Immunome Named a Top Innovator Winner

June 8, 2010 By Leave a Comment

Award Recognizes Cutting Edge Private Companies Driving the Future of Innovation
WYNNEWOOD, Pa.–(Business Wire)–
Immunome, a discovery-stage antibody platform company focused on
life-threatening infectious diseases, is pleased to announce that it has been
selected as a winner of the annual New York Venture Summit Top Innovator award
by youngStartup Ventures. The companies awarded this honor have been identified
as those that play a leading role in innovation for the Technology, Life
Sciences and Clean-tech sectors.

As one of the winners, Tim Pelura, CEO of Immunome, will present the company at
the exclusive 2010 New York Venture Summit on June 17th at The Hotel Penn in New
York City, where a select group of 450 entrepreneurs, investors, and corporate
developers will gather to be the first to meet this next wave of leading edge
companies.

“We are very excited and honored to be in this elite group of youngStartup
Ventures Top Innovators,” said Tim Pelura, president and CEO of Immunome. “Every
day, physicians are seeing more and more patients with life threatening
infections for which they have inadequate or no treatment options. We believe
that if you want to cure a disease, you should start with the immune system of
someone that has already done it. Our technology enables us to capture the
natural curative antibodies of the healthy human immune system for use as
therapies for those patients unable to mount a defense.”

Honoring the Best

To Honor the youngStartup Ventures Top Innovator recipients, youngStartup
Ventures has invited their CEOs and founders to present at The New York Venture
Summit, a forum for the most exciting early stage and emerging growth companies,
and to share their insights on the future of innovation, and the entrepreneurial
journey. Held at The Hotel Penn in New York City, this intimate, invitation-only
conference is the premier venue for today’s promising startups.

For more information on the summit visit:

http://www.youngstartup.com/newyork2010/overview.php

About Immunome

Immunome is a discovery stage biopharmaceutical company that has created a
proprietary Native Human Monoclonal Antibody (N-huMAB) platform. N-huMAbs are in
the exact structures created by nature and possess the natural safety and
protective power of the human immune system. The Immunome method is an optimized
hybridoma method that exclusively produces affinity-matured IgG N-huMAbs. The
method begins with small blood samples obtained from volunteer donors who are
immune to pathogens of interest. B-cells from these donors are converted to
stable hybridoma cells that express full-length N-huMAbs that are specific for
those pathogens. The strength of the Immunome technology is its ability to
capture the innate immune response to infectious diseases and for vaccines. The
Immunome method is intrinsically unbiased, so Immunome is able to obtain
N-huMAbs not accessible by other antibody cloning methods. Because the Immunome
hybridomas express N-huMAbs in their authentic, full-length configurations,
Immunome`s N-huMAbs are suitable for functional testing without modification.
Immunome has captured high affinity, potent N-huMAbs in several therapeutic
classes – infectious disease, neurological illness, and biodefense. Immunome has
focused its internal development efforts on life-threatening infectious
diseases.

www.immunomeinc.com

Immunome
Tim Pelura, 484-476-1396
CEO
tjpelura@immunomeinc.com

Copyright Business Wire 2010

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Disrupting key structure in TB bacterium could aid in new drug design

May 12, 2010 By Leave a Comment

Washington, May 12 (ANI): In a bid to find new ways to fight tuberculosis (TB), scientists have found that disabling a structure essential to the bacterium”s survival could kill the microbes in the infected host and thwart TB infections.

In a study, scientists from the U.S. Department of Energy”s (DOE) Brookhaven National Laboratory, Stony Brook University (SBU), and Weill Cornell Medical College describe new features of how this structure, known as a proteasome, is put together and how it works.

The details could assist researchers working to develop anti-TB drugs.

“Mycobacterium tuberculosis, the bacterium that causes TB, infects one person in three worldwide, so finding new ways to battle this pathogen is a major public health priority —particularly in developing nations where active TB infections are endemic,” said study co-author Huilin Li.

Earlier studies revealed important structural details of the Mycobacterium tuberculosis proteasome, a piece of cellular machinery that carves up unwanted or damaged proteins, allowing the bacterium to evade a key defense of the human immune system.

The researchers have even identified small molecules that might be incorporated into drugs to inhibit the proteasome.

“The primary aim of this new study was to look at how the proteasome, comprised of 28 proteins, is constructed,” said Li.

The scientists used Brookhaven Lab”s National Synchrotron Light Source (NSLS) — a source of intense x-ray, ultraviolet, and infrared light — and a cryo-electron microscope to take molecular-level snapshots of the proteasome at various stages of assembly.

The studies revealed important intermediate steps and changes in the shapes of the components making up the completed structure.

The snapshots also reveal how one component in particular can inhibit the assembly process.

“Such detailed understanding of the assembly process might suggest novel approaches for developing anti-TB drugs by preventing the maturation of the proteasome. This would be an alternative to the traditional approach of inhibiting the activity of the mature proteasome,” said Li.

The researchers were also curious to find out how the Mycobacterium tuberculosis proteasome keeps the entrance to the protein-cleaving chamber shut.

“The fully constructed proteasome is literally a death chamber for cellular proteins, so the passage to the chamber has to be safely closed, and open only when necessary,” explained Li.

Higher-level organisms, such as humans or yeast, also have gate-closed proteasomes to degrade unwanted proteins. In these cases, the gate closure mechanism is known and straightforward—each of the seven end proteins is different, and they can assume different conformations, or shapes, to open and close the gate.

But in bacterial proteasomes, the seven end proteins are identical.

“The question has been how the same protein sequence takes on the necessarily different conformations in order to seal the central pore,” said Li.

Images taken by the scientists using x-ray beams at the NSLS reveal an asymmetric and tightly closed gate structure at the seven-fold symmetrical entrance.

The scientists also snapped additional images showing that the gate structure retains some flexibility.

“This flexibility may be key to opening the gate to allow entry to proteins that need to be degraded. Figuring out how to reduce the flexibility, and thus keep the gate permanently shut, could be yet another strategy in developing proteasome-targeting anti-TB drugs,” said Li.

The new approaches are particularly attractive because the differences in assembly and gating mechanisms between human and TB proteasomes are more significant than the differences in the enzyme active sites that have been primary targets for drug development.

Thus, drugs designed to inactivate these aspects of the TB proteasome would be less likely to also inhibit proteasomes in human cells.

The study appeared online in EMBO J, the journal of the European Molecular Biology Organization. (ANI)

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New finding may help in dengue fever fight

May 7, 2010 By Leave a Comment

Washington, May 7 (ANI): A new study by scientists from Imperial College London has found that some of the human immune system”s defences against the virus that causes dengue fever actually help the virus to infect more cells.

According to the researchers, their new findings could help with the design of a vaccine against the dengue virus.

The study also brings scientists closer to understanding why people who contract dengue fever more than once usually experience more severe and dangerous symptoms the second time around.

Dengue fever is transmitted by a mosquito bite and is prevalent in sub-tropical and tropical regions including South East Asia and South America. Symptoms include high fever, severe aching in the joints and vomiting. The dengue virus can also cause hemorrhagic fever, which can be fatal.

Professor Gavin Screaton, the lead author of the study from Imperial College London, and his colleagues identified a set of antibodies, produced by the human immune system to fight off the dengue virus, that they believe scientists should avoid including in any new vaccine to prevent dengue fever.

The new research shows that these precursor membrane protein (prM) antibodies do not do a very effective job of neutralising the virus. Moreover, these antibodies actually help the virus to infect more cells.

The study suggests that when a person who has already been infected with one strain of dengue virus encounters a different strain of dengue virus, the prM antibodies awakened during the first infection spring into action again. However, rather than protecting the body from the second infection, these prM antibodies help the virus to establish itself.

This activity of the prM antibodies could explain why a second infection with a different strain of the virus can cause more harm than the first infection. The researchers believe that if a dengue virus vaccine contained prM antibodies, this could cause similar problems.

The researchers reached their conclusions after analysing individual antibodies to the dengue virus extracted from blood samples donated by infected volunteers.

The new research has been published in the journal Science. (ANI)

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Why some people with HIV develop AIDS and others don”t

May 6, 2010 By Leave a Comment

London, May 6 (ANI): Scientists are a step closer to understanding why some people with HIV develop full-blown AIDS, and others don”t.

Researchers in Massachusetts and California say that the answer lies in how the immune cells that recognize invaders are educated – a finding that may pave the way for new strategies for designing an HIV vaccine.

The human immune system detects foreign cells with the help of cell-surface proteins called human leukocyte antigens (HLAs). Each person”s cells carry a particular set of HLA molecules – the person”s HLA type – which bind fragments of virus or bacterial protein and ”present” them to T cells, the immune cells that recognize and attack infected cells.

But before T cells are ready to perform their killer function, they are in effect trained on fragments of the body”s own proteins – self-peptides – in an organ called the thymus.

To ”graduate” from the thymus, a T cell must be able to recognize at least one combination of HLA molecule and self-peptide, which provides the template for its subsequent immune response against a foreign peptide bound to that HLA molecule. T cells that bind to self-peptides very strongly, however, are rejected, as they would attack the body”s own cells.

Researchers began with two observations. First, HIV-infected people who manage to keep the virus in check – so-called ”elite controllers” – often carry a particular HLA gene variant, HLA B571. Second, people with this gene also have a higher risk of developing autoimmune diseases, in which the immune system does produce a harmful response against the body”s own proteins.

Arup Chakraborty, an immunologist at the Massachusetts Institute of Technology in Cambridge, and one of the lead authors of the study, thought the two observations might be related.

He had not previously studied HIV, but he had studied how T cells are selected in the thymus by their ability to recognize specific HLA molecules and the peptides bound to them. He surmised that the HLA molecules of elite controllers might be binding a relatively small number of self-peptides.

Indeed, a look through a database of the binding properties of HLA molecules revealed that HLA B57, along with HLA B27 – which also protects against HIV – binds a much smaller proportion of self-peptides than HLAs that are not protective. The researchers then used a computer algorithm to predict how this would affect T-cell maturation.

T cells that develop in people with the HLA B57 gene would be presented with a smaller variety of peptides in the thymus. Their model showed these cells have broader activity and would be likely to recognize HIV even if the virus mutates, allowing the immune system of elite controllers to keep the infection under control.

But that same property would also make them more likely to turn on the body”s own cells, explaining why HLA B57 leads to a higher risk of developing autoimmune diseases. “If you have a smaller diversity of self-peptides in the thymus,” says Chakraborty, “there”s a higher probability that T cells with a stronger reactivity and cross-reactivity” might be released.

Testing their model on data from 1,900 HIV-infected individuals with known HLA types, 1,100 of which were elite controllers, the researchers found that the progression of the disease was strongly correlated with the number of self-peptides an HLA molecule was able to bind.

The study has been published online in Nature. (ANI)

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Had flu? You may have H1N1 protection

November 19, 2009 By Leave a Comment

People who have had repeated flu infections — or repeated flu vaccines — may have some protection against the new pandemic swine influenza, U.S. researchers said on Monday.

They found evidence that the human immune system can recognize bits of the new H1N1 virus that are similar to older, distantly related H1N1 strains.

“What we have found is that the swine flu has similarities to the seasonal flu, which appear to provide some level of pre-existing immunity. This suggests that it could make the disease less severe in the general population than originally feared,” said Alessandro Sette, director of the Center for Infectious Disease at California’s La Jolla Institute.

The study, published in the Proceedings of the National Academy of Sciences, may also help explain why many older people are less likely to have severe disease, said Allison Deckhut-Augustine of the National Institute of Allergy and Infectious Diseases.

“Adults may have some pre-existing immunity for H1N1,” Deckhut-Augustine said in a telephone interview.

That does not mean older people are protected from infection, and Deckhut-Augustine stressed that people should still be vaccinated against H1N1.

Swine flu has infected millions of people globally and killed an estimated 3,900 in the United States alone, according to the U.S. Centers for Disease Control and Prevention. Drug makers are struggling to make vaccines and governments are working to vaccinate their populations.

Bjoern Peters and colleagues at the La Jolla Institute looked at flu epitopes — molecular markers or structures that the immune system recognizes — dating back 20 years.

“We found that the immune system’s T-cells can recognize a significant percent of the markers in swine flu,” Peters said in a statement.

DUAL PROTECTION

The human immune system has two kinds of protection. Antibody response can prevent infection, while T-cells fight infection once it has occurred.

Peters and colleagues found T-cell protection but not antibody response.

“This T-cell response decreases severity of disease but doesn’t prevent infection,” said Deckhut-Augustine, whose agency helped pay for the study and maintains the public database that Peters used.

The effect could be cumulative, Peters said, which could explain why people over 50 seem to be less likely to get noticeable H1N1 infections.

“This may also suggest why children are more susceptible to severe infection and why they might need two boosts,” Deckhut-Augustine said. “They haven’t been around as long and they haven’t been exposed to different strains of H1N1 as long as adults.”

Influenza is a very mutation-prone virus and from year to year the circulating strains drift, or change slightly. This is why new vaccines must be formulated each year and why people can catch flu again and again.

The new H1N1 was a never-before-seen combination of swine flu viruses, with a sprinkling of human and avian flu virus genetic sequences. But its long-ago ancestor was an H1N1 virus first seen in the 1918 influenza pandemic that killed upwards of 50 million people.

The researchers found that the new H1N1 swine flu shared 49 percent of its epitopes with older, seasonal H1N1 strains.

Using blood from healthy donors, they found that T-cells could recognize about 17 percent of these markers.

(Editing by Eric Beech)

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HIV uses several routes to escape immune system pressure

September 19, 2009 By Leave a Comment

Washington, September 19 (ANI): Researchers at the Emory Vaccine Center have shown that HIV relies upon a number of strategies rather than use any preferred escape route to escape immune system pressure.

The human immune system has the ability to temporarily overpower HIV in early infection.

Studies conducted in the recent past have shown that most newly infected patients develop neutralizing antibodies. These are blood proteins that glob onto the virus and would allow patients to defend themselves – if they were facing only one target.

However, the problem occurs when HIV mutates, and disguises itself enough to get away from the antibodies. The virus eventually wears down the immune system into exhaustion.

The Emory team’s findings attain significance as they suggest that even if any scientist succeeds in identifying a vaccine component that can stimulate neutralizing antibodies, HIV’s capacity for rapid mutation could still be a confounding factor.

Dr. Cynthia Derdeyn, associate professor of pathology at Emory University School of Medicine, Emory Vaccine Center and Yerkes National Primate Research Center, says that a single type of neutralizing antibody may not be enough to contain HIV.

“These neutralizing antibodies work really well – they hit the virus fast and hard. But so far, every time we look, the virus escapes,” she says.

During the study, the researchers took blood samples from the participants a few weeks after infection occurred, and then later as two participants’ immune responses continued.

They isolated individual viruses over the first two years of HIV infection, and tested how well the patients’ own antibodies could neutralize them.

“In one patient where we had very early samples, there was evidence that neutralizing antibody came up within weeks, and that’s earlier than what was previously thought,” Derdeyn says.

In both patients, some viruses mutated part of their outer proteins so that after the mutation, an enzyme would be likely to attach a sugar molecule to it.

Though the sugar molecule interferes with antibody attack, this tactic, known as the “glycan shield”, was not observed in all cases.

Other viruses mutated the part of the outer protein that the neutralizing antibodies stick to directly. In both patients, many changes in the virus’ genetic code were necessary for escape.

“We need to understand early events in the immune response if we are going to figure out what a potential vaccine should have in it. What we can show is that even in one patient, several escape strategies are going on,” Derdeyn says.

According to her, that means that in order to be immune to HIV infection, someone may need to have several types of neutralizing antibodies ready to go.

Seeing how the virus mutates will allow researchers to choose the best parts to put in a vaccine, she says.

The results are online and scheduled for publication in the September issue of the journal Public Library of Science Pathogens.(ANI)

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Parasites’ quirky trick to persuade immune cells to invite them in for dinner

August 21, 2009 By Leave a Comment

Washington, Aug 21 (ANI): Scientists from Imperial College London have found that parasite leishmania tricks immune system to let it enter the body and cause skin infection.

Leishmaniasis is an infection caused by Leishmania parasites that cause disfiguring and painful skin ulcers, and in severe cases the infection can also spread to the internal organs.

Patients with the infection often suffer from social exclusion because of their disfigurement.

Leishmania parasites are transmitted by sand flies. After the parasites infect a sand fly, they make a sticky gel so that when the fly bites a human, it regurgitates this gel into the body.

The new study conducted over mice showed that the gel persuades immune cells known as macrophages to feed the parasites, rather than killing them.

The gel helps the parasites to establish an infection by enticing macrophages to the bite site. Macrophages usually kill invading pathogens by eating and digesting them.

However, the gel persuades macrophages to engulf the parasites and feed them rather than digest them.

This happens within the first few days following infection, enabling the parasites to establish themselves and infect the skin.

“Leishmaniasis is a very debilitating disease, yet we know comparatively little about the way the parasites are transmitted by sand flies,” said Dr Matthew Rogers, lead author of the study from the Division of Investigative Science at Imperial College London.

“This is because when scientists study the disease they usually inject the parasite into tissues without including the gel or the sand fly’s saliva. Our new research shows that we must consider the way the parasites enter the body – along with the gel and saliva – if we are to recreate infection and get an accurate picture of what is going on.

“Our new research shows that Leishmania parasites are very cunning – they make their own gel to control the human immune system so they can establish a skin infection.

“There is more work to be done here – our previous work in mice has suggested that injecting a synthetic version of the gel into people might provide them with some protection against infection and we would like to explore this further,” he added.

The study is published in PLoS Pathogens. (ANI)

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Genetic mapping shows how staph infections disrupt immune system

July 14, 2009 By Leave a Comment

Washington, July 14 (ANI): Researchers have used genetic mapping to explain how the human immune system is programmed to respond to Staphylococcus aureus infections.

Infectious disease specialists at UT Southwestern Medical Center have mapped the gene profiles of children with severe S. aureus infections, to see how the pathogen alters the human immune system.

The findings of the study could open new doors for improved therapeutic interventions.t has long been unknown how the host’s immune system responded to S. aureus infection, and why some individuals are more vulnerable towards severe staphylococcal infections than others.

“The beauty of our study is that we were able to use existing technology to understand in a real clinical setting what’s going on in actual humans – not models, not cells, not mice, but humans. We have provided the first description of a pattern of response within an individual’s immune system that is very consistent, very reproducible and very intense,” said Dr. Monica Ardura, lead author of the study.

The immune system consists of two components- the innate system, which provides immediate defense against infection, and the adaptive system, whose memory cells are called into action to fight off subsequent infections.

During the study, the researchers extracted ribonucleic acid from a drop of blood, and placed it on a special gene chip called a microarray, which probes the entire human genome to determine which genes are turned on or off.

It was found that in children with invasive staphylococcal infections, the genes involved in the body’s innate immune response are overactivated while those associated with the adaptive immune system are suppressed.

“It’s a very sophisticated and complex dysregulation of the immune system, but our findings prove that there’s consistency in the immune response to the staphylococcus bacterium. Now that we know how the immune system responds, the question is whether we can use this to predict patient outcomes or differentiate the sickest patients from the less sick ones. How can we use this knowledge to develop better therapies?” said Ardura.

The researchers used blood samples collected between 2001 and 2005 from 77 children – 53 hospitalized at Children’s Medical Center Dallas with invasive S. aureus infections and 24 controls.

Ardura claimed that more research was needed because the results represented a one-time snapshot of what’s going on in the cell during an invasive staphylococcal infection.

The researchers are now hoping to understand better how various staph-infection therapies affect treatment.

The study is available online in PLoS One, the Public Library of Science’s online journal. (ANI)

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Waste from TV screens may be recycled for medical purposes, say researchers

July 14, 2009 By Leave a Comment

Washington, July 14 (ANI): University of York scientists say that it is possible to recycle waste material from discarded televisions to make them useful for medical purposes.

The researchers say that they have found a way to recover the chemical compound polyvinyl-alcohol (PVA) from television screens, and transform it into a substance which could be suitable for use in tissue scaffolds which help parts of the body regenerate.

They reckon that it could also be used in pills and dressings that are designed to deliver drugs to particular parts of the body.

Professor James Clark, director of the York Green Chemistry Centre of Excellence and one of the author’s of the research, said: “With 2.5 billion liquid crystal displays already reaching the end of their life, and LCD televisions proving hugely popular with consumers, that is a huge amount of potential waste to manage.”

He added: “It is important that we find ways of recycling as many elements of LCDs as possible so we don’t simply have to resort to burying and burning them.”

Describing their technique in an article published the journal Green Chemistry, the researchers have revealed that they heat recovered material in water in a microwave, and then wash it in ethanol to produce “expanded PVA”.

Given that this material does not provoke a response from the human immune system, the researchers say that it may be suitable for use in biomedicine. (ANI)

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New fluorescent solution detect harmful ozone in air and body

June 23, 2009 By Leave a Comment

London, June 23 (ANI): Scientists at the University of Pittsburgh have developed a fluorescent substance that can help detect the presence of a harmful molecule in the air and body.

The researchers say that the substance glows bright green when exposed even minute amounts of ozone in the air and in biological samples such as human lung cells.

Ozone is at once a harmful pollutant and lung irritant, and a possible natural weapon that certain research suggests the human body employs against infections.

The researchers believe that their simple and fast-acting detector can function as a consumer device to measure surrounding ozone, or as a lab tool to gain insight into its effect on the human body and its debated role in the human immune system.

What distinguishes the probe from existing ozone-detection methods is the fact that it’s sensitive only to ozone, say the researchers.

Current indicators can register a false-positive in response to humidity, other reactive oxygen species, and atmospheric compounds such as lead, palladium, and platinum.

“As you inhale air, you inhale ozone, and it is not known how deeply it penetrates the lung or its effect on the body,” Nature magazine quoted Kazunori Koide, a chemistry professor in Pitt’s School of Arts and Sciences, who is the paper’s corresponding author, as saying.

“Patients with respiratory diseases who are more sensitive to ozone may be able to monitor their exposure, as should employees in industrial and laboratory jobs that include regular ozone exposure. Our method is quick, so people will know they’ve exceeded safe levels before they suffer the symptoms, and it’s highly specific to ozone, so it will prevent having false data,” Koide added.

The team’s detection method consists of a small molecule-based probe added to regular distilled water. Ozone reacts with the probe through a process called ozonolysis, creating the organic compound aldehyde.

The aldehyde undergoes an additional reaction known as beta elimination to produce a substance that glows bright green-or Pittsburgh Green, as the researchers termed it-under an ultraviolet (UV) lamp or microscope.

According to the researchers, the solution began to glow within 30 minutes of coming into contact with ozone.

For the indoor experiment, the research team left paper strips coated with the solution for eight hours in an unventilated office with two photocopiers and two laser printers, devices that are known to generate ozone.

When exposed to UV light, the strips revealed concentrations of ozone captured from within the room.

To test the probe outdoors, the scientists placed the solution at four high-traffic areas in Pittsburgh for eight hours on a sunny day, but out of direct sunlight, and successfully detected ozone.

The researchers also tested the probe on human lung fluid and blood serum to determine its biomedical potential. The samples were exposed to ozone and glowed under a laser light, showing that the probe could work in biological samples.

They went further and exposed human lung cells treated with the probe to ozone-rich air for five minutes.

With a microscope, they observed the fluorescent glow expand within the cell, illustrating that ozone indeed penetrated the cell membrane.

A research article describing the probe has been published in the journal Nature Chemistry. (ANI)

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How smallpox affects human immune system

May 12, 2009 By Leave a Comment

Washington, May 12 (ANI): Scientists from University of Florida have shed light on how small pox affects immune system.

The research team have come across a particular interaction between the proteins produced by smallpox virus in concert with human proteins that disables one of the body’s first responders to injury – inflammation.

“This virus that has killed more humans than any other contains secrets about how the human immune system works,” said Dr. Grant McFadden, a professor of molecular genetics and microbiology at the College of Medicine and a member of the UF Genetics Institute.

“I’m always amazed at how sophisticated these pathogens are, and every time we look, they have something new to teach us about the human immune system,” he added.

During the study, the research team, along with colleagues from the University of Alberta, the Centers for Disease Control and Prevention and a private company called Myriad Genetics, systematically screened the smallpox proteome – the entire complement of new proteins produced by the virus – during interactions with proteins from human DNA.

These protein-on-protein interactions resulted in a particularly devastating pairing between a viral protein called G1R and a human protein called human nuclear factor kappa-B1, which is believed to play a role in the growth and survival of both healthy cells and cancer cells by activating genes involved in immune responses and inflammation.

“One of the strategies of the virus is to inhibit inflammation pathways, and this interaction is an inhibitor of human inflammation such that we have never seen before,” McFadden said.

“This helps explain some of the mechanisms that contribute to smallpox pathogenesis.

“But another side of this is that inflammation can sometimes be harmful or deadly to people, and we may learn a way to inhibit more dangerous inflammation from this virus,” he added.

The study appears in the Proceedings of the National Academy of Sciences. (ANI)

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How Salmonella survives in environment

March 24, 2009 By Leave a Comment

Washington, Mar 24 (ANI): Researchers at University of Liverpool have shown how a single-celled organism, living freely in the environment, could be a source of Salmonella transmission to animals and humans.

Salmonella are microscopic living creatures that can contaminate almost any food type, causing diarrhoea, abdominal pain and fever.

Scientists know that Salmonella – which can also cause typhoid fever – has evolved unique mechanisms to prevent the body’s immune system from functioning effectively, but until now it was not understood how it survives so successfully in the environment.

Now, Liverpool scientists, in collaboration with the Institute for Animal Health, have demonstrated that Salmonella use a secretion system to protect themselves inside amoeba – a single-celled organism living on land and in the water.

Their study suggests that amoeba may be a major source of Salmonella within the environment and could play a significant role in transmission of infection to man and animals.

Salmonella uses a system, called SP12 type III, which acts as a bacterial machine inside organisms and causes disease in humans, animals and plants.

The system employs a ‘syringe-like’ mechanism to inject bacteria into cells that would normally release compounds to rid the body of harmful substances.

This system changes the structure of the cell and prevents these compounds from coming into contact with pathogens and destroying them.

“Salmonella has managed to survive extremely successfully in the environment, finding its way into our food and causing illness, despite the body’s best efforts to fight it off. We found that it uses a system, which operates, in the human immune system as well as inside amoeba living in the environment. This system essentially protects Salmonella within cellular compartments, called phagosomes, where it can survive and multiply,” Dr Paul Wigley, from the National Centre for Zoonosis Research, based at the University’s Leahurst campus, said.

“Its ability to survive in amoeba is a huge advantage to its continued development as it may be more resistant to disinfectants and water treatment. This means that we need to work to understand ways of controlling amoeba in water supplied to animals and prevent it acting as a ‘Trojan Horse’ for Salmonella and other pathogens,” he added. (ANI)

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