical plates and hippocampus are not formed in the XtJ/XtJ mice. The XtJ/XtJ mouse has a large deletion in Gli3 structural gene and shows null expression. From these corroborations, we speculated that the differences in the Gli3 gene expression levels resulted in the phenotypic differences between the Pdn/Pdn and XtJ/XtJ mice. [source]

High-resolution mapping of the Gli3 deletion in the mouse extra-toesH mutant

GENESIS: THE JOURNAL OF GENETICS AND DEVELOPMENT, Issue 3 2007
Matthieu Genestine
Abstract Extra-toes is a semidominant mutation that affects the Gli3 gene and provokes limb and brain abnormalities. Among the different alleles of this mutation, XtH is due to a deletion that has not yet been fully characterized. Using a PCR-based strategy, we undertook a high-resolution mapping of this deletion and confirmed that XtH is a null allele of Gli3. We further designed a PCR test to identify unequivocally heterozygous and homozygous embryos from their wild-type littermates. Despite the length of the XtH deletion, available data on the mouse genome indicate that no genes other than Gli3 are deleted in XtH mutants. Thus, the XtH mutation can be used as a model for studying the effects that absence of Gli3 function has during development. genesis 45:107,112, 2007. © 2007 Wiley-Liss, Inc. [source]

Birth defects caused by mutations in human GLI3 and mouse Gli3 genes

CONGENITAL ANOMALIES, Issue 1 2010
Ichiro Naruse
ABSTRACT GLI3 is the gene responsible for Greig cephalopolysyndactyly syndrome (GCPS), Pallister,Hall syndrome (PHS) and Postaxial polydactyly type-A (PAP-A). Genetic polydactyly mice such as Pdn/Pdn (Polydactyly Nagoya), XtH/XtH (Extra toes) and XtJ/XtJ (Extra toes Jackson) are the mouse homolog of GCPS, and Gli3tmlUrtt/Gli3tmlUrt is produced as the mouse homolog of PHS. In the present review, relationships between mutation points of GLI3 and Gli3, and resulting phenotypes in humans and mice are described. It has been confirmed that mutation in the upstream or within the zinc finger domain of the GLI3 gene induces GCPS; that in the post-zinc finger region including the protease cleavage site induces PHS; and that in the downstream of the GLI3 gene induces PAP-A. A mimicking phenomenon was observed in the mouse homolog. Therefore, human GLI3 and mouse Gli3 genes have a common structure, and it is suggested here that mutations in the same functional regions produce similar phenotypes in human and mice. The most important issue might be that GCPS and PHS exhibit an autosomal dominant trait, but mouse homologs, such as Pdn/Pdn, XtH/XtH, XtJ/XtJ and Gli3tmlUrt/Gli3tmlUrt, are autosomal recessive traits in the manifestation of similar phenotypes to human diseases. It is discussed here how the reduced amounts of the GLI3 protein, or truncated mutant GLI3 protein, disrupt development of the limbs, head and face. [source]

Essential roles of Gli3 and sonic hedgehog in pattern formation and developmental anomalies caused by their dysfunction

CONGENITAL ANOMALIES, Issue 3 2006
Jun Motoyama
ABSTRACT Pattern formation along the body axis directs the proportion of different types of cells required for functional tissue structures. The secreted protein sonic hedgehog (Shh) and zinc finger transcription factor Gli3 are key players in pattern formation during brain and limb development; the antagonistic action of Shh towards Gli3 may be crucial for pattern formation. Recent findings from Shh/Gli3 double homozygous mutants suggest that a balance of both activities is required for the production of the normal proportion of different cell types during organogenesis. This conclusion contrasts with the alternative hypothesis that a Shh gradient directs the specification of several different cell types. The observations reviewed here offer a new perspective on understanding the pathogenesis of human birth defects caused by mutations of the Shh and Gli3 genes. [source]