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DEVELOPMENT AND TISSUE PLASTICITY

Single-fiber myosin heavy chain polymorphism: how many patterns and what proportions?

Departments of ¹Orthopaedics, ²Physiology and Biophysics, and ³Otolaryngology, College of Medicine, University of California, Irvine, California 92697

Submitted 21 October 2002 ; accepted in final form 5 May 2003

	ABSTRACT

TOP ABSTRACT METHODS RESULTS DISCUSSION DISCLOSURES REFERENCES

 
Previous studies have reported the existence of skeletal muscle fibers that coexpress multiple myosin heavy chain isoforms. These surveys have usually been limited to studying the polymorphic profiles of skeletal muscle fibers from a limited number of muscles (i.e., usually <4). Additionally, few studies have considered the functional implications of polymorphism. Hence, the primary objective of this study was to survey a relatively large number of rat skeletal muscle/muscle regions and muscle fibers (n 5,000) to test the hypothesis that polymorphic fibers represent a larger fraction of the total pool of fibers than do so-called monomorphic fibers, which express only one myosin heavy chain isoform. Additionally, we used Hill's statistical model of the force-velocity relationship to differentiate the functional consequences of single-fiber myosin heavy chain isoform distributions found in these muscles. The results demonstrate that most muscles and regions of rodent skeletal muscles contain large proportions of polymorphic fibers, with the exception of muscles such as the slow soleus muscle and white regions of fast muscles. Several muscles were also found to have polymorphic profiles that are not consistent with the IIIAIIXIIB scheme of muscle plasticity. For instance, it was found that the diaphragm muscle normally contains I/IIX fibers. Functionally, the high degree of polymorphism may 1) represent a strategy for producing a spectrum of contractile properties that far exceeds that simply defined by the presence of four myosin heavy chain isoforms and 2) result in relatively small differences in function as defined by the force-velocity relationship.

isoform; hybrid fiber; polymorphic fiber; force-velocity relationship; fiber type

Some of the key observations made using the single-fiber electrophoretic approach are as follows. First, it has been shown (1, 11-13, 15, 19, 26-30, 33, 35, 40) that some muscles contain so-called hybrid or polymorphic fibers (i.e., fibers that coexpress >1 MHC isoform) under normal conditions. Second, in some rodent muscles, perturbations of thyroid and loading state appear to increase the degree of polymorphism (11, 12). Finally, Pette and colleagues (1, 19, 22, 26-30, 33, 35, 39, 40) have used this approach to develop the concept that transitions in MHC isoform expression are, for the most part, obligated to follow a sequential scheme summarized as II/IIAIIAIIA/IIXIIXIIX/IIBIIB.

Recently, we made several novel observations regarding MHC polymorphism in single fibers of rodent skeletal muscle (11-13, 15). Using the combined intervention of hyperthyroidism and mechanical unloading, we found that large numbers of single fibers (65% of the total population of fibers) in the rodent soleus muscle were capable of displaying a high degree of polymorphism as evidenced by the coexpression of all four adult MHC isoforms (11, 12). The findings from these studies also provided evidence to suggest that rodent skeletal muscle fibers are not obligated to follow the sequential scheme proposed by Pette and colleagues (see Ref. 26). Collectively, these findings suggest that the genetic regulation of MHC isoforms is much more complex than previously thought.

The high degree of polymorphism noted above prompted us to ask a question somewhat analogous to that proposed by Brooke and Kaiser (9). However, rather than addressing the question of "Muscle fiber types: how many and what kind?", the objective of this study was to answer the following question: "Single-fiber MHC polymorphism: how many patterns and what proportions?" In an attempt to address this issue, we examined the MHC isoform compositions of single fibers (5,000 fibers) taken from a spectrum of rodent muscles/muscle regions (13 different muscles/muscle regions) commonly studied. Additionally, we used these data in conjunction with Hill's (20) statistical model of the force-velocity relationship and the single-fiber mechanical data of Bottinelli et al. (8) to address issues related to the mechanical importance of polymorphism within individual fibers.

The findings of this study have important implications with respect to 1) the complexity of MHC isoform gene regulation, 2) the II/IIAIIAIIA/IIXIIXIIX/IIBIIB MHC isoform transition scheme, and 3) the functional significance of MHC isoform polymorphism as illustrated by the force-velocity relationship.

	METHODS

TOP ABSTRACT METHODS RESULTS DISCUSSION DISCLOSURES REFERENCES

 
Collection of muscle samples. All experiments described in this study were approved by our Institutional Animal Care and Use Committee (IACUC) before experimentation. In experiment 1, muscle samples were harvested from five to seven female Sprague-Dawley rats (mean body wt = 292 g; Bantin-Kingman, Fremont, CA). These animals were estimated by the vendor to be >100 days of age at the time of study. The muscles analyzed in this study were the 1) diaphragm (DIA), 2) extensor digitorum longus (EDL), 3) medial gastrocnemius (MG), 4) plantaris (PLAN), 5) rectus femoris (RF), 6) soleus (SOL), 7) tibialis anterior (TA), 8) vastus intermedius (VI), and 9) vastus lateralis (VL). The MG, TA, and VL muscles are known to exhibit regional variations in muscle fiber composition. Hence, the MG was separated into the red (RMG), mixed (MMG), and white (WMG) regions, and both the TA and VL muscles were separated into red (i.e., RTA and RVL) and white (WTA and WVL) regions, respectively. Supplemental analyses were subsequently performed on the DIA muscle with the use of animals from both Bantin-Kingman and Harlan (Indianapolis, IN; for details, see Additional analyses of DIA single-fiber MHC isoform composition). The mean body weight of animals involved in these supplemental analyses was 297 g, and the ages of these animals are estimated to be >100 days.

Isolation of single fibers. The midportion of each muscle/region (5 mm) was used for determining the MHC isoform composition of single fibers. The techniques used in the current study are similar to those published previously (11-13, 15, 42). Typically, 40-50 individual muscle fibers/sample were isolated. Overall, 4,081 fibers were analyzed in the first phase of study (experiment 1). Each muscle segment used for single-fiber MHC isoform analyses was cut into small strips and then stored in a glycerol relaxing solution (50% glycerol, 2 mM EGTA, 1 mM MgCl₂, 4 mM ATP, 10 mM imidazole, 100 mM KCl, pH 7.0, -20°C). Single fibers were isolated by microdissection with the use of microsurgical forceps (Super Fine Dumont tweezers; Biomedical Research Instruments, Rockville, MD) and a dissection microscope (Technival 2, ausJena, Germany) with back lighting. Isolated fibers were then transferred into individual polypropylene microcentrifuge tubes (500 µl) that contained 30 µl of denaturing sample buffer [62.5 mM Tris (pH 6.8), 1.0% (wt/vol) SDS, 0.01% (wt/vol) bromophenol blue, 15.0% (vol/vol) glycerol, and 5.0% (vol/vol) -mercaptoethanol]. Each sample was heated (70°C for 2 min) and placed into a sonicator for 60 min. Approximately 15 µl of each sample were then loaded into a well of the gel, and electrophoresis was performed as described below.

Discontinuous PAGE separation of MHC isoforms. MHC isoforms were separated by use of techniques described previously (10-13). The separating gel consisted of 8% acrylamide, 0.16% bis-acrylamide, 30% glycerol, 0.4% SDS, 0.2 M Tris (pH 8.8), and 0.1 M glycine. This solution was degassed for 15 min, and polymerization was then initiated by adding TEMED (0.05% final concentration) and ammonium persulfate (APS; 0.1% final concentration) to the separating gel solution. The separating gel was poured, layered with ethyl alcohol, and given 30 min to polymerize. The stacking gel solution contained 4% acrylamide, 0.08% bis-acrylamide, 30% glycerol, 70 mM Tris (pH 6.7), 4 mM EDTA, and 0.4% SDS. This solution was also degassed for 15 min before adding TEMED (0.05% final concentration) and APS (0.1% final concentration). It was then layered onto the separating gel. The running buffer contained 0.1 M Tris, 0.15 M glycine, and 0.1% SDS. An SG-200 vertical slab gel system (CBS Scientific, Del Mar, CA) was used for electrophoresis. Gels were run for 24 h and at 270 V. This method separated the fast type IIA, fast type IIX, fast type IIB, and slow type I MHC isoforms (progressive order of migration). MHC protein isoform bands obtained from single fibers were stained with the use of a silver stain kit (Bio-Rad, Richmond, CA). A densitometer (Molecular Dynamics, Sunnyvale, CA) was used to scan and quantify the MHC isoform bands.

Polymorphism index. A simple index was developed to express the proportion of polymorphic fibers relative to the total population of fibers. The polymorphism index was simply defined as

Additional analyses of DIA single-fiber MHC isoform composition. The single-fiber electrophoretic MHC protein analyses yielded several interesting findings with respect to the DIA muscle (see Fig. 1A). First, we observed that there was a high degree of polymorphism and a significant proportion of fibers (10%) that appeared to coexpress the slow type I and fast type IIX MHC isoform (see RESULTS). In this context, we performed supplemental experiments (referred to as experiment 2) that included both Western blots and RT-PCR analyses of single fibers to further confirm or reject the presence of the I/IIX fibers in the DIA. Second, the single-fiber MHC isoform profile of the DIA muscles observed in the current study (see Fig. 1A) were quite different from those previously published by Sieck et al. (32), who also used Sprague-Dawley rats. There are several potential reasons for these discrepancies, such as 1) gender differences (i.e., male vs. female rats), 2) possible regional differences, and 3) different breeders/vendors. These latter two possibilities were addressed by examination of the single-fiber MHC isoform distributions in the dorsal and ventral regions of the costal DIA (referred to as experiment 3) and by contrasting the distributions in animals obtained from Bantin-Kingman and Harlan (defined as experiment 4). Possible regional differences (experiment 3) were examined by separating five hemidiaphragm muscles into two regions defined as 1) dorsal costal DIA and 2) ventral costal DIA. Approximately 220 single fibers were isolated from each region, and the MHC isoform composition was determined as described above. With respect to potential variations due to breeders, it should be noted that Sprague-Dawley rats are an outbred strain and are bred for maximum heterozygocity. Hence, we compared the MHC isoform composition of single fibers from the costal hemidiaphragms of animals obtained from Bantin-Kingman (experiments 1 and 3) with those from Harlan (experiment 4). This involved obtaining five animals from Harlan and isolating fibers from the ventral (n = 198) and dorsal (n = 204) regions of the costal hemidiaphragm muscles. Collectively, experiments 2-4 involved analyses on 1,024 fibers from the DIA muscle.

View larger version (38K): [in this window] [in a new window]   Fig. 1. Single-fiber myosin heavy chain (MHC) isoform distribution of diaphragm (DIA; n = 635), extensor digitorum longus (EDL; n = 268), red medial gastrocnemius (RMG; n = 355), mixed MG (MMG; n = 187), plantaris (PLAN; n = 345), rectus femoris (RF; n = 187), soleus (SOL; n = 278), red tibialis anterior (RTA; n = 262), white TA (WTA; n = 187), vastus intermedius (VI; n = 396), red vastus lateralis (RVL; n = 395), white VL (WVL; n = 190), and white MG (WMG; n = 396) muscles/regions. The relative proportion of any given pool of fibers is shown on the y-axis, and the x-axis represents the various combinations of MHC isoforms for a given pool of fibers. As an example, the slow type I fibers represented 18% of the total pool of fibers analyzed in the DIA muscle. The relative proportion of a given MHC isoform in any pool of hybrid fibers is represented by the relative fill for that MHC isoform. For instance, the fast type IIX MHC isoform represented 55% of the total MHC content of the I/IIX fibers found in the DIA muscle. The percentage shown next to the abbreviation for each muscle represents the degree of polymorphism. In the case of the DIA muscle, 55% of all the fibers were categorized as polymorphic fibers. The initial analyses of the diaphragm muscle consisted of 278 fibers. However, this distribution was markedly different from that published by other investigators (5, 32). Hence, the sampling of the diaphragm muscle was repeated, giving rise to the large no. of fibers examined for the diaphragm. Importantly, both profiles of the diaphragm were similar to one another (P > 0.05). Note that the profiles are shown in order (slowest to fastest) of the predicted maximal shortening velocity [Vmax; see arrow with corresponding Vmax in units of fiber lengths (FL)/s].

Western blot analyses of I/IIX fibers in the DIA muscle. As noted above, a second experiment was performed to provide a higher degree of assurance that the I/IIX fibers observed in the DIA muscle did not also express the fast type IIA MHC isoform. This second experiment employed a more sensitive approach utilizing both Western blot and chemiluminescent techniques. Two hundred single fibers were isolated from the DIA muscle (n = 5), and each fiber was halved. One segment of the fiber was used for electrophoretic determination of MHC composition. Fibers that appeared to be I/IIX fibers (20 fibers) on the basis of electrophoresis were identified, and the remaining one-half of that fiber was used for Western blot analyses.

The Western blot analyses were performed as follows. A volume of 15 µl of sample buffer was loaded into each lane of a gel, and electrophoresis was performed. After electrophoresis, the MHC isoforms were transferred onto nitrocellulose paper, using a constant voltage of 110 V for 2 h. The blotting buffer contained 25 mM Tris, 192 mM glycine, and 20% methanol. The temperature of the blotting chamber was maintained at 4°C by use of an ice bath. On completion of protein transfer, the nitrocellulose paper was placed into a blocking solution that contained 5% nonfat milk in PBS. The nitrocellulose paper was then incubated in a solution containing the primary monoclonal antibody (1:36,000; MY-32, Sigma, St. Louis, MO) that recognized all three fast MHC isoforms. Subsequently, the nitrocellulose paper was washed and incubated with a solution containing the secondary antibody. Detection of MHC isoforms was performed with the use of an enhanced chemiluminescent kit (ECL; Amersham Pharmacia Biotech, Piscataway, NJ).

RT-PCR of analyses of DIA fibers. We also performed RT-PCR to further demonstrate the polymorphic nature of the DIA muscle and the coexpression of I/IIX mRNA isoforms. This was accomplished by isolating sections of a DIA muscle and quickly freezing the section in isopentane cooled by liquid nitrogen. Subsequently, samples were placed in a cryostat, and a transverse section 2-3 mm in length was sectioned and then immediately freeze dried. Single fibers were then isolated and placed into 100 µl of TRI-Reagent (Molecular Research Center, Cincinnati, OH), vortexed briefly (10-15 s), and stored at -80°C.

The TRI-Reagent solution was subsequently thawed at room temperature, and after adding 22 µl of chloroform, each sample was vortexed (10-15 s) and stored for 5 min at room temperature. Samples were then centrifuged at 12,500 g for 20 min (4°C). After centrifugation, total RNA was precipitated from the aqueous phase with isopropanol, and after a washing with ethanol it was dried with the use of a centrivap.

The total amount of extracted RNA was reverse transcribed in a 20-µl reaction volume, using Superscript II and oligo(dT) according to the supplied instructions (GIBCO, Life Technology). At the end of the RT reaction, the tubes were heated at 72°C for 15 min to stop the reaction and were stored frozen at -80°C until use in the PCR reactions.

PCR was used to amplify MHC cDNA isoforms by use of specific primers for each isoform. The 5'-oligonucleotide primer was common to each of the MHC mRNA isoforms and contained the following sequence: 5'-GAAGGCCAAGAAGGCCATC-3'. The 3'-oligonucleotide primers were derived from the 3'-untranslated regions of the four different MHC isoforms where the sequences are known to be highly specific. The sequences for the 3'-oligonucleotide primers are shown in Table 1.

Two microliters of each RT reaction were used for each PCR reaction in a 50-µl final volume. The PCR reaction was carried out in the presence of 3 mM MgCl₂ with the use of standard PCR buffer (GIBCO), 0.2 mM dNTP, 1 µM primers, and 0.75 units of DNA Taq polymerase (GIBCO). Amplifications were carried out in a Stratagene Robocycler with an initial denaturing step of 3 min at 95°C followed by 26 cycles, with each cycle consisting of 1) denaturing for 1 min at 95°C, 2) annealing for 1 min at 5°C, and 3) extension for 1 min at 72°C. The last cycle ended with a final extension step of 3 min at 72°C.

PCR products were then subjected to electrophoresis on an agarose gel. DNA bands were detected by use of Sybr green. Band identity was based on molecular size (by comparison with a DNA 100-bp ladder).

Hill's statistical model of the force-velocity relationship and the importance of MHC isoform distribution at the single-fiber level. Hill (20) developed a statistical model to illustrate the dependence of the whole muscle force-velocity relationship on the force-velocity relationships of the individual muscle fibers that make up a given muscle. In this context, we attempted to model the force-velocity relationships of each muscle/muscle region by employing Hill's model in conjunction with 1) the single-fiber MHC protein isoform data for each muscle and 2) the single-fiber force-velocity data published by Bottinelli et al. (8).

The Hill equation (20) can be written as

(1)

where P_o = maximal isometric tension, P = isotonic tension, V = shortening velocity, and a and b are constants with dimensions of force and velocity, respectively. The Hill equation can be normalized relative to P_o and maximal shortening velocity (V_max) as follows

(2)

With the use of substitutions of P/P_o = P', V/V_max = V', and a/P_o = b/V_max = 1/G, Eq. 2 can be rewritten as follows (41)

(3)

Hill's statistical model employed a total of 82 fibers that were distributed among 10 different populations that varied in maximal shortening velocity (V_{max fiber}). In the present study, the statistical distributions of fibers for any given muscle were based on the actual MHC isoform distributions observed at the single-fiber level. The V' for any given pool of fibers was determined by dividing the shortening velocity of the whole muscle (V_muscle) by the maximal shortening velocity for that given group or pool of fibers (i.e., V_{max fiber}). The contribution of each pool of fibers to overall force production was determined by taking the value obtained from Eq. 3 and multiplying by the number of fibers in each pool. For the purposes of this model, the V_{max fiber} values of pure slow type I, fast type IIA, fast type IIX, and fast type IIB fibers were assumed to be 0.64, 1.40, 1.45, and 1.8 fiber lengths/s (FL/s; Ref. 8), respectively. The V_{max fiber} for any given fiber type was determined by

(4)

where f_x is the fraction of that given MHC isoform in the fiber and V_{max x} is the maximal shortening velocity associated with that given MHC isoform.

By use of the approach described above, 20 data points (ranging from 1 to 100% P_o) were used to fit the Hill equation. The mean difference between the real (modeled) and predicted (value derived from Hill equation) V at the lowest fitted value (i.e., 1% P_o) was 3.1%. The mean ± SE coefficient of determination for fitting the Hill equation was 0.9996 ± 0.0002. The lowest coefficient of determination was 0.995.

Statistical analyses. Analysis of the regional distribution of specific fiber types in the DIA muscle was performed by use of a t-test. Overall differences in fiber type distribution of the DIA were determined using a chi-square test. In all statistical tests, significance was defined as P 0.05.

	RESULTS

TOP ABSTRACT METHODS RESULTS DISCUSSION DISCLOSURES REFERENCES

 
To properly characterize single-fiber MHC polymorphism, three variables must be considered: 1) the different types of polymorphic fibers, 2) the relative proportion of each type of polymorphic fiber, and 3) the ratio of MHC isoform coexpression within a given type of polymorphic fiber. These three variables are integrated into the graphical representations of single-fiber MHC isoform compositions shown in Fig. 1.

Proportions of polymorphic fibers. The proportion of polymorphic fibers was highly variable from one muscle to another (3-78% of the total population of fibers). However, as shown in Fig. 1, the majority of the muscles/regions sampled in this study exhibited a significant degree of single-fiber MHC polymorphism as evidenced by a polymorphism index of >40%. In 8 of these 13 muscles/regions, the proportion of polymorphic fibers was actually greater than the proportion of fibers that expressed only one MHC isoform. Moreover, the IIX/IIB fibers represented the largest pool of any fiber type in the hindlimb musculature.

Patterns of single-fiber MHC polymorphism. The patterns of polymorphism were quite variable among the muscles/regions sampled. For instance, in the WMG, WTA, and WVL muscles there was only one type of polymorphic fiber (IIX/IIB), and it represented only a small proportion of the total population of fibers (3-14%). As expected, the remainder of the fibers in these muscles expressed only the fast type IIB MHC isoform. In contrast, muscles like the PLAN and RTA had 9-10 different types of polymorphic fibers. This is remarkable given that there are only 11 possible combinations of MHC isoform coexpression in muscles that express the four adult MHC isoforms commonly found in the hindlimb musculature. The most common polymorphic fiber type among the fast muscles sampled was the IIX/IIB fiber. These fibers were the dominant fiber type in every muscle that had relatively large pools of the fast type IIX and IIB MHC isoforms. Another consistent trend was that muscles containing significant amounts of I and IIA or I and IIX MHC isoforms exhibited substantial numbers of I/IIA and I/IIX fibers, respectively (e.g., DIA, VI, and RVL).

As noted, 10-12% of the fibers in the DIA muscle coexpressed the slow type I and fast type IIX MHC isoforms (see Fig. 2A). The presence of such polymorphic fibers is not consistent with the sequential scheme of MHC isoform transitions. The DIA muscle was not unique in this respect. Specifically, the PLAN, RF, and RTA muscles also contained fibers that coexpressed specific combinations not consistent with the sequential scheme.

View larger version (41K): [in this window] [in a new window]   Fig. 2. A: electrophoretic separation of MHC isoforms from single fibers taken from the DIA muscle. Lane 1, control sample that contains all 4 adult MHC isoforms. Note that the single fiber shown in lane 10 coexpressed just the slow type I and fast type IIX MHC isoforms. This combination of MHC isoforms is inconsistent with the expression pattern proposed by Pette and colleagues (1, 19, 22, 26, 29, 30, 33-35, 39, 40). Additionally, it has been reported previously that the diaphragm contains a relatively small proportion of polymorphic fibers. Note that the fibers represented in lanes 3-5 and lanes 7-11 exhibited various polymorphic patterns, thereby supporting the contention that polymorphic fibers represent a significant proportion of the fibers in the diaphragm muscle. A is a collage of 2 gels (lanes 1-7, gel 1; lanes 8-12, gel 2). B: an example of a Western blot that was performed to determine whether I/IIX fibers might contain trace amounts of the fast type IIA MHC isoform. As noted in METHODS, blots were probed with the use of a MAb that recognizes all of the fast MHC isoforms. Control sample used in lane 2 contained all 3 MHC isoforms, and each of the fast bands is clearly delineated. Sample shown in lane 1 is from a fiber that was identified as an I/IIX fiber by electrophoresis. Note that the MAb clearly established the presence of the fast type IIX MHC isoform but did not detect even trace amounts of the fast type IIA MHC isoform, supporting the identification of this as an I/IIX fiber. Film was overexpressed to increase the probability of detecting even small amounts of the fast type IIA MHC isoform. C: an example of RT-PCR analyses performed on single-fiber MHC mRNA isoforms. Note that this example demonstrates 2 key findings: 1) polymorphic patterns of MHC mRNA isoform expression and 2) presence of fibers that express both the slow type I and fast type IIX MHC mRNA isoforms.

Western blot and RT-PCR analyses of I/IIX fibers in the DIA. As noted in METHODS, we were surprised to find such a high percentage of I/IIX fibers in the DIA muscle, especially because previous studies (17, 32) had not reported the presence of such fibers. Hence, we performed further analyses (both Western blots and RTPCR) in an attempt to either confirm or reject their presence. As described in METHODS, the MHC isoform compositions of 200 fibers from the DIA muscle were determined by electrophoresis, and 23 I/IIX fibers were identified. Subsequently, these fibers were analyzed with the use of a Western blot approach. An example of the Western blot results is shown in Fig. 2B. Note that the MAb used for the Western blot analyses was specific for all three of the fast MHC isoforms, and, as shown in Fig. 2B, only the fast type IIX MHC isoform was detected in a fiber initially identified as I/IIX fibers via electrophoresis. All 23 I/IIX fibers identified by electrophoresis were subsequently shown (by Western blotting) to express only the fast type IIX and not the fast type IIA MHC isoform.

The presence of polymorphic fibers (and specifically I/IIX fibers) in the DIA muscle was also confirmed using RT-PCR. For instance, Fig. 2C demonstrates the coexpression of the slow type I and fast type IIX MHC mRNA isoforms.

Regional distribution of polymorphic fibers in the DIA muscle. In our initial sampling of the costal DIA muscle (experiments 1 and 2), we did not attempt to determine whether there was a regional difference in single-fiber MHC isoform distribution. We were interested in this issue, because previous studies (17, 32) had not reported the same patterns or degree of polymorphism as observed in the current study. Hence, to determine whether this might be due to differences in regional sampling, we conducted another experiment (i.e., experiment 3) whereby single fibers were isolated from the dorsal and ventral regions of the costal DIA. Three key observations evolved from this third experiment. First, there appeared to be regional differences with respect to the proportion of the slow type I fibers, with the ventral region having a higher proportion (i.e., 30 vs. 10% of the total population; P < 0.001; see Fig. 3). Second, the dorsal region had a higher proportion of fast type IIX fibers (P < 0.001). Finally, both regions contained fibers that coexpressed the slow type I and fast type IIX MHC isoforms (i.e., I/IIX fibers). The dorsal region appeared to have a higher proportion of the I/IIX fibers (P < 0.05).

View larger version (16K): [in this window] [in a new window]   Fig. 3. Histogram showing the regional distribution of fibers in the DIA muscle. The ventral costal region (A) had a higher proportion of slow type I fibers compared with the dorsal costal region (B), whereas the dorsal region had a higher proportion of fast type IIX fibers. Both regions contained 10-20% I/IIX fibers. The combined single-fiber MHC isoform profile of the ventral and dorsal regions is very similar to that shown in Fig. 1A. No. of fibers sampled: ventral, n = 209 fibers; dorsal, n = 213 fibers.

Breeder-dependent variations in DIA MHC isoform composition. Because Sprague-Dawley rats are an outbred strain and are bred for maximum heterozygocity, it is possible that differences in MHC isoform composition could be dependent on the source of animals (i.e., breeder). To examine this possibility with respect to the DIA muscle, we compared the single-fiber MHC isoform profiles of DIA muscles obtained from Bantin-Kingman (Figs. 1 and 3) and Harlan (Fig. 4). In contrasting the data shown in Figs. 3 and 4, it is clear that there can be significant differences (P < 0.001) between the single-fiber MHC isoform profiles of DIA muscles obtained from different vendors. This may partially or completely explain the differences between our initial findings (i.e., those shown in Figs. 1 and 3) and those of Sieck et al. (32). Interestingly, however, the observations made on the animals obtained from Harlan are consistent in the following ways with those made on Bantin-Kingman animals: 1) the DIA muscle of the female Sprague-Dawley rat is highly polymorphic, 2) the DIA muscle of the female Sprague-Dawley rat contains I/IIX fibers, and 3) there are regional differences in the DIA muscle of the female Sprague-Dawley rat.

View larger version (21K): [in this window] [in a new window]   Fig. 4. Gel (top) and histogram [ventral (A) and dorsal (B)] showing the regional distribution of fibers in the DIA muscles of animals obtained from Harlan. The different lanes shown are from the same gel and are not a collage of lanes from different gels. Note that the high degree of polymorphism is similar to that observed in the animals from Bantin-Kingman. However, the patterns of polymorphism are quite different. For instance, note the large proportion of IIX/IIB fibers found in the animals from Harlan, whereas those obtained from Bantin-Kingman had very few IIX/IIB fibers. Also, note that the diaphragm muscles from Harlan also contained I/IIX fibers (see lane 2 in gel), but the proportions of these fibers were smaller than those observed in the DIA muscles of animals from Bantin-Kingman. No. of fibers sampled: ventral, n = 198 fibers; dorsal, n = 204 fibers.

Functional consequences of MHC isoform composition. As noted in METHODS, we used Hill's statistical model of the force-velocity relationship to provide some insights regarding the functional importance of single-fiber MHC polymorphism. The results of these analyses are shown in Fig. 5, A and B. There are several points to be made regarding the results of these analyses. First, as expected, the SOL muscle, with its high percentage of slow fibers, has the slowest predicted V_max. Second, most of the muscles in the rodent hindlimb are fast as evidenced by V_max values that fall within the range of 1.5-1.8 FL/s. Interestingly, even the so-called red regions of the TA, MG, and VL muscles are predicted to have V_max values that are only somewhat slower than those of the fast white regions. Finally, the VI and DIA muscles have V_max values that fall between the extremes as identified by the slow SOL muscle and the fast white regions of muscles like the MG.

View larger version (31K): [in this window] [in a new window]   Fig. 5. A: force-velocity relationships of different muscles/regions predicted by Hill's statistical model (20). B: an enlarged view of the high shortening velocity domain shown in A. The x-axis represents force plotted relative to maximal isometric tension (Po); y-axis represents shortening velocity (FL/s). Most of the force-velocity relationships appear to be similar to one another, and typically there is little difference between so-called "red" and "white" regions. DIA, dashed dark blue line; EDL, solid black line; MMG, long-dashed red line; RMG, short-dashed red line; PLAN, dark cyan line; SOL, long-dashed black line; RTA, short-dashed blue line; WTA, solid blue line; VI, dashed pink line; RVL, dashed green line; WVL, solid green line.

	DISCUSSION

TOP ABSTRACT METHODS RESULTS DISCUSSION DISCLOSURES REFERENCES

 
In revisiting the question initially posed by Brooke and Kaiser (9) but in a contemporary context, single-fiber MHC polymorphism appears to be a common occurrence among a large number of muscles/muscle regions in the rat. In some muscles, there can be >10 different types of muscle fibers, and polymorphic fibers may collectively represent the majority of fibers. This relatively high degree of polymorphism raises important issues about the complexity of MHC gene expression, especially as it relates to individual myonuclei and the concept of an obligatory scheme of MHC isoform transition. The findings of this study also provide an interesting contrast between the diverse patterns of MHC polymorphism and the functional consequences of such polymorphism. Each of these issues is considered in more detail below (see Are muscle fibers obligated to follow the IIIAIIXIIB scheme of plasticity? and What is the functional significance of MHC polymorphism?), but first we address important technical considerations underlying the analyses performed in this study.

Important technical considerations. Although the issue of MHC polymorphism has been examined in a large number of studies, few studies have tried to quantitatively assess the extent of MHC polymorphism across a broad spectrum of muscles. Rather, most studies examined a small set of muscles or the effects of various interventions on single-fiber MHC isoform distribution. Many of these studies employed immunohistochemical approaches. As noted by our laboratory previously (11), immunohistochemical approaches are limited in several key ways. First, they can only indicate the presence or absence of a given MHC isoform. In polymorphic fibers, such approaches cannot provide any information about the relative distribution of a given MHC isoform. Second, there are no antibodies currently available that specifically recognize the fast type IIX MHC isoform. In many instances, the identification of fast type IIX MHC isoform has been based on the absence of staining. This approach precludes the ability to identify fibers expressing the fast type IIX MHC isoform in combination with other MHC isoforms. Given these key considerations, we believe that single-fiber polymorphism can only be properly studied in the rat (as well as other species) with the use of single-fiber electrophoretic approaches similar to those used in the current study.

As noted above, many studies have examined single-fiber MHC isoform polymorphism. Few (if any) of these studies attempted to determine whether such sampling approaches yielded results that were representative of the whole muscle. This same comment also applies to a number of studies that have examined other properties of single fibers, such as V_max, stiffness, and calcium sensitivity. Theoretically, such single-fiber sampling procedures should provide reasonable estimates of the property of interest given that two criteria are satisfied: 1) fibers are chosen at random, and 2) a sufficient number of fibers are sampled. To determine whether such criteria were satisfied using approaches similar to those employed in this study, we correlated in four previous studies (11-13, 15) the MHC isoform composition of whole muscle predicted from single-fiber analyses with that actually determined by whole muscle analyses. Collectively, the results from these four studies showed that the coefficients of determination were typically >0.90, and the slopes of the single fiber vs. whole muscle relationship approximated 1.0 (i.e., 0.93). Hence, for any given muscle/region, we have a high degree of confidence that the single-fiber profiles shown in Figs. 1, 3, and 4 provide reasonable representations of the various types of fibers, their relative proportions, and the relative distributions of MHC isoforms found within a given pool of fibers.

In this context, several studies have examined the single-fiber MHC isoform distribution of the DIA muscle (17, 32). For instance, Sieck et al. (32) examined the single-fiber MHC isoform distribution of 700 fibers from the costal region of the DIA and reported that 85% of all the fibers in the DIA expressed only one MHC isoform. The majority (12% of all fibers sampled) of the remaining fibers coexpressed the fast type IIX and IIB MHC isoforms. More recently, Bortolotto et al. (5) examined the single-fiber MHC isoform composition of 43 fibers from the DIA muscle of the Wistar-Kyoto strain of rats and observed that 65% of the fibers expressed only the fast type IIX MHC isoform. Interestingly, Bortolotto et al. also reported the presence of I/IIX polymorphic fibers (5% of the total pool of 43 fibers studied). In our initial sampling of the DIA muscle, we were struck by two findings: 1) the high degree of polymorphism and 2) the presence of I/IIX fibers.

Given the above, it should be noted that Sprague-Dawley rats were used in both the current study and the study of Sieck et al. (32). Why then is there such a clear discrepancy between the two studies with respect to the single-fiber distributions of MHC isoforms in the DIA muscle? There are two observations that might explain such disparate findings. First, Sieck et al. used adult male Sprague-Dawley rats, whereas we used adult female rats. Second, the breeders/vendors were different. With respect to this latter issue, Sprague-Dawley rats are an outbred strain, and it is entirely possible that there may be variations in the myosin phenotype that are breeder/vendor dependent. To examine this possibility, we performed a fourth experiment on the DIA muscle and obtained animals from Harlan. The distribution that was obtained from this group of animals (i.e., those obtained from Harlan) was quite different (P < 0.001; see Figs. 1, 3, and 4) from that of those purchased from Bantin-Kingman. Specifically, the DIA muscles of animals obtained from Harlan had a large proportion of IIX/IIB fibers, something not seen in the animals obtained from Bantin-Kingman. The disparity of single-fiber polymorphism certainly suggests that there can be significant differences in myosin phenotype that are breeder dependent and that comparisons of published studies may be difficult when contrasting studies that use different breeders.

To our knowledge, no previous studies have attempted to determine the functional significance of different patterns of MHC isoform expression at the single-fiber level and across a broad spectrum of muscles. From a logistical perspective, it would be difficult and impractical to actually make mechanical measurements on thousands of fibers. Hence, we modeled the force-velocity relationships of whole muscles/regions of muscles by employing 1) Hill's statistical model of the force-velocity relationship, 2) the single-fiber data reported by Bottinelli et al. (8), and 3) the actual distributions of MHC isoforms observed at the single-fiber level. Two observations indicate that this represents a reasonable approach. First, the data shown in Fig. 5 predict that the V_max of the PLAN is approximately twofold greater than that of the SOL muscle. This is consistent with actual data published by our laboratory previously (14). Second, in another publication (13), this modeling approach predicted a reduction of 11% in V_max, and this approximated the 14% decline actually observed at the whole muscle level. Hence, as a first approximation, this method seems reasonable for determining the functional importance of myosin isoform distributions at the single-fiber level, especially across a broad spectrum of muscles.

There are several important assumptions that should be acknowledged in the application of this model, however. The first is that V_max is assumed to be dependent primarily on the MHC isoform composition and not on other sarcomeric proteins such as the myosin light chains (MLCs). Although this appears to be true for the slow type I, fast type IIA, and fast type IIX fibers, it should be noted that MLCs might influence the activity of the fast type IIB MHC isoform (7). This issue is minimized by simply using the mean value published by Bottinelli et al. (8). The second important consideration is that the V_{max fiber} was assumed to be determined by the relative percentages of MHC isoforms within a given fiber and the V_max associated with any given MHC isoform. This approach seems reasonable given the findings of Bottinelli et al. (6), who examined the V_max of fibers expressing IIX, IIX/IIB, and IIB MHC isoforms. These investigators observed that the IIX/IIB fibers had V_max values that were intermediate between fast type IIX and IIB fibers and dependent on the relative proportions of the fast type IIX and IIB MHC isoforms. Additionally, these findings and the approach taken in the present study are consistent with the cross-bridge model developed by Huxley (21).

With respect to measures of V_max, it should be noted that V_max is determined by extrapolation of force-velocity data. As a result, it underestimates the maximal unloaded shortening velocity (V_o) determined by so-called slack test techniques. There are several reasons for this (10). The force-velocity relationship represents a composite of all of the individual force-velocity relationships. The importance of this is that at slow shortening velocities, all of the fibers contribute to the shape of the force-velocity relationship, whereas at higher shortening velocities, the slower fibers will be unable to generate any force and thus the shape of the force-velocity relationship in this region will be determined by only the fastest fibers (10). The net result is that at very high shortening velocities (corresponding to loading conditions <1-2% P_o), the force-velocity relationship deviates from a hyperbola such that V_max for the muscle will always be less than that predicted by the presence of the fastest fibers. In muscles where the muscle fibers are homogeneous with respect to contractile properties (e.g., WMG), there will be little difference between measures of V_max and V_o. In contrast, the differences between V_max and V_o will be greater in muscles like the rat SOL, where V_max is determined by the large predominance of slow fibers and V_o is probably determined by the presence of the small population of fast fibers (14). Currently, it is not known whether measures of V_o in whole muscle simply reflect that of the fastest fibers. This is unlikely in heterogeneous muscles, given the presence of mechanical linkages between adjacent muscle fibers and the potential for the slower fibers to retard the shortening velocity of the faster fibers.

Are muscle fibers obligated to follow the IIIAIIXIIB scheme of plasticity? Over the course of the past 10-12 years, Pette and colleagues (1, 19, 22, 26-30, 33-35, 39, 40) published a number of original studies (both whole muscle and single fiber) and review articles and proposed that transitions in MHC isoforms generally follow a scheme that can be summarized as follows: II/IIAIIAIIA/IIXIIXIIX/IIBIIB. The development of this scheme evolved from studying muscle fibers under normal steady-state and transitional conditions. However, as shown in Figs. 1, 2, 3, 4, we observed pools of fibers in the current study that under normal conditions clearly do not inherently adhere to this scheme. For instance, in the DIA muscle, 5-20% of the single fibers coexpressed the slow type I and fast type IIX MHC isoforms (see Figs. 1, 2, 3, 4). There was also another pool of fibers (I/IIX/IIB) in the DIA muscle that also did not appear to adhere to this model. As shown in Fig. 1, the DIA muscle was not unique in this respect given that the EDL, RMG, MMG, PLAN, RF, RTA, VI, and RVL muscles/regions all contained small pools of fibers that were inconsistent with the scheme presented by Pette and coworkers (1, 19, 22, 26-30, 33-35, 39, 40).

Additionally, some perturbations (e.g., hyperthyroidism + mechanical unloading, spinal transection; neonatal development) have been shown to produce transitions in the patterns of MHC isoform expression that are also inconsistent with the obligatory sequential MHC transition scheme. For example, Caiozzo et al. (11) observed pools of I/IIB and I/IIX/IIB polymorphic fibers after 2 wk of a combined intervention of hyperthyroidism plus mechanical unloading. Importantly, time-course analyses demonstrated that the upregulation of the fast type IIA MHC isoform, in response to this intervention, occurred after the upregulation of the fast type IIX and IIB MHC isoforms (11). Findings from Talmadge and colleagues (37, 38) reported the existence of I/IIX fibers after hindlimb suspension and spinal cord transection. With respect to spinal cord transection, Talmadge et al. (38) observed large proportions (15-25%) of I/IIX fibers 90 and 180 days after spinal cord transection. Di Maso et al. (15) examined transitions in single-fiber MHC isoform expression during neonatal development in eu- and hypothyroid rats. In the hypothyroid animals, the PLAN was observed to contain pools of fibers that coexpressed the combination of embryonic (E), neonatal (N), slow type I, and fast type IIB MHC isoforms. Further, E/N/I/IIX fibers were also observed in that study.

Collectively, segmental variations in MHC isoform expression (16, 30) and the presence of polymorphic fibers that do not adhere to the sequential scheme (both under steady-state and transitional conditions) provide important pieces of evidence demonstrating that the genetic regulation of MHC isoform composition is sufficiently complex that it may not be simply described by the II/IIAIIAIIA/IIXIIXIIX/IIBIIB scheme. Does this mean that all fiber transitions do not adhere to this scheme? On the basis of the single-fiber studies to date (including our own), certainly an argument can be made that many fibers appear to follow such a scheme. However, a definitive answer awaits analyses of the genotypic expression of individual myonuclei.

What is the functional significance of MHC polymorphism? The presence of a large proportion of polymorphic fibers in the hindlimb muscles of the rat raises a number of interesting issues related to muscle function and motor unit recruitment. From a functional perspective, the monomorphic pattern of MHC isoform expression might lead to the greatest changes in contractile velocities when 1) recruiting different types of motor units (e.g., slow to fast fatigable) and 2) a fiber undergoes a transition in MHC isoform expression (e.g., slow type I to fast type IIA MHC). In contrast, the polymorphic model potentially might 1) provide smoother transitions in contractile velocities when recruiting additional motor units and 2) minimize the functional significance of MHC isoform transitions. A good example of this latter phenomenon was observed in a study that combined the interventions of hypothyroidism and mechanical overload (13). In that study, it was observed that the combined intervention upregulated the slow type I MHC isoform content from 5 to 20% of the total MHC pool. Single-fiber electrophoretic analyses demonstrated that 65-70% of the fibers expressed the slow type I MHC isoform. Importantly, however, the upregulation of the slow type I MHC isoform was distributed primarily across three different pools of polymorphic fibers, where the fast MHC isoforms represented the majority of the total MHC content. This pattern of distribution (as opposed to a monomorphic model) is hypothesized to minimize the functional consequences of MHC isoform transitions by maintaining the ability of the muscle to produce work and mechanical power (10).

Whether by design or coincidence, polymorphism in rodent skeletal muscle provides a unique design that results not just in four types of cellular motors (i.e., muscle fibers) but has the potential for producing a spectrum of cellular motors that is defined by the types of MHC isoforms and their relative distributions within a given fiber. In this context, one issue that probably will never be resolved is why more than two types of MHC genes evolved. Conceptually, muscles could simply produce a broad spectrum of function by varying the proportions of the slow type I and fast type IIB MHC isoforms within individual fibers. Perhaps comparative approaches, employing cladistical analyses, might be helpful in resolving this issue.

The application of Hill's statistical model, as used in this study, illustrates intrinsic differences in the force-velocity relationship that are independent of other factors such as architectural properties (e.g., cross-sectional area and fiber length). However, as noted by Lieber and Friden (24), factors such as fiber length may be as important as (if not more so than) MHC isoform composition in determining differences in shortening velocities between muscles.

Perspectives

Mosaicism of skeletal muscle: polymorphism raises important issues about the MHC expression patterns of individual myonuclei. With the advent of histochemical methods, it was found that most muscles contained fibers that differed in their staining intensities. This variation in staining patterns was described by some as a "mosaic" pattern. For many years, it was assumed that each individual muscle fiber only expressed a single MHC isoform. The single-fiber MHC polymorphism reported herein and by previous investigations across a broad spectrum of species including humans (2, 10-13, 15, 16, 19, 27, 29-31, 33-35, 39, 40, 42) represents another level of mosaicism (one that exists at the protein level) that further complicates the concept of a fiber type. Within this context, a fundamental issue that remains unresolved is how MHC polymorphism is regulated at the myonuclear level. Are there differences in the expression patterns of individual myonuclei that represent an even more complex level of mosaicism? The presence of hundreds to thousands of nuclei per muscle fiber gives rise to several interesting possibilities. For instance, all of the myonuclei may have identical genotypic expression patterns. If this is the case, then polymorphism must be the consequence of multiple MHC gene expression within a given myonucleus. Alternatively, gene expression might differ from one myonucleus to another. Consistent with this latter suggestion, Peuker and Pette (30) reported a segmental difference in MHC mRNA isoforms along the length of IIX/IIB fibers from the rabbit gastrocnemius muscle. Edman et al. (16) also observed segmental variations in MHC isoform expression and ATPase activity in frog skeletal muscle fibers. Such segmental differences support the hypothesis that there are differences in the expression programs of individual myonuclei. In accordance with this suggestion, Hall and Ralston (18) discussed the concept of the "mosaic of domains." This term implies that individual myonuclei may express protein products that differ from those of other myonuclei within the same muscle fiber. As Hall and Ralston noted, a good example of this is the expression of acetylcholine receptors by the myonuclei associated with the motor end-plate. If it is indeed found that the genotypic expression of myonuclei differs along the length of a fiber, then this will significantly complicate our attempt to understand the roles of neural, hormonal, and mechanical factors in regulating both the genotype and phenotype of skeletal muscle.

	DISCLOSURES

TOP ABSTRACT METHODS RESULTS DISCUSSION DISCLOSURES REFERENCES

 
This work was supported in part by National Institute of Arthritis and Musculoskeletal and Skin Diseases Grants AR-46856 (to V. J. Caiozzo) and AR-30346 (to K. M. Baldwin).

	FOOTNOTES

 

Address for reprint requests and other correspondence: V. J. Caiozzo, Medical Sciences I B-152, Dept. of Orthopaedics, College of Medicine, Univ. of California, Irvine, CA 92697 (E-mail: vjcaiozz{at}uci.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

	REFERENCES

TOP ABSTRACT METHODS RESULTS DISCUSSION DISCLOSURES REFERENCES

 

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