HIV virus in disguise tricks immune system, Marie Larsson is Professor of Molecular Virology

Name: Marie LarssonTitle: Professor of Molecular Virology
Department: IKE

CONTACT

Phone: +46 (0)10-103 10 55
E-mail: marie.larsson@liu.se

Address:
Linköping University
Department of Clinical and Experimental Medicine
Virology
SE-581 85 Linköping
Sweden

Marie Larsson is Professor of Molecular Virology. Her research is in the area of immunovirology, specifically HIV research with focus on the immunomodulatory effect this virus has on dendritic cells and T cells. She has also ongoing projects exploring new adjuvants and vaccine constellations for cancer and virus. Furthermore, she is investigating the induction and sustainment of cancer associated inflammation and the deleterious effect this has on host immune defense.

Immunomodulatory effects of HIV-1’s interactions with DCs and T cells from

blood and mucosa
So far over 30 million people have died from HIV-1 infection (figure 1), the majority of them in the developing countries, and this epidemic is still cause for major concern. The existing antiretroviral therapy dampens the infection and the destruction of the immune system, i.e. AIDS, but does not cure the disease. Sadly, this therapy is not available to all HIV infected and is a very expensive lifelong commitment with severe side effects.

A vaccine blocking HIV infection is theDendritic cell sought-after solution but there is no hope that we will have such a vaccine in the near future. Instead we can hope for a therapy that induces a potent long lasting immune response consisting of CD4+ and CD8+ T cells, two types of control cells involved in the immune defense, that have proven to be important to control the infection. There exists a unique cell in all tissues in our bodies, the dendritic cell (DC) (Figure 2) with unique ability to activate T cells so they can perform their job in the body. DCs in the vaginal and rectal tissues are one of the first cells to encounter HIV during intercourse with an infected individual (Figure 3 and 4). Unfortunately, HIV hijacks the DCs, which makes this cell responsible for spreading the virus to interacting T cells in the body which provokes HIV-infection of T cells and cell death when it should be initiating immune responses to fight the infection.DC HIV

My research aspires to elucidate the mechanisms behind the immunomodulatory effects HIV exerts on DCs and on their ability to activate T cells. Focus will be on; Elucidation of the mechanisms involved in HIV’s binding to and uptake by DCs and the subsequent degradation that leads to DC antigen presentation of HIV peptides for activation of HIV specific T cells. Elucidation of the mechanisms responsible for the negative effects HIV exerts on DCs and if presence of HIV virions during DC T cell priming impairs the T cell function. Elucidate the effect opsonized HIV-1 exerts on immune cells such as DCs, NK cells and T cells. Identification of receptors and cells involved in the initial HIV infection of cervical mucosa and colorectal mucosa,  and potential microbiocides that can block the initial infection, and elucidation of why HIV affects the T cells in the gut to a higher extent than the T cells in blood.

HIV will continue to kill people and have a great impact on mankind until we have a drug that can stop this infection. My ambition is that the planed research will answer some basic questions regarding the role of DCs in HIV pathogenesis and induction of potent immune response against this virus. This knowledge will guide how a vaccine/therapy needs to be constructed in order to have high efficacy.

                                                             Mucosal transmission

                                                                Cervix

Cancer research

Elucidation the role of IL-1α and the microenvironment in development of pancreatic cancer

Pancreatic ductal adenocarcinoma (PDAC) is a common gastrointestinal malignancy with an exceptional poor prognosis and a mortality rate that nearly matches the rate of incidence. The cross-talk between PDAC and stroma cells, e.g. cancer associated fibroblasts (CAF), and immune cells, may create an environment with chronic inflammation augmenting tumor transformation and maintenance.

In PDAC, more than 70% of the total tumor mass can consist of fibrotic stroma, which makes CAFs the major component in this cancer. PDAC inflammatory environment consists of many mediators, e.g. IL-1, COX-2, IL-6, and CXCL8, and some of these factors correlate to tumor development and poor prognosis. Of note, elevated expression of IL-1 in tumors has been associated with more aggressive disease. Several studies, including ours have reported that dendritic cells (DCs), one of the immune cells found in the tumor microenvironment, show phenotypic and functional abnormalities when isolated from tumor bearing animals and individuals with PDAC. Recent findings provided some evidence that the COX-2 metabolite PGE2 is involved in the upregulation of immunomodulatory factors in DCs impairing their T cell stimulatory ability. The aims are to examine the receptor-ligands and signaling pathways involved in the cross talk between stroma cells, i.e. CAFs, and PDAC cells giving rise to the inflammatory environment and creating an environment sustaining the PDAC. To examine the role IL-1 cytokine family and effects these cytokines cell signaling have on creating the inflammatory environment and in tumor development and survival. To examine whether neutralization of IL1 signaling pathway enhances the survival and quality of life for individuals with pancreatic cancer.

The information gained from the proposed research will help us understand the mechanisms underlying the development of PDAC and the effect this solid tumor exert on the body and may help designing therapies for PDAC.

Source: Linköping University

Scheduling tool a big help in healthcare

The HIV virus avoids the body’s immune cells by disguising itself using proteins that normally take part in the defence against infections. These are the findings of research conducted at the Division of Molecular Virology.

Professor Marie LarssonThese “complement proteins” are soluble molecules that attach themselves to foreign particles and those of the body in different patterns. These patterns help the immune system to identify and attack dangerous intruders such as viruses and bacteria.

Phd student Rada EllegårdInstead, HIV exploits the complement proteins present in all body fluids in order to make its way into the body tissues without being attacked. It was known previously that infections are much more effective if the virus is surrounded by the bodily fluids normally present in blood or sexual contagion than if it is isolated in a laboratory environment. In an article in the Journal of Immunology Marie Larsson, professor of molecular virology (left) and PhD student Rada Ellegård (right) provide an explanation of this phenomenon.

“The ability to use our complement proteins in this way is probably key to the success of HIV in being transmitted. We are currently carrying out further work to investigate these mechanisms in the male genital mucous membrane – the tissue where the virus infection takes place in sexual transmission,” says Ms Larsson.

The first thing HIV particles come into contact with is dendritic cells, immune cells that function as sentry posts. Their job is to identify viruses as dangerous and hostile to the body, and to respond by producing the substances that combat infections and moving to a lymph node to set a specific immune defence in motion.

In the case of HIV, this process does not seem to work very well. The disguise stops the dendritic cells recognising the virus, which instead establishes an infection in the mucous membrane and uses the movement to the lymph nodes as a way to spread around the whole body.

As more and more cells are infected and killed, the virus slowly breaks down our immune system. Without treatment this sequence of events leads to AIDS, a condition where the victim becomes extremely vulnerable to infection and where normally harmless viruses and bacteria become life-threatening.

Related content

Marie Larsson - research presentation >>

                                       HIV-illustration

When a virus is captured by a dendritic cell, it is recognised by a virus sensor that normally sets in motion infection reduction factors which inhibit the production of new virus particles (picture, left). HIV has the ability to clothe itself in complements, a type of protein present in our bodily fluids. In this way it can dampen the signals from the virus sensors and produce many new particles (picture, right).


Source: Linköping University

HIV testing yields diagnoses in Kenya but few seek care

A sweeping effort in a rural region of Kenya to test all adults for HIV discovered 1,300 new infections, but few of the newly diagnosed people pursued treatment, a study in the journal Lancet HIV reports.
PROVIDENCE, R.I. [Brown University] — Between December 2009 and February 2011, health workers with the AMPATH Consortium sought to test and counsel every adult resident in the Bunyala subcounty of Kenya for HIV. A study in the journal Lancet HIV reports that the campaign yielded more than 1,300 new positive diagnoses, but few of those new patients sought health care.

“Home-based counseling and testing (HBCT) provided a diagnosis to nearly 40 percent of people living with HIV in this subcounty who otherwise most likely would not have gone for HIV testing,” said study lead author Becky Genberg, assistant professor (research) of health services, policy and practice in the Brown University School of Public Health. “They therefore would not have known about their HIV infection and not had the opportunity to change their behavior to protect others.”

AMPATH’s HBCT program is part of a strategy to identify all individuals living with HIV in the catchment area, start them on antiretroviral medication as soon as possible, and help them stay on their medications. Antiretroviral medication not only suppresses HIV infections for most patients but also reduces their ability to transmit the virus.

Genberg with co-author Edwin Sang “We are working on a variety of studies, all designed to understand the barriers facing the newly diagnosed, and to implement and evaluate strategies to increase their engagement and retention in HIV care over time.”

In Bunyala, home to about 66,000 people, the HBCT program tested about 32,000 adults. Among them, 3,482 had HIV. Of those, 2,122 already knew they were infected, but 1,360 did not know it yet.

A major finding of the study is that three years later only 15 percent of the newly diagnosed people had engaged in care for their infection. A likely reason why, Genberg said, is that newly diagnosed people typically don’t yet feel sick.

“That so few linked to care following HBCT is a call for innovative and creative strategies to work alongside HBCT to support the mostly healthy, asymptomatic newly diagnosed to engage with care in a way that is meaningful for them,” Genberg said.

In an editorial in the journal, Rashida Ferrand of the London School of Hygiene and Tropical Medicine said the study sounds a warning that home-based testing must be paired with effective ways to convince newly diagnosed patients to seek help.

“Unless paired with interventions targeted at hard-to-reach populations, the diagnosing of undiagnosed individuals in many settings will not be cost-effective and will have little effect on individual and population viral suppression,” she and colleagues wrote.

Genberg, who has been in Kenya this winter, said she is working with Kenyan collaborators on developing the needed interventions: “Right now we are working on a variety of studies, all designed to understand the barriers facing the newly diagnosed, and to implement and evaluate strategies to increase their engagement and retention in HIV care over time.”

In addition to Genberg the study’s authors are Joseph Hogan and Corey Duefield of Brown; Violet Naanyu, Juddy Wachira, and Samson Ndege of Moi University in Kenya; Edwin Sang, Monicah Nyambura, and Michael Odawa of AMPATH; and corresponding author Paula Braitstein of the University of Toronto.

The President’s Emergency Plan for AIDS Relief funded the study though USAID (grant AID-623-A-12-0001). Additional support came from the National Institutes of Health (K01MH099966) and the Bill and Melinda Gates Foundation.

Source: Brown University

Multiple allergic reactions traced to single protein

This is a mast cell. Credit: Priyanka Pundir/University of Alberta

Johns Hopkins and University of Alberta researchers have identified a single protein as the root of painful and dangerous allergic reactions to a range of medications and other substances. If a new drug can be found that targets the problematic protein, they say, it could help smooth treatment for patients with conditions ranging from prostate cancer to diabetes to HIV. Their results appear in the journal Nature on Dec. 17.

Previous studies traced reactions such as pain, itching and rashes at the injection sites of many drugs to part of the immune system known as mast cells. When specialized receptors on the outside of mast cells detect warning signals known as antibodies, they spring into action, releasing histamine and other substances that spark inflammation and draw other immune cells into the area. Those antibodies are produced by other immune cells in response to bacteria, viruses or other perceived threats. However, "although many of these injection site reactions look like an allergic response, the strange thing about them is that no antibodies are produced," says Xinzhong Dong, Ph.D., an associate professor of neuroscience in the Institute for Basic Biomedical Sciences at the Johns Hopkins University School of Medicine.

To zero in on the cause of the reactions, Benjamin McNeil, Ph.D., a postdoctoral fellow in Dong's laboratory, first set out to find which mast cell receptor -- or receptors -- responded to the drugs in mice. Previous studies had identified a human receptor likely to be at fault in the allergic reactions; McNeil found a receptor in mice that, like the human receptor, is found only in mast cells. He then tested that receptor by putting it into lab-grown cells and found that they did react to medications that provoke mast cell response. He found similar results for the human receptor that previous studies had indicated was a likely culprit.

"It's fortunate that all of the drugs turn out to trigger a single receptor -- it makes that receptor an attractive drug target," McNeil says.

To find out whether eliminating the receptor really would eliminate the allergic reactions, the research team also disabled the gene for the suspect receptor in mice. These "knockout" mice did not have any of the drug allergy symptoms that their genetically normal counterparts displayed.

The researchers are now working to find compounds that could safely block the culprit receptor in humans, known as MRGPRX2. Such a drug would not prevent true allergic reactions, which produce antibodies, but only the pseudoallergic reactions triggered by MRGPRX2. Still, it could improve the lives of many patients, says McNeil, by lessening the drug side effects they currently endure. Medications that trigger MRGPRX2 include cancer drugs cetrorelix, leuprolide and octreotide; HIV drug sermorelin; fluoroquinolone antibiotics; and neuromuscular blocking drugs used to paralyze muscles during surgeries.

Dong's research group is also looking into the possibility that MRGPRX2 could be behind immune conditions such as rosacea and psoriasis that don't stem from medication use.

Source: Johns Hopkins Medicine

Long-acting drug effectively prevents HIV-like infection in monkeys

The new drug cabotegravir (in vials above) has been shown to protect monkeys from infection by an HIV-like virus, and a clinical trial testing cabotegravir's safety and acceptability has begun. Unlike other preventive treatments, it would require only one injection every three months.
Credit: Zach Veilleux / The Rockefeller University

A regime of anti-HIV drugs -- components of regimens to treat established HIV infection -- has the potential to protect against infection in the first place. But real life can interfere; the effectiveness of this prophylactic approach declines if the medications aren't taken as prescribed.

HIV researchers hope a new compound, known as cabotegravir, could make dosing easier for some because the drug would be administered by injection once every three months. A clinical trial testing long-acting cabotegravir's safety and acceptability has already begun at multiple U.S. sites including The Rockefeller University Hospital. Meanwhile two new studies, including one conducted by researchers at the Aaron Diamond AIDS Research Center (ADARC) and Rockefeller University, published today (January 15) in Science Translational Medicine, show that long-acting cabotegravir injections are highly protective in a monkey model of vaginal transmission of a virus similar to HIV.

"Clinical trial results have demonstrated that the effectiveness of preventive oral medications can range with results as high as 75 percent effective to as low as ineffective, and a lot of that variability appears to hinge on the patient's ability to take the pills as prescribed," says study researcher Martin Markowitz, a professor at Rockefeller University and ADARC. "Long acting cabotegravir has the potential to create an option that could improve adherence by making it possible to receive the drug by injection once every three months."

Developed by ViiV Healthcare and GlaxoSmithKline, and previously known as GSK744 LA, cabotegravir is an antiretroviral drug. Antiretrovirals interfere with HIV's ability to replicate itself using a host cell and they are used to treat an HIV infection or to prevent those at high risk from acquiring it in the first place.

Cabotegravir belongs to a group of antiretrovirals that target integrase, an enzyme the virus uses to integrate itself into the cell's genome. This compound is a relative of an already FDA-approved integrase inhibitor, dolutegravir, but with chemical properties that allow it to be formulated into a long-acting suspension for injection.

A previous study by the ADARC and Rockefeller team in collaboration with ViiV Healthcare and GSK found long-acting cabotegravir could protect male rhesus macaque monkeys from exposure to a virus related to HIV. Following up on these results, a phase 2 clinical trial is now underway in a group of 120 men at low risk of infection. Before cabotegravir's effectiveness in high risk individuals can be tested, trials must show that study participants tolerate the drug well and find the quarterly injections, which are a novel approach to HIV prevention, acceptable.

Both new animal studies were conducted with women in mind; in 2013 women accounted for 47 percent of new HIV infections worldwide according to the Joint United Nations Programme on HIV and AIDS. Working separately, two teams tested the drug's ability to block vaginal transmission in two species of monkeys with different breeding cycles and susceptibility to infection.

First author Chasity Andrews, a postdoctoral fellow at ADARC and Rockefeller, and colleagues at ADARC, the Tulane Regional Primate Center and ViiV/GSK, studied female rhesus macaques treated with progesterone to increase their susceptibility to the virus. They found injections of long acting cabotegravir were 90 percent effective at protecting the monkeys from repeated high-dose exposures to the virus.

Meanwhile, the complementary study conducted by researchers at the CDC and ViiV/GSK found female pigtail macaques injected with cabotegravir were completely protected against multiple exposures to the virus.

"While we are still a long way off from showing that this drug works for HIV prevention in humans, our hope is that it may one day offer high risk women, as well as men, an additional option for HIV prevention," Markowitz says. "One of the lessons we have learned from contraception is the more options available, the better. We are hoping for the same in HIV prevention -- more options and better results."

Source: Rockefeller University

New tool for exploring cells in 3D created

The new software can generate editable models of mid-size biological structures such as this one of HIV. Credit: Image created by Graham Johnson and Ludovic Autin of The Scripps Research Institute

Researchers can now explore viruses, bacteria and components of the human body in more detail than ever before with software developed at The Scripps Research Institute (TSRI).

In a study published online ahead of print December 1 by the journal Nature Methods, the researchers demonstrated how the software, called cellPACK, can be used to model viruses such as HIV.

"We hope to ultimately increase scientists' ability to target any disease," said Art Olson, professor and Anderson Research Chair at TSRI who is senior author of the new study.

Putting cellPACK to the Test

The cellPACK software solves a major problem in structural biology. Although scientists have developed techniques to study relatively large structures, such as cells, and very small structures, such as proteins, it has been harder to visualize structures in the medium "mesoscale" range.

With cellPACK, researchers can quickly and efficiently process the data they've collected on smaller structures to assemble models in this mid-size range. Previously, researchers had to create these models by hand, which took weeks or months compared with just hours in cellPACK.

As a demonstration of the software's power, the authors of the new study created a model of HIV showing how outer "spike" proteins are distributed on the surface of the immature virus.

The new model put to the test a conclusion made by HIV researchers from super-resolution microscopic studies -- that the distribution of the spike proteins on the surface of the immature virus is random. But by using cellPACK to generate thousands of models, testing alternative hypotheses, the researchers found that the distribution was not random. "We demonstrated that their interpretation of the distribution did not match that hypothesis," said Olson.

A Team Effort

The cellPACK software began as the thesis project of a TSRI graduate student, Graham Johnson, now a QB3 faculty fellow at the University of California, San Francisco (UCSF) who continues to contribute to the project. Johnson had more 15 years' experience as a medical illustrator, and he wanted to create an easy way to visualize mesoscale structures. cellPACK is an expansion of Johnson's autoPACK software, which maps out the density of materials -- from concrete in a building to red blood cells in an artery.

The researchers see cellPACK as a community effort, and they have made the autoPACK and cellPACK software free and open source. Thousands of people have already downloaded the software from http://www.autopack.org.

"With the creation of cellPACK, Dr. Olson and his colleagues have addressed the challenge of integrating biological data from different sources and across multiple scales into virtual models that can simulate biologically relevant molecular interactions within a cell," said Veersamy Ravichandran, PhD, of the National Institutes of Health's National Institute of General Medical Sciences, which partially funded the research. "This user-friendly tool provides a new platform for data analysis and simulation in a collaborative manner between laboratories."

As new information comes in from the scientific community, researchers will tweak the software so it can model new shapes. "Making it open source makes it more powerful," said Olson. "The software right now is usable and very useful, but it's really a tool for the future."

Source: Scripps Research Institute

How llamas' unusual antibodies might help in the fight against HIV/AIDS

Llamas contribute to the fight against AIDS. Credit: Nika Stropakke, CC-BY

Most vaccines work by inducing an immune response characterized by neutralizing antibodies against the respective pathogen. An effective HIV vaccine has remained elusive so far, but researchers have continued to make progress, often employing innovative methods. A study published on December 18th in PLOS Pathogens reports that a combination of antibodies from llamas can neutralize (destroy) a wide range of circulating HIV viruses.

After initial disappointment that HIV vaccine candidates were unable to elicit neutralizing antibodies, researchers found that some HIV-infected individuals did produce such antibodies. The current challenge is therefore to find safe and effective vaccine formulations (as opposed to HIV infection) that trigger the development of neutralizing antibodies that can recognize and prevent infection with all or most circulating HIV subtypes.

Many known neutralizing antibodies are directed against a specific part of the virus that binds to the CD4 receptor on the human target cells, and structural biology studies indicated that the site is a narrow groove. Antibodies in most mammals are relatively large proteins made up of two copies of two different individual parts (or chains), and bulkiness might be one reason why neutralizing antibodies are rare. Llamas are a notable exception: besides the common four-chain antibodies they also produce smaller ones made up of only two of the four chains. Robin Weiss, an HIV expert, and Theo Verrips, a llama antibody expert, therefore started working with this unconventional research animal.

Laura McCoy (working with Weiss at University College London, UK) led an international group of researchers to test immunization protocols and the resulting immune response in llamas. Having previously identified one particular HIV neutralizing llama antibody, for this study the researchers immunized two additional llamas and identified a total of three new neutralizing antibodies. The four HIV neutralizing llama antibodies target different parts of the CD4-binding site of the virus, and the researchers could show that when used in combination, rather than interfering with each other, they are more potent and can neutralize all of the 60 different HIV strains tested.

To understand how the llama immunization--which included two sets of four sequential vaccine injections per animal--worked, the researchers sequenced many copies of antibody-coding genes from blood cells collected after the first set of immunizations and after a further four rounds of vaccination. They also looked at the "naïve" antibody repertoire from seven llamas that had not been vaccinated. The results suggest that the neutralizing antibodies were not part of the pre-immunization repertoire, nor were they detectable after the first vaccination round. Rather, they were generated as immune cells repeatedly encountered the vaccine and responded by maturing specific antibodies that can recognize it.

While it is encouraging that broadly neutralizing antibodies were found in all of the immunized llamas, they are present only at low concentrations in the blood, and so fail to meet the goal for a protective HIV vaccine. Nonetheless, the researchers conclude that the llama model has allowed them to examine the generation of four broadly neutralizing antibodies induced by vaccination, which has not been possible in any other species.

Source: PLOS.

Genetic factors behind surviving or dying from Ebola shown in mouse study

In an emerging disease research lab at the University of Washington, Chris Williams, a research scientist who specializes in microbiology laboratory robotics, programs a piece of equipment that can be programmed to performs many lab tasks. Credit: Brian Donohue

A newly developed mouse model suggests that genetic factors are behind the mild-to-deadly range of reactions to the Ebola virus.

People exposed to Ebola vary in how the virus affects them. Some completely resist the disease, others suffer moderate to severe illness and recover, while those who are most susceptible succumb to bleeding, organ failure and shock.

In earlier studies of populations of people who have contracted Ebola, these differences are not related to any specific changes in the Ebola virus itself that made it more or less dangerous; instead, the body's attempts to fight infection seems to determine disease severity.

In the Oct. 30 edition of Science, scientists describe strains of laboratory mice bred to test the role of an individual's genetic makeup in the course of Ebola disease. Systems biologists and virologists Angela Rasmussen and Michael Katze from the Katze Laboratory at the University of Washington Department of Microbiology led the study in collaboration with the National Institutes of Health's Rocky Mountain Laboratories in Montana and University of North Carolina at Chapel Hill.

Research on Ebola prevention and treatment has been hindered by the lack of a mouse model that replicates the main characteristics of human Ebola hemorrhagic fever. The researchers had originally obtained this genetically diverse group of inbred laboratory mice to study locations on mouse genomes associated with influenza severity.

The research was conducted in a highly secure, state-of-the-art biocontainment safety level 4 laboratory in Hamilton, Mont. The scientists examined mice that they infected with a mouse form of the same species of Ebola virus causing the 2014 West Africa outbreak. The study was done in full compliance with federal, state, and local safety and biosecurity regulations. This type of virus has been used several times before in research studies. Nothing was done to change the virus.

Interestingly, conventional laboratory mice previously infected with this virus died, but did not develop symptoms of Ebola hemorrhagic fever.

In the present study, all the mice lost weight in the first few days after infection. Nineteen percent of the mice were unfazed. They not only survived, but also fully regained their lost weight within two weeks. They had no gross pathological evidence of disease. Their livers looked normal.

Eleven percent were partially resistant and less than half of these died. Seventy percent of the mice had a greater than 50 percent mortality. Nineteen percent of this last group had liver inflammation without classic symptoms of Ebola, and thirty-four percent had blood that took too long to clot, a hallmark of fatal Ebola hemorrhagic fever in humans. Those mice also had internal bleeding, swollen spleens and changes in liver color and texture.

The scientists correlated disease outcomes and variations in mortality rates to specific genetic lines of mice.

"The frequency of different manifestations of the disease across the lines of these mice screened so far are similar in variety and proportion to the spectrum of clinical disease observed in the 2014 West African outbreak," Rasmussen said.

While acknowledging that recent Ebola survivors may have had immunity to this or a related virus that saved them during this epidemic, Katze said, "Our data suggest that genetic factors play a significant role in disease outcome."

In general, when virus infection frenzied the genes involved in promoting blood vessel inflammation and cell death, serious or fatal disease followed. On the other hand, survivors experienced more activity in genes that order blood vessel repair and the production of infection-fighting white blood cells.

The scientists note that certain specialized types of cells in the liver could also have limited virus reproduction and put a damper on systemic inflammation and blood clotting problems in resistant mice. Susceptible mice had widespread liver infection, which may explain why they had more virus in their bodies and poorly regulated blood coagulation. The researchers also noticed that spleens in the resistant and susceptible mice took alternate routes to try to ward off infection.

"We hope that medical researchers will be able to rapidly apply these findings to candidate therapeutics and vaccines," Katze said. They believe this mouse model can be promptly implemented to find genetic markers, conduct meticulous studies on how symptoms originate and take hold, and evaluate drugs and that have broad spectrum anti-viral activities against all Zaire ebolaviruses, including the one responsible for the current West African epidemic.

Source: University of Washington Health Sciences/UW Medicine

Promising compound rapidly eliminates malaria parasite

A new report says that the rapid action of (+)-SJ733 will likely slow malaria drug resistance. Credit: Peter Barta, St. Jude Children's Research Hospital

An international research collaborative has determined that a promising anti-malarial compound tricks the immune system to rapidly destroy red blood cells infected with the malaria parasite but leave healthy cells unharmed. St. Jude Children's Research Hospital scientists led the study, which appears in the current online early edition of the Proceedings of the National Academy of Sciences (PNAS).

The compound, (+)-SJ733, was developed from a molecule identified in a previous St. Jude-led study that helped to jumpstart worldwide anti-malarial drug development efforts. Malaria is caused by a parasite spread through the bite of an infected mosquito. The disease remains a major health threat to more than half the world's population, particularly children. The World Health Organization estimates that in Africa a child dies of malaria every minute.

In this study, researchers determined that (+)-SJ733 uses a novel mechanism to kill the parasite by recruiting the immune system to eliminate malaria-infected red blood cells. In a mouse model of malaria, a single dose of (+)-SJ733 killed 80 percent of malaria parasites within 24 hours. After 48 hours the parasite was undetectable.

Planning has begun for safety trials of the compound in healthy adults.

Laboratory evidence suggests that the compound's speed and mode of action work together to slow and suppress development of drug-resistant parasites. Drug resistance has long undermined efforts to treat and block malaria transmission.

"Our goal is to develop an affordable, fast-acting combination therapy that cures malaria with a single dose," said corresponding author R. Kiplin Guy, Ph.D., chair of the St. Jude Department of Chemical Biology and Therapeutics. "These results indicate that SJ733 and other compounds that act in a similar fashion are highly attractive additions to the global malaria eradication campaign, which would mean so much for the world's children, who are central to the mission of St. Jude."

Whole genome sequencing of the Plasmodium falciparum, the deadliest of the malaria parasites, revealed that (+)-SJ733 disrupted activity of the ATP4 protein in the parasites. The protein functions as a pump that the parasites depend on to maintain the proper sodium balance by removing excess sodium.

The sequencing effort was led by co-author Joseph DeRisi, Ph.D., a Howard Hughes Medical Institute investigator and chair of the University of California, San Francisco Department of Biochemistry and Biophysics. Investigators used the laboratory technique to determine the makeup of the DNA molecule in different strains of the malaria parasite.

Researchers showed that inhibiting ATP4 triggered a series of changes in malaria-infected red blood cells that marked them for destruction by the immune system. The infected cells changed shape and shrank in size. They also became more rigid and exhibited other alterations typical of aging red blood cells. The immune system responded using the same mechanism the body relies on to rid itself of aging red blood cells.

Another promising class of antimalarial compounds triggered the same changes in red blood cells infected with the malaria parasite, researchers reported. The drugs, called spiroindolones, also target the ATP4 protein. The drugs include NITD246, which is already in clinical trials for treatment of malaria. Those trials involve investigators at other institutions.

"The data suggest that compounds targeting ATP4 induce physical changes in the infected red blood cells that allow the immune system or erythrocyte quality control mechanisms to recognize and rapidly eliminate infected cells," DeRisi said. "This rapid clearance response depends on the presence of both the parasite and the investigational drug. That is important because it leaves uninfected red blood cells, also known as erythrocytes, unharmed."

Laboratory evidence also suggests that the mechanism will slow and suppress development of drug-resistant strains of the parasite, researchers said.

Planning has begun to move (+)-SJ733 from the laboratory into the clinic beginning with a safety study of the drug in healthy adults. The drug development effort is being led by a consortium that includes scientists at St. Jude, the Swiss-based non-profit Medicines for Malaria Venture and Eisai Co., a Japanese pharmaceutical company.

Source: St. Jude Children's Research Hospital