Potential for ALS treatment found in three #proteins

Potential for ALS treatment found in three proteins http://news360.com/article/284360340

Where ALS comes from and how it progresses are mysteries that continue to vex medical science. But recent research at Sweden's KTH Royal Institute of Technology has found three proteins that could shed some light on the mechanisms behind this deadly disease.

Anna Häggmark, a researcher in affinity proteomics at KTH and Science for Life Laboratory, says the three proteins were identified in what is one of the most extensive plasma profiling studies performed in this field of research.

In the search for treatments and earlier diagnoses of ALS, scientists are focused on biomarkers, or biological characteristics that reflect a physiological change in the body during or after an illness. A typical example of a biomarker is troponin, which is secreted into the blood when a heart muscle is damaged following a heart attack.

"This is a really nice clue," Häggmark says. "The three proteins we have found seem to represent different aspects of this disease's pathogenesis. After further evaluation of their role within ALS, they can perhaps help to support diagnostics or even serve as a drug targets for those stricken with the disease."

There are currently no reliable markers for ALS, or amyotrophic lateral sclerosis, a progressive neurodegenerative disease that destroys the nerve cells that control muscle movement, causing muscles to become weak and then paralyzed. ALS affects all skeletal muscles, including those used for breathing and swallowing.

Häggmark explains that one protein, NEFM, is a structural component of neurons in the central and peripheral nervous system. If found in blood plasma, it could indicate nerve fiber death as a result of ALS.

RGS18, on the other hand, is a cell signaling protein. The increase of this protein may reflect its leakage from the degenerated muscles in these patients, the study states.

The third protein, SLC25A20, is a mitochondrial protein thereby representing a cellular structure that that has previously been shown as linked to ALS.

The team's partners at the Medical University of Warsaw provided plasma samples from 367 Polish ALS patients and 101 controls. The initial protein profiles were obtained by using 352 antibodies from the Human Protein Atlas, targeting 278 proteins.

"As far as we know it's the most extensive plasma profiling study published within ALS, in terms of numbers of patients included," Häggmark says.

The researchers will work further with the verification of their results, using an expanded collection of plasma samples from Sweden, Poland and Germany as well as cerebrospinal fluid from ALS patients. "We'll look at these proteins in additional sample materials and see if we can confirm our findings," she says.

Häggmark says the ongoing study will include examining "disease specificity" of the markers, that is, whether what they find in ALS is also relevant for other neurological degenerative diseases, such as multiple sclerosis.

Journal Reference:

  •  Anna Häggmark, Maria Mikus, Atefeh Mohsenchian, Mun-Gwan Hong, Björn Forsström, Beata Gajewska, Anna Barańczyk-Kuźma, Mathias Uhlén, Jochen M. Schwenk, Magdalena Kuźma-Kozakiewicz, Peter Nilsson. Plasma profiling reveals three proteins associated to amyotrophic lateral sclerosis. Annals of Clinical and Translational Neurology, 2014; 1 (8): 544 DOI: 10.1002/acn3.83

Scientists discover how to change human leukemia cells into harmless immune cells

Scientists discover how to change human leukemia cells into harmless immune cells http://news360.com/article/284355310

SOURCE: Stanford Medicine

Researchers at the Stanford University School of Medicine have discovered that when a certain aggressive leukemia is causing havoc in the body, the solution may be to force the cancer cells to grow up and behave.

After a chance observation in the lab, the researchers found a method that can cause dangerous leukemia cells to mature into harmless immune cells known as macrophages.

The findings are described in a paper that published online March 16 in the Proceedings of the National Academy of Sciences.

B-cell acute lymphoblastic leukemia with a mutation called the Philadelphia chromosome is a particularly aggressive cancer with poor outcomes, said Ravi Majeti, MD, PhD, an assistant professor of medicine and senior author of the paper. So finding potential treatments is particularly exciting.

Majeti and his colleagues made the key observation after collecting leukemia cells from a patient and trying to keep the cells alive in a culture plate. "We were throwing everything at them to help them survive," said Majeti, who is also a member of the Stanford Cancer Institute and the Stanford Institute for Stem Cell Biology and Regenerative Medicine.
An unusual metamorphosis

Postdoctoral scholar Scott McClellan, MD, PhD, a lead author of the paper, mentioned that some of the cancer cells in culture were changing shape and size into what looked like macrophages. Majeti concurred with that observation, but the reasons for the changed cells were a mystery until he remembered an old research paper, which showed that early B-cell mouse progenitor cells could be forced to become macrophages when exposed to certain transcription factors - proteins that bind to certain DNA sequences.

"B-cell leukemia cells are in many ways progenitor cells that are forced to stay in an immature state," Majeti said. So he, McClellan and student Christopher Dove, an MD/PhD student and the paper's other lead author, did more experiments and confirmed that methods shown to have altered the fate of the mouse progenitor cells years ago could be used to transform these human cancer cells into macrophages, which can engulf and digest cancer cells and pathogens.

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