Joh Lawrence D, Wroblewski Tadeusz, Ewing Nicholas N, VanderGheynst Jean S
Department of Biological and Agricultural Engineering, University of California, Davis, One Shields Avenue, Davis, California 95616, USA.
Biotechnol Bioeng. 2005 Sep 30;91(7):861-71. doi: 10.1002/bit.20557.
Transient expression following agroinfiltration of plant tissue was investigated as a system for producing recombinant protein. As a model system, Agrobacterium tumefaciens containing the beta-glucuronidase (GUS) gene was vacuum infiltrated into lettuce leaf disks. Infiltration with a suspension of 10(9) colony forming units/mL followed by incubation for 72 h at 22 degrees C in continuous darkness produced a maximum of 0.16% GUS protein based on dry tissue or 1.1% GUS protein based on total soluble protein. This compares favorably to expression levels for commercially manufactured GUS protein from transgenic corn seeds. A. tumefaciens culture medium pH between 5.6 and 7.0 and surfactant concentrations < or = 100 ppm in the vacuum infiltration did not affect GUS expression, while infiltration with an A. tumefaciens density of 10(7) and 10(8) colony forming units/mL, incubation at 29 degrees C, and a surfactant concentration of 1,000 ppm significantly reduced expression. Incubation in continuous light caused lettuce to produce GUS protein more rapidly, but final levels did not exceed the GUS production in leaves incubated in continuous darkness after 72 h at 22 degrees C. The kinetics of GUS expression during incubation in continuous light and dark were represented well using a logistic model, with rate constants of 0.30 and 0.29/h, respectively. To semi-quantitatively measure the GUS expression in large numbers of leaf disks, a photometric enhancement of the standard histochemical staining method was developed. A linear relationship with an R2 value of 0.90 was determined between log10 (% leaf darkness) versus log10 (GUS activity). Although variability in expression level was observed, agroinfiltration appears to be a promising technology that could potentially be scaled up to produce high-value recombinant proteins in planta.
研究了农杆菌介导的植物组织瞬时表达作为生产重组蛋白的系统。作为模型系统,将含有β-葡萄糖醛酸酶(GUS)基因的根癌农杆菌真空渗入生菜叶盘。用10⁹菌落形成单位/毫升的悬浮液进行渗入,然后在22℃连续黑暗中孵育72小时,基于干组织产生的GUS蛋白最高可达0.16%,基于总可溶性蛋白产生的GUS蛋白为1.1%。这与转基因玉米种子商业化生产的GUS蛋白的表达水平相比具有优势。真空渗入时,根癌农杆菌培养基pH在5.6至7.0之间且表面活性剂浓度≤100 ppm不影响GUS表达,而用密度为10⁷和10⁸菌落形成单位/毫升的根癌农杆菌进行渗入、在29℃孵育以及表面活性剂浓度为1000 ppm会显著降低表达。在连续光照下孵育使生菜更快产生GUS蛋白,但最终水平不超过在22℃连续黑暗中孵育72小时后的叶片中的GUS产量。使用逻辑模型很好地表示了连续光照和黑暗孵育期间GUS表达的动力学,速率常数分别为0.30和0.29/小时。为了半定量测量大量叶盘中的GUS表达,开发了标准组织化学染色方法的光度增强法。确定了log₁₀(%叶片黑暗度)与log₁₀(GUS活性)之间的线性关系,R²值为0.90。尽管观察到表达水平存在差异,但农杆菌介导的瞬时表达似乎是一种有前途的技术,有可能扩大规模以在植物中生产高价值的重组蛋白。
