Posts tagged Huntington's disease

Researchers at McMaster University have discovered a solution to a long-standing medical mystery in Huntington’s disease (HD).

HD is a brain disease that can affect 1 in about 7,000 people in mid-life, causing an increasing loss of brain cells at the centre of the brain. HD researchers have known what the exact DNA change is that causes Huntington’s disease since 1993, but what is typically seen in patients does not lead to disease in animal models. This has made drug discovery difficult.

In this week’s issue of the science journal, the Proceedings of the National Academy of Sciences, professor Ray Truant’s laboratory at McMaster University’s Department of Biochemistry and Biomedical Sciences of the Michael G. DeGroote School of Medicine reveal how they developed a way to measure the shape of the huntingtin protein, inside of cell, while still alive. They then discovered was that the mutant huntingtin protein that causes disease was changing shape. This is the first time anyone has been able to see differences in normal and disease huntingtin with DNA defects that are typical in HD patients.

They went on to show that they can measure this shape change in cells derived from the skin cells of living Huntington’s disease patients.

“With mouse models, we know that some drugs can stop, and even reverse Huntington’s disease, but now we know exactly why,” said Truant. “The huntingtin protein has to take on a precise shape, in order to do its job in the cell. In Huntington’s disease, the right parts of the protein can’t line up to work properly. It’s like trying to use a paperclip after someone has bent it out of shape.”

The research also shows that the shape of disease huntingtin protein can be changed back to normal with chemicals that are in development as drugs for HD.  “We can refold the paper clip,” said Truant.

The methods they developed have been scaled up and used for large scale robotic drug screening, which is now ongoing with a pharmaceutical company. They are looking for drugs that can enter the brain more easily. Furthermore, they can tell if the shape of huntingtin has been corrected in patients undergoing drug trials, without relying on years to know if the HD is affected yet.

This research was a concerted effort from many sources: funding from the Canadian Foundation Institute and the Ontario Innovation Trust for an $11M microscopy centre at McMaster in 2006, ongoing support from the Canadian Institutes of Health Research, and important funding from the Toronto-based Krembil Foundation. The project was initiated with charity grant support from the Huntington Society of Canada, which allowed them to show this method was promising for further support.

The last piece of the puzzle was from the Huntington’s disease patient community, with skin cell donations from living patients and unaffected spouses that allowed the team to look at real human disease.

More information about Huntington’s Disease can be found at HDBuzz.net, a global website in eleven languages that takes primary published research articles and explains them to plain language to more than 300,000 non-scientists per month.

There are eight other diseases that have a similar DNA defects as Huntington’s disease, Truant’s group is now using similar tools to develop assays to measure shape changes in those diseases, to see if this shapeshifting is common in other diseases.

(Source: newswise.com)

(Source: sri.com)

Scientists using sophisticated imaging techniques have observed a molecular protein folding process that may help medical researchers understand and treat diseases such as Alzheimer’s, Lou Gehrig’s and cancer.

The study, reported this month in the journal Cell, verifies a process that scientists knew existed but with a mechanism they had never been able to observe, according to Dr. Hays Rye, Texas A&M AgriLife Research biochemist.

“This is a step in the direction of understanding how to modulate systems to prevent diseases like Alzheimer’s. We needed to understand the cell’s folding machines and how they interact with each other in a complicated network,” said Rye, who also is associate professor of biochemistry and biophysics at Texas A&M.

Rye explained that individual amino acids get linked together like beads on a string as a protein is made in the cell.

“But that linear sequence of amino acids is not functional,” he explained. “It’s like an origami structure that has to fold up into a three-dimensional shape to do what it has to do.”

Rye said researchers have been trying to understand this process for more than 50 years, but in a living cell the process is complicated by the presence of many proteins in a concentrated environment.

"The constraints on getting that protein to fold up into a good ‘origami’ structure are a lot more demanding,” he said. “So, there are special protein machines, known as molecular chaperones, in the cell that help proteins fold.”

But how the molecular chaperones help protein fold when it isn’t folding well by itself has been the nagging question for researchers.

“Molecular chaperones are like little machines, because they have levers and gears and power sources. They go through turning over cycles and just sort of buzz along inside a cell, driving a protein folding reaction every few seconds,” Rye said.

The many chemical reactions that are essential to life rely on the exact three-dimensional shape of folded proteins, he said. In the cell, enzymes, for example, are specialized proteins that help speed biological processes along by binding molecules and bringing them together in just the right way.

“They are bound together like a three-dimensional jigsaw puzzle,” Rye explained.  “And the proteins — those little beads on the string that are designed to fold up like origami — are folded to position all these beads in three-dimensional space to perfectly wrap around those molecules and do those chemical reactions.

“If that doesn’t happen — if the protein doesn’t get folded up right – the chemical reaction can’t be done. And if it’s essential, the cell dies because it can’t convert food into power needed to build the other structures in the cell that are needed. Chemical reactions are the structural underpinning of how cells are put together, and all of that depends on the proteins being folded in the right way.”

When a protein doesn’t fold or folds incorrectly it turns into an “aggregate,” which Rye described as “white goo that looks kind of like a mayonnaise, like crud in the test tube.

“You’re dead; the cell dies,” he said.

Over the past 20 years, he said, researchers have linked that aggregation process “pretty convincingly” to the development of diseases — Alzheimer’s disease, Lou Gehrig’s disease, Huntington’s disease, to name a few. There’s evidence that diabetes and cancer also are linked to protein folding disorders.

“One of the main roles for the molecular chaperones is preventing those protein misfolding events that lead to aggregation and not letting a cell get poisoned by badly folded or aggregated proteins,” he said.

Rye’s team focused on a key molecular chaperone — the HSP60.

“They’re called HSP for ‘heat shock protein’ because when the cell is stressed with heat, the proteins get unstable and start to fall apart and unfold,” Rye said. “The cell is built to respond by making more of the chaperones to try and fix the problem.

“This particular chaperone takes unfolded protein and goes through a chemical reaction to bind the unfolded protein and literally puts it inside a little ‘box,’” Rye said.

He added that the mystery had long been how the folding worked because, while researchers could see evidence of that happening, no one had ever seen precisely how it happened.

Rye and the team zeroed in on a chemically modified mutant that in other experiments had seemed to stall at an important step in the process that the “machine” goes through to start the folding action. This clued the researchers that this stalling might make it easier to watch.

They then used cryo-electron microscopy to capture hundreds of thousands of images of the process at very high resolutions which allowed them to reconstruct from two-dimensional flat images a three-dimensional model. A highly sophisticated computer algorithm aligns the images and classifies them in subcategories.

“If you have enough of them you can actually reconstruct and view a structure as a three-dimensional model,” Rye said.

What the team saw was this: The HSP60 chaperone is designed to recognize proteins that are not folded from the ones that are. It binds them and then has a separate co-chaperone that puts a “lid” on top of the box to keep the folding intermediate in the box. They could see the box move, and parts of the molecule moved to peel the chaperone box away from the bound protein — or “gift” in the box. But the bound protein was kept inside the package where it could then initiate a folding reaction. They saw tiny tentacles, “like a little octopus in the bottom of the box rising up and grabbing hold of the substrate protein and helping hold it inside the cavity.”

"The first thing we saw was a large amount of an unfolded protein inside of this cavity,” he said. “Even though we knew from lots and lots of other studies that it had to go in there, nobody had ever seen it like this before. We can also see the non-native protein interacting with parts of the box that no one had ever seen before. It was exciting to see all of this for the first time. I think we got a glimpse of a protein in the process of folding, which we actually can compare to other structures.”

“By understanding the mechanism of these machines, the hope is that one of the things we can learn to do is turn them up or turn them off when we need to, like for a patient who has one of the protein folding diseases,” he said.

(Source: today.agrilife.org)

While Huntington’s disease (HD) is currently incurable, the HD research community anticipates that new disease-modifying therapies in development may slow or minimize disease progression. The success of HD research depends upon the identification of reliable and sensitive biomarkers to track disease and evaluate therapies, and these biomarkers may eventually be used as outcome measures in clinical trials. Biomarkers could be especially helpful to monitor changes during the time prior to diagnosis and appearance of overt symptomatology. Three reports in the current issue of the Journal of Huntington’s Disease explore the potential of neuroimaging, proteomic analysis of brain tissue, and plasma inflammatory markers as biomarkers for Huntington’s disease.

"Characteristics of an ideal biomarker include quantification which is reliable, reproducible across sites, minimally invasive and widely available. The biomarker should show low variability in the normal population and change linearly with disease progression, ideally over short time intervals. Finally, the biomarker should respond predictably to an intervention which modifies the disease," says Elin Rees, researcher at UCL Institute of Neurology, London.

In the first report, Rees and colleagues explore the use of neuroimaging biomarkers. She says they are strong candidates as outcome measures in future clinical trials because of their clear relevance to the neuropathology of disease and their increased precision and sensitivity compared with some standard functional measures. This review looks at results from longitudinal imaging studies, focusing on the most widely available imaging modalities: structural MRI (volumetric and diffusion), functional MRI, and PET.

"All imaging modalities are logistically complicated and expensive compared with standard clinical or cognitive end-points and their sensitivity is generally reduced in individuals with later stage HD due to movement," says Rees. "Nevertheless, imaging has several advantages including the ability to track progression in the pre-manifest stage before any detectable clinical or cognitive change."

Current evidence suggests that the best neuroimaging biomarkers are structural MRI and PET using [11C] raclopride (RACLO-PET) as the tracer, in order to assess changes in the basal ganglia, especially the caudate.

A study led by Garth J.S. Cooper, PhD, professor of Biochemistry and Clinical Biochemistry at the School of Biological Sciences and the Department of Medicine at the University of Auckland, used comparative proteome analysis to identify how protein expression might correlate with Huntington’s neurodegeneration in two regions of human brain: the middle frontal gyrus (MFG) and the visual cortex (VC). The investigators studied post mortem human brain tissue from seven HD brains and eight matched controls. They found that the MFG of HD brains differentially expressed 22 proteins compared to controls, while only seven were different in the VC. Several of these proteins had not been linked to HD previous. Investigators categorized these proteins into six general functional categories: stress response, apoptosis, glycolysis, vesicular trafficking, and endocytosis. They determined that there is a common thread in the degenerative processes associated with HD, Alzheimer’s disease, and diabetes.

The third report explores the possibility that inflammatory markers in plasma can be used to track HD, noting that immune changes are apparent even during the preclinical stage. “The innate immune system orchestrates an inflammatory response involving complex interactions between cytokines, chemokines and acute phase proteins and is thus a rich source of potential biomarkers,” says Maria Björkqvist, PhD, head of the Brain Disease Biomarker Unit, Department of Experimental Science of Lund University, Sweden.

The authors compare plasma levels of several markers involved in inflammation and innate immunity of healthy controls and HD patients at different stages of disease. Two methods were used to analyze plasma: antibody-based technologies and multiple reaction monitoring (MRM).

None of the measures were significantly altered in both HD cohorts tested and none correlated with HD disease stage. Only one substance, C-reactive protein (CRP), was decreased in early HD – but this was found in only one of the two cohorts, so the finding may not be reliable. The investigators were unable to confirm other studies that had found HD-related changes in other inflammatory markers, including components of the complement system.

Some markers correlated with clinical measures. For instance, ApoE was positively correlated with depression and irritability scores, suggesting an association between ApoE and mood changes.

Even though recent data suggest that the immune system is likely to be a modifier of HD disease, inflammatory proteins do not seem to be likely candidates to be biomarkers for HD. “Many proteomic studies designed to provide potential biomarkers of disease have generated significant findings, however, often these biomarkers fail to replicate during the validation process,” says Björkqvist.

(Source: eurekalert.org)

Scientific progress in Huntington’s disease (HD) relies upon the availability of appropriate animal models that enable insights into the disease’s genetics and/or pathophysiology. Large animal models, such as domesticated farm animals, offer some distinct advantages over rodent models, including a larger brain that is amenable to imaging and intracerebral therapy, longer lifespan, and a more human-like neuro-architecture. Three articles in the latest issue of the Journal of Huntington’s Disease discuss the potential benefits of using large animal models in HD research and the implications for the development of gene therapy.

A review by Morton and Howland explores the advantages and drawbacks of small and large animal models of HD. In the same issue, Baxa et al. highlight the development of a transgenic minipig HD model that expresses a human mutant huntingtin (HTT) fragment through the central nervous system (CNS) and peripheral tissues and manifests neurochemical and reproductive changes with age. In another report, Van der Bom et al. describe a technique employing CT and MRI that allows precise intracerebral application of therapeutics to transgenic HD sheep.

Huntington’s disease (HD) is an inherited progressive neurological disorder for which there is presently no effective treatment. It is caused by a single dominant gene mutation an expanded CAG repeat in the HTT gene - leading to expression of mutant HTT protein. Expression of mutant HTT causes changes in cellular functions, which ultimately results in uncontrollable movements, progressive psychiatric difficulties, and loss of mental abilities.

The search for new large animal models of HD arises from the recognition that there are some practical limitations of rodent and other small animal models. Because neurodegenerative diseases like HD progress over a lifetime, a rodent’s short life span excludes the possibility of studying long-term changes. There are also important anatomic differences between the brains of humans and rodents that become especially relevant when studying HD, including the lack of a gyrencephalic (convoluted) cortex and differences in the structure and cellular characteristics of the basal ganglia compared to humans. Not only does a rodent’s small brain often preclude the use of advanced neuroimaging techniques, it is also not clear how intracerebral application of trophic factors, transplant therapies, and gene therapies in small animals might translate to the much larger human brain.

"Importantly, the brains of large animals can be studied using sensitive measures that should be highly translatable to the human condition, including MRI and PET imaging, EEG, and electrophysiology, as well as behavioral tests looking at motor and cognitive function," says Professor Jenny Morton, PhD, of the Department of Physiology, Development and Neuroscience at the University of Cambridge. "Moving to larger-brained animal models after promising results are obtained in rodents is a logical, and possibly necessary, step to optimize delivery and biodistribution, validating on-target mechanism of action, and assessing safety profiles," says Professor Morton

"Strategies directed against the huntingtin gene in the brain are an important part of CHDI’s therapeutic portfolio", says David Howland, PhD, Director of Model Systems at CHDI. "Translating preclinical results for gene-based therapies from rodent models to larger-brained models of HD is an important step along the path toward clinical testing."

Significant advances have been made in the creation and characterization of HD models in nonhuman primates (NHP). “The relevance to human biology of NHP models in Huntington’s disease hold great potential value for preclinical research and development, but we need to fully consider the substantial issues of cost, long-term housing of affected animals, access of the models to HD investigators, and ethical concerns with modeling in these species,” says Dr Howland. “CHDI has invested in efforts to expand modeling in large animals to include sheep and minipigs to work around some of these concerns about NHP models.”

Large domesticated farm animals offer some distinct advantages as models of HD. Sheep, for example, are domesticated, docile, live outdoors, are easy to care for, and relatively economical to maintain. A sheep’s brain is about the same size as a large primate’s, is gyrencephalic, and the basal ganglia that degenerate in HD are anatomically similar to those in humans. Sheep live long enough that the time available for studying progressive neurological diseases such as HD is much greater than is possible in rodents. HD transgenic sheep express HTT protein in the brain and abnormal HD-associated neurochemical changes. These HD sheep have been subject to advanced genomic techniques and, because they carry a human transgene that is expressed at both an mRNA and protein level, they are seen as suitable for testing gene therapy-based reagents directed against human HTT. A further advantage, says Professor Morton, is that “although sheep have a reputation for being stupid, this is probably undeserved they have very good memories and are capable of learning and remembering new tasks.”

In order to advance the use of the HD sheep model, I.M.J. van der Bom, PhD, from the Department of Radiology at the University of Massachusetts, and colleagues developed a multi-modal technique using skull markings seen with CT imaging and brain anatomy from MR imaging to allow more precise placement of intracerebral cannulae into sheep brain. The technique offers the ability to directly image micro-cannula placement to ensure accurate targeting of the therapeutic injection in the brain. With this technique, the authors hope to study the extent of optimal safety, spread and neuronal uptake of adeno-associated virus (AAV) based therapeutics.

"Pigs, and mainly minipigs, represent a viable model for preclinical drug trials and long-term safety studies," says Jan Motlik, DVM, PhD, DSc, from the Laboratory of Cell Regeneration and Plasticity of the Institute of Animal Physiology and Genetics in Libechov, Czech Republic. Advantages include its large brain size and long lifespan. Genetic advances have been made, including defining the porcine genome, with a 96% similarity between the porcine and human huntingtin genes. In addition to well-established methods for pig husbandry, they are economical to house and have body systems very similar to that of humans.

In the report by Baxa et al., a new HD minipig model using lentiviral infection of porcine embryos is described. The authors report that they successfully developed a heterozygote transgenic HD minipig that expresses a human mutant HTT fragment throughout the CNS and peripheral tissues through 4 successive generations. The model produces viable offspring, with a total neonatal mortality rate of 17%. The authors reported that one affected HD minipig showed a decline beginning at 16 months of a neuronal phosphoprotein, DARPP32, in the neostriatum, the brain region most affected by HD. A loss of fertility, possibly HD related, was also found.

(Source: news.bio-medicine.org)

By using a model, researchers at the University of Montreal have identified and “switched off” a chemical chain that causes neurodegenerative diseases such as Huntington’s disease, amyotrophic lateral sclerosis and dementia. The findings could one day be of particular therapeutic benefit to Huntington’s disease patients. “We’ve identified a new way to protect neurons that express mutant huntingtin proteins,” explained Dr. Alex Parker of the University of Montreal’s Department of Pathology and Cell Biology and its affiliated CRCHUM Research Centre. A cardinal feature of Huntington’s disease – a fatal genetic disease that typically affects patients in midlife and causes progressive death of specific areas of the brain – is the aggregation of mutant huntingtin protein in cells. “Our model revealed that increasing another cell chemical called progranulin reduced the death of neurons by combating the accumulation of the mutant proteins. Furthermore, this approach may protect against neurodegenerative diseases other than Huntington’s disease.”

There is no cure for Huntingdon’s disease and current strategies show only modest benefits, and a component of the protein aggregates involved are also present in other degenerative diseases. “My team and I wondered if the proteins in question, TDP-43 and FUS, were just innocent bystanders or if they affected the toxicity caused by mutant huntingtin,” Dr. Parker said. To answer this question, Dr. Parker and University of Montreal doctoral student Arnaud Tauffenberger turned to a simple genetic model based on the expression of mutant huntingtin in the nervous system of the transparent roundworm C. elegans. A large number of human disease genes are conserved in worms, and C. elegans in particular enables researchers to rapidly conduct genetic analyses that would not be possible in mammals.

Dr. Parker’s team found that deleting the TDP-43 and FUS genes, which produce the proteins of the same name, reduced neurodegeneration caused by mutant huntingtin. They then confirmed their findings in the cell of a mammal cell, again by using models. The next step was then to determining how neuroprotection works. TDP-43 targets a chemical called progranulin, a protein linked to dementia. “We demonstrated that removing progranulin from either worms or cells enhanced huntingtin toxicity, but increasing progranulin reduced cell death in mammalian neurons. This points towards progranulin as a potent neuroprotective agent against mutant huntingtin neurodegeneration,” Dr. Parker said. The researchers will need to do further testing this in more complex biological models to determine if the same chemical switches work in all mammals. If they do, then progranulin treatment may slow disease onset or progression in Huntington’s disease patients.

(Source: eurekalert.org)