Atkin Kate E, Reiss Renate, Koehler Valentin, Bailey Kevin R, Hart Sam, Turkenburg Johan P, Turner Nicholas J, Brzozowski A Marek, Grogan Gideon
York Structural Biology Laboratory, Department of Chemistry, University of York, York YO10 5YW, UK.
J Mol Biol. 2008 Dec 31;384(5):1218-31. doi: 10.1016/j.jmb.2008.09.090. Epub 2008 Oct 14.
Monoamine oxidase from Aspergillus niger (MAO-N) is a flavoenzyme that catalyses the oxidative deamination of primary amines. MAO-N has been used as the starting model for a series of directed evolution experiments, resulting in mutants of improved activity and broader substrate specificity, suitable for application in the preparative deracemisation of primary, secondary and tertiary amines when used as part of a chemoenzymatic oxidation-reduction cycle. The structures of a three-point mutant (Asn336Ser/Met348Lys/Ile246Met or MAO-N-D3) and a five-point mutant (Asn336Ser/Met348Lys/Ile246Met/Thr384Asn/Asp385Ser or MAO-N-D5) have been obtained using a multiple-wavelength anomalous diffraction experiment on a selenomethionine derivative of the truncated MAO-N-D5 enzyme. MAO-N exists as a homotetramer with a large channel at its centre and shares some structural features with human MAO B (MAO-B). A hydrophobic cavity extends from the protein surface to the active site, where a non-covalently bound flavin adenine dinucleotide (FAD) sits at the base of an 'aromatic cage,' the sides of which are formed by Trp430 and Phe466. A molecule of l-proline was observed near the FAD, and this ligand superimposed well with isatin, a reversible inhibitor of MAO-B, when the structures of MAO-N proline and MAO-B-isatin were overlaid. Of the mutations that confer the ability to catalyse the oxidation of secondary amines in MAO-N-D3, Asn336Ser reduces steric bulk behind Trp430 of the aromatic cage and Ile246Met confers greater flexibility within the substrate binding site. The two additional mutations, Thr384Asn and Asp385Ser, that occur in the MAO-N-D5 variant, which is able to oxidise tertiary amines, appear to influence the active-site environment remotely through changes in tertiary structure that perturb the side chain of Phe382, again altering the steric and electronic character of the active site near FAD. The possible implications of the change in steric and electronic environment caused by relevant mutations are discussed with respect to the improved catalytic efficiency of the MAO-N variants described in the literature.
黑曲霉单胺氧化酶(MAO-N)是一种黄素酶,可催化伯胺的氧化脱氨反应。MAO-N已被用作一系列定向进化实验的起始模型,产生了活性提高和底物特异性更广泛的突变体,当作为化学酶促氧化还原循环的一部分使用时,适用于伯胺、仲胺和叔胺的制备性消旋化。使用对截短的MAO-N-D5酶的硒代甲硫氨酸衍生物进行的多波长反常衍射实验,获得了一个三点突变体(Asn336Ser/Met348Lys/Ile246Met或MAO-N-D3)和一个五点突变体(Asn336Ser/Met348Lys/Ile246Met/Thr384Asn/Asp385Ser或MAO-N-D5)的结构。MAO-N以同四聚体形式存在,其中心有一个大通道,与人单胺氧化酶B(MAO-B)具有一些结构特征。一个疏水腔从蛋白质表面延伸到活性位点,一个非共价结合的黄素腺嘌呤二核苷酸(FAD)位于一个“芳香笼”的底部,其侧面由Trp430和Phe466形成。在FAD附近观察到一个L-脯氨酸分子,当MAO-N脯氨酸和MAO-B-异吲哚酮的结构叠加时,该配体与MAO-B的可逆抑制剂异吲哚酮很好地重叠。在赋予MAO-N-D3催化仲胺氧化能力的突变中,Asn336Ser减少了芳香笼中Trp430后面的空间位阻,Ile246Met赋予底物结合位点更大的灵活性。在能够氧化叔胺的MAO-N-D5变体中发生的另外两个突变Thr384Asn和Asp385Ser,似乎通过三级结构的变化远程影响活性位点环境,这种变化扰乱了Phe382的侧链,再次改变了FAD附近活性位点的空间和电子特性。关于文献中描述的MAO-N变体催化效率的提高,讨论了相关突变引起的空间和电子环境变化的可能影响。
