Abstract
Cardiovascular diseases (CVD) are the leading cause of premature death and disability in humans that are closely related to lipid metabolism and signaling. This study aimed to assess whether circulating lysophospholipids (LPL), lysophosphatidic acids (LPA) and monoacylglycerols (MAG) may be considered as potential therapeutic targets in CVD. For this objective, plasma levels of 22 compounds (13 LPL, 6 LPA and 3 MAG) were monitored by liquid chromatography coupled with tandem mass spectrometry (HPLC/MS2) in different rat models of CVD, i.e., angiotensin-II-induced hypertension (HTN), ischemic chronic heart failure (CHF) and sugen/hypoxia(SuHx)-induced pulmonary hypertension (PH). On one hand, there were modest changes on the monitored compounds in HTN (LPA 16:0, 18:1 and 20:4, LPC 16:1) and CHF (LPA 16:0, LPC 18:1 and LPE 16:0 and 18:0) models compared to control rats but these changes were no longer significant after multiple testing corrections. On the other hand, PH was associated with important changes in plasma LPA with a significant increase in LPA 16:0, 18:1, 18:2, 20:4 and 22:6 species. A deleterious impact of LPA was confirmed on cultured human pulmonary smooth muscle cells (PA-SMCs) with an increase in their proliferation. Finally, plasma level of LPA(16:0) was positively associated with the increase in pulmonary artery systolic pressure in patients with cardiac dysfunction. This study demonstrates that circulating LPA may contribute to the pathophysiology of PH. Additional experiments are needed to assess whether the modulation of LPA signaling in PH may be of interest.
Highlights
Cardiovascular diseases (CVD) are the leading cause of mortality and a major contributor to disability
Impact of lysophosphatidic acids (LPA) on Pulmonary Artery Smooth Muscle Cell (PA-SMC) Proliferation To better evaluate whether LPA species may be involved in the pathophysiology of pulmonary hypertension (PH), we investigated their impact on the proliferation of human pulmonary artery smooth muscle cells (PA-SMC) derived from PH and control patients using 5-bromo-2-deoxyuridine (BrdU) incorporation (Figure 6A,B, respectively)
We aimed to determine if LPA levels are associated with estimated pulmonary artery systolic pressure (PAPs) determined by transthoracic echocardiography in 90 patients with cardiac dysfunction followed in the Department of Cardiology of Rouen University Hospital
Summary
Cardiovascular diseases (CVD) are the leading cause of mortality and a major contributor to disability. Metabolites 2021, 11, x FOR PEER REVI9EWinhibitors confirms the close link between atherosclerosis, CVD2aonf 1d9 lipid metabolism and it is well admitted that those strategies significantly reduce long-term mortality and morbidity, especially in the elderly [3,4,5]. MCoVrbDidittryi,gegspeercitahlley ipnrtohde uelcdteirolyn[o3–f5o].xMidosizt elidpidlos wcir-cduelantesithtyroluigphobplrooodtestirnea(mo,xe-iL- DL) and oxidized mthliaepcrorforpemeroooltreecbiuonlua(nrad)co(tmooxoptLlhepexre(sam)oo)flwelicpuhildiecsshiannbcdleucpdorionmtgeeianlhbs uiwgmihtihnlyaoreclenipnrtoircpahrloehtdyeidnirsno.pLohixpoiobdpicirzocetoedrienpscoahnroe-spholipids (ox-PL) tadinisinpglanyoinn-pgoplarroli-paidths esurochgeasntircigplyrcoepriedretsiaensd[6ch–o8l]e.stOerxol-PesLterasrseuerrsopuencdieadllbyy parhoyn- e to hydrolysis by dtrhoephliilpicolapyreortceoimnpaossseodcoifatpehdospphhoolisppidhs,oflriepeacsheolAes2ter(oLlpa-nPdLaApo2l)ip, oaplrsootekinns.oCwVnD as serum platelettraicgtgievrathtienpgrofdauccttoiorn-aocfeotxyildihzeyddlroowla-dseens(iPtyAlFip-oAprHot)e,inan(oxin-LflDaLm) amndatooxirdyizmedalripkoe-r of CVD, leading ptrootethine(a)r(eolxeLaps(ea))owf hbicohtbhecooxmiedhizigehdly feantrticyheadciindosxiadnizdedlpyhsoospphhoolisppidhso(olixp-PidL)sdi(sL- PL) [9,10]. These playing pro-atherogenic properties [6,7,8]. LPA metabolism kinsocwonmtopcloenxtrwibuitthe tvoaarthioeruosscalenroasbiso[l1ic2,1a3n].dHcoawteavbeor,ltihcepraoltehowf LaPyLs.inTtheepreatahorephfyosu- r major enzymatic ioplaogthywofamyasnyfoorthLerPCAVDprhoasdbuecentipoono:rltyheevaeluxattreadc[e1l4l–u1l7a].rLLPAPLm-eatuabtooltisamxiins c(oLmPpLle-xATX) pathway (1), wfothirtheLPvpAahrioposruopsdhaunacattbiiodonlii:cctaahncediedxc-atprtaahcbeoolslliupclhapraotLlhiPpwLaa-aysues.topTthaaetxrhienwa(rLaePyfLo(-uPArATmX-Pa)jLopraAtehn1w/zyaPmyLa(A1ti)c2, )ptha(e2th)pw,htaohyses- monoacylglycerol pkhiantiadsicea(cMid-AphGosKp)hopliaptahsewpaaythw(3a)ya(PnAd-PtLhAe1/dPeLAn2o)v(2o),gtlhyecmeroonpoahcoylsgplyhceartoel kaicnyaslteransferase (GPAT) (pMaAtGhKw)apyath(4w)a.y A(3)manodntghsetdethnoevsoeglpyacetrhowphaoyspshraetespacoynltrsainbslfeerfaoser (LGPPAAT)ppraotdhwuacytion, the last three (4a)r.eAimnotrnagcstetlhluesleapraathnwdaryesvreesrpsoinbslieblwe fiotrhLtPhAepirnotdeurcvtieon,titohenlaosft lthyrseoeparheoisnptrhacaetl-idic acid acyltranslufelarrasaensd(LrePvAerAsibTl)e, lwipitihdtphehoinstperhvaetnetiopnhoosfplhysaotpahsoessp(hLatPidPic) aancidd laycsyoltprahnosfseprahsoeslipases (lysoPL) for (wpLaPayAth(A2w)T, )(a,3yl)ipa(in2dd)p,(h4(3)o,s)rpeahsnpadteectp(i4vh)eo,lsyrpe(hFsaiptgauesrceesti1(vL)eP[1lPy8)].a(nFdiglyusroeph1o)s[p1h8o]l.ipases (lysoPL) for path-
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