Mycoplasmas - Stealth Pathogens

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Mycoplasmas - Stealth Pathogens 7/14/01-

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Mycoplasmas - Stealth Pathogens

 

Mycoplasmas are a specific and unique species of bacteria - the smallest

free-living organism known on the planet. The primary differences between

mycoplasmas and other bacteria is that bacteria have a solid cell-wall

structure and they can grow in the simplest culture media.

 

Mycoplasmas however, do not have a cell wall, and like a tiny jellyfish with

a pliable membrane, can take on many different shapes which make them

difficult to identify, even under a high powered electron microscope.

Mycoplasmas can also be very hard to culture in the laboratory and are often

missed as pathogenic causes of diseases for this reason.

 

The accepted name was chosen because Mycoplasmas were observed to have a

fungi-like structure (Mycology is the study of fungi - hence " Myco " ) and it

also had a flowing plasma-like structure without a cell wall - hence

" plasma " . The first strains were isolated from cattle with arthritis and

pleuro-pneumonia in 1898 at the Pasteur Institute.

 

The first human strain was isolated in 1932 from an abscessed wound.

 

The first connection between mycoplasmas and rheumatoid diseases was made in

1939 by Drs. Swift and Brown.

 

Unfortunately, mycoplasmas didn't become part of the medical school

curriculum until the late 1950's when one specific strain was identified and

proven to be the cause of atypical pneumonia, and named Mycoplasma

pneumonia.

 

The association between immunodeficiency and autoimmune disorders with

mycoplasmas was first reported in the mid 1970s in patients with primary

hypogammaglobulinemia (an autoimmune disease) and infection with four

species of mycoplasma that had localized in joint tissue. Since that time,

scientific testing methodologies have made critical technological progress

and along with it, more mycoplasma species have been identified and recorded

in animals, humans and even plants.

 

While Mycoplasma pneumonia is certainly not the only species causing disease

in humans, it makes for a good example of how this stealth pathogen can move

out of it's typical environment and into other parts of the body and begin

causing other diseases. While residing in the respiratory tract and lungs,

Mycoplasma pneumonia remains an important cause of pneumonia and other

airway disorders, such as tracheobronchitis, pharyngitis and asthma.

 

When this stealth pathogen hitches a ride to other parts of the body, it is

associated with non-pulmonary manifestations, such as blood, skin, joint,

central nervous system, liver, pancreas, and cardiovascular syndromes and

disorders. Even as far back as 1983, doctors at Yale noted:

 

" Over the past 20 years the annual number of reports on extrapulmonary

symptoms during Mycoplasma (M.) pneumoniae disease has increased. Clinical

and epidemiological data indicate that symptoms from the skin and mucous

membranes, from the central nervous system, from the heart, and perhaps from

other organs as well are not quite uncommon manifestations of M. pneumoniae

disease. " (15)

 

This single stealth pathogen has been discovered in the urogenital tract of

patients suffering from inflammatory pelvic disease, urethritis, and other

urinary tract diseases. (8)

 

It has been discovered in the heart tissues and fluid of patients suffering

from cardititis, pericarditis, tachycardia, hemolytic anemia, and other

coronary heart diseases.(9, 10, 14) It has been found in the cerebrospinal

fluid of patients with meningitis and encephalitis, seizures, ALS,

Alzheimer's and other central nervous system infections, diseases and

disorders.(11-13)

 

It has even been found regularly in the bone marrow of children with

leukemia.(16- 18) It is amazing that one single tiny bacteria can be the

cause of so many seemingly unrelated diseases in humans. But as with all

mycoplasma species, the disease is directly related to where the mycoplasma

resides in the body and which cells in the body it attaches to or invades.

 

Today, over 100 documented species of mycoplasmas have been recorded to

cause various diseases in humans, animals, and plants.

 

Mycoplasma pneumonia as well as at least 7 other mycoplasma species have now

been linked as a direct cause or significant co-factor to many chronic

diseases including, rheumatoid arthritis, Alzheimer's, multiple sclerosis,

fibromyalgia, chronic fatigue, diabetes, Crohn's Disease, ALS, nongonoccal

urethritis, asthma, lupus, infertility, AIDS and certain cancers and

leukemia, just to name a few.(1-6)

 

In 1997, the National Center for Infectious Diseases, Centers for Disease

Control and Prevention's journal, Emerging Infectious Diseases, published

the article, Mycoplasmas: Sophisticated, Reemerging, and Burdened by Their

Notoriety, by Drs. Baseman and Tully who stated:

 

" Nonetheless, mycoplasmas by themselves can cause acute and chronic diseases

at multiple sites with wide-ranging complications and have been implicated

as cofactors in disease. Recently, mycoplasmas have been linked as a

cofactor to

 

AIDS pathogenesis and to malignant transformation, chromosomal aberrations,

the Gulf War Syndrome, and other unexplained and complex illnesses,

including chronic fatigue syndrome, Crohn's disease, and various

arthritides. "

 

Mycoplasmas, unlike viruses, can grow in tissue fluids (blood, joint, heart,

chest and spinal fluids) and can grow inside any living tissue cell without

killing the cells, as most normal bacteria and viruses will do.

 

Mycoplasmas are frequently found in the oral and genito-urinary tracts of

normal healthy people and are found to infect females four times more often

than males, which just happens to be the same incidence rate in rheumatoid

arthritis, fibromyalgia, Chronic Fatigue and other related disorders.(7)

Mycoplasmas are parasitic in nature and can attach to specific cells without

killing the cells and thus their infection process and progress can go

undetected.

 

In some people the attachment of mycoplasmas to the host cell acts like a

living thorn; a persistent foreign substance, causing the host's immune

defense mechanism to wage war. This allergic type of inflammation often

results in heated, swollen, and painful inflamed tissues, like those found

in rheumatoid diseases, fibromyalgia and many other autoimmune disorders

like lupus and MS, Crohn's and others.

 

In such cases the immune system begins attacking itself and/or seemingly

healthy cells. Some species of mycoplasmas also have the unique ability to

completely evade the immune system. Once they attach to a host cell in the

body, their unique plasma and protein coating can then mimic the cell wall

of the host cell and the immune system cannot differentiate the mycoplasma

from the body's own host cell.

 

Mycoplasmas are parasitic in nature because they rely on the nutrients found

in host cells including cholesterol, amino acids, fatty acids and even DNA.

 

They especially thrive in cholesterol rich and arginine-rich environments.

Mycoplasmas can generally be found in the mucous membrane in the respiratory

tract. They need cholesterol for membrane function and growth, and there is

an abundance of cholesterol in the bronchial tubes of the respiratory tract.

Once attached to a host cell, they then begin competing for nutrients inside

the host cells.

 

As nutrients are depleted, then these host cells can begin to malfunction,

or even change normal functioning of the cell, causing a chain reaction with

other cells (especially within the immune and endocrine systems).

Mycoplasmas can even cause RNA and DNA mutation of the host cells and have

been linked to certain cancers for this reason.

 

Mycoplasmas can also invade and live inside host cells which evade the

immune system, especially white blood cells. Once inside a white blood cell,

mycoplasmas can travel throughout the body and even cross the blood/brain

barrier, and into the central cervous system and spinal fluid.

 

 

 

Footnotes

Baseman, Joel, et.al., Mycoplasmas: Sophisticated, Reemerging, and Burdened

by Their Notoriety, CDC, Journal of Infectious Diseases, Vol 3, No.1, Feb

1997

S-C. Mycoplasmas and AIDS. In: Maniloff J, McElhaney RN, Finch LR, Baseman

JB, editors. Mycoplasmas: molecular biology and pathogenesis. Washington

(DC): American Society for Microbiology, 1992:525-45.

 

Nicolson G, Nicolson NL. Diagnosis and treatment of mycoplasmal infections

in Gulf War illness-CFIDS patients. Intl J Occup Med Immunol Toxicol

1996;5:69-78.

 

Wear DJ, et.al. Mycoplasmas and oncogenesis:persistent infection and

multistage malignant transformation. Proc Natl Acad Sci USA

1995;92:10197-201.

 

Ekbom A, Daszak P, Kraaz W, Wakefield AJ. Crohn's disease after in-utero

measles virus exposure. Lancet 1996;348:516-7.

 

Taylor-Robinson D. Mycoplasmas in rheumatoid arthritis and other human

arthritides. J Clin Pathol 1996;49:781-2.

 

Dr.Harold Clark, The Intercessor, June 1993, The Road Back Foundation,

Delaware OH.

 

Goulet M, et.al., Isolation of Mycoplasma pneumoniae from the human

urogenital tract. J Clin Microbiol 1995;33:2823-5

 

Daxbock F, et.al., Severe hemolytic anemia and excessive leukocytosis

masking mycoplasma pneumonia. Ann Hematol. 2001 Mar;80(3):180-2.

 

Higuchi ML, et.al., Detection of Mycoplasma pneumoniae and Chlamydia

pneumoniae in ruptured atherosclerotic plaques. Braz J Med Biol Res. 2000

Sep;33(9):1023-6.

 

Socan M, Neurological symptoms in patients whose cerebrospinal fluid is

culture- and/or polymerase chain reaction-positive for Mycoplasma

pneumoniae. Clin Infect Dis. 2001 Jan 15;32(2):E31-5.

 

Bencina D, et.al., Intrathecal synthesis of specific antibodies in patients

with invasion of the central nervous system by Mycoplasma pneumoniae. Eur J

Clin Microbiol Infect Dis. 2000 Jul;19(7):521-30

 

Smith R, et.al., Neurologic manifestations of Mycoplasma pneumoniae

infections: diverse spectrum of diseases. A report of six cases and review

of the literature. Clin Pediatr (Phila). 2000 Apr;39(4):195-201.

 

Umemoto M, Advanced atrioventricular block associated with atrial

tachycardia caused by Mycoplasma pneumoniae infection. Acta Paediatr Jpn.

1995 Aug;37(4):518-20.

 

Lind K. Manifestations and complications of Mycoplasma pneumoniae disease: a

review.Yale J Biol Med. 1983 Sep-Dec;56(5-6):461-8.

 

Alexander FE. Is Mycoplasma Pneumonia associated with childhood acute

lymphoblastic leukemia? Cancer Causes Control. 1997 Sep;8(5):803-11.

 

Hall JE, Mycoplasma pneumonia in acute childhood leukemia. Pediatr Pulmonol.

1985 Nov-Dec;1(6):333-6.

 

Murphy WH, Gullis C, Dabich L, Heyn R, Zarafonetis CJD. Isolation of

Mycoplasma from leukemic and nonleukemia patients. J Nat Cancer Inst

1970;45:243-51.

 

 

 

How Mycoplasmas Interact In The Body

To understand how mycoplasmas can cause widespread disease, we must first

look at the species' unique properties and interactions with host cells.

Unlike viruses and bacteria, mycoplasmas are the smallest free-living and

self-duplicating microorganisms, as they don't require living cells to

replicate their DNA and growth.

Mycoplasmas are able to hide inside the cells of the host (patient) or to

attach to the outside of host cells.

Whether they live inside or outside the host cell, they depend on host cells

for nutrients such as cholesterol, amino acids, etc. They compete with the

host cells for these nutrients which can interfere with host cell function

without killing the host cell.

A mycoplasma has very little DNA of its own, but is capable of using DNA

from a host cell. When a mycoplasma takes over the DNA of the host cell,

anything can happen - including causing that cell to malfunction in many

different ways and/or die, or can cause DNA mutation of the host cell.

Mycoplasmas attach to host cells with a tiny arm coated in protein which

attaches to the protein coating of host cells. For this reason, antibiotics

like tetracycline, which are classified as " protein synthesis inhibitors "

are often used against mycoplasma infections. While these antibiotics may

block this protein attachment and very slowly starve it from the nutrients

it needs from host cells to thrive and replicate, it still takes a healthy

immune system to actually kill the mycoplasma for good.

Mycoplasmas are highly adaptable to changing environments and can move

anywhere in the body, attaching to or invading virtually any type of cell in

the body.

The mycoplasma adhesion proteins are very similar to human proteins. Once

adhered to the host cell, the mycoplasma can completely mimic or copy the

protein cell of the host cell. This can cause the immune system to begin

attacking the body's own cells; an event that happens in all autoimmune

diseases.

Certain Mycoplasma species can either activate or suppress host immune

systems, and they may use these activities to evade host immune responses.

Mycoplasmas can turn on the chain reaction called an immune system response.

This includes the stimulation of pro-inflammatory cytokines (chemical

messengers of the immune system) which is generally found in most autoimmune

and inflammatory diseases and disorders.

Mycoplasma can also attach to or invade immune system cells, like the very

phagocytes (natural killer cells) that are supposed to kill them. Inside

these phagocytes, they can be carried to new locations of inflammation or

disease - hidden away like a spy who has infiltrated the defending army.

When a mycoplasma attaches to a host cell, it generates and releases

hydrogen peroxide and superoxide radicals which cause oxidative stress and

damage to the surrounding tissues.

 

The Main Human Mycoplasma Pathogens

Pathogen / Implicated Disease (1-6)

Mycoplasma genitalium Arthritis, chronic nongonococcal urethritis, chronic

pelvic inflammatory disease, other urogenital infections and diseases,

infertility, AIDS/HIV

Mycoplasma fermentansArthritis, Gulf War Syndrome, Fibromyalgia, Chronic

Fatigue Syndrome, Lupus, AIDS/HIV, autoimmune diseases, ALS, psoriasis and

Scleroderma, Crohn's and IBS, cancer, endocrine disorders, Multiple

Sclerosis, diabetes

Mycoplasma salivariumArthritis, TMJ disorders, Eye and ear disorders and

infections, gingivitis, periodontal diseases including even cavities.

Mycoplasma hominis and Ureaplasma urealyticum Two mycoplasmas commonly found

in the urogenital tracts of healthy persons. However, over the years, the

pathogenic roles of these mycoplasmas have been proven in adult urogenital

tract diseases, neonatal respiratory infections, and a range of other

diseases usually in immunocompromised patients.

Mycoplasma pneumonia Pneumonia, asthma, upper and lower respiratory

diseases, heart diseases, leukemia, CNS disorders and diseases, urinary

tract infections, Crohn's and Irritable Bowel Syndrome, autoimmune diseases.

Mycoplasma incognitus and

Mycoplasma penetrans AIDS/HIV, urogenital infections and diseases,

Autoimmune disorders and diseases

Mycoplasma pirum Urogenital infections and diseases, AIDS/HIV

 

DR. MERCOLA'S COMMENT:

One can use the protocol I modified to treat rheumatoid arthritis.

It has also become quite obvious and clear that NST is one of the most

useful therapies as it helps to rebalance the autonomic nervous system and

secondarily the immune system so it can defeat stealth pathogens like

mycoplasma.