Journal of Histochemistry and Cytochemistry, Vol. 50, 1543-1554, November 2002, Copyright © 2002, The Histochemical Society, Inc.


ARTICLE

Expression of Myosin Heavy Chain Isoforms Along Intrafusal Fibers of Rat Soleus Muscle Spindles After 14 Days of Hindlimb Unloading

L. De-Donckera, F. Picqueta, G. Butler Browneb, and M. Falempina
a Laboratoire de Plasticité Neuromusculaire, Université des Sciences et Technologies de Lille 1, Villeneuve d'Ascq, France
b UMR CNRS 7000, Faculté de Médecine Paris 6, Paris, France

Correspondence to: L. De-Doncker, Laboratoire de Plasticité Neuromusculaire, EA 1032, IFR 118, Bât. SN4, Université des Sciences et Technologies de Lille 1, 59655 Villeneuve d'Ascq Cedex, France. E-mail: neuromus@pop.univ-lille1.fr


  Summary
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Materials and Methods
Results
Discussion
Literature Cited

Morphological, contractile, histochemical, and electrophoretical characteristics of slow postural muscles are altered after hindlimb unloading (HU). However, very few data on intrafusal fibers (IFs) are available. Our aim was to determine the effects of 14 days of hindlimb unloading on the morphological and immunohistochemical characteristics of IF in rat soleus muscle. Thirty-three control and 32 unloaded spindles were analyzed. The number and distribution of muscle spindles did not appear to be affected after unloading. There was no significant difference in number, cross-sectional area, and histochemical properties of IF between the two groups. However, after unloading, a significant decrease in slow type 1 MHC isoform and a slight increase in slow-tonic MHC expression were observed in the B and C regions of the bag1 fibers. The {alpha}-cardiac MHC expression was significantly decreased along the entire length of the bag2 fibers and in the B and C regions of the bag1 fibers. In 12 muscle spindles, the chain fibers expressed the slow type 1 and {alpha}-cardiac MHC isoforms over a short distance of the A region, although these isoforms are not normally expressed. The most striking finding of the study was the relative resistance of muscle spindles to perturbation induced by HU. (J Histochem Cytochem 50:1543–1553, 2002)

Key Words: rat, soleus, hindlimb unloading, intrafusal fibers, histochemistry, myosin heavy chain isoforms


  Introduction
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THE MUSCLE SPINDLES are stretch receptors that inform the central nervous system about changes in rate and muscle length (Matthews 1981 ; Hulliger 1984 ; Hunt 1990 ). In the rat hindlimbs, the muscle spindles are 3–5 mm long and lie parallel to the extrafusal muscular fibers. They consist of small intrafusal fibers (IFs) surrounded by a capsule (Kucera et al. 1978 ). Each IF has two contractile ends, an equatorial region devoid of myofibrils but rich in myonuclei (Banks et al. 1982 ), and receives both sensory and motor innervation (Hunt 1990 ; Banks 1994 ). Three arbitrary regions (A, B, C) have been defined in muscle spindles: (a) the A region is composed of the equatorial and juxtaequatorial regions containing the periaxial space; (b) the B region extends from the end of the periaxial space to the end of the capsule; and (c) the C region corresponds to the extracapsular portion. Three different IF types have been identified in mammalian muscle spindles: the nuclear bag1 fibers, the nuclear bag2 fibers, and the nuclear chain fibers (Banks et al. 1982 ). This distinction is based on morphological criteria, i.e., myonuclei accumulation, diameter, and length (Banks et al. 1982 ; Hunt 1990 ), myofibrillar ATPase activity (Ovalle and Smith 1972 ; Soukup 1976 ; Kucera et al. 1978 ), and immunohistochemical characteristics (Soukup et al. 1995 ; Wang et al. 1997 ; Walro and Kucera 1999 ). Each IF type expresses a specific combination of myosin heavy chain (MHC) isoforms with regional variations along their length (Pedrosa-Domellof et al. 1991 ; Kucera et al. 1992 ; Soukup et al. 1995 ). Bag2 fibers express at least six MHC isoforms (embryonic, neonatal, slow-twitch, {alpha}-cardiac, slow-tonic, and fast-twitch). Nuclear bag1 fibers express four MHC isoforms (embryonic, slow-twitch, slow-tonic, and {alpha}-cardiac) and nuclear chain fibers express two MHC isoforms (neonatal and fast-twitch). The importance of the primary endings to normal spindle development has been repeatedly demonstrated by selectively eliminating the sensory or motor supply in fetal or neonatal rats (for review see Soukup et al. 1995 ; Soukup and Novotova 1996 ; Maier 1997 ; Wang et al. 1997 ). These studies showed that sensory innervation is required for the development and maintenance of muscle spindle integrity and for the expression of spindle-specific MHC isoforms. Motor innervation contributes to the diversity in the distribution of the different MHC isoforms along the length of the nuclear bag fibers. Therefore, the regulation of MHC expression within the different IF types is very complex and reflects a complex interaction of inductive and suppressive effects of motor and sensory innervation as well as the intrinsic properties of specific myoblast lineages (Kucera and Walro 1990 ; Pedrosa-Domellof et al. 1991 ; Soukup et al. 1995 ; Wang et al. 1997 ; Walro and Kucera 1999 ). After a period of hindlimb unloading (HU) slow postural muscles, such as the soleus (ankle extensor), become atrophied. This atrophy is characterized by a decrease in muscle weight, in cross-sectional area of muscle fibers, and in strength. It is also accompanied by modifications in contraction kinetics and in histochemical and electrophoretical properties (for review see Edgerton and Roy 1996 ; Ohira 2000 ). Very few data exist concerning the effects of HU on the IF properties (Soukup et al. 1990b ). During unloading, the soleus muscle is often in a shortened position (Riley et al. 1990 ). Consequently, because the natural mechanical stimulus of the muscle spindles is the muscular stretch (Hulliger 1984 ), we hypothesized that the muscle spindles were probably little or not at all stimulated. The afferent activity of Ia and II fibers originating from these stretch receptors was probably reduced. This has never been demonstrated but was suggested by Anderson et al. 1999 to explain the inhibited tendinous reflex after HU. Ohira et al. 1992 have also suggested that the afferent input may be reduced if the muscle is shortened during HU. Moreover, during HU the reactivation of Ia fibers by tendinous vibrations is an effective countermeasure to prevent muscle atrophy developed during HU (Falempin and Fodili In-Albon 1999 ). These authors suggested that, in this condition, the proprioceptive information was decreased. They attributed the atrophy prevention to the reactivation of muscle spindle afferents which, in turn, augmented the excitation of the {alpha}-motor neurons. It is known that the Ia afferents not only innervate IFs but also project onto {alpha}-skeletomotor and ß-skeletofusimotor neurons, and onto interneurons which, in turn, project on to {gamma}-fusimotor neurons in the spinal cord (Bernstein and Goldberg 1995 ). We suggest that this reduction in afferent neural activity could modify MHC isoform expression by altering the activity of ß- and {gamma}-fusimotor neurons that innervate the contractile portion of the IF. Therefore, the aim of this study was to identify the MHC isoform distribution along IFs and to determine if this distribution was modified by unloading. A panel of eight different antibodies, in combination with ATPase labeling, was used.


  Materials and Methods
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Animals
Eight male Wistar rats (Iffa Credo; l'Arbresle, France) weighing 280–300 g were randomly divided into two groups of four rats: control rats and HU rats. Initially, all of the rats were housed in the same room at a constant temperature (25C) with a 12-hr:12-hr light–dark cycle and were fed and allowed water ad libitum. Animals in the HU group were unloaded for 14 days using Morey's model (Morey et al. 1979 ). Briefly, an orthopedic tape-adhesive plaster, covering less than half of the cleaned and dried tail, was connected to the top of the cage, where a swivel allowed 360° rotation. The rats were elevated in a head-down position (30°) so that the hindlimbs could not touch the cage floor or walls, while they were able to ambulate freely on their forelimbs. The experiments and the animal housing conditions received authorization from both the Agricultural and Forest in Ministry and the National Education Ministry (Veterinary Service of Health and Animal Protection, authorization 59-00980).

Tissue Processing
Rats were anesthetized with sodium pentobarbital (35 mg·kg-1). In both groups, the right and left soleus muscles were excised, stretched to their resting length, and immediately frozen in an isopentane solution precooled to its freezing point by liquid nitrogen. The muscles were stored at -80C until histochemical and immunohistochemical analyses were performed. The soleus muscles of the control and HU groups were cut into serial frozen transverse sections (10 µm thick) using a cryostat microtome (Leica CM 1800; Heidelberg, Germany) set at -20C. Along the muscle, every 280 µm, 11 sections perpendicular to the muscle longitudinal axis were performed. The first section was used as a negative control in the immunohistochemical analysis. The next two sections were processed for myofibrillar adenosine 5'-triphosphatase (ATPase) with acid (pH 4.3) and alkaline (pH 10.4) preincubations according to the method of Guth and Samaha 1969 . The remaining sections were labeled with antibodies against the different MHC isoforms.

Antibodies and Labeling
Eight monoclonal antibodies (MAbs) were used in this study (Table 1). Binding of the primary antibodies was localized by an immunoperoxidase reaction utilizing the Novostain Universal Quick Kit (Tebu-Novocastra; Le Perray–en–Yvelines, France). Serial cross-sections were incubated in prediluted blocking serum (normal horse serum) for about 10 min. The excess serum was blotted and sections were incubated with primary antibodies diluted in PBS for 2 hr. Serial cross-sections were washed for 5 min in PBS. Then the sections were incubated for 30 min in prediluted biotinylated universal secondary antibody. At the end of 30 min, sections were washed with PBS for 5 min and incubated in ready-to-use streptavidin–peroxidase complex reagent for 30 min. To label the serial cross-sections, the peroxidase substrate solution (diaminobenzidine, DAB) was added after the sections had been washed for 5 min with PBS. Positive fibers were characterized by a brown color and negative fibers remained unlabeled. Finally, after dehydration with alcohol and toluene, the slides were mounted in Eukitt resin. The cross-sectional area (CSA) and the densitometry of the antibody labeling along the different IF types were measured using an image analyzer (SAMBA 2005; Villeneuve d'Ascq, France). To avoid a disparity in the labeling, for each antibody, all the sections were identically processed with the same diluted solution. The slides were also incubated simultaneously for 5 min in a common DAB solution. The zero of the densitometer for each preparation was adjusted on the negative fibers in the section; the slight variations of labeling between each slide were therefore discarded. The immunohistochemically labeled slides were analyzed with the image analyzer. This system was made up of a digital camera fixed to a standard optical light microscope. The camera was coupled to a computer with video monitor and image acquisition and storage modules. The measures were quantified to 256 gray levels (level 1 corresponding to black color and to 0% of light transmission, and level 256 to white color and 100% of light transmission), which were then converted automatically into optical density, taking into account the studied area. The densitometric values were expressed in percentage (OD = log10 (1/light transmission). According to Nibbering et al. 1986 , the formation of the reaction product after DAB/H2O2 staining for immunoperoxidase-labeled cells indicated a linear relationship between the amount of enzyme-coupled antibodies bound to cells and the amount of enzyme reaction product. With the densitometric approach, the more elevated OD is, the more important the protein amount is. The densitometric analysis has already been used as a semiquantitative approach in rat muscular fibers (Sant'Ana Pereira et al. 1995 ). In muscle spindle immunohistochemistry, the immunoreactivity is usually scored as absent (-), weak to moderate (+), and strong (++). This way of expressing the results does not allow detection of fine modifications in the expression level of myosin isoforms under a given experimental condition. Consequently, we intentionally chose to express our results as values obtained using densitometric measurements. However, as for the ATPase activity (Kucera 1981 ), in the most nucleated equatorial region of the IFs, the MAb labeling was present only around the IFs because the central part of the IFs was not labeled. In this case, the densitometric measurement was made only on the colored part of IFs without taking into account the IF center.


 
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Table 1. Antibodies used in this study and their specificity in the rat

Identification of IF Types
The muscle spindles were identified in both control and unloaded soleus muscles groups as encapsulations of small-diameter fibers. As stated previously, each muscle spindle can be divided into two encapsular regions (A and B regions) and one extracapsular portion (C region). Intrafusal fibers were classified as nuclear bag1, nuclear bag2, and nuclear chain fibers according to their morphology and their histochemical reaction after preincubation in acid and alkaline solutions (Soukup 1976 ; Kucera et al. 1978 ) and their MHC isoform contents, which were not uniform along their length (Pedrosa-Domellof et al. 1991 ; Kucera et al. 1992 ; Soukup et al. 1995 ). Rat muscle spindles usually contain four IFs: one bag1, one bag2, and two chain fibers (Kucera and Walro 1988b ). The diameter of these IFs decreases in the following order: nuclear bag2 > bag1 > chain fibers (Soukup 1976 ). Nuclear bag1 fibers exhibit low acid and alkaline ATPase activity along their intracapsular region but have high acid ATPase activity at their poles. Nuclear bag2 fibers have an acid-stable ATPase activity along their length and an intracapsular alkaline-stable ATPase activity that is lost beyond the capsular sleeve. Nuclear chain fibers have low acid and high alkaline ATPase activities along their entire length (Kucera et al. 1978 ; Khan and Soukup 1988 ). The nuclear bag1 and bag2 fibers were labeled with both ALD58 MAb, specific for the slow-tonic MHC isoform, and F88 MAb, specific for the {alpha}-cardiac MHC isoform. Nuclear chain fibers did not express these two MHC isoforms, except in a very short equatorial length where the slow-tonic isoform was detected (Pedrosa et al. 1989 ; Pedrosa-Domellof et al. 1991 ).

Statistical Analysis
All results were expressed as means ± SD. A Student's t-test was used to establish the intergroup comparisons and statistical significance was accepted at p<0.05.


  Results
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Materials and Methods
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A total of 33 control muscle spindles (33 bag2, 33 bag1, 69 chain fibers) and 32 HU muscle spindles (32 bag2, 32 bag1, 67 chain fibers) were analyzed throughout their entire length. Most of the muscle spindles in the control and unloaded groups contained one bag1, one bag2, and two chain fibers. However, in three control and four HU muscle spindles, there were three nuclear chain fibers. There was no significant different between the number of muscle spindles in control (14.3 ± 1.5) and HU groups (13.5 ± 1.3).

Cross-sectional Areas
The CSAs of IFs are shown in Fig 1. For both control and HU groups, the CSAs of bag2 fibers were significantly larger than those of bag1 and chain fibers, and those of bag1 fibers were higher than those of chain fibers, independent of the muscle spindle region. For all IF types in both animal groups, the CSAs in the B region were significantly higher than those in the A and C regions (Fig 1). After 14 days of unloading, no significant difference in the CSAs of all IF types between control and HU groups was observed.



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Figure 1. Histogram of cross-sectional areas (CSAs) of the three intrafusal fiber types in A, B, and C regions of the control (CONT) and hindlimb unloaded (HU) groups. Empty bar, A region; hatched bar, B region; full bar, C region. *Significant differences of CSA with the A region, {dagger}with the B region, {ddagger}with bag1 and chain fibers, and §with chain fibers.

Histochemical Analysis
In Fig 2 (control group), the Figures 2.1–2.3 and Figures 2.4–2.6 respectively illustrative the acid (pH 4.3) and alkaline (pH 10.4) ATPase activity of IFs in the A, B, and C regions of a muscle spindle. In the muscle spindles of the control group, the nuclear bag1 fibers had low to moderate acid ATPase activity in A and B regions, but the activity was high at the end of the B region and towards the poles. After alkaline preincubation, they showed a low ATPase activity along their entire length. Nuclear bag2 fibers exhibited high acid ATPase activity and high to moderate alkali ATPase labeling along their length. However, in the more extracapsular region, the nuclear bag2 fibers lost their alkaline ATPase activity. In general, after acid preincubation, nuclear chain fibers exhibited low ATPase activity and high to moderate alkali ATPase labeling along their entire length. However, the nuclear chain fibers in the muscle spindles of Fig 2 exhibited moderate acid ATPase activity in the A region. In the most equatorial region, all IF types had a rim or no ATPase activity. Histochemical labeling did not show any difference between control and HU groups. However, it is obvious that a slight increase or decrease in one of the MHC isoforms would not necessarily be made visible by changes in ATPase activity. Moreover, ATPase labeling does not allow demonstration of the co-expression of several MHC isoforms within a fiber.



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Figure 2. Transverse sections (10 µm thick) through the encapsulated A and B regions and extracapsular C region of a rat soleus spindle in the control group. The spindle contains one bag1 (thin arrow), one bag2 (thick arrow), and two chain fibers (star). Sections were processed for ATPase labeling with acid (pH 4.3, 2.12.3) and alkaline (pH 10.4, 2.4–2.6) preincubations and were labeled with NCL MHCs (MHCs) (2.7–2.9), SC71 (2.10–2.12), MY32 (2.13–2.15), ALD58 (2.16–2.18), F88 (2.19–2.21), BFF3 (2.22–2.24), 2B6 (2.25–2.27) antibodies. NCL MHCd is not shown. Bar = 40 µm.

Immunohistochemistry
The regional variation of labeling with all antibodies is illustrated in Fig 2 for the control group. Fig 3 illustrates only the antibody labelings that were changed by the HU condition. The results have been refined by densitometric measurements (Table 2, control group and Table 3, HU group).



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Figure 3. Transverse sections (10 µm thick) through the encapsulated A and B regions and extracapsular C region of a rat soleus spindle in the control (CONT) and in the hindlimb unloaded (HU) groups. The spindle of the HU group contains one bag1 (thin arrow), one bag2 (thick arrow), and two chain fibers (star). Sections were labeled with NCL MHCs named MHCs in the figure (CONT: 3.1–3.3; HU: 3.4–3.6), ALD58 (CONT: 3.7–3.9; HU: 3.10–3.12), F88 (CONT: 3.13–3.15; HU: 3.16–3.18). Bar = 40 µm.


 
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Table 2. Densitometric analysis of the immunohistochemical labeling in intrafusal fibers of the control group (CONT)


 
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Table 3. Densitometric analysis of the immunohistochemical labeling in intrafusal fibers of the HU groupa

Control Group Nuclear Bag1 Fibers. NCL MHCs (Figures 2.7–2.9) labeled only the fibers towards the poles at the end of the B region and in the C region. SC71 (Figures 2.10–2.12) and ALD 58 MAbs (Figures 2.16–2.18) strongly labeled the fibers in A and B regions and the labeling slightly decreased towards the C region (Table 2). The nuclear bag1 fibers were labeled with F88 MAb (Figures 2.19–2.21) over a short distance in the B and C regions. The binding with F88 MAb was strong to moderate in the B region and low to moderate towards the C region. The labeling with 2B6 MAb (Figures. 2.25–2.27), specific for embryonic MHC, was low in the A region. No binding was seen in the B and C regions of bag1 fibers. Whatever the IF MY32 (Figures 2.13–2.15), BFF3 (Figures 2.22–2.24), NCL MHCd MAbs did not label the nuclear bag1 fibers (not shown).

Nuclear Bag2 Fibers. NCL MHCs MAb reacted strongly with the nuclear bag2 fibers along their entire length. The nuclear bag2 fibers bound MY32 and F88 MAbs along their entire length but the binding intensity decreased from the A to the C region (Table 2). With SC71, ALD58, and 2B6 MAbs, the nuclear bag2 fibers were labeled only in the A region. BF-F3 MAb reacted in both A and B regions of bag2 fibers; the labeling was lower in the B region. NCL MHCd MAb did not label bag2 fibers.

Nuclear Chain Fibers. Nuclear chain fibers reacted with MY32 MAb in the A and B regions. BF-F3 labeled the nuclear chain fibers in the A and B regions, with higher labeling in the B region (Table 2). SC71 MAb bound only the A region of nuclear chain fibers. Our results showed no labeling with NCL MHCs, ALD58, F88, 2B6, and NCL MHCd MAbs in any region of the nuclear chain fibers.

HU Group. There was no difference with the control group in the regional variation and in the labeling intensity with SC71, MY32, BF-F3, 2B6, and NCL MHCd MAbs along the nuclear bag1 and bag2 fibers.

Nuclear Bag1 Fibers. NCL MHCs, ALD58, and F88 MAbs (Figures 3.4–3.6, 3.10–3.12, and 3.16–3.18, respectively) showed modified labeling compared to the control group (Figures 3.1–3.3, 3.7–3.9, and 3.13–3.15, respectively). Densitometric analysis, presented in Table 3, showed that type 1 MHC expression in nuclear bag1 fibers decreased significantly in both B and C regions after unloading. Moreover, the labeling intensity with ALD58 MAb, specific for slow-tonic MHC isoform, was significantly increased in the B and C regions of bag1 fibers. With F88 MAb, our results showed that the expression of {alpha}-cardiac MHC isoforms in bag1 fibers was significantly decreased in the B and C regions after unloading.

Nuclear Bag2 Fibers. After unloading, the labeling intensity with F88 MAb significantly decreased in all regions of the nuclear bag2 fibers compared with the control group. There was no difference with the control group in the regional variation and the labeling intensity with ALD58 MAb along bag2 fibers. However, although the difference was not significant, type 1 MHC isoform expression presented a slight decrease in the B and C regions of the nuclear bag2 fibers after a period of unloading.

Nuclear Chain Fibers. There was no difference with the control group in the regional variation and labeling intensity along the nuclear chain fibers with all antibodies, except for NCL MHCs and F88 MAbs. Indeed, among the 32 muscle spindles that were studied, only 12 presented nuclear chain fibers that bound the NCL MHCs and F88 MAbs (Figures 3.4 and 3.16, respectively) over a short distance of the A region (special chain in Table 3), whereas chain fibers in the control group never bound these antibodies.


  Discussion
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Morphological Characteristics
The number and distribution of muscle spindles in the rat soleus were not significantly different in the two experimental groups. These data are in agreement with those described previously by Soukup et al. 1990b . Our results showed that, in the control group, the bag2 fiber CSAs were greater than the bag1 fiber CSAs, which were also larger than the chain fiber CSAs. These data are in agreement with the results of other authors (Botterman and Edgerton 1975 ; Soukup 1976 ; Soukup et al. 1993 ). The same results were obtained after unloading. It therefore appears that IFs are more resistant to myogenic atrophy than the extrafusal fibers, as suggested earlier by other authors (Yellin and Eldred 1970 ; Maier et al. 1972 ).

Histochemical Analysis
In the control group, our data are similar to those obtained by other authors for the same species (Botterman and Edgerton 1975 ; Soukup 1976 ; Kucera et al. 1978 ; Kucera and Walro 1987 ). In some control muscle spindles, the nuclear chain fibers have moderate acid-stable ATPase activity. Soukup 1976 has also reported some differences in ATPase labeling. In the rat soleus muscle spindles, the nuclear chain fiber ATPase activity was low, medium, or high after acid preincubation.

After a 14-day period of HU, no significant difference was observed in the ATPase labeling in the IFs compared to the control group. The regional variation in ATPase labeling along the IFs is due to the non-uniform expression of MHC isoforms in the different regions of those fibers (Kucera and Walro 1989 ; Pedrosa et al. 1989 ; Kucera et al. 1992 ; Soukup et al. 1995 ).

MHC Isoform Expression of IFs in Control and HU Groups
Control Group. Our results are in agreement with other studies concerning the regional variation of labeling with NCL MHCs (Pedrosa-Domellof et al. 1991 ; Kucera et al. 1992 ; Soukup et al. 1995 ; Walro et al. 1997 ; Wang et al. 1997 ), MY32 (Pedrosa et al. 1989 ; Kucera et al. 1992 ), ALD58 (Kucera and Walro 1989 ; Kucera et al. 1992 ; Soukup et al. 1995 ; Soukup and Thornell 1997 ), and F88 (Pedrosa et al. 1990 ; McWhorter et al. 1995 ).

However, some differences were observed with SC71, BF-F3, 2B6, and NCL MHCd antibodies. Our results showed that SC71 bound to the encapsulated polar region of bag1 fibers and labeling was also seen in the juxtaequatorial region in bag1 and chain fibers. Our results were in accordance with those described by Kucera et al. 1992 . However, in the A region of our nuclear bag2 fibers, only a low level of labeling was seen with the SC71 MAb. This difference in the labeling with SC71 between our results and those of Kucera et al. 1992 could be due to the antibody dilution. Indeed, Kucera et al. 1992 used the SC71 with a 1:600 dilution, whereas we used a 1:20 dilution.

A difference in labeling was observed in the nuclear bag1 fibers with MY32 and SC71 MAbs. Nuclear bag1 fibers were labeled by SC71 along their entire length, whereas MY32 MAb never labeled these fibers. This was surprising because the MY32 MAb is supposed to react with all fast-twitch MHC isoforms (Schiaffino et al. 1989 ). SC71 MAb is specific for the MHC 2A isoform and never crossreacts with other MHC isoforms. Therefore, the fast-twitch MHC isoform, recognized in nuclear bag1 fibers by the SC71 but not by MY32, could be a specific muscle spindle MHC isoform whose epitope resembles that recognized by SC71 on the MHC 2A isoform. The possible existence of other specific muscle spindle MHC isoforms not expressed in extrafusal fibers has already been suggested by other authors (Kucera et al. 1992 ; Pedrosa-Domellof et al. 1993 ). Kucera et al. 1992 suggested that the labeling intensity and the regional variation with MY32 were higher and broader than those with SC71 (MHC 2A) and BF-F3 (MHC 2B) MAbs, indicating the possible existence of a specific fast-twitch MHC isoform expressed by the IFs but not by the extrafusal fibers.

Our results show that the BF-F3 MAb bound only the nuclear bag2 and chain fibers in the A and B regions, whereas Kucera et al. 1992 showed that these fibers were labeled only in the B region. This difference with our data could therefore be explained by the dilution (1:200) that they used, since we used a lower dilution (1:10).

Only a low level of labeling or no labeling was observed with 2B6 and NCL MHCd antibodies, respectively. These labeling differences reflected either differences in antibody affinities or the existence of more than one embryonic MHC isoform (Silberstein and Blau 1986 ). 2B6 gave a low level of labeling in the juxtaequatorial region of the nuclear bag fibers, and bag1 fibers were more intensely labeled than the nuclear bag2 fibers. Maier et al. 1988 observed that, with 2B6 MAb diluted at 1:50 (Gambke and Rubinstein 1984 ), the nuclear bag1 and bag2, but not nuclear chain fibers, were labeled in the juxtaequatorial and polar regions. However, we observed that, at this dilution, 2B6 MAb crossreacted with the fast type 2A myosin in extrafusal fibers (data not shown). We therefore used a 1:2000 dilution to remove this crossreaction. On the other hand, Harris et al. 1989 showed that 2B6 MAb was effective at a dilution of 1:2000–1:4000 to label the embryonic MHC isoform. Therefore, the labeling observed by Maier et al. 1988 could be due to the expression of both embryonic and MHC 2A isoforms in the nuclear bag fibers. However, our results showed that nuclear chain fibers expressed the MHC 2A isoform in the A region. If the labeling pattern observed with 2B6 MAb in the nuclear bag fibers was also due to the crossreactivity with the MHC 2A isoform, in the study of Maier et al. 1988 , the nuclear chain fibers should be labeled by 2B6 MAb. This is not the case. Such a surprising result could support the hypothesis that, in the nuclear bag1 fibers, the MHC isoform recognized by SC71 MAb is not the MHC 2A isoform but a specific fast-twitch isoform not recognized by 2B6 antibody. This is perhaps the reason why, in the study of Maier et al. 1988 , 2B6 did not label the nuclear chain fibers at 1:50 dilution.

Kucera et al. 1992 , using three different MAbs against embryonic MHC, observed either no, medium, or high-intensity labeling in IFs. Differences in antibody affinities and/or the existence of more than one embryonic MHC isoform (Silberstein and Blau 1986 ) cannot be ruled out. Our data showed no labeling with NCL MHCd MAb in all the IFs, which was in agreement with the results obtained by Kucera et al. 1992 using the BF-B6, another MAb specific for neonatal MHC. However, using other antibodies, it has been observed that the neonatal MHC is expressed in the nuclear bag2 and nuclear chain fibers (Pedrosa-Domellof et al. 1991 ; Soukup et al. 1995 ). Discrepancies among all these results could be related to the different specificities of the antibodies. The fact that no labeling was observed with NCL MHCd could be due to the presence of a small amount of neonatal MHC isoform that was not detected by the immunohistochemical method.

HU Group. All the observations on regional variation and labeling intensity in muscle spindles of the control group were also valid for the HU group. However, after unloading, some differences were observed in the expression level of slow type I, slow-tonic, and {alpha}-cardiac MHC isoforms.

The regulation of the {alpha}-cardiac MHC isoform expression along the length of bag fibers is under the influence of motor innervation. The expression of {alpha}-cardiac MHC appears one day after the arrival of bag1 and bag2 {gamma}-motor innervation (Pedrosa et al. 1990 ). After neonatal de-efferentation, the reactivity of nuclear bag2 fibers to the anti-{alpha}-cardiac MHC isoform was decreased and was limited to a shorter portion of the fibers, whereas the nuclear bag1 fibers were unreactive (Pedrosa et al. 1990 ; Pedrosa-Domellof et al. 1991 ). Conversely, slow-tonic MHC isoform expression along the length of bag fibers is undoubtedly related to the presence of sensory innervation. Indeed, neonatal denervation (Soukup et al. 1990a ; Kucera et al. 1993 ) and deafferentation (Kucera and Walro 1987 , Kucera and Walro 1988a , Kucera and Walro 1988b ) prevented the expression of the slow-tonic MHC isoform. However, after neonatal de-efferentation, the regional variation of this MHC isoform along the intrafusal bag2 fibers is modified and the slow-tonic MHC isoform is expressed more intensely and over most of their length (Soukup et al. 1990a ; Pedrosa-Domellof et al. 1991 ).

In adult rat muscle spindles, deafferentation or de-efferentation produced less severe alterations, but the expression pattern of some MHC isoform along the IF was modified (Wang et al. 1997 ). Wang et al. 1997 observed that, when adult rat muscle spindles were de-efferented in the extensor digitorum longus (EDL) muscle, the nuclear bag1 fibers, which normally express the {alpha}-cardiac MHC in the outer B region, ceased to express this isoform. Moreover, bag2 fibers continued to express this isoform but less intensely than normally. Pedrosa et al. 1990 and Soukup et al. 1990a both showed that, after denervation or neonatal de-efferentation, the expression of the {alpha}-cardiac MHC was decreased and the slow-tonic expression was increased along the length of nuclear bag fibers. According to these studies, we suggest that the decrease in {alpha}-cardiac and the increase in slow-tonic MHC isoforms in nuclear bag fibers reflect a decrease in the activity pattern of the motor nerves during unloading. This hypothesis is reinforced by the fact that, when extrafusal fibers are deprived of motor innervation (Harris et al. 1989 ), the expression of slow type 1 MHC isoform decreases. Similarly, our results showed that the expression of slow MHC isoform significantly decreased in the nuclear bag1 fibers after a period of unloading. However, Walro et al. 1997 , who used two kinds of deafferentation, concluded that regulation of MHC expression in adult EDL muscle of rat also depended on neurotrophic factors transported anterogradely from afferent neurons to the IFs.

It is more difficult to understand why slow-twitch and {alpha}-cardiac MHC isoforms are expressed over a very short distance of the A region in nuclear chain fibers after unloading. The expression of these two MHC isoforms is usually dependent on motor innervation, whose influence decreases from the C to the A region. Therefore, the expression of slow-twitch and {alpha}-cardiac MHC isoforms over only a short portion of the A region was unexpected. No previous studies on fetal, neonatal, or adult muscle spindles have reported a possible afferent or motor influence on the expression of slow-twitch and {alpha}-cardiac MHC isoforms in nuclear chain fibers.

To conclude, after unloading, the muscle spindle integrity and the labeling pattern of the majority of MHC isoforms were preserved. However, some differences were observed: a decrease in {alpha}-cardiac MHC expression and an increase in slow-tonic expression along the nuclear bag fibers. In the literature, it has been demonstrated that the level of {alpha}-cardiac MHC expression (Pedrosa et al. 1990 ; Soukup et al. 1990a ; Pedrosa-Domellof et al. 1991 ) and the regional variations in slow-tonic MHC expression depended on motor innervation (Soukup et al. 1990a ; Pedrosa-Domellof et al. 1991 ). Consequently, we hypothesized that the observed changes could be due to a decreased influence of motor innervation. In fact, it has been demonstrated that Ia afferents project not only onto {alpha}-skeletomotor neurons but also onto ß-skeletofusimotor and {gamma}-fusimotor neurons (Bernstein and Goldberg 1995 ). Therefore, the decrease in motor innervation activity could be due to decreased proprioceptive information. During unloading, the soleus muscle is often in a shortened position (Riley et al. 1990 ) and electromyographic activity is considerably reduced (Blewett and Elder 1993 ). As early suggested by Ohira et al. 1992 , we supposed that the muscle spindles, which are stretch sensors, are probably little or not at all stimulated. Consequently, the afferent activity of Ia and II fibers originating from these stretch receptors might be reduced, as shown indirectly by Falempin and Fodili In-Albon 1999 . We therefore conclude that proprioceptive feedback could regulate the expression of some MHC isoforms in adult muscle spindles, although changes in neurotrophic factors anterogradely transported from afferents to intrafusal fibers during hindlimb unloading cannot be ruled out.


  Acknowledgments

Supported by grants from the CNES (3027) and the Conseil Régional du Nord Pas-De-Calais.

The SC-71 and BF-F3 antibodies developed by Schiaffino et al. 1989 were obtained from the Deutsche Sammlung von Mikroorganismen and Zellkulturen Gmbh (DSMZ; Braunschweig, Germany). The ALD58 antibody developed by Shafiq et al. 1984 was obtained from the Developmental Studies Hybridoma Bank (DSHB; Iowa City, IA) maintained by The University of Iowa (Department of Biological Sciences, Iowa City, IA). We thank Dr A. Kelly and Dr N.A. Rubinstein for their gift of 2B6 to Dr G.S. Butler Browne.

Received for publication January 18, 2002; accepted May 29, 2002.


  Literature Cited
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Anderson J, Almeida–Silveira MI, Perot C (1999) Reflex and muscular adaptations in rat soleus muscle after hindlimb suspension. J Exp Biol 202(19):2701-2707[Abstract/Free Full Text]

Banks RW (1994) The motor innervation of mammalian muscle spindles. Prog Neurobiol 43:323-362[Medline]

Banks RW, Barker D, Stacey MJ (1982) Form and distribution of sensory terminals in cat hindlimb muscle spindles. Philos Trans R Soc Lond 299:329-364. [B][Medline]

Bernstein JJ, Goldberg WJ (1995) Experimental spinal cord transplantation as a mechanism of spinal cord regeneration. Paraplegia 33:250-253[Medline]

Blewett C, Elder GC (1993) Quantitative EMG analysis in soleus and plantaris during hindlimb suspension and recovery. J Appl Physiol 74:2057-2066[Abstract]

Botterman BR, Edgerton VR (1975) Histochemical profiles of rat soleus intrafusal fibres after chronic exercise. J Histochem 7:151-164

Davis CE, Harris JB, Nicholson LV (1991) Myosin isoform transitions and physiological properties of regenerated and re-innervated soleus muscles of the rat. Neuromusc Disord 1:411-421[Medline]

Edgerton VR, Roy RR (1996) Neuromuscular adaptation to actual and simulated spaceflight. In Fregly MJ, Blatteis CM, eds. Handbook of Physiology. Sect 4. Environmental Physiology. New York, American Physiological Society by Oxford University Press, 721-763

Falempin M, Fodili In-Albon S (1999) Influence of brief daily tendon vibration on rat soleus muscle in non-weight-bearing situation. J Appl Physiol 87:3-9[Abstract/Free Full Text]

Gambke B, Rubinstein NA (1984) A monoclonal antibody to the embryonic myosin heavy chain of rat skeletal muscle. J Biol Chem 259:12092-12100[Abstract/Free Full Text]

Guth L, Samaha FJ (1969) Qualitative differences between actomyosin ATPase of slow and fast mammalian muscle. Exp Neurol 25:138-152[Medline]

Harris AJ, Fitzsimons RB, McEwan JC (1989) Neural control of the sequence of expression of myosin heavy chain isoforms in fetal mammalian muscles. Development 107:751-769[Abstract]

Hoh JFY, Hughes S (1989) Immunocytochemical analysis of the perinatal development of cat masseter muscle using anti-myosin antibodies. J Muscle Res Cell Motil 10:312-325[Medline]

Hulliger M (1984) The mammalian muscle spindle and its central control. Rev Physiol Biochem Pharmacol 101:1-110[Medline]

Hunt CC (1990) Mammalian muscle spindle: peripheral mechanisms. Physiol Rev 70:643-663[Abstract/Free Full Text]

Khan MA, Soukup T (1988) Histochemical heterogeneity of intrafusal muscle fibres in slow and fast skeletal muscles of the rat. J Histochem 20:52-60

Kucera J (1981) Histochemical profiles of cat intrafusal muscle fibers and their motor innervation. Histochemistry 73:397-418[Medline]

Kucera J, Dorovini–Zis K, Engel WK (1978) Histochemistry of rat intrafusal muscle fibers and their motor innervation. J Histochem Cytochem 26:973-988[Abstract]

Kucera J, Walro JM (1987) Postnatal maturation of spindles in deafferented rat soleus muscles. Anat Embryol (Berl) 176:449-461[Medline]

Kucera J, Walro JM (1988a) The effect of neonatal deafferentation or deefferentation on the immunocytochemistry of muscle spindles in the rat. Neurosci Lett 95:88-92[Medline]

Kucera J, Walro JM (1988b) The effect of neonatal deafferentation or deefferentation on myosin heavy chain expression in intrafusal muscle fibers of the rat. Histochemistry 90:151-160[Medline]

Kucera J, Walro JM (1989) Nonuniform expression of myosin heavy chain isoforms along the length of cat intrafusal muscle fibers. Histochemistry 92:291-299[Medline]

Kucera J, Walro J (1990) Myosin heavy chain expression in developing rat intrafusal muscle fibers. Neursci Lett 109:18-22

Kucera J, Walro JM, Gorza L (1992) Expression of type-specific MHC isoforms in rat intrafusal muscle fibers. J Histochem Cytochem 40:293-307[Abstract/Free Full Text]

Kucera J, Walro JM, Reichler J (1993) Differential effects of neonatal denervation on intrafusal muscle fibers in the rat. Anat Embryol (Berl) 187:397-408[Medline]

Leger JO, Bouvagnet P, Bau B, Roncucci R, Leger JJ (1985) Levels of ventricular myosin fragments in human sera after myocardial infarction, determined with monoclonal antibodies to myosin heavy chains. Eur J Clin Invest 15:422-429[Medline]

Maier A (1997) Development and regeneration of muscle spindles in mammals and birds. Int J Dev Biol 41:1-17[Medline]

Maier A, Eldred E, Edgerton VR (1972) The effects on spindles of muscle atrophy and hypertrophy. Exp Neurol 37:100-123[Medline]

Maier A, Gambke B, Pette D (1988) Immunohistochemical demonstration of embryonic myosin heavy chains in adult mammalian intrafusal fibers. Histochemistry 88:267-271[Medline]

Matthews PB (1981) Evolving views on the internal operation and functional role of the muscle spindle. J Physiol 320:1-30[Medline]

McWhorter DL, Walro JM, Signs SA, Wang J (1995) Expression of alpha-cardiac myosin heavy chain in normal and denervated rat muscle spindles. Neursci Lett 200:2-4

Morey ER, Sabelman EE, Turner RT, Baylink DJ (1979) A new rat model simulating some aspects of space flight. Physiologist 22:S23-24[Medline]

Nibbering PH, Marijnen JG, Raap AK, Leijh PC, van Furth R (1986) Quantitative study of enzyme immunocytochemical reactions performed with enzyme conjugates immobilized on nitrocellulose. Histochemistry 84:538-543[Medline]

Ohira Y (2000) Neuromuscular adaptation to microgravity environment. Jpn J Physiol 50:303-314[Medline]

Ohira Y, Yasui W, Kariya F, Kaihatsu K (1992) The relationship between afferent input and muscle atrophy in response to unloading. Biol Sci Space 6:258-259

Ovalle WK, Smith RS (1972) Histochemical identification of three types of intrafusal muscle fibers in the cat and monkey based on the myosin ATPase reaction. Can J Physiol Pharmacol 50:195-202[Medline]

Pedrosa F, Butler–Browne GS, Dhoot GK, Fischman DA, Thornell LE (1989) Diversity in expression of myosin heavy chain isoforms and M-band proteins in rat muscle spindles. Histochemistry 92:185-194[Medline]

Pedrosa F, Soukup T, Thornell LE (1990) Expression of an alpha cardiac-like myosin heavy chain in muscle spindle fibres. Histochemistry 95:105-113[Medline]

Pedrosa–Domellof F, Gohlsch B, Thornell LE, Pette D (1993) Electrophoretically defined myosin heavy chain patterns of single human muscle spindles. FEBS Lett 335:239-242[Medline]

Pedrosa–Domellof F, Soukup T, Thornell LE (1991) Rat muscle spindle immunocytochemistry revisited. Histochemistry 96:327-338[Medline]

Riley DA, Slocum GR, Bain JL, Sedlak FR, Sowa TE, Mellender JW (1990) Rat hindlimb unloading: soleus histochemistry, ultrastructure, and electromyography. J Appl Physiol 69:58-66[Abstract/Free Full Text]

Sant'Ana Pereira JAA, De Haan A, Wessels A, Moorman AFM, Sargeant AJ (1995) The mATPase histochemical profile of rat type IIX fibres: correlation with myosin heavy chain immunolabelling. Histochem J 27:715-722[Medline]

Schiaffino S, Gorza L, Sartore S, Saggin L, Ausoni S, Vianello M, Gundersen K et al. (1989) Three myosin heavy chain isoforms in type 2 skeletal muscle fibres. J Muscle Res Cell Motil 10:197-205[Medline]

Shafiq SA, Shimizu T, Fischman DA (1984) Heterogeneity of type 1 skeletal muscle fibers revealed by monoclonal antibody to slow myosin. Muscle Nerve 7:380-387[Medline]

Silberstein L, Blau HM (1986) Two foetal-specific myosin isozymes in human muscle. In Emerson C, Fishmann DA, Nadal-Ginard B, Siddiqui MAQ, eds. Molecular Biology of Muscle Development. New York, Alan R Liss, 253

Soukup T (1976) Intrafusal fiber types in rat limb muscle spindles: morphological and histochemical characteristics. Histochemistry 47:43-57[Medline]

Soukup T, Novotova M (1996) Alternative strategies in muscle genotype and phenotype studies. A model of intrafusal muscle fiber type differentiation. Gen Physiol Biophys 15:345-356[Medline]

Soukup T, Pedrosa F, Thornell LE (1990a) Influence of neonatal motor denervation on expression of myosin heavy chain isoforms in rat muscle spindles. Histochemistry 94:245-256[Medline]

Soukup T, Pedrosa–Domellof F, Thornell LE (1993) Differentiation of supernumerary fibres in neonatally deefferented rat muscle spindles. Differentiation 53:35-43[Medline]

Soukup T, Pedrosa–Domellof F, Thornell LE (1995) Expression of myosin heavy chain isoforms and myogenesis of intrafusal fibres in rat muscle spindles. Microsc Res Tech 30:390-407[Medline]

Soukup T, Thornell LE (1997) Expression of myosin heavy chain isoforms in regenerated muscle spindle fibres after muscle grafting in young and adult rats—plasticity of intrafusal satellite cells. Differentiation 62:179-186[Medline]

Soukup T, Zelena J, Thornell LE, Asmussen G (1990b) Postnatal development of rat muscle spindles under different experimental conditions. Ergebn Exp Med (Berl) 53:238-255

Walro JM, Kucera J (1999) Why adult mammalian intrafusal and extrafusal fibers contain different myosin heavy chain isoforms. Trends Neurosci 22:180-184[Medline]

Walro JM, Wang J, Story GM (1997) Afferent-inherent regulation of myosin heavy chain isoforms in rat muscle spindles. Muscle Nerve 20:1549-1560[Medline]

Wang J, McWhorter DL, Walro JM (1997) Stability of myosin heavy chain isoforms in selectively denervated adult rat muscle spindles. Anat Rec 249:32-43[Medline]

Yellin H, Eldred E (1970) Spindle activity of the tenotomized gastrocnemius muscle in the cat. Exp Neurol 29:513-533[Medline]