Mesenchymal patterning by Hoxa2 requires blocking Fgf-dependent activation of Ptx1

Nicoletta Bobola; Marta Carapuço; Sabine Ohnemus; Benoît Kanzler; Andreas Leibbrandt; Annette Neubüser; Jacques Drouin; Moisés Mallo

doi:10.1242/dev.00554

Mesenchymal patterning by Hoxa2 requires blocking Fgf-dependent activation of Ptx1

Nicoletta Bobola, Marta Carapuço, Sabine Ohnemus, Benoît Kanzler, Andreas Leibbrandt, Annette Neubüser, Jacques Drouin, Moisés Mallo

Research output: Contribution to journal › Article › peer-review

Abstract

Hox genes are known key regulators of embryonic segmental identity, but little is known about the mechanisms of their action. To address this issue, we have analyzed how Hoxa2 specifies segmental identity in the second branchial arch. Using a subtraction approach, we found that Ptx1 was upregulated in the second arch mesenchyme of Hoxa2 mutants. This upregulation has functional significance because, in Hoxa2-/-;Ptx1-/- embryos, the Hoxa2-/- phenotype is partially reversed. Hoxa2 interferes with the Ptx1 activating process, which is dependent on Fgf signals from the epithelium. Consistently, Lhx6, another target of Fgf8 signaling, is also upregulated in the Hoxa2-/- second arch mesenchyme. Our findings have important implications for the understanding of developmental processes in the branchial area and suggest a novel mechanism for mesenchymal patterning by Hox genes that acts to define the competence of mesenchymal cells to respond to skeletogenic signals.

Original language	English
Pages (from-to)	3403-3414
Number of pages	11
Journal	Development
Volume	130
Issue number	15
DOIs	https://doi.org/10.1242/dev.00554
Publication status	Published - Aug 2003

Keywords

Branchial arches
Fgf signaling
Hox genes
Hoxa2
Mesenchymal patterning
Ptx1

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@article{4ca7bcec96bc47008be42b338487ed84,

title = "Mesenchymal patterning by Hoxa2 requires blocking Fgf-dependent activation of Ptx1",

abstract = "Hox genes are known key regulators of embryonic segmental identity, but little is known about the mechanisms of their action. To address this issue, we have analyzed how Hoxa2 specifies segmental identity in the second branchial arch. Using a subtraction approach, we found that Ptx1 was upregulated in the second arch mesenchyme of Hoxa2 mutants. This upregulation has functional significance because, in Hoxa2-/-;Ptx1-/- embryos, the Hoxa2-/- phenotype is partially reversed. Hoxa2 interferes with the Ptx1 activating process, which is dependent on Fgf signals from the epithelium. Consistently, Lhx6, another target of Fgf8 signaling, is also upregulated in the Hoxa2-/- second arch mesenchyme. Our findings have important implications for the understanding of developmental processes in the branchial area and suggest a novel mechanism for mesenchymal patterning by Hox genes that acts to define the competence of mesenchymal cells to respond to skeletogenic signals.",

keywords = "Branchial arches, Fgf signaling, Hox genes, Hoxa2, Mesenchymal patterning, Ptx1",

author = "Nicoletta Bobola and Marta Carapu{\c c}o and Sabine Ohnemus and Beno{\^i}t Kanzler and Andreas Leibbrandt and Annette Neub{\"u}ser and Jacques Drouin and Mois{\'e}s Mallo",

year = "2003",

month = aug,

doi = "10.1242/dev.00554",

language = "English",

volume = "130",

pages = "3403--3414",

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T1 - Mesenchymal patterning by Hoxa2 requires blocking Fgf-dependent activation of Ptx1

AU - Bobola, Nicoletta

AU - Carapuço, Marta

AU - Ohnemus, Sabine

AU - Kanzler, Benoît

AU - Leibbrandt, Andreas

AU - Neubüser, Annette

AU - Drouin, Jacques

AU - Mallo, Moisés

PY - 2003/8

Y1 - 2003/8

N2 - Hox genes are known key regulators of embryonic segmental identity, but little is known about the mechanisms of their action. To address this issue, we have analyzed how Hoxa2 specifies segmental identity in the second branchial arch. Using a subtraction approach, we found that Ptx1 was upregulated in the second arch mesenchyme of Hoxa2 mutants. This upregulation has functional significance because, in Hoxa2-/-;Ptx1-/- embryos, the Hoxa2-/- phenotype is partially reversed. Hoxa2 interferes with the Ptx1 activating process, which is dependent on Fgf signals from the epithelium. Consistently, Lhx6, another target of Fgf8 signaling, is also upregulated in the Hoxa2-/- second arch mesenchyme. Our findings have important implications for the understanding of developmental processes in the branchial area and suggest a novel mechanism for mesenchymal patterning by Hox genes that acts to define the competence of mesenchymal cells to respond to skeletogenic signals.

AB - Hox genes are known key regulators of embryonic segmental identity, but little is known about the mechanisms of their action. To address this issue, we have analyzed how Hoxa2 specifies segmental identity in the second branchial arch. Using a subtraction approach, we found that Ptx1 was upregulated in the second arch mesenchyme of Hoxa2 mutants. This upregulation has functional significance because, in Hoxa2-/-;Ptx1-/- embryos, the Hoxa2-/- phenotype is partially reversed. Hoxa2 interferes with the Ptx1 activating process, which is dependent on Fgf signals from the epithelium. Consistently, Lhx6, another target of Fgf8 signaling, is also upregulated in the Hoxa2-/- second arch mesenchyme. Our findings have important implications for the understanding of developmental processes in the branchial area and suggest a novel mechanism for mesenchymal patterning by Hox genes that acts to define the competence of mesenchymal cells to respond to skeletogenic signals.

KW - Branchial arches

KW - Fgf signaling

KW - Hox genes

KW - Hoxa2

KW - Mesenchymal patterning

KW - Ptx1

U2 - 10.1242/dev.00554

DO - 10.1242/dev.00554

M3 - Article

SN - 0950-1991

VL - 130

SP - 3403

EP - 3414

JO - Development

JF - Development

IS - 15

ER -

Mesenchymal patterning by Hoxa2 requires blocking Fgf-dependent activation of Ptx1

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Keywords

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