Read The Lupus Book: A Guide for Patients and Their Families, Third Edition Online
Authors: Daniel J. Wallace
Lupus Specificity
Antinuclear
Nucleus
98
5–10
Fair
Anti-DNA
Nucleus
50
Ͻ1
Excellent
Antihistone
Nucleus
50
1–3
Fair
Anti-Sm
Nucleus
25
Ͻ1
Excellent
Anti-RNP
Nucleus
25
Ͻ1
Fair
Antiphospholipid
Membrane
33
5
Fair
Anti-Ro (SSA)
Cytoplasm
30
Ͻ1
Fair
Anti-La (SSB)
Cytoplasm
15
Ͻ1
Fair
Antiribosomal P
Cytoplasm
20
Ͻ1
Good
Antierythrocyte
Red cells
15–30
Ͻ1
Fair
ANCA
White cells
20
Ͻ1
Poor
Antilymphocyte
White cells
Most
20
Poor
Antiplatelet
Platelets
15–30
Ͻ5
Poor
Antineuronal
Nerve cells
20
Ͻ1
Good
Rheumatoid factor
Ag-Ab*
30
5–10
Poor
Immune complexes
Ag-Ab*
Most
Varies
Poor
* Ag-Ab is an abbreviation for antigen-antibody complexes. These immune complexes are elevated with many common bacterial and viral infections, not just with lupus.
The Enemy Is Our Cells
[33]
but these approaches have been abandoned. One laboratory has extensive ex-
perience inducing lupus in cats with an antithyroid preparation, but this has not been adopted as a research tool by other investigators. More than 95 percent of animal lupus research studies involve mice with lupus.
WHY SHOULD WE STUDY ANIMAL MODELS OF LUPUS?
Antivivisectionists loudly proclaim that animal research is inhumane and un-
necessary. They believe that computer modeling and tissue-culture work rule
out the need for animal studies. However, many of the advances in lupus over
the last 30 years would not have been possible without animal studies, and
thousands of human lives have been saved as a result of this work. The immune
system of a mouse is remarkably similar to that of a human. As hard as we try,
no satisfactory computer simulation of the mouse’s or human’s immune system
exists, in large part because there’s a lot we don’t know about it.
The breakthroughs resulting from mouse work in SLE include proof that
genetic factors are important determinants of autoimmune disease and have led
to the identification of genes important in lupus. Animal research has also proved that lupus can be influenced by environmental and hormonal factors. Therapy
has pushed forward because trials of multiple therapeutic interventions that never would have worked in humans have saved years of research and lots of misery
for patients. Furthermore, many of the drugs we use to treat lupus (e.g., cyclophosphamide) were first shown to be effective in mice. Three types of mice are
used by researchers: breeds which spontaneously develop lupus, those in whom
it can be induced, or mice missing a specific gene. There have even been strong suggestions from mouse work that ‘‘gene therapies’’ may become useful in the
treatment of lupus, as scientists have been able to develop breeds of ‘‘knock
out’’ mice missing a specific gene or chemical.
As long as investigators stick to well-established guidelines that mandate hu-
mane and ethical environments for animal research, these efforts can save bil-
lions of dollars and a lot of unnecessary trial and error in humans while accelerating the pace for establishing the efficacy of new treatments. For example,
since mice with lupus live 1 to 2 years and humans with lupus can live up to
100 years, the influence of different therapeutic or environmental interventions can be seen more easily in animals with lupus.
This page intentionally left blank
Now that we have seen how our complex immune system works, we can return
to the question of what causes lupus. Researchers now believe that SLE probably results from multiple factors. It begins when certain genes predisposing an individual to lupus interact with environmental stimuli. These interactions result in immunologic responses that make autoantibodies (antibodies to one’s self)
and form immune complexes (antigens combined with antibodies). Certain au-
toantibodies and immune complexes are capable of causing the tissue damage
typically seen in lupus.
This part briefly outlines the causes of lupus and the immunologic responses
typically seen in lupus patients; subsequent chapters review these concepts in
more detail.
THE GENETICS OF LUPUS
Several different single genes increase the relative risk for lupus by increasing the body’s ability to promote certain autoantibodies. These are called HLA (human
leukocyte antigen) class II genes (there are class I, II, and III genes), and they are present on the surface of all cells that present foreign material, called antigens, to white blood cells, which are central in the body’s immune system. A defect in
HLA class III genes results in low complement levels (an important protein that plays a role in inflammation), which are commonly observed in SLE. Outside the
HLA system, genes that help program the structure of immunoglobulin or the re-
ceptors on the surface of T cells are important as well. And as one might deduce from the much greater number of female SLE patients, sex hormones also play a
role in the unique immunologic response of lupus patients. In fact, female sex hormones are more compatible with lupus activity than are male hormones.
[36]
What Causes Lupus?
ENVIRONMENTAL FACTORS
Environmental factors such as ultraviolet light, certain prescription drugs, and some chemicals can promote lupus. They either act like antigens that react
against the body or introduce new antigens to the immune system. Viruses
and other microbes can also alter cellular DNA or RNA (the essential structural material of chromosomes) and make them respond as if they were antigens.
For still unknown reasons, non-Caucasians are more susceptible to these
events.
ABNORMALITIES OF B LYMPHOCYTES
One-third of the human white blood cells are called lymphocytes. They are
divided into B and T cells. B cells are the body’s ‘‘humoral’’ response; their
job is to produce immunoglobulins and ultimately antibodies. The B lympho-
cytes in lupus patients are overactive; that is, they produce abnormally large
amounts of immunoglobulin and autoantibodies.
ABNORMALITIES OF T LYMPHOCYTES
The T cells are our body’s ‘‘memory’’ lymphocytes. They remember what is
foreign (or antigenic) and signal us to respond to this stimulus. Different types of T cells have various functions: they suppress immune response (suppressor
cells), promote the immune response (helper cells), destroy cells (natural killer cells), or promote chemicals (e.g., cytokines) that modulate or signal other immune cells to do certain things.
In SLE, the abnormalities observed include increased helper function, de-
creased suppressor function, an alteration of the lymphocytes that promote au-
toantibody formation, and increased B-cell responses. CD8 cells and NK cells
end up promoting inflammation rather than suppressing it.
ALTERATIONS IN CELL SIGNALING
Antigen-presenting cells, or macrophages, normally process antigen and make
peptides (specialized protein components) which stimulate T lymphocytes. In
lupus, some T-cell surface receptors are altered structurally or functionally, and the normal two-step co-stimulatory ‘‘handoff’’ of information is bobbled. Further down the road, altered receptors on the B-cell surface mishandle signals
from T cells.
ABNORMALITIES OF IMMUNOGLOBULIN RESPONSE
B cells make immunoglobulins, which destroy foreign material and protect the
body. In lupus, the regulation of this process goes awry when autoantibodies
What Causes Lupus?
[37]
form or when immune complexes are deposited in tissue and produce inflam-
mation. Autoantibodies that target different parts of cells, such as anti-DNA,
anticardiolipin, or anti-Ro (SSA), are capable of damaging tissues directly.
ABNORMALITIES IN DECREASING IMMUNE RESPONSES
In a healthy body, antigenic or foreign material combines with antibodies to
form immune complexes that vary in size, shape, charge, and binding properties.
Circulating immune complexes are usually cleared and dispersed through a fil-
tering system in which the spleen plays a prominent role. In SLE, this clearance is defective because certain important receptors have lost their binding ability and these complexes are unusually large or small in size or too plentiful.
Moreover, in the lupus patient, the body’s ability to control inflammation is
hampered because T-suppressor cells develop helper functions and natural killer cells promote B cells instead of killing certain invaders. Indeed, the body’s
system of ‘‘tolerance’’ (its ability to distinguish what is self from what is foreign) is altered. The regulation of cytokines is also altered in lupus.
ABNORMALITIES IN APOPTOSIS
Apoptosis
, the Greek word for falling or dropping off, refers to programmed cell death. Normally, cells die by two mechanisms: they are either killed or are genetically programmed to die. Apoptosis genes activated in a pregnant woman
ensure that their baby will not have 3 arms, 8 legs, or 4 hearts. In adults,
Environmental factors,
drugs, infectious
agents
Loss of regulating
cells which control
autoreactivity
Disease progression, Epitope spreading
Tissue Injury
Fig. III.1.
Factors Promoting the Development of SLE
[38]
What Causes Lupus?
damaged or old cells are genetically selected to die. When this fails to occur
normally, studies have suggested that the persistence of debris from damaged
cells in lupus patients may promote autoantibody formation. Nucleosomes are
chromatin complexes generated during apoptosis that are phagocytized by B
cells which activate T cells.
LOSS OF TOLERANCE
“Bad” cells can be eliminated by the thymus, spleen, lymph glands, and mac-
rophages. In SLE, evidence of loss of tolerance occurs whereby “self” or slightly altered self is recognized as being foreign. This occurs by several mechanisms
including loss of T cell tolerance (by the thymus centrally or peripherally; cells without HLA markers escape thymic deletion) and loss of B cell tolerance. B
cell tolerance is lost via failed elimination in the spleen, lymph nodes, bone
marrow through clonal deletion, receptor editing, or passive transfer which re-
sults in defects in our surveillance mechanisms. These inhibit, delete, suppress or ignore which leads to autoreactive cells “breaking through” and ultimately
autoantibodies are produced.
Summing Up
Genetic, environmental, T-cell, B-cell, and antibody factors combine to produce what we recognize as lupus. We still don’t know which factors are the cart and
which the horse. And we don’t yet know why event A leads to event B. We do
know that lupus results in alterations of immune regulation that cause the body to become sensitive to its own tissues. Figure III.1 summarizes some of these
concepts. In the next few chapters, we explore some of the factors that induce
lupus.
Is lupus a genetic disorder? Does it run in families? How can it be passed on
or be inherited? These questions are commonly asked. The answer is not simple,
but researchers now believe that various genes that predispose people to lupus
are inherited, among them the
major histocompatibility complex
, or
MHC
, which includes the
human leukocyte antigen (HLA)
region, a specific area of the genes.
Along with HLA, we also inherit T-cell receptor genes and other genes relevant
to SLE, such as immunoglobulin genes. Each of us inherits a unique chemical
signature, just as we inherit our blood type.
All this probably seems a little like alphabet soup, but in the next few pages
we take a closer look at how the principles of genetics apply to our understanding of lupus.
THE MAJOR HISTOCOMPATIBILITY COMPLEX:
A GENE SYSTEM
Every human cell that contains a nucleus (or center) also contains 23 pairs of
chromosomes
. We inherit one member of every pair from each of our parents.
These chromosomes store the genetic material responsible for determining
whether you are a male or female, have red hair, are color blind, might develop cystic fibrosis, among other characteristics. In mapping human chromosomes,
geneticists have referred to the ‘‘short’’ and ‘‘long’’ arms of the chromosomes, which have been numbered for convenience. On the short arm of the sixth
chromosome lie a series of specific sites, called genetic markers, that determine what an individual’s HLA system will look like. First described in the early
1970s, the HLA region contains genes that may predispose one to a remarkable
number of diseases, especially rheumatic disorders.