Satellite cell dysfunction contributes to the progressive muscle atrophy in myotonic dystrophy type 1

AIMS

Myotonic dystrophy type 1 (DM1), one of the most common forms of inherited neuromuscular disorders in the adult, is characterized by progressive muscle weakness and wasting leading to distal muscle atrophy whereas proximal muscles of the same patients are spared during the early phase of the disease. In this report, the role of satellite cell dysfunction in the progressive muscular atrophy has been investigated.

METHODS

Biopsies were obtained from distal and proximal muscles of the same DM1 patients. Histological and immunohistological analyses were carried out and the past regenerative history of the muscle was evaluated. Satellite cell number was quantified in vivo and proliferative capacity was determined in vitro.

RESULTS

The size of the CTG expansion was positively correlated with the severity of the symptoms and the degree of muscle histopathology. Marked atrophy associated with typical DM1 features was observed in distal muscles of severely affected patients whereas proximal muscles were relatively spared. The number of satellite cells was significantly increased (twofold) in the distal muscles whereas very little regeneration was observed as confirmed by telomere analyses and developmental MyHC staining (0.3-3%). The satellite cells isolated from the DM1 distal muscles had a reduced proliferative capacity (36%) and stopped growing prematurely with telomeres longer than control cells (8.4 vs. 7.1 kb), indicating that the behaviour of these precursor cells was modified.

CONCLUSIONS

Our results indicate that alterations in the basic functions of the satellite cells progressively impair the muscle mass maintenance and/or regeneration resulting in gradual muscular atrophy.

Sca-1-expressing nonmyogenic cells contribute to fibrosis in aged skeletal muscle

We report an age-dependent increase in nonimmunohematopoietic cells (CD45neg) in regenerating muscle characterized by high stem-cell antigen (Sca-1) expression. In aged regenerating muscle, only 14% of these CD45negSca-1pos cells express MyoD, whereas 82% of CD45negSca-1(pos) cells are MyoDpos in young adult muscle. In vitro, CD45negMyoDnegSca-1pos cells overexpress fibrosis-promoting genes, potentially controlled by Wnt2. The cells are proliferative, nonmyogenic, and nonadipogenic, and arise in clonally derived myoblast cultures from aged mice. MyoDneg Sca-1pos nonmyogenic cells also emerge in C2C12 myoblast cultures at late passage. Both in vitro and in vivo studies suggest that MyoDnegSca-1pos cells from aged muscle are more susceptible to apoptosis than myoblasts, which may contribute to depletion of the satellite cell pool. Thus, with age, a subset of myoblasts takes on an altered phenotype, which is marked by high Sca-1 expression. These cells do not participate in muscle regeneration, and instead may contribute to muscle fibrosis in aged muscle.

Lymphoid-affiliated genes are associated with active histone modifications in human hematopoietic stem cells

To address the role of chromatin structure in the establishment of hematopoietic stem cell (HSC) multilineage potential and commitment to the lymphoid lineage, we have analyzed histone modifications at a panel of lymphoid- and myeloid-affiliated genes in multipotent and lineage-committed hematopoietic cells isolated from human cord blood. Our results show that many B- and T-lymphoid genes, although silent in HSCs, are associated with acetylated histones H3 and H4. We also detected histone H3 lysine 4 methylation but not repressive lysine 9 or 27 methylation marks at these loci, indicative of an open chromatin structure. Interestingly, the relative level of H3 lysine 4 dimethylation to trimethylation at B-specific loci was high in multipotent CD34(+)CD38(lo) progenitors and decreased as they become actively transcribed in B-lineage cells. In vitro differentiation of CD34(+) cells toward the erythroid, granulocyte, and T-cell lineages resulted in a loss of histone acetylation at nonlineage-associated genes. This study provides evidence that histone modifications involved in chromatin decondensation are already in place at lymphoid-specific genes in primary human HSCs, supporting the idea that these genes are "primed" for expression before lineage commitment. This permissive chromatin structure is progressively lost as the stem cell differentiates.

Cellular and molecular mechanisms underlying age-related skeletal muscle wasting and weakness

Some of the most serious consequences of ageing are its effects on skeletal muscle. The term 'sarcopenia' describes the slow but progressive loss of muscle mass with advancing age and is characterised by a deterioration of muscle quantity and quality leading to a gradual slowing of movement and a decline in strength. The loss of muscle mass and strength is thought to be attributed to the progressive atrophy and loss of individual muscle fibres associated with the loss of motor units, and a concomitant reduction in muscle 'quality' due to the infiltration of fat and other non-contractile material. These age-related changes in skeletal muscle can be largely attributed to the complex interaction of factors affecting neuromuscular transmission, muscle architecture, fibre composition, excitation-contraction coupling, and metabolism. Given the magnitude of the growing public health problems associated with sarcopenia, there is considerable interest in the development and evaluation of therapeutic strategies to attenuate, prevent, or ultimately reverse age-related muscle wasting and weakness. The aim is to review our current understanding of some of the cellular and molecular mechanisms responsible for age-related changes in skeletal muscle.