Design of a Cyclodextrin Bioproduction Process Using Bacillus pseudofirmus and Paenibacillus macerans

Future Pharmacology Pub Date : 2023-07-11 DOI:10.3390/futurepharmacol3030035

Alexandre Miguel Guedes, Tiago Filipe Santos Alves, P. Salústio, H. Cabral-Marques, M. Ribeiro

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Abstract

Cyclodextrin (CD) drug delivery systems offer the potential to enhance the desired physicochemical properties and pharmacokinetic parameters of drugs while maintaining their safety. Cyclodextrin-glucosyl-transferase (CGTase) is amongst the most important enzymes used in CD biosynthesis. However, the bioproduction of CDs still faces challenges in terms of optimization and process complexity. This study proposes a novel CD bioproduction system in a batch mode to increase yield and reduce costs. Two bacterial strains were selected: the alkalophilic Bacillus pseudofirmus DSM2517 strain and the neutrophilic Paenibacillus macerans DSM1574 strain. Three different culture media, two temperatures (30 °C and 37 °C), and three scales (shake flasks 20 mL and 100 mL, and bioreactor 3.2 L) were evaluated with respect to bacterial growth kinetics, protein production, and CGTase biosynthesis and activity for β-CD production. Bacterial growth was monitored by measuring optical density (OD600 nm), while CGTase activity was assessed by measuring β-CD production directly in the medium after filtration or in samples after concentration (using a Vivaspin 500® ultrafiltration spin column with a 10 kDa cut-off). β-CD quantification was performed using the phenolphthalein colorimetric method and HPLC. The best conditions for combined growth and protein production, for both microorganisms, in shake flasks were achieved with a medium containing 2% dextrin as the carbohydrate source. Scale-up to the bioreactor displayed improved growth kinetics for both bacteria and higher protein production and CGTase activity for Paenibacillus macerans.

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假硬芽孢杆菌和芽胞杆菌生产环糊精的工艺设计

环糊精(CD)给药系统提供了在保持药物安全性的同时增强药物所需的物理化学性质和药代动力学参数的潜力。环糊精-葡萄糖基转移酶(CGTase)是CD生物合成中最重要的酶之一。然而，CDs的生物生产仍然面临着优化和工艺复杂性方面的挑战。本研究提出了一种新的间歇式CD生物生产系统，以提高产量和降低成本。选择嗜碱性假硬芽孢杆菌DSM2517菌株和嗜中性嗜绿芽孢杆菌DSM1574菌株。研究了三种不同的培养基、两种温度(30°C和37°C)和三种天平(摇瓶20 mL和100 mL，生物反应器3.2 L)对细菌生长动力学、蛋白质产量、CGTase生物合成和β-CD生产活性的影响。通过测量光密度(OD600 nm)来监测细菌生长，而通过直接测量过滤后的培养基或浓缩后的样品(使用Vivaspin 500®超滤自旋柱，截止值为10 kDa)中β-CD的产生来评估CGTase活性。采用酚酞比色法和高效液相色谱法对β-CD进行定量。以含有2%糊精的培养基为碳水化合物源，在摇瓶中获得了两种微生物联合生长和蛋白质生产的最佳条件。放大后的生物反应器显示，细菌的生长动力学得到改善，蛋白质产量和CGTase活性均有所提高。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Future Pharmacology

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