Effective tissue repair relies on an organs ability to control the number and function of stem cells or tissue specific progenitors. Satellite cells (SCs) are the """"""""cell of choice"""""""" for adult skeletal muscle repair. Based on the assumption that all somatic cells, including SCs, have a finite capacity;reducing the number of SCs within the pool while keeping intrinsic capacity unchanged will lead to eventual functional exhaustion and impaired muscle repair. Similarly, if intrinsic capacity is impaired, while the number of SCs in the pool is maintained, this will also lead to a detrimental outcome for muscle function. During aging, muscle regeneration capacity is significantly impaired. This coincides with a decline in SC number and function. It remains unresolved whether age related impairment in muscle regeneration is caused by a loss in SC number and/or function. The first part of the proposal focuses on understanding the heterogeneity within the SC pool throughout life, moreover whether subsets of SCs are 'age-resistant. We will use a novel GFP reporter that allows proliferative output to be determined on a cell-by-cell basis in vivo. Slow and fast dividing SCs will be tested for functional diversity.
This aim will answer whether aging is associated with a loss of specific functional subpopulations of SCs. The second part of the proposal focuses on studying the importance of the number of SCs available in the pool for effective repair. We will systematically decrease the number of SCs within adult and aged muscle to ask, 1) whether a decline in SC number causes impaired regeneration, 2) whether forced proliferative demand induced by limiting the number of SCs forces premature SC exhaustion.
This aim will be achieved using novel genetic strategies that enable SC specific cell ablation. The third part of the proposal focuses on the intrinsic capacity of SCs to effectively repair muscle, in particular the role of P16INK4A as a regulator of SC progenitor proliferation and lineage progression during aging. P16INK4A, an aging biomarker, has been implicated in regenerative impairment of aged tissue. The role of P16INK4A in myogenesis has not been studied previously. Finally by combining SC-ablation technology and P16INK4A loss-of-function approaches, the interaction between SC number and function for effective tissue repair will be interrogated. Understanding the coordination between the number and intrinsic capacity of SCs will be critical for treatment of sarcopenia and other muscle degeneration pathologies.
The specific aims of this proposal are: 1) to study heterogeneity in the SC pool as it relates to proliferative output throughout life, 2) to determine if proliferative output is causally related to sarcopenia and 3) to study the effect of genetically manipulating SC function through P16INK4A loss-of-function approaches for efficient muscle repair in young and aged muscle.

Public Health Relevance

Deciphering the coordination between satellite cell number and function during muscle regeneration is critical for harnessing their potential to treat sarcopenia in an increasingly aging population. Furthermore, the biology of adult satellite cells may serve as a paradigm for stem cells in other tissues.

Agency
National Institute of Health (NIH)
Institute
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Type
Research Project (R01)
Project #
1R01AR060868-01A1
Application #
8236048
Study Section
Skeletal Muscle and Exercise Physiology Study Section (SMEP)
Program Officer
Boyce, Amanda T
Project Start
2011-09-21
Project End
2016-07-31
Budget Start
2011-09-21
Budget End
2012-07-31
Support Year
1
Fiscal Year
2011
Total Cost
$353,250
Indirect Cost
Name
Massachusetts General Hospital
Department
Type
DUNS #
073130411
City
Boston
State
MA
Country
United States
Zip Code
02199
Hwang, Ara B; Brack, Andrew S (2018) Muscle Stem Cells and Aging. Curr Top Dev Biol 126:299-322
Brack, Andrew S; Muñoz-Cánoves, Pura (2016) The ins and outs of muscle stem cell aging. Skelet Muscle 6:1
Eliazer, Susan; Brack, Andrew S (2016) Lost in Translation: Preserving Satellite Cell Function with Global Translational Control. Cell Stem Cell 18:5-7
Egerman, Marc A; Cadena, Samuel M; Gilbert, Jason A et al. (2015) GDF11 Increases with Age and Inhibits Skeletal Muscle Regeneration. Cell Metab 22:164-74
Kollu, Swapna; Abou-Khalil, Rana; Shen, Carl et al. (2015) The Spindle Assembly Checkpoint Safeguards Genomic Integrity of Skeletal Muscle Satellite Cells. Stem Cell Reports 4:1061-74
Brack, Andrew S (2014) Pax7 is back. Skelet Muscle 4:24
Chakkalakal, Joe V; Christensen, Josef; Xiang, Wanyi et al. (2014) Early forming label-retaining muscle stem cells require p27kip1 for maintenance of the primitive state. Development 141:1649-59
Jung, Yunjoon; Brack, Andrew S (2014) Cellular mechanisms of somatic stem cell aging. Curr Top Dev Biol 107:405-38
Brack, Andrew S; Hochedlinger, Konrad (2013) ISSCR 2013: back to Bean Town. Stem Cell Reports 1:479-85
Brack, Andrew S (2013) Ageing of the heart reversed by youthful systemic factors! EMBO J 32:2189-90

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