Complex genetic architecture of three-dimensional craniofacial shape variation in domestic pigeons

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Elena F. Boer, Emily T. Maclary, Michael D. Shapiro
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引用次数: 5

Abstract

Deciphering the genetic basis of vertebrate craniofacial variation is a longstanding biological problem with broad implications in evolution, development, and human pathology. One of the most stunning examples of craniofacial diversification is the adaptive radiation of birds, in which the beak serves essential roles in virtually every aspect of their life histories. The domestic pigeon (Columba livia) provides an exceptional opportunity to study the genetic underpinnings of craniofacial variation because of its unique balance of experimental accessibility and extraordinary phenotypic diversity within a single species. We used traditional and geometric morphometrics to quantify craniofacial variation in an F2 laboratory cross derived from the straight-beaked Pomeranian Pouter and curved-beak Scandaroon pigeon breeds. Using a combination of genome-wide quantitative trait locus scans and multi-locus modeling, we identified a set of genetic loci associated with complex shape variation in the craniofacial skeleton, including beak shape, braincase shape, and mandible shape. Some of these loci control coordinated changes between different structures, while others explain variation in the size and shape of specific skull and jaw regions. We find that in domestic pigeons, a complex blend of both independent and coupled genetic effects underlie three-dimensional craniofacial morphology.

Abstract Image

家鸽三维颅面形状变异的复杂遗传结构
破解脊椎动物颅面变异的遗传基础是一个长期存在的生物学问题,在进化、发育和人类病理学中具有广泛的意义。颅面多样化最惊人的例子之一是鸟类的适应性辐射,其中喙在其生活史的几乎每个方面都起着至关重要的作用。家鸽(Columba livia)为研究颅面变异的遗传基础提供了一个特殊的机会,因为它在单一物种中具有独特的实验可及性和非凡的表型多样性平衡。我们使用传统和几何形态计量学来量化由直喙波美拉尼亚和弯喙Scandaroon鸽子品种衍生的F2实验室杂交品种的颅面变异。利用全基因组数量性状位点扫描和多位点建模的结合,我们确定了一组与颅面骨骼复杂形状变异相关的遗传位点,包括喙形、脑壳形状和下颌骨形状。这些基因座中的一些控制着不同结构之间的协调变化,而另一些则解释了特定头骨和颌骨区域的大小和形状的变化。我们发现,在家鸽中,独立和耦合的遗传效应的复杂混合是三维颅面形态的基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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