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Abstract

To utilize three-dimensional (3D) engineered human skeletal muscle tissue for translational studies and in vitro studies of drug toxicity, there is a need to promote differentiation and functional behavior. In this study, we identified conditions to promote contraction of engineered human skeletal muscle bundles and examined the effects of transient inhibition of microRNAs (miRs) on myogenic differentiation and function of two-dimensional (2D) and 3D cultures of human myotubes. In 2D cultures, simultaneously inhibiting both miR-133a, which promotes myoblast proliferation, and miR-696, which represses oxidative metabolism, resulted in an increase in sarcomeric α-actinin protein and the metabolic coactivator PGC-1α protein compared to transfection with a scrambled miR sequence (negative control). Although PGC-1α was elevated following joint inhibition of miRs 133a and 696, there was no difference in myosin heavy chain (MHC) protein isoforms. 3D engineered human skeletal muscle myobundles seeded with 5 × 10⁶ human skeletal myoblasts (HSkM)/mL and cultured for 2 weeks after onset of differentiation consistently did not contract when stimulated electrically, whereas those seeded with myoblasts at 10 × 10⁶ HSkM/mL or higher did contract. When HSkM were transfected with both anti-miRs and seeded into fibrin hydrogels and cultured for 2 weeks under static conditions, twitch and tetanic specific forces after electrical stimulation were greater than for myobundles prepared with HSkM transfected with scrambled sequences. Immunofluorescence and Western blots of 3D myobundles indicate that anti-miR-133a or anti-miR-696 treatment led to modest increases in slow MHC, but no consistent increase in fast MHC. Similar to results in 2D, only myobundles prepared with myoblasts treated with anti-miR-133a and anti-miR-696 produced an increase in PGC-1α mRNA. PGC-1α targets were differentially affected by the treatment. HIF-2α mRNA showed an expression pattern similar to that of PGC-1α mRNA, but COXII mRNA levels were not affected by the anti-miRs. Overall, joint inhibition of miR-133a and miR-696 accelerated differentiation, elevated the metabolic coactivator PGC-1α, and increased the contractile force in 3D engineered human skeletal muscle bundles.

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References

Truskey

G.A.

, Achneck

H.E.

, Bursac

, Chan

, Cheng

C.S.

, Fernandez

, Hong

, Jung

, Koves

, Kraus

W.E.

, Leong

, Madden

, Reichert

W.M.

, and Zhao

Design considerations for an integrated microphysiological muscle tissue for drug and tissue toxicity testing. Stem Cell Res Ther, 4 Suppl 1, S10, 2013.

Martin

N.R.

, Passey

S.L.

, Player

D.J.

, Khodabukus

, Ferguson

R.A.

, Sharples

A.P.

, Mudera

, Baar

, and Lewis

M.P.

Factors affecting the structure and maturation of human tissue engineered skeletal muscle. Biomaterials, 34, 5759, 2013.

Moon du

, Christ

, Stitzel

J.D.

, Atala

, and Yoo

J.J.

Cyclic mechanical preconditioning improves engineered muscle contraction. Tissue Eng Part A, 14, 473, 2008.

Guo

, Gonzalez

, Stancescu

, Vandenburgh

H.H.

, and Hickman

J.J.

Neuromuscular junction formation between human stem cell-derived motoneurons and human skeletal muscle in a defined system. Biomaterials, 32, 9602, 2011.

Lambernd

, Taube

, Schober

, Platzbecker

, Gorgens

S.W.

, Schlich

, Jeruschke

, Weiss

, Eckardt

, and Eckel

Contractile activity of human skeletal muscle cells prevents insulin resistance by inhibiting pro-inflammatory signalling pathways. Diabetologia, 55, 1128, 2012.

Madden

, Juhas

, Kraus

, Truskey

, and Bursac

Contractile human myobundles for studies of muscle physiology and drug response. Elife, 4, e04885, 2015.

Chen

J.F.

, Mandel

E.M.

, Thomson

J.M.

, Wu

, Callis

T.E.

, Hammond

S.M.

, Conlon

F.L.

, and Wang

D.Z.

The role of microRNA-1 and microRNA-133 in skeletal muscle proliferation and differentiation. Nat Genet, 38, 228, 2006.

Guller

, and Russell

A.P.

MicroRNAs in skeletal muscle: their role and regulation in development, disease and function. J Physiol, 588, 4075, 2010.

Koning

, Werker

P.M.

, van der Schaft

D.W.

, Bank

R.A.

, and Harmsen

M.C.

MicroRNA-1 and microRNA-206 improve differentiation potential of human satellite cells: a novel approach for tissue engineering of skeletal muscle. Tissue Eng Part A, 18, 889, 2012.

10.

Rhim

, Cheng

C.S.

, Kraus

W.E.

, and Truskey

G.A.

Effect of microRNA modulation on bioartificial muscle function. Tissue Eng Part A, 16, 3589, 2010.

11.

Cheng

C.S.

, El-Abd

, Bui

, Hyun

Y.E.

, Hughes

R.H.

, Kraus

W.E.

, and Truskey

G.A.

Conditions that promote primary human skeletal myoblast culture and muscle differentiation in vitro. Am J Physiol Cell Physiol, 306, C385, 2014.

12.

Aoi

, Naito

, Mizushima

, Takanami

, Kawai

, Ichikawa

, and Yoshikawa

The microRNA miR-696 regulates PGC-1{alpha} in mouse skeletal muscle in response to physical activity. Am J Physiol Endocrinol Metab, 298, E799, 2010.

13.

Eivers

S.S.

, McGivney

B.A.

, Gu

, MacHugh

D.E.

, Katz

L.M.

, and Hill

E.W.

PGC-1alpha encoded by the PPARGC1A gene regulates oxidative energy metabolism in equine skeletal muscle during exercise. Anim Genet, 43, 153, 2012.

14.

Wang

Y.X.

, Zhang

C.L.

, Yu

R.T.

, Cho

H.K.

, Nelson

M.C.

, Bayuga-Ocampo

C.R.

, Ham

, Kang

, and Evans

R.M.

Regulation of muscle fiber type and running endurance by PPARdelta. PLoS Biol, 2, e294, 2004.

15.

Philp

, Belew

M.Y.

, Evans

, Pham

, Sivia

, Chen

, Schenk

, and Baar

The PGC-1alpha-related coactivator promotes mitochondrial and myogenic adaptations in C2C12 myotubes. Am J Physiol Regul Integr Comp Physiol, 301, R864, 2011.

16.

Hinds

, Bian

, Dennis

R.G.

, and Bursac

The role of extracellular matrix composition in structure and function of bioengineered skeletal muscle. Biomaterials, 32, 3575, 2011.

17.

Juhas

, Engelmayr

G.C.

Jr ., Fontanella

A.N.

, Palmer

G.M.

, and Bursac

Biomimetic engineered muscle with capacity for vascular integration and functional maturation in vivo. Proc Natl Acad Sci U S A, 111, 5508, 2014.

18.

van der Ven

P.F.

, Schaart

, Jap

P.H.

, Sengers

R.C.

, Stadhouders

A.M.

, and Ramaekers

F.C.

Differentiation of human skeletal muscle cells in culture: maturation as indicated by titin and desmin striation. Cell Tissue Res, 270, 189, 1992.

19.

Bonavaud

, Agbulut

, Nizard

, D'Honneur

, Mouly

, and Butler-Browne

A discrepancy resolved: human satellite cells are not preprogrammed to fast and slow lineages. Neuromuscul Disord, 11, 747, 2001.

20.

Mouly

, Edom

, Barbet

J.P.

, and Butler-Browne

G.S.

Plasticity of human satellite cells. Neuromuscul Disord, 3, 371, 1993.

21.

Edom

, Mouly

, Barbet

J.P.

, Fiszman

M.Y.

, and Butler-Browne

G.S.

Clones of human satellite cells can express in vitro both fast and slow myosin heavy chains. Dev Biol, 164, 219, 1994.

22.

Scott

, Stevens

, and Binder-Macleod

S.A.

Human skeletal muscle fiber type classifications. Phys Ther, 81, 1810, 2001.

23.

Mudera

, Smith

A.S.

, Brady

M.A.

, and Lewis

M.P.

The effect of cell density on the maturation and contractile ability of muscle derived cells in a 3D tissue-engineered skeletal muscle model and determination of the cellular and mechanical stimuli required for the synthesis of a postural phenotype. J Cell Physiol, 225, 646, 2010.

24.

Snyman

, Goetsch

K.P.

, Myburgh

K.H.

, and Niesler

C.U.

Simple silicone chamber system for in vitro three-dimensional skeletal muscle tissue formation. Front Physiol, 4, 349, 2013.

25.

Rhim

, Lowell

D.A.

, Reedy

M.C.

, Slentz

D.H.

, Zhang

S.J.

, Kraus

W.E.

, and Truskey

G.A.

Morphology and ultrastructure of differentiating three-dimensional mammalian skeletal muscle in a collagen gel. Muscle Nerve, 36, 71, 2007.

26.

Kragstrup

T.W.

, Kjaer

, and Mackey

A.L.

Structural, biochemical, cellular, and functional changes in skeletal muscle extracellular matrix with aging. Scand J Med Sci Sports, 21, 749, 2011.

27.

Gosselin

L.E.

, Adams

, Cotter

T.A.

, McCormick

R.J.

, and Thomas

D.P.

Effect of exercise training on passive stiffness in locomotor skeletal muscle: role of extracellular matrix. J Appl Physiol (1985), 85, 1011, 1998.

28.

Siegman

M.J.

, Davidheiser

, Mooers

S.U.

, and Butler

T.M.

Structural limits on force production and shortening of smooth muscle. J Muscle Res Cell Motil, 34, 43, 2013.

29.

Larkin

L.M.

, Calve

, Kostrominova

T.Y.

, and Arruda

E.M.

Structure and functional evaluation of tendon-skeletal muscle constructs engineered in vitro. Tissue Eng, 12, 3149, 2006.

30.

Rasbach

K.A.

, Gupta

R.K.

, Ruas

J.L.

, Wu

, Naseri

, Estall

J.L.

, and Spiegelman

B.M.

PGC-1alpha regulates a HIF2alpha-dependent switch in skeletal muscle fiber types. Proc Natl Acad Sci U S A, 108, 21866, 2010.

31.

Lin

, Wu

, Tarr

P.T.

, Zhang

C.Y.

, Wu

, Boss

, Michael

L.F.

, Puigserver

, Isotani

, Olson

E.N.

, Lowell

B.B.

, Bassel-Duby

, and Spiegelman

B.M.

Transcriptional co-activator PGC-1 alpha drives the formation of slow-twitch muscle fibres. Nature, 418, 797, 2002.

32.

Williams

A.H.

, Liu

, van Rooij

, and Olson

E.N.

MicroRNA control of muscle development and disease. Curr Opin Cell Biol, 21, 461, 2009.

33.

van Rooij

, Purcell

A.L.

, and Levin

A.A.

Developing microRNA therapeutics. Circ Res, 110, 496, 2012.

34.

Liu

, Bezprozvannaya

, Shelton

J.M.

, Frisard

M.I.

, Hulver

M.W.

, McMillan

R.P.

, Wu

, Voelker

K.A.

, Grange

R.W.

, Richardson

J.A.

, Bassel-Duby

, and Olson

E.N.

Mice lacking microRNA 133a develop dynamin 2-dependent centronuclear myopathy. J Clin Invest, 121, 3258, 2011.

35.

, Dickinson

C.E.

, Finkelstein

E.B.

, Neville

C.M.

, and Sundback

C.A.

The role of fibroblasts in self-assembled skeletal muscle. Tissue Eng Part A, 17, 2641, 2011.

36.

Duisters

R.F.

, Tijsen

A.J.

, Schroen

, Leenders

J.J.

, Lentink

, van der Made

, Herias

, van Leeuwen

R.E.

, Schellings

M.W.

, Barenbrug

, Maessen

J.G.

, Heymans

, Pinto

Y.M.

, and Creemers

E.E.

miR-133 and miR-30 regulate connective tissue growth factor: implications for a role of microRNAs in myocardial matrix remodeling. Circ Res, 104, 170, 2009.

37.

Thorsteinsdottir

, Deries

, Cachaco

A.S.

, and Bajanca

The extracellular matrix dimension of skeletal muscle development. Dev Biol, 354, 191, 2011.

38.

Morozova

, Zinovyev

, Nonne

, Pritchard

L.-L.

, Gorban

A.N.

, and Harel-Bellan

Kinetic signatures of microRNA modes of action. RNA, 18, 1635, 2012.

39.

Kirby

T.J.

, Chaillou

, and McCarthy

J.J.

The role of microRNAs in skeletal muscle health and disease. Front Biosci, 20, 37, 2015.

40.

Ebert

M.S.

, and Sharp

P.A.

Roles for MicroRNAs in conferring robustness to biological processes. Cell, 149, 515, 2012.

41.

Schiaffino

, and Reggiani

Fiber types in mammalian skeletal muscles. Physiol Rev, 91, 1447, 2011.

42.

Khodabukus

, and Baar

Glucose concentration and streptomycin alter in vitro muscle function and metabolism. J Cell Physiol, 230, 1226, 2015.

43.

Khodabukus

, and Baar

The effect of serum origin on tissue engineered skeletal muscle function. J Cell Biochem, 115, 2198, 2014.

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Cell Density and Joint microRNA-133a and microRNA-696 Inhibition Enhance Differentiation and Contractile Function of Engineered Human Skeletal Muscle Tissues

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