Department of Chemical and Biological Engineering, The University of Sheffield, Mappin Street, Sheffield, S1 3JD, U.K.
Cell Culture and Fermentation Sciences, BioPharmaceuticals Development, R&D, AstraZeneca, Gaithersburg, Maryland 20878, United States.
ACS Synth Biol. 2021 May 21;10(5):1155-1165. doi: 10.1021/acssynbio.0c00643. Epub 2021 May 3.
To successfully engineer mammalian cells for a desired purpose, multiple recombinant genes are required to be coexpressed at a specific and optimal ratio. In this study, we hypothesized that synthetic promoters varying in transcriptional activity could be used to create single multigene expression vectors coexpressing recombinant genes at a predictable relative stoichiometry. A library of 27 multigene constructs was created comprising three discrete fluorescent reporter gene transcriptional units in fixed series, each under the control of either a relatively low, medium, or high transcriptional strength synthetic promoter in every possible combination. Expression of each reporter gene was determined by absolute quantitation qRT-PCR in CHO cells. The synthetic promoters did generally function as designed within a multigene vector context; however, significant divergences from predicted promoter-mediated transcriptional activity were observed. First, expression of all three genes within a multigene vector was repressed at varying levels relative to coexpression of identical reporter genes on separate single gene vectors at equivalent gene copies. Second, gene positional effects were evident across all constructs where expression of the reporter genes in positions 2 and 3 was generally reduced relative to position 1. Finally, after accounting for general repression, synthetic promoter transcriptional activity within a local multigene vector format deviated from that expected. Taken together, our data reveal that mammalian synthetic promoters can be employed in vectors to mediate expression of multiple genes at predictable relative stoichiometries. However, empirical validation of functional performance is a necessary prerequisite, as vector and promoter design features can significantly impact performance.
为了成功地将哺乳动物细胞工程化用于特定目的,需要共表达多个重组基因,并使其以特定的最佳比例表达。在本研究中,我们假设转录活性不同的合成启动子可用于创建单个多基因表达载体,以可预测的相对化学计量比共表达重组基因。构建了一个由 27 个多基因构建体组成的文库,这些构建体包含三个离散的荧光报告基因转录单元,以固定的序列排列,每个转录单元均由低、中或高转录强度的合成启动子控制,这些启动子以各种可能的组合排列。通过在 CHO 细胞中进行绝对定量 qRT-PCR 测定每个报告基因的表达。这些合成启动子在多基因载体的背景下通常能按预期发挥作用;然而,观察到与预测的启动子介导的转录活性存在显著差异。首先,与在单独的单基因载体上以相同的基因拷贝共表达相同的报告基因相比,多基因载体中所有三个基因的表达均受到不同程度的抑制。其次,所有构建体中都存在基因位置效应,报告基因在位置 2 和 3 的表达通常低于位置 1。最后,在考虑到普遍抑制后,局部多基因载体格式中的合成启动子转录活性偏离预期。总的来说,我们的数据表明,哺乳动物合成启动子可用于载体以可预测的相对化学计量比表达多个基因。然而,功能性能的实证验证是必要的前提,因为载体和启动子的设计特征会显著影响性能。
