Nonnatural amino acid incorporation has been one of the most important protein engineering techniques. Particularly site-specific incorporation of nonnatural amino acids would allow design of artificial proteins containing a nonnatural amino acid with minimal perturbation of their native properties. Site-specific incorporation of phenylalanine (Phe) analogs and tryptophan (Trp) analogs, such as -bromophenylalanine (pBrF), -iodophenylalanine, -azidophenylalanine, 6-chlorotrytophan, 6-bromotryptophan, 5-bromotrytophan, and benzothienylalanine, into proteins in has been realized by strains outfitted with a mutant yeast phenylalanyl-tRNA suppressor (ytRNA) and a mutant yeast phenylalanyl-tRNA synthetase (yPheRS (T415G)) with a point mutation in the active site of the enzyme. In order to reduce Trp and lysine (Lys) misincorporation at an amber codon, the ytRNA containing the optimized sequence and the yPheRS (T415A) showing higher specificity toward pBrF were developed. Combining ytRNA and yPheRS (T415A) allowed incorporation of pBrF into murine dihydrofolate reductase in response to an amber codon with at least 98% fidelity.ududRe-assignment of degenerate sense codons offers the prospect of a substantially expanded genetic code and a correspondingly enriched set of building blocks for natural and artificial proteins. Here we describe the use of a mutant yeast phenylalanine transfer RNA (ytRNA) containing a modified anticodon to break the degeneracy of the genetic code in . By using an strain co-transformed with ytRNA and a mutant yPheRS (T415G), we demonstrated efficient replacement of Phe by L-3-(2-naphthyl)alanine (2Nal) at UUU, but not at UUC codons.ududHowever, this method had two limitations. First, the yPheRS (T415G) also activated Trp, which led to Trp misincorporation. Second, 2Nal was misincorporated at UUC Phe codons, due to the relaxed codon recognition of AAA anticodon in the ytRNA. High-throughput screening of a yPheRS library led to a more selective yPheRS variant (yPheRS_naph). The rationally designed ytRNA, which has the CAA anticodon recognizing only a UUG (Leu) codon, allowed incorporation of 2Nal only at UUG codon. Combined use of yPheRS_naph and ytRNA achieved multiple-site-specific incorporation of 2Nal into proteins. These results illustrate a general method for increasing the number of distinct, genetically-encoded amino acids available for protein engineering.
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机译:非天然氨基酸掺入一直是最重要的蛋白质工程技术之一。特别地,非天然氨基酸的位点特异性掺入将允许设计含有非天然氨基酸的人工蛋白质,而其天然特性的扰动最小。将苯丙氨酸(Phe)类似物和色氨酸(Trp)类似物(例如-溴苯丙氨酸(pBrF),-碘苯丙氨酸,-叠氮苯丙氨酸,6-氯色氨酸,6-溴色氨酸,5-溴色氨酸和苯并噻吩基丙氨酸)特异地掺入到蛋白质中通过配备有突变的酵母苯丙氨酰-tRNA抑制剂(ytRNA)和突变的酵母苯丙氨酰-tRNA合成酶(yPheRS(T415G))的菌株实现了该菌株,该酶在酶的活性位点具有点突变。为了减少琥珀色密码子上的Trp和赖氨酸(Lys)错掺,开发了含有优化序列的ytRNA和对pBrF表现出更高特异性的yPheRS(T415A)。 ytRNA和yPheRS(T415A)的结合可将pBrF整合到鼠二氢叶酸还原酶中,以响应琥珀色密码子,保真度至少为98%。 ud ud简并有义密码子的重新分配为遗传密码的实质性扩展和相应的发展提供了前景丰富的天然和人工蛋白质构建基集。在这里,我们描述了使用含有修饰的反密码子的突变酵母苯丙氨酸转移RNA(ytRNA)来打破遗传密码的简并性。通过使用与ytRNA和突变yPheRS(T415G)共转化的菌株,我们证明了UUU处L-3-(2-萘基)丙氨酸(2Nal)可以有效取代Phe,而UUC密码子则不能。 ,这种方法有两个局限性。首先,yPheRS(T415G)也激活了Trp,从而导致Trp掺入错误。其次,由于ytRNA中AAA反密码子的轻松密码子识别,在UUC Phe密码子中并入了2Nal。 yPheRS库的高通量筛选导致更具选择性的yPheRS变体(yPheRS_naph)。合理设计的ytRNA具有仅识别UUG(Leu)密码子的CAA反密码子,仅允许在UUG密码子中掺入2Nal。 yPheRS_naph和ytRNA的联合使用实现了将2Nal多点特异性掺入蛋白质中。这些结果说明了增加可用于蛋白质工程的独特的遗传编码氨基酸数量的通用方法。
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