Fadaei Reza, Bernstein Annie C, Jenkins Andrew N, Pickens Allison G, Zarrow Jonah E, Alli-Oluwafuyi Abdul-Musawwir, Tallman Keri A, Davies Sean S
Department of Pharmacology, Vanderbilt University. Nashville, TN, USA, 37232.
College of Arts and Sciences, Vanderbilt University, Nashville, TN, USA.
bioRxiv. 2024 Nov 1:2024.10.30.621135. doi: 10.1101/2024.10.30.621135.
-acyl phosphatidylethanolamine-hydrolyzing phospholipase D (NAPE-PLD) hydrolyzes phosphatidylethanolamines (PE) where the headgroup nitrogen has been enzymatically modified with acyl chains of four carbons or longer (-acyl-PEs or NAPEs). The nitrogen headgroup of PE can also be non-enzymatically modified by reactive lipid aldehydes, thus forming -aldehyde modified-PEs (NALPEs). Some NALPEs such as -carboxyacyl-PEs are linked to PE via amide bonds similar to NAPEs, but others are linked by imine, pyrrole, or lactam moieties. Whether NAPE-PLD can hydrolyze NALPEs was unknown. We therefore characterized the major NALPE species formed during lipid peroxidation of arachidonic acid and linoleic acid and generated various NALPEs for characterization of their sensitivity to NAPE-PLD hydrolysis by reacting synthesized aldehydes with PE. We found that NAPE-PLD could act on NALPEs of various lengths and linkage types including those derived from PE modified by malondialdehyde (-MDA-PE), butane dialdehyde (-BDA-PE), 4-hydroxynonenal (-HNE-PE), 4-oxo-nonenal (-ONE-PE), 9-keto-12-oxo-dodecenoic acid (-KODA-PE), and 15-E-isolevuglandin (-IsoLG-PE). To assess the relative preference of NAPE-PLD for various NALPEs versus its canonical NAPE substrates, we generated a substrate mixture containing roughly equimolar concentrations of the seven NALPEs as well as two NAPEs (-palmitoyl-PE and -linoleoyl-PE) and measured their rate of hydrolysis. Several NALPE species, including the -HNE-PE pyrrole species, were hydrolyzed at a similar rate as -linoleoyl-PE and many of the other NALPEs showed intermediate rates of hydrolysis. These results significantly expand the substrate repertoire of NAPE-PLD and suggest that it may play an important role in clearing products of lipid peroxidation in addition to its established role in the biosynthesis of -acyl-ethanolamines.
酰基磷脂酰乙醇胺水解磷脂酶D(NAPE - PLD)可水解磷脂酰乙醇胺(PE),其中头部基团氮已被四个或更长碳链的酰基链酶促修饰(-酰基-PE或NAPE)。PE的氮头部基团也可被反应性脂质醛非酶促修饰,从而形成-醛修饰-PE(NALPE)。一些NALPE,如-羧酰基-PE,通过与NAPE类似的酰胺键与PE相连,但其他的则通过亚胺、吡咯或内酰胺部分相连。NAPE - PLD是否能水解NALPE尚不清楚。因此,我们对花生四烯酸和亚油酸脂质过氧化过程中形成的主要NALPE种类进行了表征,并通过将合成醛与PE反应生成各种NALPE,以表征它们对NAPE - PLD水解的敏感性。我们发现NAPE - PLD可作用于各种长度和连接类型的NALPE,包括那些由丙二醛(-MDA - PE)、丁二醛(-BDA - PE)、4 - 羟基壬烯醛(-HNE - PE)、4 - 氧代壬烯醛(-ONE - PE)、9 - 酮-12 - 氧代十二碳烯酸(-KODA - PE)和15 - E - 异前列烷素(-IsoLG - PE)修饰的PE衍生而来的NALPE。为了评估NAPE - PLD对各种NALPE与其经典NAPE底物的相对偏好性,我们生成了一种底物混合物,其中包含大致等摩尔浓度的七种NALPE以及两种NAPE(-棕榈酰-PE和-亚油酰-PE),并测量了它们的水解速率。几种NALPE种类,包括-HNE - PE吡咯种类,水解速率与-亚油酰-PE相似,许多其他NALPE显示出中等水解速率。这些结果显著扩展了NAPE - PLD的底物范围,并表明它除了在-酰基乙醇胺的生物合成中已确立的作用外,可能在清除脂质过氧化产物中起重要作用。
