靶標解讀IFN-γ
1、簡介
干擾素(IFN)多效性細胞因子家族,根據受體特異性可分為三型:I型(含IFN-α/β等13個亞型,通過IFNAR1/IFNAR2受體傳遞信號)、II型(僅包含IFN-γ,特異性結合IFNGR1/IFNGR2受體)及III型(IFN-λ,依賴IL-10R2/IFNLR1受體發揮作用)[1-2]。IFN-γ是Ⅱ型干擾素的成員,其基因定位于人類染色體12q15區域,包含4個外顯子,其編碼基因在脊椎動物中呈現高度保守性(人鼠氨基酸序列同源性約70%)。編碼的成熟蛋白由143個氨基酸通過鏈間二硫鍵形成功能性同源二聚體,其受體結合域中保守的α螺旋結構對生物活性至關重要[3]。
IFN-γ主要由T淋巴細胞、自然殺傷細胞(NK)和抗原提呈細胞(APCs,包括單核細胞、巨噬細胞和樹突狀細胞)分泌[4-6]。其表達受先天免疫信號的嚴格調控,APCs通過分泌IL-12/IL-18激活STAT4/NF-κB通路,一方面趨化NK細胞向炎癥部位遷移,另一方面直接誘導IFN-γ基因轉錄,形成連接病原識別與適應性免疫啟動的關鍵調控軸[7-9]。
作為免疫微環境的核心調控者,IFN-γ在感染部位呈現爆發式表達特征,其通過激活巨噬細胞殺菌功能、上調MHC分子表達及驅動Th1分化等機制增強宿主防御[10]。同時,該因子在腫瘤免疫中發揮雙重作用:既可誘導腫瘤細胞免疫原性死亡,又能促進免疫檢查點分子(如PD-L1)表達形成負反饋調控[11]。這種功能復雜性與其獨特的信號級聯機制直接相關,IFN-γ通過結合異源二聚體受體(IFNGR1/IFNGR2),觸發JAK1/JAK2-STAT1磷酸化級聯反應,磷酸化STAT1入核后協同IRF家族蛋白,通過結合干擾素刺激反應元件(ISRE)啟動數百種干擾素刺激基因(ISGs)轉錄,形成級聯放大效應。
2、功能或作用機制
1)受體激活與激酶級聯
IFN-γ以同源二聚體形式結合異源二聚體受體IFNGR,誘導受體構象變化。此過程激活受體偶聯的JAK1(結合IFNGR2)和JAK2(結合IFNGR1)酪氨酸激酶,觸發二者相互磷酸化。活化的JAK1進一步磷酸化IFNGR1鏈第440位酪氨酸殘基(Y440),形成兩個相鄰的STAT1蛋白SH2結構域結合位點[12-14]。
2)STAT1磷酸化與復合物組裝
募集至受體的STAT1分子在其C端Y701位點被JAK激酶磷酸化,激活誘導STAT1同源二聚化并從受體解離,同源二聚體進一步激活激活IRF-1(Interferon Regulatory Factor-1,干擾素調節因子-1)及IFN-γ激活序列(GAS),以啟動后續的基因轉錄調控,而少部分受體解離的STAT1會與STAT2及IRF-9形成異源復合物[15-17]。其中,STAT1:STAT1:IRF-9復合物調控經典GAS(IFN-γ-激活序列)響應基因;STAT1:STAT2:IRF-9(ISGF3復合物):靶向ISRE(干擾素刺激反應元件)
3)核轉位與基因轉錄調控
磷酸化Stat1同源二聚體與ISGF3復合物轉位入核,分別結合靶基因啟動子區的GAS和ISRE元件[18]。IRF-1作為次級轉錄因子,進一步擴大調控網絡。此過程激活包括ICAM-1(細胞間黏附分子)、iNOS(誘導型一氧化氮合酶)及IRF家族成員在內的多種干擾素調控基因,形成多層級轉錄放大效應。
3、臨床應用
1)抗感染
IFN-γ作為一種重要的免疫調節因子,在抗感染過程中發揮著關鍵作用。它通過激活巨噬細胞,增強其吞噬和殺傷能力,促進抗原提呈,從而提高機體對病原體的清除效率[20]。此外,IFN-γ還能誘導產生抗菌肽和其他具有直接殺菌作用的分子,進一步加強宿主防御功能。
2)抗腫瘤
IFN-γ在腫瘤免疫監視中占據核心地位,能夠直接抑制腫瘤細胞增殖,并通過多種途徑增強機體的抗腫瘤免疫反應。IFN-γ可以上調MHC I類分子表達,使腫瘤細胞更容易被識別;刺激NK細胞、T細胞等效應細胞的活性;誘導免疫檢查點分子如PD-L1的表達,進而調節腫瘤微環境中的免疫平衡[11,21-22]。
3)自身免疫性疾病
過度活躍的IFN-γ信號可能導致自身免疫性疾病的發生和發展,如系統性紅斑狼瘡(SLE)、多發性硬化癥(MS)等[23-24]。針對IFN-γ信號通路的關鍵節點進行干預,如使用單克隆抗體阻斷IFN-γ與其受體結合,或設計小分子化合物抑制下游信號傳導,可有效控制病情進展,減少并發癥。
4)移植排斥反應
術后,供體與受體之間的HLA(Human Leukocyte Antigen,人類白細胞抗原)差異是引發急性排斥反應的主要原因。IFN-γ在此過程中扮演重要角色,它能增強移植物特異性T細胞的活化,加劇局部炎癥反應,最終導致移植物功能喪失。IFN-γ抑制藥物可下調移植排斥介導的免疫應答。此外,IL-10等具有抗炎效果的細胞因子,可以作為潛在的治療策略,減輕IFN-γ帶來的不利影響[25]。
5)神經退行性疾病
IFN-γ在神經退行性疾病如阿爾茨海默病(AD)、帕金森病(PD)中顯示出復雜的雙重作用。一方面,適度的IFN-γ水平有助于清除β-淀粉樣蛋白沉積物,減緩疾病進程;另一方面,過量的IFN-γ可能會加重神經炎癥,損害神經元結構與功能[26]。針對IFN-γ在神經退行性疾病中的復雜角色,未來的研究需要更加細致地解析其調控網絡,以期找到既能利用其有益效應又能避免不良后果的治療方案。
相關產品
參考文獻
[1] Bazan, J. F. (1990) Structural design and molecular evolution of a cytokine receptor superfamily. Proc. Natl. Acad. Sci. USA 87, 6934– 6938.
[2] Thoreau, E., Petridou, B., Kelly, P. A., Djiane, J., Mornon, J. P. (1991) Structural symmetry of the extracellular domain of the cytokine/growth hormone/prolactin receptor family and interferon receptors revealed by hydrophobic cluster analysis. FEBS Lett. 282, 26–31.
[3] Adolf, G. R. (1985) Structure and effects of interferon-gamma. Oncology 42, 1–10.
[4] Carnaud, C., Lee, D., Donnars, O., Park, S. H., Beavis, A., Koezuka, Y., Bendelac, A. (1999) Cutting edge: cross-talk between cells of the innate immune system: NKT cells rapidly activate NK cells. J. Immunol. 163, 4647–4650.
[5] Frucht, D. M., Fukao, T., Bogdan, C., Schindler, H., O’Shea, J. J., Koyasu, S. (2001) IFN-gamma production by antigen-presenting cells: mechanisms emerge. Trends Immunol. 22, 556–560.
[6] Gessani, S., Belardelli, F. (1998) IFN-gamma expression in macrophages and its possible biological significance. Cytokine Growth Factor Rev. 9,117–123.
[7] Munder, M., Mallo, M., Eichmann, K., Modolell, M. (1998) Murine
macrophages secrete interferon gamma upon combined stimulation with
interleukin (IL)-12 and IL-18: a novel pathway of autocrine macrophage
activation. J. Exp. Med. 187, 2103–2108.
[8] Fukao, T., Matsuda, S., Koyasu, S. (2000) Synergistic effects of IL-4 and IL-18 on IL-12-dependent IFN-gamma production by dendritic cells.
J. Immunol. 164, 64–71.
[9] Schindler, H., Lutz, M. B., Rollinghoff, M., Bogdan, C. (2001) The
production of IFN-gamma by IL-12/IL-18-activated macrophages requires STAT4 signaling and is inhibited by IL-4. J. Immunol. 166,
3075–3082.
[10] Bach, E. A., Szabo, S. J., Dighe, A. S., Ashkenazi, A., Aguet, M., Murphy,K. M., Schreiber, R. D. (1995) Ligand-induced autoregulation of IFNgamma receptor beta chain expression in T helper cell subsets. Science 270, 1215–1218.
[11] Kaplan, D. H., Shankaran, V., Dighe, A. S., Stockert, E., Aguet, M., Old, L. J., Schreiber, R. D. (1998) Demonstration of an interferon gamma dependent tumor surveillance system in immunocompetent mice. Proc. Natl. Acad. Sci. USA 95, 7556–7561.
[12] Greenlund, A.C., Farrar, M.A., Viviano, B.L., Schreiber, R. D. (1994) Ligand-induced IFN gamma receptor tyrosine phosphorylation couples the receptor to its signal transduction system (p91). EMBO J. 13, 1591–1600.
[13] Briscoe, J., Rogers, N. C., Witthuhn, B. A., Watling, D., Harpur, A.G., Wilks, A.F., Stark, G.R. , Ihle , J.N. ,Kerr,I.M. (1996) Kinase-negative mutants of JAK1 can sustain interferon-gamma-inducible gene expression but not an antiviral state. EMBO J. 15, 799–809.
[14] Igarashi, K., Garotta, G., Ozmen, L., Ziemiecki, A., Wilks, A. F., Harpur, A. G., Larner, A. C., Finbloom, D. S. (1994) Interferon-gamma induces tyrosine phosphorylation of interferon-gamma receptor and regulated association of protein tyrosine kinases, Jak1 and Jak2, with its receptor. J. Biol. Chem. 269, 14333–14336.
[15] Darnell Jr., J. E., Kerr, I. M., Stark, G. R. (1994) Jak-STAT pathways and transcriptional activation in response to IFNs and other extracellular signaling proteins. Science 264, 1415–1421.
[16] Schindler, C., Darnell Jr., J. E. (1995) Transcriptional responses to polypeptide ligands: the JAK-STAT pathway. Annu. Rev. Biochem. 64,
621–651.
[17] Ramana, C.V., Chatterjee-Kishore, M., Nguyen, H., Stark, G. R. (2000) Complex roles of Stat1 in regulating gene expression. Oncogene 19, 2619–2627
[18] Paludan, S.R. (1998)Interleukin-4 and interferon-gamma: the quintessence of a mutual antagonistic relationship. Scand. J. Immunol. 48,459–468.
[19] Schroder, K., Hertzog, P. J., Ravasi, T., and Hume, D. A. (2003) Interferon-γ: an overview of signals, mechanisms and functions. J. Leukoc. Biol. 75, 163–189. doi:10.1189/jlb.0603252
[20] Davies, E. G., Isaacs, D., Levinsky, R. J. (1982) Defective immune interferon production and natural killer activity associated with poor neutrophil mobility and delayed umbilical cord separation. Clin. Exp. Immunol. 50, 454–460.
[21] Dighe, A. S., Richards, E., Old, L. J., Schreiber, R. D. (1994) Enhanced in vivo growth and resistance to rejection of tumor cells expressing dominant negative IFN gamma receptors. Immunity 1, 447–456.
[22] Tannenbaum, C. S., Hamilton, T. A. (2000) Immune-inflammatory mechanisms in IFNgamma-mediated anti-tumor activity. Semin. Cancer Biol. 10, 113–123.
[23] Lee, J. Y., Goldman, D., Piliero, L. M., Petri, M., Sullivan, K. E. (2001)Interferon-gamma polymorphisms in systemic lupus erythematosus. Genes Immun. 2, 254–257.
[24] Baechler, E. C., Batliwalla, F. M., Karypis, G., Gaffney, P. M., Ortmann, W. A., Espe, K. J., Shark, K. B., Grande, W. J., Hughes, K. M., Kapur, V., Gregersen, P. K., Behrens, T. W. (2003) Interferon-inducible gene expression signature in peripheral blood cells of patients with severe lupus. Proc. Natl. Acad. Sci. USA 100, 2610–2615.
[25] Soyoz, M., Pehlivan, M., Tatar, E., Cerci, B., Coven, H. I. K., and Ayna, T. K. (2021) Consideration of IL-2, IFN-γ and IL-4 expression and methylation levels in CD4+ T cells as a predictor of rejection in kidney transplant. Transpl. Immunol. 68, 101414. doi:10.1016/j.trim.2021.101414
[26] Baik, S. H., Kang, S., Lee, W., Choi, H., Chung, S., Kim, J.-I., and Mook-Jung, I. (2019) A Breakdown in Metabolic Reprogramming Causes Microglia Dysfunction in Alzheimer's Disease. Cell Metab. 30(3), 493–507. doi:10.1016/j.cmet.2019.06.005