An Org-1–Tup transcriptional cascade reveals different types of alary muscles connecting internal organs in <i>Drosophila</i>

Boukhatmi, Hadi; Schaub, Christoph; Bataillé, Laetitia; Reim, Ingolf; Frendo, Jean-Louis; Frasch, Manfred; Víncent, Alaín

doi:10.1242/dev.111005

Cited by 26 publications

(43 citation statements)

References 53 publications

(77 reference statements)

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“…The myogenic function of Drosophila collier was first reported for its role in the specification of a hemisegmentally repeated abdominal muscle subtype (Crozatier and Vincent, 1999), where it is regulated by and required in cooperation with nau/MyoD for DA3 muscle differentiation (Enriquez et al, 2012;Dubois et al, 2007). This domain is notably distinct from that of org-1/Tbx1 action (Schaub et al, 2012;Boukhatmi et al, 2014). Two COE homologs in vertebrates, Ebf2 and Ebf3, regulate Myf5 and MyoD expressions in the somitic and branchiomeric muscles of Xenopus (Green and Vetter, 2011).…”

Section: Discussionmentioning

confidence: 99%

“…In vertebrates, Tbx1 is involved in activating MRF genes in the pharyngeal mesoderm (Kelly et al, 2004). In Drosophila, the Tbx1 homologue, Org-1, activates muscle-specific transcription factors temporally downstream of nau in several somatic muscles (Schaub et al, 2012), and acts independently of nau in alary muscle development (Boukhatmi et al, 2014). collier (also known as knot), the Drosophila homolog and founding member of the COE (Collier/Olfactory-I/Early B-Cell Factor) family of transcription factors, cooperates with Nau to cause differentiation of a distinct subset of muscles from those that require Org-1 (Enriquez et al, 2012;Dubois et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

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Rewiring of an ancestral Tbx1/10-Ebf-Mrf network for pharyngeal muscle specification in distinct embryonic lineages

Tolkin

Christiaen

2016

Development

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Skeletal muscles arise from diverse embryonic origins in vertebrates, yet converge on extensively shared regulatory programs that require muscle regulatory factor (MRF)-family genes. Myogenesis in the tail of the simple chordate Ciona exhibits a similar reliance on its single MRF-family gene, and diverse mechanisms activate Ci-Mrf. Here, we show that myogenesis in the atrial siphon muscles (ASMs) and oral siphon muscles (OSMs), which control the exhalant and inhalant siphons, respectively, also requires Mrf. We characterize the ontogeny of OSM progenitors and compare the molecular basis of Mrf activation in OSM versus ASM. In both muscle types, Ebf and Tbx1/10 are expressed and function upstream of Mrf. However, we demonstrate that regulatory relationships between Tbx1/10, Ebf and Mrf differ between the OSM and ASM lineages. We propose that Tbx1, Ebf and Mrf homologs form an ancient conserved regulatory state for pharyngeal muscle specification, whereas their regulatory relationships might be more evolutionarily variable.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Rewiring of an ancestral Tbx1/10-Ebf-Mrf network for pharyngeal muscle specification in distinct embryonic lineages

Tolkin

Christiaen

2016

Development

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“…We, along with our colleagues, have shown recently that org-1 and tailup control embryonic AM development and that Org-1 directly regulates tup expression by binding to a distinct enhancer element (tup-ADME) [29]. Staining of adult hearts with antibodies against Tup showed that, in addition to pericardial cells, the nuclei of the VLMs were positive for Tup ( Figure 3E).…”

Section: Resultsmentioning

confidence: 70%

“…We found that, apart from cardiomyocytes, tup-ADME-GFP activity was present in the VLMs ( Figure 3G). When the ability of tup-ADME to bind Org-1 is abolished by base pair changes introduced into the three identified Org-1-binding motifs [29], this leads to a nearly complete loss of tup-ADME-orgI-IIImut-GFP activity in the VLMs. Because the expression in the cardiomyocytes stayed robust ( Figure 3H, asterisks), this demonstrates VLM-specific, direct regulation of the tup-ADME enhancer element by Org-1.…”

Section: Resultsmentioning

confidence: 99%

Org-1-Dependent Lineage Reprogramming Generates the Ventral Longitudinal Musculature of the Drosophila Heart

et al. 2015

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Only few examples of transdifferentiation, which denotes the conversion of one differentiated cell type to another, are known to occur during normal development, and more often, it is associated with regeneration processes. With respect to muscles, dedifferentiation/redifferentiation processes have been documented during post-traumatic muscle regeneration in blastema of newts as well as during myocardial regeneration. As shown herein, the ventral longitudinal muscles of the adult Drosophila heart arise from specific larval alary muscles in a process that represents the first known example of syncytial muscle transdifferentiation via dedifferentiation into mononucleate myoblasts during normal development. We demonstrate that this unique process depends on the reinitiation of a transcriptional program previously employed for embryonic alary muscle development, in which the factors Org-1 (Drosophila Tbx1) and Tailup (Drosophila Islet1) are key components. During metamorphosis, the action of these factors is combined with cell-autonomous inputs from the ecdysone steroid and the Hox gene Ultrabithorax, which provide temporal and spatial specificity to the transdifferentiation events. Following muscle dedifferentiation, inductive cues, particularly from the remodeling heart tube, are required for the redifferentiation of myoblasts into ventral longitudinal muscles. Our results provide new insights into mechanisms of lineage commitment and cell-fate plasticity during development.

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“…2). In the embryo, Drosophila AMs run immediately anterior to segmental boundaries, with their dorsal projections extending on either side of the boundary and connecting two adjacent AMs with one another (Boukhatmi et al, 2014) (Fig. 1).…”

Section: Alary Musclesmentioning

confidence: 99%

Hox control of Drosophila larval anatomy; The Alary and Thoracic Alary-Related Muscles

Bataillé

Frendo

Víncent

2015

Mechanisms of Development

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The body plan of arthropods and vertebrates involves the formation of repetitive segments, which subsequently diversify to give rise to different body parts along the antero-posterior/rostro-caudal body axis. Anatomical variations between body segments are crucial for organ function and organismal fitness. Pioneering work in Drosophila has established that Hox transcription factors play key roles both in endowing initially identical segments with distinct identities and organogenesis. The focus of this review is on Alary Muscles (AMs) and the newly discovered Thoracic Alary-Related Muscles (TARMs). AMs and TARMs are thin muscles which together connect the circulatory system and different midgut regions to the exoskeleton, while intertwining with the respiratory tubular network. They were hypothesized to represent a new type of muscles with spring-like properties, maintaining internal organs in proper anatomical positions during larval locomotion. Both the morphology of TARMs relative to AMs, and morphogenesis of connected tissues is under Hox control, emphasizing the key role of Hox proteins in coordinating the anatomical development of the larva.

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An Org-1–Tup transcriptional cascade reveals different types of alary muscles connecting internal organs in Drosophila

Cited by 26 publications

References 53 publications

Rewiring of an ancestral Tbx1/10-Ebf-Mrf network for pharyngeal muscle specification in distinct embryonic lineages

Rewiring of an ancestral Tbx1/10-Ebf-Mrf network for pharyngeal muscle specification in distinct embryonic lineages

Org-1-Dependent Lineage Reprogramming Generates the Ventral Longitudinal Musculature of the Drosophila Heart

Hox control of Drosophila larval anatomy; The Alary and Thoracic Alary-Related Muscles

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