Isoform Diversity of Giant Proteins in Relation to Passive and Active Contractile Properties of Rabbit Skeletal Muscles

doi:10.1085/jgp.200509364

Published online 17 October 2005 doi:10.1085/jgp.200509364
The Rockefeller University Press, 0022-1295 $8.00
JGP, Volume 126, Number 5, 461-480

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ARTICLE

Isoform Diversity of Giant Proteins in Relation to Passive and Active Contractile Properties of Rabbit Skeletal Muscles

Lucas G. Prado¹, Irina Makarenko², Christian Andresen², Martina Krüger², Christiane A. Opitz¹, and Wolfgang A. Linke²

¹ Institute of Physiology and Pathophysiology, University of Heidelberg, D-69120 Heidelberg, Germany
² Physiology and Biophysics Unit, University of Muenster, D-48149 Muenster, Germany

Correspondence to Wolfgang A. Linke: wlinke{at}uni-muenster.de

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The active and passive contractile performance of skeletal musclefibers largely depends on the myosin heavy chain (MHC) isoformand the stiffness of the titin spring, respectively. Open questionsconcern the relationship between titin-based stiffness and activecontractile parameters, and titin's importance for total passivemuscle stiffness. Here, a large set of adult rabbit muscles(n = 37) was studied for titin size diversity, passive mechanicalproperties, and possible correlations with the fiber/MHC composition.Titin isoform analyses showed sizes between $~$ 3300 and 3700 kD;31 muscles contained a single isoform, six muscles coexpressedtwo isoforms, including the psoas, where individual fibers expressedsimilar isoform ratios of 30:70 (3.4:3.3 MD). Gel electrophoresisand Western blotting of two other giant muscle proteins, nebulinand obscurin, demonstrated muscle type–dependent sizedifferences of $≤$ 70 kD. Single fiber and single myofibril mechanicsperformed on a subset of muscles showed inverse relationshipsbetween titin size and titin-borne tension. Force measurementson muscle strips suggested that titin-based stiffness is notcorrelated with total passive stiffness, which is largely determinedalso by extramyofibrillar structures, particularly collagen.Some muscles have low titin-based stiffness but high total passivestiffness, whereas the opposite is true for other muscles. Plotsof titin size versus percentage of fiber type or MHC isoform(I-IIB-IIA-IID) determined by myofibrillar ATPase staining andgel electrophoresis revealed modest correlations with the typeI fiber and MHC-I proportions. No relationships were found withthe proportions of the different type II fiber/MHC-II subtypes.Titin-based stiffness decreased with the slow fiber/MHC percentage,whereas neither extramyofibrillar nor total passive stiffnessdepended on the fiber/MHC composition. In conclusion, a lowcorrelation exists between the active and passive mechanicalproperties of skeletal muscle fibers. Slow muscles usually expresslong titin(s), predominantly fast muscles can express eithershort or long titin(s), giving rise to low titin-based stiffnessin slow muscles and highly variable stiffness in fast muscles.Titin contributes substantially to total passive stiffness,but this contribution varies greatly among muscles.

L.G. Prado and I. Makarenko contributed equally to this work.

Abbreviations used in this paper: BDM, 2,3-butanedione monoxime;MHC, myosin heavy chain; PT, passive tension; SL, sarcomerelength.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Textbook knowledge indicates that the type of myosin heavy chain(MHC) expressed in a skeletal muscle is a major determinantof that muscle's contractile characteristics. Slow MHC isoformspredominante in slow muscles, fast MHC isoforms in fast muscles(Staron and Pette, 1986). MHC is encoded by a multigene familyconsisting of several members expressed in a developmentallyregulated and tissue-specific manner (Schiaffino and Reggiani,1994). In adult mammalian muscles, four MHC isoforms have beenidentified, which are termed I (slow), IIA, IIX or IID, andIIB (all fast). The unique expression of any one of these MHCisoforms in a single muscle fiber is primarily responsible forthe distinct fiber types observed in skeletal muscle after stainingfor myofibrillar ATPase following acid or alkaline preincubations(Termin et al., 1989). Both the myofibrillar ATPase activitiesand the MHC-based fiber type composition of a muscle can beused to predict the contractile properties of the whole muscle(Thomason et al., 1986; Ranatunga and Thomas, 1990). A closerelationship has been suggested to exist between the isoformsof MHC and those of myosin light chains (Salviati et al., 1982;Schiaffino and Reggiani, 1994) and regulatory proteins in thesarcomere, e.g., the troponins (Salviati et al., 1982; Wadeet al., 1990; O'Connell et al., 2004). Also the molecular compositionsof both the sarcomeric M-band (Agarkova et al., 2004) and Z-disc(Sorimachi et al., 1997; MacArthur and North, 2004) correlatewith muscle fiber type.

Titin (Wang et al., 1979), first described as connectin (Maruyamaet al., 1976), is a giant protein in sarcomeres, which is expressedin different isoforms generated by alternative splicing fromthe transcript of a single titin gene (Labeit and Kolmerer,1995). Titin molecules span across half sarcomeres and the Iband segment acts as a molecular spring, whereas the A bandpart is functionally stiff (Fig. 1). Titin's differentiallyspliced part is in the I band and in skeletal muscles expressingso-called "N2A-titin," there are two segments that vary in lengthin the different isoforms: a "proximal" tandem Ig region andthe PEVK domain (Fig. 1). Titin has multiple roles in sarcomericfunction (Neagoe et al., 2003; Granzier and Labeit, 2004; Milleret al., 2004; Tskhovrebova and Trinick, 2004) but is well recognizedfor being a main determinant of passive tension (PT) (Maruyamaet al., 1984; Magid and Law, 1985; Horowits et al., 1986; Funatsuet al., 1990; Salviati et al., 1990). It has been shown thatlong titin isoforms give rise to relatively low PT, short titinisoforms to higher PT (Wang et al., 1991; Horowits, 1992; Linkeet al., 1996; Granzier et al., 2000).

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Figure 1. Titin and nebulin in the sarcomere and nomenclature of elastic I-band regions in the skeletal muscle titin isoforms, "N2A."

The largest titin sequenced to date (3,700 kD) is found in humansoleus, a slow muscle with low myofibrillar PT (Trombitas etal., 1998

), whereas small titin (3,400 kD) is expressed in thefast-twitch rabbit psoas (Freiburg et al., 2000

), which hashigh myofibrillar PT (Linke et al., 1996

). Many researchershave therefore assumed that the muscle type may be related tothe titin size, in that fast muscles express short and stifftitin, slow muscles long and compliant titin. This idea, however,had never been tested, largely because of difficulties in resolvingsize differences of proteins in the MD range. We have recentlyoptimized the detection of titin isoforms on 2% SDS-PAGE (Neagoeet al., 2002

; Opitz et al., 2004

). Here, by using sequencedtitin isoforms as size markers, we determined the titin sizevariations in a set of 37 different adult rabbit skeletal muscles.Similarly, we analyzed the size distributions of two other giantmuscle proteins: nebulin, an actin-binding protein acting asa thin filament length ruler (Kruger et al., 1991

; Labeit etal., 1991

); and obscurin, a sarcomere-associated signaling protein(Young et al., 2001

) also suggested to provide an elastic linkbetween adjacent myofibrils (Borisov et al., 2004

). We findthat isoform variability is low for nebulin (range, $~$ 700–760kD), modest for obscurin ( $~$ 680–750 kD), but large for titin(3300–3700 kD). The titin size diversity is shown by singlemyofibril, single fiber, and fiber bundle mechanics to causesubstantial differences in titin-based PT between muscles.

Two previously unresolved issues concern titin's importancefor total passive muscle stiffness and the relationship betweentitin-based stiffness and active contractile parameters. Herewe tested the hypothesis that titin-borne PT, adjustable bymodifying the length of titin's elastic spring, is related tothe active contractile properties characterized by the fiber/MHCcomposition. Fiber types I, IIA, and IIB/IID were discriminatedby myosin ATPase staining, and MHC isoforms I, IIA, IIB, andIID were determined on SDS-PAGE. Only a low correlation withtitin size and titin-based stiffness is found. Results suggestthat predominantly slow muscles have long titin and low titin-bornePT, whereas fast muscles express long or short titin(s) anddiffer greatly in titin-based PT. Finally, we extend earlierevidence suggesting that a large contribution to a muscle'spassive stiffness comes from extramyofibrillar structures, particularlycollagen (Kovanen et al., 1984a; Gosselin et al., 1998; Ducompset al., 2003). We demonstrate by fiber bundle mechanics thatthe relative contribution of titin versus that of the extracellularmatrix to passive stiffness varies greatly among different muscles.Some muscles (e.g., soleus) have low titin-borne stiffness buthigh total passive stiffness, whereas the opposite is true forother muscles (e.g., psoas). Titin-based stiffness, but notextramyofibrillar stiffness, correlates with muscle type.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Dissection of Rabbit Skeletal Muscles
Adult male New Zealand white rabbits (weight, 2–3 kg)obtained from the university's animal house were killed by themethod of captive bolt according to the recommendations of theinstitutional animal care committee (Medical Faculty, Universityof Heidelberg). Skeletal muscles were dissected with the helpof a Rabbit Dissection Manual (Wingerd, 1985), and anatomicallocations of skeletal muscles were verified using a rabbit anatomyatlas (Popesko et al., 1992). Dissected muscles were shock-frozenin liquid nitrogen and stored at –80°C until furtheranalysis. Some muscles were also used directly after fresh dissectionfor intact fiber bundle mechanics (see below), whereas musclesto be used for single-fiber mechanics were stored at –20°Cin 50% glycerol: 50% low ionic strength buffer (75 mM KCl, 10mM Tris, 2 mM MgCl₂, 2 mM EGTA, 40 µg/ml protease inhibitorleupeptin, pH 7.1). Each muscle type was dissected at leasttwice (from two different animals).

SDS-PAGE
Frozen skeletal muscles were homogenized in ice-cold salt buffersupplemented with 40 µg/ml leupeptin. For details, seeNeagoe et al. (2002) and Opitz et al. (2004). After brief centrifugation,solubilization buffer (1% SDS, 1% 2-mercaptoethanol, 10% glycerol,8 µg/ml leupeptin, 6 µM bromophenol blue, 4.3 mMTris-HCl, pH 8.8, 4.3 mM EDTA) was added to the pellet, sampleswere incubated for 5 min on ice and boiled for 3 min.

Conventional 12.5% SDS-PAGE to separate proteins in the rangeof 15–220 kD was performed according to standard protocols.To investigate titin and nebulin isoforms, agarose-strengthenedSDS-PAGE with a 2% polyacrylamide concentration was performed(Linke et al., 1997; Neagoe et al., 2002) using a Laemmli buffersystem and a Biometra mini-gel system. To help estimate themolecular weight of titin isoforms, 2% SDS-PAGE lanes were loadedwith a mix of muscle expressing titin of unknown size and therabbit psoas muscle, which expresses two N2A-titin isoformsof $~$ 3.40 and 3.30 MD at a ratio of $~$ 30:70%. In sequencing studies,rabbit psoas titin has been predicted to be 3.40 MD (Freiburget al., 2000). Using the psoas-titin bands as internal standards,the molecular mass of the titin band(s) of any muscle couldbe determined independent of size markers in adjacent gel lanes.Alternate lanes on a gel were loaded with psoas muscle alone,muscle with unknown titin size alone, or rat heart tissue, whichprovided another useful size marker at 3,000 kD (N2B-titin isoform),plus two faint cardiac N2BA-titin bands at 3,220 and 3,390 kD(Opitz et al., 2004; Warren et al., 2004). All gels were alsoloaded with rabbit soleus (titin, $~$ 3,600 kD) and some gels withhuman soleus (3,700 kD) and human heart tissue (N2B isoform,3,000 kD; N2BA isoform, 3,300 kD) to obtain additional titin(and nebulin) size markers. We are grateful to Dr. R. Bittner(University of Vienna, Vienna, Austria) and Drs. Roger Hajjarand Federica del Monte (Massachusetts General Hospital, Boston,MA) for the gift of human soleus and human heart tissue, respectively.Attempts were made to load all lanes with equal amounts of solubilizedprotein after spectrophotometric analysis (Bradford method).

Protein bands were visualized with Coomassie brilliant blueor by silver staining, and gels were digitized by multiple scanningusing a CanoScan 9900F scanner (Canon). Molecular weight calibration,measurements of titin size, and densitometry analyses were doneusing TotalLab software (Phoretix). A linear relationship betweenlog M_w and migration distance was assumed. Mean values (±SEM)of titin size were calculated from three to five observationsper muscle type.

Western Blotting
Immunoblotting to detect obscurin isoforms was done using chemiluminescentreaction kit (ECL system, Amersham Biosciences) according tostandard protocols (Makarenko et al., 2004). Primary obscurinantibodies were ${alpha}$ -I48/I49 and ${alpha}$ -DH-domain, which were providedby M. Gautel (Young et al., 2001) and E. Ehler (King's CollegeLondon, UK). Peroxidase-conjugated IgG served as secondary antibody.

Single-fiber Mechanics
Single fibers 4–5 mm long were dissected from chemicallyskinned skeletal muscles previously stored in 50% glycerol:50% low ionic strength buffer at –20°C for a maximumof 3 wk. We selected five muscles expressing different titinsizes, from small to large: psoas < EDL < gastrocnemius< longissimus dorsi < diaphragm. Except for the psoas,these muscles were found to express a single titin isoform.EDL and longissimus showed a similar proportion of slow fibers/MHC-Iisoforms. Before dissection, muscles were skinned overnightin relaxing buffer (8 mM ATP, 10 mM phosphocreatine, 20 mM imidazole,4 mM EGTA, 12 mM Mg-proprionate, 97 mM K-proprionate, 40 µg/mlleupeptin, pH 7.0, 180 mM ionic strength), to which 0.5% TritonX-100 had been added. Dissection was performed in relaxing bufferand care was taken to avoid excessive stretching of the fibers.

Mechanical measurements were made with a muscle mechanics workstation(Scientific Instruments; Minajeva et al., 2002; Opitz et al.,2003) at room temperature. Fibers were bathed in relaxing buffer(plus 40 µg/ml leupeptin, 30 mM 2,3-butanedione monoxime(BDM), an active force inhibitor, and 380 U/ml creatine kinase)and were attached to a motor arm and force transducer throughstainless steel clips. Sarcomere length (SL) was measured bylaser diffraction (Makarenko et al., 2004) using a 670-nm He-Nelaser. Only fibers with a clear diffraction pattern were usedfor mechanical measurements. Fibers were stretched from slackSL (2.0–2.2 µm) in six to seven steps of $~$ 0.2 µm/sarcomere(completed in 1 s) to a maximum SL, while SL was recorded duringa 2-min pause after each step. Following the last stretch–hold,fibers were released back to slack SL to test for possible shiftsof baseline force. Two identical stretch–release protocolswere performed on one preparation; little differences were usuallyfound between the recordings. From the recordings we measuredthe force at the end of each hold period and used these valuesto calculate force per cross-sectional area. The latter wasestimated from the diameter of each sample (assuming a circularshape) measured in the nonstretched state under a binocularmicroscope using a 10-µm grid.

Mechanical Measurements on Fiber Bundles
Fiber bundles 400–700 µm in diameter and 4–7mm long were prepared from freshly excised muscles or deep-frozentissue. Five muscles with increasing proportions of slow fibers/MHC-Iwere selected: psoas < EDL < gastrocnemius < diaphragm< soleus. Muscle strips were dissected as previously reported(Friden and Lieber, 2003) in a relaxing solution that preventsdepolarization across any site of disrupted membrane and proteolyticdegradation. In addition, the solution contained 20 mM BDM tofully relax the intact strips (Fryer et al., 1988) without affectingpassive tension (Mutungi and Ranatunga, 1996); BDM also helpsprotect intact fibers from damage (Bagni et al., 2002). Alternativelysome preparations were dissected and mechanically studied instandard Tyrode solution continuously bubbled with carbogen.Results of mechanical tests were similar for a given musclein either type of solution.

Force and SL measurements (laser diffractometry) were performedin the apparatus also used for single-fiber studies. The stretchprotocol was the same as described above. After measuring thestretch-dependent passive force of intact fiber bundles, thesuspended muscle strip was skinned in relaxing buffer including40 µg/ml leupeptin and 30 mM BDM, to which 0.5% wt/volTriton X-100 had been added. During skinning, the experimentalchamber was cooled down to $~$ 10°C and the skinning solutionwas stirred continuously using a magnetic bar. Skinning wascompleted after 4–6 h, when passive force developmentremained similar in two consecutive stretch protocols appliedat a 30-min interval. Fiber bundles were then washed thoroughlywith relaxing solution and passive force was recorded at roomtemperature. Finally, muscle strips were exposed to 0.2 µgtrypsin/ml relaxing buffer (without leupeptin) for 45 min, whichselectively proteolyzed titin, then the trypsin was washed outwith relaxing buffer (plus leupeptin), and the same stretchprotocol was repeated. For analysis, we again used the forceat the end of each hold period (elastic force component).

To obtain force/cross-sectional area, the diameter of each samplewas measured in the nonstretched state under a binocular microscope;a circular shape of the strip was assumed to calculate cross-sectionalarea. In addition, some bundles were fixed with 4% paraformaldehydein relaxing buffer following the mechanical measurements andcross sections were cut with a microtome (Makarenko et al.,2004). The cross-sectional area, confirmed to be of near-circularshape, was determined in at least four sections cut along thefiber axis; the area varied by <12% among different sectionsof the same muscle strip. The measured areas compared reasonablywell with the values calculated from the diameter of the specimens.

On quasi-steady-state passive tension versus SL plots, the datafor each muscle were pooled in SL bins spaced 0.2 µm andmean passive tension values were calculated for all five muscletypes, separately for intact, skinned, and titin-extracted preparations.Pooled data points for a given muscle were fitted by two-orderpolynomials. Passive stiffness was estimated from the area underthe respective fit curves (integrals) as previously described(Makarenko et al., 2004). The unit of the stiffness thus calculatedwas N/m. The stiffness before skinning was taken as 100% (totalstiffness).

Single Myofibril Mechanics
Rabbit psoas and soleus myofibrils were isolated as previouslydescribed (Linke et al., 1996; Minajeva et al., 2001). In brief,thin muscle strips tied to glass rods were skinned in ice cold,low ionic strength buffer supplemented with 0.5% Triton X-100for a minimum of 5 h. The skinned strips were minced and homogenizedin rigor buffer to separate myofibrils.

A setup for myofibrillar force measurements has been previouslydescribed (Linke et al., 1997; Kulke et al., 2001). In brief,under a Carl Zeiss Axiovert 135 microscope, a myofibril wassuspended between a glass needle attached to a piezomotor (PhysikInstrumente) and another needle connected to a force transducer(homebuilt) with nanonewton resolution. Data collection andmotor control were done with a PC, DAQ board, and custom-writtenLabView software (National Instruments). SLs were measured witha color-CCD camera (Sony), frame grabber, and Scion Image software(NIH) (Minajeva et al., 2002). Force measurements were performedat room temperature in relaxing buffer (Linke et al., 1994)supplemented with 30 mM BDM and 40 µg/ml leupeptin. Theprotocol consisted of stretching a nonactivated myofibril stepwisefrom slack SL by $~$ 0.2 µm/sarcomere/step; each step wascompleted in 1 s. Following each step, the specimen was heldat a constant SL for 20 s to wait for stress relaxation. Foranalysis we considered only the passive force at the end ofthe hold period, which represents titin-based force (Minajevaet al., 2001; Linke and Leake, 2004). To test for possible shiftsof force baseline, myofibrils were finally released back toslack SL. Force data were related to the cross-sectional areainferred from the diameter of the specimens (Linke et al., 1994).

Modeling Titin-based Passive Force
Predictions for the shape of the force–extension curveof a given titin isoform were based on the assumption that overallsingle molecule titin elasticity could be modeled as two independentwormlike chains (WLCs) acting in series, corresponding to segmentsof tandem Ig domains and the PEVK region (Linke et al., 1998;Li et al., 2002). The WLC model of entropic elasticity (Markoand Siggia, 1995) predicts the relationship between the relativeextension of a polymer (z/L) and the entropic restoring force(f) through

(1)
where k_B is the Boltzmannconstant, T is absolute temperature (here, 300 K), A is thepersistence length (a measure of the bending rigidity of thechain), z is the end-to-end length, and L is the chain's contourlength. For the titin segments, we used persistence length valuesof 10 nm (Ig domain regions) and 0.9 nm (PEVK domain), as suggestedby Li et al. (2002). The contour lengths for the segments followfrom the number of domains/residues in each segment and themaximum length of one domain (4.5 nm) or residue (0.36 nm).Unfolding of proximal Ig domains was modeled as a two-stateprocess (folded and unfolded) according to Rief et al. (1997)and Kellermayer et al. (1997). Unfolding of distal Ig domainswas excluded within the force range modeled.

The force developed by a single titin molecule upon extensionof a myofibril was predicted using the following size valuesfor skeletal titin isoforms: (a) 3,700 kD, the size of human-soleustitin containing 90 (68 proximal, 22 distal) Ig domains and2,200 PEVK residues in the molecule's elastic I band part (Labeitand Kolmerer, 1995), and (b) a mix of 3,400 kD (30% weight)and 3,300 kD (70% weight) isoforms, which mimicks the situationin rabbit psoas. Psoas titin was assumed to contain 72 (50 proximal,22 distal) Ig domains and 800 PEVK residues in the 3,400-kDisoform (Freiburg et al., 2000) and 65 (43 proximal, 22 distal)Ig domains and 650 PEVK residues in the 3,300-kD isoform. Forother parameters in the simulation, see Li et al. (2002).

Electron Microscopy
Intact and triton-skinned plus trypsin-treated rabbit psoasand soleus muscle strips (following mechanical measurements)were fixed in 4% paraformaldehyde (in relaxing buffer), dehydratedin an alcohol series, and embedded in Epon blocks. Cross sectionsor longitudinal sections were cut using a Reichert ultramicrotome.Contrasted sections were then used for transmission electronmicroscopy performed with a Carl Zeiss EM 900 at 80 kV. Of maininterest were the collagen depositions in between the musclefibers.

Histology and Myosin ATPase Staining
Small strips of muscle tissue were incubated in 4% paraformaldehydeovernight. Then the strips were attached to the plates of acryosectioning device (MICROM HM-500-O) using frozen sectionmedium (Neg–50; Richard-Allan Scientific). 20-µm-thickserial transverse sections were cut at –18°C, recoveredon a gelatin-coated glass slide, and dried. Myosin ATPase stainingwas performed following a protocol by Hamalainen and Pette (1993).Preincubation time was 15 min at pH 4.5 (room temperature) andincubation time was 45 min at pH 9.4 (37°C). In these acid-ATPase–stainedsections, dark fibers were classified as type-I and lighterfibers as type-II. Type-IIA fibers appeared white, whereas type-IIBor IID fibers were stained gray (Lind and Kernell, 1991). Followingstaining, sections on slides were sealed with EUKITT and toppedwith a coverslip. For some sections we also used alkaline preincubationat pH 9.4 and generally confirmed the fiber type classificationobtained by acid preincubation (not depicted).

Analysis of fiber types was done under a Leitz Orthomat-W microscopeand pictures were taken with a camera on Elite chrome Kodakfilm. For microscopic analysis, we selected an area comprising50 fibers on a given section and determined the percentage offiber types. Two different areas on each section and two differentserial sections were analyzed for each skeletal muscle and theaverages and error estimates of the four areas were calculated.

MHC Typing by Gel Electrophoresis
MHC isoforms were separated on 8% SDS-PAGE containing 30% glycerolaccording to the method of Talmadge and Roy (1993). A Biometraminigel system was used for electrophoresis and was kept onice during separation. A constant voltage of 70 V was appliedover a 30-h running time. Gels were stained with Coomassie brilliantblue.

Each rabbit muscle type was analyzed a minimum of four timesand the average composition of myosin types was calculated.The percentage of MHC types I, IIB, IID, and IIA was determinedby densitometric analysis using TotalLab software (Phoretix).Although the gels allowed separation of the bands for MHC-IIDand MHC-IIA, we chose to combine these two MHC types in theanalysis, as their contractile properties are more similar toone another than to those of the other MHC isoforms (Andruchovet al., 2004).

Regression Analysis
Linear regression analysis was performed to detect correlationsbetween mean titin size and fiber/MHC composition. Similarly,obscurin size was related to titin size and the type-I fiber/MHC-Iproportions. Estimates for a statistically significant relationshipwere based on standard criteria: correlation coefficient, R $≤$ 0.3, no correlation; 0.3 < R < 0.7, low to modest correlation;R $≥$ 0.7, high correlation. The P value in the regression analysishad to be below 0.05 for the correlation to be judged significant.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Titin Size Varies Greatly in Rabbit Skeletal Muscles
The size of rabbit titin isoforms was determined by 2% SDS-PAGEby comparison with the molecular masses of sequenced human titins(Fig. 2 A). Rabbit soleus was found to be $~$ 100 kD smaller thanhuman soleus, which was also apparent by comparison with humanheart titin expressing 3.0-MD N2B isoform and $~$ 3.3-MD N2BA isoforms(Fig. 2 A). Intact (T1) N2A-titin showed a broad size distributionin the set of 37 rabbit skeletal muscles, ranging from $~$ 3.3 to3.7 MD (Fig. 2, A–F). No single prevailing titin sizewas apparent on a histogram plot of the binned size distribution,although the majority of muscles had titin sizes between either3.40–3.45 MD or 3.60–3.65 MD (Fig. 3 A). 31 musclesexhibited a single titin isoform (Fig. 2; Fig. 3, A and B),including the gastrocnemius, which has obvious red and whiteportions. Another muscle that contains two portions differinggreatly in type-I fiber content, the tibialis anterior (Mabuchiet al., 1982), showed two isoforms separated by $~$ 100 kD (Fig. 3B). Two titin isoforms were detected in 6 of the 37 muscles,also in the psoas, the three hindlimb adductor muscles (longus,brevis, and magnus), and the gluteus medius (Fig. 2 F; Fig. 3B). In all but one (the psoas) muscle expressing two titinbands, the lower-mobility protein appeared much stronger thanthe higher-mobility protein. The T2-titin bands, which are consideredto be degradation forms of the intact titin molecule, were generallyweak on the gels and only rarely made up >15% of the intensityof the T1-titin bands (Fig. 2).

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Figure 2. Detection of titin and nebulin isoforms by 2% SDS-PAGE. (A) Size comparison of rabbit muscle titins with sequenced human heart and soleus titins (Coomassie-stained gel). (B and C) Coomassie-stained gels showing up to two muscle samples charged to the same gel lane to obtain internal titin-size standards. Rabbit psoas expresses two isoforms of 3.4 and 3.3 MD at a ratio of 30:70; rat heart contains 3.0-MD titin. (D and E) Examples for titin appearance on silver-stained gels. (F) Silver-stained full gel also showing the nebulin bands and higher-magnification image of titin bands. (G) Comparison of titin isoform pattern in fiber bundles and in single fibers from rabbit psoas on Coomassie-stained gels. The proportion of 3.3-MD isoform was analyzed relative to the total T1-titin intensity (=combined 3.3 + 3.4-MD isoform intensity); the bottom panel shows mean ± SD for fiber bundles (n = 10). (H) Histogram distribution of the 3.3-MD isoform percentage in 15 different single psoas fibers. T2, titin degradation band.

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Figure 3. Titin and nebulin sizes in adult rabbit skeletal muscles. (A) Histogram of the titin-size distribution. Gray, major titin bands; white, minor titin bands. (B) Titin isoform size (mean ± SEM; n = 3–5) in all 37 muscles studied. Thick bars, major titin; thin bars, minor titin. (C) Nebulin size (mean ± SEM) in comparison to the size of rabbit psoas nebulin estimated at $~$ 700 kD. Muscles are in alphabetical order.

The titin size values of individual muscles are listed in Table I.The shortest major isoform was detected in psoas ( $~$ 3,300 kD),the largest isoform in diaphragm (3,700 kD), similar to humansoleus titin (Fig. 2 A). Also many facial muscles (levator labiisuperior, mentalis, sphincter colli profundus, zygomaticomandibularis;range of mean sizes, 3,608–3,667 kD) predominantly expresslong titins. Otherwise we did not find any obvious clusteringof long or short titins depending on body location.

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TABLE I Fiber Type and MHC Isoform Composition, as well as Titin Size(s), in 37 Rabbit Skeletal Muscles (Continued)

Often muscles are arranged such that contraction of one muscle,the agonist, stretches its counterpart, the antagonist, theextension of which is determined by the passive mechanical properties.We therefore searched for preferential patterns of titin expressionin agonist–antagonist pairs. However, no such patternswere apparent: (a) the biceps brachii (agonist) and the tricepsbrachii (antagonist) express the same titin size (3,465 ±10 versus 3,470 ± 12 kD); (b) agonists with a similarsize of the major titin isoform, the tibialis anterior (3,414± 12 kD) and EDL (3,425 ± 10 kD), oppose antagoniststhat differ in titin size, the soleus (3,596 ± 17 kD)and gastrocnemius (3,435 ± 6 kD); (c) the muscle groupthat includes the hindlimb adductors (a. longus, 3,420 ±6 kD; a. magnus, 3,413 ± 9 kD), the pectineus (3,473± 20 kD), and the gracilis (3,403 ± 9 kD), whichall express a rather short major titin isoform, is antagonistto the glutei, which both contain also a short 3,405-kD titin;and (d) the teres major has titin of 3,530 ± 12 kD, whereasthe muscles of the antagonist group can express a similar sizetitin ([cleido]deltoideus, 3,530 ± 15 kD) or larger titins(pectoralis, mean size, 3,605–3,655 kD; [acromio]trapezius,3,620 ± 12 kD). There is no predictable pattern of titinsize expression in agonist–antagonist muscle systems.

Individual Fibers in a Muscle Show a Similar Titin Isoform Expression Pattern
Since the vast majority of rabbit muscles express a single titinisoform, the same isoform must be present in all individualfibers of a given muscle. Analysis of titin size at the single-fiberlevel was therefore deemed unnecessary in these muscles. However,we wanted to know the isoform composition in a muscle expressingtwo titin sizes, such as the psoas, at the single-fiber level.15 different single psoas fibers were studied by 2% SDS-PAGEand all of them revealed a doublet titin band (Fig. 2, G and H).The proportion of the major 3.3-MD isoform varied somewhatin these fibers (range, 61–79%; Fig. 2 H), but the meanproportion of 70.5 ± 4.4% (mean ± SD) was identicalto that measured in chunks of psoas muscle tissue (Fig. 2 G),70.4 ± 3.8% (n = 10). Thus, individual psoas fibers allcontain two titin isoforms and express these isoforms at a similarratio.

Nebulin Size Shows Low Variability but Is Increased in Predominantly Slow Muscles
An abundant giant protein in skeletal muscle is nebulin, a thinfilament length ruler (Kruger et al., 1991; Labeit et al., 1991;Pfuhl et al., 1994; McElhinny et al., 2005). Analysis of nebulin-sizeexpression in the 37 rabbit muscles revealed much less variabilitythan for titin (Fig. 3 C). Only three muscles (soleus, diaphragm,and adductor brevis) showed a significantly increased (by 50–70kD) nebulin size compared with the psoas nebulin band, whichserved as a reference band estimated at $~$ 700 kD (Fig. 2 F). Thosethree muscles were the only muscles containing >50% type-I MHCor >50% type-I fibers (Table I).

Titin Size Differences Translate into Large Differences in Titin-based Passive Tension
To determine how the variability in titin size expression affectstitin-based PT, we measured the passive SL–tension curvesof single skinned fibers of psoas, EDL, gastrocnemius, longissimusdorsi, and diaphragm muscles (Fig. 4 A). The lowest PT was seenin the slow diaphragm expressing 3,700-kD titin isoform. Amongthe other muscles (which are predominantly fast in rabbit; Table I),distinct differences in PT levels were found: longissimusexhibited the lowest PT, EDL and gastrocnemius intermediatePT, and psoas the highest PT (Fig. 4 A). These differences becomeobvious > $~$ 2.7–2.9 µm SL and reflect the expressionof different-size titins in those muscles (Fig. 4 B). Muscleswith a similar proportion of MHC-I isoforms, such as EDL andlongissimus (Table I), differed markedly in PT. The data shows(a) that the passive stiffness of fibers scales inversely withtitin size and (b) that fast muscle fibers can have either highor low PT levels.

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Figure 4. Passive tension of single muscle fibers correlates inversely with titin size. (A) Passive SL–tension curves of single fibers from five different triton-skinned rabbit muscles. Data are means ± SEM. Curves are second-order polynomial fits. Inset, mechanics protocol. Arrows indicate quasi-steady-state force, which was used to calculate PT in the main figure. (B) Single-fiber (titin-based) mean PT at a given sarcomere length (µm; indicated left to each curve) plotted against titin size of the respective rabbit muscles.

To confirm that differences in fiber PT arise from differencesin myofibrillar PT, passive SL–tension relationships wereobtained from single isolated myofibrils of rabbit psoas andsoleus muscle (Fig. 5). The mean PT was larger in psoas thanin soleus myofibrils by a factor of $~$ 1.2 (not statistically significantin Student's t test), 3.0, and 3.4 (both statistically significantat P < 0.05), at 2.3, 2.7, and 3.1 µm SL, respectively(Fig. 5 B, symbols). These differences are comparable to thosereported for rabbit soleus and psoas at the single-fiber level(Horowits, 1992

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Figure 5. Range of variability in titin-based passive force due to titin-size differences estimated by single-myofibril mechanics and wormlike chain simulations. (A) Scheme of experimental arrangement for mechanical manipulation of single myofibrils. Bar, 5 µm. Inset, typical force trace during stepwise stretch of myofibril. Arrows indicate quasi-steady-state (elastic) force. (B) Differences in titin-based force between myofibrils expressing longer titin (soleus) and those expressing short titins (psoas). Symbols (mean ± SEM) correspond to the right and top axes and indicate the elastic component of PT in single myofibrils. Lines correspond to the left and bottom axes and show wormlike chain predictions of force per titin molecule, for a muscle expressing short titins (30:70 mix of 3.4/3.3 MD isoforms, as in rabbit psoas) in comparison to a muscle expressing long titin (3.7 MD; as in human soleus or rabbit diaphragm). Titin extensions of 0–700 nm mimick the SL range 1.8–3.2 µm. The curves show the maximum and minimum forces that are to be expected from the titin size variability in rabbit muscles.

We wanted to know whether the measured PT difference is in arange that can, in theory, be expected from the observed variationsin titin size. Therefore we modeled the force per titin moleculeusing an approach described earlier (Li et al., 2002

; Makarenkoet al., 2004

), which is based on the wormlike chain propertiesof the titin spring. Different domain compositions in titin'selastic I-band segment were assumed based on sequence information(see MATERIALS AND METHODS), corresponding to short titin isoforms(as in psoas) or long titin (as in soleus). The force differenceswere predicted to be low at small extensions but increase athigher extensions and were qualitatively similar to the measureddifferences at the myofibril level (Fig. 5 B, curves). The modeledforce curves essentially represent the boundaries for the titin-basedforce differences that can be expected from the titin size variability.

Fiber Types and Myosin Heavy Chain Isoforms in Rabbit Skeletal Muscles
In the set of rabbit skeletal muscles we also determined thefiber type and MHC isoform compositions. Myofibrillar ATPasestaining of transverse serial cryosections after preincubationat pH 4.5 (Fig. 6 A) distinguished type-I fibers (black staining)from type-II fibers (lighter staining), which again could besubclassified in type-IIA (white appearance) and type-IID orIIB fibers (greyish staining). The MHC types were determinedby 8% SDS-PAGE, which resolved the isoforms I, IIB, IID, andIIA (Fig. 6 B). The mean percentages of fiber types and MHCisoforms in each muscle are listed in Table I. There was a goodcorrelation (coefficient, R = 0.957) between type-I fiber percentageand type-I MHC percentage (Fig. 6 C). Most rabbit muscles containeda majority of type-II fibers or type-II MHCs and thus were classifiedas predominantly fast (34 muscles). Only three muscles werepredominantly slow, containing >50% type-I fiber/MHC types:soleus, diaphragm, and adductor brevis. The fiber-type or MHC-typeproportions measured by us were usually consistent with thosereported by others for a given rabbit muscle. (An exceptionwas the gracilis muscle, which contained 99.5% type IIA/IIDMHC and not, as reported by Pagliassotti and Donovan (1990),almost exclusively type-IIB MHC.) A list of references on MHC/fibertype composition in rabbit muscles has been added to Table I(right column).

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Figure 6. Fiber and myosin typing. (A) Detection of fiber types I, IIA, and IIB or IID by myosin ATPase staining of 20-µm-thick transverse cryosections preincubated at pH 4.5. Bars, 100 µm. (B) Myosin heavy chain isoforms I, IIB, IID/IIA discriminated by 8% SDS-PAGE. (C) Correlation between type-I fiber composition and MHC-I isoform percentage of 35 rabbit skeletal muscles (for two muscles ATPase staining was not determined). Data are mean ± SEM. The line is a linear regression; results are shown in the lower right corner.

Fast Muscles Express either Short or Long Titin(s), Slow Muscles Only Long Titin
On plots of titin size (major band only) versus percentage offiber type or MHC isoform (Fig. 7), we found a modest, statisticallysignificant correlation with the type-I fibers and type-I MHCs(Fig. 7, A and D). As for type-I fibers (Fig. 7 A), the correlationcoefficient, R, was 0.447 (P = 0.007; n = 35) if all muscleswere included in the analysis and 0.651 (P < 0.0001; n =32) if the three slow muscles were excluded. When titin sizewas plotted against percentage of MHC-I (Fig. 7 D), R was 0.412(P = 0.011; n = 37; all muscles included) and 0.554 (P = 0.0007;n = 34; slow muscles excluded), respectively. In contrast, norelationships were found between titin size and the relativecontent of type-IIA fibers (Fig. 7 B), type-IIB/IID fibers (Fig. 7C), or type-IIA/IID MHC (Fig. 7 E). There were only 10 musclesthat actually contained type-IIB MHC, confirming earlier observationsthat only a minority of rabbit muscles contains type-IIB MHC(Aigner et al., 1993

), and titin size did not correlate withthe percentage of MHC-IIB in these muscles (Fig. 7 F).

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Figure 7. Relationships between titin size and muscle fiber type or MHC isoform percentage determined by myofibrillar ATPase staining (left) and 8% SDS-PAGE (right). Lines are linear regressions (results are shown in each panel). Correlations were made with (A) type-I, (B) type-IIA, (C) type-IIB or IID fibers, and (D) type-I, (E) type-IIA or IID, (F) type-IIB MHC. Dashed lines are regressions after omitting data points for muscles containing >50% type-I fibers or type-I MHC (=slow muscles). The dotted line in F is a regression to the data points of the 10 muscles with MHC-IIB content above zero. Only the major titin band was included in the analysis. Data are means ± SEM.

In these experiments we chose not to study single fibers butmuscle chunks, because the aim was a correlation with the titinisoforms and because we had found that most muscles (31 outof 37) contain only a single titin isoform. In these muscles,a single titin isoform must be present in all individual fibers.Since many of these muscles contain different fiber/MHC types,we also know that the different fiber types in a given musclenevertheless contain the same titin isoform. The one musclestudied for titin isoforms at the single-fiber level, the psoas,contained 100% type-IID fibers/MHC, in agreement with Hamalainenand Pette (1993)

. Since individual psoas fibers express 3.4-MDand 3.3-MD titin isoforms at a similar ratio (Fig. 2, G and H),the MHC/fiber type versus titin isoform relationship isestablished unambiguously. In the remaining five muscles showinga titin doublet on gels, the minor titin band was always veryfaint (e.g., Fig. 2 F, Adductor longus) and it was consideredsufficient to correlate the fiber/MHC type only with the majortitin isoform (Fig. 7).

Taken together the data suggest that fiber type or MHC isoformare weak indicators of titin size. Clearly, fast muscles canexpress either short or long titin isoforms. However, Fig. 7(A and D) also shows that muscles with a type-I fiber content $≥$ 23% or those with a MHC-I content >20%, i.e., the predominantlyslow muscles and the slower ones among the fast muscles, allcontain relatively large titin isoform(s) >3,580 kD.

Titin-based Stiffness Contributes Significantly to Total Passive Muscle Stiffness
Mechanical measurements were performed on fiber bundles dissectedfrom five rabbit muscles differing greatly in fiber-type/MHCcomposition (psoas, soleus, gastrocnemius, EDL, and diaphragm)to determine to what degree titin contributes to total passivemuscle stiffness. The quasi-steady-state PT was first recordedin intact fiber bundles, then in chemically skinned fibers,and finally after proteolytic digestion of titin (Fig. 8). Asa measure of passive stiffness, we calculated the integralsunder the fit curves to the pooled data points (intact fiberstiffness = 100%).

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Figure 8. Contribution of titin to total passive stiffness in different muscle types. (A–E) Passive SL–tension curves of muscle strips before (circles; solid curve) and after (squares; dashed curve) skinning with Triton X-100, and following 45-min-long treatment with 0.2 µg/ml trypsin to disrupt titin (triangles; dotted curve). Data points are means ± SEM. Numbers next to curves indicate the remaining relative stiffness after the respective chemical treatments; passive stiffness was calculated from the integrals below the two-order polynomial fit curves. Insets, relative contributions from titin and extramyofibrillar elements to total passive muscle stiffness. (A) Psoas (n = 10), (B) soleus (n = 11), (C) gastrocnemius (n = 5), (D) EDL (n = 5), (E) diaphragm muscle (n = 5). (F) Relationships of total, titin-based, and extramyofibrillar passive stiffness with the relative type-I fiber/MHC-I content (top; MHC, cyan and pink; fibers, blue and red color) and the relative type-IIB/D fiber content (bottom) of the five muscles. Fit curves are linear regressions. Statistically significant correlations were found only for titin-based stiffness: type-I fibers, R = –0.8801, P = 0.0489; MHC-I, R = –0.8834, P = 0.0469; type-IIB/D fibers, R = 0.9806, P = 0.0032.

After skinning, the passive stiffness was reduced in all muscletypes (dashed curves in Fig. 8, A–E); the highest relativestiffness decrease (by 37%) occurred in soleus, the smallestdecrease (by $~$ 24%) in gastrocnemius. The stiffness decrease upontriton treatment was unlikely to be due to titin modifications,because we found the titin expression patterns on 2% SDS-PAGEgels to be unchanged in skinned compared with intact muscles(examples in Fig. 9 A), Rather, it may be the mechanical uncouplingbetween muscle fibers and the connective tissue and some removalof extracellular material during skinning that account for thedecreased passive stiffness.

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Figure 9. Effect of skinning and low trypsin (0.2 µg/ml) treatment on rabbit muscle proteins. (A) 2% SDS-PAGE for titin in psoas, soleus, and gastrocnemius. T1, intact titin; T2, titin degradation band. (B) 12.5% SDS-PAGE and intensity profiles showing no change of protein bands other than titin after low-trypsin treatment of skinned psoas muscle.

We then tested the effect of selective degradation of titinby low doses of trypsin on PT (Fig. 8, A–E). Minute concentrationsof trypsin disrupt titin but have no measurable effect on othermuscle proteins (Funatsu et al., 1990

; Higuchi, 1992

; Helmeset al., 2003

). The trypsin effect was confirmed here: titinwas readily proteolyzed by 0.2 µg/ml trypsin applied for45 min (Fig. 9 A), but other muscle proteins remained unchangedas judged by 12.5% SDS-PAGE (Fig. 9 B). Following titin proteolysis,the PT of the five muscles dropped by different amounts (reflectingthe differences in titin-based stiffness), but still remainedmuch above zero. In psoas and diaphragm, only 15.8% and 14.0%,respectively, of the total (intact muscle) stiffness remained,much less than in soleus (39.1%) and gastrocnemius (34.8%) (dottedcurves in Fig. 8, A–C and E). A source of this residualstiffness is unlikely to be intermediate filaments, as theycontribute to PT only at SLs >3.4 µm (Salviati et al.,1990

; Wang et al., 1993

). Rather, collagen fibers surroundingthe muscle cells are suggested to be the main cause of the residualstiffness. Indeed, on electron micrographs of psoas and soleusfiber bundles we detected abundant collagen depositions in bothintact and skinned/trypsin-treated muscle strips (Fig. 10).However, the collagen network was much more extensive in soleusthan in psoas, at both experimental stages (Fig. 10). The higherabundance of collagen fibers in soleus may explain the greaterresidual stiffness in this muscle compared with psoas.

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Figure 10. Collagen fibers in rabbit psoas and soleus. Representative electron micrographs of muscle strips before (A and C) and after (B and D) exposure to Triton X-100 (skinning) and 0.2 µg/ml trypsin (titin proteolysis), in soleus (A and B) and psoas (C and D). Note the extensive collagen depositions in intact soleus, which are barely removed during skinning. Psoas contains much less collagen than soleus. Mechanical measurements had been performed on the treated fiber bundles before preparation for EM. Arrowheads, collagen fibers in cross section; arrows, in longitudinal section. Bar, 1 µm (for all panels).

These results show that titin's relative contribution to totalpassive stiffness is much higher in some muscles, like psoas(57%) and diaphragm ( $~$ 56%), than in others, like soleus ( $~$ 24%),EDL (42%), and gastrocnemius ( $~$ 41%). Another significant stiffnesscomponent comes from the extramyofibrillar structures, includingcollagen (Fig. 8, A–E, insets). Hence, both extrasarcomeric(particularly collagen) and myofibrillar (titin) elements contributesubstantially to total passive stiffness; the actual magnitudederived from one or the other source varies in a muscle-specificmanner. As an example, rabbit soleus generated up to twice asmuch total PT as psoas, particularly at longer SLs (Fig. 8, A and B,solid curves), but psoas contains much stiffer titinthan soleus (Fig. 8 F). In conclusion, some muscles have lowtitin-borne stiffness but high total passive stiffness, whereasthe opposite is true for other muscles.

Passive Stiffness and Fiber/MHC Composition
Using the results shown in Fig. 8 (A–E), we also correlatedtotal, titin-based, and extramyofibrillar passive stiffnesswith the fiber/MHC composition (Fig. 8 F). Linear regressionanalysis revealed a statistically significant relationship betweentitin-based stiffness and the type-I fiber/MHC-I percentages(R = –0.88; P < 0.05), as well as the type-IIB/D fiberproportion (R = 0.98; P < 0.005). (As the five muscles studiedcontained no MHC-IIB isoform [Table I], there was also a significantcorrelation between titin-based stiffness and the MHC-IIA/Dpercentage.) In contrast, no correlations with the muscle typewere found for both total and extramyofibrillar passive stiffness(P >> 0.05 in regression analyses). Thus, titin-based stiffnesstends to be higher the faster the muscle, but the magnitudeof both extramyofibrillar and total passive stiffness may beindependent of muscle type.

Obscurin Isoforms Vary in Size in a Muscle Type–dependent Manner
Finally we investigated the size distribution of obscurin, agiant protein (Fig. 11 A) that associates with the sarcomereand is involved in myocyte assembly and signaling (Young etal., 2001). Obscurin is of similar size but at least 10 timesless abundant compared with nebulin (Young et al., 2001). Thereforethe protein was identified on Western blots prepared from 2.0%SDS-PAGE gels using two different anti-obscurin antibodies (Fig. 11,B–D). Both antibodies should detect all large obscurinisoforms, as the site of differential splicing in the obscurinsequence is upstream of the antibody binding sites (Fig. 11A). The size variability was moderate in the 35 rabbit musclesstudied, ranging from $~$ 680 to 750 kD (Fig. 11, B–D andF). Except for the gastrocnemius, which showed two bands ofsimilar intensity on the blots, the muscles exhibited a clearmajor obscurin band. However, sometimes we detected a minorobscurin band of higher electrophoretic mobility compared withthe major band (Fig. 11 C, asterisks). As the minor band wasnot consistently detectable even in a given muscle type (compareFig. 11 B, left, with Fig. 11 C), we consider these signalsto most likely represent degradation forms of obscurin (similarto the T2 bands of titin).

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Figure 11. Size diversity of obscurin. (A) Domain structure of obscurin according to Young et al. (2001)

. Binding sites of the antibodies used in this study are indicated. (B–D) Western blots from 2% SDS-PAGE using (B and C) ${alpha}$ -obscurin DH domain antibodies (asterisks in C, obscurin degradation bands) or (D) ${alpha}$ -obscurin 48/49 antibodies. (E) Western blots from 12.5% polyacrylamide gels using ${alpha}$ -obscurin DH domain antibodies. No signal was detectable in the M_w range 6–250 kD. (F) Estimated molecular weight of obscurin isoforms for 35 different rabbit muscles.

Small obscurin isoforms generated by differential splicing havebeen reported on the cDNA level in human muscles (Russell etal., 2002

). Therefore we tested the set of rabbit skeletal musclesby Western blotting using 12.5% SDS-PAGE gels and ${alpha}$ -DH antibodyThis antibody potentially detects the small isoforms, whichhave been reported to contain the DH domain. However, no obscurinisoforms were detectable in the molecular weight range between6 and 250 kD (Fig. 11 E). Thus, the small isoforms may not beexpressed in detectable amounts in rabbit muscles.

Given that obscurin may play a role for intermyofibrillar extensibility(Borisov et al., 2004), and thus, the mechanical propertiesof muscle, we studied the protein's size distribution in relationto the fiber/MHC proportions and titin isoform size (Fig. 12).The correlation with either the MHC-I isoform or the type-Ifiber proportion was stronger than for titin (correlation coefficient,R $~$ 0.6; Fig. 12 A). As with titin, no significant relationshipswere found with any type-II fiber or MHC-II subtype (unpublisheddata). In contrast, the correlation between obscurin size andtitin size (Fig. 12 B) was very modest (R = 0.45–0.48),indicating that there is only a trend for fibers with compliant(long) titin(s) to express large obscurin isoform.

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Figure 12. Relationships between obscurin size and (A) the proportions of type-I fibers (red squares and lines) or MHC-I isoform (blue circles and lines) and (B) titin size (major band) in 35 rabbit muscles. Linear regressions (results shown in lower right of each panel) are to all data points (solid lines), and after omitting points for the three slow muscles (dashed lines).

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Although titin is the third most abundant protein in striatedmuscle cells (Maruyama et al., 1976

; Wang et al., 1979

), muchless is known about the isoform diversity of this giant polypeptidethan is the case for many of the contractile and regulatoryproteins. This work investigated three previously unresolvedissues: (1) the range of titin isoform sizes expressed in alarge set of adult skeletal muscles; (2) the correlation oftitin isoform diversity with both titin-based PT developmentand titin's contribution to total passive muscle stiffness;and (3) the relationship between titin isoform size, titin-basedstiffness, and fiber-type/MHC isoform composition.

We found that the size diversity of titin is large, rangingfrom 3.3 to 3.7 MD. Muscles expressing large titins have lowPT at the single-fiber and myofibril levels, whereas muscleswith relatively small titins have higher PT. The relationshipbetween titin size and active contractile parameters was verymodest, suggesting a trend for predominantly slow fibers toexpress long titin isoforms. Consistent with this, titin-bornestiffness was lower the higher the proportion of slow fibers/MHC-I.In contrast, no significant correlations were found betweentitin size and the percentage of the various type-II fiber/MHC-IIsubtypes. Thus, besides fiber/MHC composition, other factorsmay determine the differential splicing of titin. We also showedthat in whole muscles, a substantial contribution to total passivestiffness arises not only from titin but also from extramyofibrillarstructures, particularly collagen. However, titin-based stiffnessand total passive-muscle stiffness do not necessarily correlate;for instance, a muscle with low titin-based PT (e.g., soleus)can have greater total PT than a muscle with high titin-basedPT (e.g., psoas). Because of the highly variable extramyofibrillarstiffness among muscles, the total passive stiffness does notdepend on the muscle type. We conclude that the active and passivemechanical properties of skeletal muscles are not strongly correlated.

The idea that muscle type and titin size may be related hademerged, because the largest titin sequenced to date occursin human soleus, a muscle containing almost exclusively slowfibers, whereas a small titin was described in psoas, whichhas predominantly fast fibers (Freiburg et al., 2000). Thiswork now suggests that the psoas is not a typical fast musclein rabbit, as far as titin expression is concerned. Among the34 predominantly fast muscles studied here (most rabbit skeletalmuscles are fast-type), the psoas expresses the very shortesttitin isoform (major, $~$ 3.3 MD; minor, $~$ 3.4 MD). However, in theother fast rabbit muscles, the titin size (major isoform) variedbetween 3.40 and 3.67 MD. Clearly, fast muscles containing predominantlytype-II fibers/MHC-II can express either short or long titin(s).In contrast, slow muscles with a majority of type-I fibers/MHC-Ionly expressed long titin isoform(s). Among the 37 muscles studiedonly three were slow type. Soleus and diaphragm are well-knownslow muscles and also the adductor brevis has previously beenrecognized as a predominantly slow muscle in rabbits (Hitomiet al., 2005). As the number of slow muscles in rabbit is apparentlylimited, it would be useful to study titin-size expression inlarger vertebrate species containing a higher proportion ofslow muscles, which are particularly needed to counterbalancegravity. We predict that skeletal titin sizes may tend to begreater in large species than in small rodents. It will be interestingto see whether our conclusion that predominantly slow musclesdo not express short titin isoforms holds up in other species.Support for this conclusion comes from our observation thatalso the slower ones among the fast muscles express relativelylong titin isoform(s).

We caution that the molecular masses of titin isoforms determinedby 2% SDS-PAGE may differ somewhat from the true values, giventhat there are various factors that can affect the electrophoreticmobility of solubilized proteins, apart from molecular weight.But the mobility of titin bands of some muscles (human soleus,rabbit psoas, and major bands in rat and human heart) couldbe correlated with the isoform size determined by sequencing(Freiburg et al., 2000; Warren et al., 2004), thus providinguseful markers. Importantly, differences in the electrophoreticmobility of titin isoforms could be detected with high confidenceby comparing the positions of the titin band(s) of any musclewith those of the two bands for rabbit psoas titin on the samegel lane (Fig. 2). Considering the resolution limits of thegel detection system, we estimate that the titin sizes measuredby us may be within <50 kD of the true sizes. Thus, the truetitin isoform sizes in the 37 rabbit skeletal muscles couldrange between $~$ 3,250 and 3,750 kD, but not beyond.

Ample evidence suggests that the titin isoform size is a mainfactor determining the PT level of a skeletal muscle fiber (Wanget al., 1991; Horowits, 1992) or myofibril (Linke et al., 1996).This notion was confirmed here by mechanical measurements onskinned single fibers and myofibrils; the PT level correlatedinversely with titin size (Fig. 4 B). Myofibrils from the slowsoleus (Fig. 5 B) and fibers from the predominantly slow diaphragm(Fig. 4 A) generated the lowest PT and it is likely that alsoother slow type muscles expressing large titin(s) have low PT.In a representative selection of five muscles with very differentfiber/MHC compositions, titin-borne stiffness decreased withthe percentage of type-I fibers/MHC-I isoforms (Fig. 8 F). Asfor the predominantly fast muscles, we found that even muscleswith similar type-I fiber/MHC-I proportions (such as EDL andlongissimus dorsi) can differ substantially in the magnitudeof PT development (Fig. 4 A). Hence, this study establishesthat titin-based PT depends somewhat on muscle type but is highlyvariable among the fast skeletal muscles.

What could be the reason slow muscles contain a low stiffnesstitin spring whereas fast muscles exhibit no preferred titinstiffness? A clue may come from the observation that titin elasticityis important for the positional stability of thick filamentsduring isometric contraction (Horowits and Podolsky, 1988).Then, a high stiffness titin spring would provide a higher stabilitythan a low stiffness spring. A high stiffness spring may berequired in very fast muscles generating the highest activetensions very rapidly. Indeed, most muscles with zero or verylow content of type-I fibers/MHCs expressed short titin(s).This is the main reason why the relationship between titin sizeand type-I fiber/MHC percentage was clearly stronger when onlythe predominantly fast muscles were included in the analysisthan when all muscles were included (Fig. 7, A and D). Why themodestly fast muscles (type-1 fiber/MHC-I content between $~$ 5%and 20%) contain either stiff or compliant titin springs, remainsa matter for future investigation. Slow muscles and the slowerfast type muscles expressing long titins may not need a highpositional stability of A bands for optimum performance.

Elegant work by Magid and Law (1985) in an earlier study onfrog had suggested that myofibrils bear most of the restingtension of whole muscle, but our results on rabbit muscles donot support this view. Mechanical measurements of muscle stripsbefore and after skinning, and following titin-specific proteolysisby low dose trypsin, demonstrated that extramyofibrillar elementscontribute to total passive muscle stiffness on average no lessthan the titin filaments (Fig. 8). Along this line, variousstudies have shown that the extracellular matrix, especiallythe collagen content, isoform type, and collagen cross-linkingstatus, is important for a muscle's in situ passive stiffness(Alnaqeeb et al., 1984; Kovanen et al., 1984a,b; Gosselin etal., 1998; Reich et al., 2000). In contrast, the contributionof intermediate filaments to PT (Ansved and Edström, 1991)appears to be very small in the physiological SL range up to $~$ 3.4 µm (Salviati et al., 1990; Wang et al., 1993). Inour hands, the collagen network remained in rabbit psoas andsoleus muscle strips after skinning and trypsin treatment (Fig. 10),and the residual PT following titin degradation was mostlikely due to these abundant collagen fibers.

The relative importance of titin versus extracellular (collagen,connective tissue) structures for the total PT level of wholemuscle varied greatly between different muscle types (Fig. 8).Soleus muscle expressed a compliant titin isoform but containeda more extensive network of collagen fibers than psoas, whichin turn expressed stiffer titin springs. However, the totalpassive stiffness of soleus exceeded that of psoas. Our dataare consistent with a recent study on rabbits (Ducomps et al.,2003) showing that a glycolytic muscle like the psoas containsfar less collagen than a pure oxidative (slow) muscle like thesemimembranosus proprius. Also for rat, it has long been knownthat soleus contains abundant collagen fibers, making this musclestiffer than the psoas (Kovanen et al., 1984a,b). This notwithstanding,the collagen content of other fast muscles may be higher thanthat of psoas. Indeed, the fast rabbit EDL and rectus femorismuscles were shown to contain more collagen than the slow semimembranosusproprius, and the collagen content scaled positively with totalpassive stiffness (Ducomps et al., 2003