Gene regulatory networks and craniofacial patterning in the chick

雏鸡的基因调控网络和颅面模式

• 批准号: RGPIN-2019-05717
• 负责人: Bendall, Andrew
• 金额: $ 2.33万
• 依托单位: University of Guelph
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=715762
• 关键词: Gene; regulatory; networks; craniofacial; patterning

Understanding the diversity of life on earth, and its origins, has occupied human thought for centuries. Indeed, contemplation of biological diversity and the origins of novel types of organisms is deeply significant for a species capable of reconciling its own place in life's great variety of forms. A key insight of modern evolutionary developmental biology is that, by and large, evolution proceeds through modulation of gene regulation, rather than by modulation of the genes themselves. Identifying regulatory sequences in the genomes of model organisms, understanding how they operate to regulate gene expression, and how they have changed in different animal lineages is, therefore, our best way to reconstruct pathways of macroevolution. My research program focuses on the mechanisms of action of Dlx genes (a family of six related transcription factors) and their contributions to evolutionary diversity. The genes themselves are highly conserved across animal species and they function in conserved ways in the brain, limbs, skeleton, and skin of diverse kinds of animals. My research group explores Dlx genes in a variety of these embryonic contexts, most recently in jaw patterning. Experimental loss of Dlx genes in mice and zebrafish, and naturally occurring mutations in humans, confirm that Dlx genes play a conserved role in jaw patterning in very different kinds of vertebrates and point to the likelihood that they participate in regulatory networks of genes that pattern jaws in all vertebrates. We propose to advance our knowledge of jaw development and evolution on three fronts, with Dlx genes as the initial focus. We want to test whether candidate Dlx-regulated genes in mice are directly regulated by Dlx transcription factors in the chick embryo and, if so, what DNA sequences mediate that regulation. Additionally we will identify, in an unbiased way, novel genome binding sites for Dlx proteins in jaw forming tissue in chick embryos and, thereby, the genes regulated by those sequences. We are interested in the functions of these regulatory elements on two different timescales. On the one hand, we want to understand how those elements function in individual chick embryo development in molecular detail. On the other hand, we wish to compare how the regulatory networks are similar and different among diverse kinds of living vertebrates to understand how the networks have changed over evolutionary time. For the latter objective, we will manipulate the sequences of these regulatory elements to understand how they function in the regulation of gene expression in the chick, and ask whether this is the same or different from their functions in mice. This research will advance our knowledge of jaw development in an important model system (the chick) and of gene regulation more broadly. This work will also generate novel tools to improve gene function manipulation in the chicken embryo, which may benefit the Canadian poultry industry.

了解地球上生命的多样性及其起源，几个世纪以来一直占据着人类的思想。事实上，对生物多样性和新型有机体起源的思考，对于一个能够在各种各样的生命形式中协调自己位置的物种来说，具有深刻的意义。现代进化发育生物学的一个关键观点是，总的来说，进化是通过基因调控的调节而不是基因本身的调节来进行的。因此，识别模式生物基因组中的调控序列，了解它们如何调控基因表达，以及它们在不同动物谱系中如何变化，是我们重建宏观进化途径的最佳途径。 我的研究项目主要集中在Dlx基因（一个由六个相关转录因子组成的家族）的作用机制及其对进化多样性的贡献。这些基因本身在动物物种中是高度保守的，它们以保守的方式在各种动物的大脑、四肢、骨骼和皮肤中发挥作用。我的研究小组探索了Dlx基因在各种胚胎环境中的作用，最近的一次是在颌骨模式中。Dlx基因在小鼠和斑马鱼中的实验丢失以及在人类中自然发生的突变证实了Dlx基因在非常不同种类的脊椎动物中的下颌图案中发挥保守作用，并指出它们参与所有脊椎动物中下颌图案的基因调控网络的可能性。 我们建议在三个方面推进我们对颌骨发育和进化的认识，并以Dlx基因为最初的重点。我们想测试小鼠中Dlx调控的候选基因是否直接受鸡胚中Dlx转录因子的调控，如果是的话，是什么DNA序列介导了这种调控。此外，我们将确定，在一个公正的方式，新的基因组结合位点的Dlx蛋白在鸡胚颌骨形成组织，从而，这些序列调控的基因。我们感兴趣的功能，这些监管要素在两个不同的时间尺度。一方面，我们想了解这些元素在单个鸡胚发育中的分子细节。另一方面，我们希望比较不同种类的脊椎动物之间的调节网络是如何相似和不同的，以了解网络如何随着进化而变化。对于后一个目标，我们将操纵这些调控元件的序列，以了解它们如何在鸡的基因表达调控中发挥作用，并询问这与它们在小鼠中的功能是否相同或不同。这项研究将推进我们的知识颌骨发育的一个重要的模型系统（鸡）和基因调控更广泛。这项工作还将产生新的工具，以改善鸡胚胎中的基因功能操作，这可能有利于加拿大家禽业。