RAN轉譯
亨丁頓舞蹈症 病患的Htt RAN轉譯 全稱為重複區關聯的非AUG轉譯 (英語:Repeat Associated Non-AUG translation ),是真核生物 細胞 中一種異常的mRNA 轉譯 機制,發生在具簡單重複序列 (微衛星)的mRNA 上,不需起始密碼子 AUG即可轉譯重複序列,產生由一或兩種(少數案例為數種)胺基酸 組成的重複蛋白。此轉譯機制最早於2011年在第八型小腦萎縮症 (SCA8)與第一型強直性肌肉失養症 (DM1)患者中發現[ 1] [ 2] 亨丁頓舞蹈症 及肌萎缩性脊髓侧索硬化症 等數種神經退化性疾病 患者的某些基因中皆有三核苷酸重复序列扩增 ,在神經組織中由RAN轉譯生成重複蛋白,可能與其致病原因有關。目前對RAN轉譯的詳細過程與調控機制尚不清楚。
絕大多數的真核轉譯 是始於起始密碼子 AUG,其中多數依賴5′端帽 (少數病毒mRNA則是使用內部核糖體進入位點 ),轉譯起始時eIF4F 複合體與mRNA的5′端帽結合,核糖體小次單元 tRNA 及eIF1 等蛋白組成43S前起始複合物 ,並從mRNA的5′往3′掃描,直到發現AUG後開始轉譯[ 3] 簡單重複序列 (微衛星)的mRNA,不使用AUG作為起始密碼子,可能自重複序列 上游近似AUG的密碼子(如CUG)起始,也可能自重複序列開始轉譯[ 4] 開放閱讀框 ,可產生多種可能對細胞具毒性的單胺基酸重複蛋白或二肽重复蛋白(DPR)[ 5] 5′非轉譯區 、編碼區 或內含子 中[ 6] mRNA (反義RNA ),且兩者的重複序列均能以所有開放閱讀框進行RAN轉譯,因此最多能產生6種重複蛋白[ 7] 酵母菌 也可進行RAN轉譯[ 8]
許多神經退化性疾病 與基因中微衛星 序列重複數異常有關,通稱三核苷酸重复序列疾病 [ 4] [ 9] 二級結構 有關[ 6] 整合应激反应 [ 4] 核糖體蛋白 RPS25 [ 8] FMR1 上游開放閱讀框 (uORF)的功能[ 10]
RAN轉譯已在數種神經退化性疾病患者中發現,包括第八型小腦萎縮症(SCA8)患者ATXN8 ATXN8OS 額顳葉失智症 (FTD)與肌萎缩性脊髓侧索硬化症 (ALS)患者C9ORF72 DMPK基因 基因的CTG重複與DM1-AS的CAG重複、第二型強直性肌肉失養症(DM2)患者CNBP 亨丁頓舞蹈症 患者Htt1 HTT-AS1 福斯氏角膜內皮失養症 TCF4 [ 4]
C9ORF72
人類神經組織中表現的C9ORF72 [ 11] [ 12] 突變 而具有上百個短重複序列[ 13] 額顳葉失智症 (FTD)或肌萎缩性脊髓侧索硬化症 (ALS),其致病機制可能為影響和一些蛋白 甘氨酸 -丙氨酸 (poly GA)、多甘氨酸-脯氨酸 (poly GP)、多甘氨酸-精氨酸 (poly GR)等,可能在神經元中具有毒性而致病[ 14] [ 15] [ 16] [ 4] G-四聯體 介導的轉譯連讀 內含子 中有一個上游開放閱讀框(uORF)可抑制RAN轉譯[ 17]
X染色體脆折症運動失調症候群 FMR1 [ 18] [ 19] [ 20]
亨丁頓舞蹈症是Htt1基因中的CAG重複序列擴增造成,可以所有開放閱讀框進行RAN轉譯產生多麩醯胺酸 、多丙氨酸和多絲氨酸 三種重複蛋白,且與其互補的DNA也會轉錄成mRNA(具CUG重複序列),亦可以所有開放閱讀框進行RAN轉譯產生多白胺酸 、多半胱氨酸 和多丙氨酸等三種重複蛋白,具突變的老鼠模型 顯示這些重複蛋白在前額葉 和小腦 的腦區累積,可能造成神經發炎 等損傷[ 21]
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