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Abstract

Objective:

Increased macrophage recruitment in the early stages of wound healing leads to an excessive inflammatory response associated with elevated fibrosis and scarring. This recruitment relies upon integrins on the surface of monocytes that regulate their migration and extravasation from the circulation into the wound site, where they differentiate into macrophages. The aim of this study was to determine if inhibiting monocyte extravasation from the circulation into burns would reduce macrophages numbers in burns and lead to reduced inflammation and scar formation.

Approach:

Scald burns were created on mice and treated with integrin alpha L (αL) function blocking antibody via intravenous delivery day 1 after injury. The effect of inhibiting macrophage recruitment into the burn was assessed using macro- and microscopic wound parameters as well as immunohistochemistry for inflammatory cell markers, cytokines, and collagen deposition.

Results:

Burn wound-associated macrophages were reduced by 54.7% at day 3 following treatment with integrin αL antibody, with levels returning to normal by day 7. This reduction in macrophages led to a concomitant reduction in inflammatory mediators, including tumor necrosis factor-alpha (TNFα) and Il-10 as well as a reduction in proscarring transforming growth factor beta 1 (TGFβ1). This reduced inflammatory response was also associated with less alpha smooth muscle actin (αSMA) expression and an overall trend toward reduced scar formation with a lower collagen I/III ratio.

Innovation:

Treatment of burns with integrin αL function blocking antibodies reduces inflammation in burn wounds.

Conclusion:

These results suggest that reducing macrophage infiltration into burn wounds may lead to a reduced early inflammatory response and less scar formation following burn injury.

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References

Ladak

, Tredget

. Pathophysiology and management of the burn scar. Clin Plast Surg, 2009; 36:661–674.

Stramer

, Mori

, Martin

. The inflammation-fibrosis link? A Jekyll and Hyde role for blood cells during wound repair. J Invest Dermatol, 2007; 127:1009–1017.

Tiwari

. Burn wound: how it differs from other wounds?. Indian J Plast Surg, 2012; 45:364–373.

Cowin

, Brosnan

, Holmes

, Ferguson

. Endogenous inflammatory response to dermal wound healing in the fetal and adult mouse. Dev Dyn, 1998; 212:385–393.

Eming

, Krieg

, Davidson

. Inflammation in wound repair: molecular and cellular mechanisms. J Invest Dermatol, 2007; 127:514–525.

Eming

, Hammerschmidt

, Krieg

, Roers

. Interrelation of immunity and tissue repair or regeneration. Semin Cell Dev Biol, 2009; 20:517–527.

Murray

, Stow

. Cytokine secretion in macrophages: SNAREs, Rabs, and membrane trafficking. Front Immunol, 2014; 5:538.

Brancato

, Albina

. Wound macrophages as key regulators of repair: origin, phenotype, and function. Am J Pathol, 2011; 178:19–25.

Hesketh

, Sahin

, West

, Murray

. Macrophage phenotypes regulate scar formation and chronic wound healing. Int J Mol Sci, 2017; 18:E1545.

10.

Mirza

, DiPietro

, Koh

. Selective and specific macrophage ablation is detrimental to wound healing in mice. Am J Pathol, 2009; 175:2454–2462.

11.

Goren

, Allmann

, Yogev

, Schurmann

, Linke

, Holdener

, et al. A transgenic mouse model of inducible macrophage depletion: effects of diphtheria toxin-driven lysozyme M-specific cell lineage ablation on wound inflammatory, angiogenic, and contractive processes. Am J Pathol, 2009; 175:132–147.

12.

Martin

, D'Souza

, Martin

, Grose

, Cooper

, Maki

, et al. Wound healing in the PU.1 null mouse—tissue repair is not dependent on inflammatory cells. Curr Biol, 2003; 13:1122–1128.

13.

Lucas

, Waisman

, Ranjan

, Roes

, Krieg

, Muller

, et al. Differential roles of macrophages in diverse phases of skin repair. J Immunol, 2010; 184:3964–3977.

14.

Schnoor

, Alcaide

, Voisin

, van Buul

. Crossing the vascular wall: common and unique mechanisms exploited by different leukocyte subsets during extravasation. Mediators Inflamm, 2015; 2015:946509.

15.

Kourtzelis

, Mitroulis

, von Renesse

, Hajishengallis

, Chavakis

. From leukocyte recruitment to resolution of inflammation: the cardinal role of integrins. J Leukoc Biol, 2017; 102:677–683.

16.

Ley

, Laudanna

, Cybulsky

, Nourshargh

. Getting to the site of inflammation: the leukocyte adhesion cascade updated. Nat Rev Immunol, 2007; 7:678–689.

17.

Sumagin

, Prizant

, Lomakina

, Waugh

, Sarelius

. LFA-1 and Mac-1 define characteristically different intralumenal crawling and emigration patterns for monocytes and neutrophils in situ. J Immunol, 2010; 185:7057–7066.

18.

Frampton

, Plosker

. Efalizumab: a review of its use in the management of chronic moderate-to-severe plaque psoriasis. Am J Clin Dermatol, 2009; 10:51–72.

19.

Veale

, Offenhäuser

, Lei

, Stanley

, Stow

, Murray

. VAMP3 regulates podosome organisation in macrophages and together with Stx4/SNAP23 mediates adhesion, cell spreading and persistent migration. Exp Cell Res, 2011; 317:1817–1829.

20.

Adams

, Ruzehaji

, Strudwick

, Greenwood

, Campbell

, Arkell

, et al. Attenuation of Flightless I, an actin-remodelling protein, improves burn injury repair via modulation of transforming growth factor (TGF)-beta1 and TGF-beta3. Brit J Dermatol, 2009; 161:326–336.

21.

Reisman

, Floyd

, Wagener

, Kirk

, Larsen

, Ford

. LFA-1 blockade induces effector and regulatory T-cell enrichment in lymph nodes and synergizes with CTLA-4Ig to inhibit effector function. Blood, 2011; 118:5851–5861.

22.

Wang

, Li

, Nurieva

, Yang

, Sen

, Carreno

, et al. LFA-1 affinity regulation is necessary for the activation and proliferation of naive T cells. J Biol Chem, 2009; 284:12645–12653.

23.

Jackson

, Kopecki

, Adams

, Cowin

. Flii neutralizing antibodies improve wound healing in porcine preclinical studies. Wound Rep Regen, 2012; 20:523–536.

24.

Ibbetson

, Pyne

, Pollard

, Olson

, Samuel

. Mechanotransduction pathways promoting tumor progression are activated in invasive human squamous cell carcinoma. Am J Pathol, 2013; 183:930–937.

25.

Samuel

, Lopez

, McGhee

, Croft

, Strachan

, Timpson

, et al. Actomyosin-mediated cellular tension drives increased tissue stiffness and beta-catenin activation to induce epidermal hyperplasia and tumor growth. Cancer Cell, 2011; 19:776–791.

26.

Kular

, Scheer

, Pyne

, Allam

, Pollard

, Magenau

, et al. A negative regulatory mechanism involving 14-3-3zeta limits signaling downstream of ROCK to regulate tissue stiffness in epidermal homeostasis. Dev Cell, 2015; 35:759–774.

27.

Prieto

, Eklund

, Patarroyo

. Regulated expression of integrins and other adhesion molecules during differentiation of monocytes into macrophages. Cell Immunol, 1994; 156:191–211.

28.

Rohl

, Zaharia

, Rudolph

, Murray

. The role of inflammation in cutaneous repair. Wound Prac Res, 2015; 23:8–12, 4–5.

29.

Zomer

, Trentin

. Skin wound healing in humans and mice: challenges in translational research. J Dermatol Sci, 2018; 90:3–12.

30.

Talamonti

, Spallone

, Di Stefani

, Costanzo

, Chimenti

. Efalizumab. Expert Opin Drug Safety, 2011; 10:239–251.

31.

Mileski

, Burkhart

, Hunt

, Kagan

, Saffle

, Herndon

, et al. Clinical effects of inhibiting leukocyte adhesion with monoclonal antibody to intercellular adhesion molecule-1 (enlimomab) in the treatment of partial-thickness burn injury. J Traum, 2003; 54:950–958.

32.

Sun

, Friedrich

, Heuslein

, Pferdehirt

, Dangelo

, Natesan

, et al. Reduction of burn progression with topical delivery of (anti-tumor necrosis factor-α)-hyaluronic acid conjugates. Wound Rep Regen, 2012; 20:563–572.

33.

Ashcroft

, Jeong

, Ashworth

, Hardman

, Jin

, Moutsopoulos

, et al. Tumor necrosis factor-alpha (TNF-alpha) is a therapeutic target for impaired cutaneous wound healing. Wound Rep Regen, 2012; 20:38–49.

34.

Ritsu

, Kawakami

, Kanno

, Tanno

, Ishii

, Imai

, et al. Critical role of tumor necrosis factor-alpha in the early process of wound healing in skin. J Dermatol, 2017; 21:14–19.

35.

Wendling

, Balblanc

, Brousse

, Lohse

, Lehuede

, Garbuio

, et al. Surgery in patients receiving anti-tumour necrosis factor alpha treatment in rheumatoid arthritis: an observational study on 50 surgical procedures. Ann Rheum Dis, 2005; 64:1378–1379.

36.

Peters

, Sindrilaru

, Hinz

, Hinrichs

, Menke

, Al-Azzeh

EAD

, et al. Wound-healing defect of CD18(−/−) mice due to a decrease in TGF-β(1) and myofibroblast differentiation. EMBO J, 2005; 24:3400–3410.

37.

Cameron

, Turner

, Adams

, Jackson

, Melville

, Arkell

, et al. Flightless I is a key regulator of the fibroproliferative process in hypertrophic scarring and a target for a novel antiscarring therapy. Brit J Dermatol, 2016; 174:786–794.

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Systemic Delivery of Anti-Integrin αL Antibodies Reduces Early Macrophage Recruitment,Inflammation,and Scar Formation in Murine Burn Wounds

Abstract

Objective:

Approach:

Results:

Innovation:

Conclusion:

Get full access to this article

References

Supplementary Material