Posts tagged oxidative stress

Neuropathic pain — pain that results from a malfunction in the nervous system — is a daily reality for millions of Americans. Unlike normal pain, it doesn’t go away after the stimulus that provoked it ends, and it also behaves in a variety of other unusual and disturbing ways. Someone suffering from neuropathic pain might experience intense discomfort from a light touch, for example, or feel as though he or she were freezing in response to a slight change in temperature.

A major part of the answer to the problem of neuropathic pain, scientists believe, is found in spinal nerve cells that release a signaling chemical known as GABA. These GABA neurons act as a sort of brake on pain impulses; it’s thought that when they die or are disabled the pain system goes out of control. If GABA neurons could be kept alive and healthy after peripheral nerve or tissue injury, it’s possible that neuropathic pain could be averted.

Now, University of Texas Medical Branch at Galveston researchers have found a way to, at least partially, accomplish this objective. The key, they determined, is stemming the biochemical assault by reactive oxygen species that are generated in the wake of nerve injury.

"GABA neurons are particularly susceptible to oxidative stress, and we hypothesized that reactive oxygen species contribute to neuropathic sensitization by promoting the loss of GABA neurons as well as hindering GABA functions," said UTMB professor Jin Mo Chung, senior author of a paper on the research now online in the journal Pain.

To test this hypothesis — and determine whether GABA neurons could be saved — the researchers conducted a series of experiments in mice that had been surgically altered to simulate the conditions of neuropathic pain. In one key experiment, mice treated with an antioxidant compound for a week after surgery were compared with untreated mice. The antioxidant mice showed less pain-associated behavior and were found to have far more GABA neurons than the untreated mice.

"So by giving the antioxidant we lowered the pain behavior, and when we look at the spinal cords we see the GABA neuron population is almost the same as normal," Chung said. "That suggested we prevented those neurons from dying, which is a big thing."

One complication, Chung noted, is a “moderate quantitative mismatch” between the behavioral data and the GABA-neuron counts. While the anti-oxidant mice displayed less pain behavior, their behavioral improvement wasn’t as substantial as their high number of GABA neurons would suggest. One possibility is that the surviving neurons were somehow impaired — a hypothesis supported by electrophysiological data.

Although no clinical trials are planned in the immediate future, Chung believes anti-oxidants have great potential as a treatment for neuropathic pain. “If this is true and it works in humans — well, any time you can salvage neurons, it’s a good thing,” he said. “Neuropathic pain is very difficult to treat, and I think this is a possibility, a good possibility.”

(Source: eurekalert.org)

Biologists at The Scripps Research Institute (TSRI) have made a significant discovery that could lead to a new therapeutic strategy for Parkinson’s disease.

The findings, recently published online ahead of print in the journal Molecular and Cell Biology, focus on an enzyme known as parkin, whose absence causes an early-onset form of Parkinson’s disease. Precisely how the loss of this enzyme leads to the deaths of neurons has been unclear. But the TSRI researchers showed that parkin’s loss sharply reduces the level of another protein that normally helps protect neurons from stress.

“We now have a good model for how parkin loss can lead to the deaths of neurons under stress,” said TSRI Professor Steven I. Reed, who was senior author of the new study. “This also suggests a therapeutic strategy that might work against Parkinson’s and other neurodegenerative diseases.”

Genetic Clues

Parkinson’s is the world’s second-most common neurodegenerative disease, affecting about one million people in the United States alone. The disease is usually diagnosed after the appearance of the characteristic motor symptoms, which include tremor, muscle rigidity and slowness of movements. These symptoms are caused by the loss of neurons in the substantia nigra, a brain region that normally supplies the neurotransmitter dopamine to other regions that regulate muscle movements.

Most cases of Parkinson’s are considered “sporadic” and are thought to be caused by a variable mix of factors including advanced age, subtle genetic influences, chronic neuroinflammation and exposure to pesticides and other toxins. But between 5 and 15 percent of cases arise specifically from inherited gene mutations. Among these, mutations to the parkin gene are relatively common. Patients who have no functional parkin gene typically develop Parkinson’s-like symptoms before age 40.

Parkin belongs to a family of enzymes called ubiquitin ligases, whose main function is to regulate the levels of other proteins. They do so principally by “tagging” their protein targets with ubiquitin molecules, thus marking them for disposal by roving protein-breakers in cells known as proteasomes. Because parkin is a ubiquitin ligase, researchers have assumed that its absence allows some other protein or proteins to evade proteasomal destruction and thus accumulate abnormally and harm neurons. But since 1998, when parkin mutations were first identified as a cause of early-onset Parkinson’s, consensus about the identity of this protein culprit has been elusive.

“There have been a lot of theories, but no one has come up with a truly satisfactory answer,” Reed said.

Oxidative Stress

In 2005, Reed and his postdoctoral research associate (and wife) Susanna Ekholm-Reed decided to investigate a report that parkin associates with another ubiquitin ligase known as Fbw7. “We soon discovered that parkin regulates Fbw7 levels by tagging it with ubiquitin and thus targeting it for degradation by the proteasome,” said Ekholm-Reed.

Loss of parkin, they found, leads to rises in Fbw7 levels, specifically for a form of the protein known as Fbw7β. The scientists observed these elevated levels of Fbw7β in embryonic mouse neurons from which parkin had been deleted, in transgenic mice that were born without the parkin gene, and even in autopsied brain tissue from Parkinson’s patients who had parkin mutations.

Subsequent experiments showed that when neurons are exposed to harmful molecules known as reactive oxygen species, parkin appears to work harder at tagging Fbw7β for destruction, so that Fbw7β levels fall. Without the parkin-driven decrease in Fbw7β levels, the neurons become more sensitive to this “oxidative stress”—so that more of them undergo a programmed self-destruction called apoptosis. Oxidative stress, to which dopamine-producing substantia nigra neurons may be particularly vulnerable, has long been considered a likely contributor to Parkinson’s.

“We realized that there must be a downstream target of Fbw7β that’s important for neuronal survival during oxidative stress,” said Ekholm-Reed.

A New Neuroprotective Strategy

The research slowed for a period due to a lack of funding. But then, in 2011, came a breakthrough. Other researchers who were investigating Fbw7’s role in cancer reported that it normally tags a cell-survival protein called Mcl-1 for destruction. The loss of Fbw7 leads to rises in Mcl-1, which in turn makes cells more resistant to apoptosis. “We were very excited about that finding,” said Ekholm-Reed. The TSRI lab’s experiments quickly confirmed the chain of events in neurons: parkin keeps levels of Fbw7β under control, and Fbw7β keeps levels of Mcl-1 under control. Full silencing of Mcl-1 leaves neurons extremely sensitive to oxidative stress.

Members of the team suspect that this is the principal explanation for how parkin mutations lead to Parkinson’s disease. But perhaps more importantly, they believe that their discovery points to a broad new “neuroprotective” strategy: reducing the Fbw7β-mediated destruction of Mcl-1 in neurons, which should make neurons more resistant to oxidative and other stresses.

“If we can find a way to inhibit Fbw7β in a way that specifically raises Mcl-1 levels, we might be able to prevent the progressive neuronal loss that’s seen not only in Parkinson’s but also in other major neurological diseases, such as Huntington’s disease and ALS [amyotrophic lateral sclerosis],” said Reed.

Finding such an Mcl-1-boosting compound, he added, is now a major focus of his laboratory’s work.

(Source: scripps.edu)

Down syndrome, the most common genetic form of intellectual disability, results from an extra copy of one chromosome. Although people with Down syndrome experience intellectual difficulties and other problems, scientists have had trouble identifying why that extra chromosome causes such widespread effects.

In new research published this week, Anita Bhattacharyya, a neuroscientist at the Waisman Center at UW-Madison, reports on brain cells that were grown from skin cells of individuals with Down syndrome.

"Even though Down syndrome is very common, it’s surprising how little we know about what goes wrong in the brain," says Bhattacharyya. "These new cells provide a way to look at early brain development."

The study began when those skin cells were transformed into induced pluripotent stem cells, which can be grown into any type of specialized cell. Bhattacharyya’s lab, working with Su-Chun Zhang and Jason Weick, then grew those stem cells into brain cells that could be studied in the lab.

One significant finding was a reduction in connections among the neurons, Bhattacharyya says. “They communicate less, are quieter. This is new, but it fits with what little we know about the Down syndrome brain.”  Brain cells communicate through connections called synapses, and the Down neurons had only about 60 percent of the usual number of synapses and synaptic activity. “This is enough to make a difference,” says Bhattacharyya. “Even if they recovered these synapses later on, you have missed this critical window of time during early development.”

The researchers looked at genes that were affected in the Down syndrome stem cells and neurons, and found that genes on the extra chromosome were increased 150 percent, consistent with the contribution of the extra chromosome.

However, the output of about 1,500 genes elsewhere in the genome was strongly affected. “It’s not surprising to see changes, but the genes that changed were surprising,” says Bhattacharyya. The predominant increase was seen in genes that respond to oxidative stress, which occurs when molecular fragments called free radicals damage a wide variety of tissues.

"We definitely found a high level of oxidative stress in the Down syndrome neurons," says Bhattacharyya. "This has been suggested before from other studies, but we were pleased to find more evidence for that. We now have a system we can manipulate to study the effects of oxidative stress and possibly prevent them."

Down syndrome includes a range of symptoms that could result from oxidative stress, Bhattacharyya says, including accelerated aging. “In  their 40s, Down syndrome individuals age very quickly. They suddenly get gray hair; their skin wrinkles, there is rapid aging in many organs, and a quick appearance of Alzheimer’s disease. Many of these processes may be due to increased oxidative stress, but it remains to be directly tested.”

Oxidative stress could be especially significant, because it appears right from the start in the stem cells. “This suggests that these cells go through their whole life with oxidative stress,” Bhattacharyya adds, “and that might contribute to the death of neurons later on, or increase susceptibility to Alzheimer’s.”

Other researchers have created neurons with Down syndrome from induced pluripotent stem cells, Bhattacharyya notes. “However, we are the first to report this synaptic deficit, and to report the effects on genes on other chromosomes in neurons. We are also the first to use stem cells from the same person that either had or lacked the extra chromosome. This allowed us to look at the difference just caused by extra chromosome, not due to the genetic difference among people.”

The research, published the week of May 27 in the Proceedings of the National Academy of Sciences, was a basic exploration of the roots of Down syndrome. Bhattacharyya says that while she did not intend to explore treatments in the short term, “we could potentially use these cells to test or intelligently design drugs to target symptoms of Down syndrome.”

(Source: news.wisc.edu)