Roy Varnika, Roth Robert, Berge Mark, Chitta Rajesh, Vajrala Sucheta, Kuntumalla Srilatha, E Schmelzer Albert, Schoner Ron
Cell Culture and Fermentation Sciences, MedImmune, LLC, 1 MedImmune Way, Gaithersburg, Maryland, 20878.
Innovative Medicines, AstraZeneca R&D, Mölndal, Sweden.
Biotechnol Bioeng. 2017 Aug;114(8):1753-1761. doi: 10.1002/bit.26299. Epub 2017 May 18.
Human neurturin (NTN) is a cystine knot growth factor with potential therapeutic use in diseases such as Parkinson's and diabetes. Scalable high titer production of native NTN is particularly challenging because of the cystine knot structure which consists of an embedded ring comprised of at least three disulfide bonds. We sought to pursue enhanced scalable production of NTN in Escherichia coli. Our initial efforts focused on codon optimization of the first two codons following AUG, but these studies resulted in only a marginal increase in NTN expression. Therefore, we pursued an alternative strategy of using a bicistronic vector for NTN expression designed to reduce mRNA secondary structure to achieve increased ribosome binding and re-initiation. The first cistron was designed to prevent sequestration of the translation initiation region in a secondary conformation. The second cistron, which contained the NTN coding sequence itself, was engineered to disrupt double bonded base pairs and destabilize the secondary structure for ribosome re-initiation. The ensemble approach of reducing NTN's mRNA secondary structure and using the bicistronic vector had an additive effect resulting in significantly increased NTN expression. Our strain selection studies were conducted in a miniaturized bioreactor. An optimized strain was selected and scaled up to a 100 L fermentor, which yielded an inclusion body titer of 2 g/L. The inclusion bodies were refolded to yield active NTN. We believe that our strategy is applicable to other candidate proteins that are difficult-to-express due to stable mRNA secondary structures. Biotechnol. Bioeng. 2017;114: 1753-1761. © 2017 Wiley Periodicals, Inc.
人神经营养因子(NTN)是一种胱氨酸结生长因子,在帕金森病和糖尿病等疾病中具有潜在的治疗用途。由于胱氨酸结结构由至少三个二硫键组成的嵌入环构成,因此可扩展的高滴度天然NTN生产极具挑战性。我们试图在大肠杆菌中提高NTN的可扩展产量。我们最初的努力集中在优化AUG后的前两个密码子,但这些研究仅使NTN表达略有增加。因此,我们采用了一种替代策略,即使用双顺反子载体进行NTN表达,旨在减少mRNA二级结构,以增加核糖体结合和重新起始。第一个顺反子旨在防止翻译起始区域在二级构象中被隔离。第二个顺反子包含NTN编码序列本身,经过改造以破坏双键碱基对并使二级结构不稳定,从而实现核糖体重新起始。减少NTN的mRNA二级结构并使用双顺反子载体的整体方法具有累加效应,导致NTN表达显著增加。我们的菌株筛选研究在小型生物反应器中进行。选择了一个优化的菌株并扩大规模至100 L发酵罐,其包涵体滴度为2 g/L。将包涵体复性以产生活性NTN。我们相信我们的策略适用于其他由于稳定的mRNA二级结构而难以表达的候选蛋白质。《生物技术与生物工程》2017年;114:1753 - 1761。© 2017威利期刊公司
