Tag: cells
Researchers Reduce Inflammation In Human Cells, A Major Cause Of Frailty

Researchers Reduce Inflammation In Human Cells, A Major Cause Of Frailty

From Mayo Clinic News Network, Mayo Clinic News Network (TNS)

ROCHESTER, Minn. — Chronic inflammation, closely associated with frailty and age-related diseases, is a hallmark of aging. Mayo Clinic researchers have discovered that inhibiting key enzyme pathways reduces inflammation in human cells in culture dishes and decreases inflammation and frailty in aged mice.

The results appear in Proceedings of the National Academy of Sciences of the United States of America. While further studies are needed, researchers are hopeful that these findings will be a step toward treatments for frailty and other age-related chronic conditions.

In the study, researchers found that Janus kinase (JAK) inhibitors, drugs that work to block activity of JAK enzymes, decreased the factors released by human senescent cells in culture dishes. Senescent cells are cells that contribute to frailty and diseases associated with aging. Also, these same JAK inhibitors reduced inflammatory mediators in mice. Researchers examined aged mice, equivalent to 90-year-old people, before and after JAK inhibitors. Over the course of two months, the researchers found substantial improvement in the physical function of the aged mice, including grip strength, endurance and physical activity.

“One of the things we want to do is find some kind of treatment for this other than prescribing better wheelchairs or walkers, or other kinds of things that we are stuck with now that are Band-Aid solutions,” says Dr. James Kirkland, director of the Mayo Clinic Robert and Arlene Kogod Center on Aging and senior author of the study. A clinical geriatrician, Dr. Kirkland says he sees frailty in many of his elderly patients and that it’s often associated with poor outcomes and functional disability.

“Our goal is not necessarily to increase life span, and certainly not life span at all costs. Our goal is to enhance health span — the period during life when people are independent,” explains Dr. Kirkland. “This drug approach and others we are developing look like they might hold some promise in reaching that goal.”

©2015 Mayo Foundation for Medical Education and Research. Distributed by Tribune Content Agency, LLC

Photo: Mayo Clinic researchers have discovered that inhibiting key enzyme pathways reduces inflammation in human cells in culture dishes and decreases inflammation and frailty in aged mice. Researchers are hopeful that these findings will be a step toward treatments for frailty and other age-related chronic conditions. (Georg Drexel/Peter Atkins/Fotolia/TNS)

Paul Allen Gives $100 Million To Explore How Cells Work

Paul Allen Gives $100 Million To Explore How Cells Work

By Sandi Doughton, The Seattle Times (TNS)

SEATTLE — After tackling the brain, the Ebola epidemic, and a host of other issues, billionaire Paul Allen has a new target for scientific philanthropy: unraveling the inner workings of human cells.

On Monday, the Microsoft co-founder announced a $100 million, five-year grant to establish the Allen Institute for Cell Science in Seattle.

The goal is to better understand the teeming world inside cells, where thousands of organelles and millions of molecules interact in a dynamic ballet that researchers are just beginning to fathom.

“We really don’t have a good idea of how normal cells work, and what goes wrong in disease,” said Rick Horwitz, the former University of Virginia professor who jumped at the chance to lead the new institute. “People spend careers trying to understand little parts of the cell, but nobody has stitched it together — because it’s too complicated for any individual to study.”

The institute will take on the challenge by combining new technologies, like microscopes that can visualize living cells in three dimensions, with enough computational firepower to make sense of the flood of data that will result, Horwitz said.

Eventually, he and his team hope to develop computer models that mimic living cells. If they succeed, those models could also shed light on what goes haywire in cancer and other diseases and help develop cures, he said.

At a time when federal research budgets are shrinking, the announcement is “one of the most exciting things to happen in Seattle science in a long time,” said Dr. Chuck Murry, co-director of the Institute for Stem Cell and Regenerative Medicine at the University of Washington. “When the Allen folks get into something, they do it at a scale that’s just mind-blowing.”

The grant is one of Allen’s largest, on par with the $100 million he committed earlier this year to fight Ebola in West Africa, and a $100 million grant in 2003 to establish the Seattle-based Allen Institute for Brain Science. He has since plowed an additional $300 million into the brain institute.

Allen, who joined his old partner Bill Gates in pledging to donate the bulk of his wealth, has stepped up his philanthropic efforts in recent years. It’s a good bet he will continue investing in the cell institute — as long as it measures up, said Allan Jones, who leads the Allen Institute for Brain Science and helped organize its new sister institute.

“We need to knuckle down and show that we can deliver something very powerful,” Jones said.

Diagrams in biology textbooks make it seem like cell structure and function have already been nailed down. Scientists have, indeed, learned a lot about different cell types, the role of organelles like the nucleus, and specific pathways, like the chain of events that causes muscle cells to contract. But there’s a big gap when it comes to understanding the way cells function as a whole.

For example, researchers tried for years to coax breast tissue cells growing in petri dishes to produce milk proteins with no success. What finally worked was growing the cells on a pliable matrix, more like their natural habitat.

“All these nuances are really important,” Horwitz said.

One reason it has proved so difficult to translate genetic discoveries into treatments is that scientists have only a fuzzy idea of the way gene mutations upset the normal cellular machinery.

Applied on a large scale, super-resolution microscopy along with techniques to precisely tweak DNA and tag molecules with fluorescent dyes will allow researchers at the institute to track what’s happening inside normal cells and see what changes when mutations are introduced, Horwitz said.

The result will be like Google Maps for cells, he added. “Our output will be a kind of visual, dynamic atlas that shows where all of these things are in the cell and how they change over time.”

The first project will focus on the way stem cells derived from adult tissue transform themselves into multiple cell types, including heart muscle and skin.

Understanding that process in more detail will be of great value in the effort to harness stem cells to repair damaged organs ,said Jennifer Lippincott-Schwartz, president of the American Society of Cell Biology.

Horwitz and Jones unveiled plans for the institute Monday at the society’s annual meeting in Philadelphia.

“We’re all very excited about this initiative,” Lippincott-Schwartz said.

With its dedicated mission, the cell institute will be able to bring together experts in cell biology, computational modeling and microscopy in a way that’s tough to do at a university, said Joan Brugge, chair of the Department of Cell Biology at Harvard Medical School.

“You need a really coordinated effort,” said Brugge, who serves on the institute’s science advisory board. “It’s very difficult for the federal funding agencies to fund these kind of Manhattan Project-style initiatives, because they are so large.”

Just as at the Allen Institute for Brain Science, all of the data and tools developed at the cell institute will be freely available to scientists around the world.

The two institutes will be housed together in a new, seven-story lab building under construction in the South Lake Union neighborhood.

The cell institute will employ about 75 scientists, technicians and other staff, Horwitz estimated.

Photo via Wikimedia Commons