Genetic basis for an evolutionary shift from ancestral preaxial to postaxial limb polarity in non-urodele vertebrates

Anna Trofka; Bau Lin Huang; Jianjian Zhu; William F. Heinz; Valentin Magidson; Yuki Shibata; Yun Bo Shi; Basile Tarchini; H. Scott Stadler; Mirindi Kabangu; Nour W. Al Haj Baddar; S. Randal Voss; Susan Mackem

doi:10.1016/j.cub.2021.09.010

Genetic basis for an evolutionary shift from ancestral preaxial to postaxial limb polarity in non-urodele vertebrates

Anna Trofka
, Bau Lin Huang
, Jianjian Zhu
, William F. Heinz
, Valentin Magidson
, Yuki Shibata
, Yun Bo Shi
, Basile Tarchini
, H. Scott Stadler
, Mirindi Kabangu
, Nour W. Al Haj Baddar
, S. Randal Voss
, Susan Mackem

Producción científica: Article › revisión exhaustiva

8 Citas (Scopus)

Resumen

In most tetrapod vertebrates, limb skeletal progenitors condense with postaxial dominance. Posterior elements (such as ulna and fibula) appear prior to their anterior counterparts (radius and tibia), followed by digit-appearance order with continuing postaxial polarity. The only exceptions are urodele amphibians (salamanders), whose limb elements develop with preaxial polarity and who are also notable for their unique ability to regenerate complete limbs as adults. The mechanistic basis for this preaxial dominance has remained an enigma and has even been proposed to relate to the acquisition of novel genes involved in regeneration. However, recent fossil evidence suggests that preaxial polarity represents an ancestral rather than derived state. Here, we report that 5′Hoxd (Hoxd11-d13) gene deletion in mouse is atavistic and uncovers an underlying preaxial polarity in mammalian limb formation. We demonstrate this shift from postaxial to preaxial dominance in mouse results from excess Gli3 repressor (Gli3R) activity due to the loss of 5′Hoxd-Gli3 antagonism and is associated with cell-cycle changes promoting precocious cell-cycle exit in the anterior limb bud. We further show that Gli3 knockdown in axolotl results in a shift to postaxial dominant limb skeleton formation, as well as expanded paddle-shaped limb-bud morphology and ensuing polydactyly. Evolutionary changes in Gli3R activity level, which also played a key role in the fin-to-limb transition, appear to be fundamental to the shift from preaxial to postaxial polarity in formation of the tetrapod limb skeleton.

Idioma original	English
Páginas (desde-hasta)	4923-4934.e5
Publicación	Current Biology
Volumen	31
N.º	22
DOI	https://doi.org/10.1016/j.cub.2021.09.010
Estado	Published - nov 22 2021

Nota bibliográfica

Publisher Copyright:
© 2021

Financiación

We thank Denis Duboule for generously providing the 5′HoxdDel(RXII) (d11-d13 deleted) mutant line, Deneen Wellik for the Hoxd11 mutant line, Steve Vokes for both RosaGrem1 and RosaGli3R transgenic lines, Trevor Williams for the AP2Cre transgenic line, Alan Godwin for help in generating the DSRed2 cassette used to create the Hoxd13 targeting construct, Matt Anderson for advice on HCR protocols, Rich Hwang for advice on tadpole analysis, and members of the CDBL for critical discussion. This research was supported by the Center for Cancer Research (S.M. Intramural Research Program) and the Frederick National Laboratory (W.F.H. and V.M. OMAL Contract no. 75N91019D00024), NCI, NIH; by the Office of Infrastructure Programs, NIH (S.R.V. and M.K. P40-OD019794); and by grants from OHSU Medical Research Foundation and Shriners Hospitals for Children (H.S.S.). S.M. A.T. and B.-L.H. designed the project. S.M. wrote the original paper draft, and S.M. B.-L.H. J.Z. and S.R.V. contributed to text editing and revisions. A.T. B.-L.H. J.Z. M.K. N.W.A.H.B. and S.R.V. performed the experiments; Y.S. and Y.-B.S. assisted with Xenopus; and M.K. and N.W.A.H.B. assisted with axolotl larval collection and processing for analyses. S.R.V. performed axolotl microinjections. W.F.H. and V.M. provided technical advice and assistance with live-imaging data collection and analysis. H.S.S. and B.T. generated key genetically engineered mice used for analyses. The authors declare no competing interests. We thank Denis Duboule for generously providing the 5′HoxdDel(RXII) (d11-d13 deleted) mutant line, Deneen Wellik for the Hoxd11 mutant line, Steve Vokes for both RosaGrem1 and RosaGli3R transgenic lines, Trevor Williams for the AP2Cre transgenic line, Alan Godwin for help in generating the DSRed2 cassette used to create the Hoxd13 targeting construct, Matt Anderson for advice on HCR protocols, Rich Hwang for advice on tadpole analysis, and members of the CDBL for critical discussion. This research was supported by the Center for Cancer Research (S.M., Intramural Research Program) and the Frederick National Laboratory (W.F.H. and V.M., OMAL Contract no. 75N91019D00024 ), NCI, NIH ; by the Office of Infrastructure Programs , NIH (S.R.V. and M.K., P40-OD019794 ); and by grants from OHSU Medical Research Foundation and Shriners Hospitals for Children (H.S.S.).

Financiadores	Número del financiador
CDBL
OMAL
NIH Office of Research Infrastructure Programs	P40-OD019794
RXII
National Institutes of Health (NIH)	F22CA000024
National Institutes of Health (NIH)
NIH Office of the Director	P40OD019794
NIH Office of the Director
National Childhood Cancer Registry – National Cancer Institute
Shriners Hospitals for Children Cincinnati
Frederick National Laboratory for Cancer Research	75N91019D00024
Frederick National Laboratory for Cancer Research
Medical Research Council-São Paulo Research Foundation

ASJC Scopus subject areas

General Biochemistry, Genetics and Molecular Biology
General Agricultural and Biological Sciences

Acceder al documento

10.1016/j.cub.2021.09.010

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Trofka, A., Huang, B. L., Zhu, J., Heinz, W. F., Magidson, V., Shibata, Y., Shi, Y. B., Tarchini, B., Stadler, H. S., Kabangu, M., Al Haj Baddar, N. W., Voss, S. R., & Mackem, S. (2021). Genetic basis for an evolutionary shift from ancestral preaxial to postaxial limb polarity in non-urodele vertebrates. Current Biology, 31(22), 4923-4934.e5. https://doi.org/10.1016/j.cub.2021.09.010

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title = "Genetic basis for an evolutionary shift from ancestral preaxial to postaxial limb polarity in non-urodele vertebrates",

abstract = "In most tetrapod vertebrates, limb skeletal progenitors condense with postaxial dominance. Posterior elements (such as ulna and fibula) appear prior to their anterior counterparts (radius and tibia), followed by digit-appearance order with continuing postaxial polarity. The only exceptions are urodele amphibians (salamanders), whose limb elements develop with preaxial polarity and who are also notable for their unique ability to regenerate complete limbs as adults. The mechanistic basis for this preaxial dominance has remained an enigma and has even been proposed to relate to the acquisition of novel genes involved in regeneration. However, recent fossil evidence suggests that preaxial polarity represents an ancestral rather than derived state. Here, we report that 5′Hoxd (Hoxd11-d13) gene deletion in mouse is atavistic and uncovers an underlying preaxial polarity in mammalian limb formation. We demonstrate this shift from postaxial to preaxial dominance in mouse results from excess Gli3 repressor (Gli3R) activity due to the loss of 5′Hoxd-Gli3 antagonism and is associated with cell-cycle changes promoting precocious cell-cycle exit in the anterior limb bud. We further show that Gli3 knockdown in axolotl results in a shift to postaxial dominant limb skeleton formation, as well as expanded paddle-shaped limb-bud morphology and ensuing polydactyly. Evolutionary changes in Gli3R activity level, which also played a key role in the fin-to-limb transition, appear to be fundamental to the shift from preaxial to postaxial polarity in formation of the tetrapod limb skeleton.",

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author = "Anna Trofka and Huang, \{Bau Lin\} and Jianjian Zhu and Heinz, \{William F.\} and Valentin Magidson and Yuki Shibata and Shi, \{Yun Bo\} and Basile Tarchini and Stadler, \{H. Scott\} and Mirindi Kabangu and \{Al Haj Baddar\}, \{Nour W.\} and Voss, \{S. Randal\} and Susan Mackem",

note = "Publisher Copyright: {\textcopyright} 2021",

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Trofka, A, Huang, BL, Zhu, J, Heinz, WF, Magidson, V, Shibata, Y, Shi, YB, Tarchini, B, Stadler, HS, Kabangu, M, Al Haj Baddar, NW, Voss, SR & Mackem, S 2021, 'Genetic basis for an evolutionary shift from ancestral preaxial to postaxial limb polarity in non-urodele vertebrates', Current Biology, vol. 31, n.º 22, pp. 4923-4934.e5. https://doi.org/10.1016/j.cub.2021.09.010

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AU - Trofka, Anna

AU - Huang, Bau Lin

AU - Zhu, Jianjian

AU - Heinz, William F.

AU - Magidson, Valentin

AU - Shibata, Yuki

AU - Shi, Yun Bo

AU - Tarchini, Basile

AU - Stadler, H. Scott

AU - Kabangu, Mirindi

AU - Al Haj Baddar, Nour W.

AU - Voss, S. Randal

AU - Mackem, Susan

PY - 2021/11/22

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N2 - In most tetrapod vertebrates, limb skeletal progenitors condense with postaxial dominance. Posterior elements (such as ulna and fibula) appear prior to their anterior counterparts (radius and tibia), followed by digit-appearance order with continuing postaxial polarity. The only exceptions are urodele amphibians (salamanders), whose limb elements develop with preaxial polarity and who are also notable for their unique ability to regenerate complete limbs as adults. The mechanistic basis for this preaxial dominance has remained an enigma and has even been proposed to relate to the acquisition of novel genes involved in regeneration. However, recent fossil evidence suggests that preaxial polarity represents an ancestral rather than derived state. Here, we report that 5′Hoxd (Hoxd11-d13) gene deletion in mouse is atavistic and uncovers an underlying preaxial polarity in mammalian limb formation. We demonstrate this shift from postaxial to preaxial dominance in mouse results from excess Gli3 repressor (Gli3R) activity due to the loss of 5′Hoxd-Gli3 antagonism and is associated with cell-cycle changes promoting precocious cell-cycle exit in the anterior limb bud. We further show that Gli3 knockdown in axolotl results in a shift to postaxial dominant limb skeleton formation, as well as expanded paddle-shaped limb-bud morphology and ensuing polydactyly. Evolutionary changes in Gli3R activity level, which also played a key role in the fin-to-limb transition, appear to be fundamental to the shift from preaxial to postaxial polarity in formation of the tetrapod limb skeleton.

AB - In most tetrapod vertebrates, limb skeletal progenitors condense with postaxial dominance. Posterior elements (such as ulna and fibula) appear prior to their anterior counterparts (radius and tibia), followed by digit-appearance order with continuing postaxial polarity. The only exceptions are urodele amphibians (salamanders), whose limb elements develop with preaxial polarity and who are also notable for their unique ability to regenerate complete limbs as adults. The mechanistic basis for this preaxial dominance has remained an enigma and has even been proposed to relate to the acquisition of novel genes involved in regeneration. However, recent fossil evidence suggests that preaxial polarity represents an ancestral rather than derived state. Here, we report that 5′Hoxd (Hoxd11-d13) gene deletion in mouse is atavistic and uncovers an underlying preaxial polarity in mammalian limb formation. We demonstrate this shift from postaxial to preaxial dominance in mouse results from excess Gli3 repressor (Gli3R) activity due to the loss of 5′Hoxd-Gli3 antagonism and is associated with cell-cycle changes promoting precocious cell-cycle exit in the anterior limb bud. We further show that Gli3 knockdown in axolotl results in a shift to postaxial dominant limb skeleton formation, as well as expanded paddle-shaped limb-bud morphology and ensuing polydactyly. Evolutionary changes in Gli3R activity level, which also played a key role in the fin-to-limb transition, appear to be fundamental to the shift from preaxial to postaxial polarity in formation of the tetrapod limb skeleton.

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KW - limb axis formation polarity

KW - postaxial limb polarity in mutant axolotl

KW - preaxial limb polarity in mutant mice

KW - vertebrate limb development

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SN - 0960-9822

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SP - 4923-4934.e5

JO - Current Biology

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ER -

Genetic basis for an evolutionary shift from ancestral preaxial to postaxial limb polarity in non-urodele vertebrates

Resumen

Nota bibliográfica

Financiación

ASJC Scopus subject areas

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