School of Pharmacy, University of Otago, Dunedin, New Zealand.
J Clin Endocrinol Metab. 2011 Dec;96(12):E2072-7. doi: 10.1210/jc.2011-0463. Epub 2011 Oct 5.
Congenic NOD.ABH(D18Mit8-D18Mit214) mice, which contain greater than 12.8 Mb of DNA encompassing Idd21.1 from diabetes-resistant Biozzi/ABH mice, have a lower frequency of diabetes compared with the parental nonobese diabetic (NOD) strain, possibly due to reduced pathogenicity of β-islet-infiltrating immune cells.
The objective of the study was to identify an Idd21.1 candidate gene.
The methods used in the study were adoptive transfer into scid mice lacking an adaptive immune system; dendritic cell phenotyping and gene expression analysis; and fine-mapping Idd21.1 by congenic mapping.
Diabetes incidences of NOD.scid.ABH(D18Mit8-D18Mit214) mice receiving splenocytes from NOD and NOD.ABH(D18Mit8-D18Mit214) were similar to that previously observed in NOD.scid recipients, suggesting that the diabetes resistance in NOD.ABH(D18Mit8-D18Mit214) is primarily mediated by the adaptive immune system, findings supported by adoptive transfer of CD4(+) T cells. In activated dendritic cells, there were no conclusive differences in cytokine profiles and activation marker expression. However, microarray analysis comparing gene expression between activated dendritic cells from NOD and NOD.ABH (D18Mit8-D18Mit214) revealed that Smad2, in a maximal 6.5-Mb region to which Idd21.1 was further resolved by congenic mapping, was differentially expressed (increased in NOD). Quantitative real-time PCR confirmed the differential expression of Smad2, and other genes in the TGF-β signaling pathway, in activated dendritic cells.
These results implicate Smad2 as an Idd21.1 candidate and Smad2 and the TGF-β signaling pathway in activated dendritic cells in diabetogenesis. With suggestive evidence from human genome-wide association studies supporting a role for SMAD7 in human type 1 diabetes, a comprehensive genetic investigation of the SMAD genes in type 1 diabetes is warranted.
含有大于 12.8Mb 的 DNA 的同源 NOD.ABH(D18Mit8-D18Mit214) 小鼠,包含来自糖尿病抗性 Biozzi/ABH 小鼠的 Idd21.1,与非肥胖型糖尿病 (NOD) 亲本品系相比,糖尿病的发病率较低,这可能是由于β胰岛浸润免疫细胞的致病性降低。
本研究的目的是鉴定 Idd21.1 候选基因。
本研究采用的方法是将缺乏适应性免疫系统的 scid 小鼠进行过继转移;树突状细胞表型和基因表达分析;通过同源性作图对 Idd21.1 进行精细作图。
接受来自 NOD 和 NOD.ABH(D18Mit8-D18Mit214) 的脾细胞的 NOD.scid.ABH(D18Mit8-D18Mit214) 小鼠的糖尿病发病率与之前在 NOD.scid 受体中观察到的相似,这表明 NOD.ABH(D18Mit8-D18Mit214) 的糖尿病抗性主要由适应性免疫系统介导,这一发现得到了 CD4(+)T 细胞过继转移的支持。在激活的树突状细胞中,细胞因子谱和激活标志物表达没有明显差异。然而,对来自 NOD 和 NOD.ABH(D18Mit8-D18Mit214)的激活树突状细胞之间的基因表达进行微阵列分析表明,Smad2 在进一步通过同源性作图解析的 Idd21.1 的最大 6.5Mb 区域中差异表达(在 NOD 中增加)。定量实时 PCR 证实 Smad2 及其在 TGF-β 信号通路中的其他基因在激活的树突状细胞中的差异表达。
这些结果表明 Smad2 是 Idd21.1 的候选基因,Smad2 和 TGF-β 信号通路在激活的树突状细胞中参与了糖尿病的发生。人类全基因组关联研究提供了 SMAD7 在人类 1 型糖尿病中的作用的提示性证据,因此有必要对 1 型糖尿病中的 SMAD 基因进行全面的遗传研究。
