Distribution maps of D-dopachrome tautomerase in the mouse brain.

D-Dopachrome tautomerase is an enzyme related by amino acid sequence and catalytic activity to macrophage migration inhibitory factor. Both of these small molecules are pro-inflammatory cytokines mediating broad innate immune responses. Although it is well established that the gene product of D-dopachrome tautomerase is widely expressed in liver and kidney cells, no study has mapped the distribution pattern of this tautomeric enzyme in the mammalian nervous system. Here, we address this void by characterizing the cellular localization of D-dopachrome tautomerase in the adult mouse brain. Two well-characterized polyclonal antibodies were used for Western blotting and immunohistochemical localization of the endogenous tautomeric enzyme. Our results show that D-dopachrome tautomerase is present throughout the brain parenchyma with a large fraction of heterogeneous interneurons harboring a stable and robust expression of the enzyme. These data point to a potential involvement of D-dopachrome tautomerase activity in the mature mouse brain, and suggest some functional and evolutionary relationship between innate immunity and tautomerization of D-dopachrome in mammalian species.

Resistance vessel remodeling and reparative angiogenesis in the microcirculatory bed of long-term denervated skeletal muscles.

In denervated skeletal muscles, atrophy of muscle fibers and interstitial fibrosis are associated with alterations within the vascular bed. Our study has placed particular emphasis on changes occurring in resistance vessels and the microcirculatory bed of rat hindlimb skeletal muscles that had been denervated for 25 months. We found that the tunica media of the majority of long-term denervated resistance vessels undergoes deterioration. In small intramuscular arteries and arterioles, atrophic vascular smooth muscle cells (vSMCs) enclosed in a thick basal lamina are separated by expanded extracellular space. The remodeling and sclerotic changes in the arterial wall occasionally result in deformation of the lumen. It was also found that the microcirculatory bed undergoes significant alterations. In 25-month denervated extensor digitorum longus muscle, the capillary-to-fiber ratio is only 0.13 +/- 0.01 and the mean number of capillaries per fascicle decreases almost ninefold compared to contralateral control muscle. Ultrastructural findings demonstrate that 24.67 +/- 0.48% of capillaries examined in the chronically denervated fascicles show structural features typical for capillary regeneration. In addition, long cytoplasmic extensions of pericytes might develop a layer completely encircling the capillary endothelium. In pre- and postcapillary segments of the microcirculatory bed, some perivascular cells possess a phenotype that is intermediate between that of pericytes and atrophic vSMCs. RT-PCR and/or Western blot analyses showed that molecules participating in angiogenesis are detected in 25-month denervated skeletal muscle. We hypothesize that despite the fact that the microcirculatory bed of chronically denervated muscle undergoes significant reduction it still sustains the capacity for reparative capillary growth.

Interrelations of myogenic response, progressive atrophy of muscle fibers, and cell death in denervated skeletal muscle.

Little is known concerning the time-course and structural dynamics of reactivation of compensatory myogenesis in denervated muscle, its initiating cellular mechanisms, and the relationship between this process and the progression of postdenervation atrophy. The purpose of this study was to investigate the interrelations between temporal and spatial patterns of the myogenic response in denervated muscle and progressive atrophy of muscle fibers. Another objective was to study whether reactivation of myogenesis correlates with destabilization of the differentiated state and death of denervated muscle cells. It has remained unclear whether muscle fiber atrophy was the primary factor activating the myogenic response, what levels of cellular atrophy were associated with its activation, and whether the initiation and intensity of myogenesis depended on the local and individual heterogeneity of atrophic changes among fibers. For this reason, our objective was also to identify the levels of atrophic and degenerative changes in denervated muscle fibers that are correlated with activation of the myogenic response. We found that the reactivation of myogenesis in the tibialis anterior and extensor digitorum longus muscles of the rat starts between days 10-21 following nerve transection, before atrophy has attained advanced level, long before dead cells are found in the tissue. Formation of new muscle fibers reaches its maximum between 2 and 4 months following denervation and gradually decreases with progressive postdenervation atrophy. The myogenic response is biphasic and includes two distinct processes. The first process resembles the formation of secondary and tertiary generations of myotubes during normal muscle development and dominates during the first 2 months of denervation. During this period, activated satellite cells form new myotubes on live differentiated muscle fibers. Most of the daughter myotubes in 1- and 2-month denervated muscle develop on the surface of fast type parent muscle fibers, and some of the newly formed muscle fibers express slow myosin. Some fast type parent fibers are weakly or, more rarely, moderately immunopositive for embryonic isomyosin. This indicates that reactivation of myogenesis may also depend on the fiber type. The level of atrophy, destabilization of the differentiated myofiber phenotype, and degenerative changes of individual fibers in denervated muscle are very heterogeneous. The myogenic response of the first type is associated predominantly with fibers of average and higher than average levels of atrophy. Muscle cells that undergo a lesser degree of atrophy also form daughter fibers, although with a lower incidence. We did not find any correlation between the size of newly formed fibers and the level of atrophy of parent fibers. The topographical distribution of new myotubes both in the peripheral and central areas of the mid-belly equatorial sections at the early stages following nerve transection indicates that myogenesis of the first type represents a systemic reaction of muscle to the loss of neural control. These data indicate that activation of the myogenic response does not depend on cell death and degenerative processes per se. The second type of myogenesis is a typical regenerative reaction that occurs mainly within the spaces surrounded by the basal laminae of dead muscle fibers. Myocytes of different sizes are susceptible to degeneration and death, which indicates that cell death in denervated muscle does not correlate with levels of muscle cell atrophy. The regenerative process frequently results in development of abnormal muscle cells that branch or form small clusters. Replacement of lost fibers becomes activated between 2 and 4 months following nerve transection, i.e., mainly at advanced stages of postdenervation atrophy, when cell death becomes a contributing factor of the atrophic process. In long-term denervated muscle, the first and second types of myogenesisoccur concurrently, and the topographical distribution of the myogenic response becomes more heterogeneous than during the first weeks following denervation. Thus, our data demonstrate differential temporal and spatial expression of two patterns of myogenesis in denervated muscle that appear to be controlled by different regulatory mechanisms during the postdenervation period. (c) 2001 Wiley-Liss, Inc.

Reparative myogenesis in long-term denervated skeletal muscles of adult rats results in a reduction of the satellite cell population.

This study, conducted on 25-month denervated rat hindlimb muscles, was directed toward elucidating the basis for the poor regeneration that is observed in long-term denervated muscles. Despite a approximately 97.6% loss in mean cross-sectional area of muscle fibers, the muscles retained their fascicular arrangement, with the fascicles containing approximately 1.5 times more fibers than age-matched control muscles. At least three distinct types of muscle fibers were observed: degenerating, persisting (original), and newly formed (regenerated) fibers. A majority of newly formed fibers did not appear to undergo complete maturation, and morphologically they resembled myotubes. Sites of former motor end-plates remained identifiable in persisting muscle fibers. Nuclear death was seen in all types of muscle fibers, especially in degenerating fibers. Nevertheless, the severely atrophic skeletal muscles continued to express developmentally and functionally important proteins, such as MyoD, myogenin, adult and embryonic subunits of the nicotinic acetylcholine receptor, and neural-cell adhesion molecule. Despite the prolonged period of denervation, slow and fast types of myosin were found in surviving muscle fibers. The number of satellite cells was significantly reduced in long-term denervated muscles, as compared with age-matched control muscles. In 25-month denervated muscle, satellite cells were only attached to persisting muscle fibers, but were never seen on newly formed fibers. Our data suggest that the absence of satellite cells in a population of immature newly formed muscle fibers that has arisen as a result of continuous reparative myogenesis may be a crucial, although not necessarily the only, factor underlying the poor regenerative ability of long-term denervated muscle.

Skeletal muscle regeneration in very old rats.

This study was undertaken to assess the regenerative capacity of skeletal muscle in rats near the end of their normal life span. Two experiments were performed. In the first, extensor digitorum longus (EDL) muscles were cross-age transplanted from 32-month-old male inbred Wistar (WI/HicksCar) rats in place of an EDL muscle in 4-month-old hosts. The other EDL muscle in the hosts was autotransplanted. After 60 days, the old-into-young muscle transplants regenerated as well as the young-into-young autotransplants. In the second experiment, EDL muscles in young adult (4 months) and old rats (32 and 34 months) of WI/HicksCar and Brown Norway (BN) were injected with a local anesthetic, bupivacaine, and allowed to regenerate for 41 days. In all cases, the masses and absolute maximum tetanic force of the regenerates equaled or exceeded those of untouched contralateral control muscles. These experiments showed that under appropriate conditions, very old muscles can regenerate to equal or exceed the contralateral control values, which in old rats are much less than those in muscles of young rats.

[Changes in the myocardium of adult rats when cultured in diffusion chambers in vivo]. / Izmeneniia miokarda vzroslykh krys pri kul'tivirovanii v diffuzionnykh kamerakh in vivo.

Morpho-functional changes of left ventricle myocardium were studied in 30 adult male rats by the method of subcutaneous implantation of diffusion chambers. The transplants were examined in 1, 3, 6, 8 and 10 days after the beginning of cultivation. The method of light microscopy at the 1-2 microm sections was used after histological processing of specimens for the identification of muscle and non-muscle cells and studying of their particular changes. In the muscular fibres there were cardiomyocytes of the destructive, survived and reconstructed forms. It was shown that smooth muscle cells and periocytes are separated from blood microvessels and migrated into the interstitial space. Multinuclear drawing rods formated from activational endotheliocytes were detected between the muscular fibers. Furthermore the cells containing large amount of lipid granules-¿lypophags¿ and the two types of macrophage-like cells were demonstrated. The area of growth including fibroblast-like and spindle-shaped cells were observed around the margins of transplants on the late stages of implantation.

[The ultrastructural characteristics of the reactive changes in the cardiomyocytes of adult rats when cultured in vivo]. / Ul'trastrukturnye osobennosti reaktivnykh izmenenii kardiomiotsitov vzroslykh krys pri kul'tivirovanii in vivo.

60 implantes of the left atrium myocardium were studied on the 1st, 3rd and 6th days of in vivo culture according to F. M. Lazarenko method (outbred laboratory male rats of 200-250g. body weight were used both as donors and recipients). Reactive changes of the cultured cardiomyocytes were assessed by methods of light and electron microscopy. Polymorphic nature of the cardiomyocyte reactive changes with the preservation of its tissue pecific determination was established. Myocardium implant did not form myosymplastic elements, cellular characteristics of organization remained in its implanted pieces. Data concerning degenerating and surviving cardiomyocytes are presented as well as those on cellular forms, identification of which is difficult on the ultrastructural level.