Angiopoietin-1 Promotes Cardiac and Skeletal Myocyte Survival Through Integrins

doi:10.1161/01.RES.0000158285.57191.60

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Circulation Research. 2005;96:e8-e24
Published online before print February 3, 2005, doi: 10.1161/01.RES.0000158285.57191.60

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(Circulation Research. 2005;96:e8.)
© 2005 American Heart Association, Inc.

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Angiopoietin-1 Promotes Cardiac and Skeletal Myocyte Survival Through Integrins

Susan M. Dallabrida, Nesreen Ismail, Julianne R. Oberle, Blanca E. Himes, Maria A. Rupnick

From the Division of Vascular Biology (S.M.D., N.I., J.R.O., B.E.H., M.A.R.), Children’s Hospital, Boston; Harvard-MIT Division of Health Sciences and Technology (B.E.H.), Cambridge; the Division of Cardiovascular Medicine (M.A.R.), Brigham and Women’s Hospital, Boston; and the Department of Chemical Engineering (M.A.R.), Massachusetts Institute of Technology, Cambridge, Mass.

Correspondence to Maria Rupnick, MD, PhD, Vascular Biology Division, Children’s Hospital, Research Building, Rm RB11-211, 1 Blackfan Circle, Boston, MA 02115. E-mail maria.rupnick{at}childrens.harvard.edu

Abstract

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Cardiac myocyte loss, regardless of insult, can trigger compensatorymyocardial remodeling leading to heart failure. Identifyingmediators of cardiac myocyte survival may advance clinical effortstoward myocardial preservation. Angiopoietin-1 limits ischemia-inducedcardiac injury. This benefit is ascribed to angiogenesis becausethe receptor, tie2, is largely endothelial-specific. We proposethat direct, non-tie2 interactions of angiopoietin-1 on cardiacmyocytes contribute to this cardioprotection. We found thatmouse C2C12 skeletal myocytes lack tie2, yet dose-dependentlyadhered to angiopoietin-1 and angiopoietin-2 similarly to laminin,fibronectin, vitronectin, and more than to collagen-I, -III,and -IV. Adhesion was divalent cation-mediated (Mn²⁺, Ca²⁺,not Mg²⁺), blocked with EDTA/EGTA, RGD-based peptides, and selectintegrin subunit antibodies. Similar findings were obtainedwith human skeletal myocytes (HSMs) and freshly isolated ratneonatal cardiac myocytes (NCMs). Furthermore, angiopoietin-1conferred significant survival advantage exceeding that of mostcell matrices, which was not fully explained by differencesin cell adhesion. Angiopoietin-1 promoted survival of serum-starvedC2C12, HSM, and NCM (MTT, trypan blue) and prevented taxol-inducedapoptosis (caspase-3). Immobilized and soluble angiopoietin-1phosphorylated Akt_S473 and MAPK_p42/44, (not FAK_Y397) in C2C12more than in endothelial cells and more than did angiopoietin-2or cell matrices. EDTA, RGD-based peptides, and some integrinantibodies blocked these responses. Angiopoietin-1 activatedHSM and NCM Akt_S473 and MAPK_p42/44 survival pathways. We proposethat this novel function contributes to developmental and cardioprotectiveactions of angiopoietin-1 presently attributed to vascular effectsalone. Angiopoietin-1 may prove therapeutically valuable incardiac remodeling by supporting myocyte viability and preservingpump function. The full text of this article is available onlineat http://circres.ahajournals.org.

Key Words: angiopoietin-1 • angiopoietin-2 • cardiac myocytes • adhesion molecules • myocyte apoptosis • skeletal myocytes

Introduction

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

There is growing consensus that cardiomyocyte (CM) apoptosiscontributes to many cardiac diseases (eg, ischemia,¹ infarction,²hypertension,³ myocarditis,⁴ transplant rejection,⁵ and heartfailure^6,7 ). Research efforts are directed at defining the incidenceof CM death, the contributions to cardiac dysfunction, and theconsequences of inhibiting apoptosis. Incentive is based onthe rationale that CM loss reduces contractile mass of the heartand may be a preventable catalyst of heart failure. In supportof this concept, low levels of CM apoptosis (23 CM/10⁵ nuclei)cause lethal cardiomyopathy in mice.⁸ CM apoptosis rates arehigher in cardiomyopathy patients (80 to 250 CM/10⁵ nuclei)compared with healthy hearts (1 to 10 CM/10⁵ nuclei).^9,10 Further,ischemic preconditioning upregulates bcl-2, a cytoprotectiveprotein, and is linked to reduced apoptosis.¹¹ Despite amassingexperimental and clinical evidence, mechanisms and signalingpathways in CM apoptosis are largely unexplored. Identifyingregulatory mediators may lead to novel therapies to preservemyocardial function after injury. Toward this goal, we introducea novel function for angiopoietin-1 as a direct cardiac myocytesurvival factor.

Angiopoietin-1 (Ang1) and angiopoietin-2 (Ang2) are secretedproteins that bind the tie2 receptor, which is largely limitedto endothelium.^12,13 Angiopoietins are most noted as regulatorsof vascular maturation. Ang1 associates with matrix and actslocally, whereas Ang2 freely diffuses.¹⁴ Ang1 promotes endothelialcell survival^15,16 and increases mural cell¹⁷ and matrix¹⁸ contactswith vessels to establish quiescence and promote maturation.Ang2 often favors vessel destabilization allowing angiogenesisor regression,¹⁹ at high concentrations acts as a weak agonist,²⁰and is an agonist on lymphatic endothelium.²¹

A role for angiopoietins in cardiovascular health and diseaseis emerging. Ang1 and tie2 knockouts result in embryonic lethalcardiac defects, including impairments in vascular maturationand in endocardial and trabeculae formations.²² A similar phenotypeis produced by transgenic overexpression of Ang2, a competitiveAng1 antagonist.¹⁹ Postnatally, as the heart transitions fromextensive neonatal remodeling to limited adult remodeling, Ang1levels increase.²³ The endothelial-specific tie2 receptor^12,13 is constitutively activated in adult hearts,²⁴ suggesting Ang1may serve a maintenance function for the vasculature.

The Ang/tie2 system is also implicated in cardiac remodelingunder pathological conditions. Expressions of Ang2 increaseafter myocardial infarction^25,26 and hypoxia/reoxygenation injury,²⁷and plasma Ang2 levels are higher in patients with heart failure.²⁸In contrast, Ang1 expressions are reduced in hypoxic myocardium.²⁶Ang1 overexpression in mice, rats, and rabbits with acute myocardialinfarcts reduced infarct sizes and preserved ejection fractions.^29–31 These benefits were ascribed solely to the role of Ang1 in angiogenesisbecause the tie2 receptor is endothelial-specific.^12,13 However,fibroblasts were recently shown to adhere to Ang1 and Ang2 viaintegrins ( ${alpha}$ ₅ß₁, ${alpha}$ _vß₅),³² raising the possibilitythat other nonendothelial cell types, such as CM may directlyinteract with angiopoietins.³³

Integrins are cell surface adhesion receptors composed of ${alpha}$ andß subunits, which combine to form at least 24 heterodimerswith different, although often overlapping, ligands and signalingproperties.³⁴ Integrins are also regulated by dynamic spatialand temporal expression patterns³⁵ and subunit isoforms. Forexample, integrin adhesion, expression, and activation shiftduring cardiac development,³⁶ hypertrophy,³⁵ infarct,³⁷ andfailure.³⁸ Information traffic via integrins is bidirectional,enabling cells to interact with the extracellular matrix (ECM)/environment.Integrins thereby mediate numerous vital CM activities suchas cell shape, adhesion, apoptosis, anoikis, hypertrophy, survival,differentiation, contraction, and conduction.³⁹

In this study, we present the first evidence that cardiac andskeletal myocytes adhere to Ang1 and Ang2 via integrins. Weshow that Ang1 markedly promotes CM survival under stress, andAng1 protects CM from apoptosis. This raises the possibilitythat the cardioprotective benefits of Ang1 overexpression inischemic hearts are due, in part, to direct interactions betweenAng1 and CM, mediated via integrins. If so, angiopoietin regulationmay serve as a novel target for preserving myocyte viabilityafter cardiac insults, impeding heart failure development.

Materials and Methods

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Details of the following methods can be found in the ExpandedMaterials and Methods section of the online data supplementavailable http://circres.ahajournals.org.

Cell Culture
We chose to use the C2C12 cell line (American Tissue CultureCollection) because these transformed mouse skeletal myoblasts,once differentiated, have features of CM such as expressionof cardiac isoforms of contractile proteins and well-organizedmyofibrils.⁴⁰ Further, using a cell line eliminates the possibilityof contaminating cells found in primary cultures. C2C12 cellswere grown in high-glucose (4.5 g/L) DMEM (HG-DMEM) (Gibco)supplemented with 10% heat-inactivated fetal calf serum (FCS)(Hyclone)/0.01 mol/L HEPES (Gibco)/L-glutamine-penicillin G-streptomycinsulfate (GPS) (Gibco) (37°C, 5% CO₂). For adhesion, survival,and caspase-3 assays, C2C12 myoblasts were differentiated tomyocytes by confluence.⁴¹ Cells that were 4 to 7 days postconfluencewere used. Microvascular endothelial Ms1 cells were culturedin low glucose (1.0 g/L) DMEM (LG-DMEM) supplemented with 10%FCS/GPS (37°C, 10% CO₂). Human skeletal muscle primary myoblasts(Cambrex) were grown in Clonetics SkGM BulletKit Medium plusgrowth factors (37°C, 5% CO₂) and differentiated to myocytesby confluence and growth factor withdrawal as per manufacturersinstructions.

Cardiac Myocyte Isolation
Cardiac myocytes were isolated from the ventricles of Sprague-DawleyP2 rat pups (Charles River Laboratories, Wilmington, Mass) followingpublished procedures.⁴² Briefly, ventricles were minced, digestedin 0.6 mg/mL trypsin/EDTA at 4°C overnight, then 1 mg/mLcollagenase for 30 minutes 37°C, and preplated. Myocyteswere collected, rinsed, and grown in LG-DMEM/2% FCS.

RT-PCR
Cells were immersed in RNALater (Ambion). Total RNA was purifiedusing RNeasy mini kits (Qiagen). cDNA was made using AdvantageRT-for-PCR kits (Clontech) with RNA (1 µg). PCR with tie1,tie2, and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) (Invitrogen)primers were performed as we have described.⁴³

Cell Adhesion Assay
Assays were conducted as we⁴⁴ and others³² have described withsome modifications. Human recombinant Ang1 and Ang2 (R&DSystems) were dissolved in 0.1% bovine serum albumin (BSA),fraction V/phosphate-buffered saline (PBS) (Fisher), and thenfurther diluted in PBS at 0 to 400 nmol/L. BSA controls containedcomparable amounts of 0.1% BSA/PBS diluted in PBS. Ang1, Ang2,and BSA control solutions were used to coat wells in 96-wellflat-bottom-tissue culture plates (room temperature, 1 hour).Wells were also coated with human fibronectin, vitronectin,collagen I, collagen III, and mouse laminin and collagen IVas per the manufacturers’ instructions. Wells were blockedfor at least 30 minutes with 0.5% heat-inactivated BSA (10 minutes,80°C)/PBS, rinsed three times with PBS, and prepared cellswere added.

C2C12 myocytes, primary rat neonatal cardiac myocytes (NCMs),and primary human skeletal myocytes (HSMs) were detached withtrypsin/EDTA, rinsed in serum-free medium, plated onto immobilizedproteins, and incubated for 40 minutes. Wells were rinsed, attachedcells fixed, toluidine blue-stained, solubilized, and absorbancesmeasured (650 nm). Values were corrected for background myocyteadhesion to BSA wells. For some assays, adhesion was challengedwith EDTA, EGTA, GRGESP (RGE), or GRGDSP (RGD) peptides, oradhesion-blocking integrin subunit antibodies. Assays were alsodone in which divalent cations were depleted and replaced^44,45 (CaCl₂, MgCl₂, MnCl₂, or no divalent cations).

Cell Survival Assays
A trypan blue assay and an MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-tetrazoliumbromide (Sigma) assay with improved sensitivity were used tomeasure myocyte viability⁴⁶ on immobilized angiopoietins comparedwith the various extracellular matrices. C2C12, HSM, and NCMwere prepared and 96-well plates were coated as described (adhesionassay) using 200 nmol/L solutions to coat the plate surfaces.

Caspase-3 Assay
Apoptosis was measured in C2C12 myocytes, NCMs, and HSMs usinga Caspase Colorimetric Kit (Promega) as per manufacturer’sinstructions. Myocytes were prepared and 96-well plates werecoated as described (adhesion assay). Cells were incubated inserum-free medium on untreated wells (plate) or wells coatedwith 200 nmol/L Ang1, Ang2, matrix component, or BSA for 1 day.Apoptosis was then induced by taxol⁴⁷ in an overnight incubation,and caspase-3 activity was measured.

Cell Signaling
Phosphorylation of Akt (protein kinase B) serine 473 (pAkt_S473),mitogen-activated protein kinase (MAPK) p42/44 (ERK 1/ERK 2)threonine 202/tyrosine 204 (pMAPK_{p42(T202)/44(Y204)}), and focaladhesion kinase (FAK) tyrosine 397 (pFAK_Y397) were measuredin myocytes (C2C12, HSM, NCM) incubated either on immobilizedor in soluble molecules (200 nmol/L Ang1, Ang2, laminin, fibronectin,vitronectin, collagen I, -III, and -IV, BSA) or on the platealone (unmodified tissue culture wells), and examined by Westernblotting. We conducted two types of soluble studies in whichactivation of Akt and MAPK_p42/44 were measured. In one, we added200 nmol/L soluble molecules to cells (C2C12, Ms1) in suspension.In the other, we plated cells (C2C12, HSM, Ms1) onto tissueculture plates, serum-starved cells, added wortmannin to somewells, then added (3.6 or 200 nmol/L) soluble molecules, andmade protein lysates.

Results

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

Skeletal and Cardiac Myocytes Adhere to Ang1 and Ang2
C2C12 mouse skeletal myocytes (Figure 1A), human skeletal myocytes(HSMs, Figure 1B), and rat neonatal cardiac myocytes (NCMs,Figure 1C) all adhered to immobilized Ang1 and Ang2 in a concentration-dependentmanner. In contrast, undifferentiated C2C12 myoblasts did notattach to either angiopoietin (data not shown). The number ofmyocytes adhering to Ang1 versus Ang2 was similar among thecell types.

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Figure 1. Skeletal and cardiac myocytes adhere to Ang1 and Ang2. Mouse C2C12 myocytes (A), human skeletal myocytes (HSM) (B), and rat neonatal cardiac myocytes (NCM) (C) were plated on wells (n=3/group) coated with Ang1, Ang2, laminin, fibronectin, vitronectin, collagens-I, -III, and -IV, or BSA for 40 minutes. Attached myocytes were fixed. Photographs show adherent cells (bar=50 µm). Cells were then stained with toluidine blue, solubilized, and absorbances were measured (650 nm) and corrected for background adhesion to BSA-blocked wells.

We compared myocyte adhesion to angiopoietins to six ECM/basementmembrane (BM) components prominent in the heart (Figure 1).C2C12 myocyte adhesion curves for Ang1, Ang2, laminin, fibronectin,and vitronectin were similar, whereas little adhesion occurredon collagen-I, -III, or -IV (Figure 1A). In contrast, HSMs adheredto all the matrix components and at lower surface coating concentrationsthan to Ang1 or Ang2 (Figure 1B). However, when the plates werecoated with 200 nmol/L of each molecule, the number of adherentHSMs plateaued and was similar on all the surfaces. At thatconcentration, NCM also adhered to Ang1 and Ang2 similarly tomost other matrix molecules, with the exception of superioradhesion to collagen–IV (Figure 1C). The concentrationfor maximum adhesion of myocytes to Ang1 and Ang2 is equal toor less than that for fibroblasts to Ang1/Ang2³² and for endothelialcell (EC) to angiopoietin-like protein-3 (Angptl3),⁴⁸ whichdoes not bind tie2.

Based on these findings, 200 nmol/L coating concentrations wereused for the matrices in subsequent assays. This enabled thefunctional effects of each matrix to be assessed at comparablecell densities. The exceptions were poor adhesion of C2C12 tothe collagens and greater adhesions of NCM to collagen-I and-IV.

Our data shows that mouse, rat, and human myocytes (primarycells, cell lines) interact with human Ang1 and Ang2. This likelyreflects the highly conserved amino acid sequence. Ang1 homologyfor human versus mouse is 97% and for human versus rat is 96%.Human Ang2 is 85% identical to mouse and 86% identical to ratsequence.

Myocyte Adhesion to Ang1/Ang2 Does Not Involve the Tie2 Receptor and Is Inhibited by RGD and EDTA
We conducted RT-PCR of tie2, tie1 (related receptor that doesnot bind angiopoietins), and GAPDH (housekeeping gene) usingMs1 (mouse microvascular endothelial cells), HMVECs (human microvascularendothelial cells), and rat left ventricle (LV) tissue as positivecontrols (tie2, tie1). C2C12 myocytes, HSM, and NCM did notexpress mRNA for tie2 or tie1 (Figure 2A). To determine whethertie2 expression was conditional, we conducted RT-PCR and real-timePCR for tie2 and GAPDH with C2C12 myoblasts and myocytes thatwere cultured in full and serum-free medium. Tie2 mRNA was notdetectable under any condition used in our assays, whereas GAPDHmRNAs were abundant (data not shown). Thus, angiopoietin/myocyteinteractions do not involve tie2.

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Figure 2. Myocyte adhesion to Ang1 and Ang2 does not involve the tie2 receptor and is blocked by EDTA and RGD peptides. A, mRNA expressions (RT-PCR) of tie2, tie1, Ang1, Ang2, and GAPDH in C2C12 myocytes (C2C12), Ms1 microvascular endothelial cells (Ms1), human skeletal myocytes (HSM), human microvascular endothelial cells (HMVEC), rat neonatal cardiac myocytes (NCM), mouse left ventricle (LV), human heart, and rat LV were measured. B and C, Cell adhesion assays were conducted with C2C12 myocytes (n=3/group per study; studies done in duplicate) and adhesion quantified using toluidine blue absorbances. B, Myocytes were preincubated with PBS (Control), 10 mmol/L EDTA or EGTA, or 500 µg/mL GRGESP (RGE) or GRGDSP (RGD) peptides diluted in PBS. Myocyte adhesion to Ang1 and Ang2 was blocked with EDTA, EGTA, and RGD-based peptides (*P $≤$ 0.003 Ang1; #P $≤$ 0.003 Ang2). C, Divalent cations were depleted and then myocytes were put in serum-free media with no divalent cations (No Cations²⁺) or 2 mmol/L CaCl₂, MnCl₂, or MgCl₂. Myocyte adhesion to Ang1 and Ang2 was mediated by Ca²⁺ and Mn²⁺ (*P $≤$ 0.004 Ang1; #P $≤$ 0.007 Ang2), but not Mg²⁺.

We measured Ang1 and Ang2 mRNA expressions in C2C12 myocytes,NCM, and HSM using mouse, rat, and human heart as positive controls.Skeletal and cardiac myocytes express Ang1 mRNAs (Figure 2A).Only C2C12 myocytes express Ang2 transcripts.

We propose that integrins mediate myocyte interactions withAng1 and Ang2. Integrin adhesions require divalent cations with3 to 5 divalent cation binding sites per integrin heterodimer.⁴⁹Integrins also require an exposed aspartic (D) or glutamic acid(E) in the ligand.⁵⁰ There are different D-based (LDV, RTD,REDV, KRLDGS) and E-based (LRE)⁴⁹ motifs, but RGD-based motifsare most common. Requiring divalent cations and antagonism byRGD peptides would support a role for integrins in mediatingmyocyte-angiopoietin interactions.

C2C12 myocyte adhesion to Ang1 and Ang2 were significantly blockedby RGD-based peptides (74.1±7.5%, 89.2±10.1%),EDTA (96.0±1.5%, 95.8±3.7%), and EGTA (95.5±5.8%,91.8±3.0%) (Figure 2B). EDTA nonspecifically chelatesdivalent cations, whereas EGTA has a higher affinity for Ca²⁺than Mg²⁺. To define the divalent cations mediating C2C12 myocyteadhesion to Ang1 and Ang2, we examined the effects of Ca²⁺,Mg²⁺, Mn²⁺, and no divalent cations.^44,45 Mn²⁺ and Ca²⁺ supportedadhesion to Ang1 and Ang2, but Mg²⁺ did not (Figure 2C). Ca²⁺occupies divalent cation sites in many integrins.⁵¹ Mn²⁺ activatesintegrins, increasing the kinetic "on" rate.^45,52 A determinantof integrin high-affinity binding (firm adhesion) to a ligandis activation from a low to high affinity state, involving aconformational change.⁵⁰ Overall, these findings suggest thatmyocyte adhesion to Ang1 and Ang2 is integrin-mediated.

Integrins Mediate Skeletal and Cardiac Myocyte Adhesion to Ang1 and Ang2
To assess whether integrins mediate the attachment of C2C12myocytes, NCM, and HSM to Ang1 and Ang2, we conducted adhesionassays using adhesion-blocking integrin antibodies. C2C12 myocyteadhesion to Ang1 was inhibited by ${alpha}$ ₆ (93.5%±5.6%), ß₃(53.9%±13.6%), ß₁ (44.1%±11.5%), ${alpha}$ ₁ (39.9%±4.1%),and ${alpha}$ _v (35.1%±2.7%), but not ${alpha}$ ₄ or ${alpha}$ ₅ antibodies (Figure 3A).Adhesion to Ang2 was blocked by ß₃ (71.1%±2.5%),ß₁ (66.7%±1.8%), ${alpha}$ ₆ (61.3%±1.7%), ${alpha}$ ₁ (39.3%±8.8%),and ${alpha}$ ₅ (36.9%±5.9%), but not ${alpha}$ ₄ or ${alpha}$ _v antibodies (Figure 3A).Integrin subunits ${alpha}$ ₆ and ß₃ appear to be key mediatorsof C2C12 myocyte adhesion. Subunit ${alpha}$ ₆ can pair with ß₁or ß₄. Currently, no anti-mouse adhesion-blockingß₄ integrin subunit antibodies are commercially available,so we were unable to further analyze ${alpha}$ ₆ involvement using thismethod. Integrin subunit ß₃ only complexes with ${alpha}$ _v,except for platelets where ß₃ complexes with ${alpha}$ _IIb.In line with our results that ß₃ mediates adhesion, ${alpha}$ _vß₃ mediates HMVEC adhesion to Angptl3.⁴⁸ NCM adhesionto Ang1 was inhibited by ß₁ (81.3%±3.8%) andß₃ (67.1%±14.4%), but not ${alpha}$ ₁ antibody (Figure 3B).NCM adhesion to Ang2 was also blocked by ß₁ (67.5%±7.7%)and ß₃ (91.9%±6.9%), but not ${alpha}$ ₁ antibody (Figure 3B).Again, further analysis was limited by a lack of commerciallyavailable anti-rat integrin antibodies.

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Figure 3. Integrins mediate skeletal and cardiac myocyte adhesion to Ang1 and Ang2. C2C12 myocytes (A), NCMs (B), or HSMs (C) were preincubated with PBS (control) or 50 µg/mL of different integrin antibodies diluted in PBS (n=3/group per study; studies done in duplicate), and adhesion to Ang1 and Ang2 was quantified using toluidine blue absorbances. Antibodies reducing cell adhesion to Ang1 or Ang2 are indicated (*P $≤$ 0.03 Ang1; #P $≤$ 0.03 Ang2).

To better define the integrins involved, we examined HSMs, whichenabled use of human antibodies ( ${alpha}$ ₁ to ${alpha}$ ₆, ${alpha}$ _v, ß₃ toß₄, ${alpha}$ _vß₃, ${alpha}$ _vß₅, ${alpha}$ _vß₆).HSM adhesion to both Ang1 and Ang2 was markedly blocked by antibodies( ${alpha}$ ₂, ${alpha}$ ₅, ${alpha}$ _v) followed by (ß₃, ß₄) (Figure 3C).Anti- ${alpha}$ ₆ significantly inhibited adhesion to Ang1, but not Ang2.EDTA considerably blunted HSM adhesion to Ang1 and Ang2, showingthe need for divalent cations (Figure 3C).

In mouse (C2C12), rat (NCM), and human (HSM) myocyte studies,ß₃ antibodies, consistently blocked adhesion, whereasantibody LM609 ( ${alpha}$ _vß₃) did not. This suggests that although ${alpha}$ _vß₃ may be a receptor for Ang1/Ang2 on myocytes, theinteraction may be somewhat different than that seen in othersystems. For example, LM609 inhibited the interaction betweenAngptl3 and HMVECs.⁴⁸

HSM studies also implicated ${alpha}$ ₂ß₁, ${alpha}$ ₅ß₁, ${alpha}$ ₆(ß₄and/or ß₁), and perhaps, ${alpha}$ _vß₁, as integrinsthat mediate myocyte interactions with Ang1 and Ang2. Fibroblastsadhere to Ang1 and Ang2 mainly via ${alpha}$ ₅ß₁ and ${alpha}$ _vß₅integrins.³² The only prevalent CM integrin not tested was ${alpha}$ ₇because of a lack of a commercially available antibody.

Ang1 Promotes Skeletal and Cardiac Myocyte Survival
To assess the function of integrin-mediated myocyte adhesionto Ang1 and Ang2, we conducted trypan blue and MTT-based viability/survivalassays. Myocytes were incubated in serum-free medium on thevarious matrices (200 nmol/L) for 1 day. Overall, Ang1 promotedC2C12 myocyte, HSM, and NCM viability (trypan blue) better thanor similar to the other matrices tested (Table).

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Table 1. Skeletal and Cardiac Myocyte Viability on Different ECMs

In MTT survival assays, C2C12 myocytes were incubated in serum-freemedium on wells coated with 200 nmol/L Ang1, Ang2, BSA, fibronectin,or laminin, or plate (unmodified tissue culture well). Photomicrographs(day 1 and 4 shown) (Figure 4A) show that myocytes on BSA didnot spread, but rather remained rounded, aggregated, and died.In contrast, myocytes on Ang1, Ang2, and plate spread, maintaininga normal morphology the first 2 days. Thereafter, myocytes onAng1 approached confluence, whereas those on Ang2 and platebegan elongating, forming aggregates, and dying. Ang1 promotedC2C12 myocyte survival better than all other conditions (Figure 4B and 4C).

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Figure 4. Ang1 increases skeletal and cardiac myocyte survival. MTT-based survival studies were conducted with (A through C) C2C12 myocytes or (D and E) NCMs. Myocytes were plated in serum-free media (n=3/group per study; studies done in duplicate) on 200 nmol/L (A and B, D and E) Ang1, Ang2, unmodified tissue culture wells (plate), or BSA for 1 to 7 days or (C) on Ang1, fibronectin (FN), or laminin (lam) for 1 day. MTT was quantified by absorbance at 570 nm. A and D, Photomicrographs were taken (bar=100 microns). Increases in C2C12 myocyte survival on Ang1 vs (B) BSA (*P $≤$ 0.001), plate (*P $≤$ 0.001), and Ang2 (*P $≤$ 0.005); (C) fibronectin (*P=0.003) and laminin (**P=0.0001) are indicated. B, Myocyte viability on Ang2 exceeded BSA and plate (#P $≤$ 0.04) on day1. E, Increases in NCM survival on Ang1 vs BSA (*P $≤$ 0.004), plate (*P $≤$ 0.0009), and Ang2 (*P $≤$ 0.0002) are indicated.

To assess if Ang1 enables cardiac myocyte survival, we conductedMTT-based viability assays using freshly isolated rat NCM. Similarto C2C12 myocytes, photomicrographs (day 4 shown) show thatNCM on BSA were largely rounded, yet those on Ang1, Ang2, andplate spread and maintained a normal morphology (Figure 4D).However, only NCM on Ang1 had increased survival compared withthe other conditions (Figure 4E).

Adhesion to Ang1 Prevents Skeletal and Cardiac Myocyte Apoptosis
We determined the effects of Ang1, Ang2, and some matrix componentson myocyte apoptosis by measuring caspase-3 activity after taxoltreatment in serum-free conditions on the various matrices.Adhesion to Ang1 markedly prevented C2C12 myocyte (Figure 5A),HSM (Figure 5B), and NCM (Figure 5C) apoptosis. For C2C12 myocytes,Ang1 prevented caspase-3 activation better than Ang2, laminin,collagen-I and -III, BSA, and plate (*P $≤$ 0.01), similar to collagenIV and vitronectin, and slightly less than fibronectin (P=0.0006).In HSMs, Ang1 prevented caspase-3 activation considerably betterthan Ang2, collagen IV, fibronectin, laminin, vitronectin, BSA,and plate (*P $≤$ 0.001), but was not as protective as collagens-Ior -III (P $≤$ 0.01). Ang1 prevented NCM caspase-3 activation morethan Ang2, fibronectin, laminin, vitronectin, BSA, and plate(P $≤$ 0.02), similar to collagen IV, and less than collagens-I and-III (P $≤$ 0.01). We evaluated the percentage of caspase-3 activationsuppressed by Ang1 compared with plate (C2C12, 50.5%; HSM, 8.0%;NCM, 41.5%).

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Figure 5. Ang1 prevents apoptosis in skeletal and cardiac myocytes. C2C12 myocytes (A), HSMs (B), and NCMs (C) were plated on 200 nmol/L Ang1, Ang2, collagen I (Col I), collagen III (Col III), collagen IV (Col IV), fibronectin (FN), laminin (Lam), vitronectin (VN), unmodified tissue culture wells (plate), or BSA in serum-free media (1 day), then 0.2 µmol/L taxol was added for 24 hours to induce apoptosis (n=6/group per study; studies done in duplicate). Percent caspase-3 activity per total myocytes was determined. Ang1 effectively inhibited caspase-3 activity for skeletal and cardiac myocytes. *Significantly higher caspase-3 activity compared with Ang1. A, For C2C12 myocytes, from left to right, *P=0.0000005, *P=0.000004, *P=0.01, *P=0.00000004, *P=0.000000001, and *P=0.00000004. B, For HSMs, from left to right, *P=0.0000004, *P=0.00004, *P=0.001, *P=0.0000002, *P=0.00002, *P=0.00000002, and *P=0.0000001. C, For NCMs, from left to right, *P=0.003, *P=0.00009, *P=0.02, *P=0.02, *P=0.00004, and *P=0.0004.

This data demonstrates that Ang1 prevented myocyte (mouse, rat,human) apoptosis under adverse conditions as well as or betterthan most other matrices tested. This cytoprotection is notexplained by differences in cell adhesion, because at 200 nmol/L,there are similar numbers of adherent C2C12 (Figure 1A), HSMs(Figure 1B), and NCMs (Figure 1C) to Ang1, Ang2, and the othermatrices, except for less C2C12 myocytes on the collagens andmore NCMs on collagens-I and -IV. These data suggest a novel,direct role for Ang1 in protecting myocytes from injury.

Ang1 Activates Akt and MAPK_p42/44 Signals in Skeletal and Cardiac Myocytes
We used Western blotting to determine whether myocyte interactionswith Ang1 and Ang2 activate Akt, MAPK_p42/44, and FAK signals,because these pathways increase survival and prevent apoptosisof CM. Comparisons were made among myocytes plated on the variousimmobilized matrices or suspended (Sus) in serum free media.Ang1 significantly induced C2C12 myocyte phosphorylation ofAkt_ser473 (Figure 6A) and MAPK_p42/44 (Figure 6B) more than anyother matrix (*P $≤$ 0.0001 Ang1 versus other matrix), whereas FAKactivation was not affected (Figure 6C). Ang1 also activatedAkt_ser473 (Figure 7A) and MAPK_p42/44 (Figure 7B) in HSMs morethan all other conditions (*P $≤$ 0.001). In NCMs as well, Ang1 promotedphosphorylation of Akt_ser473 (Figure 8A) and MAPK_p42/44 (Figure 8B)more than all other ECM (*P $≤$ 0.05), but did not alter FAKactivation (Figure 8C). The ability of Ang1 to increase Aktand MAPK_p42/44 phosphorylation in myocytes suggests a novelmechanism that may have therapeutic value in preserving CM viabilityand function after injury.

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Figure 6. Ang1 phosphorylates Akt and MAPK_p42/44 in C2C12 myocytes. C2C12 myocytes were held in suspension (Sus.) or plated on immobilized 200 nmol/L Ang1, Ang2, laminin (Lam), collagen I (Coll. I), collagen III (Coll. III), collagen IV (Coll. IV), fibronectin (FN), vitronectin (VN), BSA, or unmodified tissue culture wells (plate) for 40 minutes (n=3/group per study; studies done in duplicate). Akt, phospho-Akt_ser473 (A), MAPK_p42/44, phospho-MAPK_{p42(thr202)/44(tyr204)} (B)_, and FAK and phospho-FAK_tyr397 (C) were measured by Western blotting. Ang1 induced Akt and MAPK_p42/44 phosphorylation, but not FAK. *Ang1-induced Akt and MAPK_p42/44 activations were significantly greater than all other conditions tested (*P $≤$ 0.0001).

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Figure 7. Ang1 phosphorylates Akt and MAPK_p42/44 in HSMs. A and B, HSMs were held in suspension (Sus.) or plated on immobilized 200 nmol/L Ang1, Ang2, laminin (Lam), collagen I (Col. I), collagen III (Col. III), collagen IV (Col. IV), fibronectin (FN), vitronectin (VN), BSA, or unmodified tissue culture wells (plate) for 40 minutes (n=3/group per study; studies done in duplicate). Akt, phospho-Akt_ser473 (A) and MAPK_p42/44, phospho-MAPK_{p42(thr202)/44(tyr204)} (B) were measured by Western blotting. Ang1 induced Akt and MAPK_p42/44 phosphorylation (*P $≤$ 0.001 for Ang1 vs all other conditions).

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Figure 8. Ang1 phosphorylates Akt and MAPK_p42/44 in NCMs. A through C, NCMs were held in suspension (Sus.) or plated on immobilized 200 nmol/L Ang1, Ang2, laminin (Lam), collagen I (Col. I), collagen III (Col. III), collagen IV (Col. IV), fibronectin (FN), vitronectin (VN), BSA, or unmodified tissue culture wells (plate) for 40 minutes (n=3/group per study; studies done in duplicate). Akt, phospho-Akt_ser473 (A), MAPK_p42/44, phospho-MAPK_{p42(thr202)/44(tyr204)} (B)_, and FAK and phospho-FAK_tyr397 (C) were measured by Western blotting. Ang1 induced Akt and MAPK_p42/44 phosphorylation (*P $≤$ 0.05 for Ang1 vs the other conditions), but not FAK.

Ang1-Mediated Myocyte Activation of Akt and MAPK Occurs via Integrins
To assess whether Ang1 activation of myocyte Akt and MAPK_p42/44occurs via integrins, we preincubated C2C12 myocytes with EDTA,GRGDSP or GRGESP peptides, integrin antibodies ( ${alpha}$ ₄, ${alpha}$ ₆, ß₃),or PBS, and then plated them on 200 nmol/L immobilized Ang1or vitronectin. We chose vitronectin for comparison becauseit induced the second highest Akt phosphorylation after Ang1(Figure 6A). Furthermore, cell interactions with vitronectinvia integrins can be disrupted with RGD-based peptides and EDTA.³²Again, suspended myocytes were used as a negative control. EDTAsignificantly reduced myocyte Akt (Figure 9A and 9B) and MAPK_p42/44(Figure 9C and 9D) activation when incubated on Ang1 (Figure 9A,Akt; Figure 9C, MAPK) or vitronectin (Figure 9B, Akt; Figure 9D,MAPK) (*P $≤$ 0.002). GRGDSP peptide was consistently more effectiveat blocking Ang1- (Figure 9A, Akt; Figure 9C, MAPK) and vitronectin-(Figure 9B, Akt; Figure 9D, MAPK) induced cell signaling, thanGRGESP peptide (#P $≤$ 0.05). GRGESP peptide reduced myocyte Aktand MAPK_p42/44 activation, which may reflect nonspecific interferencewith integrin adhesion.⁵³

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Figure 9. Ang1-induced myocyte activation of cell signaling was disrupted by EDTA, RGD-based peptides, and integrin antibodies. Activation of (A and B) Akt and (C and D) MAPK_p42/44 were examined in C2C12 myocytes preincubated with PBS, 10 mmol/L EDTA, or 500 µg/mL GRGESP (RGE) or GRGDSP (RGD) peptides for 30 minutes, then plated on either immobilized 200 nmol/L (A and C) Ang1 or (B and D) vitronectin for 40 minutes. Samples were processed for Western blotting (n=3/group per study; studies done in duplicate). As a control, myocytes in suspension (Sus.) were subjected to the same conditions. EDTA reduced Ang1- and vitronectin-induced Akt and MAPK_p42/44 activations (*P $≤$ 0.002). Both peptides reduced Akt and MAPK_p42/44 phosphorylations. However, RGD was more effective than RGE in all cases (*P $≤$ 0.005). Phosphorylation of Akt (E) and MAPK_p42/44 (F) were examined in C2C12 myocytes preincubated with PBS or 50 µg/mL integrin subunit antibodies (Ab- ${alpha}$ ₄, Ab- ${alpha}$ ₆, Ab-ß₃) for 30 minutes, then plated on immobilized 200 nmol/L Ang1 for 40 minutes (n=3/group), and Western blotting was conducted. Myocytes in suspension (Sus.) were subjected to the same conditions and used as controls. Ang1 activations were inhibited by (E) Ab-ß₃ (Akt *P=0.001) and (F) Ab- ${alpha}$ ₆ (MAPK_p42/44, *P=0.00001) and Ab-ß₃ (MAPK_P42/44, **P=0.001). Studies were done in duplicate.

Ang1-induced Akt phosphorylation was significantly blocked byanti-ß₃ (*P=0.001), with a trend for anti- ${alpha}$ ₆ (P=0.06),and was not effected by anti- ${alpha}$ ₄ (Figure 9E). Ang1 activationof MAPK_p42/44 was blocked by anti-ß₃ more than anti- ${alpha}$ ₆(*P $≤$ 0.001), but not anti- ${alpha}$ ₄ (Figure 9F). Thus, antibodies to anti- ${alpha}$ ₄did not affect myocyte adhesion (Figure 3A) or signaling, butantibodies to ß₃ and ${alpha}$ ₆ reduced both myocyte adhesion(Figure 3A) and signaling. This data demonstrates that Ang1-inducedactivation of myocyte Akt and MAPK_p42/44 is integrin-mediated.

Soluble Ang1 Activates Myocyte Akt and MAPK_p42/44 Signaling
To determine whether Ang1-induced phosphorylation of Akt andMAPK_p42/44 required cell adhesion, we placed C2C12 myocytesand Ms1 microvascular endothelial cells in suspension in serum-freemedium and added 200 nmol/L Ang1, Ang2, fibronectin, laminin,vitronectin, or PBS. Western blotting showed that Ang1 markedlyphosphorylated Akt (Figure 10A) and MAPK_p42/44 (Figure 10B)in both cell types considerably more than did the other solubleconditions (*P $≤$ 0.001 Ang1 versus other conditions). Activationwas greater in myocytes (65.7-fold Akt; 3.5 fold MAPK) thanendothelial cells (3.4-fold Akt; 2.1-fold MAPK). Thus, Ang1potently activated cytoprotective signaling pathways in myocytesin a non-tie2, cell adhesion–independent manner.

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Figure 10. Soluble Ang1 activates Akt and MAPK_p42/44 signaling in suspended myocytes and endothelial cells. C2C12 myocytes and Ms1 endothelial cells were suspended in 200 nmol/L soluble Ang1, Ang2, laminin (Lam), fibronectin (FN), vitronectin (VN), or PBS for 30 minutes. Akt and phospho-Akt_ser473 (A) and MAPK_p42/44 and phospho-MAPK_{p42(thr202)/44(tyr204)} (B) were measured by Western blotting (n=3/group per study; studies done in duplicate). For myocytes and Ms1 cells, Ang1 induced increases in Akt (A) and MAPK_p42/44 (B) phosphorylations vs the other conditions (*P $≤$ 0.001), although the magnitude of the activation was larger for myocytes than endothelial cells.

Ang1 has been shown in several reports to activate endothelialcell Akt^15,54,55 and MAPK_p42/44.^56,57 In all of these endothelialcell studies, similar assays were conducted. Endothelial cellswere grown in tissue culture dishes, serum-starved, then solubleAng1 was added and Akt and/or MAPK_p42/44 phosphorylations wereassessed. To further compare the effects of soluble Ang1 onmyocytes versus endothelial cells, we also conducted this typeof assay. We found that Ang1 phosphorylated Akt (Figure 11)and MAPK_p42/44 (Figure 12) on C2C12 myocytes, HSMs, and Ms1endothelial cells. Wortmannin, a phosphatidylinositol 3'-kinase(PI3-K) inhibitor, effectively blocked Akt (Figure 11) and MAPK_p42/44(Figure 12) activation in both myocytes and endothelial cells.Studies have also shown that wortmannin blocks MAPK_p42/44 phosphorylationin myoblasts.⁵⁸ Thus, Ang1-induced myocyte Akt and MAPK_p42/44activation appear to be PI3-K–mediated. We found thatMs1 endothelial cell, but not myocyte, Akt (Figure 11) and MAPK_p42/44(Figure 12) were phosphorylated by 3.6 nmol/L Ang1, a commonlyused dose in endothelial cell studies.^15,54–57 Ang1 (200nmol/L) increased phosphorylation of Akt HSM (4.2-fold), C2C12myocytes (2.4-fold), and Ms1 endothelial cells (2.1-fold). ForMAPK_p42/44, Ang1 (200 nmol/L) increased HSMs (3.5-fold), C2C12myocytes (2.3-fold), and Ms1 (3.8-fold).

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Figure 11. Soluble Ang1 activates Akt signaling in myocytes and endothelial cells grown in serum-free media on tissue culture plates. C2C12 myocytes (A), HSMs (B), and Ms1 endothelial cells (C) grown adhered to tissue culture plates were incubated with the indicated concentrations of soluble Ang1, Ang2, laminin (Lam), or PBS for 30 minutes. Some wells were preincubated with 200 nmol/L wortmannin (W) for 2 hours before the addition of soluble factors. Cell lysates were prepared and Western blotting conducted for Akt and phospho-Akt_ser473 (n=3/group per study; studies done in duplicate). Ang1 phosphorylated Akt greater than all the other conditions tested (*P $≤$ 0.008, C2C12) and (*P $≤$ 0.001, HSM). For Ms1 endothelial cells, Ang1 significantly phosphorylated Akt (3.6 nmol/L, *P=0.006 vs PBS) and (200 nmol/L, **P=0.0005 vs PBS). For Ms1, 200 nmol/L laminin also activated Akt (#P=0.008 vs PBS). Wortmannin abrogated Ang1-induced Akt phosphorylation for C2C12 myocytes, HSMs, and Ms1 endothelial cells.

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Figure 12. Soluble Ang1 activates MAPK_p42/44 signaling in myocytes and endothelial cells grown in serum-free media on tissue culture plates. C2C12 myocytes (A), HSMs (B), and Ms1 endothelial cells (C) adhered to tissue culture plates were incubated with the indicated concentrations of soluble Ang1, Ang2, laminin (Lam), or PBS for 30 minutes. Some wells were preincubated with 200 nmol/L wortmannin (W) for 2 hours before the addition of soluble factors. Cell lysates were prepared and Western blotting conducted for MAPK_p42/44 and phospho-MAPK_{p42(thr202)/44(tyr204)} (phosphoMAPK_p42/44) (n=3/group per study; studies done in duplicate). Ang1 phosphorylated MAPK_p42/44 greater than all the other conditions tested (*P $≤$ 0.004, C2C12) and (*P $≤$ 0.02, HSM). For Ms1 endothelial cells, Ang1 significantly phosphorylated MAPK_p42/44 (3.6 nmol/L, *P=0.008 vs PBS) and (200 nmol/L, **P=0.008 vs PBS). Wortmannin abrogated Ang1-induced MAPK_p42/44 phosphorylation for C2C12 myocytes, HSMs, and Ms1 endothelial cells.

Discussion

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

In this study, we show that skeletal and cardiac myocytes adhereto Ang1 and Ang2 via integrins and that Ang1 promotes survivalunder adverse conditions. This finding revises the current viewthat angiopoietins act essentially on the vasculature via theendothelial cell (EC)–specific receptor, tie2. With therecognition that angiopoietins act on CMs, ECs, and fibroblasts,³²an expanded role for these molecules in cardiac health and diseasemay emerge. Angiopoietins appear well-positioned to mediatemyocardial remodeling, which requires coordination among thesevarious cell types for proper cardiac function. Interest inmechanisms that regulate balanced remodeling is increasing withthe appreciation that disproportionate changes in these cellularcomponents occur in pathological cardiac remodeling and mayultimately contribute to heart failure. Furthermore, our findingsindicate that this novel angiopoietin role extends beyond theheart. Cytoprotective effects on skeletal myocytes (HSM, C2C12myocytes) suggest that Ang1 may also directly mediate skeletalmuscle survival^59,60 during insults such as limb ischemia fromperipheral vascular disease. We propose that this new angiopoietinfunction acts in concert with effects on the vasculature toprotect the heart and peripheral tissues under adverse conditions.

We found that RGD-based peptides and EDTA blocked myocyte adhesionto Ang1 and Ang2 (Figures 2 and 3 ). Fibroblast³² adhesion toAng1 and Ang2, and EC⁴⁸ adhesion to Angptl3 are also inhibitedby RGD-based peptides and EDTA. These features support integrininvolvement. However, Ang1, Ang2, and Angptl3 lack an RGD site.We examined mouse, rat, and human Ang1 and Ang2, and found noexact matches to 22 well-known integrin-binding motifs.⁵³ However,there were areas resembling integrin motifs in the fibrinogen-like(fbg-lk) domain of Ang1 and Ang2 that were conserved among mouse,rat, human, and other species (eg, QHREDGS). This region resemblesKRLDGS (fibrinogen) or REDV (fibronectin) integrin motifs. AQHREDGS or similar amino acid (AA) sequence exists in humanAng1 and 2, mouse Ang1 to 3 and 5, pig Ang1 and 2, chicken Ang2isoforms A and B, zebrafish Ang1 to 3, Caenorhabditis elegansangiopoietin (Ang)-related protein, human Angptl1 to 6, mouseAngptl3, and yellow fever mosquito Ang-related protein. MouseAngptl4 and African clawed frog Ang-related protein have a nearbyRGD site. An exception is human Ang4, which lacks the D, andhas a diverging function from its counterpart.⁶¹ We proposethat select myocyte integrins adhere to Ang1 and Ang2 via thefbg-lk domain, possibly at or including the AA’s QHREDGS.In support of this concept, ECs adhere to via ${alpha}$ _vß₃via the Angptl3 fbg-lk domain,⁴⁸ and fbg-lk domains of Angptl3,Ang1, and Ang2 are very homologous.^19,48,62

Our studies implicate integrins (eg, ${alpha}$ ₆ß₄, ${alpha}$ ₆ß₁, ${alpha}$ _vß₃, ${alpha}$ _vß₁, ${alpha}$ ₅ß₁, ${alpha}$ ₂ß₁)for mediating myocyte adhesion to Ang1 and/or Ang2. Our findingstogether with those of Carlson et al (fibroblasts)³² suggestthat each cell type has a characteristic set of integrins thatengages the angiopoietins, which may partially overlap amongcell types. Our most complete analysis was conducted on skeletalmyocytes (HSM) owing to the greater availability of anti-humanintegrin antibodies. There are fewer available anti-rat antibodies,so additional integrins may yet be identified that mediate cardiacmyocyte adhesion to Ang1 and Ang2. Furthermore, the expressionof many integrin subunits shift during myocyte differentiation.⁶³This may account for our finding that C2C12 differentiationinto myocytes is vital for attachment to Ang1 and Ang2.

Promising integrin subunit candidates include ß₃ and ${alpha}$ ₆. ß₃ antibodies blocked mouse, rat, and human myocyteadhesion to Ang1 and Ang2 (Figure 3A through 3C) and preventedAng1 induction of Akt and MAPK_p42/44 phosphorylations (Figure 9E and 9F).ß₃ is important in CM focal adhesion complexesand is active in cardiac hypertrophy.⁶⁴ Also, ${alpha}$ ₆ inhibited myocyteattachment to Ang1 and Ang2 (Figure 3A and 3C) and abrogatedMAPK_p42/44 activation (Figure 9F). ${alpha}$ ₆ is vital to CM function,prevalent on CM, and is not expressed by cardiac fibroblasts.⁶⁵Isoforms ( ${alpha}$ _6A and ${alpha}$ _6B) are expressed in fetal and adult hearts,³⁶and levels shift during cardiac development.^66,67 The blockingeffects of ß₃ and ${alpha}$ ₆ antibodies support a link betweenmyocyte-Ang1 interactions and activation of cell signaling (Figures 6 through 12 ).

We examined the impact of Ang1 on signaling pathways criticalto CM survival and protection from apoptosis. Akt phosphorylationis necessary and sufficient for CM cytoprotection. Constitutivelyactive Akt reduced infarct size (64%), CM apoptosis (84%),⁶⁸and heart failure⁶⁹ in vivo. In vitro Akt phosphorylation preventedDNA fragmentation,⁷⁰ caspase activation, cytochrome c release,⁷¹and CM apoptosis.⁷⁰ Phosphorylated MAPK_p42/44 activated CM prosurvivalsignals⁷² and reduced reperfusion injury,⁷³ ß-adrenergicstimulation³⁸-induced CM apoptosis, and heart failure.⁷⁴ Thus,Ang1 activation of human, mouse, and rat myocyte Akt and MAPK_p42/44signals may increase myocyte survival and prevent apoptosis.

A direct role for Ang1 in preventing caspase-3 activation inCM may ultimately advance efforts toward preserving cardiacfunction. In a mouse model of ischemia/reperfusion injury, cardiospecificcaspase-3 overexpression increased CM apoptosis, poly-ADP ribosepolymerase (DNA repair enzyme) degradation, DNA fragmentation,and infarct size.⁷⁵ Alternatively, inhibiting caspase-3 preventedCM apoptosis⁷⁶ and reduced ischemia injury,^77,78 infarct size,⁷⁹postinfarct remodeling,⁸⁰ and heart failure.⁸¹ Activated caspase-3can degrade CM contractile proteins (myosin light chain-1,⁸²sarcomeres,⁸³ and myofibrils⁷⁵) without inciting cell death.This contributes to LV remodeling, dilation,⁸⁴ and reduced LVfunction in ischemia,⁸⁴ reperfusion injury,⁷⁵ infarct, and heartfailure.⁸²

Our data show that Ang1 and Ang2 are not EC-specific and canuse non-tie2 receptors. Ang1 and Ang2 can act directly on cardiacand skeletal myocytes through integrins and promote myocytesurvival (Table, Figure 4) through specific pathways such ascaspase-3 inhibition (Figure 5) and Akt and MAPK_p42/44 phosphorylation(Figures 6 through 12 ). These actions are similar to those reportedfor Ang1 as an EC survival factor,^{15,16,54,56,85} namely inhibitionof caspase,^54,55 and activation of Akt,^15,54,56 MAPK_p42/44,⁵⁵PI-3K, survivin, and eNOS.^86,87 Whether there is an integrin-mediatedcomponent to these EC effects in addition to the tie2 receptorinteractions has not been explored. Precedents suggest thatthis may be possible. Hepatic fibrinogen/Ang-related protein,which does not bind tie2, prevents HUVEC apoptosis in serum-freemedia.⁸⁸ Angptl3, which also does not bind tie2, adheres toHMVECs via integrin ${alpha}$ _vß₃, activating Akt, MAPK_p42/44,and some FAK.⁴⁸ HUVEC adhesion to Ang1 and Ang2 activates MAPK_p42/44and FAK,³² and EDTA- and RGD-based peptides nullify these signals,implicating integrins as mediators of angiopoietin signals onECs. Thus, in the heart, Ang1 may act on CMs and cardiac ECsto promote survival and maintain cardiovascular health.

Ang1 and Ang2 promoted adhesion of all the myocytes studied(Figure 1). However, only Ang1 increased myocyte survival (Figure 4,Table) and regulated cytoprotective signaling (Figures 5 through 12 ). The observations that both immobilized (Figures 6 through 9 HREF="#FIG7">) and soluble (Figures 10 through 12 ) Ang1, but notAng2, activated myocyte Akt and MAPK_p42/44 signaling within30 minutes, suggests that this distinction is not due to differencesin coating affinities or protein degradation. Furthermore, Ang1-inducedsignal activation remained intact in suspended myocytes (Figure 10),eliminating differences in cell adhesion as an explanation.Cell adhesion was not required for this response. The differentsurvival effects of the angiopoietins may relate to the regionin the fbg-lk domain of each molecule that we propose mediatesadhesion. These regions share 77.8% homology, which is greateroverlap than that found in the full-length proteins 62% homology.We are exploring the possibility that this region of Ang2 mayresemble Ang1 enough to have a similar binding site conformation,but vary in key residues needed to induce signaling. On endothelium,the mechanism-of-action of Ang2 is complex. Ang2 is a tie2 antagoniston vascular endothelium,¹⁹ and at high concentrations is a weakagonist.²⁰ On lymphatic endothelium, Ang2 acts as a tie2 agonist.²¹Similar complexities likely characterize the actions of Ang2on myocytes via integrins.

Soluble Ang1 added to myocytes and endothelial cells grown intissue culture plates activated Akt (Figure 11) and MAPK_p42/44(Figure 12). Our study is the first to use human recombinantAng1 to measure myocyte and endothelial cell signaling. Previousstudies^{15,54–57,89} used a variant form of Ang1, termedAng1*.⁹⁰ Ang1* contains the first 73 amino acids of Ang2 fusedto the 77th amino acid of Ang1 with a cysteine to serine mutationat amino acid 265.⁹¹ Ang1* was engineered because it is easierto produce and purify than Ang1. However, sequences within thefirst 76 amino acids of Ang1 are critical for multimerizationand tie2 activation,⁹² and thus may alter the activities ofAng1.

Our studies show similar effects of human Ang1 on human, mouse,and rat myocytes. Several in vivo studies demonstrate that humanAng1 is effective in other animals. In myocardial infarctionmodels, transfection of human Ang1 plasmids³⁰ or adenoviralvectors²⁹ reduced infarct zones in mice and rats, respectively.Plasmid-driven overexpression of human Ang1 reduced hindlimbischemia in rabbits^93,94 and gastric ulcers in rats.⁹⁵

Mechanisms-of-action and functional significance of angiopoietin–myocyteinteractions in vivo remain to be determined. Various ischemiamodels have shown a protective benefit from overexpressing Ang1.Ang1 overexpression in the heart resulted in smaller infarctzones and preserved cardiac function following myocardial infarctions.^29–31 Improved myoblast survival and reduced tissue necrosis withhindlimb ischemia⁹⁶ and enhanced survival of muscle^59,60 andskin⁹⁷ flaps have also been reported. These studies showed increasesin perfusion and/or capillary density, which were thought toexplain the protective effects of Ang1 on the muscle and othertissues. However, our findings suggest that nonvascular mechanismsmay also contribute to the superior outcomes. We show that Ang1directly promotes survival of cardiac and skeletal myocytes(Figure 4, Table), prevents caspase-3 activation (Figure 5),and activates cell survival pathways (Figures 6 through 12 ).This suggests that Ang1 directly supports myocyte survival invivo under adverse conditions (eg, ischemia).

In summary, we demonstrated that angiopoietins directly interactwith myocytes via integrins to mediate cell adhesion and survival.It is worth noting that Ang1 activated cytoprotective signalingcascades far more potently than any of the other integrin ligandstested, whether in an immobilized (Figures 6 through 9 ) or soluble(Figures 10 through 12 ) form. In fact, when cells were heldin suspension and incubated with soluble Ang1, Ang1 was moreefficacious at inducing anti-apoptotic pathways in myocytesthan in endothelial cells; for which it is a well-recognizedsurvival factor.

These findings support the concept that Ang1-myocyte interactionsare biologically relevant. We propose that this new angiopoietinfunction acts in concert with effects on the vasculature toprotect the heart. Furthermore, understanding the role of Ang1in CM survival may lead to novel therapies to stabilize andmaintain CM number and function after cardiac insults, therebyimpeding heart failure.

Acknowledgments

This work was supported in part by NIH grants K02-HL071840-01and R21-CA107976-01 (to M.A.R.), and NIH grant K01-DK063970-01A2and Harvard Medical School Scholars in Medicine Award (to S.M.D.).We thank Thomas Michel MD, PhD, Cardiovascular Division, Brighamand Women’s Hospital, and Douglas B. Sawyer, MD, PhD andDavid Pimintel, MD, Whitaker Cardiovascular Institute, BostonUniversity School of Medicine for providing rat neonatal cardiacmyocytes used in preliminary studies for this work.

Footnotes

Original received May 18, 2004; resubmission received December17, 2004; revised resubmission received January 24, 2005; acceptedJanuary 25, 2005.

References

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

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