In an effort to expand the genetic alphabet and create semi-synthetic organisms (SSOs) that store and retrieve increased information, we have developed the unnatural base pairs (UBPs) d>NaM and d>5SICS or d>TPT3 (d>NaM-d>5SICS and d>NaM-d>TPT3). The UBPs form based on hydrophobic and packing forces, as opposed to complementary hydrogen bonding, and while they are both retained within the in vivo environment of an E. coli SSO, their development was based on structure-activity relationship (SAR) data generated in vitro. To address the likely possibility of different requirements of the in vivo environment, we screened 135 candidate UBPs for optimal performance in the SSO. Interestingly, we find that in vivo SARs differ from those collected in vitro, and most importantly, we identify four UBPs whose retention in the DNA of the SSO is higher than that of d>NaM-d>TPT3, which was previously the most promising UBP identified. The identification of these four UBPs further demonstrates that when optimized, hydrophobic and packing forces may be used to replace the complementary hydrogen bonding used by natural pairs and represents a significant advance in our continuing efforts to develop SSOs that store and retrieve more information than natural organisms.
展开▼
机译:为了扩展遗传字母并创建存储和检索更多信息的半合成生物(SSO),我们开发了d > NaM 和d > 5SICS < / strong>或d > TPT3 (d > NaM -d > 5SICS 和d > NaM -d > TPT3 < / strong>)。与互补氢键相反,UBP是基于疏水力和堆积力形成的,虽然它们都保留在大肠杆菌SSO的体内环境中,但它们的开发是基于结构和活性关系(SAR)数据体外。为了解决体内环境不同要求的可能可能性,我们筛选了135个候选UBP,以在SSO中获得最佳性能。有趣的是,我们发现体内的SAR与体外收集的SAR不同,最重要的是,我们发现了四个SBP在DNA中的保留率高于d > NaM -d >的UBP。 TPT3 ,以前是最有前途的UBP。对这四个UBP的鉴定进一步表明,当优化时,疏水力和堆积力可用于取代天然对所使用的互补氢键,这代表着我们不断努力开发储存和检索比自然生物更多信息的SSO的重大进展。 。
展开▼
