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。     

Ash2l-1调控小鼠卵黄囊早期造血

作为甲基转移酶MLL/SET1复合体的核心成分之一,ASH2L能够促进组蛋白H3K4me3修饰的形成,并在小鼠早期胚胎发育过程中行使重要功能.在小鼠中,由于启动子的选择性使用,Ash2l会转录成两种不同长度的转录本并形成两种蛋白质亚型:ASH2L-1和ASH2L-2.目前有关该基因在小鼠胚胎发育中的作用机制及不同亚型的功能还不清楚.本文利用CRISPR/Cas9技术特异敲除Ash2l-1并研究该亚型的生理学功能.研究结果发现,当Ash2l-1缺失时,小鼠胚胎在E9.5~E10.5时发生致死.特别是Ash2l-1-/-E9.5胚胎的卵黄囊血管和早期造血发育存在明显缺陷.转录组测序结果显示,Ash2l-1的缺失影响红细胞发育和成熟、血管发生和形成相关基因的表达.H3K4me3的CUT&RUN结果显示,在一些表达下调关键基因的启动子区,H3K4me3修饰水平出现下降.以上结果表明,Ash2l-1在小鼠卵黄囊的早期造血和血管形成过程中是必不可少的,它可能是通过调控关键基因启动子区的H3K4me3修饰水平而控制这些基因的表达,从而在相关过程中行使功能.     

qPCR array检测分析 C57BL/6小鼠胚胎后肢发育基因表达谱

目的:胚胎生育过程中因肢体发育异常造成的出生缺陷比率不低,其相关基因表达模式尚不明确。本实验通过建立实时定量PCR芯片(Real-time quantitative polymerasechain reaction array,qPCR array)检测方案,研究C57BL/6品系小鼠后肢发育相关基因的表达谱。方法:以同源异形盒基因家族(Hox)、Wnt5a、配对同源结构域基因(Pitx1)、成纤维生长因子(Fgf8)、音猬因子(Shh)等小鼠肢体发育相关的重要基因制作基因检测表达谱,以C57BL/6品系怀孕雌鼠为材料,取胚胎肢芽发育的四个关键时期(E10.5,E11.5,E12.5,E13.5)的胎鼠后肢,利用qPCR array方案检测表达谱中基因的相对表达水平差异。结果:通过已建立的qPCR array检测了C57BL/6品系小鼠胚胎后肢发育时期Hox家族、Wnt5a、Pitx1、Fgf8、Shh等基因的表达差异。以E10.5为对照,检测出在后肢发育时期基因呈三种表达模式,即Hoxb6、Hoxb8、Hoxc8、Hoxc9、Hoxc10、Hoxd9和Shh基因的表达水平呈上调;Hoxa11、Hoxa13、Hoxc12、Hoxc13、Hoxd13等基因表达出现下调;Hoxc9、Hoxc10、Hoxc11、Hoxd9、Hoxd12、Fgf8和Pitx1等基因的相对表达量呈先上调后下调的曲线表达模式,且有少部分基因在小鼠后肢发育时期表达水平无明显变化。结论:Hox家族、Wnt5a、Pitx1、Fgf8、Shh等基因在小鼠后肢发育时期表达,并且表达模式存在明显差异。     

Msx1重新分布Ezh2和H3K27me3到细胞核核周具有细胞类型特异性

细胞核内部的空间排布并不是随机的,而是高度动态且具细胞特异性的。在发育过程中,序列特异性的转录调控因子和表观遗传修饰因子的协同作用及其核定位与基因的表达调控密切相关。我们前期研究发现,在成肌细胞中,同源异型框蛋白Msx1通过重新分布Ezh2复合物和抑制标记H3K27me3到细胞核核周来调控靶标基因的表达,从而抑制成肌细胞的分化。这种机制是成肌细胞所特有的,还是Msx1在抑制非成肌细胞分化时也会重新分布Ezh2复合物和转录抑制性标记H3K27me3到细胞核核周,目前还不清楚。在发育过程中,Msx1可以抑制乳腺上皮细胞HC11和成骨细胞BMP2T3的分化,因此我们选取了这两种非成肌细胞做进一步探究。我们发现,在这两种非肌肉细胞中,Msx1虽也富集在细胞核核周,却并不能重新分布Ezh2和转录抑制性标记H3K27me3到细胞核核周。我们的研究表明Msx1重新分布Ezh2和抑制性标记H3K27me3到细胞核核周具有细胞类型特异性。提示我们,Msx1可能是通过不同的分子机制来调控不同类型细胞的分化。     

小鼠胚胎发育过程中Brachyury对Wnt信号通路的作用研究

Brachyury对调控小鼠胚胎发育起着至关重要的作用,缺乏Brachyury蛋白的小鼠胚胎不能正常发育。Wnt信号通路在小鼠胚胎发育中可控制胚胎的轴向发育等重要的生理过程,Brachyury可能通过与Wnt信号通路的相互作用导致短尾表型的产生。为了揭示Brachyury与Wnt信号通路相互作用关系,本研究制作了Brachyury突变小鼠,通过提取不同时期的胚胎并提取总RNA,经反转录进行qPCR检测Brachyury与Wnt信号通路相关成分的表达关系。结果显示,Brachyury、Axin2、Dkk1及Wnt3a的表达在突变胚胎和野生胚胎中的表达有显著差异。因此,Brachyury作为转录因子对上述Wnt信号通路成分的表达有调节作用,它们形成一个调控网络调控小鼠胚胎的正常发育。本研究为小鼠胚胎发育期间Brachyury (T)的功能作用提供了理论基础。     

miR-181在人类疾病中的研究进展

miRNA-181是一个进化中极其保守的明星分子.在人类基因组中,miR-181家族成员包括miR-181a-1、miR-181a-2、miR-181b-2、miR-181b-2、miR-181c和miR-181d.miR-181最早是在小鼠B淋巴细胞中发现其特异高表达,且能调控早期造血系统的形成,从而引起了人们的关注.miR-181在小鼠胸腺、脑、肺等器官中高表达,骨髓和脾脏中也可检测到它的存在,而在造血前体细胞中低表达.其中,miR-181a被认为参与B细胞的分化成熟过程.其后,大量研究证实miR-181是一个重要的基因表达调控因子,功能涉及生物体免疫、炎症,细胞周期调控、细胞凋亡及分化等病理生理过程.另一方面miR-181在多种肿瘤中表达异常,包括白血病、神经母细胞瘤、神经胶质瘤等,但其功能及调控机制不太清楚.本文就miR-181分子的基因结构、基因表达与调控、生物学功能以及与疾病发生的相关性作一综述.     

caveolin-1 mRNA在小鼠牙发育过程中的表达

目的:检测caveolin-1基因mRNA在小鼠牙发育不同时期间充质细胞中的表达,初步探讨caveolin-1在小鼠牙胚发育过程中的作用。方法:以E9.5第一鳃弓间充质细胞及E16.5下颌第一磨牙牙胚细胞作为研究发育机制的模型,应用RT-PCR技术检测caveolin-1 mRNA的表达。结果:caveolin-1 mRNA在两种细胞中均有表达,其在牙胚细胞中的表达水平高于第一鳃弓间充质细胞。结论:caveolin-1可能在牙发育过程中发挥作用。     

人类的性别与性别畸形

从细胞遗传学和分子遗传学的角度阐述了人类性别的形成机理和性别畸形的致病机理。人类性别的形成是以SRY基因为主导的、多基因参与和调控的、有序表达的生理过程。性别畸形的形成是由于性染色体数目或结构异常、与性别形成有关的基因缺失、突变或与其表达调控相关的其他基因突变所致。     

微管蛋白亚型及其功能

微管是真核细胞构成细胞骨架的主要成分,由α/β微管蛋白组装而成。微管在细胞多种活动中发挥着重要的作用,其功能主要受微管结合蛋白、微管蛋白的翻译后修饰以及微管蛋白亚型的调控。已有研究发现,α/β微管蛋白存在多种亚型,微管蛋白亚型在不同组织以及发育过程中的表达模式差异较大。多种微管蛋白亚型基因的突变可以引起神经系统疾病。该文综述了微管蛋白亚型的研究进展,尤其在微管功能调控、神经系统发育及其相关疾病中的作用。     

ELF5在正常乳腺发育和乳腺肿瘤发生中的作用

ELF5(E74-like factor 5)也被称为ESE2,属于ETS(E-twenty-six)转录因子家族成员之一,它在调控胚胎发育以及乳腺组织发育中起到重要作用。在桑椹胚时期,ELF5在调控胚胎内细胞团向胚胎形成过程中或是在胎盘发育的细胞命运决定中起到关键作用。在哺乳动物正常乳腺发育中,ELF5可通过诱导细胞定向分化而获得孕期乳腺分泌细胞类型,从而调控乳腺干/祖细胞的命运。在人类乳腺癌中,ELF5是诱导乳腺肿瘤细胞由表达雌激素受体阳性(ER+)的luminal亚型向表达雌激素受体阴性(ER-)的basal亚型转化的一个关键调控因子,并抑制细胞获得雌激素敏感表型。现主要综述了ELF5的结构特点、功能以及其在哺乳动物乳腺发育中的调控作用。     

Transgenically ectopic expression of Bmp4 to the Msx1 mutant dental mesenchyme restores downstream gene expression but represses Shh and Bmp2 in the enamel knot of wild type tooth germ

Bmp4 is a downstream gene of Msx1 in early mouse tooth development. In this study, we introduced the Msx1-Bmp4 transgenic allele to the Msx1 mutants in which tooth development is arrested at the bud stage in an effort of rescuing Msx1 mutant tooth phenotype in vivo. Ectopic expression of a Bmp4 transgene driven by the mouse Msx1promoter in the dental mesenchyme restored the expression of Lef-1 and Dlx2 but neither Fgf3 nor syndecan-1 in the Msx1 mutant molar tooth germ. The mutant phenotype of molar but not incisor could be partially rescued to progress to the cap stage. The Msx1-Bmp4 transgene was also able to rescue the alveolar processes and the neonatal lethality of the Msx1 mutants. In contrast, overexpression of Bmp4 in the wild type molar mesenchyme down-regulated Shh and Bmp2 expression in the enamel knot, the putative signaling center for tooth patterning, but did not produce a tooth phenotype. These results indicate that Bmp4 can bypass Msx1 function to partially rescue molar tooth development in vivo, and to support alveolar process formation. Expression of Shh and Bmp2 in the enamel knot may not represent critical signals for tooth patterning.     

Regulation of proliferation in developing human tooth germs by MSX homeodomain proteins and cyclin-dependent kinase inhibitor p19INK4d

Before the secretion of hard dental tissues, tooth germs undergo several distinctive stages of development (dental lamina, bud, cap and bell). Every stage is characterized by specific proliferation patterns, which is regulated by various morphogens, growth factors and homeodomain proteins. The role of MSX homeodomain proteins in odontogenesis is rather complex. Expression domains of genes encoding for murine Msx1/2 during development are observed in tissues containing highly proliferative progenitor cells. Arrest of tooth development in Msx knockout mice can be attributed to impaired proliferation of progenitor cells. In Msx1 knockout mice, these progenitor cells start to differentiate prematurely as they strongly express cyclin-dependent kinase inhibitor p19^INK4d. p19^INK4d induces terminal differentiation of cells by blocking the cell cycle in mitogen-responsive G1 phase. Direct suppression of p19^INK4d by Msx1 protein is, therefore, important for maintaining proliferation of progenitor cells at levels required for the normal progression of tooth development. In this study, we examined the expression patterns of MSX1, MSX2 and p19^INK4d in human incisor tooth germs during the bud, cap and early bell stages of development. The distribution of expression domains of p19^INK4d throughout the investigated period indicates that p19^INK4d plays active role during human tooth development. Furthermore, comparison of expression domains of p19^INK4d with those of MSX1, MSX2 and proliferation markers Ki67, Cyclin A2 and pRb, indicates that MSX-mediated regulation of proliferation in human tooth germs might not be executed by the mechanism similar to one described in developing tooth germs of wild-type mouse.     

A new function of BMP4: dual role for BMP4 in regulation of Sonic hedgehog expression in the mouse tooth germ

The murine tooth development is governed by sequential and reciprocal epithelial-mesenchymal interactions. Multiple signaling molecules are expressed in the developing tooth germ and interact each other to mediate the inductive tissue interactions. Among them are Sonic hedgehog (SHH), Bone Morphogenetic Protein-2 (BMP2) and Bone Morphogenetic Protein-4 (BMP4). We have investigated the interactions between these signaling molecules during early tooth development. We found that the expression of Shh and Bmp2 is downregulated at E12.5 and E13.5 in the dental epithelium of the Msx1 mutant tooth germ where Bmp4 expression is significantly reduced in the dental mesenchyme. Inhibition of BMP4 activity by noggin resulted in repression of Shh and Bmp2 in wild-type dental epithelium. When implanted into the dental mesenchyme of Msx1 mutants, beads soaked with BMP4 protein were able to restore the expression of both Shh and Bmp2 in the Msx1 mutant epithelium. These results demonstrated that mesenchymal BMP4 represents one component of the signal acting on the epithelium to maintain Shh and Bmp2 expression. In contrast, BMP4-soaked beads repressed Shh and Bmp2 expression in the wild-type dental epithelium. TUNEL assay indicated that this suppression of gene expression by exogenous BMP4 was not the result of an increase in programmed cell death in the tooth germ. Ectopic expression of human Bmp4 to the dental mesenchyme driven by the mouse Msx1 promoter restored Shh expression in the Msx1 mutant dental epithelium but repressed Shh in the wild-type tooth germ in vivo. We further demonstrated that this regulation of Shh expression by BMP4 is conserved in the mouse developing limb bud. In addition, Shh expression was unaffected in the developing limb buds of the transgenic mice in which a constitutively active Bmpr-IB is ectopically expressed in the forelimb posterior mesenchyme and throughout the hindlimb mesenchyme, suggesting that the repression of Shh expression by BMP4 may not be mediated by BMP receptor-IB. These results provide evidence for a new function of BMP4. BMP4 can act upstream to Shh by regulating Shh expression in mouse developing tooth germ and limb bud. Taken together, our data provide insight into a new regulatory mechanism for Shh expression, and suggest that this BMP4-mediated pathway in Shh regulation may have a general implication in vertebrate organogenesis.     

A nonsense mutation in MSX1 causes Witkop syndrome

Witkop syndrome, also known as tooth and nail syndrome (TNS), is a rare autosomal dominant disorder. Affected individuals have nail dysplasia and several congenitally missing teeth. To identify the gene responsible for TNS, we used candidate-gene linkage analysis in a three-generation family affected by the disorder. We found linkage between TNS and polymorphic markers surrounding the MSX1 locus. Direct sequencing and restriction-enzyme analysis revealed that a heterozygous stop mutation in the homeodomain of MSX1 cosegregated with the phenotype. In addition, histological analysis of Msx1-knockout mice, combined with a finding of Msx1 expression in mesenchyme of developing nail beds, revealed that not only was tooth development disrupted in these mice, but nail development was affected as well. Nail plates in Msx1-null mice were defective and were thinner than those of their wild-type littermates. The resemblance between the tooth and nail phenotype in the human family and that of Msx1-knockout mice strongly supports the conclusions that a nonsense mutation in MSX1 causes TNS and that Msx1 is critical for both tooth and nail development.     

Cranial neural crest-derived mesenchymal proliferation is regulated by Msx1-mediated p19(INK4d) expression during odontogenesis

Neural crest cells are multipotential progenitors that contribute to various cell and tissue types during embryogenesis. Here, we have investigated the molecular and cellular mechanism by which the fate of neural crest cell is regulated during tooth development. Using a two- component genetic system for indelibly marking the progeny of neural crest cells, we provide in vivo evidence of a deficiency of CNC-derived dental mesenchyme in Msx1 null mutant mouse embryos. The deficiency of the CNC results from an elevated CDK inhibitor p19(INK4d) activity and the disruption of cell proliferation. Interestingly, in the absence of Msx1, the CNC-derived dental mesenchyme misdifferentiates and possesses properties consistent with a neuronal fate, possibly through a default mechanism. Attenuation of p19(INK4d) in Msx1 null mutant mandibular explants restores mitotic activity in the dental mesenchyme, demonstrating the functional significance of Msx1-mediated p19(INK4d) expression in regulating CNC cell proliferation during odontogenesis. Collectively, our results demonstrate that homeobox gene Msx1 regulates the fate of CNC cells by controlling the progression of the cell cycle. Genetic mutation of Msx1 may alternatively instruct the fate of these progenitor cells during craniofacial development.     

Rescue of cleft palate in Msx1-deficient mice by transgenic Bmp4 reveals a network of BMP and Shh signaling in the regulation of mammalian palatogenesis

Cleft palate, the most frequent congenital craniofacial birth defects in humans, arises from genetic or environmental perturbations in the multi-step process of palate development. Mutations in the MSX1 homeobox gene are associated with non-syndromic cleft palate and tooth agenesis in humans. We have used Msx1-deficient mice as a model system that exhibits severe craniofacial abnormalities, including cleft secondary palate and lack of teeth, to study the genetic regulation of mammalian palatogenesis. We found that Msx1 expression was restricted to the anterior of the first upper molar site in the palatal mesenchyme and that Msx1 was required for the expression of Bmp4 and Bmp2 in the mesenchyme and Shh in the medial edge epithelium (MEE) in the same region of developing palate. In vivo and in vitro analyses indicated that the cleft palate seen in Msx1 mutants resulted from a defect in cell proliferation in the anterior palatal mesenchyme rather than a failure in palatal fusion. Transgenic expression of human Bmp4 driven by the mouse Msx1 promoter in the Msx1(-/-) palatal mesenchyme rescued the cleft palate phenotype and neonatal lethality. Associated with the rescue of the cleft palate was a restoration of Shh and Bmp2 expression, as well as a return of cell proliferation to the normal levels. Ectopic Bmp4 appears to bypass the requirement for Msx1 and functions upstream of Shh and Bmp2 to support palatal development. Further in vitro assays indicated that Shh (normally expressed in the MEE) activates Bmp2 expression in the palatal mesenchyme which in turn acts as a mitogen to stimulate cell division. Msx1 thus controls a genetic hierarchy involving BMP and Shh signals that regulates the growth of the anterior region of palate during mammalian palatogenesis. Our findings provide insights into the cellular and molecular etiology of the non-syndromic clefting associated with Msx1 mutations.