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135 results on '"Pira, Charmaine"'

9. Two limb-specific enhancers control Lmx1b expression in a modular and autoregulatory manner

Author

Ros, María A., Haro, Endika, Castilla-Ibeas, Alejandro, Zdral, Sofía, Galán, Laura, Pira, Charmaine, Petit, Florence, and Oberg, Kerby C.

Abstract

Trabajo presentado en el EMBO Workshop: Enhanceropathies: understanding enhancer function to understand human disease, celebrado en Santander (España) del 06 al 09 de octubre de 2021., Lmx1b is the key regulator of dorso-ventral (DV) pattern in the limb, as it is both necessary and sufficient to specify dorsal fates. Accordingly, targeted disruption of Lmx1b results in double ventral limbs. In humans, mutations in the LMX1B gene are responsible for the autosomal dominant Nail-Patella Syndrome (OMIM #161200), characterized by incomplete limb dorsalization. Here, we report on two enhancers located upstream of the gene, LARM1 and LARM2, that regulate Lmx1b specifically in the limb. These sequences contain several canonical Lmx1b binding sites that mediate a positive loop of Lmx1b autoregulation. Deletion of these enhancers together results in mice with double ventral limbs, like these of Lmx1b-nul mice. Remarkably, deletion of each individual enhancer produced a double ventral phenotype clearly restricted to the posterior half of the limb in LARM1 mutants and to the anterior in LARM2 mutants, indicating differential activity of these enhancers along the anterior-posterior axis. These results reflect an unexpected complex, modular and autoregulatory mode of Lmx1b transcriptional regulation during limb development. We also report on several NPS patient families with normal LMX1B coding sequence but variations in the LARM region that exhibit limb restricted phenotypes, stressing the role of regulatory modules in disease pathogenesis.

Published
2021

10. Identification of limb-specific Lmx1b auto-regulatory modules with Nail-Patella Syndrome pathogenicity

Author

Haro, Endika, Petit, Florence, Pira, Charmaine, Spady, Conor, Ivey, Lauren, Gray, Austin L., Escande, Fabienne, Jourdain, Anne-Sophie, Nguyen, Andy, Fellmann, Florence, Good, Jean-Marc, Francannet, Christine, Manouvrier-Hanu, Sylvie, Ros, María A., and Oberg, Kerby C.

Abstract

Resumen del trabajo presentado en el 17th Spanish Society for Developmental Biology Meeting Virtual Meeting, celebrado en modalidad virtual del 18 al 20 de noviembre de 2020., Lmx1b is a LIM homeodomain transcription factor that plays essential roles in a wide range of developmental processes including the development of the kidney, the eye, the dopaminergic and serotonergic neurons and the limb. In the limb, Lmx1b expression is restricted to the dorsal mesenchyme and is responsible for limb dorsalization. Mice lacking functional Lmx1b die at birth because of multisystemic malformations. Homozygous Lmx1b mutants develop a double-ventral limb phenotype with loss of dorsal structures such as the patella, whereas the ventral ones such as the sesamoid bones are duplicated and dorsal tendons and muscles are transformed into mirror images of ventral ones. At superficial level, hair and nails are absent while typical ventral features such as pads are also duplicated. Herein, we report on two conserved Lmx1bassociated cis-regulatory modules (LARM1 and LARM2) located upstream of Lmx1b that are bound by Lmx1b and mediate an autoregulatory loop required to provide adequate levels of Lmx1b expression necessary for limb dorsalization. Combined removal of both enhancer lead to a limb restricted phenotype identical to that of the Lmx1b Knockout mice with no other Lmx1b-related systemic defects, indicating that they are limb specific enhancers. Unexpectedly, the CRISPR/Cas9 deletion of each individual enhancer produced a double ventral phenotype clearly restricted to the posterior or anterior half of the autopod in LARM1 and LARM2 respectively, unveiling spatial modularity in the transcriptional control of Lmx1b in the limb. In humans, LMX1B haploinsufficiency causes Nail-patella syndrome (NPS; MIM 161200), characterized by nail dysplasia, absent/hypoplastic patellae, chronic kidney disease, and glaucoma. Of most interest, we report on two NPS patient families with normal LMX1B coding sequence and limb-restricted phenotype, but with loss-of-function variations in the LARM1/2 region, stressing the role of regulatory modules in disease pathogenesis.

Published
2020

11. Identification of limb-specific Lmx1b auto-regulatory modules with Nail-patella syndrome pathogenicity

Author

Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), Rare Disorders Consortium Disease Network (US), Haro, Endika, Petit, Florence, Pira, Charmaine, Spady, Conor, Lucas, Sara, Yorozuya, Lauren I., Gray, Austin L., Escande, Fabienne, Jourdain, Anne-Sophie, Nguyen, Andy, Fellmann, Florence, Good, Jean-Marc, Francannet, Christine, Manouvrier-Hanu, Sylvie, Ros, María A., Oberg, Kerby C., Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), Rare Disorders Consortium Disease Network (US), Haro, Endika, Petit, Florence, Pira, Charmaine, Spady, Conor, Lucas, Sara, Yorozuya, Lauren I., Gray, Austin L., Escande, Fabienne, Jourdain, Anne-Sophie, Nguyen, Andy, Fellmann, Florence, Good, Jean-Marc, Francannet, Christine, Manouvrier-Hanu, Sylvie, Ros, María A., and Oberg, Kerby C.

Abstract

LMX1B haploinsufficiency causes Nail-patella syndrome (NPS; MIM 161200), characterized by nail dysplasia, absent/hypoplastic patellae, chronic kidney disease, and glaucoma. Accordingly in mice, Lmx1b has been shown to play crucial roles in the development of the limb, kidney and eye. Although one functional allele of Lmx1b appears adequate for development, Lmx1b null mice display ventral-ventral distal limbs with abnormal kidney, eye and cerebellar development, more disruptive, but fully concordant with NPS. In Lmx1b functional knockouts (KOs), Lmx1b transcription in the limb is decreased nearly 6-fold, indicating autoregulation. Herein, we report on two conserved Lmx1b-associated cis-regulatory modules (LARM1 and LARM2) that are bound by Lmx1b, amplify Lmx1b expression with unique spatial modularity in the limb, and are necessary for Lmx1b-mediated limb dorsalization. These enhancers, being conserved across vertebrates (including coelacanth, but not other fish species), and required for normal locomotion, provide a unique opportunity to study the role of dorsalization in the fin to limb transition. We also report on two NPS patient families with normal LMX1B coding sequence, but with loss-of-function variations in the LARM1/2 region, stressing the role of regulatory modules in disease pathogenesis.

Published
2021

18. Identification of limb-specific Lmx1b auto-regulatory modules with Nail-Patella Syndrome pathogenicity

Author

Haro, Endika, primary, Petit, Florence, additional, Pira, Charmaine U., additional, Spady, Conor D., additional, Ivey, Lauren A., additional, Gray, Austin L., additional, Escande, Fabienne, additional, Jourdain, Anne-Sophie, additional, Nguyen, Andy, additional, Fellmann, Florence, additional, Good, Jean-Marc, additional, Francannet, Christine, additional, Manouvrier-Hanu, Sylvie, additional, Ros, Marian A., additional, and Oberg, Kerby C., additional

Published
2020
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26. Autoregulation of Lmx1b during limb development: A role in Nail-Patella Syndrome?

Author

Oberg, Kerby, Haro, Endika, Pira, Charmaine, and Ros, Marian A.

Subjects
musculoskeletal diseases, CULA, integumentary system, Limb dorsalization, Mouse, 610 Medical sciences, Medicine, musculoskeletal system, NPS, body regions, Congenital upper limb anomalies, ddc: 610, Nail-Patella Syndrome, FOS: Biological sciences, Genomic, Genetics, LMX1B, Limb development
Abstract

Objectives/Interrogation: The LIM homeodomain transcription factor Lmx1b is restricted to the dorsal limb mesenchyme during development and is essential for distal limb dorsalization. In humans, LMX1B mutations cause Nail-Patella Syndrome characterized by nail dysplasia, absent or hypoplastic patellae,[for full text, please go to the a.m. URL], 14th Triennial Congress of the International Federation of Societies for Surgery of the Hand (IFSSH), 11th Triennial Congress of the International Federation of Societies for Hand Therapy (IFSHT), 11th Triennial Congress of the International Federation of Societies for Hand Therapy (IFSHT)

Published
2020

30. Two Lmx1b-associated cis-regulatory modules (LARM1/2) mediate Lmx1b auto-amplification during limb dorsalization and their disruption can cause a limb-specific form of Nail-Patella syndrome

Author

Oberg, Kerby C., Haro, Endika, Petit, Florence, Pira, Charmaine, Spady, Conor, Ivey, Lauren, Gray, Austin L., Escande, Fabienne, Jourdain, Anne-Sophie, Nguyen, Andy, Good, Jean-Marc, Francannet, Christine, Manouvrier-Hanu, Sylvie, Ros, María A., Oberg, Kerby C., Haro, Endika, Petit, Florence, Pira, Charmaine, Spady, Conor, Ivey, Lauren, Gray, Austin L., Escande, Fabienne, Jourdain, Anne-Sophie, Nguyen, Andy, Good, Jean-Marc, Francannet, Christine, Manouvrier-Hanu, Sylvie, and Ros, María A.

Abstract

During limb development, the Lmx1b homeodomain transcription factor is restricted to dorsal mesenchyme and is required for distal dorsalization. Lmx1b also contributes to kidney, eye and cerebellar development. Haploinsufficiency of the human LMX1B genes causes Nail-Patella Syndrome (NPS) characterized by nail dysplasia, absent or hypoplastic patellae, eye abnormalities, and progressive kidney disease. In the functional Lmx1b knockout mouse, transcription of the mutant Lmx1b mRNA in the limb is reduced, indicating a role for Lmx1b in an auto-amplifying feedback loop. Previous Lmx1b-targeted ChIP-seq data identified two Lmx1b-associated regulatory modules (LARM1/2) bound by Lmx1b. Herein, we demonstrate that LARM1/2 activity overlaps Lmx1b expression in the dorsal limb mesoderm and is dependent on conserved Lmx1b binding sites for activity. We also demonstrate interaction between the LARM enhancers and the Lmx1b promoter. In addition, we performed a targeted CRISPR-Cas excision of the LARM1/2 region in mice; loss of LARM1/2 reduced the expression of Lmx1b in normal mice and generated a phenotype with nearly symmetrical ventral-ventral distal limbs. LARM1/2 loss was limb-specific and did not affect any other Lmx1b-related organs. We extended our investigation to humans with an NPS phenotype that lacked a variation within the LMX1B coding sequence. In two families with a limb-restricted phenotype, loss-of-function variations in the LARM region were identified. These data indicate that the limb-specific expression of Lmx1b is amplified through an auto-regulatory loop involving LARM1/2. Furthermore, disruption of LARM1/2 function can cause isolated limb malformations in mice and human NPS.

Published
2019

31. LHX2 Mediates the FGF-to-SHH Regulatory Loop during Limb Development

Author

Watson, Billy, primary, Feenstra, Jennifer, additional, Van Arsdale, Jonathan, additional, Rai-Bhatti, Karndeep, additional, Kim, Diana, additional, Coggins, Ashley, additional, Mattison, Gennaya, additional, Yoo, Stephen, additional, Steinman, Eric, additional, Pira, Charmaine, additional, Gongol, Brendan, additional, and Oberg, Kerby, additional

Published
2018
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