Archive for the ‘Antiagiogenesis’ Category

In dogs, endostatin and vitamin D3 reduce lung metastases

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Posted 21 Nov 2010 — by James Street
Category Antiagiogenesis, Dog Osteosarcoma, Lung Metastases
Even after limb amputation, osteosarcoma often recurs as metastases to the lungs. The reason
for this recurrence is thought to be due to cancer cells which had already seeded the lungs, but
which were unable to grow when the primary, or first, tumor was present on the limb. Primary
tumors are known to produce certain angiogenesis inhibitors,
such as angiostatin and endostatin, which circulate in the
bloodstream and act to suppress the growth of cancer cells
in distant organs. When the primary tumor is removed by amputation, the presence of
these inhibitors is reduced, allowing those distant cancer cells to grow. Dogs with
osteosarcoma were recently shown to secrete angiostatin in their
urine, which disappears once their tumor is removed. Hence,
antiangiogenic therapy may prove to be useful to treat osteosarcoma
in the limb, as well as to prevent metastases.
In animal studies, various angiogenesis inhibitors have been
shown to reduce osteosarcoma growth, including anti-VEGF
antibody, AGM-1470, and vitamin D3. These agents have
not yet been formally studied in formal canine trials.

Brain Tumors Grow Their Own Blood Supply

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Posted 21 Nov 2010 — by James Street
Category Antiagiogenesis
by Jocelyn Kaiser on 21 November 2010, 1:00 PM

sn-braincancer.jpg

Shape-shifters. Some cells within these mouse blood vessels developed from human brain tumor cells.
Credit: R. Wang et al., Nature, Advanced Online Publication (2010)

Tumors are notoriously hard to kill. Attack them with chemotherapy, and they develop drug resistance; surgically remove them, and they may have already metastasized to other parts of the body. Now scientists have found that tumors have yet another trick up their sleeve: They can create their own blood supply by morphing into blood vessels. The observations, reported by two separate teams online today in Nature, could explain why drugs designed to choke off blood to brain tumors often fail.

The researchers drew the link between tumor cells and blood vessel cells with a series of experiments on glioblastomas—fast-growing brain tumors that contain tufts of thin, abnormal blood vessels. Neurosurgeon and stem cell scientist Viviane Tabar and colleagues at Memorial Sloan-Kettering Cancer Center in New York City first took glioma samples from the operating room and looked for chromosomal abnormalities in the endothelial cells lining the tumor’s blood vessels. They found patterns exactly like those in cells from the tumor itself, suggesting that at least some of the blood vessel cells came from the tumor.

The researchers then sorted glioma cells into different types using antibodies that stick to specific proteins on a cell’s surface. They showed that the cells that give rise to blood vessels are an immature cancer cell, known as a stemlike cancer cell. Finally, the researchers injected these cancer stem cells into the brains of mice with weakened immune systems and then examined the blood vessels within the resulting tumors. The vessels stained positive for antibodies to human endothelial cells, again showing that some of the cells had to come from the tumor.

The bottom line: “There is plasticity within the tumor, and it can make its own blood vessels,” says Tabar. She says that this could explain why cancer drugs aimed at choking off a tumor’s blood supply by blocking growth signals, known as angiogenesis inhibitors, usually stop working within about 6 months. When her team added one of the antiangiogenesis drugs to a culture of the cancer cells, the drug stopped immature blood vessel cells from maturing but didn’t block the stem cells from developing into the immature blood vessel cells. Because tumor cells are genetically unstable, they may easily find ways to bypass the antiangiogenesis drugs, Tabar says.

A separate team led by Ruggero De Maria at the Istituto Superiore di Sanità in Rome published a similar set of experiments today. Both teams suggest that combining antiangiogenesis drugs with another drug that stops the stem cells from maturing might be a way to overcome resistance in gliomas and perhaps other cancers.

Other papers have hinted that cancer cells might give rise to blood vessel cells, but the two studies reporting essentially the same result confirm that suspicion, says angiogenesis researcher David Cheresh of the University of California, San Diego. “These two papers will put the controversy to rest.”

Endostatin prevents angiogenesis-induced ability of osteosarcoma to metastasize to the lungs

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Posted 19 Nov 2010 — by James Street
Category Antiagiogenesis, Drugs, Metastases, Osteosarcoma

1: J Bone Joint Surg Br. 2004 Jan;86(1):143-7.
Concomitant tumour resistance in patients with osteosarcoma. A clue to a new therapeutic strategy.

Kaya M, Wada T, Nagoya S, Kawaguchi S, Isu K, Yamashita T.

Department of Orthopaedic Surgery, Sapporo Medical University School of Medicine, S-1, W-16, Chuo-ku, Sapporo 060-8543, Hokkaido, Japan.

Concomitant tumour resistance (CTR) is a unique phenomenon in which animals harbouring large primary tumours are resistant to the growth of smaller metastatic tumours by systemic angiogenic suppression. To examine this clinically, in ten patients with osteosarcoma, we investigated the effects of removal of the primary tumour on the development of pulmonary metastases, the systemic angiogenesis-inducing ability and the serum levels of several angiogenesis modulators. We found that removal of the primary tumour significantly elevated systemic angiogenesis-inducing ability in five patients who had post-operative recurrence of the tumour. Post-operative elevation of the angiogenesis-induced ability was suppressed by the addition of an angiogenic inhibitor, endostatin. Also, primary removal of the tumour decreased the serum levels of vascular endothelial growth factor and endostatin. These findings suggest, for the first time, the presence of CTR in patients with osteosarcoma for whom post-operative antiangiogenic therapy may be used to prevent the post-operative progression of micrometastases.

PMID: 14765882 [PubMed - indexed for MEDLINE]

University Of East Anglia Makes Cancer Breakthrough

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Posted 27 Oct 2010 — by James Street
Category Antiagiogenesis

University Of East Anglia Makes Cancer Breakthrough

15 Oct 2010   

Scientists at the University of East Anglia have made an important breakthrough in the way anti-cancer drugs are tested.

A tumour cannot grow to a large size or spread until it has developed its own blood supply and leading research has looked for a way of halting capillary formation to stop tumours taking hold.

But new findings published today in the Journal of Cell Science have shown that scientists testing such treatments may not have been studying exactly what they thought they were.

The research proves that cells are able to switch their genetic profile turning off genes expressed by blood vessel cells and turning on genes specific to lymphatic cells.

This “switch” was previously thought to be impossible and means that scientists may have been researching lymphatic cells, rather than blood vessel cells. It is hoped the discovery will propel the race to find revolutionary new treatments.

Lead author Dr Lin Cooley, said: “It has always been thought that cells could not change from blood to lymphatic vascular cells.

“Other researchers have been doing experiments thinking they were looking at blood vessel cells, when in fact they were looking at lymphatic vascular cells. This breakthrough is important because they have not been studying what they think they have been studying.

“It is a big discovery and will be very important in testing potential anti-cancer drugs.”

Researchers used human vein cells in experiments where they form capillaries the smallest of the body’s blood vessels – when cultured in various environments similar to the body.

The human vascular system is made up of two separate circulatory networks the blood and lymphatic vasculature. Blood vessels and lymphatic vessels are structurally similar, but have very different roles, and are made up of two distinct cell types.

Dr Cooley said: “We have discovered that when vein cells form tube structures, they appear to “switch” their genetic profile, turning off genes expressed by blood vessel cells, and turning on genes specific to lymphatic vessels.

“This change can be reversed, and is dependent on the particular environment they are cultured in.

“We have also shown that their identity changes in response to the cell’s environment rather than only being specified by signals during early embryonic development”.

The research has been conducted by the Biomedical Research Centre part of the university’s School of Biological Sciences, in collaboration with the VBCRC Invasion and Metastasis Group in Australia and the University of Melbourne. It was funded by cancer charity Big C.

Sources: East Anglia University, AlphaGalileo Foundation.

Article URL: http://www.medicalnewstoday.com/articles/204683.php

Main News Category: Cancer / Oncology

Also Appears In:  Biology / Biochemistry,  Blood / Hematology,  Vascular,

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Actibind prevents malignant cells from moving through the blood stream

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Posted 25 Sep 2010 — by James Street
Category Antiagiogenesis, Metastases

Israeli fruit research bears results in curbing cancer
By David Brinn   July 15, 2006

There may not noticeably be a direct path from developing ways to grow larger peaches and nectarines to discovering a way to stop the growth and spread of cancer cells – but that hasn’t stopped Professor Oded Shoseyov.

The research team headed by Shoseyov at Hebrew University’s Faculty of Agriculture has used their knowledge and intuition of the inner workings of inhibiting cell growth to discover a protein that has the effect of blocking the blood supply to tumors.

Their approach has been shown to inhibit the malignant cells without affecting normal cells and without the severe side effects of traditional treatments such as radiation and chemotherapy. The strategy involves isolating the malignant tumor from its nutritional and oxygen supplies, thereby halting its growth and stopping metastases (spread of cancer cells to other parts of the body.)

“We were pretty much hoping and expecting to achieve the results we did, and we were pleased,” Shoseyov told ISRAEL21c. “But we realized that when we started investigating the mechanism, it was a fundamental process of nature, so we weren’t that surprised that we were proven right.”

The work on the project, which included Shoseyov’s associates Dr. Levava Roiz, Dr. Patricia Smirnoff and Dr. Betty Schwartz, was published recently in the journal Cancer of the American Cancer Society.

Shoseyov, an eighth generation Israeli who comes from a family of farmers, completed his PhD focusing on the biochemistry of wine flavor. His family’s vineyard in Carmey Yosef produces a boutique wine called Bravdo (bravdo.com), and it was his interest in agriculture that led him into his field of research.

“The goal of our initial research was to find solutions for farmer to increase the size of their peaches and nectarines. The problem is that the trees produce too many flowers – if you don’t perform manual thinning to reduce the flowers, you end up with a lot of fruit – but extremely small in size. Therefore they have less commercial value,” said Shoseyov.

“At the moment, the practice is to manually remove many of the fruitlets or flowers at the beginning of the season in the spring. However, it’s very labor intensive work. One worker can handle about 3-4 trees a day, and it’s a big effort. For example, if a hectare has 350 trees, it can take weeks and great expense to go through the whole orchard.”

Shoseyov and his team focused the actions of actibind, a protein that is produced by the black mold Aspergillus niger: a well-known microorganism used in bio and food technology. In plants, actibind binds actin, a major component of the intracellular structure in plants, interfering with the plants’ pollen tubes and halting cell growth.

“We studied this mechanism carefully and developed a process in which actibind was sprayed in the fields and reduced the number of flowers sprouting on the peach and nectarine trees,” he said.

An effort to commercialize the process failed because, in Shoseyov’s view, the fields had to be sprayed so many times, it was still more economically feasible to manually thin the trees. However, with disappointment came the silver lining – discovery.

“In the course of our work, we started to get deeper into the science and understand how the actibind inhibits growth. We surmised that this process of inhibiting tip growth is probably not exclusive to plants and fungi and is more of a natural phenomenon in nature and found in other organisms.

“Since cancer cells also have characteristic tip growth, we decided to check whether actibind has the ability to inhibit tip growth in cancer cells,” he said.

The team found an actibind-like protein, RNaseT2, was also subsequently found to bind actin in human and animal migrating cells, such as the cells that are responsible for new blood vessel formation (angiogenesis) in tumors.

“There are two important process in the development of a tumor,” explained Shoseyov -”metastases (spread of cancer cells to other parts of the body). Most cancer victims end up dying from a metatastic tumor, not a primary tumor, so preventing this metastases is extremely important.

“The second important process is angiogenesis – the development of blood vessels in the tumor which support its growth. If you’re able to prevent this – which also requires tip growth, you have another good mechanism to prevent tumor growth.”

The researchers discovered that by blocking the blood supply to the tumors, actibind halted the ability of malignant cells to move through the blood stream to form new metastases. A further plus is that actibind is not toxic to normal cells, thereby significantly minimizing the risk of side effects.

While Shoseyov may not have been surprised by the results, he admits that their research did provide an unexpected benefit.

During the completion of the human genome project, the gene encoding for RNaseT2, the human actibind-like protein which the HU researchers proved effective in inhibiting tumor growth, was found on chromosome 6.

“For many years, doctors have been using a certain molecular marker in humans to predict if a tumor is benign or malignant. When a patient has a tumor, a biopsy is taken and observed under a microscope. The rule of thumb is that if the tip of chromosome 6 is broken off, then it’s an indication that the tumor is malignant and the decision is taken to go full steam ahead with treatment like chemotherapy,” said Shoseyov.

As part of the human genome project, an Italian group asked ‘what missing at the end of this chromosome tip that enables the cells to become malignant when it’s broken?’ According to Shoseyov, the missing ingredient is… actibind.

“To our surprise, we found that actibind is also in humans. And when it’s not there, tip growth is not controlled, and that loss of control results in malignancy,” he said.

In laboratory experiments using cell cultures that originated from human colon cancer, breast cancer and melanoma, increasing the level of actibind was found to reduce the ability of these cells to form tumorogenic colonies. Further experimentation, with a variety of animal models, showed that the increased actibind inhibited the growth of colon cancer-derived tumors, metastases and blood vessel formation.

The fungal actibind and the human RNaseT2 represent the basis for a new class of drugs that could be used as a front-line therapy in the fight against cancer, say the researchers.

“Both in vitro and in vivo, we’ve shown that actibind has an anti-cancer effect.
We’ve file a patent that belongs to the university, and we’re now exploring the possibility of a further investigation in order to develop it into a cancer drug,” said Shoseyov.

While Shoseyov has no intentions of giving up his vineyard, the promising results of his study have convinced him to put aside his fruit research for the foreseeable future.

“It’s definitely going to be cancer from now on.”

Blood Vessels Refill Their Old Shoes After Treatment With VEGF Inhibitors Is Stopped

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Posted 25 Sep 2010 — by James Street
Category Antiagiogenesis

06 Oct 2006

Inhibitors of the protein VEGF are currently being used to treat individuals with certain cancers. As tumors grow they develop their own blood vessels, which supply the tumor cells with the nutrients and oxygen that they need to survive, and VEGF inhibitors exert their anti-cancer effect by destroying blood vessels in the tumor. Current VEGF inhibitors work by blocking the function of any VEGF in the individual, but little is known about the reversibility of their effects.

Now, in a study appearing in the October issue of the Journal of Clinical Investigation, Donald McDonald and colleagues from UCSF, show that it takes the blood vessels in tumors in mice 7 days to regrow after treatment with VEGF inhibitors is withdrawn. The new blood vessels grew along the tracks left behind by the old blood vessels destroyed by the VEGF inhibitors. This study indicates that although VEGF inhibitors destroy blood vessels in a tumor, the development of approaches that combine VEGF inhibitors with agents that destroy blood vessel tracks might be more effective at preventing blood vessel re-growth in a tumor.

In an accompanying commentary, Kristy Red-Horse and Napoleone Ferrara explain how important these findings are for the future development of strategies aimed at destroying the blood vessels that feed a tumor.

TITLE: Rapid vascular regrowth in tumors after reversal of VEGF inhibition

AUTHOR CONTACT:

Donald M. McDonald
University of California San Francisco, San Francisco, California, USA.

AUTHOR CONTACT:

Napoleone Ferrara
Genentech Inc., South San Francisco, California, USA.

Researchers propose that available drugs (now on the market), which sever the “parasitic” connection between tumor cells and fibroblasts, may be effective cancer therapy

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Posted 02 Sep 2010 — by James Street
Category Antiagiogenesis, Antioxidants, genetic research, Metastases, Nutrition and Cancer

September 1, 2010
Four key studies now propose a new theory about how cancer cells grow and survive, allowing researchers to design better diagnostics and therapies to target high-risk cancer patients. These studies were conducted by a large team of researchers at Thomas Jefferson University’s Kimmel Cancer Center.

This new idea also explains why so many cancer patients say that “their cancer is eating them alive” – an accurate observation that has never been understood, the researchers say.
 

These four new studies, co-published in the September issue of the journal Cell Cycle, provide evidence that and metastasis is directly “fueled” by normal supporting cells.

These supporting cells are called fibroblasts (fibroblast: A cell that gives rise to connective tissue) and they produce the stroma () (Stroma: the connective, functionally supportive framework of a biological cell, tissue, or organ) that surrounds . As the cancer progresses, increasing numbers of these stromal cells eat themselves to provide recycled nutrients to tumor cells – leading to dramatic weight loss in patients.

They also found that without recycled nutrients provided by fibroblasts, tumor cells are more fragile and die. Based on this breakthrough, the researchers propose that available drugs (now on the market), which sever the “parasitic” connection between tumor cells and fibroblasts, may be effective therapeutics.

“We think we have finally figured out how cancer really works – and this reverses 85 years of dogma, upon which current cancer research and therapy is based,” says the study’s senior investigator, Michael P. Lisanti, M.D., Ph.D., Chairman of Jefferson’s Department of Stem Cell Biology & Regenerative Medicine.

The prevailing theory, known as the Warburg Effect, developed by German researcher Otto Warburg in 1924 (for which he won a Nobel prize), says that tumor cells change their metabolism in order to fuel their own growth. As evidence, Warburg pointed to a lack of mitochondria, which are tiny “power plants,” in laboratory cancer cells, saying these cells have found another way to produce the energy they need.

Richard Pestell, MB, BS, MD, Ph.D, FRACP, director of the Kimmel Cancer Center and co-author on these studies notes, “These studies suggest that the absence of mitochondria in laboratory cancer cells may reflect in part that cultured cells have had to adjust to life outside of their original environment, without their stromal partner.” Drs. Lisanti, Pestell and colleagues found this out by performing a simple experiment in which they mixed cancer cells and fibroblasts together, and then searched for mitochondria. The found the fibroblasts didn’t have any mitochondria, and that the cancer cells had all the mitochondria.

“The Warburg Effect is happening, but it is happening to fibroblasts, not to cancer cells. Fibroblasts have no mitochondria because they are eating them to provide energy to cancer cells, and cancer cells have a ton of mitochondria because they need these power plants to process all the recycled nutrients given to them by fibroblasts, which then helps them grow and spread,” Dr. Lisanti says.

They have dubbed this finding “The Reverse Warburg Effect.”

“It’s amazing,” Dr. Lisanti says. “Much of what we know about cancer is backwards because cancer researchers used isolated tumor cells for most cancer studies. Now, when we put cancer cells back in their stromal environment, we see how cancer cells critically depend on fibroblasts for their survival.”

Tumor cells do this by employing oxidative stress as a weapon. Then, oxidative stress in fibroblasts “tricks” these stromal cells into eating themselves to feed cancer cells, the researchers say. This process of “self-eating” or “self-cannibalism” is called autophagy.

During periods of starvation, normal cells undergo autophagy. This metabolic re-programming allows cells to recycle nutrients by continually eating themselves, including their mitochondria. This permits starving cells to recycle nutrients and to survive under hostile conditions.

Now, Dr. Lisanti and colleagues have figured out how cancer cells take advantage of this recycling process. To satisfy their large appetite, hungry cancer cells induce oxidative stress in the fibroblasts and this stress forces the stromal cells to eat themselves, which provides recycled nutrients or “food” to fuel survival of nearby cancer cells.

“It’s that simple. Cancer cells are eating us alive by stealing nutrients from normal cells using oxidative stress, and by employing those recycled nutrients to support their own growth. Stem cells are then recruited from the bone marrow to produce fresh fibroblasts, to continually fuel cancer cell growth,” Dr. Lisanti says. “For years, cancer patients have said they felt as though the cancer in their body was eating them alive. These patients were right. Essentially, the cancer knows how to induce oxidative stress and turns a local wasting process into a whole-body phenomenon.”

Co-author Ubaldo Martinez-Outschoorn, M.D., a medical oncologist at Jefferson says “Patients have been telling us that cancer is eating them alive for years: Now we know they were right!” One of his cancer patients recently said, “Doc, I can’t eat enough food to maintain my weight. No matter how much I eat, I feel tired, and I am always losing weight.”

“Now that we understand the mechanism, this reverses our thinking about cancer metabolism and about how to stop this stress and starve the cancer cells,” he says.

In one of the published studies, Dr. Lisanti shows that using anti-oxidants can prevent oxidative stress in the fibroblasts, thus cutting off the fuel supply to cancer cells, starving them. “We are now performing drug screening assays to discover new anti-oxidants and other molecules like this,” he says.

The researchers have additionally identified two key metabolites – ketones and lactate – produced by the co-opted fibroblasts that provide high-energy food to the cancer cells. This finding also explains a mystery and provides a warning.

The mystery concerns why people with diabetes are much more likely to develop cancer than non-diabetics. The reason, Dr. Lisanti says, is that diabetic patients produce elevated levels of ketones, and he now shows that ketones fuel cancer cell growth.
The warning comes from the common use of lactate, a type of sugar, in cancer patients. Surgeons often give their cancer patients an intravenous solution of lactate before, during, and after surgery, Dr. Lisanti says. “But we see that cancer cells are using energy-rich fuels, such as lactate, to increase their numbers of mitochondria to power cancer cell growth, survival, and metastasis, so surgeons may want to re-consider or stop this practice.”

The findings have led the researchers to question the value of research using isolated laboratory cancer cells – the basis of most cancer research – and the anticancer drugs that result from it.

For example, genetic mutations have long been thought to be the root cause of cancer, but Dr. Lisanti’s group observed that these alterations might be the consequence of the tumor cell’s interactions with the normal stroma. Oxidative stress induced by cancer cells in fibroblasts feeds back upon cancer cells, amplifying the production of reactive oxygen species (ROS). They believe that ROS is then used by cancer cells to mutate their own genes to promote survival.

“These ROS molecules cause DNA damage in the cancer cells, resulting in genomic instability – random mutations and DNA breakage, as well as abnormal chromosome numbers. This instability helps cancer cells evolve into a more aggressive form,” Dr. Lisanti says.

“So, we see three consequences resulting from activating oxidative stress in normal stromal cells,” he says. “First, it forces stromal cells to make food for cancer cells. Second, this abundance of food protects the cancer cells against death. Finally, oxidative stress modifies cancer cell DNA, causing mutations and allowing them to evolve into a more aggressive form.”

Additionally, the researchers say their new theory of stromal metabolic re-programming suggests that cancer cells do not need blood vessels to feed them, which explains why some angiogensis inhibitors (drugs that shut down blood vessel growth) have not worked – and, in fact, may be dangerous.

“If an aggressive cancer cell can use oxidative stress to extract nutrients from normal stromal cells, it can go anywhere without the need for a blood supply. This may be how cancer cells spread all over the body,” Dr. Lisanti says. “Furthermore, angiogenesis inhibitors induce hypoxia, which is low oxygen, in the stroma. This is exactly the condition that drives nutrient recycling via autophagy. So angiogenesis inhibitors may help provide food or recycled nutrients to feed cancer cells. This explains why angiogenesis inhibitors have been very disappointing in clinical trials, as they may be having just the opposite effect, promoting cancer cell growth and metastasis.”

These new findings also have clear implications for cancer diagnosis, the researchers say. Many of the molecules that Dr. Lisanti’s group identified could be used as diagnostics to identify high-risk cancer patients or to monitor the success of their anti-cancer therapy.

Among them is caveolin-1 (Cav-1), which is produced by fibroblasts. Dr. Lisanti had shown earlier that loss of Cav-1 predicts poor prognosis in breast cancer patients, and is linked to early tumor recurrence, metastasis, and drug resistance. He now understands why, as breast cancer patients with absent stromal Cav-1 are feeding their via recycled nutrients. That explains why a loss of stromal Cav-1 is such a good biomarker for identifying high-risk patients.

“The idea that a cancer cell’s local environment is important for tumor growth is now well-accepted by the cancer research community,” Dr. Lisanti says. “Now we show why this notion is correct.”

These studies were funded in part by grants from the NIH/National Cancer Institute, Susan G. Komen for the Cure, The American Cancer Society, The Breast Cancer Alliance, The Falk Medical Research Trust, The Landenberger Research Foundation and The Pennsylvania Department of Health.

Provided by Thomas Jefferson University (news : web)