<i>HoxD</i> cluster scanning deletions identify multiple defects leading to paralysis in the mouse mutant <i>Ironside</i>

Tarchini, Basile; Huynh, Thi Hanh Nguyen; Cox, Greg; Duboule, Denis

doi:10.1101/gad.351105

Cited by 48 publications

(45 citation statements)

References 47 publications

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“…Variability near or within the histone genes might lead to the alteration of epigenetic marks or histone expression levels, thus compromising embryo survival. Another relevant category was constituted by genes that encode transcription factors that are deeply involved in embryogenesis such as PAX5 that is essential for the genesis of the midbrain and cerebellum (Pfeffer et al 2000), HOXD genes (HOXD1, HOXD3, HOXD4, HOXD8, HOXD9, HOXD12, and HOXD13) that are important for the innervation of the hindlimbs (Tarchini et al 2005) and digit development (Delpretti et al 2012), and DMRT1 and DMRT2 that are involved in somitogenesis (DMRT2) and sexual determination (Bellefroid et al 2013). Notably, the loss of function of DMRT1 has been recently reported as a potential cause for human spermatogenic failure (Lopes et al 2013).…”

Section: Resultsmentioning

confidence: 99%

A Flexible Bayesian Model for Testing for Transmission Ratio Distortion

et al. 2014

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Current statistical approaches to investigate the nature and magnitude of transmission ratio distortion (TRD) are scarce and restricted to the most common experimental designs such as F 2 populations and backcrosses. In this article, we describe a new Bayesian approach to check TRD within a given biallelic genetic marker in a diploid species, providing a highly flexible framework that can accommodate any kind of population structure. This model relies on the genotype of each offspring and thus integrates all available information from either the parents' genotypes or population-specific allele frequencies and yields TRD estimates that can be corroborated by the calculation of a Bayes factor (BF). This approach has been evaluated on simulated data sets with appealing statistical performance. As a proof of concept, we have also tested TRD in a porcine population with five half-sib families and 352 offspring. All boars and piglets were genotyped with the Porcine SNP60 BeadChip, whereas genotypes from the sows were not available. The SNP-by-SNP screening of the pig genome revealed 84 SNPs with decisive evidences of TRD (BF . 100) after accounting for multiple testing. Many of these regions contained genes related to biological processes (e.g., nucleosome assembly and co-organization, DNA conformation and packaging, and DNA complex assembly) that are critically associated with embryonic viability. The implementation of this method, which overcomes many of the limitations of previous approaches, should contribute to fostering research on TRD in both model and nonmodel organisms.

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Section: Resultsmentioning

confidence: 99%

A Flexible Bayesian Model for Testing for Transmission Ratio Distortion

et al. 2014

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“…Alternatively, in those animals where the elaboration of more-caudal segments is delayed in time, a mere delay in 'posterior' Hox gene activation might be sufficient to restrict their expression posteriorly, thus preventing their deleterious effects (the 'Hox clock') (Duboule, 1994b). The importance of posterior prevalence has been verified in many instances; for example, in the proper determination of pools of motoneurons (Tarchini et al, 2005) and in the early sequential migration of epiblast cells during chick gastrulation (Iimura and Pourquié, 2006).…”

Section: To Give Time To Timementioning

confidence: 99%

The rise and fall of Hox gene clusters

2007

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Although all bilaterian animals have a related set of Hox genes, the genomic organization of this gene complement comes in different flavors. In some unrelated species, Hox genes are clustered; in others, they are not. This indicates that the bilaterian ancestor had a clustered Hox gene family and that, subsequently, this genomic organization was either maintained or lost. Remarkably, the tightest organization is found in vertebrates, raising the embarrassingly finalistic possibility that vertebrates have maintained best this ancestral configuration. Alternatively, could they have co-evolved with an increased `organization' of the Hox clusters, possibly linked to their genomic amplification, which would be at odds with our current perception of evolutionary mechanisms? When discussing the why's and how's of Hox gene clustering, we need to account for three points: the mechanisms of cluster evolution; the underlying biological constraints; and the developmental modes of the animals under consideration. By integrating these parameters, general conclusions emerge that can help solve the aforementioned dilemma. “See my son, here time becomes space” Gurnemanz, in Parsifal (R. Wagner)

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“…In order to obtain the various genotypes shown in Table 1, mice heterozygous for the HoxD allele (Zakany et al, 2004) [referred to as 'Del(1-10)'] were crossed with either del(1-13) (Zakany et al, 2001), del(4-13) (Zakany and Duboule, 1999), del(8i-13) (Tarchini et al, 2005) or del (11)(12)(13) . To produce the novel Del(4-11) allele, we used targeted meiotic recombination (TAMERE) (Hérault et al, 1998) after a cross between the del(4-13) allele and the md11f allele (Beckers and Duboule, 1998).…”

Section: Mouse Stocks Tamere Crosses and Genotypingmentioning

confidence: 99%

Hox gene function in vertebrate gut morphogenesis: the case of the caecum

2007

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The digestive tract is made of different subdivisions with various functions. During embryonic development, the developing intestine expresses combinations of Hox genes along its anterior to posterior axis, suggesting a role for these genes in this regionalization process. In particular, the transition from small to large intestine is labelled by the transcription of all Hoxd genes except Hoxd12 and Hoxd13, the latter two genes being transcribed only near the anus. Here, we describe two lines of mice that express Hoxd12 ectopically within this morphological transition. As a consequence, budding of the caecum is impeded, leading to complete agenesis in homozygous individuals. This effect is concurrent with a dramatic reduction of both Fgf10 and Pitx1 expression. Furthermore, the interactions between 'anterior' Hox genes and ectopic Hoxd12 suggest a model whereby anterior and posterior Hox products compete in controlling Fgf10 signalling, which is required for the growth of this organ in mice. These results illuminate components of the genetic cascade necessary for the emergence of this gut segment, crucial for many vertebrates.

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HoxD cluster scanning deletions identify multiple defects leading to paralysis in the mouse mutant Ironside

Cited by 48 publications

References 47 publications

A Flexible Bayesian Model for Testing for Transmission Ratio Distortion

A Flexible Bayesian Model for Testing for Transmission Ratio Distortion

The rise and fall of Hox gene clusters

Hox gene function in vertebrate gut morphogenesis: the case of the caecum

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