Rewiring metabolism slows colorectal cancer growth

Many cancers have less MPC in them than normal adult tissues. Re-introducing MPC into cancer cells slows growth of tumors following injection into mice as compared to unmanipulated cells. Credit: Ralph DeBerardinis

Cancer is an unwanted experiment in progress. As the disease advances, tumor cells accumulate mutations, eventually arriving at ones that give them the insidious power to grow uncontrollably and spread. Distinguishing drivers of cancer from benign mutations open opportunities for developing targeted cancer therapies.

A University of Utah-led study reports that cancers select against a protein complex called the mitochondrial pyruvate carrier (MPC), and re-introduction of MPC in colon cancer cells impairs several properties of cancer, including growth. The research, which appears online on Oct. 30 in Molecular Cell, implicates changes in a key step in metabolism -- the way cellular fuel is utilized -- as an important driver of colon cancer that is also likely to be important in many other cancer settings.

Cancers appear to do whatever they can to get rid of MPC, a protein involved in carbohydrate metabolism, shows the study led by Jared Rutter, Ph.D., professor of biochemistry and Dee Glen and Ida W. Smith Endowed Chair for Cancer Research at the University of Utah. At least 18 types of cancers -- colon, brain, breast, and liver among them -- have significantly less MPC than normal adult cells. Some cancers simply delete a region of the genome that contains one of the MPC genes, others find different ways to dampen MPC expression. In fact, a survey of patient biopsies shows that the less MPC there is, the more aggressive the cancer becomes.

"Loss of MPC seems to be a biomarker for cancer aggressiveness and patient survival," said Rutter, also co-director of the Diabetes and Metabolism Center at the University of Utah, and co-leader of the Nuclear Control of Cell Growth and Differentiation Program at the Huntsman Cancer Institute. "That was our first clue that MPC might be important."

Even more striking, when Rutter's group reintroduced MPC into colon cancer cell lines, properties that define them as cancerous, reverted. The cells divide less frequently under certain conditions and decrease expression of stem cell markers, an early step frequently defining the potential to form tumors and spread. Further, the engineered cells are dramatically impaired in their ability to form tumors after injection into mice. Tumors containing cells with MPC were as small as one-fourth the size of tumors made from cells without the protein complex.

"We think these results show that elimination of MPC is an early and important step in development of cancer," said John Schell, who is co-first author with Kristofor Olson, both M.D.-Ph.D. students at the University of Utah. "Finding the stem cell connection was probably the most exciting part for us, and is something we'll pursue further to understand how loss of MPC changes cell behavior."

The role of MPC in the normal cell, and what loss of MPC does to a cancer cell, addresses an observation first made nearly one century ago. Nobel Prize-wining biochemist Otto Warburg noted that cancer cells change their metabolism to support uncontrolled growth and proliferation. Scientists later found the way in which the metabolite pyruvate is processed is key to these metabolic changes. In normal adult cells, pyruvate enters the mitochondria, the cell's powerhouse, and fuels energy production. In cancer, pyruvate is diverted from the mitochondria to an alternative metabolic pathway that makes cell-building material.

Scientists had long suspected the so-called Warburg effect seen in cancer was contingent upon controlling entry of pyruvate into the mitochondria. But there was no way to directly test the idea until two years ago, when Rutter's group and others identified MPC as pyruvate's doorway to the mitochondria. The current report in Molecular Cell shows that cancer cells shut that door by repressing MPC, and that experimentally re-opening the door by re-introducing MPC not only inhibits cancer growth, but also redirects pyruvate to the metabolic pathway used in normal cells. In other words, MPC counteracts the Warburg effect.

"This makes sense because MPC is a pinch point in metabolism," said Rutter. "Our work, taken together with that from many other laboratories, shows that most cancer cells are completely reliant on this unusual metabolism known as the Warburg effect."

Understanding the Warburg effect has been an area of intense interest in recent years because of the potential to translate those discoveries into new cancer therapeutics. "We think this information can be used to design therapies that are specifically toxic to cancer cells," said Rutter.

Source: University of Utah Health Sciences

First steps in formation of pancreatic cancer identified

Shown is a region of a pancreas with preneoplastic lesions. Red labeling indicates macrophages, green labeling indicates pancreatic acinar cells that dedifferentiate, and grey labeling indicates further progressed pancreatic lesions. Credit: Image courtesy of Mayo Clinic

Researchers at Mayo Clinic's campus in Jacksonville say they have identified first steps in the origin of pancreatic cancer and that their findings suggest preventive strategies to explore.

In an online issue of Cancer Discovery, the scientists described the molecular steps necessary for acinar cells in the pancreas -- the cells that release digestive enzymes -- to become precancerous lesions. Some of these lesions can then morph into cancer.

"Pancreatic cancer develops from these lesions, so if we understand how these lesions come about, we may be able to stop the cancer train altogether," says the study's lead investigator, Peter Storz, Ph.D., a cancer biologist.

The need for new treatment and prevention strategies is pressing, Dr. Storz says. Pancreatic cancer is one of the most aggressive human cancers -- symptoms do not occur until the cancer is well advanced. One-year survival after diagnosis is only 20 percent. It is the fourth leading cause of cancer death in this country.

The scientists studied pancreatic cells with Kras genetic mutations. Kras produces a protein 

that regulates cell division, and the gene is often mutated in many cancers. More than 95 percent of pancreatic cancer cases have a Kras mutation.

The researchers detailed the steps that led acinar cells with Kras mutations to transform into duct-like cells with stem cell-like properties. Stem cells, which can divide at will, are also often implicated in cancer.

They found that Kras proteins in the acinar cells induce the expression of a molecule, ICAM-1, which attracts macrophages, a specific kind of immune cells. These inflammatory macrophages release a variety of proteins, including some that loosen the structure of the cells, allowing acinar cells to morph into different types of cells. These steps produced the precancerous pancreatic lesions.

"We show a direct link between Kras mutations and the inflammatory environment that drive the initiation of pancreatic cancer," Dr. Storz says.

But the process can be halted in laboratory mice, he adds. "We could do this two ways -- by depleting the macrophages or by treating the transformed cells with a blocking antibody that shuts down ICAM-1," says Dr. Storz. "Doing either one reduced the number of precancerous lesions."

Dr. Storz noted that a neutralizing antibody that blocks ICAM-1has already been developed. It is being tested for a wide variety of disorders, including stroke and rheumatoid arthritis.

"Understanding the crosstalk between acinar cells with Kras mutations and the microenvironment of those cells is key to developing targeted strategies to prevent and treat this cancer," he says.

Source: Mayo Clinic

Understanding, improving body's fight against pathogens

Significant reductions in the number of plasma cells in the spleen and bone marrow were observed in the absence of DOK3. Each dot in the figure represents one plasma cell detected. Credit: Image courtesy of A*Star Agency for Science, Technology and Research

Scientists from A*STAR's Bioprocessing Technology Institute (BTI) have uncovered the crucial role of two signalling molecules, DOK3 and SHP1, in the development and production of plasma cells. These discoveries, published in two journals PNAS and Nature Communications, advance the understanding of plasma cells and the antibody response, and may lead to optimisation of vaccine development and improved treatment for patients with autoimmune diseases such as lupus and tumours such as multiple myeloma.

While they exist in small populations in humans, the large amounts of antibodies secreted by plasma cells make them key to the body's immune system and its ability to defend itself against pathogens, such as bacteria and viruses. Proper maintenance of a pool of plasma cells is also critical for the establishment of lifelong immunity elicited by vaccination.

Dysregulation of plasma cell production and maintenance could lead to autoimmune diseases and multiple myeloma. Autoimmune diseases occur when the immune system does not distinguish between healthy tissue and antigens, which are found in pathogens. This results in expansion of plasma cells which produce excessive amounts of antibodies leading to destruction of one's own healthy tissue. The discoveries by scientists in BTI's Immunology Group have improved understanding of the mechanism by which plasma cells are developed from a major class of white blood cells called B cells.

For the first time, the molecule DOK3 was found to play an important role in formation of plasma cells. While calcium signalling typically controls a wide range of cellular processes that allow cells to adapt to changing environments, it was found to inhibit the expression of the membrane proteins essential for plasma cell formation. These membrane proteins include PDL1 and PDL2, and represent some of the key targets for the development of immunotherapy by pharmaceutical companies. DOK3 was able to promote the production of plasma cells by reducing the effects of calcium signalling on these membrane proteins. The absence of DOK3 would thus result in defective plasma cell formation.

In another study, BTI scientists discovered the importance of SHP1 signalling to the long term survival of plasma cells. While the molecule SHP1 has a proven role in prevention of autoimmune diseases, it was found that the absence of SHP1 would result in the failure of plasma cells to migrate from the spleen where they are generated to the bone marrow, a survival niche where they are able to survive for much longer periods. This could result in a reduction of the body's immune response and thus, an increased susceptibility to infections and diseases. The scientists in this study also successfully rectified the defective immune response caused by an absence of SHP1 by applying antibody injections, which might advance the development of therapeutics. On the other hand, targeting SHP1 might be a strategy to treat multiple myeloma where the accumulation of cancerous plasma cells in the bone marrow survival niches is undesirable.

Findings hold potential for improved treatment

The discovery of these new targets for modulating the antibody response allows the development of novel therapeutic strategies for patients with autoimmune diseases and cancer.Understanding the mechanism that governs plasma cell differentiation is also critical for the optimal design of vaccines and adjuvants, which are added to vaccines to boost the body's immune response.

Prof Lam Kong Peng, Executive Director of BTI, said, "These findings allow better understanding of plasma cells and their role in the immune system. The identification of these targets not only paves the way for development of therapeutics for those with autoimmune diseases and multiple myeloma, but also impacts the development of immunological agents for combating infections."

Source: A*Star Agency for Science, Technology and Research

Scientists discover new way protein degradation is regulated

Chamber of doom. Rockefeller scientists have identified a new way that proteins are degraded in the proteasome (green). They found that the enzyme tankyrase regulates proteasome activity by promoting the assembly of proteasome subunits into the active complex called 26S. Credit: Image by Sigi Benjamin-Hong, Strang Laboratory of Apoptosis and Cancer Biology

Proteins, unlike diamonds, aren't forever. And when they wear out, they need to be degraded in the cell back into amino acids, where they will be recycled into new proteins. Researchers at Rockefeller University and the Howard Hughes Medical Institute have identified a new way that the cell's protein recycler, the proteasome, takes care of unwanted and potentially toxic proteins, a finding that has implications for treating muscle wasting, neurodegeneration and cancer.

The consensus among scientists has been that the proteasome is constantly active, chewing up proteins that have exceeded their shelf life. A mounting body of evidence now suggests that the proteasome is dynamically regulated, ramping up its activity when the cell is challenged with especially heavy protein turnover. The researchers, postdoctoral associate Park F. Cho-Park and Hermann Steller, head of the Strang Laboratory of Apoptosis and Cancer Biology at Rockefeller, have shown that an enzyme called tankyrase regulates the proteasome's activity. In addition, Cho-Park and Steller demonstrate that a small molecule called XAV939, originally identified by scientists at Novartis who developed it as therapeutic for colon cancer, inhibits tankyrase and blocks the proteasome's activity. The research is reported in today's issue of the journal Cell.

"Our findings have tremendous implications for the clinic since it gives a new meaning to an existing class of small-molecule compound," says Steller, Strang Professor at Rockefeller and an investigator at HHMI. "In particular, our work suggests that tankyrase inhibitors may be clinically useful for treating multiple myeloma."

Tankyrase was originally identified in the late 1990s by Rockefeller's Titia de Lange and her colleagues in the Laboratory for Cell Biology and Genetics, who showed that it plays a role in elongating telomeres, structures that cap and protect the ends of chromosomes. In a series of experiments in fly and human cells, Cho-Park and Steller discovered that tankyrase uses a process called ADP-ribosylation to modify PI31, a key factor that regulates the activity and assembly of proteasome subunits into the active complex called 26S. By promoting the assembly of more 26S particles, cells under stress can boost their ability to break down and dispose of unwanted proteins.

The proteasome is currently a target for developing cancer therapeutics. The FDA has approved Velcade, a proteasome inhibitor, for the treatment of multiple myeloma and mantle cell lymphoma. However, patients on Velcade can experience peripheral neuropathy or become resistant to the drug.

Multiple myeloma cells need increased proteasome activity to survive. Preliminary data from Cho-Park and Steller show that XAV939 can block the growth of multiple myeloma cells by inhibiting the assembly of additional proteasomes without affecting the basal level of proteasomes in the cell. This selective targeting may mean fewer side effects for patients. 

"Drugs, such as XAV939, that inhibit the proteasome through other mechanisms than Velcade may have significant clinical value," says Steller.

The findings by Cho-Park and Steller also link, for the first time, metabolism and regulation of the proteasome. Sometimes the proteasome digests too much protein, which can lead to loss of muscle, says Steller.

"This discovery reveals fundamental insights into protein degradation, a process important for normal cell biology, and a key factor in disorders such as muscle wasting and neurodegeneration," said Stefan Maas of the National Institutes of Health's National Institute of General Medical Sciences, which partly supported the study. "Intriguingly, the findings also enlighten ongoing research on cancer therapies, exemplifying the impact of basic research on drug development."

Source: Rockefeller University

Powerful new system for classifying tumors revealed

This diagram illustrates how tumors with different tissues of origin were reclassified on the basis of molecular analyses. Credit: Zhong Chen, NIH/NIDCD

Cancers are classified primarily on the basis of where in the body the disease originates, as in lung cancer or breast cancer. According to a new study, however, one in ten cancer patients would be classified differently using a new classification system based on molecular subtypes instead of the current tissue-of-origin system. This reclassification could lead to different therapeutic options for those patients, scientists reported in a paper published August 7 in Cell.

"It's only ten percent that were classified differently, but it matters a lot if you're one of those patients," said senior author Josh Stuart, a professor of biomolecular engineering at UC Santa Cruz.

Stuart helped organize the study as part of the Pan-Cancer Initiative of the Cancer Genome Atlas (TCGA) project. A large team of researchers from multiple institutions performed a comprehensive analysis of molecular data from thousands of patients representing 12 different types of cancer. This was the most comprehensive and diverse collection of tumors ever analyzed by systematic genomic methods. Each tumor type was characterized using six different "platforms" or methods of molecular analysis--mostly genomic platforms such as DNA and RNA sequencing, plus a protein expression analysis.

The research team used statistical analyses of the molecular data to divide the tumors into groups or "clusters," first analyzing the data from each platform separately and then combining them in an integrated cross-platform analysis developed by co-first author Katherine Hoadley of the University of North Carolina. All six platforms as well as the integrated analysis converged on the same divisions of the cancers into 11 major subtypes. 

Five of those subtypes were nearly identical to their tissue-of-origin counterparts. But some tissue-of-origin categories split into several different molecular subtypes, and some subtypes encompass tumors with several different tissues of origin.

Bladder cancer was a particularly interesting group, because it split into seven different clusters, with most samples falling into one of three subtypes. One subtype was bladder cancer only, but some bladder cancers clustered with lung adenocarcinomas, and others with a subtype called 'squamous-like' that includes some lung cancers, some head-and-neck cancers, and some bladder cancers.

"If you look at survival rates, the bladder cancers that clustered with other tumor types had a worse prognosis. So this is not just an academic exercise," Stuart said.

Other findings from the study reconfirmed cancer subtypes that were already recognized, such as the different subtypes of breast cancer based on well-characterized biomarkers. The findings provide a more refined, quantitative picture of the differences between breast cancer subtypes, Stuart said. For example, the results reinforce the idea that 'basal-like' breast cancers are a unique tumor type. "Basal-like breast cancers are as different from luminal breast cancers as they are from lung cancers," he said.

The fact that all six platforms for molecular analysis identified the same set of subtypes, both individually and in multi-platform analyses, is an important result, Stuart noted. Not only does it give the researchers confidence in the subtypes they identified, it also means that different kinds of data can be used to classify a tumor.

"We can now say what the telltale signatures of the subtypes are, so you can classify a patient's tumor just based on the gene expression data, or just based on mutation data, if that's what you have," Stuart said. "Having a molecular map like this could help get a patient into the right clinical trial."

Although follow-up studies are needed to validate the findings, this new analysis lays the groundwork for classifying tumors into molecularly defined subtypes. The new classification scheme could be used to enroll patients in clinical trials and could lead to different treatment options based on molecular subtypes.

According to Stuart, the percentage of tumors that are reclassified based on molecular signatures is likely to grow as more samples and tumor types are included in the analysis (the next major Pan-Cancer analysis will include 21 tumor types). Coauthor Christopher Benz, an oncologist at the Buck Institute for Research on Aging and UC San Francisco, noted that the 10 percent reclassification rate in the current study is likely an underestimate due to the unequal representation of different tumors. "If our study had included as many bladder cancers as breast cancers, for example, we would have reclassified 30 percent," Benz said.

The researchers reported that each molecular subtype may reflect tumors arising from distinct cell types. For example, the data showed a marked difference between cancers of epithelial and non-epithelial origins. "We think the subtypes reflect primarily the cell of origin. Another factor is the nature of the genomic lesion, and third is the microenvironment of the cell and how surrounding cells influence it," Stuart said. "We are disentangling the signals from these different factors so we can gauge each one for its prognostic power."

The study involved an enormous amount of molecular and clinical data, which was managed by data coordinator Kyle Ellrott, a software developer in Stuart's lab at UC Santa Cruz. The data sets and results have been made available to other researchers through the Synapse web site (http://www.synapse.org). Stuart worked with the bioinformatics company Sage Bionetworks to create Synapse as a data repository for the Pan-Cancer Initiative.

"It's a huge amount of information, and all the data is available as programmable data sets that other researchers can use to do further analysis," Stuart said. "The scale of this project is hard to imagine. All of the data that the TCGA project has been churning out got funneled into this paper, and it's giving us an unbiased look at what the data have to tell us about cancer."

Source: University of California - Santa Cruz

New approach aims to silence cancer 'survival genes'

Silencing the SIRT1 gene: Cancer cells before and after treatment in vitro. Non-cancerous cells (not shown) are unaffected. Credit: Image courtesy of University of York

Scientists at the University of York are working on a promising new approach for tackling colorectal cancer, the second most common cause of cancer-related death.

The new method works by silencing cancer 'survival genes' and could potentially combat cancer through the selective killing of colorectal cancer cells without adverse effects on normal, non-cancer cells.

Funded by York's Centre for Chronic Diseases and Disorders (C2D2), the project led by Professor Jo Milner from York's Department of Biology involved preliminary studies to establish the suitability of an ex vivo model for the future development of anti-cancer therapies for colorectal cancer using a technique called RNA interference.

The new approach builds on ground-breaking research by Professor Milner and her team at York more than a decade ago. This early work, funded by Yorkshire Cancer Research (YCR), used the newly-developed technique of RNA interference to successfully kill human cervical cancer cells grown in culture without causing damage to healthy cells.

Professor Milner explained: "When a mammalian cell elects to die it does so with great precision and without harming its neighbours. This process of 'programmed cell death' enables the continuous replacement of aging cells and also the sculpting of tissues and neuronal pathways.

"However, when this normal process of programmed cell death fails the continued abnormal growth of affected cells can lead to cancer. Some cancers develop following infection with a virus, such as human papilloma virus which causes human cervical cancer. Here the virus expresses specific viral genes that disrupt normal cellular control mechanisms resulting in abnormal cell proliferation and survival.

"Using RNA interference (RNAi) we first identified the viral gene responsible for the continued survival of cervical cancer cells. Then we established the feasibility of RNAi-based therapeutics for the selective killing of human cervical cancer cells growing in vitro."

Professor Milner and her team next studied cells from other cancer types, including colorectal cancer and breast cancer. Such cancers develop when the cell's internal control system fails due to damage to one or more of the regulatory genes.

Professor Milner said "We discovered that other genes, belonging to a group called stress-response genes, acquire a new pro-survival function during the process of cancerous transformation. Importantly, this acquired cancer-specific survival function operates under normal, physiological conditions. Silencing these cancer-specific survival genes by RNA interference causes the cancer cells to die while the survival of non-cancerous cells appears normal. This is in contrast to treating cancer by radiotherapy and/or genotoxic drugs -- these agents cause genotoxic stress and damage both cancer and normal cells and tissues in the body, resulting in unwanted adverse side effects for the patient."

For the work on colorectal cancer therapies to progress towards the clinic, the team has had to meet the challenge of modifying the agent siRNA. siRNA is the synthetic RNA molecule which is designed to silence a chosen gene by inducing RNA interference and selectively suppressing expression of that gene. However, siRNA is very unstable and is rapidly degraded when in contact with human tissues.

As reported in the journal Molecular Therapy, the team has now successfully met this challenge and converted the unstable siRNA molecule into a stable form without losing its ability and very high efficacy for targeted gene silencing. A novel siRNA/DNA has been shown to be resistant to degradation while retaining high efficacy and selectivity for target gene silencing when tested on human cancer cells grown in culture.

The next step will involve testing this novel therapeutic agent for cancer-specific cell killing using human tissue maintained ex vivo, using an experimental model which was validated in the course of the C2D2-funded research.

Professor Paul Kaye, Director of C2D2, said: "Professor Milner's team has now shown that ex vivo cultures of colorectal tumour material, derived from human patients, maintain cancer-related biochemistry over several days, and of sufficient time known to produce a killing effect with the novel siRNA/DNA in vitro. It is marvelous that C2D2 has been able to support this ground breaking research that has validated an ex vivo model that can be used to progress this novel therapeutic towards the clinic, and without the need for animal research."

Source: University of York

Computer model predicts red blood cell flow

Rendering of stream of blood cells. Credit: © Witold Krasowski / Fotolia

Adjacent to the walls of our arterioles, capillaries, and venules -- the blood vessels that make up our microcirculation -- there exists a peculiar thin layer of clear plasma, devoid of red blood cells. Although it is just a few millionths of a meter thick, that layer is vital. It controls, for example, the speed with which platelets can reach the site of a cut and start the clotting process.

"If you destroy this layer, your bleeding time can go way up, by 60 percent or more, which is a real issue in trauma," said Eric Shaqfeh, the Lester Levi Carter Professor and a professor of chemical engineering and mechanical engineering at Stanford University. Along with his colleagues, Shaqfeh has now created the first simplified computer model of the process that forms that layer -- a model that could help to improve the design of artificial platelets and medical treatments for trauma injuries and for blood disorders such as sickle cell anemia and malaria.

The model is described in a paper appearing in the journal Physics of Fluids.

The thin plasma layer, known as the Fåhræus-Lindqvist layer, is created naturally when blood flows through small vessels. In the microcirculation, the layer forms because red blood cells tend to naturally deform and lift away from the vessel walls. "The reason they don't just continually move away from the wall and go far away is because, as they move away, then also collide with other red blood cells, which force them back," Shaqfeh explained. "So the Fåhræus-Lindqvist layer represents a balance between this lift force and collisional forces that exist in the blood."

Because the deformation of red blood cells is a key factor in the Fåhræus-Lindqvist layer, its properties are altered in diseases, such as sickle cell anemia, that affect the shape and rigidity of those cells. The new model, which is a scaled-down version of an earlier numerical model by Shaqfeh and colleagues that provided the first large-scale, quantitative explanation of the formation of the layer, can predict how blood cells with varying shapes, sizes, and properties -- including the crescent-shaped cells that are the hallmark of sickle cell anemia -- will influence blood flow.

The model can also help predict the outcome of -- and perfect -- treatments for trauma-related injuries. One common thing to do during treatment for trauma injuries is to inject saline, which among other things reduces the hematocrit, the blood fraction of red blood cells. With our model, Shaqfeh said, "we can predict how thick the Fåhræus-Lindqvist layer will be with a given hematocrit, and therefore how close the platelets will be to the periphery of the blood vessels -- and how quickly clotting will occur.

Source: American Institute of Physics (AIP)

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

First step: From human cells to tissue-engineered esophagus

This images shows a tissue-engineered esophagus. Credit: The Saban Research Institute

In a first step toward future human therapies, researchers at The Saban Research Institute of Children's Hospital Los Angeles have shown that esophageal tissue can be grown in vivo from both human and mouse cells. The study has been published online in the journal Tissue Engineering, 
Part A.

The tissue-engineered esophagus formed on a relatively simple biodegradable scaffold after the researchers transplanted mouse and human organ-specific stem/progenitor cells into a murine model, according to principal investigator Tracy C. Grikscheit, MD, of the Developmental Biology and Regenerative Medicine program of The Saban Research Institute and pediatric surgeon at Children's Hospital Los Angeles.

Progenitor cells have the ability to differentiate into specific types of cell, and can migrate to the tissue where they are needed. Their potential to differentiate depends on their type of "parent" stem cell and also on their niche. The tissue-engineering technique discovered by the CHLA researchers required only a simple polymer to deliver the cells, and multiple cellular groupings show the ability to generate a replacement organ with all cell layers and functions.

"We found that multiple combinations of cell populations allowed subsequent formation of engineered tissue. Different progenitor cells can find the right 'partner' cell in order to grow into specific esophageal cell types -- such as epithelium, muscle or nerve cells -- and without the need for exogenous growth factors. This means that successful tissue engineering of the esophagus is simpler than we previously thought," said Grikscheit.

She added that the study shows promise for one day applying the process in children who have been born with missing portions of the organ, which carries food, liquids and saliva from the mouth to the stomach. The process might also be used in patients who have had esophageal cancer -- the fastest growing type of cancer in the U.S. -- or otherwise damaged tissue, for example from accidentally swallowing caustic substances.

"We have demonstrated that a simple and versatile, biodegradable polymer is sufficient for the growth of tissue-engineered esophagus from human cells," added Grikscheit. "This not only serves as a potential source of tissue, but also a source of knowledge, as there are no other robust models available for studying esophageal stem cell dynamics. Understanding how these cells might behave in response to injury and how various donor cell types relate could expand the pool of potential donor cells for engineered tissue."

Additional contributors include first author Ryan G. Spurrier, MD, Allison L. Speer, MD, Xiaogang Hou, PhD and Wael N. El-Nachef, MD, of The Saban Research Institute of Children's Hospital Los Angeles. The study was supported by grants from the California Institute for Regenerative Medicine.

Source: Children's Hospital Los Angeles Saban Research Institute