Clémençon Benjamin, Lüscher Benjamin P, Hediger Matthias A
Institute of Biochemistry and Molecular Medicine, University of Bern, Bern, Switzerland.
Institute of Biochemistry and Molecular Medicine, University of Bern, Bern, Switzerland.
J Pharmacol Toxicol Methods. 2018 Jul-Aug;92:67-76. doi: 10.1016/j.vascn.2018.03.004. Epub 2018 Mar 23.
Membrane proteins represent roughly one third of the human proteome and many of them serve as targets of therapeutic drugs. An exception is the SLC solute carrier superfamily with only a handful of approved drugs targeting SLCs. Indeed, for many of the SLCs, the natural transport substrates are still unknown. A major limitation for SLCs has been the difficulty to thoroughly characterize these multimembrane spanning proteins. The intrinsic properties of membrane proteins with alternative hydrophobic and hydrophilic domains lead to instability, making the purification tasks even more challenging compared to soluble proteins. This issue also holds true for conventional ligand-binding assays (LBAs) which usually require high-quality, pure and concentrated protein samples. Herein, we report a novel binding assay strategy to overcome these issues, taking advantage of a unique combination of yeast expression and microscale thermophoresis (MST). Following yeast overexpression of SLC15A1/PepT1 ortholog from moss Physcomitrella patens, PepT, which exhibits remarkable similarity to human PepT1, the approach was validated using dipeptide glycylsarcosine (Gly-Sar) and antiviral prodrug valacyclovir as test substrates.
The originality of our approach is based on the comparative analysis of solubilized total membrane preparations with or without expression of the SLC target of interest, using a yeast strain (S. cerevisiae), in which the corresponding endogenous SLC homolog is depleted. MST is a recently developed technique that takes advantage of the properties of biomolecules in solution to migrate along a temperature gradient. Importantly, this migration is affected by substrate binding. It is being monitored by fluorescence using labelled SLC molecules in the presence of different ligand concentrations.
We herein report a novel MST/yeast-based method to characterize binding of ligands to SLCs without the need for a prior SLC-purification step. For validation purposes, we used a close eukaryotic homolog of the human H-coupled oligopeptide transporter PepT1 (SLC15A1) that mediates uptake of di-tripeptides and peptide-like drugs as a test model. This approach allowed the successful confirmation of the binding of Gly-Sar at the mM range and revealed for the first time the K of the antiviral prodrug valacyclovir to the PepT1 homolog at around 50 μM.
This novel LBA approach is independent of protein purification. It is suitable for drug discovery as it is upscalable to high throughput compound screening. It works well for SLC transporters which are underrepresented targets due to their difficulties to study them. Moreover, this approach could make a significant contribution toward "deorphanization" of SLCs, revealing their transport substrates.
膜蛋白约占人类蛋白质组的三分之一,其中许多是治疗药物的靶点。溶质载体(SLC)超家族是个例外,仅有少数几种已获批的靶向SLC的药物。实际上,许多SLC的天然转运底物仍不为人知。SLC面临的一个主要限制是难以全面表征这些跨膜多次的蛋白质。具有交替疏水和亲水结构域的膜蛋白的固有特性导致其不稳定,与可溶性蛋白相比,这使得纯化工作更具挑战性。对于传统的配体结合分析(LBA)而言,这个问题同样存在,因为这类分析通常需要高质量、纯净且浓缩的蛋白质样品。在此,我们报告了一种新颖的结合分析策略,利用酵母表达和微量热泳动(MST)的独特组合来克服这些问题。在从苔藓小立碗藓中过表达SLC15A1/PepT1直系同源物(与人类PepT1具有显著相似性的PepT)后,使用二肽甘氨酰甘氨酸(Gly-Sar)和抗病毒前体药物伐昔洛韦作为测试底物对该方法进行了验证。
我们方法的独特之处在于,使用一种相应内源性SLC同源物已缺失的酵母菌株(酿酒酵母),对有或无目标SLC表达的溶解总膜制剂进行比较分析。MST是一种最近开发的技术,它利用生物分子在溶液中的特性使其沿温度梯度迁移。重要的是,这种迁移会受到底物结合的影响。在存在不同配体浓度的情况下,使用标记的SLC分子通过荧光监测这种迁移。
我们在此报告了一种基于MST/酵母的新方法,用于表征配体与SLC的结合,而无需事先进行SLC纯化步骤。为了验证,我们使用了人类H +偶联寡肽转运体PepT1(SLC15A1)的一个密切的真核同源物作为测试模型,该同源物介导二 - 三肽和类肽药物的摄取。这种方法成功确认了Gly-Sar在毫摩尔范围内的结合,并首次揭示了抗病毒前体药物伐昔洛韦与PepT1同源物的解离常数约为50μM。
这种新颖的LBA方法不依赖于蛋白质纯化。它适用于药物发现,因为它可扩展用于高通量化合物筛选。对于因研究困难而研究较少的SLC转运体,该方法效果良好。此外,这种方法可为SLC的“去孤儿化”做出重大贡献,揭示它们的转运底物。
