Activation of fungal silent gene clusters: a new avenue to drug discovery.

Axel A Brakhage, Julia Schuemann, Sebastian Bergmann, Kirstin Scherlach, Volker Schroeckh, Christian Hertweck
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引用次数: 114

Abstract

The ongoing exponential growth of DNA sequence data will lead to the discovery of many natural-product biosynthesis pathways by genome mining for which no actual product has been characterised. In many cases, these clusters remain silent under laboratory conditions. New technologies based on genetic engineering are available to induce silent genes. Heterologous expression of a silent gene cluster under the control of defined promoters can be applied. Alternatively, promoters of biosynthesis genes within the genome can be exchanged by defined promoters. Most promising, however, is the activation of pathway-specific regulatory genes, which was recently demonstrated. Such regulatory genes are present in many secondary metabolite gene clusters. This approach is rendered feasible by the fact that all of the genes encoding the large number of enzymes required for the synthesis of a typical secondary metabolite are clustered and that in some cases, a single regulator controls the expression of all members of a gene cluster to a certain extent. The advantage of this technique is that only a small gene needs to be handled, and that an ectopic integration is sufficient, bypassing all limitations of homologous recombination. Most conveniently, this strategy can trigger the concerted expression of all pathway genes. The vast amount of DNA sequences in the public database represents only the beginning of this new genomics era. The activation of these gene clusters by genetic engineering will lead to the discovery of many so far unknown products and therefore represents a novel avenue to drug discovery.

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真菌沉默基因簇的激活:药物发现的新途径。
DNA序列数据的持续指数增长将导致通过基因组挖掘发现许多天然产物生物合成途径,而这些途径没有实际产物被表征。在许多情况下,这些簇在实验室条件下保持沉默。基于基因工程的新技术可以诱导沉默基因。在确定的启动子控制下,沉默基因簇的异源表达可以应用。或者,基因组内生物合成基因的启动子可以被定义的启动子交换。然而,最有希望的是通路特异性调控基因的激活,这一点最近得到了证实。这些调控基因存在于许多次生代谢物基因簇中。这种方法是可行的,因为编码合成一种典型次级代谢物所需的大量酶的所有基因都聚集在一起,而且在某些情况下,一个单一的调节因子在一定程度上控制了一个基因簇中所有成员的表达。这种技术的优点是只需要处理一个小的基因,并且一个异位整合就足够了,绕过了同源重组的所有限制。最方便的是,这种策略可以触发所有途径基因的协调表达。公共数据库中大量的DNA序列仅仅代表了这个新的基因组学时代的开始。通过基因工程激活这些基因簇将导致发现许多迄今为止未知的产物,因此代表了药物发现的新途径。
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