Volumetric muscle loss (VML) due to traumatic injury results in the abrupt loss of contractile units, stem cells, and connective tissue, leading to long-term muscle dysfunction and reduced regenerative potential. Muscle connective tissue contains a proregenerative extracellular matrix (ECM), and our lab harnesses the regenerative capacity of decellularized muscle matrix (DMM) to treat VML, a condition with limited treatment options. However, a major limitation is that muscle often comes from aged donors. Previous work from our lab showed that aged donor muscle contains higher levels of advanced glycation end-product (AGE) cross-links compared to muscle from younger donors. This study aimed to determine whether increased AGE cross-links reduce the regenerative capacity of DMM. To test this, we first generated AGEs in DMM with direct D-ribose incubation. We then removed ∼35% of the gastrocnemius muscle in a model and treated it with either AGE-DMM or standard DMM (no AGEs), comparing results to controls. Although muscle force results remained unchanged between AGE-DMM and DMM, AGEs led to reduced muscle mass in histological sections, fewer fibers, and smaller fiber diameters. AGEs also increased collagen levels in histology, but protein assays showed reduced collagen production. We investigated the canonical receptor for AGEs, the receptor for AGEs (RAGE), and found elevated levels in AGE-treated VML compared to DMM alone, along with increased levels of the noncanonical receptor galectin-3. Both RAGE and galectin-3 are associated with inflammation, and proteomics revealed higher inflammatory markers in AGE-treated muscle than in DMM alone. In conclusion, our data suggest that AGEs impair the regenerative potential of DMM, highlighting the importance of considering donor age when sourcing muscle for DMM therapies.
Impact Statement
This study investigates advanced glycation end-product cross-links in skeletal muscle extracellular matrix (ECM) as a way to model its deleterious effects on muscle regeneration in vivo. We demonstrate here that ECM glycations reduce muscle regeneration, enhance inflammatory markers, reduce ECM protein production, and proteomic analysis identified unique targets that could be explored in future research endeavors.
Get full access to this article
View all access options for this article.
References
1.
UrciuoloA, QuartaM, MorbidoniV, et al.Collagen VI regulates satellite cell self-renewal and muscle regeneration. Nat Commun, 2013; 4:1964; doi: 10.1038/ncomms2964
2.
ReedRK, RubinK. Transcapillary exchange: Role and importance of the interstitial fluid pressure and the extracellular matrix. Cardiovasc Res, 2010; 87(2):211–217; doi: 10.1093/cvr/cvq143
3.
McClureMJ, CohenDJ, RameyAN, et al.Decellularized muscle supports new muscle fibers and improves function following volumetric injury. Tissue Eng Part A, 2018; 24(15–16):1228–1241; doi: 10.1089/ten.TEA.2017.0386
4.
UrciuoloA, De CoppiP. Decellularized tissue for muscle regeneration. Int J Mol Sci, 2018; 19(8); doi: 10.3390/ijms19082392
5.
CeafalanLC, PopescuBO, HinescuME. Cellular players in skeletal muscle regeneration. Biomed Res Int, 2014; 2014:957014; doi: 10.1155/2014/957014
6.
OlsonLC, NguyenTM, HeiseRL, et al.Advanced glycation end products are retained in Decellularized muscle matrix derived from aged skeletal muscle. Int J Mol Sci, 2021; 22(16); doi: 10.3390/ijms22168832
7.
VollsetSE, GorenE, YuanCW, et al.Fertility, mortality, migration, and population scenarios for 195 countries and territories from 2017 to 2100: A forecasting analysis for the Global Burden of Disease Study. Lancet, 2020; 396(10258):1285–1306; doi: 10.1016/s0140-6736(20)30677-2
McClureMJ, OlsonLC, CohenDJ, et al.RNU (Foxn1 (RNU)-Nude) rats demonstrate an improved ability to regenerate muscle in a volumetric muscle injury compared to sprague dawley rats. Bioengineering (Basel), 2021; 8(1); doi: 10.3390/bioengineering8010012
11.
OlsonLC, ReddenJT, GilliamL, et al.Human Adipose-Derived Stromal Cells Delivered on Decellularized Muscle Improve Muscle Regeneration and Regulate Rage and P38 Mapk. Bioengineering (Basel), 2022; 9(9):426.
12.
OlsonLC, NguyenT, SabalewskiEL, et al.S100b treatment overcomes RAGE signaling deficits in myoblasts on advanced glycation end-product cross-linked collagen and promotes myogenic differentiation. Am J Physiol Cell Physiol, 2024; 326(4):C1080–C1093; doi: 10.1152/ajpcell.00502.2023
13.
CoronaBT, WenkeJC, WardCL. Pathophysiology of volumetric muscle loss injury. Cells Tissues Organs, 2016; 202(3–4):180–188; doi: 10.1159/000443925
14.
PorzionatoA, SfrisoMM, PontiniA, et al.Decellularized human skeletal muscle as biologic scaffold for reconstructive surgery. Int J Mol Sci, 2015; 16(7):14808–14831; doi: 10.3390/ijms160714808
15.
Strieder-BarbozaC, BakerNA, FlesherCG, et al.Advanced glycation end-products regulate extracellular matrix-adipocyte metabolic crosstalk in diabetes. Sci Rep, 2019; 9(1):19748; doi: 10.1038/s41598-019-56242-z
16.
HuS, HeW, LiuZ, et al.The accumulation of the glycoxidation product N(ε)-carboxymethyllysine in cardiac tissues with age, diabetes mellitus and coronary heart disease. Tohoku J Exp Med, 2013; 230(1):25–32; doi: 10.1620/tjem.230.25
17.
SnowLM, FugereNA, ThompsonLV. Advanced glycation end-product accumulation and associated protein modification in type II skeletal muscle with aging. J Gerontol A Biol Sci Med Sci, 2007; 62(11):1204–1210; doi: 10.1093/gerona/62.11.1204
18.
NederveenJP, JoanisseS, ThomasACQ, et al.Age-related changes to the satellite cell niche are associated with reduced activation following exercise. Faseb J, 2020; 34(7):8975–8989; doi: 10.1096/fj.201900787R
19.
LukjanenkoL, JungMJ, HegdeN, et al.Loss of fibronectin from the aged stem cell niche affects the regenerative capacity of skeletal muscle in mice. Nat Med, 2016; 22(8):897–905; doi: 10.1038/nm.4126
20.
ChenWJ, LinIH, LeeCW, et al.Aged skeletal muscle retains the ability to remodel extracellular matrix for degradation of collagen deposition after muscle injury. Int J Mol Sci, 2021; 22(4); doi: 10.3390/ijms22042123
21.
CoronaBT, WuX, WardCL, et al.The promotion of a functional fibrosis in skeletal muscle with volumetric muscle loss injury following the transplantation of muscle-ECM. Biomaterials, 2013; 34(13):3324–3335; doi: 10.1016/j.biomaterials.2013.01.061
22.
OlsonLC, ReddenJT, SchwartzZ, et al.Advanced glycation end-products in skeletal muscle aging. Bioengineering (Basel), 2021; 8(11); doi: 10.3390/bioengineering8110168
23.
van der LugtT, WeselerAR, GebbinkWA, et al.Dietary advanced glycation Endproducts induce an inflammatory response in human macrophages in vitro. Nutrients, 2018; 10(12); doi: 10.3390/nu10121868
24.
MulrennanS, BalticS, AggarwalS, et al.The role of receptor for advanced glycation end products in airway inflammation in CF and CF related diabetes. Sci Rep, 2015; 5:8931; doi: 10.1038/srep08931
25.
YangW, HuP. Skeletal muscle regeneration is modulated by inflammation. J Orthop Translat, 2018; 13:25–32; doi: 10.1016/j.jot.2018.01.002
26.
ChapmanMA, MukundK, SubramaniamS, et al.Three distinct cell populations express extracellular matrix proteins and increase in number during skeletal muscle fibrosis. Am J Physiol Cell Physiol, 2017; 312(2):C131–C143; doi: 10.1152/ajpcell.00226.2016
Sastourné-ArreyQ, MathieuM, ContrerasX, et al.Adipose tissue is a source of regenerative cells that augment the repair of skeletal muscle after injury. Nat Commun, 2023; 14(1):80; doi: 10.1038/s41467-022-35524-7
29.
JohnsonCD, ZhouLY, KopinkeD. A guide to examining intramuscular fat formation and its cellular origin in skeletal muscle. J Vis Exp, 2022; 183(183); doi: 10.3791/63996
30.
LoomisT, HuLY, WohlgemuthRP, et al.Matrix stiffness and architecture drive fibro-adipogenic progenitors’ activation into myofibroblasts. Sci Rep, 2022; 12(1):13582; doi: 10.1038/s41598-022-17852-2
31.
KiranS, DwivediP, KumarV, et al.Immunomodulation and biomaterials: Key players to repair volumetric muscle loss. Cells, 2021; 10(8); doi: 10.3390/cells10082016
32.
EgawaT, KidoK, YokokawaT, et al.Involvement of receptor for advanced glycation end products in microgravity-induced skeletal muscle atrophy in mice. Acta Astronautica, 2020; 176:332–340; doi: 10.1016/j.actaastro.2020.07.002
33.
YabuuchiJ, UedaS, YamagishiS, et al.Association of advanced glycation end products with sarcopenia and frailty in chronic kidney disease. Sci Rep, 2020; 10(1):17647; doi: 10.1038/s41598-020-74673-x
34.
DalalM, FerrucciL, SunK, et al.Elevated serum advanced glycation end products and poor grip strength in older community-dwelling women. J Gerontol A Biol Sci Med Sci, 2009; 64(1):132–137; doi: 10.1093/gerona/gln018
35.
SincennesMC, BrunCE, LinAYT, et al.Acetylation of PAX7 controls muscle stem cell self-renewal and differentiation potential in mice. Nat Commun, 2021; 12(1):3253; doi: 10.1038/s41467-021-23577-z
36.
Kassar-DuchossoyL, GiaconeE, Gayraud-MorelB, et al.Pax3/Pax7 mark a novel population of primitive myogenic cells during development. Genes Dev, 2005; 19(12):1426–1431; doi: 10.1101/gad.345505
37.
OlguinHC, PiscontiA. Marking the tempo for myogenesis: Pax7 and the regulation of muscle stem cell fate decisions. J Cell Mol Med, 2012; 16(5):1013–1025; doi: 10.1111/j.1582-4934.2011.01348.x
38.
AnsseauE, Laoudj-ChenivesseD, MarcowyczA, et al.DUX4c is up-regulated in FSHD. It induces the MYF5 protein and human myoblast proliferation. PLoS One, 2009; 4(10):e7482; doi: 10.1371/journal.pone.0007482
39.
ZammitPS, CarvajalJJ, GoldingJP, et al.Myf5 expression in satellite cells and spindles in adult muscle is controlled by separate genetic elements. Dev Biol, 2004; 273(2):454–465; doi: 10.1016/j.ydbio.2004.05.038
40.
MusaròA, Cusella De AngelisMG, GermaniA, et al.Enhanced expression of myogenic regulatory genes in aging skeletal-muscle. Exp Cell Res, 1995; 221(1):241–248; doi: 10.1006/excr.1995.1372
41.
RiuzziF, SorciG, SaghedduR, et al.RAGE in the pathophysiology of skeletal muscle. J Cachexia Sarcopenia Muscle, 2018; 9(7):1213–1234; doi: 10.1002/jcsm.12350
42.
JangM, OhSW, LeeY, et al.Targeting extracellular matrix glycation to attenuate fibroblast activation. Acta Biomater, 2022; 141:255–263; doi: 10.1016/j.actbio.2022.01.040
43.
SaghedduR, ChiappalupiS, SalvadoriL, et al.Targeting RAGE as a potential therapeutic approach to Duchenne muscular dystrophy. Hum Mol Genet, 2018; 27(21):3734–3746; doi: 10.1093/hmg/ddy288
44.
WadaR, YagihashiS. Role of advanced glycation end products and their receptors in development of diabetic neuropathy. Ann N Y Acad Sci, 2005; 1043:598–604; doi: 10.1196/annals.1338.067
45.
RiuzziF, BeccaficoS, SaghedduR, et al.Levels of S100B protein drive the reparative process in acute muscle injury and muscular dystrophy. Sci Rep, 2017; 7(1):12537; doi: 10.1038/s41598-017-12880-9
46.
SorciG, RiuzziF, ArcuriC, et al.Amphoterin stimulates myogenesis and counteracts the antimyogenic factors basic fibroblast growth factor and S100B via RAGE binding. Mol Cell Biol, 2004; 24(11):4880–4894; doi: 10.1128/mcb.24.11.4880-4894.2004
47.
RiuzziF, SorciG, BeccaficoS, et al.S100B engages RAGE or bFGF/FGFR1 in myoblasts depending on its own concentration and myoblast density. Implications for muscle regeneration. PLoS One, 2012; 7(1):e28700; doi: 10.1371/journal.pone.0028700
48.
MishraPK, YingW, NandiSS, et al.Diabetic cardiomyopathy: An immunometabolic perspective. Front Endocrinol (Lausanne), 2017; 8:72; doi: 10.3389/fendo.2017.00072
49.
DurieuxJJ, VitaN, PopescuO, et al.The two soluble forms of the lipopolysaccharide receptor, CD14: Characterization and release by normal human monocytes. Eur J Immunol, 1994; 24(9):2006–2012; doi: 10.1002/eji.1830240911
50.
WeiP, DongM, BiY, et al.Identification and validation of a signature based on macrophage cell marker genes to predict recurrent miscarriage by integrated analysis of single-cell and bulk RNA-sequencing. Front Immunol, 2022; 13:1053819; doi: 10.3389/fimmu.2022.1053819
51.
ZhuZ, AtkinsonTP, HovankyKT, et al.High prevalence of complement component C6 deficiency among African-Americans in the south-eastern USA. Clin Exp Immunol, 2000; 119(2):305–310; doi: 10.1046/j.1365-2249.2000.01113.x
52.
NoerJB, TalmanMM, MoreiraJMA. HLA Class II Histocompatibility Antigen γ Chain (CD74) expression is associated with immune cell infiltration and favorable outcome in breast cancer. Cancers (Basel), 2021; 13(24); doi: 10.3390/cancers13246179
53.
FangBA, KovačevićŽ, ParkKC, et al.Molecular functions of the iron-regulated metastasis suppressor, NDRG1, and its potential as a molecular target for cancer therapy. Biochim Biophys Acta, 2014; 1845(1):1–19; doi: 10.1016/j.bbcan.2013.11.002
54.
Al BarashdiMA, AliA, McMullinMF, et al.Protein tyrosine phosphatase receptor type C (PTPRC or CD45). J Clin Pathol, 2021; 74(9):548–552; doi: 10.1136/jclinpath-2020-206927
55.
YeeCSK, SanalO, ChouJS, et al.Coronin-1A oligomerization is critical for host defense against viral pathogens. Journal of Allergy and Clinical Immunology, 2014; 133(2):AB94; doi: 10.1016/j.jaci.2013.12.351
56.
AokiM, AokiH, RamanathanR, et al.Sphingosine-1-Phosphate signaling in immune cells and inflammation: Roles and therapeutic potential (vol 2016, 8606878, 2016). Mediators of Inflammation, 2016; 2016:1; doi: 10.1155/2016/2856829
57.
ChenWW, WangW, SunXX, et al.NudCL2 regulates cell migration by stabilizing both myosin-9 and LIS1 with Hsp90. Cell Death Dis, 2020; 11(7):534; doi: 10.1038/s41419-020-02739-9
58.
TuH, LiYL. Inflammation balance in skeletal muscle damage and repair. Front Immunol, 2023; 14:1133355; doi: 10.3389/fimmu.2023.1133355
59.
LiaoHJ, ZakhalevaJ, ChenW. Cells and tissue interactions with glycated collagen and their relevance to delayed diabetic wound healing. Biomaterials, 2009; 30(9):1689–1696; doi: 10.1016/j.biomaterials.2008.11.038
60.
KimJT, KasukonisB, DunlapG, et al.Regenerative repair of volumetric muscle loss injury is sensitive to age. Tissue Eng Part A, 2020; 26(1–2):3–14; doi: 10.1089/ten.tea.2019.0034
61.
GerhardGS, HansonA, WilhelmsenD, et al.AEBP1 expression increases with severity of fibrosis in NASH and is regulated by glucose, palmitate, and miR-372-3p. PLoS One, 2019; 14(7):e0219764; doi: 10.1371/journal.pone.0219764
LiuL, BroszczakDA, BroadbentJA, et al.Comparative label-free mass spectrometric analysis of temporal changes in the skeletal muscle proteome after impact trauma in rats. Am J Physiol Endocrinol Metab, 2020; 318(6):E1022–E1037; doi: 10.1152/ajpendo.00433.2019
66.
LeeEJ, AhmadSS, LimJH, et al.Interaction of Fibromodulin and Myostatin to regulate skeletal muscle aging: An opposite regulation in muscle aging, diabetes, and intracellular lipid accumulation. Cells, 2021; 10(8):17; doi: 10.3390/cells10082083
67.
YinHD, CuiC, HanSS, et al.Fibromodulin modulates chicken skeletal muscle development via the transforming growth factor-β signaling pathway. Animals (Basel), 2020; 10(9):11; doi: 10.3390/ani10091477
Briceno NoriegaD, ZenkerHE, CroesCA, et al.Receptor mediated effects of advanced glycation end products (AGEs) on innate and adaptative immunity: Relevance for food allergy. Nutrients, 2022; 14(2); doi: 10.3390/nu14020371
70.
Janelle-MontcalmA, BoileauC, PoirierF, et al.Extracellular localization of galectin-3 has a deleterious role in joint tissues. Arthritis Res Ther, 2007; 9(1):R20; doi: 10.1186/ar2130
71.
CerriDG, RodriguesLC, AlvesVM, et al.Endogenous galectin-3 is required for skeletal muscle repair. Glycobiology, 2021; 31(10):1295–1307; doi: 10.1093/glycob/cwab071
72.
PalanissamiG, PaulSFD. RAGE and its ligands: Molecular interplay between glycation, inflammation, and hallmarks of cancer-A review. Horm Cancer, 2018; 9(5):295–325; doi: 10.1007/s12672-018-0342-9
73.
PaliwalP, PisheshaN, WijayaD, et al.Age dependent increase in the levels of osteopontin inhibits skeletal muscle regeneration. Aging (Albany NY), 2012; 4(8):553–566; doi: 10.18632/aging.100477
74.
HerwigN, BelterB, WolfS, et al.Interaction of extracellular S100A4 with RAGE prompts prometastatic activation of A375 melanoma cells. J Cell Mol Med, 2016; 20(5):825–835; doi: 10.1111/jcmm.12808
