Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/american-medical-association/blood-borne-revitalization-of-the-aged-brain-UjwEtJc9Wy
References (17)
-
F. Loffredo, M. Steinhauser, S. Jay, Joseph Gannon, James Pancoast, Pratyusha Yalamanchi, M. Sinha, C. Dall’Osso, D. Khong, J. Shadrach, Christine Miller, B. Singer, A. Stewart, N. Psychogios, R. Gerszten, Adam Hartigan, Mi‐jeong Kim, T. Serwold, A. Wagers, Richard Lee (2013)
Growth Differentiation Factor 11 Is a Circulating Factor that Reverses Age-Related Cardiac HypertrophyCell, 153
-
Lida Katsimpardi, N. Litterman, Pamela Schein, Christine Miller, F. Loffredo, G. Wojtkiewicz, John Chen, Richard Lee, A. Wagers, L. Rubin (2014)
Vascular and Neurogenic Rejuvenation of the Aging Mouse Brain by Young Systemic FactorsScience, 344
-
S. Villeda, Kristopher Plambeck, J. Middeldorp, Joseph Castellano, Kira Mosher, Jian Luo, Lucas Smith, Gregor Bieri, Karin Lin, D. Berdnik, Rafael Wabl, Joe Udeochu, Elizabeth Wheatley, B. Zou, D. Simmons, X. Xie, F. Longo, T. Wyss-Coray (2014)
Young blood reverses age-related impairments in cognitive function and synaptic plasticity in miceNature Medicine, 20
-
Brice Keyes, J. Segal, Evan Heller, Wen-Hui Lien, Chiung-Ying Chang, Xingyi Guo, D. Oristian, D. Zheng, E. Fuchs (2013)
Nfatc1 orchestrates aging in hair follicle stem cellsProceedings of the National Academy of Sciences, 110
-
J. Ruckh, Jing-Wei Zhao, J. Shadrach, P. Wijngaarden, T. Rao, A. Wagers, R. Franklin (2012)
Rejuvenation of regeneration in the aging central nervous system.Cell stem cell, 10 1
-
G. Baht, David Silkstone, Linda Vi, P. Nadesan, Y. Amani, H. Whetstone, Qingxia Wei, B. Alman (2015)
Exposure to a youthful circulaton rejuvenates bone repair through modulation of β-cateninNature Communications, 6
-
S. Villeda, Jian-Min Luo, Kira Mosher, B. Zou, Markus Britschgi, Gregor Bieri, Trisha Stan, Nina Fainberg, Zhaoqing Ding, A. Eggel, Kurt Lucin, Eva Czirr, J. Park, S. Couillard-Després, L. Aigner, Ge Li, E. Peskind, J. Kaye, J. Quinn, D. Galasko, X. Xie, T. Rando, T. Wyss-Coray (2011)
The ageing systemic milieu negatively regulates neurogenesis and cognitive function -
K. Baruch, A. Deczkowska, Eyal David, Joseph Castellano, Omer Miller, A. Kertser, T. Berkutzki, Z. Barnett-Itzhaki, Dana Bezalel, T. Wyss-Coray, I. Amit, M. Schwartz (2014)
Aging-induced type I interferon response at the choroid plexus negatively affects brain functionScience, 346
-
Clinical Review & Education Clinical Implications of Basic Neuroscience Research Blood-Borne Revitalization of the Aged Brain -
M. Sinha, Young Jang, Juhyun Oh, D. Khong, Elizabeth Wu, R. Manohar, Christine Miller, Samuel Regalado, F. Loffredo, James Pancoast, M. Hirshman, Jessica Lebowitz, J. Shadrach, M. Cerletti, Mi‐jeong Kim, T. Serwold, L. Goodyear, B. Rosner, Richard Lee, A. Wagers (2014)
Restoring Systemic GDF11 Levels Reverses Age-Related Dysfunction in Mouse Skeletal MuscleScience, 344
-
I. Conboy, M. Conboy, A. Wagers, Eric Girma, I. Weissman, T. Rando (2005)
Rejuvenation of aged progenitor cells by exposure to a young systemic environmentNature, 433
-
S. Salpeter, A. Khalaileh, N. Weinberg-Corem, O. Ziv, B. Glaser, Y. Dor (2013)
Systemic regulation of the age-related decline of pancreatic β-cell replication. Diabetes 2013;62:2843–2848Diabetes, 62
-
S. Burke, C. Barnes (2006)
Neural plasticity in the ageing brainNature Reviews Neuroscience, 7
-
M. Egerman, S. Cadena, J. Gilbert, Angelika Meyer, Hallie Nelson, Susanne Swalley, Carolyn Mallozzi, C. Jacobi, L. Jennings, I. Clay, G. Laurent, Shengling Ma, S. Brachat, E. Lach‐Trifilieff, T. Shavlakadze, A. Trendelenburg, A. Brack, D. Glass (2015)
GDF11 Increases with Age and Inhibits Skeletal Muscle Regeneration.Cell metabolism, 22 1
-
J. Aimone, Yan Li, Star Lee, G. Clemenson, Wei Deng, F. Gage (2014)
Regulation and function of adult neurogenesis: from genes to cognition.Physiological reviews, 94 4
-
S. Salpeter, A. Khalaileh, N. Weinberg-Corem, O. Ziv, B. Glaser, Y. Dor (2013)
Systemic Regulation of the Age-Related Decline of Pancreatic β-Cell ReplicationDiabetes, 62
-
A. Brack, M. Conboy, Sudeep Roy, Mark Lee, C. Kuo, C. Keller, T. Rando (2007)
Increased Wnt Signaling During Aging Alters Muscle Stem Cell Fate and Increases FibrosisScience, 317
- Publisher
- American Medical Association
- Copyright
- Copyright 2015 American Medical Association. All Rights Reserved. Applicable FARS/DFARS Restrictions Apply to Government Use.
- ISSN
- 2168-6149
- eISSN
- 2168-6157
- DOI
- 10.1001/jamaneurol.2015.1616
- pmid
- 26237737
- Publisher site
- See Article on Publisher Site
Abstract
In the modern medical era, more diverse and effective treatment options have translated to increased life expectancy. With this increased life span comes increased age-associated disease and the dire need to understand underlying causes so that therapies can be designed to mitigate the burden to health and the economy. Aging exacts a seemingly inevitable multisystem deterioration of function that acts as a risk factor for a variety of age-related disorders, including those that devastate organs of limited regenerative potential, such as the brain. Rather than studying the brain and mechanisms that govern its aging in isolation from other organ systems, an emerging approach is to understand the relatively unappreciated communication that exists between the brain and systemic environment. Revisiting classical methods of experimental physiology in animal models has uncovered surprising regenerative activity in young blood with translational implications for the aging liver, muscle, brain, and other organs. Soluble factors present in young or aged blood are sufficient to improve or impair cognitive function, respectively, suggesting an aging continuum of brain-relevant systemic factors. The age-associated plasma chemokine CCL11 has been shown to impair young brain function while GDF11 has been reported to increase the generation of neurons in aged mice. However, the identities of specific factors mediating memory-enhancing effects of young blood and their mechanisms of action are enigmatic. Here we review brain rejuvenation studies in the broader context of systemic rejuvenation research. We discuss putative mechanisms for blood-borne brain rejuvenation and suggest promising avenues for future research and development of therapies.
Journal
JAMA Neurology – American Medical Association
Published: Oct 1, 2015