Showing posts with label aging. Show all posts
Showing posts with label aging. Show all posts

Tuesday, 20 August 2013

Multiple myeloma: link to gene involved in aging

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Main Category: Genetics
Also Included In: Cancer / Oncology;  Blood / Hematology
Article Date: 19 Aug 2013 - 8:00 PDT Current ratings for:
Multiple myeloma: link to gene involved in aging
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Researchers say that a gene responsible for helping to control the aging process by regulating a "cell's internal clock" may be linked to a type of blood cancer.

Scientists from The Institute of Cancer Research in the UK found a genetic variant called TERC among four new variants that they linked to multiple myeloma - a form of cancer that affects immune cells produced in the bone marrow for circulation in the blood. Their findings are published in the journal Nature Genetics.

The researchers say that this latest discovery takes the number of total genetic variants linked to myeloma to seven, and may help lead to the discovery of genetic causes of the disease.

Myeloma is a relatively uncommon cancer according to the American Cancer Society statistics, with a 1 in 149 risk of developing the disease in the US.

For the study, the research team analyzed the genetic make-up of 4,692 patients who had myeloma, and compared this with DNA of 10,990 people who did not have the blood cancer.

The scientists say that in a previous study they conducted, three genetic variants were discovered in DNA, which was found to increase the risk of myeloma.

The new batch of variants in this most recent study were discovered by combining these samples with other samples collected by researchers in Germany. The researchers add that this produced more data and more statistical accuracy.

From this, the genetic variant TERC was discovered. It works, the scientists explain, by regulating the length of telomere "caps" (protective caps) on the ends of DNA. Over time, these caps erode in healthy cells, causing tissues to age.

But the researchers say that some cancer cells appear to be ignoring the aging trigger and continue to divide. They add that if the link between TERC and myeloma is confirmed, this could lead to new treatments of the blood cancer.

Richard Houlston, professor of molecular and population genetics at The Institute of Cancer Research (ICR), explains: "Our study has taken an important step forward in understanding the genetics of myeloma, and suggested an intriguing potential link with a gene that acts as a cell's internal timer."

Prof. Houlston adds:

"We know cancer often seems to ignore the usual controls over aging and cell death, and it will be fascinating to explore whether in blood cancers, that is a result of a direct genetic link.

Eventually, understanding the complex genetics of blood cancers should allow us to assess a person's risk or identify new avenues for treatment."

Professor Chris Bunce, research director at Leukemia & Lymphoma Research, says this research offers more evidence that the risk of myeloma can be inherited.

"By showing how these specific genes influence the cancer's development, this research could potentially lead to the development of targeted myeloma drugs in the future," adds Prof. Bunce.

"In addition we know that a common condition called MGUS predisposes to the development of myeloma. The identification of additional genetic risk factors in these patients could revolutionize their future management and prospects."

Written by Honor Whiteman

Reference: 'Common variation at 3q26.2, 6p21.33, 17p11.2 and 22q13.1 influences multiple myeloma risk,' Daniel Chubb, Niels Weinhold, Peter Broderick. Letter to Nature Genetics published online 18 August 2013 (doi:10.1038/ng.2733).
Copyright: Medical News Today
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Friday, 16 August 2013

New culprit identified that may make aging brains susceptible to neurodegenerative diseases

Main Category: Neurology / Neuroscience
Also Included In: Seniors / Aging;  Alzheimer's / Dementia;  Parkinson's Disease
Article Date: 15 Aug 2013 - 0:00 PDT Current ratings for:
New culprit identified that may make aging brains susceptible to neurodegenerative diseases
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The steady accumulation of a protein in healthy, aging brains may explain seniors' vulnerability to neurodegenerative disorders, a new study by researchers at the Stanford University School of Medicine reports.

The study's unexpected findings could fundamentally change the way scientists think about neurodegenerative disease.

The pharmaceutical industry has spent billions of dollars on futile clinical trials directed at treating Alzheimer's disease by ridding brains of a substance called amyloid plaque. But the new findings have identified another mechanism, involving an entirely different substance, that may lie at the root not only of Alzheimer's but of many other neurodegenerative disorders - and, perhaps, even the more subtle decline that accompanies normal aging.

The study, published in the Journal of Neuroscience, reveals that with advancing age, a protein called C1q, well-known as a key initiator of immune response, increasingly lodges at contact points connecting nerve cells in the brain to one another. Elevated C1q concentrations at these contact points, or synapses, may render them prone to catastrophic destruction by brain-dwelling immune cells, triggered when a catalytic event such as brain injury, systemic infection or a series of small strokes unleashes a second set of substances on the synapses.

"No other protein has ever been shown to increase nearly so profoundly with normal brain aging," said Ben Barres, MD, PhD, professor and chair of neurobiology and senior author of the study. Examinations of mouse and human brain tissue showed as much as a 300-fold age-related buildup of C1q.

The finding was made possible by the diligence and ingenuity of the study's lead author, Alexander Stephan, PhD, a postdoctoral scholar in Barres' lab. Stephan screened upward of 20,000 antibodies before finding one that binds to C1q and nothing else. (Antibodies are proteins, generated by the immune system, that adhere to specific "biochemical shapes," such as surface features of invading pathogens.)

Comparing brain tissue from mice of varying ages, as well as postmortem samples from a 2-month-old infant and an older person, the researchers showed that these C1q deposits weren't randomly distributed along nerve cells but, rather, were heavily concentrated at synapses. Analyses of brain slices from mice across a range of ages showed that as the animals age, the deposits spread throughout the brain.

"The first regions of the brain to show a dramatic increase in C1q are places like the hippocampus and substantia nigra, the precise brain regions most vulnerable to neurodegenerative diseases like Alzheimer's and Parkinson's disease, respectively," said Barres. Another region affected early on, the piriform cortex, is associated with the sense of smell, whose loss often heralds the onset of neurodegenerative disease.

Other scientists have observed moderate, age-associated increases (on the order of three- or four-fold) in brain levels of the messenger-RNA molecule responsible for transmitting the genetic instructions for manufacturing C1q to the protein-making machinery in cells. Testing for messenger-RNA levels - typically considered reasonable proxies for how much of a particular protein is being produced - is fast, easy and cheap compared with analyzing proteins.

But in this study, Barres and his colleagues used biochemical measures of the protein itself. "The 300-fold rise in C1q levels we saw in 2-year-old mice p equivalent to 70- or 80-year-old humans p knocked my socks off," Barres said. "I was not expecting that at all."

C1q is the first batter on a 20-member team of immune-response-triggering proteins, collectively called the complement system. C1q is capable of clinging to the surface of foreign bodies such as bacteria or to bits of our own dead or dying cells. This initiates a molecular chain reaction known as the complement cascade. One by one, the system's other proteins glom on, coating the offending cell or piece of debris. This in turn draws the attention of omnivorous immune cells that gobble up the target.

The brain has its own set of immune cells, called microglia, which can secrete C1q. Still other brain cells, called astrocytes, secrete all of C1q's complement-system "teammates." The two cell types work analogously to the two tubes of an Epoxy kit, in which one tube contains the resin, the other a catalyst.

Previous work in Barres' lab has shown that the complement cascade plays a critical role in the developing brain. A young brain generates an excess of synapses, creating a huge range of options for the potential formation of new neural circuits. These synapses strengthen or weaken over time, in response to their heavy use or neglect. The presence of feckless connections contributes noise to the system, so the efficiency of the maturing brain's architecture is improved if these underused synapses are pruned away.

In a 2007 paper in Cell, Barres' group reported that the complement system is essential to synaptic pruning in normal, developing brains. Then in 2012, in Neuron, in a collaboration with the lab of Harvard neuroscientist Beth Stevens, PhD, they showed that it is specifically microglia - the brain's in-house immune cells - that attack and ingest complement-coated synapses.

Barres now believes something similar is happening in the normal, aging brain. C1q, but not the other protein components of the complement system, gradually becomes highly prevalent at synapses. By itself, this C1q buildup doesn't trigger wholesale synapse loss, the researchers found - although it does seem to impair their performance. Old mice whose capacity to produce C1q had been eliminated performed subtly better on memory and learning tests than normal older mice did.

Still, this leaves the aging brain's synapses precariously perched on the brink of catastrophe. A subsequent event such as brain trauma, a bad case of pneumonia or perhaps a series of tiny strokes that some older people experience could incite astrocytes - the second tube in the Epoxy kit - to start secreting the other complement-system proteins required for synapse destruction.

Most cells in the body have their own complement-inhibiting agents. This prevents the wholesale loss of healthy tissue during an immune attack on invading pathogens or debris from dead tissue during wound healing. But nerve cells lack their own supply of complement inhibitors. So, when astrocytes get activated, their ensuing release of C1q's teammates may set off a synapse-destroying rampage that spreads "like a fire burning through the brain," Barres said.

"Our findings may well explain the long-mysterious vulnerability specifically of the aging brain to neurodegenerative disease," he said. "Kids don't get Alzheimer's or Parkinson's. Profound activation of the complement cascade, associated with massive synapse loss, is the cardinal feature of Alzheimer's disease and many other neurodegenerative disorders. People have thought this was because synapse loss triggers inflammation. But our findings here suggest that activation of the complement cascade is driving synapse loss, not the other way around."

In 2011, Barres co-founded a company, Annexon, to develop drugs that inhibit the complement cascade to treat Alzheimer's, glaucoma, Parkinson's, stroke, multiple sclerosis and several other neurodegenerative diseases characterized by massive synapse loss. Annexon has licensed multiple associated patent applications from Stanford, which filed them.

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our neurology / neuroscience section for the latest news on this subject.

The study was funded by the Ellison Medical Foundation and the National Institute of Drug Addiction (grant DA15403).

Other Stanford co-authors of the study were Daniel Madison, PhD, associate professor of molecular and cellular physiology; Mehrdad Shamloo, PhD, associate professor of comparative medicine; postdoctoral scholars Laurence Coutellier, PhD, and Jose Maria Mateos, PhD; research associate Emilie Lovelett; and graduate student Dominic Berns.

Stanford University Medical Center

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Thursday, 1 August 2013

Premature aging of immune cells present in joints of kids with chronic arthritis, Pitt/Children's Hospital team says

Main Category: Arthritis / Rheumatology
Also Included In: Immune System / Vaccines;  Pediatrics / Children's Health;  Seniors / Aging
Article Date: 31 Jul 2013 - 1:00 PDT Current ratings for:
Premature aging of immune cells present in joints of kids with chronic arthritis, Pitt/Children's Hospital team says
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The joints of children with the most common form of chronic inflammatory arthritis contain immune cells that resemble those of 90-year-olds, according to a new study led by researchers at Children's Hospital of Pittsburgh of UPMC and the University of Pittsburgh School of Medicine. The findings, published in the August issue of Arthritis and Rheumatism, suggest that innovative treatment approaches could aim to prevent premature aging of immune cells.

Juvenile idiopathic arthritis, or JIA, is the most prevalent rheumatic condition in the world and affects one of every 1,000 children in the U.S., said senior researcher Abbe de Vallejo, Ph.D., associate professor of pediatrics and immunology, Pitt School of Medicine. It usually starts with a swollen ankle, knee or wrist that parents often assume is due to a minor injury sustained while playing.

"Untreated JIA has devastating consequences," Dr. de Vallejo said. "It can slow growth and, in extreme cases, the child can be physically disfigured. It's a degenerative disease that eats up the joints."

Doctors have long thought of JIA as an autoimmune disease, meaning the body attacks itself. But previous studies by Dr. de Vallejo of young adults with rheumatoid arthritis indicated that a certain population of cells present in the joint synovial fluid and blood displayed telltale signs of abnormal cell division and premature aging. His current team at Children's wanted to see if that was true in pediatric arthritis.

They examined immune cells called T-cells in the synovial fluid and blood from 98 children ages 1 to 17 and known to have JIA, as well as 46 blood samples from children who didn't have the disease. T-cells are the army of immune cells that eradicate infection, tumors and other dangerous agents to which people may be exposed.

The research team found about one-third of the T-cells of children with JIA had shortened telomeres and had reduced, or in some cases lost, the capacity to proliferate. Telomeres are the ends of chromosomes that don't code for proteins and, because they are not fully copied by enzyme mechanisms, are trimmed slightly during each DNA replication cycle. It is thought that aging occurs when the telomeres become too short for DNA replication and cell division to proceed normally.

"The T-cells of the children with JIA had very short telomeres, about the length we see in a 90-year-old or a young adult with rheumatoid arthritis. Those same T-cells express unusually high levels of several classic protein markers of cell aging and exhaustion," Dr. de Vallejo said. "These kids haven't lived long enough to have cells that look that old. This is the first indication that premature aging in occurring in this childhood condition."

In addition, the T-cells had become dysregulated, and their immune activity could be stimulated through atypical cell surface receptors. Much more must be learned about the unusual cells and about genetic mechanisms that might contribute to the development of JIA, Dr. de Vallejo said, but these findings could point the way to new therapies.

"JIA is typically treated with broad-spectrum drugs such as steroids and biologics that essentially paralyze the entire immune system, but only a third of the cells are affected and their abnormality seems to be premature aging, rather than autoimmune activity," he noted. "This study suggests cell-targeted treatments could be developed to prevent this premature immune aging."

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our arthritis / rheumatology section for the latest news on this subject.

Co-authors of the paper include other researchers from Children’s Hospital of Pittsburgh of UPMC; Pitt School of Medicine; and the Mayo Clinic. The project was funded by the Nancy E. Taylor Foundation for Chronic Diseases, the Arthritis Foundation, and National Institutes of Health grant AR052282.

Children’s Hospital of Pittsburgh of UPMC & University of Pittsburgh Schools of the Health Sciences

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'Premature aging of immune cells present in joints of kids with chronic arthritis, Pitt/Children's Hospital team says'

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Premature aging of immune cells present in joints of kids with chronic arthritis, Pitt/Children's Hospital team says

Main Category: Arthritis / Rheumatology
Also Included In: Immune System / Vaccines;  Pediatrics / Children's Health;  Seniors / Aging
Article Date: 31 Jul 2013 - 1:00 PDT Current ratings for:
Premature aging of immune cells present in joints of kids with chronic arthritis, Pitt/Children's Hospital team says
not yet ratednot yet rated

The joints of children with the most common form of chronic inflammatory arthritis contain immune cells that resemble those of 90-year-olds, according to a new study led by researchers at Children's Hospital of Pittsburgh of UPMC and the University of Pittsburgh School of Medicine. The findings, published in the August issue of Arthritis and Rheumatism, suggest that innovative treatment approaches could aim to prevent premature aging of immune cells.

Juvenile idiopathic arthritis, or JIA, is the most prevalent rheumatic condition in the world and affects one of every 1,000 children in the U.S., said senior researcher Abbe de Vallejo, Ph.D., associate professor of pediatrics and immunology, Pitt School of Medicine. It usually starts with a swollen ankle, knee or wrist that parents often assume is due to a minor injury sustained while playing.

"Untreated JIA has devastating consequences," Dr. de Vallejo said. "It can slow growth and, in extreme cases, the child can be physically disfigured. It's a degenerative disease that eats up the joints."

Doctors have long thought of JIA as an autoimmune disease, meaning the body attacks itself. But previous studies by Dr. de Vallejo of young adults with rheumatoid arthritis indicated that a certain population of cells present in the joint synovial fluid and blood displayed telltale signs of abnormal cell division and premature aging. His current team at Children's wanted to see if that was true in pediatric arthritis.

They examined immune cells called T-cells in the synovial fluid and blood from 98 children ages 1 to 17 and known to have JIA, as well as 46 blood samples from children who didn't have the disease. T-cells are the army of immune cells that eradicate infection, tumors and other dangerous agents to which people may be exposed.

The research team found about one-third of the T-cells of children with JIA had shortened telomeres and had reduced, or in some cases lost, the capacity to proliferate. Telomeres are the ends of chromosomes that don't code for proteins and, because they are not fully copied by enzyme mechanisms, are trimmed slightly during each DNA replication cycle. It is thought that aging occurs when the telomeres become too short for DNA replication and cell division to proceed normally.

"The T-cells of the children with JIA had very short telomeres, about the length we see in a 90-year-old or a young adult with rheumatoid arthritis. Those same T-cells express unusually high levels of several classic protein markers of cell aging and exhaustion," Dr. de Vallejo said. "These kids haven't lived long enough to have cells that look that old. This is the first indication that premature aging in occurring in this childhood condition."

In addition, the T-cells had become dysregulated, and their immune activity could be stimulated through atypical cell surface receptors. Much more must be learned about the unusual cells and about genetic mechanisms that might contribute to the development of JIA, Dr. de Vallejo said, but these findings could point the way to new therapies.

"JIA is typically treated with broad-spectrum drugs such as steroids and biologics that essentially paralyze the entire immune system, but only a third of the cells are affected and their abnormality seems to be premature aging, rather than autoimmune activity," he noted. "This study suggests cell-targeted treatments could be developed to prevent this premature immune aging."

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
Visit our arthritis / rheumatology section for the latest news on this subject.

Co-authors of the paper include other researchers from Children’s Hospital of Pittsburgh of UPMC; Pitt School of Medicine; and the Mayo Clinic. The project was funded by the Nancy E. Taylor Foundation for Chronic Diseases, the Arthritis Foundation, and National Institutes of Health grant AR052282.

Children’s Hospital of Pittsburgh of UPMC & University of Pittsburgh Schools of the Health Sciences

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University of Pittsburgh Medical Center. "Premature aging of immune cells present in joints of kids with chronic arthritis, Pitt/Children's Hospital team says." Medical News Today. MediLexicon, Intl., 31 Jul. 2013. Web.
31 Jul. 2013. APA
University of Pittsburgh Medical Center. (2013, July 31). "Premature aging of immune cells present in joints of kids with chronic arthritis, Pitt/Children's Hospital team says." Medical News Today. Retrieved from
http://www.medicalnewstoday.com/releases/264123.php.

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'Premature aging of immune cells present in joints of kids with chronic arthritis, Pitt/Children's Hospital team says'

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Monday, 29 July 2013

Rapamycin showed limited effects on aging in older mice

Main Category: Seniors / Aging
Article Date: 29 Jul 2013 - 0:00 PDT Current ratings for:
Rapamycin showed limited effects on aging in older mice
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The immunosuppressive drug rapamycin has been shown to increase longevity in mice even when treatment begins at an advanced age. It is unclear if the extension of life also correlates with prolonged health and vigor.

In the current issue of the Journal of Clinical Investigation, Dan Ehninger and colleagues at the German Center for Neurodegenrative Diseases evaluated age-associated characteristics in mice treated with rapamycin. They found that rapamycin improved memory and spatial learning, reduced thyroid follicle size, and reduced body fat in older mice. However, many of these same attributes were also improved in young mice treated with the drug, indicating an age-independent drug effect.

The prevalence of cancer, a common cause of mouse mortality, was also decreased in older treated mice. The authors did find that rapamycin treatment had no effect on several age related symptoms, including cardiovascular and liver function, loss of muscle mass, strength retention, or balance.

These data suggest that rapamycin treatment may increase lifespan through reduction of cancer rates, and the drug may be useful for relief of some age related conditions.

In the accompanying commentary, Arlan Richards of the University of Texas Health Science Center at San Antonio suggests that clinical trials to study the effect of rapamycin on age related neurodegenerative diseases of the elderly such as Alzheimer's disease should be considered.

Article adapted by Medical News Today from original press release. Click 'references' tab above for source.
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Please send any medical news or health news press releases to:

Note: Any medical information published on this website is not intended as a substitute for informed medical advice and you should not take any action before consulting with a health care professional. For more information, please read our terms and conditions.



View the original article here