Ida Eržen

Frequency of M-Cadherin-stained Satellite Cells Declines in Human Muscles During Aging

To answer the question of whether the satellite cell pool in human muscle is reduced during aging, we detected satellite cells in 30-μm-thick transverse sections under the confocal microscope by binding of M-cadherin antibody. The basal lamina was detected with laminin. Nuclei were stained with bisbenzimide or propidium iodide. Satellite cells were counted by applying the disector method and unbiased sampling design. To determine if there are age-related differences in muscle fiber types, morphometric characteristics of muscle fibers were examined on thin sections stained for myofibrillar ATPase. Autopsy samples of vastus lateralis muscle from six young (28.7 ± 2.3 years) and six old (70.8 ± 1.3 years) persons who had suffered sudden death were analyzed. Numbers of satellite cells per fiber length (Nsc/Lfib) and number of satellite cells per total number of nuclei (satellite cell nuclei + myonuclei) (Nsc/Nnucl) were significantly lower in the old group (p<0.05). We demonstrate the importance of proper sampling and counting in estimation of sparsely distributed structures such as satellite cells. Our results support the hypothesis that the satellite cell fraction declines during aging.

Dynamic nature of fibre-type specific expression of myosin heavy chain transcripts in 14 different human skeletal muscles

The main goal of this study was to find out, whether the appearance of fibres without evident myosin heavy chain (MyHC) transcript expression (negative fibres) implies the existence of additional MyHC transcripts in human muscle fibres. Fourteen different skeletal muscles were analysed also to verify how MyHC transcript expression matches histochemical phenotypes of fibres. For this purpose, the expression of β-slow, 2a and 2x MyHC transcripts, demonstrated by in situ hybridisation technique, was analysed within type I, IIC, IIA, IIAX and IIX fibres, determined according to the activity of myofibrillar ATPase. Additionally, MyHC isoform expression was immunohistochemically demonstrated and metabolic profiles of negative fibres were estimated. From a total of 4444 muscle fibres analysed, only 0.8% of fibres were negative, among them type I prevailed, the remainder were type IIA and IIX fibres. The majority of fibres expressed only β, 2a and 2x MyHC transcripts and they mostly matched type I, IIA and IIX fibres respectively, but two minor hybrid fibre groups (β/2a and 2ax) exhibited variable histochemical phenotype. The infrequency, the prevailing oxidative–glycolytic metabolic profile of negative type I fibres and frequent co-appearance with transitional type IIC fibres imply that the negative fibres rather result from fibre type transition than express an additional slow or even 2b MyHC transcripts. The appearance of hybrid and mismatched fibres additionally indicates that fibre type transition occurs also in presumably normal skeletal muscles, what enables the muscles to tune even with minimal changes in mechanical demands.

Three-dimensional study of the capillary supply of skeletal muscle fibres using confocal microscopy.

Three-dimensional (3D) study of capillary network of individual muscle fibres in rat extensor digitorum longus (EDL) and soleus (SOL) muscles is presented. Stereology and 3D reconstruction techniques were applied to stacks of serial optical sections recorded by a confocal microscope from thick muscle slices. The results suggest that SOL muscle fibres have a larger surface area and volume as well as a larger length of capillaries per fibre length than EDL. On the other hand, these two muscles have a similar ratio of capillary length to fibre surface area. The 3D approach to evaluation of muscle fibre capillarization brings many advantages over traditional measurements made on single muscle sections and could also be applied to the study of angiogenesis in other tissues.

Fibre types and Myosin heavy chain expression in the Ocular Medial Rectus Muscle of the Adult Rat

Myosin heavy chain (MHC) expression was determined immunohistochemically in individual muscle fibre types characterised by activities of ATPase and the key oxidative and glycolytic enzymes in rat ocular medial rectus (MR) muscles. In the global layer (GL), glycolytic activity of muscle fibres was higher and oxidative activity lower, than in the orbital layer (OL). Muscle fibres in the former displayed rosette-like organisation with a slow fibre surrounded by several fast fibres, which expressed either MHCIIa or MHCIIb, but many co-expressed both isoforms. In the OL some slow fibres co-expressed MHCIIa. Extraocular MHC isoform (MHCeom) could not be determined immunohistochemically and no pure MHCIIx/d containing fibres were found, suggesting that these isoforms, demonstrated electrophoretically, are co-expressed with others. Slow muscle fibres in both layers co-expressed MHCβ slow, MHCα cardiac and MHC-slow tonic. Neonatal isoform (MHCneo) was co-expressed in several fast and slow muscle fibres in the orbital, but not global layer. Slow fibres in the GL displayed very low oxidative activity. Electrophoretic analysis of ocular MR muscle homogenates revealed that about 50% of total MHC was MHCIIb, MHCeom was quite prominent (25%), and MHCIIa, MHCIIx/d and MHCI contributed each about 8%. MHCneo, MHCslow tonic and MHCα cardiac could not be identified as separate bands.

Adaptive range of myosin heavy chain expression in regenerating soleus is broader than in mature muscle

SummaryIn adult rat muscles experimentally exposed to various patterns of activation, expression of myosin heavy chain isoforms changes, but only within a certain adaptive range. It is characteristic and different in fast or slow muscles. This may be due either to different intrinsic properties of the myogenic cells of the two types of muscles or to extrinsic factors. To test these assumptions, either rat soleus or extensor digitorum longus muscles were injured and transplanted to the bed of the extensor digitorum longus muscle. They regenerated and were reinnervated by the extensor digitorum longus nerve. Expression of myosin heavy chain isoforms was demonstrated immunohistochemically and by in situ hybridization, and analysed by SDS-gel electrophoresis. Three months after cross-transplantation, regenerated soleus expressed all adult myosin heavy chain isoforms, including the myosin heavy chain-2B. The latter was detected in about 50% of muscle fibres and contributed about 10–20% of all myosin heavy chains. The same percentage of myosin heavy chain-2B was found in regenerated extensor digitorum longus. In this regard therefore, the adaptive range of the regenerated soleus muscle was not significantly different from that of the extensor digitorum longus regenerating under the same conditions. This indicates that restriction of the adaptive range in a mature soleus muscle is not due to intrinsic properties of its myogenic cells. It is probably imposed by an extrinsic factor leading to irreversible shut-down of individual myosin heavy chain genes. On the other hand, myosin heavy chain-1 expression was significantly greater in the regenerated soleus than in the extensor digitorum longus innervated by the same nerve. Myosin heavy chain-1 and myosin heavy chain-2B were co-expressed in some regenerated soleus muscle fibres.

A novel method for evaluation of capillarity in human skeletal muscles from confocal 3D images

A well developed capillary bed is essential for proper function of skeletal muscles. We present for the first time a triple immunofluorescent method suitable for staining capillaries and muscle fibre outlines in thick sections of human skeletal muscle, applying antibodies against collagen IV (in red) and F8 (in green) as well as Ulex europaeus lectin, visualized in green fluorescence. Further, we present possibilities for quantitative evaluation of the capillary network which implies the length of capillaries per unit volume of muscle tissue (Lcap/Vmuscle) and the length of capillaries supplying individual muscle fibres per unit fibre length (Lcap/Lfib), per surface area (Lcap/Sfib) and per volume (Lcap/Vfib) as well as the course of capillaries in the muscle. The latter can be described by the tortuosity, orientation and mean capillary length. To get reasonable results we met the following requirements: i) high quality thick tissue sections, from which 3D image data were acquired; ii) immunofluorescent methods suitable for confocal microscopy; iii) penetration of the fluorescent dyes throughout the tissue section; iv) proper 3D image analysis methods for performing reliable measurements and v) control over relevant tissue deformations. The developed methodology is illustrated by results obtained from autopsy or biopsy samples of three human muscles, i.e. vastus lateralis, multifidus and masseter muscle that exhibit differences in genetic background, innervation, tasks and functional activity.

3D Visualization and Measurement of Capillaries Supplying Metabolically Different Fiber Types in the Rat Extensor Digitorum Longus Muscle During Denervation and Reinnervation

The aim of this study was to determine whether capillarity in the denervated and reinnervated rat extensor digitorum longus muscle (EDL) is scaled by muscle fiber oxidative potential. We visualized capillaries adjacent to a metabolically defined fiber type and estimated capillarity of fibers with very high oxidative potential (O) vs fibers with very low oxidative potential (G). Capillaries and muscle fiber types were shown by a combined triple immunofluorescent technique and the histochemical method for NADH-tetrazolium reductase. Stacks of images were captured by a confocal microscope. Applying the Ellipse program, fibers were outlined, and the diameter, perimeter, cross-sectional area, length, surface area, and volume within the stack were calculated for both fiber types. Using the Tracer plug-in module, capillaries were traced within the three-dimensional (3D) volume, the length of capillaries adjacent to individual muscle fibers was measured, and the capillary length per fiber length (Lcap/Lfib), surface area (Lcap/Sfib), and volume (Lcap/Vfib) were calculated. Furthermore, capillaries and fibers of both types were visualized in 3D. In all experimental groups, O and G fibers significantly differed in girth, Lcap/Sfib, and Lcap/Vfib, but not in Lcap/Lfib. We conclude that capillarity in the EDL is scaled by muscle fiber size and not by muscle fiber oxidative potential. (J Histochem Cytochem 57:437–447, 2009)

Histochemical and immunohistochemical profile of human and rat ocular medial rectus muscles

PurposeTo compare the organization of human and rat ocular medial recti muscles (MR).MethodsThe cryosections of human and rat MR were processed for myofibrillar ATPase (mATPase), succinate dehydrogenase and glycerol-3-phosphate dehydrogenase. To reveal myosin heavy chain (MyHC) isoforms, specific monoclonal antibodies against MyHC-1/β- slow, α-cardiac (-α), -2a, -2x, -2b, -extraocular (eom), -embryonic (-emb) and -neonatal (-neo) were applied. The MyHC gene expression was studied by in situ hybridization in human muscle.ResultsThe muscle fibers were arranged in two distinct layers in both species. In the orbital layer most fibers were highly oxidative and expressed fast MyHC isoforms, whereas slow and oxidative fibers expressed MyHC-1 and -α, some of them also MyHC-2a, -2x, -eom, very rarely -emb, and –neo. In the global layer, slow fibers with very low oxidative and glycolytic activity and three types of fast fibers, glycolytic, oxidative and oxidative-glycolytic, could be distinguished. The slow medium-sized fibers with mATPase activity stable at pH 4.4 expressed mostly MyHC-1 and -α in rat, while in humans they co-expressed MyHC-1 with -2b, -2x, -eom, and -neo. In both species, the fast fibers showed variable mATPase activity after preincubation at pH 9.4, and co-expressed various combinations of MyHC-2b, -2x, -2a and -eom but not -emb and -neo. MyHC-2b expressing fibers were larger and glycolytic, while MyHC-2a expressing fibers were smaller and highly oxidative in both species. To our knowledge, the present study is the first that demonstrated the expression of MyHC-2b in any of human skeletal muscles. Though the expression of MyHC genes did not correlate with the immunohistochemical profile of fibers in human MR, the expression of MyHC-2b gene was undoubtedly confirmed.ConclusionsRat MR represent a good model that can be applied to study human MR in experiment or disease, however certain differences are to be expected due to specific oculomotor demands in humans.

The estimation error of skeletal muscle capillary supply is significantly reduced by 3D method.

Capillary supply of individual skeletal muscle fibers is usually evaluated from two-dimensional (2D) images of thin transverse sections by the number of capillary profiles around a fiber (CAF). This method is inherently inaccurate and the resulting capillary length measurement errors can be avoided by using an alternative three-dimensional (3D) approach where the mean length of capillaries around individual muscle fibers per fiber length (Lcap/Lfib) is measured from 3D images acquired by confocal microscopy. We quantified the error of the 2D method and its reduction by using a 3D approach in realistic geometrical models of muscle fiber capillary bed and in true muscle samples. In models we showed that Lcap/Lfib was sensitive to different arrangements of capillaries, while CAF underestimated capillarization since it could not detect the increased length of capillary bed. In true muscle samples, we detected statistically significant differences in the capillary supply of control and denervated rat soleus muscles by both 2D and 3D methods. Lcap/Lfib was larger than CAF in control muscles reflecting their more complicated capillary bed. Thus, 3D approach is more sensitive in agreement with the analysis of geometrical models. We conclude that the 3D method, though technically more demanding than 2D method, represents a more precise approach to evaluation of muscle capillarization. Moreover, the 3D method could be applied to other organs and we suggest potential medical applications.

Histophotometry--the method of choice in quantifying dehydrogenase histochemistry.

Succinate, malate, and lactate dehydrogenase were demonstrated histochemically and measured histophotometrically in the heart and skeletal muscle (m. extensor digitorum longus and m. soleus) of rats at different ages. To prove the value of histophotometry, the enzymes of the tissues were estimated biochemically. The gel film technique cannot sufficiently prevent the diffusion of the soluble enzymes (malate-, lactate dehydrogenase) out of the tissue sections. Because of the different mobility, various isoenzymes, histophotometry cannot give reliable results. But, as far as membrane-bound dehydrogenases (succinate dehydrogenase) are concerned, histophotometry is the method of choice for basic measurements as in routine practical work, especially with tissues where the enzyme activities are heterogeneously distributed, e.g. in different types of muscle fibres in skeletal muscles.