Mesomelic dysplasia Kantaputra type is associated with duplications of the HOXD locus on chromosome 2q

Kantaputra, Piranit Nik; Klopocki, Eva; Hennig, Bianca P.; Praphanphoj, Verayuth; Caignec, Cédric Le; Isidor, Bertrand; Kwee, M. L.; Shears, Deborah; Mundlos, Stefan

doi:10.1038/ejhg.2010.116

Cited by 30 publications

(41 citation statements)

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“…lation in two important ways. It may help specify gene-enhancer interactions, and restrict ectopic ''enhancer adoption'' to accidental disruption of existing topologies, for example, through chromosomal rearrangements (Kokubu et al 2003;Spitz et al 2003;Niedermaier et al 2005;Gostissa et al 2009;Kantaputra et al 2010;Marini c et al 2013). Alternatively, it may help integrate the activity of multiple regulatory elements spread along large intervals (Carvajal et al 2001;Uchikawa et al 2003;Montavon et al 2011;Li et al 2012;Sanyal et al 2012;Shen et al 2012;Delpretti et al 2013;Marini c et al 2013;Visel et al 2013) into the coherent regulatory units that have been described as regulatory archipelagos, holo-enhancers or chromatin-hubs (Palstra et al 2003;Montavon et al 2011;Marini c et al 2013).…”

Section: Characteristics Of Mammalian Regulatory Domainsmentioning

confidence: 99%

Functional and topological characteristics of mammalian regulatory domains

et al. 2014

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Long-range regulatory interactions play an important role in shaping gene-expression programs. However, the genomic features that organize these activities are still poorly characterized. We conducted a large operational analysis to chart the distribution of gene regulatory activities along the mouse genome, using hundreds of insertions of a regulatory sensor. We found that enhancers distribute their activities along broad regions and not in a gene-centric manner, defining large regulatory domains. Remarkably, these domains correlate strongly with the recently described TADs, which partition the genome into distinct self-interacting blocks. Different features, including specific repeats and CTCF-binding sites, correlate with the transition zones separating regulatory domains, and may help to further organize promiscuously distributed regulatory influences within large domains. These findings support a model of genomic organization where TADs confine regulatory activities to specific but large regulatory domains, contributing to the establishment of specific gene expression profiles.

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Section: Characteristics Of Mammalian Regulatory Domainsmentioning

confidence: 99%

Functional and topological characteristics of mammalian regulatory domains

et al. 2014

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“…In addition to deletions, other rearrangements, such as inversions, translocations, or duplications involving sequences flanking the gene cluster, are observed in human patients, which are often linked to various limb anomalies (20)(21)(22)(23) (Fig. 1A).…”

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confidence: 99%

Impact of copy number variations (CNVs) on long-range gene regulation at the HoxD locus

Montavon

Thevenet

Duboule

2012

Proc. Natl. Acad. Sci. U.S.A.

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Copy number variations are genomic structural variants that are frequently associated with human diseases. Among these copy number variations, duplications of DNA segments are often assumed to lead to dosage effects by increasing the copy number of either genes or their regulatory elements. We produced a series of large targeted duplications within a conserved gene desert upstream of the murine HoxD locus. This DNA region, syntenic to human 2q31-32, contains a range of regulatory elements required for Hoxd gene transcription, and it is often disrupted and/or reorganized in human genetic conditions collectively known as the 2q31 syndrome. Unexpectedly, one such duplication led to a transcriptional down-regulation in developing digits by impairing physical interactions between the target genes and their upstream regulatory elements, thus phenocopying the effect obtained when these enhancer sequences are deleted. These results illustrate the detrimental consequences of interrupting highly conserved regulatory landscapes and reveal a mechanism where genomic duplications lead to partial loss of function of nearby located genes.chromatin architecture | enhancer-promoter interaction

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“…The 2q31.1 duplication in our cases was larger than that reported by the previous authors. 14, 11 We do not know whether our cases' phenotype is linked with increased gene expression or dysregulation at the HOXD locus. HOXD13 overexpression might explain the cutaneous syndac- Duplication at chromosome 2q31.1-q31.2 J Ghoumid et al tyly, although further expression studies in cells from the developing autopod, rather than in lymphoblasts, would be needed to ascertain this.…”

Section: Discussionmentioning

confidence: 99%

“…Recently, two reports on a dominant mesomelic dysplasia type Kantaputra have been described in association with a 2q31.1 duplication involving the HOXD locus and other genes (MTX2, EVX2, KIAA1715), out of which some are also known to have important roles during digit development. 14,11 The patients presented severe shortening of the middle segments of the arm, relative shortening of the tibia and fibula and no ophthalmologicalassociated anomaly. As our cases had a normal full skeletal survey, their phenotype is very different and is restricted to a bilateral cutaneous syndactyly between the third and fourth finger.…”

Section: Discussionmentioning

confidence: 99%

“…10 A disconnection of 5¢ Hoxd genes from the regulator could result in a downregulation of 5¢ Hoxd genes in the distal limb (autopod) and an upregulation in the proximal limb, and it has been suggested that the 2q duplication could have the same effect, therefore, explaining the mesomelic dysplasia recently reported. 11,4 Indeed, it has been recently reported that a 1 Mb microduplication of HOXD gene cluster at 2q31.1 is associated with a dominant mesomelic dysplasia, Kantaputra type. The condition is mainly affecting the upper limbs and is very variable among affected patients within the same family.…”

Section: Introductionmentioning

confidence: 99%

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Duplication at chromosome 2q31.1-q31.2 in a family presenting syndactyly and nystagmus

Ghoumid

Andrieux²,

Sablonnière

et al. 2011

Eur J Hum Genet

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HOXD genes encode transcription factors involved in the antero-posterior patterning of the limb bud and in the specification of fingers. During the embryo development, HOXD genes are expressed, following a spatio-temporal colinearity that involves at least three regions, centrometric and telomeric to this cluster. Here, we describe a father and a daughter presenting a 3-4 hand bilateral syndactyly associated with a nystagmus. Array-comparative genomic hybridisation showed a 3.8 Mb duplication at 2q31.1-q31.2, comprising 27 genes including the entire HOXD cluster. We performed expression studies in lymphoblasts by reverse transcription-PCR and observed an HOXD13 and HOXD10 overexpression, whereas the HOXD12 expression was decreased. HOXD13 and HOXD10 overexpression, associated with a misregulation of at least HOXD12, may therefore induce the syndactyly. Deletions of the HOXD cluster and its regulatory sequences induce hand malformations and, particularly, finger anomalies. Recently, smaller duplications of the same region have been reported in association with a mesomelic dysplasia, type Kantaputra. We discuss the variable phenotypes associated with such 2q duplications. European Journal of Human Genetics (2011) 19, 1198-1201; doi:10.1038/ejhg.2011.95; published online 8 June 2011Keywords: syndactyly; HOXD cluster; 2q31.1q31.2 duplication INTRODUCTION HOXD genes encode a family of highly conserved transcription factors involved in the antero-posterior patterning of the limb bud and in the specification of fingers. 1,2 During embryo development, HOXD genes are expressed following a spatio-temporal colinearity involving at least three regulatory regions, centrometric (ELCR) and telomeric (POST and Global Central Region (GCR)-Prox) to the cluster. 3 Moreover, these genes are expressed through two waves 4 during the limb budding, and control the patterning of the stylopod and the zeugopod. 5 The width and the efficiency of the genes' expression depend on their rank in the cluster. Each gene presents a precise pattern of expression. HOXD13, the most 5¢ end located gene, is highly expressed throughout the presumptive digits, whereas HOXD10, HOXD11 and HOXD12 are restricted to presumptive digit 2-5 and are underexpressed. In man, deletions of this cluster induce hand malformations and particularly finger anomalies. 5 Deletions of the whole cluster can cause severe defects, whereas deletions removing only HOXD9-HOXD13 are responsible for a milder phenotype including fifth finger clinodactyly, variable cutaneous syndactyly of toes, hypoplastic middle phalanges of the feet and synpolydactyly. 5,6 Deletions removing GCR are deleterious too, but induce minor anomalies. 7-9 ELCR has not been localised so far. Its role is so critical that deletions would be lethal and thus there is no animal model.Animal models carrying internal duplications of part of the HOXD cluster and limb anomalies exist. 3,4 Indeed, mice with targeted disruptions of Hoxd11 and Hoxa11 genes showed marked zeugopod malformation. 10 A disconnection of 5¢ Ho...

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Mesomelic dysplasia Kantaputra type is associated with duplications of the HOXD locus on chromosome 2q

Cited by 30 publications

References 24 publications

Functional and topological characteristics of mammalian regulatory domains

Functional and topological characteristics of mammalian regulatory domains

Impact of copy number variations (CNVs) on long-range gene regulation at the HoxD locus

Duplication at chromosome 2q31.1-q31.2 in a family presenting syndactyly and nystagmus

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