School of Biological Science, Whiteknights Campus, University of Reading, RG6 6AS, UK; Department of Food and Nutritional Sciences, Whiteknights Campus, University of Reading, RG6 6AS, UK.
Biocatalysts Limited, Cefn Coed Parc Nantgarw, Wales CF15 7QQ, UK.
J Struct Biol. 2021 Sep;213(3):107741. doi: 10.1016/j.jsb.2021.107741. Epub 2021 May 12.
Leucyl aminopeptidase A from Aspergillus oryzae RIB40 (AO-LapA) is an exo-acting peptidase, widely utilised in food debittering applications. AO-LapA is secreted as a zymogen by the host and requires enzymatic cleavage of the autoinhibitory propeptide to reveal its full activity. Scarcity of structural data of zymogen aminopeptidases hampers a better understanding of the details of their molecular action of autoinhibition and how this might be utilised to improve the properties of such enzymes by recombinant methods for more effective bioprocessing. To address this gap in the literature, herein we report high-resolution crystal structures of recombinantly expressed AO-LapA precursor (AO-proLapA), mature LapA (AO-mLapA) and AO-mLapA complexed with reaction product l-leucine (AO-mLapA-Leu), all purified from Pichia pastoris culture supernatant. Our structures reveal a plausible molecular mechanism of LapA catalytic domain autoinhibition by propeptide and highlights the role of intramolecular chaperone (IMC). Our data suggest an absolute requirement for IMC in the maturation of cognate catalytic domain of AO-LapA. This observation is reinforced by our expression and refolding data of catalytic domain only (AO-refLapA) from Escherichia coli inclusion bodies, revealing a limited active conformation. Our work supports the notion that known synthetic aminopeptidase inhibitors and substrates mimic key polar contacts between propeptide and corresponding catalytic domain, demonstrated in our AO-proLapA zymogen crystal structure. Furthermore, understanding the atomic details of the autoinhibitory mechanism of cognate catalytic domains by native propeptides has wider reaching implications toward synthetic production of more effective inhibitors of bimetallic aminopeptidases and other dizinc enzymes that share an analogous reaction mechanism.
米曲霉来源的亮氨酰氨基肽酶 A(AO-LapA)是一种外切肽酶,广泛应用于食品脱苦应用。AO-LapA 以酶原的形式由宿主分泌,并需要酶切自身抑制性原肽以揭示其全部活性。由于缺乏酶原氨肽酶的结构数据,因此难以更好地理解其分子自动抑制的细节,以及如何利用这些细节通过重组方法改善此类酶的性质,以实现更有效的生物加工。为了解决文献中的这一空白,本文报道了重组表达的 AO-LapA 前体(AO-proLapA)、成熟的 LapA(AO-mLapA)和 AO-mLapA 与反应产物 l-亮氨酸(AO-mLapA-Leu)的高分辨率晶体结构,所有这些都从毕赤酵母培养上清液中纯化得到。我们的结构揭示了 propeptide 对 LapA 催化结构域自动抑制的合理分子机制,并强调了分子内伴侣(IMC)的作用。我们的数据表明,IMC 是 AO-LapA 同源催化结构域成熟的绝对要求。这一观察结果得到了我们仅从大肠杆菌包涵体表达和复性的催化结构域(AO-refLapA)的表达和复性数据的支持,该数据揭示了有限的活性构象。我们的工作支持了这样一种观点,即已知的合成氨肽酶抑制剂和底物模拟了 propeptide 和相应催化结构域之间的关键极性接触,这在我们的 AO-proLapA 酶原晶体结构中得到了证明。此外,通过天然 propeptides 了解同源催化结构域的自动抑制机制的原子细节,对合成生产具有类似反应机制的更有效的双金属氨肽酶和其他二锌酶抑制剂具有更广泛的意义。
