Kristen Haggerty , Stuart Cantlay , Emily Young , Mariah K. Cashbaugh , Elio F. Delatore III , Rori Schreiber , Hayden Hess , Daniel R. Komlosi , Sarah Butler , Dalton Bolon , Theresa Evangelista , Takoda Hager , Claire Kelly , Katherine Phillips , Jada Voellinger , Robert M.Q. Shanks , Joseph Horzempa
{"title":"鉴定可改善土拉弗氏菌和其他革兰氏阴性菌荧光蛋白生物合成的 N 端标签(580N)。","authors":"Kristen Haggerty , Stuart Cantlay , Emily Young , Mariah K. Cashbaugh , Elio F. Delatore III , Rori Schreiber , Hayden Hess , Daniel R. Komlosi , Sarah Butler , Dalton Bolon , Theresa Evangelista , Takoda Hager , Claire Kelly , Katherine Phillips , Jada Voellinger , Robert M.Q. Shanks , Joseph Horzempa","doi":"10.1016/j.mcp.2024.101956","DOIUrl":null,"url":null,"abstract":"<div><p>Utilization of fluorescent proteins is widespread for the study of microbial pathogenesis and host-pathogen interactions. Here, we discovered that linkage of the 36 N-terminal amino acids of FTL_0580 (a hypothetical protein of <em>Francisella tularensis</em>) to fluorescent proteins increases the fluorescence emission of bacteria that express these recombinant fusions. This N-terminal peptide will be referred to as 580N. Western blotting revealed that the linkage of 580N to Emerald Green Fluorescent Protein (EmGFP) in <em>F. tularensis</em> markedly improved detection of this protein. We therefore hypothesized that transcripts containing <em>580N</em> may be translated more efficiently than those lacking the coding sequence for this leader peptide. In support, expression of <em>emGFP</em><sub><em>Ft</em></sub> that had been codon-optimized for <em>F. tularensis</em>, yielded significantly enhanced fluorescence than its non-optimized counterpart. Furthermore, fusing <em>emGFP</em> with coding sequence for a small N-terminal peptide (Serine-Lysine-Isoleucine-Lysine), which had previously been shown to inhibit ribosomal stalling, produced robust fluorescence when expressed in <em>F. tularensis.</em> These findings support the interpretation that 580N enhances the translation efficiency of fluorescent proteins in <em>F. tularensis.</em> Interestingly, expression of non-optimized <em>580N-emGFP</em> produced greater fluorescence intensity than any other construct. Structural predictions suggested that RNA secondary structure also may be influencing translation efficiency. When expressed in <em>Escherichia coli</em> and <em>Klebsiella pneumoniae</em> bacteria, <em>580N-emGFP</em> produced increased green fluorescence compared to untagged <em>emGFP</em> (neither allele was codon optimized for these bacteria). In conclusion, fusing the coding sequence for the 580N leader peptide to recombinant genes might serve as an economical alternative to codon optimization for enhancing protein expression in bacteria.</p></div>","PeriodicalId":2,"journal":{"name":"ACS Applied Bio Materials","volume":null,"pages":null},"PeriodicalIF":4.6000,"publicationDate":"2024-03-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S0890850824000082/pdfft?md5=4588c603f6eacdd9e1adcd4e09ecd30c&pid=1-s2.0-S0890850824000082-main.pdf","citationCount":"0","resultStr":"{\"title\":\"Identification of an N-terminal tag (580N) that improves the biosynthesis of fluorescent proteins in Francisella tularensis and other Gram-negative bacteria\",\"authors\":\"Kristen Haggerty , Stuart Cantlay , Emily Young , Mariah K. Cashbaugh , Elio F. Delatore III , Rori Schreiber , Hayden Hess , Daniel R. 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We therefore hypothesized that transcripts containing <em>580N</em> may be translated more efficiently than those lacking the coding sequence for this leader peptide. In support, expression of <em>emGFP</em><sub><em>Ft</em></sub> that had been codon-optimized for <em>F. tularensis</em>, yielded significantly enhanced fluorescence than its non-optimized counterpart. Furthermore, fusing <em>emGFP</em> with coding sequence for a small N-terminal peptide (Serine-Lysine-Isoleucine-Lysine), which had previously been shown to inhibit ribosomal stalling, produced robust fluorescence when expressed in <em>F. tularensis.</em> These findings support the interpretation that 580N enhances the translation efficiency of fluorescent proteins in <em>F. tularensis.</em> Interestingly, expression of non-optimized <em>580N-emGFP</em> produced greater fluorescence intensity than any other construct. Structural predictions suggested that RNA secondary structure also may be influencing translation efficiency. When expressed in <em>Escherichia coli</em> and <em>Klebsiella pneumoniae</em> bacteria, <em>580N-emGFP</em> produced increased green fluorescence compared to untagged <em>emGFP</em> (neither allele was codon optimized for these bacteria). 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引用次数: 0
摘要
荧光蛋白广泛应用于微生物致病机理和宿主-病原体相互作用的研究。在这里,我们发现将 FTL_0580(土拉弗氏菌的一种假定蛋白)的 36 个 N 端氨基酸与荧光蛋白连接可增加表达这些重组融合物的细菌的荧光发射。这种 N 端多肽将被称为 580N。Western 印迹显示,在土拉菌中,580N 与翡翠绿荧光蛋白(EmGFP)的连接明显改善了对这种蛋白的检测。因此,我们推测含有 580N 的转录本的翻译效率可能高于那些缺乏该前导肽编码序列的转录本。作为佐证,针对 F. tularensis 进行了密码子优化的 emGFPFt 的表达比未经优化的对应物的荧光明显增强。此外,将 emGFP 与 N 端小肽(丝氨酸-赖氨酸-异亮氨酸-赖氨酸)的编码序列融合,在 F. tularensis 中表达时可产生强荧光。这些发现支持了 580N 可提高荧光蛋白在土拉菌中的翻译效率这一解释。有趣的是,非优化 580N-emGFP 的表达比其他构建体产生更强的荧光。结构预测表明,RNA 二级结构也可能影响翻译效率。在大肠埃希菌和肺炎克雷伯菌中表达时,与未标记的 emGFP 相比,580N-emGFP 产生的绿色荧光更强(这两种等位基因都没有针对这些细菌进行密码子优化)。总之,将 580N 头肽的编码序列融合到重组基因中可能是一种经济的方法,可以替代密码子优化来提高细菌中蛋白质的表达。
Identification of an N-terminal tag (580N) that improves the biosynthesis of fluorescent proteins in Francisella tularensis and other Gram-negative bacteria
Utilization of fluorescent proteins is widespread for the study of microbial pathogenesis and host-pathogen interactions. Here, we discovered that linkage of the 36 N-terminal amino acids of FTL_0580 (a hypothetical protein of Francisella tularensis) to fluorescent proteins increases the fluorescence emission of bacteria that express these recombinant fusions. This N-terminal peptide will be referred to as 580N. Western blotting revealed that the linkage of 580N to Emerald Green Fluorescent Protein (EmGFP) in F. tularensis markedly improved detection of this protein. We therefore hypothesized that transcripts containing 580N may be translated more efficiently than those lacking the coding sequence for this leader peptide. In support, expression of emGFPFt that had been codon-optimized for F. tularensis, yielded significantly enhanced fluorescence than its non-optimized counterpart. Furthermore, fusing emGFP with coding sequence for a small N-terminal peptide (Serine-Lysine-Isoleucine-Lysine), which had previously been shown to inhibit ribosomal stalling, produced robust fluorescence when expressed in F. tularensis. These findings support the interpretation that 580N enhances the translation efficiency of fluorescent proteins in F. tularensis. Interestingly, expression of non-optimized 580N-emGFP produced greater fluorescence intensity than any other construct. Structural predictions suggested that RNA secondary structure also may be influencing translation efficiency. When expressed in Escherichia coli and Klebsiella pneumoniae bacteria, 580N-emGFP produced increased green fluorescence compared to untagged emGFP (neither allele was codon optimized for these bacteria). In conclusion, fusing the coding sequence for the 580N leader peptide to recombinant genes might serve as an economical alternative to codon optimization for enhancing protein expression in bacteria.
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