Li Li, Feng Xu, Yi Han, Jun Zeng, Shan Du, Changshan Wang
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This model allowed us to identify the mechanisms driving age-related changes in the thymic microenvironment and to assess whether these changes could be reversed. Flow cytometry was used to detect naïve T cells (CD62L<sup>+</sup>CD44<sup>-</sup>), including CD4 CD8 double-negative, double-positive, and single-positive T cells. Real-time PCR was used to detect and quantify signal-joint T cell receptor excision circles. We rearranged δRec-ΨJα in murine peripheral blood leukocytes to evaluate the thymic output of newly developed naïve T cells in the mice and gene expression in the thymus. Age-related thymic involution decreased naïve T cells and increased memory T cells, while fetal thymus transplantation improved thymic output and T cell production and reversed the impairment of thymopoiesis due to thymic involution in aged mice. Furthermore, the expression of key cytokines was restored and ETPs in the aged mice showed normal thymic T cell development. Our study suggests that degenerative changes in the thymic microenvironment are the primary cause of thymic dysfunction, leading to immunosenescence associated with age-related thymic involution.</p>","PeriodicalId":13389,"journal":{"name":"Immunologic Research","volume":" ","pages":"1161-1173"},"PeriodicalIF":3.3000,"publicationDate":"2024-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Thymic microenvironment's impact on immunosenescence.\",\"authors\":\"Li Li, Feng Xu, Yi Han, Jun Zeng, Shan Du, Changshan Wang\",\"doi\":\"10.1007/s12026-024-09519-z\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Age-related thymic involution is characterized by the loss of T cell development and the supporting epithelial network, which are replaced by adipose tissue. We previously showed that aging functionally impairs lymphohematopoietic progenitor cells, including thymic early T cell progenitors (ETPs), contributing to thymic involution. Considering that the thymic microenvironment is essential for thymocyte incubation, we aimed to investigate its role in age-related thymic involution and the mechanisms underlying these changes. The challenge in studying these processes led us to transplant T cell-depleted fetal thymus tissue into the kidney capsule of aged mice. This model allowed us to identify the mechanisms driving age-related changes in the thymic microenvironment and to assess whether these changes could be reversed. Flow cytometry was used to detect naïve T cells (CD62L<sup>+</sup>CD44<sup>-</sup>), including CD4 CD8 double-negative, double-positive, and single-positive T cells. Real-time PCR was used to detect and quantify signal-joint T cell receptor excision circles. We rearranged δRec-ΨJα in murine peripheral blood leukocytes to evaluate the thymic output of newly developed naïve T cells in the mice and gene expression in the thymus. Age-related thymic involution decreased naïve T cells and increased memory T cells, while fetal thymus transplantation improved thymic output and T cell production and reversed the impairment of thymopoiesis due to thymic involution in aged mice. Furthermore, the expression of key cytokines was restored and ETPs in the aged mice showed normal thymic T cell development. 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引用次数: 0
摘要
与年龄相关的胸腺萎缩的特点是 T 细胞发育和支持性上皮网络的丧失,这些都被脂肪组织所取代。我们以前的研究表明,衰老会损害淋巴造血祖细胞的功能,包括胸腺早期T细胞祖细胞(ETPs),从而导致胸腺萎缩。考虑到胸腺微环境对胸腺细胞的孵化至关重要,我们旨在研究它在与年龄相关的胸腺萎缩中的作用以及这些变化的机制。研究这些过程所面临的挑战促使我们将T细胞贫化的胎儿胸腺组织移植到老年小鼠的肾囊中。这种模型使我们能够确定胸腺微环境与年龄相关变化的驱动机制,并评估这些变化是否可以逆转。流式细胞术用于检测幼稚T细胞(CD62L+CD44-),包括CD4 CD8双阴性、双阳性和单阳性T细胞。实时 PCR 用于检测和量化信号接头 T 细胞受体切割圈。我们重新排列了小鼠外周血白细胞中的δRec-ΨJα,以评估小鼠胸腺中新发育的幼稚T细胞的输出量和胸腺中的基因表达。与年龄相关的胸腺内陷减少了幼稚T细胞,增加了记忆T细胞,而胎儿胸腺移植改善了胸腺输出和T细胞生成,并逆转了因胸腺内陷导致的胸腺造血功能障碍。此外,关键细胞因子的表达得到恢复,老年小鼠的 ETPs 显示胸腺 T 细胞发育正常。我们的研究表明,胸腺微环境的退行性变化是胸腺功能障碍的主要原因,它导致了与年龄相关的胸腺内陷引起的免疫衰老。
Thymic microenvironment's impact on immunosenescence.
Age-related thymic involution is characterized by the loss of T cell development and the supporting epithelial network, which are replaced by adipose tissue. We previously showed that aging functionally impairs lymphohematopoietic progenitor cells, including thymic early T cell progenitors (ETPs), contributing to thymic involution. Considering that the thymic microenvironment is essential for thymocyte incubation, we aimed to investigate its role in age-related thymic involution and the mechanisms underlying these changes. The challenge in studying these processes led us to transplant T cell-depleted fetal thymus tissue into the kidney capsule of aged mice. This model allowed us to identify the mechanisms driving age-related changes in the thymic microenvironment and to assess whether these changes could be reversed. Flow cytometry was used to detect naïve T cells (CD62L+CD44-), including CD4 CD8 double-negative, double-positive, and single-positive T cells. Real-time PCR was used to detect and quantify signal-joint T cell receptor excision circles. We rearranged δRec-ΨJα in murine peripheral blood leukocytes to evaluate the thymic output of newly developed naïve T cells in the mice and gene expression in the thymus. Age-related thymic involution decreased naïve T cells and increased memory T cells, while fetal thymus transplantation improved thymic output and T cell production and reversed the impairment of thymopoiesis due to thymic involution in aged mice. Furthermore, the expression of key cytokines was restored and ETPs in the aged mice showed normal thymic T cell development. Our study suggests that degenerative changes in the thymic microenvironment are the primary cause of thymic dysfunction, leading to immunosenescence associated with age-related thymic involution.
期刊介绍:
IMMUNOLOGIC RESEARCH represents a unique medium for the presentation, interpretation, and clarification of complex scientific data. Information is presented in the form of interpretive synthesis reviews, original research articles, symposia, editorials, and theoretical essays. The scope of coverage extends to cellular immunology, immunogenetics, molecular and structural immunology, immunoregulation and autoimmunity, immunopathology, tumor immunology, host defense and microbial immunity, including viral immunology, immunohematology, mucosal immunity, complement, transplantation immunology, clinical immunology, neuroimmunology, immunoendocrinology, immunotoxicology, translational immunology, and history of immunology.