Pax2.1 is required for the development of thyroid follicles in zebrafish

The thyroid gland is an organ primarily composed of endoderm-derived follicular cells. Although disturbed embryonic development of the thyroid gland leads to congenital hypothyroidism in humans and mammals, the underlying principles of thyroid organogenesis are largely unknown. In this study, we introduce zebrafish as a model to investigate the molecular and genetic mechanisms that control thyroid development. Marker gene expression suggests that the molecular pathways of early thyroid development are essentially conserved between fish and mammals. However during larval stages, we find both conserved and divergent features of development compared with mammals. A major difference is that in fish, we find evidence for hormone production not only in thyroid follicular cells, but also in an anterior non-follicular group of cells. We show that pax2.1 and pax8, members of the zebrafish pax2/5/8 paralogue group, are expressed in the thyroid primordium. Whereas in mice, only Pax8 has a function during thyroid development, analysis of the zebrafish pax2.1 mutant no isthmus (noi(-/-)) demonstrates that pax2.1 has a role comparable with mouse Pax8 in differentiation of the thyroid follicular cells. Early steps of thyroid development are normal in noi(-/-), but later expression of molecular markers is lost and the formation of follicles fails. Interestingly, the anterior non-follicular site of thyroid hormone production is not affected in noi(-/-). Thus, in zebrafish, some remaining thyroid hormone synthesis takes place independent of the pathway leading to thyroid follicle formation. We suggest that the noi(-/-) mutant serves as a new zebrafish model for hypothyroidism.     

小鼠内耳发育核心转录因子的保守性及调控网络的比较分析

在脊椎动物内耳发育中, Six1、Six4、Pax2、Pax8、Foxi1、Dlx5、Gbx2、Irx2/3、Msx1等基因作为核心调控基因参与听基板的诱导过程。文章通过生物信息学方法, 对小鼠内耳发育的核心转录因子进行保守性分析并研究其相互调控关系, 得到小鼠内耳发育过程中核心转录因子的基因调控网络。与文献中已知的小鼠内耳发育基因调控关系相比, Pax2、Pax8、Foxi1、Dlx5基因在内耳发育中仍然起主要调控者的角色, Six1则处于被多个转录因子调节的地位, Gbx2、Irx2/3、Msx1在调控网络中也起到重要作用。对出现的差异进行了合理的分析, 同时结合构建的调控网络预测了可能存在的Msx1对Six1、Gbx2的调控作用。序列预测结果也发现了一些新的调控关系, 所涉及的转录因子包括Sox5、Lhx2、Rax、Otx1、Otx2、Pitx1、Pitx2、Nkx2-5、Irx4、Irx6、Dlx2、Hmx1/2/3、Pou4f3、Pax4、Tlx2。文章为深入了解内耳发育调控机制提供了基础信息。     

Hoxa3 and pax1 regulate epithelial cell death and proliferation during thymus and parathyroid organogenesis

The thymus and parathyroid glands in mice develop from a thymus/parathyroid primordium that forms from the endoderm of the third pharyngeal pouch. We investigated the molecular mechanisms that promote this unique process in which two distinct organs form from a single primordium, using mice mutant for Hoxa3 and Pax1. Thymic ectopia in Hoxa3(+/-)Pax1(-/-) compound mutants is due to delayed separation of the thymus/parathyroid primordium from the pharynx. The primordium is hypoplastic at its formation, and has increased levels of apoptosis. The developing third pouch in Hoxa3(+/-)Pax1(-/-) compound mutants initiates normal expression of the parathyroid-specific Gcm2 and thymus-specific Foxn1 genes. However, Gcm2 expression is reduced at E11.5 in Pax1(-/-) single mutants, and further reduced or absent in Hoxa3(+/-)Pax1(-/-) compound mutants. Subsequent to organ-specific differentiation from the shared primordium, both the parathyroids and thymus developed defects. Parathyroids in compound mutants were smaller at their formation, and absent at later stages. Parathyroids were also reduced in Pax1(-/-) mutants, revealing a new function for Pax1 in parathyroid organogenesis. Thymic hypoplasia at later fetal stages in compound mutants was associated with increased death and decreased proliferation of thymic epithelial cells. Our results suggest that a Hoxa3-Pax1 genetic pathway is required for both epithelial cell growth and differentiation throughout thymus and parathyroid organogenesis.