Read The Lupus Book: A Guide for Patients and Their Families, Third Edition Online
Authors: Daniel J. Wallace
HLA testing is very simple. Your physician needs only a few tubes of blood
drawn from the arm. Its applications for lupus are not reliable yet, but once
scientists find out a bit more about which types of disease are associated with
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What Causes Lupus?
which genes, HLA blood testing will come down to an issue of cost and become
more widespread.
The HLA site consists of three well-defined and functionally distinct regions
known as classes I, II, and III. Class I is expressed on all cells with a nucleus and is divided into A, B, and C subtypes. Class II is present on cells that are capable of presenting antigens (foreign material) to white blood cells and includes the D subtype. The D regions are further broken down into DP, DQ, and
DR subregions, among others. Class III provides for the structural genes that
produce a variety of substances important in lupus blood and tissues such as
complement, tumor necrosis factor, and heat shock protein.
An HLA ‘‘marker’’ is given to patients based on the subtype they possess,
A, B, C, or D. Numerous
alleles
(‘‘designations’’ or ‘‘arrangements’’) can be found at the same marker or site; there are more than a hundred possible arrangements that are further subdivided. If this seems complicated, don’t worry.
This expanding area of knowledge often confuses the best immunologists and
rheumatologists.
A combination of alleles at two HLA loci are name tags, or
haplotypes
. They can differ widely among various racial and ethnic groups. For example, HLA-B27 (the marker associated with a spinal disease known as ankylosing spon-
dylitis) is found in 8 percent of Americans of European Caucasian ancestry but
is very rare among African Americans.
The statistical chance that two particular haplotypes will occur together is
about 2 percent (for example, A6 with B5). However, in certain rheumatic dis-
eases, the chance that two alleles or arrangements will occur together may
greatly exceed this.
Table 7.1 illustrates the classification of the HLA system. The labels them-
selves are not important for our purposes; what is important is that specific genes are inherited and these may predispose a person to lupus.
Table 7.1.
The HLA Region of the Major
Histocompatibility Complex
Class I (on all nucleated cells)
A markers
B markers
C markers
Class II (on all antigen-presenting cells)
DP markers
DQ markers
DR markers
Class III contains structural genes that produce
chemicals important in lupus, such as
Complement
Hormones
Cytokines
The Genetic Connection
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WHY IS HLA IMPORTANT IN LUPUS PATIENTS?
What does all this mean for lupus? First of all, certain
subsets
of the disease are associated (in other words, they are often but not always found) with very
specific
HLA markers. For instance, neonatal lupus (lupus afflicting children at birth) is most often present in children who possess the A1, B8, DR3, and
DQw52 haplotypes. Patients with discoid lupus tend to possess DR4 markers,
and DR3 is present in those with a specific skin problem known as subacute
cutaneous lupus. Sjo¨gren’s syndrome (dry eyes, dry mouth, and arthritis, which is seen in many patients with SLE) is associated with B8, DR3, and DRw52.
DR2 and DR3 are more commonly observed in Caucasians of Western European
descent than any other DR types. The presence of DQw1 correlates with certain
autoantibodies such as anti-DNA, anti-Ro, and anti-La. ‘‘Null’’ or absent alleles can account for some of the deficiencies in blood complement levels that are
frequently seen in SLE.
Even though we have yet to isolate a lupus ‘‘gene,’’ certain genetic markers
and other non-HLA genes correlate with specific lupus subsets and autoanti-
bodies. Different sets or combinations of genes may be associated with as much
as a twentyfold risk for developing SLE.
OTHER LUPUS SUSCEPTIBILITY GENES
A variety of genes outside of the HLA system may predisopose individuals
to SLE. These include genes on mannose binding protein, Fc receptor alleles,
immunoglobulin G receptors, T-cell receptors, those involved with apoptosis,
and genetic polymorphisms associated with cytokines (particularly tumor necro-
sis factor alpha, apoptosis, interleukin-6, and interleukin-10). Under the direction of Dr. Betty Tsao, our group at UCLA was the first to suggest that a set of
genes on the short arm of chromosome 1 contributes approximately 20 percent
of the risk for SLE. More recently, scientists have started performing ‘‘genome scanning,’’ or looking at all of our chromosomal regions which might be linked
with lupus.
WHAT IS THE RISK THAT A MEMBER OF A LUPUS
PATIENT’S FAMILY WILL DEVELOP LUPUS?
If you have lupus, members of your immediate family, or first-degree relatives
(brothers, sisters, parents, and children), are at a slightly increased risk for developing it too. Several surveys have estimated this risk at 10 percent for your daughter and 2 percent for your son. If you have lupus and have an identical
twin, the chance that this sibling is similarly afflicted ranges from 26 to 70
percent. If your twin is fraternal, however, this figure is only 5 to 10 percent.
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What Causes Lupus?
Interestingly, the prevalence of SLE among all family members of lupus patients is 10 to 15 percent, while the chance of any of this group having autoimmune
diseases (including lupus) is 20 to 30 percent. The most common other auto-
immune disorders include autoimmune thyroiditis (also known as Graves’ dis-
ease or Hashimoto’s thyroiditis), rheumatoid arthritis, and scleroderma. The
body may produce elevated levels of autoantibodies even though no specific
immune disorder is present. For example, nearly half the first-degree relatives of my lupus patients may have a positive ANA blood test. However, ANA is
only one of the four criteria that must be present for SLE to be diagnosed.
Whether or not a positive ANA increases the chance of developing lupus isn’t
known; most ANA-positive family members of lupus patients feel well and have
no symptoms.
Should children of lupus patients or family members be ‘‘typed’’ or screened
for SLE? I don’t recommend testing unless symptoms or signs point to some
existing clinical problem. At this time, there is nothing we can offer those who carry a lupus ‘‘gene’’ or autoantibody and have no symptoms. In other words,
by testing them, we would only make them anxious or worried. Only a small
percentage of these individuals will ever develop the disease.
THE FUTURE
It is very possible—indeed probable—that in the next 30 years we will be able
to identify patients at risk for developing SLE by using HLA testing or other
methods and that we’ll then vaccinate them to prevent lupus. By that time, all
lupus-causing genes will have been isolated and identified. Potentially this would allow us to manipulate these genes in patients with active SLE to turn off the
disease process.
Many of my newly diagnosed lupus patients examine everything they have done
or experienced regarding travel, prescription medications, occupational activi-
ties, infections, and other factors in an effort to find a reason for their disease.
In my experience, some individuals are convinced that they did something
‘‘wrong’’ and therefore became ill. When this occurs, soul searching represents a natural process that ultimately results in coming to terms with the diagnosis.
Although the precise cause of lupus is not known in each case, there are indeed certain environmental factors that may occasionally play a role in initiating the disease or making it worse. How does this happen?
A few of these mechanisms are linked to environmental factors and may
produce effects in a variety of ways. These include a virus, food, or a chemical acting as an antigen to which an antibody response is generated. Some of these
agents in patients predisposed to lupus mimic antigens to which the body is
sensitized, and the antibody response is wrongly directed against the environ-
mental factor. Alternatively, an antigen or inciting factor such as ultraviolet sunlight can damage DNA and promote the production of anti-DNA as an immune response to the altered DNA.
Various medications may also play a role in inducing lupus. Drug-induced
lupus is covered in the next chapter.
This chapter concerns itself with four types of potentially inciting agents: (1) chemical factors, such as chemical agents, metals, and toxins; (2) dietary factors, such as amino acids, fats, and caloric intake; (3) ultraviolet radiation; and (4) infectious agents, such as viruses and bacteria as well as their by-products.
WHAT CHEMICAL FACTORS CAUSE LUPUS?
Aromatic Amines
Aromatic amines
are chemical agents that may induce or aggravate rheumatic disease. This class includes
hair-coloring solutions, hydrazines
(e.g., tobacco smoke), and
tartrazines
(e.g., food colorings or medication preservatives). Ar-
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What Causes Lupus?
omatic amines are broken down in the body by a process known as
acetylation
.
An increased incidence of drug-induced lupus has been observed after exposure
to aromatic amines in patients who are
slow acetylators
, or those who metabolize aromatic amines slowly. About half of all Americans are slow acetylators. The
mechanism by which aromatic amines may induce an immunologic reaction is
poorly understood, and only a small percentage of people exposed to these
chemicals ever develop clinical immune disease.
Hair-coloring solutions
containing aromatic amines, specifically paraphen-ylenediamine, can reproduce features of autoimmune disease in experimental
animals. Several large-scale epidemiologic surveys that that have tried to find out whether aromatic amines induce lupus or cancer have yielded conflicting
results. Do I advise my lupus patients to avoid hair dyes? No, since I rarely see patients who reported a flareup because they used a hair-care product; also, they already have the disease when they visit me.
Hydrazines
are present in hydralazine, a blood pressure medication known to induce lupus. In addition, these substances are found in a variety of compounds used in agriculture and industry and occur naturally in tobacco smoke and mush-rooms. A single published report tells of a pharmaceutical worker who was
occupationally exposed to hydrazines, developed lupus, and had reproducible
symptoms and signs upon repeated exposure.
Tartrazines
are preservatives found in certain food dyes (such as FD&C yellow No. 5), tattoos, and in some medicine tablets. Occasional well-documented
reports of tartrazine-induced lupus have appeared.
Silica and Silicone
One of the most ubiquitous elements in nature, silicon, has been the focus of
numerous studies. Nearly 50 years have elapsed since the initial observations
that sandblasters exposed to
silica dust
may develop an autoimmune type of reaction characterized by lung nodules and scarring as well as autoimmune-mediated lesions in the kidney.
The injection of
silicone
, a synthetic liquid form of silicon, under the skin has been similarly associated with autoimmune reactions. According to some
scientists but not all, silicone may be broken down into silica in the body. A
few women who have undergone breast augmentation with encapsulated silicone
gel implants have developed a lupus-like disease; this is probably coincidental.
Other Chemicals
Some chemicals can produce lupus-like symptoms as part of other diseases.
Scleroderma
is a first cousin of lupus, and many overlapping features are present in both diseases. But the principal difference is that, with scleroderma, the in-Environmental Villains
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flammation heals with scarring and tightening of the skin. The development of
diseases like scleroderma has been associated with a variety of chemicals, in-
cluding polyvinylchloride, trichloroethylene, cocaine, appetite suppressant am-
phetamines, and adulterated cooking oils (i.e., an epidemic caused by denatured rapeseed oil—‘‘toxic oil syndrome’’—afflicted 15,000 people in Spain in the
early 1980s and several hundred of them died).
Autoimmune diseases resembling lupus have been found in animals exposed
to certain
metals
, including mercuric chloride, gold, and cadmium. No human reports have appeared as yet. Eosin is a chemical contained in
lipstick
that may trigger sun-sensitivity rashes and allergic dermatitis. A widely cited report speculating on a role for lipstick in the causation of lupus appeared 30 years ago, but follow-up studies have suggested that there is no connection.
SHOULD LUPUS PATIENTS AVOID ANY
FOODS OR SUPPLEMENTS?
Foods are made up of three principal components: carbohydrates, proteins, and
fat. Thus, dietary manipulations can include either altering these components or raising or lowering overall caloric intake. Studies conducted on mice with lupus have suggested that high-calorie diets may accelerate mouse kidney disease, but there is no evidence that this occurs in humans. On the other hand, while ‘‘star-vation’’ low-calorie or low-fat regimens help mice with lupus, they can occa-