Gaytán Paul, Osuna Joel, Soberón Xavier
Instituto de Biotecnología/UNAM, Ap. Postal 510-3, Cuernavaca, Morelos 62250, México.
Nucleic Acids Res. 2002 Aug 15;30(16):e84. doi: 10.1093/nar/gnf083.
Four known and nine new ceftazidime-resistance beta-lactamases were generated by a novel, contaminating codon-based mutagenesis approach. In this method, wild-type codons are spiked with a set of mutant codons during oligonucleotide synthesis, generating random combinatorial libraries of primers that contain few codon replacements per variant. Mutant codons are assembled by tandem addition of a diluted mixture of five Fmoc-dimer amidites to the growing oligo and a mixture of four DMTr-monomer amidites to generate 20 trinucleotides that encode a set of 18 amino acids. Wild-type codons are assembled with conventional chemistry and the whole process takes place in only one synthesis column, making its automation feasible. The random and binomial behavior of this approach was tested in the polylinker region of plasmid pUC19 by the synthesis of three oligonucleotide libraries mutagenized at different rates and cloned as mutagenic cassettes. Additionally, the method was biologically assessed by mutating six contiguous codons that encode amino acids 237-243 (ABL numbering) of the TEM(pUC19) beta-lactamase, which is functionally equivalent to the clinically important TEM-1 beta-lactamase. The best ceftazidime-recognizing variant was a triple mutant, R164H:E240K: R241A, displaying a 333-fold higher resistance than the wild-type enzyme.
通过一种全新的、基于密码子污染的诱变方法产生了4种已知的和9种新的对头孢他啶耐药的β-内酰胺酶。在这种方法中,在寡核苷酸合成过程中,野生型密码子被一组突变密码子掺入,从而产生引物的随机组合文库,每个变体包含少量的密码子替换。突变密码子通过将五种Fmoc-二聚体亚磷酰胺的稀释混合物串联添加到正在生长的寡核苷酸上以及四种DMTr-单体亚磷酰胺的混合物来组装,以生成20个编码一组18种氨基酸的三核苷酸。野生型密码子用传统化学方法组装,整个过程仅在一个合成柱中进行,使其自动化可行。通过合成以不同速率诱变并作为诱变盒克隆的三个寡核苷酸文库,在质粒pUC19的多克隆位点区域测试了这种方法的随机和二项式行为。此外,通过突变编码TEM(pUC19)β-内酰胺酶(其功能等同于临床上重要的TEM-1β-内酰胺酶)第237-243位氨基酸(ABL编号)的六个连续密码子对该方法进行了生物学评估。对头孢他啶识别能力最强的变体是一个三重突变体,R164H:E240K:R241A,其耐药性比野生型酶高333倍。