Esther Peña

Molecular and cellular mechanisms involved in cardiac remodeling after acute myocardial infarction

The extent of cardiac remodeling determines survival after acute MI. However, the mechanisms driving cardiac remodeling remain unknown. We examined the effect of ischemia and reperfusion (R) on myocardial changes up to 6 days post-MI. Pigs underwent 1.5h or 4h mid-LAD balloon occlusion and sacrificed or 1.5h occlusion followed by R and sacrificed at 2.5h, 1 day, 3 days, and 6 days. Ischemic- (IM) and non-ischemic myocardium (NIM) was obtained for molecular analysis of: 1) apoptosis (P-Bcl2, Bax, P-p53, active-caspase-3); 2) the TLR-4-MyD88-dependent and independent pathways; 3) Akt/mTOR/P70(S6K) axis activation; and, 4) fibrosis (TGF-β, collagen1-A1/A3). Histopathology for inflammation, collagen, and fibroblast content, TUNEL staining, and metalloproteinase activity was performed. Apoptosis is only detected upon R in IM cardiomyocytes and progresses up to 6 days post-R mainly associated with infiltrated macrophages. The Akt/mTOR/P70(s6K) pathway is also activated upon R (IM) and remains elevated up to 6 days-R (P<0.05). Ischemia activates the TLR-4-MyD88-dependent (cytokines/chemokines) and -independent (IRF-3) pathways in IM and NIM and remains high up to 6 days post-R (P<0.05). Accordingly, leukocytes and macrophages are progressively recruited to the IM (P<0.05). Ischemia up-regulates pro-fibrotic TGF-β that gradually rises collagen1-A1/-A3 mRNA with subsequent increase in total collagen fibrils and fibroblasts from 3 days-R onwards (P<0.005). MMP-2 activity increases from ischemia to 3 days post-R (P<0.05). We report that there is a timely coordinated cellular and molecular response to myocardial ischemia and R within the first 6 days after MI. In-depth understanding of the mechanisms involved in tissue repair is warranted to timely intervene and better define novel cardioprotective strategies.

Monomeric C-reactive protein is prothrombotic and dissociates from circulating pentameric C-reactive protein on adhered activated platelets under flow

AIMSnWe previously reported that C-reactive protein bioactivity on thrombogenesis was based on loss of its pentameric symmetry, resulting in formation of monomeric C-reactive protein. Our purpose was to provide mechanistic information on the direct effects of C-reactive protein isoforms on platelet activation and provide a C-reactive protein dissociation mechanism in circulating blood.nnnMETHODS AND RESULTSnC-reactive protein-induced platelet activation was evaluated by flow cytometry. Platelet aggregation, clot properties, and coagulation were also measured. Washed platelets were incubated with C-reactive protein isoforms and vasodilator-stimulated phosphoprotein (VASP) phosphorylation was analysed by western blot and immunofluorescence. C-reactive protein dissociation under flow was evaluated by confocal microscopy on the surface of adhered platelets after perfusing human blood containing pentameric C-reactive protein at different shear rates. Dissociated monomeric C-reactive protein thrombogenicity was measured in flow experiments. Platelet aggregation and flow cytometry analysis revealed that monomeric C-reactive protein significantly induced platelet aggregation, surface P-selectin and CD63 exposure, and glycoprotein IIb-IIIa activation, whereas pentameric C-reactive protein was unable to produce any effect. p38 mitogen-activated protein kinase (MAPK) and Jun N-terminal kinase (JNK) inhibitors, as well as CD36 blocking antibody partially inhibited monomeric C-reactive protein-induced platelet activation and aggregation. Additionally, monomeric C-reactive protein significantly induced VASP dephosphorylation at serine 239. We found that pentameric C-reactive protein dissociated into monomeric C-reactive protein on the surface of activated adhered platelets under flow conditions and that this generated monomeric C-reactive protein promoted further platelet recruitment.nnnCONCLUSIONSnThese data indicate that whereas serum pentameric C-reactive protein may not affect platelet activation, monomeric C-reactive protein, which dissociates from pentameric C-reactive protein on the surface of activated platelets, could contribute to atherothrombotic complications by promoting thrombosis.

Induction of RISK by HMG-CoA reductase inhibition affords cardioprotection after myocardial infarction

OBJECTIVESnCoronary occlusion and revascularization leads to myocardial damage and heart function deterioration. Statins can regress atherosclerosis and modulate platelet function, but their effect on post-acute myocardial infarction (AMI) injury remains to be fully determined. We sought to examine whether rosuvastatin (R) exerts any effect on the RISK/apoptosis pathway when administered early after coronary reperfusion.nnnMETHODSnPigs were fed 10 days a hypercholesterolemic diet before AMI induction and thereafter for 7 days randomly distributed to receive R or placebo (C) with the same diet. At sacrifice, hearts were sliced and alternatively collected for MI size and molecular analysis (gene and protein expression) in the peri-infarcted and remote myocardium. The RISK components (PKC, Erk2, and Akt/PKB) and downstream targets (HIF-1alpha and VEGF), and cell survival/apoptosis markers (Bcl-2, Bax, and Caspase-3) were analyzed. Annexin-V, Mito-Tracker staining, and inflammatory infiltration were also evaluated.nnnRESULTSnR enhanced PKC, Erk2, Akt/PKB and its downstream effectors, and attenuated inflammation and cardiomyocyte apoptosis in the peri-infarcted zone (p<0.05). No changes were detected in the remote myocardium. Infarct size was smaller in R than in C pigs (7% absolute reduction; 36% relative reduction; p<0.05) and was associated with an absolute 12% recovery of LVEF (24% relative restoration; p<0.05 vs. post-AMI).nnnCONCLUSIONSnHMG-CoA inhibition early after reperfusion activates RISK kinases, reduces the extent of damaged myocardium, and improves heart function.

Changes in thrombus composition and profilin-1 release in acute myocardial infarction

AIMnThrombus formation is a dynamic process regulated by flow, blood cells, and plasma proteins. The present study was performed to investigate the characteristics of human coronary thrombus in ST-segment elevation myocardial infarction (STEMI).nnnMETHODS AND RESULTSnPatients admitted with ST-elevation myocardial infarction, in which thrombectomy was performed, were included (n = 86). Intracoronary thrombi and blood from the culprit coronary site and the systemic circulation were obtained during percutaneous coronary intervention (PCI). Thrombi were categorized by onset-of-pain-to-PCI elapsed time in thrombus of <3 (T3) and more than 6 h of evolution (T6). Clinical, morphological, and proteomic variables were investigated. While T3 were mainly composed by platelets and fibrin(ogen), T6 were characterized by a reduced platelet content, increased leucocytes infiltration (including monocytes, neutrophils, T-cells, and B-cells), and appearance of undifferentiated progenitor cells. Significant differences between T3 and T6 were found in the cell cytoskeleton-associated proteome (beta-actin and tropomyosin 3 and 4). By discovery proteomics, we have identified profilin-1 (Pfn-1) in the coronary thrombi and detected higher levels in T3 than in T6. While plasma Pfn-1 levels were low in T3 patients, levels significantly increased in both coronary and peripheral circulation in T6 patients indicating release. In vitro platelet aggregation studies showed that platelets secrete Pfn-1 upon complete activation.nnnCONCLUSIONnCoronary thrombi show rapid dynamic changes both in structure and cell composition as a function of elapsed onset-of-pain-to-PCI time. Aged ischaemic thrombi were more likely to have reduced Pfn-1 content releasing Pfn-1 to the circulation. Onset-of-pain-to-PCI elapsed time in STEMI patients and hence age of occlusive thrombus can be profiled by Pfn-1 levels found in the peripheral circulation.

Subcellular localization of tissue factor and human coronary artery smooth muscle cell migration.

Summary.u2002 Background:u2002Tissue factor (TF) is the most relevant physiological trigger of thrombosis. Additionally TF is a transmembrane receptor with cell signaling functions. Objectives:u2002The aim of this study was to investigate TF subcellular localization, function and signaling in human coronary artery smooth muscle cell migration. Methods:u2002Coronary arteries and primary cultures of vascular smooth muscle cells (HVSMC) were obtained from human explanted hearts. Wound repair and Boyden chamber assays were used to measure migration in vitro. TF‐pro‐coagulant activity (TF‐PCA) was measured in extracted cellular membranes. Analysis of TF distribution was performed by confocal microscopy. A nucleofector device was used for TF and protease activated receptor 2 (PAR2) silencing. mRNA levels were analyzed by RT‐PCR. Results:u2002In migrating HVSMC TF translocates to the leading edge of the cells showing an intense patch‐like staining in the lamellipodia. In the migrating front TF colocalizes with filamin (FLN) in the polarized lipid rafts. TF‐PCA was increased in migrating cells. Silencing of the TF gene inhibits RSK‐induced FLN‐Ser‐2152 phosphorylation, down‐regulates CDC42, RhoA, and Rac1 protein expression and significantly inhibits cell migration. Silencing PAR2 also inhibits cell migration; however, silencing both TF and PAR2 induces a significantly higher effect on migration. Smooth muscle cells expressing TF have been identified in non‐lipid‐rich human coronary artery atherosclerotic plaques. Conclusions:u2002TF translocates to the cell front in association with cytoskeleton proteins and regulates HVSMC migration by mechanisms dependent and independent of factor (F)VIIa/PAR2. These results extend the functional role of TF to smooth muscle cell trafficking in vessel wall remodeling.

Microparticle Shedding from Neural Progenitor Cells and Vascular Compartment Cells Is Increased in Ischemic Stroke

Purpose Ischemic stroke has shown to induce platelet and endothelial microparticle shedding, but whether stroke induces microparticle shedding from additional blood and vascular compartment cells is unclear. Neural precursor cells have been shown to replace dying neurons at sites of brain injury; however, if neural precursor cell activation is associated to microparticle shedding, and whether this activation is maintained at long term and associates to stroke type and severity remains unknown. We analyzed neural precursor cells and blood and vascular compartment cells microparticle shedding after an acute ischemic stroke. Methods Forty-four patients were included in the study within the first 48h after the onset of stroke. The cerebral lesion size was evaluated at 3–7 days of the stroke. Circulating microparticles from neural precursor cells and blood and vascular compartment cells (platelets, endothelial cells, erythrocytes, leukocytes, lymphocytes, monocytes and smooth muscle cells) were analyzed by flow cytometry at the onset of stroke and at 7 and 90 days. Forty-four age-matched high cardiovascular risk subjects without documented vascular disease were used as controls. Results Compared to high cardiovascular risk controls, patients showed higher number of neural precursor cell- and all blood and vascular compartment cell-derived microparticles at the onset of stroke, and after 7 and 90 days. At 90 days, neural precursor cell-derived microparticles decreased and smooth muscle cell-derived microparticles increased compared to levels at the onset of stroke, but only in those patients with the highest stroke-induced cerebral lesions. Conclusions Stroke increases blood and vascular compartment cell and neural precursor cell microparticle shedding, an effect that is chronically maintained up to 90 days after the ischemic event. These results show that stroke induces a generalized blood and vascular cell activation and the initiation of neuronal cell repair process after stroke. Larger cerebral lesions associate with deeper vessel injury affecting vascular smooth muscle cells.

HMG-CoA reductase inhibition prior reperfusion improves reparative fibrosis post-myocardial infarction in a preclinical experimental model☆

BACKGROUNDnStudies in patients support a beneficial effect of statin treatment early after acute coronary syndrome and/or prior percutaneous coronary intervention. However, statin effect during total occlusion remains unknown.nnnOBJECTIVESnTo investigate whether infusion of activated simvastatin during ischemia and prior reperfusion and oral administration thereafter confers cardioprotection and improves cardiac healing in a preclinical model of myocardial infarction.nnnMETHODSnPigs (n=24) fed a 10 day Western-type diet underwent a 90 min coronary-balloon occlusion (MI) being randomized to a single intravenous infusion of active β-hydroxy acid derivative of simvastatin (β-OH-S; 0.3 mg/kg) 15 min prior to reperfusion or vehicle. Animals were either sacrificed 2.5 h post-reperfusion or kept under the same regime ± simvastatin (p.o., 20 mg/day) for 3 weeks. Jeopardized and remote myocardium was obtained for molecular/histological studies. Echocardiography was assessed.nnnRESULTSnβ-OH-S infusion prior to reperfusion reduced coronary and cardiac oxidative DNA-damage, diminished neutrophil infiltration at the site of ischemia, preserved mitochondrial membrane potential and reduced apoptosis in the ischemic myocardium (lower mRNA levels of Fas, casp8, p53, and casp3 and mitochondrial-p-Bcl2; and reduced TUNEL and active caspase-3; p<0.05 vs. vehicle/control). This treatment regime attenuated reperfusion-related arrhythmias and stunning leading to a 40% increased myocardial salvage (p<0.05 vs. vehicle/control). 3 weeks post-MI simvastatin-treated animals showed P-PKCε increase, lower intramyocardial lipotoxicity, TβRII/Smad2/3 signaling restoration and subsequent myofibroblast differentiation and collagen-fibril formation in the evolving scar (p<0.05 vs. control). Simvastatin suppressed cardiac RhoA mobilization and triggered Akt/eNOS signaling.nnnCONCLUSIONSnAcute HMG-CoA-reductase inhibition during total ischemia and prior reperfusion limits reperfusion injury and prolonged oral simvastatin treatment thereafter improves cardiac healing post-MI.

Tissue factor induces human coronary artery smooth muscle cell motility through Wnt-signalling.

Tissue factor (TF) is the most relevant physiological trigger of thrombosis contributing to the presentation of clinical ischemic events after plaque rupture. However, the role of human vascular smooth muscle cell (HVSMC) TF in vascular remodeling, restenosis and atherosclerosis is less known. We have hypothesized that TF contributes to atherosclerotic lesion formation, triggering smooth muscle cell migration through a specific yet unknown signaling pathway.

Aggregated low‐density lipoprotein induce impairment of the cytoskeleton dynamics through urokinase‐type plasminogen activator/urokinase‐type plasminogen activator receptor in human vascular smooth muscle cell

Summary.u2002 Background:u2002 Urokinase‐type plasminogen activator (UPA) regulates vascular smooth muscle cell (VSMC) functions relevant in vascular remodeling by facilitating proteolysis at the cell surface and inducing cell signaling pathways. Our previous results demonstrated that aggregated low‐density lipoprotein (agLDL) impair cytoskeleton dynamics, a key event contributing to VSMC behavior during progression of atherosclerotic plaques.

Allogenic adipose-derived stem cell therapy overcomes ischemia-induced microvessel rarefaction in the myocardium: systems biology study

BackgroundMyocardial microvascular loss after myocardial infarction (MI) remains a therapeutic challenge. Autologous stem cell therapy was considered as an alternative; however, it has shown modest benefits due to the impairing effects of cardiovascular risk factors on stem cells. Allogenic adipose-derived stem cells (ASCs) may overcome such limitations, and because of their low immunogenicity and paracrine potential may be good candidates for cell therapy. In the present study we investigated the effects of allogenic ASCs and their released products on cardiac rarefaction post MI.MethodsPig subcutaneous adipose tissue ASCs were isolated, expanded and GFP-labeled. ASC angiogenic function was assessed by the in-vivo chick chorioallantoic membrane (CAM) model. Pigs underwent MI induction and 7xa0days after were randomized to receive: allogenic ASCs (intracoronary infusion); conditioned media (CM; intravenous infusion); ASCsu2009+u2009CM; or PBS/placebo (control). Cardiac damage and function were monitored by 3-T cardiac magnetic resonance imaging upon infusion (baseline CMR) and 1 and 3xa0weeks thereafter. We assessed in the myocardium: microvessel density; angiogenic markers (CD105, CD31, TF, VEGFR2, VEGFR1, vWF, eNOS, CD62); collagen deposition; and reparative fibrosis (TGFβ/TβRII/collagen). Differential proteomics of ASCs and CM was performed to characterize the ASC protein signature.ResultsCAM indicated a significant ASC proangiogenic capacity. In pigs after MI, only PBS/placebo animals displayed an impaired cardiac function 3xa0weeks after infusion (pu2009<u20090.05 vs baseline). Administration of ASCsu2009+u2009CM significantly enhanced neovessel formation and favored cardiac repair post MI (pu2009<u20090.05 vs the other groups). Molecular markers of angiogenesis were significantly upregulated both at transcriptional and protein levels (pu2009<u20090.05). The in-silico bioinformatics analysis of the ASC and CM proteome (interactome) indicated activation of a coordinated protein network involved in the formation of microvessels and the resolution of rarefaction.ConclusionCoadministration of allogenic ASCs and their CM synergistically contribute to the neovascularization of the infarcted myocardium through a coordinated upregulation of the proangiogenic protein interactome.