Biocatalysts to generate novel aminoglycosides and hydroxylate inactivated C-H bonds

产生新型氨基糖苷和羟基化失活的 C-H 键的生物催化剂

• 批准号: 240750-2007
• 负责人: Auclair, Karine
• 金额: $ 3.06万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2009
• 资助国家: 加拿大
• 起止时间: 2009-01-01 至 2010-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=425910
• 关键词: Biocatalysts; generate; novel; aminoglycosides; hydroxylate

Biocatalysts are enantio-, chemo-, and regio-selective across a wide range of reactions under mild conditions. Their use in synthesis is however limited in part by chemists' apprehension to handle enzymes. We propose to develop simple biocatalytic methods to generate novel aminoglycosides and hydroxylate inactivated C-H bonds. Aminoglycosides are clinically important broad spectrum antibiotics. Unfortunately, the emergence of resistance is increasingly restricting their use. A better understanding of resistance-causing mechanisms is critical to conquer this health threat. The synthesis of aminoglycoside derivatives is challenging because of solubility issues and of the complex protection schemes required. We have developed a novel methodology for selective N-6' acylation of aminoglycosides. This has allowed the one-pot synthesis of the first nanomolar inhibitors of resistance-causing aminoglycoside 6'-N-acetyltransferase Ii. Our next goal is to prepare aminoglycosides able to escape resistance-causing enzymes while maintaining their antibacterial activity. To this end, we propose to develop new chemoenzymatic methodologies for the regioselective derivatization of aminoglycosides. Commercial enzymes and acetyltransferases will be used. In parallel, we propose to study P450 enzymes for their impressive ability to catalyze the insertion of oxygen into non-activated C-H bonds. Very few methods exist that directly hydroxylate aliphatic C-H bonds, and most of them are of limited scope. P450s represent a promising alternative; however, a number of limitations have restricted their use. These include substrate specificity, the need for 2 or 3 cofactors, incompatibility with organic solvents, low activity and poor stability. The very promiscuous P450s 3A4 and 2D6 were selected to overcome the substrate specificity issue. We have reported that some cheap chemicals can efficiently replace the natural cofactors. and recently found conditions to use these enzymes in the presence of organic solvents. Next we propose to develop a system of substrate tagging to allow prediction of the regio- and stereo-selectivity of P450s.

在温和的条件下，生物催化剂在各种反应中具有对映体、化学和区域选择性。然而，它们在合成中的使用在一定程度上受到化学家处理酶的担忧的限制。我们建议开发简单的生物催化方法来生成新的氨基糖苷类化合物和羟基化失活的C-H键。氨基糖苷类抗生素是临床上重要的广谱抗生素。不幸的是，耐药性的出现越来越限制了它们的使用。更好地了解引起耐药性的机制对于克服这一健康威胁至关重要。氨基糖苷衍生物的合成具有挑战性，因为存在溶解性问题和所需的复杂保护方案。我们开发了一种新的方法来选择性N-6‘酰化氨基糖苷类化合物。这使得一锅法合成了导致耐药的氨基糖苷6‘-N-乙酰转移酶II的第一个纳米分子抑制剂。我们的下一个目标是制备能够逃避引起耐药性的酶的氨基糖苷类化合物，同时保持它们的抗菌活性。为此，我们建议开发新的化学酶方法用于氨基糖苷类化合物的区域选择性衍生化。将使用商用酶和乙酰转移酶。同时，我们建议研究P450酶，因为它们具有令人印象深刻的能力，催化氧插入非活化的C-H键。直接羟化脂肪族C-H键的方法很少，而且大多数方法的适用范围都很有限。P450是一种很有前途的替代品；然而，一些限制因素限制了它们的使用。这些问题包括底物专一性、需要2到3个辅因子、与有机溶剂不相容、活性低和稳定性差。选择非常混杂的P450、3A4和2D6来克服底物专一性问题。我们已经报道，一些廉价的化学品可以有效地取代天然辅因子。最近发现了在有机溶剂中使用这些酶的条件。接下来，我们建议开发一种底物标记系统，以允许预测P450的区域和立体选择性。