Bui Ai Thu, Lukashova Lyudmila, Verdelis Kostas, Vasquez Brent, Bhogadi Lasya, Gabe Claire M, Margolis Henry C, Beniash Elia
Department of Oral and Craniofacial Sciences, University of Pittsburgh School of Dental Medicine (UPSDM), Pittsburgh, PA, United States.
Center for Craniofacial Regeneration, UPSDM, Pittsburgh, PA, United States.
Front Physiol. 2023 Feb 10;14:1144712. doi: 10.3389/fphys.2023.1144712. eCollection 2023.
Continuously growing mouse incisors are widely used to study amelogenesis, since all stages of this process (., secretory, transition and maturation) are present in a spatially determined sequence at any given time. To study biological changes associated with enamel formation, it is important to develop reliable methods for collecting ameloblasts, the cells that regulate enamel formation, from different stages of amelogenesis. Micro-dissection, the key method for collecting distinct ameloblast populations from mouse incisors, relies on positions of molar teeth as landmarks for identifying critical stages of amelogenesis. However, the positions of mandibular incisors and their spatial relationships with molars change with age. Our goal was to identify with high precision these relationships throughout skeletal growth and in older, skeletally mature animals. Mandibles from 2, 4, 8, 12, 16, and 24-week-old, and 18-month-old C57BL/6J male mice, were collected and studied using micro-CT and histology to obtain incisal enamel mineralization profiles and to identify corresponding changes in ameloblast morphology during amelogenesis with respect to positions of molars. As reported here, we have found that throughout active skeletal growth (weeks 2-16) the apices of incisors and the onset of enamel mineralization move distally relative to molar teeth. The position of the transition stage also moves distally. To test the accuracy of the landmarks, we micro-dissected enamel epithelium from mandibular incisors of 12-week-old animals into five segments, including 1) secretory, 2) late secretory - transition - early maturation, 3) early maturation, 4) mid-maturation and 5) late maturation. Isolated segments were pooled and subjected to expression analyses of genes encoding key enamel matrix proteins (EMPs), , , and , using RT-qPCR. and were strongly expressed during the secretory stage (segment 1), while their expression diminished during transition (segment 2) and ceased in maturation (segments 3, 4, and 5). In contrast, 's expression was very low during secretion and increased dramatically throughout transition and maturation stages. These expression profiles are consistent with the consensus understanding of enamel matrix proteins expression. Overall, our results demonstrate the high accuracy of our landmarking method and emphasize the importance of selecting age-appropriate landmarks for studies of amelogenesis in mouse incisors.
持续生长的小鼠门齿被广泛用于研究釉质形成,因为在任何给定时间,这个过程的所有阶段(即分泌、过渡和成熟阶段)都以空间确定的顺序呈现。为了研究与釉质形成相关的生物学变化,开发可靠的方法从釉质形成的不同阶段收集成釉细胞(即调节釉质形成的细胞)非常重要。显微切割是从小鼠门齿收集不同成釉细胞群体的关键方法,它依赖于磨牙的位置作为识别釉质形成关键阶段的标志。然而,下颌门齿的位置及其与磨牙的空间关系会随着年龄的增长而变化。我们的目标是在整个骨骼生长过程以及骨骼成熟的老年动物中高精度地识别这些关系。收集了2周、4周、8周、12周、16周、24周龄以及18月龄的C57BL/6J雄性小鼠的下颌骨,使用显微CT和组织学进行研究,以获得切牙釉质矿化图谱,并确定在釉质形成过程中相对于磨牙位置的成釉细胞形态的相应变化。如本文所报道,我们发现,在整个活跃的骨骼生长阶段(第2 - 16周),门齿的根尖和釉质矿化的起始相对于磨牙向远中移动。过渡阶段的位置也向远中移动。为了测试这些标志的准确性,我们将12周龄动物下颌门齿的釉质上皮显微切割成五个部分,包括1)分泌期,2)晚期分泌 - 过渡 - 早期成熟期,3)早期成熟期,4)中期成熟期和5)晚期成熟期。将分离的部分合并,使用RT-qPCR对编码关键釉质基质蛋白(EMPs)、、和的基因进行表达分析。和在分泌期(部分1)强烈表达,而在过渡阶段(部分2)其表达减弱,并在成熟期(部分3、4和5)停止表达。相比之下,在分泌期表达非常低,在整个过渡和成熟阶段显著增加。这些表达谱与对釉质基质蛋白表达的共识理解一致。总体而言,我们的结果证明了我们的标志方法的高精度,并强调了为小鼠门齿釉质形成研究选择适合年龄的标志的重要性。
