Microphthalmia with linear skin defects (MLS) syndrome: Clinical, cytogenetic, and molecular characterization of 11 cases

Morleo, Manuela; Pramparo, Tiziano; Perone, Lucia; Gregato, Giuliana; Caignec, Cédric Le; Mueller, Robert F.; Ogata, Tsutomu; Raas‐Rothschild, Annick; Blois, Marie Christine De; Wilson, Louise C.; Zaidman, Gerald W.; Zuffardi, Orsetta; Ballabio, Andrea; Franco, Brunella

doi:10.1002/ajmg.a.30864

Cited by 37 publications

(50 citation statements)

References 49 publications

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“…Additional features include agenesis of the corpus callosum, sclerocornea, chorioretinal abnormalities, infantile seizures, congenital heart defects, and mental retardation. In the majority of cases, patients carry deletions or unbalanced translocations involving the Xp22.3 region resulting in segmental monosomy of this chromosome 18. Although most patients display the classical phenotype of MLS, a high phenotypic variability, not correlated to the extent of the deleted region, has been reported.…”

Section: The Influence Of Non-random X Inactivation On Phenotypic Varmentioning

confidence: 99%

Dosage compensation of the mammalian X chromosome influences the phenotypic variability of X-linked dominant male-lethal disorders

Morleo

Franco

2008

Journal of Medical Genetics

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In mammals females inactivate one of the two X chromosomes during early development to achieve an equal gene dosage between sexes. This process, named X chromosome inactivation (XCI), usually occurs randomly. However, in a few instances, non-random XCI may take place, thus modulating the phenotype observed in female patients carrying mutations in X-linked genes. Different aspects related to dosage compensation contribute to explain the influences of XCI on the phenotypic variability observed in female patients. The study of two X-linked dominant male-lethal disorders, such as the microphthalmia with linear skin lesions (MLS) syndrome and the oral-facial-digital type I (OFDI) syndrome, offers the opportunity to discuss this intriguing topic. In addition, recent data on the characterisation of a murine model for OFDI provide the opportunity to discuss how differences in the XCI between Homo sapiens and Mus musculus can justify the discrepancies between the phenotypes observed in OFDI patients and the corresponding murine model.

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Section: The Influence Of Non-random X Inactivation On Phenotypic Varmentioning

confidence: 99%

Dosage compensation of the mammalian X chromosome influences the phenotypic variability of X-linked dominant male-lethal disorders

Morleo

Franco

2008

Journal of Medical Genetics

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“…Additional features include sclerocornea, corneal opacities, agenesis of the corpus callosum, ventriculomegaly, microcephaly, mental retardation, infantile seizures and, more rarely, cardiac anomalies. MLS is predominantly observed in patients with deletions and unbalanced translocations that involve the Xp22.3 region and that result in monosomy for this region [24]. Aicardi and Goltz syndromes share some similarities with MLS syndrome, and a few reports have described MLS patients with Xp22 deletions as possibly having Aicardi or Goltz syndromes.…”

Section: Microphthalmia With Linear Skin-defects Syndromementioning

confidence: 99%

X-inactivation and human disease: X-linked dominant male-lethal disorders

Franco

Ballabio

2006

Current Opinion in Genetics & Development

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“…Cases of anophthalmia and microphthalmia have been associated with homozygous and heterozygous mutations in genes at the core of forebrain regulatory networks (Beccari et al, 2013), such as the transcription factors (TFs) SOX2 (Fantes et al, 2003), OTX2 (Ragge et al, 2005), PAX6 (Glaser et al, 1994), VSX2 (CHX10) (Ferda Percin et al, 2000), RAX (Voronina et al, 2004), FOXE3 (Reis et al, 2010) and perhaps SIX6 (Gallardo et al, 2004); in key components of cell to cell communication, including SHH (Schimmenti et al, 2003) and BMP4 (Reis et al, 2011); or in genes involved in retinal progenitor proliferation and survival such as STRA6 (Pasutto et al, 2007;White et al, 2008), BCOR (Ng et al, 2004), HCCS (Indrieri et al, 2013;Morleo et al, 2005) and SMOC1 (Abouzeid et al, 2011;Okada et al, 2011). Yet, only a minor proportion of patients receive an accurate molecular diagnosis of the pathogenesis of their ocular malformation Williamson and FitzPatrick, 2014), indicating that additional causative genes need to be identified.…”

Section: Introductionmentioning

confidence: 99%

Meis1 coordinates a network of genes implicated in eye development and microphthalmia

et al. 2015

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Microphthalmos is a rare congenital anomaly characterized by reduced eye size and visual deficits of variable degree. Sporadic and hereditary microphthalmos have been associated with heterozygous mutations in genes fundamental for eye development. Yet, many cases are idiopathic or await the identification of molecular causes. Here we show that haploinsufficiency of Meis1, which encodes a transcription factor with evolutionarily conserved expression in the embryonic trunk, brain and sensory organs, including the eye, causes microphthalmic traits and visual impairment in adult mice. By combining analysis of Meis1 loss-offunction and conditional Meis1 functional rescue with ChIP-seq and RNA-seq approaches we show that, in contrast to its preferential association with Hox-Pbx BSs in the trunk, Meis1 binds to Hox/Pbxindependent sites during optic cup development. In the eye primordium, Meis1 coordinates, in a dose-dependent manner, retinal proliferation and differentiation by regulating genes responsible for human microphthalmia and components of the Notch signaling pathway. In addition, Meis1 is required for eye patterning by controlling a set of eye territory-specific transcription factors, so that in Meis1 −/− embryos boundaries among the different eye territories are shifted or blurred. We propose that Meis1 is at the core of a genetic network implicated in eye patterning/microphthalmia, and represents an additional candidate for syndromic cases of these ocular malformations.

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Microphthalmia with linear skin defects (MLS) syndrome: Clinical, cytogenetic, and molecular characterization of 11 cases

Cited by 37 publications

References 49 publications

Dosage compensation of the mammalian X chromosome influences the phenotypic variability of X-linked dominant male-lethal disorders

Dosage compensation of the mammalian X chromosome influences the phenotypic variability of X-linked dominant male-lethal disorders

X-inactivation and human disease: X-linked dominant male-lethal disorders

Meis1 coordinates a network of genes implicated in eye development and microphthalmia

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