FGFR1 Signaling is Associated with the Magnitude of Morphological Integration in Human Head Shape

TÁBITA HÜNEMEIER; JORGE GÓMEZ VALDÉS; DE AZEVEDO, SOLEDAD; MIRSHA QUINTO-SÁNCHEZ; LUCIANE PASSAGLIA; FRANCISCO MAURO SALZANO; GABRIELA SÁNCHEZ-MEJORADA; VÍCTOR ACUÑA-ALONZO; NEUS MARTÍNEZ ABADÍAS; MARIA CÁTIRA BORTOLINI; ROLANDO GONZÁLEZ-JOSÉ

AMERICAN JOURNAL OF HUMAN BIOLOGY

WILEY-LISS, DIV JOHN WILEY & SONS INC

Lugar: New York; Año: 2013

1042-0533

ABSTRACT: Objectives: The head can be used as a model to study complex phenotypes controlled simultaneously by morphological integration (MI) due to common factors, and modular patterns caused by local factors affecting the development and functional demands of specific structures. The fibroblast growth factor and receptor system (FGF/FGFR) participates in cell communication and pattern formation in osseous tissues, among others, and there is compelling evidence from mouse model studies suggesting a role of the FGF/FGFR pathway as a covariance-generating signalling process in head development. Here we use human data to test if specific genetic variants of another gene of this pathway, the FGFR1 gene, can be associated with differences in the integration of the head. Methods: We explored whether and how three specific variants on FGFR1, previously associated with human cephalic index, influence the pattern and level of head integration of one Native American and one admixed group from Mexico. MI, measured as the intensity of covariation among head traits, was assessed using data from threedimensional head landmark coordinates taken on 176 individuals. Results: Individuals carrying the derived allele of the rs4647905:G>C polymorphism present significantly greater levels of head MI, especially in facial structures and on the shape space where the modular portion of the covariation is explicitly removed. Conclusions: Since FGFR genes present nonconservative and tissue-specific splicing sites, they may have some effect on protein structure and performance likely involved in developmental processes responsible for the magnitude and pattern of MI in the human head. Am. J. Hum. Biol. 00:000?000, 2013.