Proto-oncogenes are normal genes involved in making cells differentiate and divide. When these genes are mutated, they are then called oncogenes. Proto-oncogenes involved in breast cancer are mostly those that cause more cell division by making the cell cycle go faster and accelerate. They are involved in pushing cell division harder, stronger and faster.

One of the proto-oncogenes is related to the epidermal growth factor receptor. This receptor plays a vital role at certain times of the life cycle, such as puberty, when big changes are going on with body growth, wherein a protein known as epidermal growth factor functions to promote cell growth. This protein binds to an epidermal growth factor receptor and signals the cell to grow. When the proto-oncogene for the receptor is over expressed, it doesn’t wait for the epidermal growth factor receptor to tell it to grow. Instead, cells begin to grow independently, just like getting stuck in the “ON” position.

Another type of epidermal growth factor receptor is a subtype, the epidermal growth factor receptor 2. This receptor is more commonly known as Her-2/neu oncogene. The type of genetic alteration that Her-2/neu has in breast cancer is known as amplification. Instead of having only one copy during cell division, the cell makes numerous copies of this gene, about ten to sixty times more. Either the gene over expression or the extra protein can be measured in a woman’s cancer by examining the cancer tissue that has been resected. Since Her-2/neu oncogene encodes a growth factor receptor, it functions in signaling the cells to grow faster and faster, although it is not involved in cancer invasiveness. About 70 to 80 percent breast precancers have over expression of Her-2/neu oncogene. The cancer cells are still contained within the breast duct, but they have been programmed to grow much faster because of the over expression of such oncogene. Although Her-2/neu oncogene was first identified in breast cancer, research is also being done to see if it is also involved in other cancer types such as lung, pancreas and ovary cancer.

For breast cancer to have an invasive nature, it needs more than one genetic alteration. So long as there’s only over expression of Her-2/neu oncogene, the cancer will remain confined within the breast duct. If it requires other forms of genetic alterations, one that causes cancer cells to move out of the ductal region or make new blood vessels (angiogenesis), then it can spread. If the cancer patient has these invasive cancer alterations and one of the accelerated cancer growths, then it is worse. People with both of these genetic alterations have a worse prognosis than with only one type of alteration alone. Cancer not only requires excessive cancer cell proliferation, it also has to invade, grow new blood vessels and spread from the breast area.

One of the fascinating things that have happened in recent years is that there is now an antibody to counteract the Her-2/neu receptor, which can be given intravenously to breast cancer patients. It has quite a unique mechanism of action. It attaches only to cells with too much Her-2/neu receptor, not the normal ones, so that while it antagonizes Her-2/neu cells, it leaves the other cells unaffected. Unlike chemotherapy, with which case most dividing cells are destroyed, it is a targeted therapy. So far, this treatment has been used only in metastatic breast cancer, but it has implications for disease that hasn’t spread yet.

Michael Russell

Your Independent guide to

Tags: breast cancer, cancer patient, chemotherapy, oncogenes

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Tags: breast cancer, cancer patient, chemotherapy, oncogenes

Mesothelioma treatment options depend on many internal factors such as: stage, location, and the patient’s age and desires. Important external factors to consider include the experience level of the oncologist with mesothelioma cases and whether or not a rural dweller would have to be transferred to a larger city for aggressive treatment or palliative care.

Patient survival rate is determined to be up to a year; while some leading cancer centers have reported life expectancy after diagnosis to be as much as five more years.

Screening

Imaging tests allow doctors to see a picture of the cancer site. These tests could include x-rays, CT scans (computed tomography), or MRI (magnetic resonance imaging).

New Screening Instrument: The Mesomark Test

The Food and Drug administration has just approved (January 2007) the world’s first in-vitro test for mesothelioma. The Mesomark assay test, developed by Fujirebio Diagnostics is administered to patients diagnosed with biphasic or epithelioid mesothelioma by a simple blood test. The test measures proteins within the blood that reflect changes in the patient’s tumor volume, a key factor for monitoring patient status and response to therapies.

Traditional Treatment Types

Surgery, removal of the entire lung and a part of the chest lining, the diaphragm and part of the sac surrounding the heart.

Thoracoscopy is the insertion of an endoscope which is a small narrow tube, containing a tiny cameria into the pleural cavity to look directly at the tumor. Pathologist’s perform a biopsy to collect a tissue. Often, chemical pleurodesis (draining fluid in the intrapleural space), can be accomplished during the same procedure.

Mediastinoscopy, another type of surgical incision is sometimes used to stage the extent of disease when enlarged nodes are seen using imaging techniques.

Laproscopy is used in mesothelioma patients when imaging techniques suggest that the tumor has penetrated through the diaphragm. This information is important in evaluating a patient for potential pleurectomy or extrapleural pneumonectomy.

Radiation Therapy (using high-dose x-rays or other high-energy rays to kill cancer cells.

Radiation - Although mesothelioma tumors are highly resistant to radiotherapy, these treatments are sometimes used to relieve symptoms arising from tumor growth, such as obstruction of a major blood vessel.

Radiotherapy is commonly applied to the sites of chest drain insertion, in order to prevent the growth of the tumor along the track in the chest wall.

Chemotherapy – is used to stop the cancer cells from growing and dividing.

Immunotherapy: Heated Intraoperative Intraperitoneal Chemotherapy requires the removal as much of the tumor as possible followed by the direct administration of a heated between (40 and 48°C) chemotherapy agent, into the abdomen for 60 to 120 minutes and then drained.

Palliative Procedures

Pleuroperitoneal Shunt is a procedure where a catheter is placed under the skin from the pleural to the peritoneal cavity. This procedure raising concerns as the catheter can cause damage by embedding itself into the abdomen.

Pleurectomy, a palliative procedure, may be performed when more extensive surgery is not an option. The procedure does not effectively remove all tumors. It is considered the most effective means of controlling pleural effusion (fluid buildup) in cases where the lung’s expansion is restricted by the mesothelioma.

Potentially Curative Procedures

These procedures are performed with “curative intent”.

Pleurectomy/Decortication is usually performed on patients with early stage pleural mesothelioma disease (Stage I and selected Stage II), and attempts to remove all gross tumor.

Extrapleural Pneumonectomy is surgery to remove a diseased lung, part of the pericardium, part of the diaphragm and part of the parietal pleura. This type of surgery is used most often to treat malignant mesothelioma and is combined with traditional chemotherapy and/or radiation, gene therapy, immunotherapy or photodynamic therapy.

Cytoreductive Surgery removes visible tumors in the peritoneal cavity. The remaining cancer cells are treated by Intra-Peritoneal Hyperthermic (heated) Chemotherapy (IPHC) and then delivered to the abdominal cavity.

New or Experimental Therapies

Gene Therapy: The best known tumor suppressor gene is called p53. If this gene is damaged or non existent oncogenes or cancer genes multiply at an abnormal rate. The main focus of gene therapy for mesothelioma involves injecting a virus that has been modified in the laboratory. The virus is injected into the pleural space in the chest, where mesothelioma develops as an attempt to kill the cancer cells.

Drug or Vaccine Therapy

Patients with mesothelioma have much higher levels of vascular endothelial growth factor (VEGF) a chemical controlling blood vessel than people with any other type of cancer. Trials are being conducted to see if VEGF can be blocked, thus stopping the growth of blood vessels feeding the mesothelioma tumors.

Bevacizumab is a drug vaccine currently in use. One trial recently reported that this drug may increase survival for patients with lung cancer. An American phase 2 trial tested bevacizumab for mesothelioma, in combination with chemotherapy drugs. Bevacizumab is still in the experimental phase and much larger trials are needed before we will know how effective it will be in treating mesothelioma and other types of cancers.

Photodynamic Therapy (PDT)

In Photodynamic therapy a drug called a photosensitizing agent is injected into the bloodstream and absorbed by the body’s cells rendering the cells sensitive to light. When the area to be treated is exposed to laser light, the cells are killed. PDT has to be combined with surgery to treat patients in the early stages of mesothelioma. PDT is still in the trial stages and very experimental.

Clinical Trials and Eligibility

Clinical Trials provide research by using a sampling of people affected by the cancer. The National Cancer Institute states that the purpose of most listed clinical trials is to test new cancer treatments or new methods of diagnosing, screening for or preventing cancer.

Eligibility requirements for clinical trials are not the same; each study has specific guidelines for participation. Some trials allow participation after other treatments have failed, while others require that the patient did not have prior treatment. Choosing a clinical test should only be done after a medical consultation.

Prevention trials - study ways to reduce the risk, or chance, of developing cancer. Most prevention trials are conducted with healthy people who have not had cancer. These trials use drugs, vitamins or diet to reduce risk of cancer. Some trials are conducted with people who have had cancer and want to prevent the return of cancer (recurrence), or reduce the chance of developing a new type of cancer.

Screening Trials - study ways to detect cancer. They are often conducted to determine whether finding cancer before it causes symptoms decreases the chance of dying from the disease. These trials involve people who do not have any symptoms of cancer.

Diagnostic Cancer Trials - develops new tests or scans

Treatment Trials – studies new drugs or combinations of drugs; new ways of giving treatment, and new types of treatment

Quality of life trials explore ways to improve the comfort and quality of life of cancer patients and cancer survivors. These trials may study ways to help people who are experiencing nausea, vomiting, sleep disorders, depression, or other effects from cancer or its treatment.

Genetics Study Trials - are sometimes part of another cancer clinical trial. The genetics component of the trial may focus on how genetic makeup can affect detection, diagnosis, or response to cancer treatment.

Clinical trials are conducted in 4 phases:

Phase 1 trials look at whether a trial treatment drug is safe or has any harmful effects and attempts to establish the right dosage required.

Phase 2 trials look at the effectiveness of the treatment.

Phase 3 trials test a new treatment against the existing standard treatment. If it yields better results, it may become the new standard treatment.

Phase 4 trials are carried out after a drug has been licensed. They collect information about side effects, safety and the long term risks and benefits of a drug.

Ongoing research attempts to improve mesothelioma treatment options but clinical trials will not all result in new and better treatment. After testing, it may be discovered that the treatment being tested does not work, or that it has worse side affects than existing treatments. But, to researchers and doctors, and in the end for patients, it is crucial to keep this research going.

About the Author:

Dave Casey is a medical writer for Mesothelioma-Adviser.com, an informational guide for mesothelioma-adviser.com/ mesothelioma cancer victims. The site provides guidance on mesothelioma-adviser.com/mesothelioma-treatment-options.html
mesothelioma treatment options and mesothelioma-adviser.com/asbestos-legal-information.html asbestos legal information.

Copyright 2007 Mesothelioma-Adviser.com

Tags: cancer patient, cancer treatment, chemotherapy, lung cancer, mesothelioma, oncogenes, pleural mesothelioma

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Tags: cancer patient, cancer treatment, chemotherapy, lung cancer, mesothelioma, oncogenes, pleural mesothelioma

Cancer. The word itself is alarming. It sounds like a death sentence. In many cases, it is. But it doesn’t necessarily have to be that way. The topic of cancer is so large that we will take at least three or four articles to even begin to touch on the main points. Like any other illness, the more you know about it, the better you’ll be able to deal with it. For example, how much did you know about your own health issues before they touched your life personally? What would you have done differently in your life if you knew that it would prevent the problem from happening? Would you have been willing to make the changes? I imagine that you would. You have that opportunity with cancer. In a series of articles, we’ll cover not only the natural health therapies for cancer but the lifestyle changes that help prevent cancer as well.

The increase in the rate of cancer is amazing. A hundred years ago, 1 in 33 people had cancer; today, 1 in 3 people either have cancer or will develop it. Statistics show that one American life is lost to cancer every 45 seconds. There is no other topic in medicine that has such urgency. So, exactly what is cancer? Basically, it is nature gone overboard. Healthy cells stop functioning properly for a variety of reasons and then begin to reproduce damaged copies of themselves. The natural process of cells multiplying becomes accelerated because these new mutant cells are not regulated by the body’s normal controls. In addition, the life span of these cells is not controlled any longer, meaning that cancer cells become virtually immortal.

There are types and stages of cancer. Of the 150 different types of cancer, there are 5 major groups:
• Carcinomas – solid tumors from cells in the surface of the mouth, nose, throat, lung airways, skin, GI tract, GU tract, breast, and thyroid. Lung, prostate, stomach, skin, colon, and breast cancers are in this type.
• Sarcomas – solid tumor from bones, fat, and other soft tissues such as muscles, tendons, abdomen, heart, central nervous system, and blood vessels. These are the most rare and most deadly of solid tumors.
• Leukemias – a blood-borne cancer type characterized by an abnormal production of white blood cells.
• Lymphomas – solid masses of abnormal white blood cells concentrated in the lymph system. Examples of this type of cancer include Hodgkin’s disease and non-Hodgkin’s lymphomas.
• Myelomas – rare tumors from antibody-producing or blood cell-producing areas in the bone marrow.

Cancer is often described by what stage it is in. Staging in cancer refers to a scale used to determine amount of cancer, its location, size, and degree of containment. The four different levels listed below describe the stages of cancer.
• Stage I – earliest, most curable stage. Local tumor only.
• Stage II – some spreading of cancer to surrounding tissue and maybe nearby lymph nodes.
• Stage III – involves spreading to distant lymph nodes
• Stage IV – most advanced, least easily cured. Cancer has spread to distant organs.

Why do some people get cancer and others don’t? What is the trigger that turns these healthy cells into mutants? What causes cancer? There are at least 33 contributing causes, according to various researchers. Each of these factors could be an article in itself so I’ll just provide you with the list for now. With this information, you can easily research these contributing items to increase your cancer knowledge. The factors that can contribute to cancer are:
1. Sunlight
2. Nuclear Radiation
3. Pesticide/Herbicide Residues
4. Industrial Toxins
5. Polluted Water
6. Tobacco and Smoking
7. Chronic Electromagnetic Field Exposure
8. Hormone Therapies
9. Immune-Suppressive Drugs
10. Irradiated Foods
11. Food Additives
12. Mercury Toxicity
13. Dental Factors
14. Chronic Stress
15. Depressed Thyroid Action
16. Intestinal Toxicity and Digestive Impairment
17. Parasites
18. Viruses
19. Diet and Nutritional Deficiencies
20. Nerve Interference Fields
21. Toxic Emotions
22. Blocked Detoxification Pathways
23. Chlorinated Water
24. Fluoridated Water
25. Ionizing Radiation
26. Geopathic Stress
27. Sick Building Syndrome
28. Free Radicals
29. Cellular Oxygen Deficiency
30. Cellular Terrain
31. Oncogenes
32. Genetic Predisposition
33. Miasm

Now that we have a little background knowledge on cancer, we will begin to cover a wide range of clinically proven natural health therapies that can be helpful for people with various forms of cancer. Each of these types of complementary medicine has a wealth of scientific research available for review, thanks to the ongoing research of the National Institutes of Health (NIH). In addition, each of the therapies is currently available through physicians with outstanding medical backgrounds. The bottom line is that all of the cancer therapies that I will discuss in the next few articles are valid and have been documented in scientific literature.

In upcoming articles, we will explore the use of the following methods for cancer therapy supported by scientific evidence:
• Nutrition – Dietary changes and Anti-Cancer Nutritional Supplements
• Anti-Cancer Herbal Supplements
• Innovative Anti-Cancer Substances
• Physical Support Therapies – Detoxification, Biological Dentistry, Water Therapy, Heat Therapy, Bodywork/Therapeutic Massage/Exercise, Qi Gong
• Energy Support Therapies – Electrodermal Screening, Magnetic Therapy, Light Therapy

In closing, please remember that early detection and prevention is the key to beating cancer. Here are the 8 Early Warning Signs for Cancer. If you experience any of these signs or symptoms, contact your physician immediately.

1. A Lump in the Breast or Testicles.
2. A Change in a Wart or Mole.
3. A Skin Sore or Sore Throat that Does Not Heal.
4. A Change in Bowel or Bladder Habits.
5. A Persistent Cough or Coughing Blood.
6. Constant Indigestion or Trouble Swallowing
7. Unusual Bleeding or Vaginal Discharge
8. Chronic Fatigue

Jerry Ryan, Ph.D. is a Natural Health Coach who teaches individuals and group classes on the scientifically documented benefits of natural health techniques. He is also an internationally published author and has been a guest speaker at such places as NIKE World Headquarters. For more information, his website is JerryRyanPhD.com JerryRyanPhD.com
mailto:DoctorRyan@JerryRyanPhD.com DoctorRyan@JerryRyanPhD.com

Tags: breast cancer, leukemia, lymphoma, oncogenes, prevent cancer

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Tags: breast cancer, leukemia, lymphoma, oncogenes, prevent cancer

Hunting for Genetic Mutations and Cancer
A little background:

1. What is a gene? A gene is an assembly line that produces a protein. A gene is made out of DNA.
2. What are proteins? Proteins are the major building blocks of cells.
3. What is a mutated gene? A mutated gene is a modified assembly line. A modification can take many forms, such as removing an essential part of the assembly line, replacing an important part with junk, etc. Very rarely a mutation is beneficial to the organism (X-Men, Evolution, Lance Armstrong?). In all other cases, a mutated gene is considered damaged DNA.

Current belief:

What is the cause of cancer? The word cause has two meanings. The first refers to the elements in the environment which impact our body, for instance, tobacco, x-ray radiation, asbestos, other chemicals, etc. These elements are usually called carcinogens. Today, hundreds of substances and mixtures are classified as carcinogens. The other meaning of the word cause refers to the internal element of the body which is the first to collapse under the attack of the carcinogens. Let us call this element our “Achilles heel.”

The current belief in medical research holds that most cancers are caused by exposure to carcinogens, and that carcinogens cause cancer by mutating genes. In other words, according to the current belief, the structural integrity of our genes is our Achilles heel, and therefore, the first internal element to collapse under the attack of the carcinogens. This belief is so ingrained that the National Human Genome Research Institute (NHGRI), an institute at the NIH, recently stated that “all cancers are based on genetic mutations in body cells.” Moreover, a search on PubMed, the search engine for scientific papers in life science, with the keywords “Mutation” AND “cancer” produced 86,490 papers and 12,238 reviews. Mutation hunting is also a big business. Look at the NIH budget allocated to discoveries of genetic mutations, the number of biotech companies chasing genetic mutations, the magnitude of the licensing agreements between biotech and pharmaceutical companies aimed to utilize newly discovered genetic mutations, and the number of stories in the media on genetic mutations and their so-called “link” to disease. However, this huge effort and billions of dollars has produced few discoveries and little benefits to the public. The reason for this limited success is simple. The cause of most cancers is not a genetic mutation. Our Achilles heel is not the structural integrity of our genes.

The story of the BRCA1 gene is a typical example of mutation hunting.

The Mystery of BRCA1
Genes, in general, produce proteins, which are the building blocks of cells. The concentration of proteins is tightly regulated. A mutated or physically altered gene produces an abnormal concentration of its protein, which may lead to disease. In 1994, Mark Skolnick, PhD, discovered the BRCA1 gene (BRCA1 is short for BReast CAncer 1). Following the discovery, scientists observed an abnormally low level of the BRCA1 protein in breast cancer tissues. The BRCA1 protein is a cell cycle suppressor, which means that the protein prevents cell replication. This observation created a lot of excitement. At the time, scientists believed that they were on the verge of finding the cause of breast cancer. The reasoning was that breast cancer patients must have a mutated BRCA1 gene, that is, a defected BRCA1 assembly line, which would explain the decreased production of the protein, and the excessive replication of breast cancer cells in tumors.

In the United States, 180,000 cases of breast cancer are diagnosed each year. However, the BRCA1 gene is mutated in less than 5% of these cases. In more than 95% of breast cancer patients the gene is not mutated, the assembly line is not defected.

So here is the mystery. If the gene is not mutated in the great majority of the breast cancer patients, why are the tumors showing low levels of the BRCA1 protein? Today, this is one of the biggest mysteries in cancer research.

The BRCA1 gene is not unique. Many normal (perfect shape, non-mutated) genes exhibit a mysterious abnormal (increased or decreased) production of proteins in cancer. Moreover, studies also report abnormal gene expression of normal genes in other diseases, such as atherosclerosis, obesity, osteoarthritis, type II diabetes, alopecia, type I diabetes, multiple sclerosis, asthma, lupus, thyroiditis, inflammatory bowel disease, rheumatoid arthritis, psoriasis, atopic dermatitis, and graft versus host disease.

According to Dr. Raxit J. Jariwalla in his European Journal of Cancer paper: (Jariwalla RJ. Microcompetition and the origin of cancer. Eur J Cancer. 2005 Jan;41(1):15-9): “The prevalent view of the nature of cancer holds that it is a complex genetic process resulting from the progressive accumulation of mutations in specific cellular genes, such as proto-oncogenes or tumor-suppressor genes, leading to perturbations in processes involving signal transduction, cell cycle regulation, and/or apoptosis. Genetic instability in tumors has been known for decades, however, the role of genomic instability in causing and promoting tumor growth remains controversial. Furthermore, although many studies report abnormal gene expression in cancer cells, often, no mutations or chemical modifications are observed around the locus of the dysregulated gene(s), suggesting that a genetic alteration is not the initiating event of cancer.”

So what is the cause of most cancers, and how do carcinogens cause cancer? You can find the answer to these questions at causeofcancer.org/

John S. Boyd, Ph.D.
The Center for the Biology of Chronic Disease (see cbcd.net/ cbcd.net/), and causeofcancer.org (see causeofcancer.org/ causeofcancer.org/), Rochester, NY

We are a 501(c)3 not-for-profit organization that specializes in researching the biology of chronic disease. By “the biology of chronic disease” we mean the original disruption that causes the disease, and the sequence of events that lead from the original disruption to the development of clinical symptoms. We hope that once the biology is clear, pharmaceutical and biotech companies will be able to formulate drugs that reverse the effects of the disruption, and therefore cure the disease, or even block the original disruption, and therefore prevent the disease from developing in healthy individuals.

Tags: breast cancer, cancer patient, oncogenes

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Tags: breast cancer, cancer patient, oncogenes

Hunting for Genetic Mutations and Cancer
The current paradigm in medical research holds that the cause of most cancers is a genetic mutation. For instance, according to the National Human Genome Research Institute (NHGRI), an institute at the NIH, “all cancers are based on genetic mutations in body cells.” In fact, mutation hunting is big business. Just look at the NIH budget allocated to discoveries of genetic mutations, the number of biotech companies chasing genetic mutations, the magnitude of the licensing agreements between biotech and pharmaceutical companies aimed to utilize newly discovered genetic mutations, and the number of stories in the media on genetic mutations and their so-called “link” to disease. However, this huge effort and billions of dollars has produced few discoveries and little benefits to the public. The reason for this limited success is simple. The cause of cancer is not a genetic mutation.

The story of the BRCA1 gene is a typical example of mutation hunting.

The Mystery of BRCA1
Genes, in general, produce proteins, which are the building blocks of cells. The concentration of the protein is tightly regulated. A mutated gene produces an abnormal concentration of its protein, which may lead to disease. In 1994, Mark Skolnick, PhD, discovered the BRCA1 gene (BRCA1 is short for BReast CAncer 1). Following the discovery, scientists observed an abnormally low level of the BRCA1 protein in breast cancer tissues. The BRCA1 protein is a cell cycle suppressor, which means that the protein prevents cell replication. This observation created a lot of excitement. At the time, scientists believed that they were on the verge of finding the cause of breast cancer. The reasoning was that breast cancer patients must have a mutated BRCA1 gene, which would explain the decreased production of the protein, and the excessive replication of breast cancer cells in tumors.

In the United States, 180,000 cases of breast cancer are diagnosed each year. However, the BRCA1 gene is mutated in less than 5% of these cases. In more than 95% of breast cancer patients the gene is not mutated.

So here is the mystery. If the gene is not mutated in the great majority of the breast cancer patients, why are the tumors showing low levels of the BRCA1 protein? Today, this is one of the biggest mysteries in cancer research.

The BRCA1 gene is not unique. Many normal (non-mutated) genes exhibit a mysterious abnormal (increased or decreased) production of proteins in cancer. Moreover, studies also report abnormal gene expression of normal genes in other diseases, such as atherosclerosis, obesity, osteoarthritis, type II diabetes, alopecia, type I diabetes, multiple sclerosis, asthma, lupus, thyroiditis, inflammatory bowel disease, rheumatoid arthritis, psoriasis, atopic dermatitis, and graft versus host disease.

According to Dr. Raxit J. Jariwalla in his paper published in the European Journal of Cancer (Jariwalla RJ. Microcompetition and the origin of cancer. Eur J Cancer. 2005 Jan;41(1):15-9): “The prevalent view of the nature of cancer holds that it is a complex genetic process resulting from the progressive accumulation of mutations in specific cellular genes, such as proto-oncogenes or tumor-suppressor genes, leading to perturbations in processes involving signal transduction, cell cycle regulation, and/or apoptosis. Genetic instability in tumors has been known for decades, however, the role of genomic instability in causing and promoting tumor growth remains controversial. Furthermore, although many studies report abnormal gene expression in cancer cells, often, no mutations or chemical modifications are observed around the locus of the dysregulated gene(s), suggesting that a genetic alteration is not the initiating event of cancer“.

The Discovery
A virus is a collection of genes. To replicate, some viruses settle in the nucleus of the host cell and use the cell machinery to replicate. What is the effect of a viral gene on the production of cellular proteins?

Think of a gene as an assembly line of a protein. Like all assembly lines, the gene has two parts, a conveyor (the gene coding section), and a control panel (the gene promoter/enhancer). Imagine a cellular shop that assembles a product called BRCA1. One of the many buttons on the control panel is called N-box. Pressing the button increases production. However, only a small number of operators (called transcription factors), those who pass a special certification (called the p300 test), have permission to press this button. What happens when a virus opens a shop across the street from the cellular shop (called latent infection) to produce its viral products? The control panel in the viral shop also has an N-box button. To start production, the virus begins to hire away some of the certified operators. What is the effect of this “hiring away” on the number of available BRCA1 units? The number decreases. Moreover, the decrease becomes apparent even before the virus starts production (the “hiring away” is what creates the effect, not the viral proteins). The viral assembly line competes with the BRCA1 assembly line for the certified operators, and by hiring them away prevents the cellular shop from producing the optimum, or “healthy” number of BRCA1 units. The lower number of BRCA1 units leads to excessive cell replication and breast cancer. (See a more technical description in a recent paper published in the European Journal of Cancer.)

The infection with the latent virus causes abnormal production of other genes, and as a result, the development of other chronic diseases. This sequence of events easily explains why people who suffer from obesity are also more likely to suffer from diabetes, cancer, and heart disease, and why a recent large scale study found that a low-fat diet does not protect against breast cancer. It also explains another surprising observation that male pattern baldness is associated with heart disease and prostate cancer. In general, this sequence of events easily explains the numerous observations indicating a co-existence or co-morbidity of some chronic diseases.

This discovery was first described by Dr. Hanan Polansky in his book, cbcd.net/book.htm Microcompetition with Foreign DNA and the Origin of Chronic Disease, published by The Center for the Biology of Chronic Disease.

In his European Journal of Cancer, Dr. Raxit J. Jariwalla reports an interesting observation on the microcompetition discovery: “The key point of the theory is that the competing DNA sequences do not bind each other but compete for binding to a limiting transcription complex. In the example cited, the viral DNA and BRCA1 do not bind each other but compete for binding to the limiting GABP*p300/cbp transcription complex. It is interesting that when explaining observations reported in the literature, biologist tend to rely on the traditional physicochemical philosophy which centers on binding/non-binding events, or physical contact between molecules. In contrast, microcompetition with foreign DNA, which in essence is a reallocation of a rare resource, seem to draw on economic rather than physicochemical principles.”

To summarize: the cause of cancer, and other chronic diseases, is not a genetic mutation, it is a reallocation of scarce genetic resources caused by the presence of latent viral DNA sequences (or other types of foreign DNA).

Reaction of the Scientific Community
What is the scientific community saying about Dr. Polansky’s discovery?

Consider what the famous heart surgeon and “Living Legend,” Michael E. DeBakey, said about the discovery, “The theory underlying the basic concept concerning the origin of chronic diseases presented by Dr. Polansky is most interesting, indeed fascinating … Perhaps a symposium could be held to provide a forum for further discussions and critiques of this fascinating theory.”

Elena N. Naumova, PhD, Associate Professor, Department of Family Medicine and Community Health, Tufts University School of Medicine, said, “Dr. Polansky’s work compellingly demonstrates a framework that could bring together researchers from different fields. His proposed theory will work its magic by clarifying ambiguous definitions, identifying similarities and differences in various biological processes, and discovering new pathways … I believe that Dr. Polansky’s book will catalyze the scientific learning process, promote interdisciplinary cross-fertilization, stimulate development of treatment strategies and drug discovery, and leave the reader inspired.”

Sivasubramanian Baskar, PhD, Senior Scientist from the National Cancer Institute, NIH, said, “At first, I wish to congratulate Dr. Hanan Polansky for his scientific bravery to take such a unique, novel approach to further stimulate our understanding of the origin and establishment of chronic diseases. The philosophy underscored is an excellent one … The amazing correlation between theoretical predictions and observed in vivo effects seems to bring us a step closer to a deeper understanding of such complex biologic processes.”

Marc Pouliot, PhD, Assistant Professor, Department of Anatomy and Physiology, Faculty of Medicine, Université Laval, Canada, said, “The concept of microcompetition will change our approach in the study of chronic diseases and will furthermore give scientists a higher level of understanding in biology. Presentation of this concept undoubtedly provides a new set of opportunities for attacking chronic diseases … They lead the way to new approaches in chronic disease treatment.”

Howard A. Young, PhD, Section Head, Cellular and Molecular Immunology Section, Laboratory of Experimental Immunology, National Cancer Institute, NIH, said, “In summary, Dr. Polansky is to be applauded for his attempt to provide a unifying basis for chronic diseases. His theories are stimulating and offer a basis for experimental testing and possible treatment.”

Michael J. Gonzalez, PhD, Professor, Medical Sciences, University of Puerto Rico, said, “I know this book will profoundly impact medical research, drug discovery, as well as natural therapies. I also believe it will benefit the scientific community and society in general by providing further means of treatment for conditions in which only palliative care is available.”

You can find more reactions and the biographies the scientists reacting to Dr. Polansky’s discovery on the publisher’s website at cbcd.net/.

Hope for Cure and Protection
The significance of Dr. Polansky’s discovery cannot be overstated. For the first time, we can start to feel a little better about these diseases. With his discovery, pharmaceutical and biotech companies can now start to design medications that will target the cause of the disease rather than its symptoms, and therefore, cure the sick and protect the healthy from these deadly diseases.

John S. Boyd, Ph.D.
cbcd.net/ The Center for the Biology of Chronic Disease, and causeofcancer.org/ causeofcancer.org, Rochester, NY

We are a 501(c)3 not-for-profit organization that specializes in researching the biology of chronic disease. By “the biology of chronic disease” we mean the original disruption that causes the disease, and the sequence of events that lead from the original disruption to the development of clinical symptoms. We specialize in researching this biology. We hope that once the biology is clear, pharmaceutical and biotech companies will be able to formulate drugs that reverse the effects of the disruption, and therefore cure the disease, or even block the original disruption, and therefore prevent the disease from developing in healthy individuals.

Tags: breast cancer, cancer patient, oncogenes, prostate cancer

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Tags: breast cancer, cancer patient, oncogenes, prostate cancer