Fungal Illness Part III

I would like to continue Dr. Marinkovich's treatise on fungal illness. There will be one more excerpt to come which talks about the various therapies. If you would like to see the first two excerpts see "5 days in 1 house" from Feb. 21 and "Fungal Illness" from Feb. 14. :

C. Hypersensitivity
The human immune response, part of the body’s system of adaptive immunity can be amazingly sensitive. A person allergic to cats can sense the presence of cat dander in a room months after the cat has departed. And rarely, one reads of a sudden death from anaphylaxis provoked by exposure to a tiny amount of antigen such as vespid venom from a single bee sting or the steam rising from a fish stew, or tiny particles of peanut contaminating a package of almonds processed on machinery previously used to process peanuts (Samson, 1992). The extreme sensitivity potential of the immune system is rarely seen but frightening when it occurs. When the number of individuals exposed to such spore levels is very high, as seems to be the case today in homes, schools and workplaces, a significant number of cases will occur. To deny this is akin to denying the existence of significant pollen or cat allergies because the great majority of people do not show such symptoms on exposure. Genetic polymorphism is the basis for a considerable number of differences within the human population and the immune response, based on the same mechanisms, shows the same wide variations in response among individuals.

V. Symptoms

While the symptoms seen in patients exposed to high ambient levels of fungal elements can vary a great deal among different individuals, a fairly consistent pattern of illness is seen in patients presenting with sufficient symptoms to warrant seeing a physician. Most patients describe a progression of symptoms beginning a few months to a few years after the onset of exposure (e.g., moving into a mold-infested house). Initially the complaints are nasopharyngeal (sore throats, hoarseness, stuffy nose, transient hearing loss), or pulmonary (cough, wheezing, shortness of breath). With time, symptoms progress to include headaches, fatigue, rashes, vertigo, muscle and joint pain, fever, recurrent sinus or ear infections, etc (Rylander, 1994). Many of these symptoms are the result of an overactive immune system trying desperately to overcome what it perceives to be an overwhelming infection. The immune system generates antibodies to the absorbed materials (or antigens). These antibodies react with the antigens to form immune complexes, which is all part of the body’s normal immune elimination function. These complexes are quickly taken up by scavenger cells, which remove the complexes from the circulation thus limiting their inflammatory effects. When complex formation continues over a long period of time, this clearing mechanism can become overloaded. The complexes then remain in the blood stream causing myriad symptoms, known to clinical immunologists as serum sickness or immune complex disease (Cochrane et al., 1973). To the patient, the symptoms appear to be a severe, unrelenting flu syndrome. When one looks up in the older literature the classical symptoms seen in serum sickness, they are exactly those symptoms the patients with fungal illness describe to their physician (Von Pirquet, 1951).

Since hypersensitivity states develop only after relatively long exposure times, normal children under ten years of age do not have significant antibody titers to fungi. However, when children experience very high exposure levels in the home or school, measurable antibody levels appear rather quickly, i.e., within a few months of exposure. Normal mature adults living in temperate or tropical climates commonly show antibody activity toward fungi and experience symptoms following unusual exposures. The onset of symptoms often follow exposures by one or two days, are not recognized for what they are, and are likely to be diagnosed as a virus infection.

VI. Mycotoxins

Mycotoxins are the most respected of fungal products for their potential to cause serious illness through their direct biochemical action on key body functions (Johanning et al., 1996) (Croft et al., 1986) (Leino et al., 2003). The immune system is not involved. One of these, aflatoxin, is known to be among the most potent of carcinogens. Another group, trichothecenes, are toxins released by the fungus Stachybotris atra (also known as Chartarum) as well as others. There is controversy regarding the role of trichothecene mycotoxins in pulmonary hemosideroisis (Dearborn et al., 1999). Other toxins can affect various hormonal, neurological and other body functions to produce serious health effects (Sorensen, 1999). They are so effective in certain biological activities that they have been harnessed by the pharmaceutical and food industries for commercial use such as antibiotics, immune suppressants to control graft rejection, medicine for cholesterol control, and enzymes used in food processing and preservation. Mycotoxins are produced by fungi under specific growth conditions and their role in human illness is not well understood. Exposure to certain mycotoxins producing organisms such as Stachybotrys seem to cause neurological damage seen as short-term memory loss, cognitive dysfunction, inability to concentrate and “fuzzy thinking”. There are common complaints of patients with fungal illness. The changes seem to be reversible, at least in part, but they can take years to resolve. Hyperactive immune systems responding to the influx of fungal antigens following chronic exposures are much more likely to be a cause of symptoms in most individuals

VII. The role of IgE and non-IgE


Allergists have accepted the role that fungal spores can play in eliciting allergy symptoms in susceptible individuals. This is akin to the effects of other airborne organic particles such as pollen, animal dander and insect dust The illness affects only individuals programmed genetically to make large quantities of specific IgE antibodies on exposure to relatively small amounts of allergen. This is type I immunopathology as defined by Gell and Coomb (Gell et al., 1964) and involves the release of pre-formed histamine and other biologically active cytokines from sensitized mast cells and basophils. Symptoms include watery nasal discharge, sneezing paroxysms, itching of the naso-oro-pharyngeal mucosa and tearing eyes, and can be significantly disabling. Symptoms disappear quickly upon cessation of exposure, leaving little, or no, residual effects. It has been suggested that perhaps five percent of the population may be affected in this way by fungi, although those numbers will vary in different climates (e.g., more in Florida than New Mexico). The great majority of patients presenting with symptoms of fungal illness do not show IgE antibody to the fungus (Fink, 1984). This may be the result of isotype switching from IgE to IgG production as stimulation of the immune system increases. When this happens far more elaborate and damaging immune responses can be generated by the body following exposure to large amount of fungal particles, especially when the exposure is chronic. These illnesses were originally described in association with various occupational exposures in unprotected workers such as farmer’s lung, bagassosis in sugar cane workers, and many others. More recently such conditions have been identified and studied in office workers whose workplace is contaminated by fungi, especially in buildings with closed ventilation systems (Fink, 1984), in individuals exposed to swamp coolers (Marinkovich et al., 1975) or contaminated air conditioners in the home (Bavaszak et al., 1970), and in many other school, home and workplace exposures, generally as case reports involving a few patients per report (Cakmak et al., 2002) (Hodgeson et al., 1998) (Dales et al., 1991). These symptoms can occur in all individuals with normal immunity because they are ultimately manifestations of a robust immune response to a heavy unrelenting airborne fungal load with consequential overload of clearing mechanisms or macrophages, and the activation of inflammatory processes.

Although the general immune response to a heavy fungal antigen exposure may consist of all the immunoglobulin isotopes (IgA, IgM, IgG, IgD and IgE) plus sensitized lymphocytes or T-cells, specific IgG is the most efficient single marker of generalized immune responses. Specific IgG antibody levels to fungi are not diagnostic when taken alone. However, antibody levels to fungi are directly proportional to levels of exposure in any individual, and generally high exposure levels result in high antibody titers. These antibody levels drop when the patient’s exposure to the offending fungi ends. When elevated, they are helpful in arriving at the presumptive diagnosis and repeat measurements at four to six month intervals help verify compliance with the fungal avoidance program and helps monitor the success of therapy.
A. Immune Complexes

The presence of antibody in the serum is not pathologic in itself. All the immunoglobulins normally present in the tissues, with possible rare exceptions, are antibodies and they contribute to the immune state. It is only when antigen(s) combines with antibody(ies) that immune complexes are formed and a potentially pathologic state is initiated. Immune complexes are not stable since the union is one of complimentary surface configurational attraction between two or more molecules produced by Van der Wall forces. The complexes can easily be disrupted as the conditions in solution change. Changes in temperative, relative numbers of reacting molecules, their nature, the epitope specificity of the reacting antibodies, etc., can all effect changes in the size, shape, surface charges, solubility, of the complex. These factors are the ones that determine the inflammatory potential of the complexes formed and whether the complexes will tend to be deposited in kidneys, joints, blood vessel walls, skin, lungs, etc. (Cochrane et al., 1973). Because of the inherent instability of immune complexes in tissue and serum, they are difficult to study. Interest in understanding immune complexes was very high in the 1950’s and 1960’s and quickly dissolved away when IgE was discovered (Ishizaka et al., 1966) and the attention of the immunological research teams was attracted to the newly defined antibody responsible for classical allergy symptoms, Type I of Gell and Coombs.

There are sound scientific reasons why specific IgG antibodies to fungi are not always diagnostic. Some individuals with high antibody levels to fungi remain symptom free during re-exposure. Such individuals may be less likely to produce the toxic immune complexes required to induce symptoms by virtue of the fungal antigen epitopes to which they respond. They may respond to minor epitopes that allow measurement of the antibody, but which do not engage in the formation of toxic immune complexes. Other individuals may have a vast scavenger system, which can rapidly take up and extinguish all immune complexes generated before symptoms can ensue. Other individuals may satisfy the high exposure and the appropriate symptom requirements and have relatively low total specific antibody levels to fungi. They may be poor antibody responders with an even lower capacity to deal with immune complexes. The observation that they can still experience flu-like symptoms following fungal exposure demonstrates that a relatively low antibody level can still produce significant, disabling symptoms.
Mold toxins can be powerful immune suppressors. It is sobering to remember there would be no organ transplant program without the availability of fungal toxins (e.g., cyclosporin). It is possible and even likely that the fungal exposure of some patients will include exposure to immune suppressive mycotoxins. Another cause for low antibody levels in a symptomatic patient could be iatrogenic. Many patients develop arthritic symptoms and present themselves to rheumatologists who may choose to use an immuno-suppressive drug such as methotrexate to treat the arthritis. Such a drug will certainly depress the immune response, relieve the severity of arthritic symptoms while masking what could be the real trigger for the arthritis.

(To be continued)

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