麦角酵母中的甲羟戊酸分泌不是由单一的非必要转运体介导的

Scott A. Wegner , José L. Avalos
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引用次数: 0

摘要

异戊烯类化合物是微生物化学生产的重要目标,可利用可再生碳原料生产香料、生物燃料和药物。为了提高异戊烯类化合物的产量,以前的研究曾通过操纵丙酮酸脱氢酶(PDH)旁路通量来增加细胞膜乙酰-coA;但这会导致甲羟戊酸的分泌,并不一定会转化为更高的异戊烯类化合物产量。鉴定和破坏介导甲羟戊酸分泌的转运体将使我们能够确定,在没有甲羟戊酸分泌的情况下,增加 PDH 旁路活性是否会改善甲羟戊酸向下游异丙烯酸的转化。我们尝试使用针对所有非必要转运体的 CRISPR 文库和两种不同的筛选方法来鉴定甲羟戊酸转运体。通过高通量筛选,在甲羟戊酸辅助营养大肠杆菌菌株生长的基础上发现,ZRT3 的破坏在很大程度上抑制了细胞外甲羟戊酸的积累。然而,研究发现破坏 ZRT3 会降低甲羟戊酸通路的整体活性,而不是阻止分泌,这表明锌的可用性与甲羟戊酸通路之间存在一种以前未报道过的相互作用。在第二个筛选中,发现野生型和分泌甲羟戊酸的酿酒酵母菌株之间的 PDR5/15 和 QDR1/2 文库代表性存在显著差异。然而,没有任何单个缺失(或选定的一对双缺失)会取消甲羟戊酸的分泌,这表明这一过程似乎是通过多个冗余转运体介导的。
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Mevalonate secretion is not mediated by a singular non-essential transporter in Saccharomyces cerevisiae
Isoprenoids are highly valued targets for microbial chemical production, allowing the creation of fragrances, biofuels, and pharmaceuticals from renewable carbon feedstocks. To increase isoprenoid production, previous efforts have manipulated pyruvate dehydrogenase (PDH) bypass pathway flux to increase cytosolic acetyl-coA; however, this results in mevalonate secretion and does not necessarily translate into higher isoprenoid production. Identification and disruption of the transporter mediating mevalonate secretion would allow us to determine whether increasing PDH bypass activity in the absence of secretion improves conversion of mevalonate into downstream isoprenoids. Attempted identification of the mevalonate transporter was accomplished using a pooled CRISPR library targeting all nonessential transporters and two different screening methods. Using a high throughput screen, based on growth of a mevalonate auxotrophic Escherichia coli strain, it was found that ZRT3 disruption largely abolished accumulation of extracellular mevalonate. However, disruption of ZRT3 was found to lower overall mevalonate pathway activity, rather than prevent secretion, indicating a previously unreported interaction between zinc availability and the mevalonate pathway. In a second screen, significant differences in PDR5/15 and QDR1/2 library representation were found between wild-type and mevalonate secreting Saccharomyces cerevisiae strains. However, no single deletion (or selected pair of double deletions) abolishes mevalonate secretion, indicating that this process appears to be mediated through multiple redundant transporters.
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