Exploiting the sequence diversity of TALE-like repeats to vary the strength of dTALE-promoter interactions.

IF 2.6 Q2 BIOCHEMICAL RESEARCH METHODS Synthetic biology (Oxford, England) Pub Date : 2017-08-09 eCollection Date: 2017-01-01 DOI:10.1093/synbio/ysx004
Orlando de Lange, Niklas Schandry, Markus Wunderlich, Kenneth Wayne Berendzen, Thomas Lahaye
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Abstract

Designer transcription activator-like effectors (dTALEs) are programmable transcription factors used to regulate user-defined promoters. The TALE DNA-binding domain is a tandem series of amino acid repeats that each bind one DNA base. Each repeat is 33-35 amino acids long. A residue in the center of each repeat is responsible for defining DNA base specificity and is referred to as the base specificying residue (BSR). Other repeat residues are termed non-BSRs and can contribute to TALE DNA affinity in a non-base-specific manner. Previous dTALE engineering efforts have focused on BSRs. Non-BSRs have received less attention, perhaps because there is almost no non-BSR sequence diversity in natural TALEs. However, more sequence diverse, TALE-like proteins are found in diverse bacterial clades. Here, we show that natural non-BSR sequence diversity of TALEs and TALE-likes can be used to modify DNA-binding strength in a new form of dTALE repeat array that we term variable sequence TALEs (VarSeTALEs). We generated VarSeTALE repeat modules through random assembly of repeat sequences from different origins, while holding BSR composition, and thus base preference, constant. We used two different VarSeTALE design approaches combing either whole repeats from different TALE-like sources (inter-repeat VarSeTALEs) or repeat subunits corresponding to secondary structural elements (intra-repeat VarSeTALEs). VarSeTALE proteins were assayed in bacteria, plant protoplasts and leaf tissues. In each case, VarSeTALEs activated or repressed promoters with a range of activities. Our results indicate that natural non-BSR diversity can be used to diversify the binding strengths of dTALE repeat arrays while keeping target sequences constant.

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利用 TALE 样性重复序列的多样性来改变 dTALE 与启动子相互作用的强度。
Designer transcription activator-like effectors(dTALEs)是一种可编程转录因子,用于调节用户定义的启动子。TALE DNA 结合域是一系列串联的氨基酸重复序列,每个重复序列结合一个 DNA 碱基。每个重复序列长 33-35 个氨基酸。每个重复序列中心的一个残基负责确定 DNA 碱基的特异性,被称为碱基特异性残基(BSR)。其他重复残基被称为非 BSR,可以非碱基特异性的方式促进 TALE DNA 的亲和性。以前的 dTALE 工程工作主要集中在 BSR 上。非 BSR 得到的关注较少,这可能是因为天然 TALE 几乎不存在非 BSR 序列多样性。然而,在不同的细菌支系中发现了序列更加多样的类似 TALE 的蛋白质。在这里,我们展示了 TALEs 和 TALE-类似物的天然非BSR 序列多样性可用于改变 DNA 结合强度,形成一种新形式的 dTALE 重复序列阵列,我们称之为可变序列 TALEs(VarSeTALEs)。我们通过随机组装不同来源的重复序列来生成 VarSeTALE 重复序列模块,同时保持 BSR 组成不变,从而保持碱基偏好不变。我们使用了两种不同的 VarSeTALE 设计方法,将来自不同 TALE 样源的整个重复序列(重复间 VarSeTALE)或与二级结构元素相对应的重复亚基(重复内 VarSeTALE)组合在一起。在细菌、植物原生质体和叶片组织中对 VarSeTALE 蛋白进行了检测。在每种情况下,VarSeTALEs 都能激活或抑制具有不同活性的启动子。我们的研究结果表明,在保持目标序列不变的情况下,可以利用天然非BSR多样性来使 dTALE 重复序列的结合强度多样化。
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