Ortman Crystal L, Dittmar Kimberly A, Witte Pamela L, Le Phong T
Department of Cell Biology, Neurobiology and Anatomy, and the Program in Immunology and Aging, Loyola University Chicago, Maywood, IL 60153, USA.
Int Immunol. 2002 Jul;14(7):813-22. doi: 10.1093/intimm/dxf042.
Despite playing a critical role in the development of naive T cells, the thymus is involuted with age. Whether a single age-associated defect or multiple aberrations contribute to thymic involution remains controversial. Here, we determined molecular aberrations in the thymocyte and epithelium compartments of the aging thymus. We demonstrated that total thymocyte numbers declined with a stepwise kinetics; clear demarcations occurred at 1.5, 3, 12 and 22 months of age. By quantitative PCR, a 2.4-fold reduction in the copies of signal joint TCR-excised circle (sjTREC)/10(5) thymocytes was first detected at 3 months; no further reduction observed thereafter. Nevertheless, the combined reductions in thymocyte numbers and sjTREC/10(5) cells caused a 7-fold decrease in sjTREC/thymus by 3 months, 21-fold by 18 months and 72-fold by 22 months as compared to 1 month. We showed aberration in expression of E2A, a transcription regulator critical for TCR beta rearrangement. While E2A expression declined 3-fold by 3 months and 18-fold by 7 months, expression of LMO2, a negative regulator of E2A activities, increased 5-fold by 18 months. Interestingly, expression of pre-T alpha and its transcriptional regulator HEB were not reduced with age. Furthermore, keratin-8 expression, specific for cortical thymic epithelium, declined 3-fold by 7 months and remained stable thereafter. In contrast, Foxn1 expression was reduced 3-fold by 3 months, 16-fold by 12 months and 37-fold by 18 months. IL-7 expression was not reduced until 7 months and reached 15-fold reduction by 22 months. Thus, the data demonstrate that thymic involution results not from a single defect, but culminates from an array of molecular aberrations in both the developing thymocytes and thymic epithelials.
尽管胸腺在初始T细胞的发育中起着关键作用,但它会随着年龄的增长而退化。胸腺退化是由单一的与年龄相关的缺陷还是多种异常共同导致的,这一问题仍存在争议。在此,我们确定了衰老胸腺中胸腺细胞和上皮细胞区室的分子异常。我们证明,胸腺细胞总数呈逐步下降的动力学变化;在1.5、3、12和22月龄时出现明显的分界。通过定量PCR,在3月龄时首次检测到信号接头TCR切除环(sjTREC)/10⁵胸腺细胞的拷贝数减少了2.4倍;此后未观察到进一步减少。然而,与1月龄相比,胸腺细胞数量和sjTREC/10⁵细胞的综合减少导致3月龄时sjTREC/胸腺减少7倍,18月龄时减少21倍,22月龄时减少72倍。我们发现E2A(一种对TCRβ重排至关重要的转录调节因子)的表达存在异常。E2A的表达在3月龄时下降了3倍,在7月龄时下降了18倍,而E2A活性的负调节因子LMO2的表达在18月龄时增加了5倍。有趣的是,前Tα及其转录调节因子HEB的表达并未随年龄增长而降低。此外,皮质胸腺上皮特异性的角蛋白8表达在7月龄时下降了3倍,此后保持稳定。相比之下,Foxn1的表达在3月龄时下降了3倍,在12月龄时下降了16倍,在18月龄时下降了37倍。IL-7的表达直到7月龄才开始降低,在22月龄时降低了15倍。因此,数据表明胸腺退化并非由单一缺陷导致,而是发育中的胸腺细胞和胸腺上皮细胞中一系列分子异常共同作用的结果。
