Jørgensen H, Nielsen J, Villadsen J, Møllgaard H
Center for Process Biotechnology, Department of Biotechnology, Technical University of Denmark, DK-2800 Lyngby, Denmark.
Biotechnol Bioeng. 1995 Apr 20;46(2):117-31. doi: 10.1002/bit.260460205.
Based on a review of the Penicillium chrysogenum biochemistry a stoichiometric model has been set up. The model considers 61 internal fluxes and there are 49 intracellular metabolites which are assumed to be in pseudo-steady state. In addition to the intracellular fluxes the model considers the uptake of 21 amino acids. From the stoichiometric model the maximum theoretical yield of penicillin V is calculated to 0.43 mol/mol glucose. If biosynthesis of cysteine is by direct sulfhydrylation rather than by transsulfuration, the maximum theoretical yield is about 20% higher, i.e., 0.50 mol/mol glucose. The theoretical yield decreases substantially if alpha-aminoadipate is converted to 6-oxo-piperidine-2-carboxylic acid (OPC). If only 40% of the alpha-aminoadipate is recycled, the maximum theoretical yield is 0.31 mol/mol glucose. The uptake rates of glucose, lactate, gamma-aminobutyrate, and 21 amino acids were measured during fed-batch cultivations. The rates of formation of penicillin V, delta-(L-alpha)-aminoadipyl-L-cysteinyl-D-valine (ACV), OPC, and the pool of isopenicillin N, 6-APA, and 8-HPA were also measured. Finally the synthesis rates of the biomass constituents RNA/DNA, protein, lipid, carbohydrate, and amino carbohydrate were measured. From these measured rates and the stoichiometric model the metabolic fluxes through the different intracellular pathways are calculated. The calculations show that penicillin formation is accompanied by a large flux through the pentose phosphate (PP) pathway due to a large requirement for nicotinamide-adenine dinucleotide phosphate (NADPH) used in the biosynthesis of cysteine. If cysteine is added to the medium, the flux through the PP pathway decreases. From the stoichiometric model Y(xATP) is calculated to 87 mmol adenosine triphosphate (ATP)/g dry weight (DW), and from the flux calculations m(ATP) is found to 3 mmol ATP/g DW/h. (c) 1995 John Wiley & Sons, Inc.
基于对产黄青霉生物化学的综述,建立了一个化学计量模型。该模型考虑了61种内部通量,假设有49种细胞内代谢物处于准稳态。除了细胞内通量外,该模型还考虑了21种氨基酸的摄取。根据化学计量模型,青霉素V的最大理论产量计算为0.43摩尔/摩尔葡萄糖。如果半胱氨酸的生物合成是通过直接巯基化而不是转硫作用,则最大理论产量高出约20%,即0.50摩尔/摩尔葡萄糖。如果α-氨基己二酸转化为6-氧代哌啶-2-羧酸(OPC),理论产量将大幅下降。如果只有40%的α-氨基己二酸被循环利用,最大理论产量为0.31摩尔/摩尔葡萄糖。在分批补料培养过程中测量了葡萄糖、乳酸、γ-氨基丁酸和21种氨基酸的摄取速率。还测量了青霉素V、δ-(L-α)-氨基己二酰-L-半胱氨酰-D-缬氨酸(ACV)、OPC以及异青霉素N、6-氨基青霉烷酸(6-APA)和8-羟基青霉烷酸(8-HPA)库的形成速率。最后测量了生物量成分RNA/DNA、蛋白质、脂质、碳水化合物和氨基碳水化合物的合成速率。根据这些测量速率和化学计量模型,计算了通过不同细胞内途径的代谢通量。计算结果表明,由于半胱氨酸生物合成中对烟酰胺腺嘌呤二核苷酸磷酸(NADPH)的大量需求,青霉素的形成伴随着通过磷酸戊糖(PP)途径的大量通量。如果向培养基中添加半胱氨酸,通过PP途径的通量会降低。根据化学计量模型,Y(xATP)计算为87毫摩尔三磷酸腺苷(ATP)/克干重(DW),根据通量计算,m(ATP)为3毫摩尔ATP/克DW/小时。(c)1995约翰威立父子公司
