合成聚合物形成所需的納米盤的方法介紹
合成納米盤是小尺寸的盤狀結構體,由細胞膜磷脂組成,而磷脂則通過合成聚合物環結合在一起。
有幾種不同的聚合物可用于制造合成納米盤,各有其優缺點。
合成聚合物如何形成所需的納米盤?
圖 1:合成納米盤描述
| 納米盤提供了細胞膜中天然膜蛋白環境的可遷移、幾乎一致的復制品。因此,它們規避了增溶去污劑的問題,使我們能夠在活性狀態下保持膜蛋白穩定或對其進行分離,以便開展進一步的科學研究。 |
有幾種不同的聚合物可用于制造合成納米盤,各有其優缺點。
合成聚合物如何形成所需的納米盤?
細胞膜為最重要的蛋白質組之一提供了其所需的環境:膜蛋白質組。膜蛋白分為外周蛋白和整合蛋白兩種,二者均具有一定的疏水性,在正常條件下不易溶解。
問題是,當這些疏水區與水或其他親水性介質接觸時,膜蛋白的 3D 結構將坍塌,從而失去其功能性。
為避免這種情況發生,蛋白質研究科學家通常使用去污劑(洗滌劑)來覆蓋膜蛋白的這些脆弱部分。但由于使用去污劑的方法也有其自身的一系列問題,如篩選過程耗時長或3D 結構的干擾等情況。
相比之下,合成聚合物能夠從其單體中形成聚合物鏈,插入所需的目標膜蛋白周圍的細胞膜之中(見圖2,頂部紅線)。像餅干模具(cookie cutter)一樣,將膜蛋白從膜中溶解出來,而聚合物則使膜蛋白在新形成的納米盤中保持穩定。
接下來采用親和層析法精確分離穩定的目標蛋白,并實施進一步的科學分析。
問題是,當這些疏水區與水或其他親水性介質接觸時,膜蛋白的 3D 結構將坍塌,從而失去其功能性。
為避免這種情況發生,蛋白質研究科學家通常使用去污劑(洗滌劑)來覆蓋膜蛋白的這些脆弱部分。但由于使用去污劑的方法也有其自身的一系列問題,如篩選過程耗時長或3D 結構的干擾等情況。
相比之下,合成聚合物能夠從其單體中形成聚合物鏈,插入所需的目標膜蛋白周圍的細胞膜之中(見圖2,頂部紅線)。像餅干模具(cookie cutter)一樣,將膜蛋白從膜中溶解出來,而聚合物則使膜蛋白在新形成的納米盤中保持穩定。
接下來采用親和層析法精確分離穩定的目標蛋白,并實施進一步的科學分析。
圖2:在包含膜蛋白的天然細胞膜中制備合成納米盤的過程。下一個步驟一般為親和層析。
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