Nathan M. Solbak

Denervation Causes Fiber Atrophy and Myosin Heavy Chain Co-Expression in Senescent Skeletal Muscle

Although denervation has long been implicated in aging muscle, the degree to which it is causes the fiber atrophy seen in aging muscle is unknown. To address this question, we quantified motoneuron soma counts in the lumbar spinal cord using choline acetyl transferase immunhistochemistry and quantified the size of denervated versus innervated muscle fibers in the gastrocnemius muscle using the in situ expression of the denervation-specific sodium channel, Nav1.5, in young adult (YA) and senescent (SEN) rats. To gain insights into the mechanisms driving myofiber atrophy, we also examined the myofiber expression of the two primary ubiquitin ligases necessary for muscle atrophy (MAFbx, MuRF1). MN soma number in lumbar spinal cord declined 27% between YA (638±34 MNs×mm−1) and SEN (469±13 MNs×mm−1). Nav1.5 positive fibers (1548±70 μm2) were 35% smaller than Nav1.5 negative fibers (2367±78 μm2; P<0.05) in SEN muscle, whereas Nav1.5 negative fibers in SEN were only 7% smaller than fibers in YA (2553±33 μm2; P<0.05) where no Nav1.5 labeling was seen, suggesting denervation is the primary cause of aging myofiber atrophy. Nav1.5 positive fibers had higher levels of MAFbx and MuRF1 (P<0.05), consistent with involvement of the proteasome proteolytic pathway in the atrophy of denervated muscle fibers in aging muscle. In summary, our study provides the first quantitative assessment of the contribution of denervation to myofiber atrophy in aging muscle, suggesting it explains the majority of the atrophy we observed. This striking result suggests a renewed focus should be placed on denervation in seeking understanding of the causes of and treatments for aging muscle atrophy.

Accumulation of severely atrophic myofibers marks the acceleration of sarcopenia in slow and fast twitch muscles

The age-related decline in muscle mass, known as sarcopenia, exhibits a marked acceleration in advanced age. Although many studies have remarked upon the accumulation of very small myofibers, particularly at advanced stages of sarcopenia, the significance of this phenomenon in the acceleration of sarcopenia has never been examined. Furthermore, although mitochondrial dysfunction characterized by a lack of cytochrome oxidase (COX) activity has been implicated in myofiber atrophy in sarcopenia, the contribution of this phenotype to the accumulation of severely atrophied fibers in aged muscles has never been determined. To this end, we examined the fiber size distribution in the slow twitch soleus (Sol) and fast twitch gastrocnemius (Gas) muscles between young adulthood (YA) and senescence (SEN). We also quantified the abundance of COX deficient myocytes and their size attributes to gain insight into the contribution of this phenotype to myofiber atrophy with aging. Our data showed that the progression of muscle atrophy, particularly its striking acceleration between late middle age and SEN, was paralleled by an accumulation of severely atrophic myofibers (≤ 1000 μm(2) in size) in both Sol and Gas. On the other hand, we observed no COX deficient myofibers in Sol, despite nearly 20% of the myofibers being severely atrophic. Similarly, only 0.17 ± 0.06% of all fibers in Gas were COX deficient, and their size was generally larger (2375 ± 319 μm(2)) than the severely atrophied myofibers noted above. Collectively, our results suggest that similar processes likely contribute to the acceleration of sarcopenia in both slow twitch and fast twitch muscles, and that COX deficiency is not a major contributor to this phenomenon.

Changes of early post-traumatic osteoarthritis in an ovine model of simulated ACL reconstruction are associated with transient acute post-injury synovial inflammation and tissue catabolism

The study described here tested the hypothesis that early intra-articular inflammation is associated with the development of post-traumatic osteoarthritis (PTOA) in a sheep model. We extended previously published work in which we investigated joint gross morphology and synovial mRNA expression of inflammatory and catabolic molecules 2 weeks after anatomic Anterior cruciate ligament (ACL) autograft reconstructive surgery (ACL-R). The same variables have been analyzed at 20 weeks post surgery together with new experimental variables at both time points. Animals were sacrificed at 20 weeks post ACL-R surgery and their joints graded for signs of PTOA. Synovial samples were harvested for histological grading plus mRNA and protein analysis for a panel of inflammatory and catabolic molecules. The mRNA expression levels for this panel plus connective tissue matrix turnover molecules were also investigated in cartilage samples. Results of gross morphological assessments at 20 weeks post surgery showed some changes consistent with early OA, but indicated little progression of damage from the 2 week time point. While significant alterations in mRNA levels for synovial inflammatory and catabolic molecules were detected at 2 weeks, values had normalized by 20 weeks. Similarly, all mRNA expression levels for inflammatory and catabolic molecules in articular cartilage had returned to normal levels by 20 weeks post ACL-R surgery. We conclude that synovial inflammatory processes are initiated very early after ACL-R surgery and may instigate events that lead to the gross cartilage and joint abnormalities observed as early as 2 weeks. However, the absence of sustained inflammation and joint instability may prevent OA progression.

Severe atrophy of slow myofibers in aging muscle is concealed by myosin heavy chain co-expression.

Although slow myofibers are considered less susceptible to atrophy with aging, slow fiber atrophy may have been underestimated previously. First, the marked atrophy of the aging rat soleus (Sol) muscle cannot be explained by the atrophy of only the fast fibers, due to their low abundance. Second, the increase in small fibers co-expressing both fast and slow myosin heavy chains (MHC) in the aging rat Sol is proportional to a decline in pure MHC slow fibers (Snow et al., 2005), suggesting that these MHC co-expressing fibers represent formerly pure slow fibers. Thus, we examined the size and proportion of MHC slow, MHC fast, and MHC fast-slow co-expressing fibers in the Sol and mixed region of the gastrocnemius (Gas) muscle in young adult (YA) and senescent (SEN) rats. Our results suggest that formerly pure MHC slow fibers are the source of MHC co-expressing fibers with aging in both muscle regions. Accounting for the atrophy of these fibers in calculating MHC slow fiber atrophy with aging revealed that MHC slow fibers atrophy on average by 40% in the Sol and by 38% in the mixed Gas, values which are similar to the 60% and 31% atrophy of pure MHC fast fibers in the Sol and mixed Gas, respectively. Probing for the atrophy-dependent ubiquitin ligase, MAFbx (atrogin 1), it was suggested that former slow fibers acquire atrophy potential via the up-regulation of MAFbx coincident with the co-expression of fast MHC. These results redefine the impact of aging on slow fiber atrophy, and emphasize the necessity of addressing the atrophy of fast and slow fibers in seeking treatments for aging muscle atrophy.

Normal sheep synovium has similar appearances and constitutive expression of inflammatory cytokines within and between knee joints: a baseline histological and molecular analysis

Abstract Clinical evidence suggests that synovium can add to adjacent articular cartilage damage, potentially contributing to the development of osteoarthritis (OA). Inflammation of the synovium (synovitis) is dependent on the type of injury sustained, the time after injury and concomitant changes in other joint tissues. To define the role of synovitis in OA development, there is a need for baseline measures that can reliably distinguish synovial inflammation from normal synovium both within and between joints. This study tested the hypothesis that normal synovium from distinct anatomical locations in young and adult sheep is homogeneous with respect to consistently low molecular expression of the inflammatory mediators – tumour necrosis factor alpha (TNF-α) and interleukins (IL) such as IL-1β, IL-1Ra, IL-6 and IL-8. Additionally, maturation will not influence the expression of these select inflammatory biomarkers. Samples of synovium from four anatomic locations (medial and lateral margins, suprapatellar pouch (patella region), posterior to the posterior cruciate ligament, from each joint of 5 adult and 4 immature animals were graded histologically or analyzed for mRNA expression of inflammatory cytokines. Histologically, no evidence of synovitis was noted although some variance in sub-intimal fibrosis was observed between sample locations in mature sheep. Molecular expression of all inflammatory mediators was low and homogeneously expressed at constitutive levels in all sample locations. These findings confirm the hypothesis that the normal sheep synovium is a homogeneous tissue throughout the joint and establishes the baseline expression levels for several pro-inflammatory mediators in both immature and mature sheep.