Posts tagged macrophages

UCSF Researchers Seek Way to Boost Parkin to Fight Both Diseases

A protein at the center of Parkinson’s disease research now also has been found to play a key role in causing the destruction of bacteria that cause tuberculosis, according to scientists led by UC San Francisco microbiologist and tuberculosis expert Jeffery Cox, PhD.

The protein, named Parkin, already is the focus of intense investigation in Parkinson’s disease, in which its malfunction is associated with a loss of nerve cells. Cox and colleagues now report that Parkin also acts on tuberculosis, triggering destruction of the bacteria by immune cells known as macrophages. Results appear online today (September 4, 2013) in the journal Nature.

The finding suggests that disease-fighting strategies already under investigation in pre-clinical studies for Parkinson’s disease might also prove useful in fighting tuberculosis, according to Cox. Cox is investigating ways to ramp up Parkin activity in mice infected with tuberculosis using a strategy similar to one being explored by his UCSF colleague Kevan Shokat, PhD, as a way to ward off neurodegeneration in Parkinson’s disease.

Globally, tuberculosis kills 1.4 million people each year, spreading from person to person through the air. Parkinson’s disease, the most common neurodegenerative movement disorder, also affects millions of mostly elderly people worldwide.

Cox homed in on the enzyme Parkin as a common element in Parkinson’s and tuberculosis through his investigations of how macrophages engulf and destroy bacteria. In a sense the macrophage — which translates from Greek as “big eater” — gobbles down foreign bacteria, through a process scientists call xenophagy.

Mycobacterium tuberculosis, along with a few other types of bacteria, including Salmonella and leprosy-causing Mycobacterium leprae, are different from other kinds of bacteria in that, like viruses, they need to get inside cells to mount a successful infection.

The battle between macrophage and mycobacterium can be especially intense. M. tuberculosis invades the macrophage, but then becomes engulfed in a sac within the macrophage that is pinched off from the cell’s outer membrane. The bacteria often escape this intracellular jail by secreting a protein that degrades the sac, only to be targeted yet again by molecular chains made from a protein called ubiquitin. Previously, Cox discovered molecules that escort these chained mycobacteria to more secure confinement within compartments inside cells called lysosomes, where the bacteria are destroyed.

The cells of non-bacterial organisms ranging in complexity from baker’s yeast to humans also use a similar mechanism — called autophagy — to dispose of their own unneeded molecules or worn out cellular components. Among the most abundant and crucial of these components are the cell’s mitochondria, metabolic powerhouses that convert food molecules into a source of energy that the cell can readily use to carry out its everyday housekeeping chores, as well as its more specialized functions.

Like other cellular components, mitochondria can wear out and malfunction, and often require replacement. The process through which mitochondria are disposed of, called mitophagy, depends on Parkin.

Cox became curious about the enzyme when he learned that specific, naturally occurring variations in the Parkin gene, called polymorphisms, are associated with increased susceptibility to tuberculosis infection.

“Because of the commonalities between mitophagy and the xenophagy of intracellular mycobacteria, as well as the links between Parkin gene polymorphisms and increased susceptibility to bacterial infection in humans, we speculated that Parkin may also be recruited to M. tuberculosis and target it for xenophagy,” Cox said.

In both mouse and human macrophages infected with M. tuberculosis in the lab, Parkin played a key role in fighting the bacteria, Cox and colleagues found. In addition, genetically engineered mice lacking Parkin died when infected with M. tuberculosis, while mice with normal Parkin survived infection.

The involvement of Parkin in targeting both damaged mitochondria and infectious mycobacteria arose long ago in evolution, Cox argues. As part of the Nature study, the research team found that Parkin-deficient mice and flies – creatures quite distant from humans in evolutionary time – also are more sensitive than normal mice and flies to intracellular bacterial infections.

Looking back more than 1 billion years, Cox noted that mitochondria evolved from bacteria that were taken up by cells in a symbiotic relationship.

In the same way that the immune system recognizes infectious bacteria as foreign, Cox said, “The evolutionary origin of mitochondria from bacteria suggests that perhaps mitochondrial dysfunction triggers the recognition of a mitochondrian as non-self.”

Having now demonstrated the importance of Parkin in fighting mycobacterial infection, Cox has begun working with Shokat to find a way to boost Parkin activity against cell-invading bacteria. “We are exploring the possibility that small-molecule drugs could be developed to activate Parkin to better fight tuberculosis infection,” Cox said.

(Source: newswise.com)

Multiple sclerosis treatments that repair damage to the brain could be developed thanks to new research.

A study has shed light on how cells are able to regenerate protective sheaths around nerve fibres in the brain.

These sheaths, made up of a substance called myelin, are critical for the quick transmission of nerve signals, enabling vision, sensation and movement, but break down in patients with multiple sclerosis (MS).

In multiple sclerosis patients, the protective layer surrounding nerve fibres is stripped away and the nerves are exposed and damaged.

-Dr Veronique Miron(MRC for Regenerative Medicine at the University of Edinburgh)

Macrophages

The study, by the Universities of Edinburgh and Cambridge, found that immune cells, known as macrophages, help trigger the regeneration of myelin.

Researchers found that following loss of or damage to myelin, macrophages can release a compound called activin-A, which activates production of more myelin.

Approved therapies for multiple sclerosis work by reducing the initial myelin injury – they do not promote myelin regeneration. This study could help find new drug targets to enhance myelin regeneration and help to restore lost function in patients with multiple sclerosis.

-Dr Veronique Miron (Medical Council Centre for Regenerative Medicine at the University of Edinburgh)

Study

The study, which looked at myelin regeneration in human tissue samples and in mice, is published in Nature Neuroscience.

It was funded by the MS Society, the Wellcome Trust and the Multiple Sclerosis Society of Canada.

Scientists now plan to start further research to look at how activin-A works and whether its effects can be enhanced.

We urgently need therapies that can help slow the progression of MS and so we’re delighted researchers have identified a new, potential way to repair damage to myelin. We look forward to seeing this research develop further.

-Dr Susan Kohlhaas (Head of Biomedical Research at the MS Society)

We are pleased to fund MS research that may lead to treatment benefits for people living with MS. We look forward to advances in treatments that address repair specifically, so that people with MS may be able to manage the unpredictable symptoms of the disease.

-Dr Karen Lee (Vice-President, Research at the MS Society of Canada

(Source: ed.ac.uk)

Identification of a protein that appears to play an important role in the immune system’s removal of amyloid beta (A-beta) protein from the brain could lead to a new treatment strategy for Alzheimer’s disease. The report from researchers at Massachusetts General Hospital (MGH) has been published online in Nature Communications.

"We identified a receptor protein that mediates clearance from the brain of soluble A-beta by cells of the innate immune system," says Joseph El Khoury, MD, of the Center for Immunology and Inflammatory Diseases in the MGH Division of Infectious Diseases, co-corresponding author of the report. "We also found that deficiency of this receptor in a mouse model of Alzheimer’s disease leads to greater A-beta deposition and accelerated death, while upregulating its expression enhanced A-beta clearance from the brain."

The brain’s immune system – which includes cells like microglia, monocytes and macrophages that engulf and remove foreign materials – appears to play a dual role in neurodegenerative disorders like Alzheimer’s disease. At early stages, these cells mount a response against the buildup of A-beta, the primary component of the toxic plaques found in the brains of patients with the devastating neurological disorder. But as the disease progresses and A-beta plaques become larger, not only do these cells lose their ability to take up A-beta, they also release inflammatory chemicals that cause further damage to brain tissue.

In their investigation of factors that may underlie the breakdown of the immune system’s clearance of A-beta, El Khoury’s team with the hypothesis that, in addition to recognizing and binding to the insoluble form of A-beta found in amyloid plaques, the brain’s immune cells might also interact with soluble forms of A-beta that could begin accumulating in the brain before plaques appear. The researchers first examined a group of receptor proteins known to be used by microglia, monocytes and macrophages to interact with insoluble A-beta. Although any role for these proteins in Alzheimer’s disease has not been known, the MGH investigators previously found that their expression in a mouse model of the disease dropped as the animals aged.

After they first identified the involvement of a receptor called Scara1 in the uptake of soluble A-beta by monocytes and macrophages, the researchers then confirmed that Scara1 appears to be the major receptor for recognition and clearance of A-beta by the innate immune system, the body’s first line of defense. In a mouse model of Alzheimer’s, animals that were missing one or both copies of the Scara1 gene died several months earlier than did those with two functioning copies. By the age of 8 months, Alzheimer’s mice with no functioning Scara1 genes had double the A-beta in their brains as did a control group of Alzheimer’s mice, while normal mice had virtually none.

To investigate possible therapeutic application of the role of Scara1 in A-beta clearance, the MGH team treated cultured immune cells with Protollin, a compound that has been used to enhance the immune response to certain vaccines. Application of Protollin to immune cells tripled their expression of Scara1 and also increased levels of a protein that attracts other immune cells. Adding Protollin-stimulated microglia to brain samples from Alzheimer’s mice reduced the size and number of A-beta deposits in the hippocampus, an area particularly damaged by the disease, but that reduction was significantly less when microglia from Scara1-deficient mice were used.

El Khoury notes that previous research showed that Protollin treatment reduced A-beta deposits in Alzheimer’s mice and the current study reveals the probable mechanism behind that finding. “Upregulating Scara1 expression is a promising approach to treating Alzheimer’s disease,” he says. “First we need to duplicate these studies using human cells and identify new classes of molecules that can safely increase Scara1 expression or activity. That could potentially lead to ways of harnessing the immune system to delay the progression of this disease.” El Khoury is an associate professor of Medicine at Harvard Medical School.

(Source: massgeneral.org)

Genetically engineered immune cells seem to promote healing in mice infected with a neurological disease similar to multiple sclerosis (MS), cleaning up lesions and allowing the mice to regain use of their legs and tails.

The new finding, by a team of University of Wisconsin School of Medicine and Public Health researchers, suggests that immune cells could be engineered to create a new type of treatment for people with MS. Currently, there are few good medications for MS, an autoimmune inflammatory disease that affects some 400,000 people in the United States, and none that reverse progress of the disease.

Dr. Michael Carrithers, assistant professor of neurology, led a team that created a specially designed macrophage – an immune cell whose name means “big eater.” Macrophages rush to the site of an injury or infection, to destroy bacteria and viruses and clear away damaged tissue. The research team added a human gene to the mouse immune cell, creating a macrophage that expressed a sodium channel called NaVI.5, which seems to enhance the cell’s immune response.

But because macrophages can also be part of the autoimmune response that damages the protective covering (myelin) of the nerves in people with MS, scientists weren’t sure whether the NaV1.5 macrophages would help or make the disease worse.

When the mice developed experimental autoimmune encephalomyelitis – the mouse version of MS — they found that the NaV1.5 macrophages sought out the lesions caused by the disease and promoted recovery.

“This finding was unexpected because we weren’t sure how much damage they would do, versus how much cleaning up they would do,” Carrithers says. “Some people thought the mice would get more ill, but we found that it protected them and they either had no disease or a very mild case.”

In follow-up experiments, regular mice that do not express the human gene were treated with the NaV1.5 macrophages after the onset of symptoms, which include weakness of the back and front limbs. The majority of these mice developed complete paralysis of their hindlimbs. Almost all of the mice that were treated with the Na1.5 macrophages regained the ability to walk. Mice treated with placebo solution or regular mouse macrophages that did not have NaV1.5 did not show any recovery or became more ill. In treated mice, the research team also found the NaV1.5 macrophages at the site of the lesions, and found smaller lesions and less damaged tissue in the treated mice.

Because the NaV1.5 variation is present in human immune cells, Carrithers says, “The questions are, ‘Why are these repair mechanisms deficient in patients with MS and what can we do to enhance them?’’’ He says the long-range goal is to develop the NaV1.5 enhanced macrophages as a treatment for people with MS.

The study is being published in the June issue of the Journal of Neuropathology and Experimental Neurology.

(Source: med.wisc.edu)

(Source: monash.edu)