Press Releases

April 2012

RCDC-supported investigator Dr. George Wang’s important findings on persistent CMV infection published in the journal Science Translational Medicine

Persistent cytomegalovirus (CMV) infection causes severe disease in immunocompromised patients and has been hypothesized to drive the development of a pool of ineffective, senescent T cells in some older adults. A diverse T cell receptor (TCR) repertoire capable of recognizing a broad range of antigenic peptides is thought to be central to effective CMV and other pathogen-specific immunity. Although many hypotheses related to TCR diversity and the ability to control persistent infections such as CMV in older adults have been proposed, the methodology necessary to accurately characterize TCR diversity has not been readily available.

In an article published in Science Translational Medicine last week, JHU OAIC RCDC supported investigator Dr. George Wang and his colleagues reported the development and utilization of a novel single-cell strategy for the clonotypic analysis of TCRαβ repertoires to probe the diversity and magnitude of human CMV–specific CD8+ T cells. Using this technology, they discovered that CD8+ TCRαβ repertoire diversity, but not the size of the CD8+ T cell response, was inversely related to circulating CMV-specific antibody levels, found to be higher in older adults with detectable (versus undetectable) CMV viral loads.  CMV-specific antibody levels have previously been linked with frailty and differential mortality risks.

Overall, these findings indicate that CD8+ T cell diversity may be more important than T cell abundance in limiting the negative consequences of CMV persistence and suggest that a highly diverse TCRαβ repertoire may be an important benchmark and target in the success of immunotherapeutic strategies for CMV and for many other common infections that may affect older adults.

On the web: http://www.ncbi.nlm.nih.gov/pubmed/22491952 and http://stm.sciencemag.org/content/4/128/128ra42.editor-summary 

September 2011

Johns Hopkins OAIC-supported investigator, Dr. Peter Abadir,  led the effort to identify a novel and fully functional mitochondrial angiotensin system that declines with age as described in the August 18^th issue of the Proceedings of the National Academy of Sciences (PNAS).  Importantly,  this research team also found that this mitochondrial  system can be upregulated with losartan in older animals.  These findings  may help to explain the biology that underlies the protection of aging skeletal muscle from disuse atrophy and scarring after injury by losartan as described in a May, 2011 Science Translational Medicine article by another Hopkins OAIC supported research team.

Please see below for links to the Abadir et al PNAS article,  and the Johns Hopkins Press Release: 
Full article: http://www.pnas.org/content/108/36/14849.long
Press Release: http://www.hopkinsmedicine.org/news/media/releases/switch_in_cells_power_plant_declines_with_age_rejuvenated_by_drug

Please note a link to the article will also be posted on the OAIC National website, under the Hot Findings link.

May 2011

OAIC-supported investigators, Ronald Cohn and Tyesha Burks, discover losartan protects against loss of old or damaged muscle.  Please click here for access to the full article.

The official press release is available here (text reprinted below): http://newswise.com/articles/blood-pressure-drug-shows-some-muscle

Blood Pressure Drug Shows Some Muscle

Released: 5/10/2011 12:20 PM EDT
Embargo expired: 5/11/2011 2:00 PM EDT
Source: Johns Hopkins Medicine

Johns Hopkins researchers discover losartan protects against loss of old or damaged muscle

Using geriatric mice, a Johns Hopkins research team has shown that losartan, a commonly used blood pressure drug,  not only improves regeneration of injured muscle but also protects against its wasting away from inactivity.

A report on the old drug's new role, which is prompting preparations for a clinical trial of losartan in older adults, appears online May 11 in the journal Science Translational Medicine.

"The goal of the investigation was to find a way to prevent a bad situation from getting worse in the case of old muscle that's injured or not used," says Ronald Cohn, M.D., an assistant professor of pediatrics and neurology in the McKusick-Nathans Institute of Genetic Medicine, Johns Hopkins University School of Medicine. "As pleased as we were to see that losartan therapy in mice had a positive effect on muscle regeneration, we were most surprised and excited by its striking prevention of disuse atrophy."

Previous studies by other groups have shown that aging in humans causes the activity of a protein secreted by cells - called transforming growth factor beta (TGF-b) - to increase, and that more TGF-b translates into less muscle repair. In addition, studies in mouse models of Marfan Syndrome and muscular dystrophy - both of which involve disorders of muscle and connective tissue - revealed that losartan promotes muscle regeneration by blocking a particular protein receptor (angiotensin II type 1) and ultimately tamping down the activity of TGF-b.

To investigate losartan's role in muscle injury regeneration in the context of aging, the Hopkins team worked with 40 mice which, at 21-months old, were considered geriatric. After treating half of those animals for a week to water laced with losartan, they injected a chemical toxin into all the animals' shin muscles. The researchers examined the stained muscle tissue under a microscope at four days and again at 19 days, looking for signs of regeneration: small fibers with larger-than-usual nuclei. After four days, they saw no difference in the number of regenerating fibers between the losartan-treated mice and those not treated. However, after 19 days, the losartan-treated mice had about 10 to 15 percent of scar tissue formation compared with 30 to 40 percent of scar tissue formation in those not treated.   

Next, the researchers conducted disuse experiments to find out if losartan, in addition to improving muscle regeneration, might have even broader clinical applications in the protection against immobilization atrophy.

Again, using 21-month-old mice, half treated with losartan and half not, the team this time clipped the hind right foot of the mice to their knees, immobilizing just the shin muscles; otherwise, the mice were normally active.

After 21 days, the animals' shin muscles were weighed and compared under a microscope. The animals not treated with losartan lost 20 percent of the mass of their immobilized shin muscles.  However, the losartan-treated animals lost virtually no mass, according to Tyesha Burks, a graduate student of Human Genetics, Johns Hopkins University School of Medicine.

"When we saw that the loss of muscle fibers was completely prevented by losartan therapy, it was quite mind-blowing," Cohn says. 

The muscles of non-hibernating species such as mice and humans invariably shrink from inactivity, whether from injury, illness or a sedentary lifestyle. The response to immobilization is particularly exaggerated with age, says Cohn, whose ongoing investigations probe the molecular mechanisms of muscle maintenance and regeneration in humans, mice and hibernating ground squirrels.

Muscle loss and weakness during aging - a condition known as sarcopenia - hasn't been aggressively addressed by researchers and clinicians the way bone loss has. There are tests and drugs for osteoporosis, but muscle deterioration is difficult to measure and its effects can be subtle, according to Jeremy D. Walston, M.D. Raymond and Anna Lublin Professor of Geriatric Medicine, Johns Hopkins University School of Medicine. While thinned bones fracture, muscles shrivel and then contribute to weakness and fatigue, which in turn may contribute to falls, injuries and the development of disability and frailty.

"Sarcopenia is an important issue in geriatric medicine and getting more critical as increasing numbers of people age into their 70s, 80s and beyond, Walston says. "These findings support the need for further investigation of losartan in sarcopenia and other muscle-related conditions in older adults. In fact, translational studies are under development within the Johns Hopkins Older Americans Independence Center.   

Support for this research came from Johns Hopkins Claude D. Pepper Older Americans Independence Center, the National Institute on Aging and the National Institutes of Health.

Authors of the paper, in addition to Cohn, are Tyesha N. Burks, Eva Andres-Mateos, Ruth Marx, Rebeca Mejias, Christel Van Erp, Jessica L. Simmers, and Jeremy D. Walston, all of Johns Hopkins. Christopher W. Ward of the University of Maryland is also an author.

On the Web:
Cohn lab: http://www.hopkinsmedicine.org/geneticmedicine/People/Faculty/Cohn.html
Science Translational Medicine: http://stm.sciencemag.org/
Hopkins Medicine magazine story about Cohn: http://www.hopkinsmedicine.org/hmn/w10/feature1.cfm