干细胞疗法治疗辐射暴露后严重组织损伤

Eliana Mariño
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引用次数: 2

摘要

近年来,沙门氏菌减毒菌株的应用已被广泛研究,用于各种生物技术产品,特别是疫苗的开发。然而,这些化合物的工业生产受到沙门氏菌细胞代谢限制的阻碍,沙门氏菌细胞自然产生大量的生长抑制剂代谢物,主要是醋酸盐。为了解决这一问题,本工作评估了两种不同的方法:改变培养条件(碳源评估)和实施遗传修饰(通过过度表达乙酰辅酶a合成酶(ACS)来增强细胞的乙酸清除能力)。野生型和重组细胞以葡萄糖或甘油为碳源,在Erlenmeyer烧瓶中以200 rpm和37℃搅拌,在最低培养基中培养。在培养过程中采集样品,采用高效液相色谱法定量测定有机酸产量和碳源消耗。通过培养液光密度(OD 600 nm)测定细胞生长情况。结果表明,碳源对鼠伤寒沙门氏菌细胞的副产物排泄起着重要作用,表明对这两种菌株来说,甘油的使用大大减少了乙酸的产量。ACS的过表达也减少了乙酸的积累,因为该酶对排泄的乙酸起同化作用。在所有条件下,甘油中培养的重组细胞效果最好。与其他实验中记录的平均值相比,生物质产量增加了40%,而乙酸积累减少了50%以上。
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Stem cell therapy for the treatment of severe tissue damage after radiation exposure
I recent years, the application of attenuated strains of Salmonella spp. has been widely investigated for the development of various biotechnological products, especially vaccines. However, the industrial production of these compounds is hampered by metabolic constraints presented by Salmonella cells, which naturally produce high amounts of growth inhibitor metabolites, mainly acetate. To deal with this problem, two different approaches were evaluated in the present work: Changing culture conditions (carbon source evaluation) and implementing genetic modifications (enhancement of cell’s acetate scavenging capabilities by overexpression of acetyl-CoA synthetase (ACS)). Wild type and recombinant cells were cultured in minimal medium with glucose or glycerol as carbon source in Erlenmeyer flasks agitated at 200 rpm and 37 oC. Samples were collected during cultivation and analyzed by HPLC to quantify organic acids production and the carbon source consumption. Cellular growth was assessed by optical density readings (OD 600 nm) of the culture broth. The results showed that the carbon source plays an important role on byproducts excretion by S. typhimurium cells, indicating that for both strains acetate production is greatly reduced using glycerol. The overexpression of ACS also reduced the acetate accumulation as this enzyme acted assimilating the excreted acetate. From all the conditions studied, the best results were obtained by the recombinant cells cultured in glycerol. An increase of 40% of biomass production was achieved, while the acetate accumulation was reduced by more than 50% in comparison to the average values registered in the other experiments.
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