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CONTENTS
Fall 2001
Neuroenndocrinology, Genetics
and
Chronic Fatigue Syndrome
By David J. RTorpy, MBBS, PHD, FRACP,
University of Queensland,
Australia
Neuroendocrinology focuses on the
integrated nervous system and hormone release network that links the brain,
pituitary and many endocrine glands. A subset of that network is the
stress system, which is composed of the pituitary adrenal axis and sympathetic
nervous system and coordinates release of cortisol, norepinephrine and
epinephrine in response to acute stressors. These systems may play a role
in chronic fatigue syndrome (CFS) and other conditions involving
fatigue.
A "stress" can be defined as any influence
that may disturb the body's inherent natural balance, including infection,
trauma or psychological disturbance such as fear or anxiety. Once the stress
system is triggered, a flow of hormones such as cortisol helps the body to
defend itself by releasing glucose into the blood, increasing blood pressure and
moderating the immune system.
A number of disorders with fatigue
as their
hallmark might be related to abnormalities in the stress system. These have been
somewhat arbitrarily separated into syndromes such as: idiopathic chronic
fatigue (unexplained fatigue for more than six months); CFS (fatigue plus four
or more of a group of eight other features, many of which involve pain)1; and
fibromyalgia (pain more prominent than in CFS but frequently associated with
fatigue).
Research findings
Although
there
is not yet enough evidence to link specific stressors to neuroendocrine problems
in CFS and fibromyalgia (FM), there is accumulating evidence of a defect in the
stress system in these patients.2,3 Highlights of current research
include:
However, there have been variable findings.
A panel of experts at a March 2001 research symposium on the neuroendocrine
aspects of CFS held by The CFIDS Association of America and the U.S. Centers for
Disease Control and Prevention (CDC) noted that low cortisol is not consistent
in all CFS patients studied. They hypothesized that some of the discrepancy may
come from the relapsing-remitting nature of the illness and differing study
designs.
It is not known if the hormonal
abnormalities identified by researchers reflect the underlying process of CFS or
if they contribute directly to symptoms. To help answer this question there have
been two treatment trials of hydrocortisone to treat CFS patients.
One positive therapeutic study was
conducted in 32 CFS patients with disease duration <100 months and no
evidence of major depression or other co-morbid psychiatric disorders. Five mg
or 10 mg of hydrocortisone was administered for 28 days in a placebo-controlled
design. Approximately 28 percent of patients experienced a reduction in fatigue
scores, such that they became comparable to controls. Only nine percent of CFS
patients taking placebo experienced similar improvement.5
A study of full-replacement level
hydrocortisone (approximately 25-35 mg hydrocortisone daily) in 70 CFS patients
for three months resulted in slight improvement on symptom scales, particularly
in wellness scores, but there was evidence of suppressed adrenocortical
responsiveness on the basis of basal and ACTH-stimulated cortisol levels in 12
patients.6
The role of genetics
Genetic
research
may shed some light on the origins of neuroendocrine abnormalities in CFS.
In
the last 10 years, studies have described rare genetic mutations of key
regulatory components of the stress system, including the glucocorticoid
receptor (which "senses" cortisol in the body) and corticosteroid binding
globulin (CBG, a transport protein for cortisol), which can lead to CFS-like
symptoms.
In the mid-1980s, subjects with altered
cortisol receptors were found to have fatigue as their only symptom.7,8 More
recently my research team has discovered a 39-member Italian-Australian family
with a newly described loss of function (null) mutation in a gene for CBG, in
association with fatigue and relatively low blood pressure.9
Plasma CBG was undetectable in family
members who are null homozygotes for the mutated CBG gene and reduced by 50
percent of the low-normal range in null heterozygotes. Idiopathic chronic
fatigue was present in 12 of 14 adult null heterozygote subjects, and in two of
three null homozygotes. Two of the 19 individuals with the null mutation were
excluded from assessment for fatigue due to confounding factors related to their
associated illnesses.
Significantly, five cases out of the
19 met
the CDC criteria for CFS, and other family members had chronic fatigue without
associated features, suggesting that these syndromal classifications are not
predictive of the mutation. Two other families with milder mutations of the CBG
gene, known as the Lyon mutation, have been identified, also in association with
fatigue and low blood pressure.10,11,12
In the case of the family my research
team
described, investigations were initiated because of a discrepancy between urine
and blood cortisol levels - blood cortisol levels were low and urine cortisol
levels were normal. However, it would not have been possible to diagnose these
patients with biochemical findings alone, if they had only one copy of the CBG
null mutation.
It should be noted that although multiple
family members with chronic fatigue are often recognized in clinical practice,
this does not necessarily imply a common genetic factor, as families tend to
share a similar environment. However, studies of identical and non-identical
twins with CFS have revealed a genetic component, as the identical twins were
more likely to share fatigue symptoms than non-identical twins.13,14
In addition, as mentioned above, specific
mutations in proteins that regulate cortisol transport or action have been found
to be associated with fatigue in individual families. It remains to be seen if
these alterations of the CBG gene may predispose individuals to the development
of CFS.
The mechanism of association between
fatigue, relative hypotension and low cortisol has also not been established by
these genetic studies. The family we described had lifelong fatigue, albeit
variable with time, and did not have postural hypotension. Lack of postural
hypotension was also noted in subjects with the glucocorticoid receptor
mutation.
Implications for future
There
is
growing evidence of neuroendocrine disturbances in people with CFS and related
disorders. To reinforce this notion, it appears that abnormalities in the
proteins for cortisol action or transport may reproduce features of CFS.
In the last 10 years,
researchers have discovered specific heritable mutations in cortisol that may
lead to fatigue.
Although heterogeneity among CFS patient sufferers is the rule, suggesting many potential
causes of the illness, the positive findings to date are
highly encouraging and should act as an impetus for further work in
this field.
It may be that specific "dissection"
of the
neuroendocrinology of CFS and related disorders may allow us to sub-categorize
this enigmatic disease. Such categorization may lead to better diagnosis and
treatment of CFS in the not-too-distant future.
References
Fukuda et al. The chronic fatigue syndrome: a comprehensive
approach to its definition and study. Ann Intern Med. 1994; 121:953-959.
Torpy DJ et
al. Chronic fatigue syndrome. www.endotext.org
(In
press).
Torpy DJ et al. Responses of the
sympathetic nervous system and the hypothalamic-pituitary-adrenal axis to
interleukin-6 in fibromyalgia: a pilot study. Arthritis and
Rheumatism. 2000; 43: 872-880.
Demitrack M et al. Evidence for impaired
activation of the hypothalamic-pituitary-adrenal axis in patients with chronic
fatigue syndrome. J Clin Endocrinol Metab. 1991;
73:1224-1234.
Cleare AJ et al. Low-dose hydrocortisone
in chronic fatigue syndrome: a randomised crossover trial. Lancet.
1999; 353:455-458.
McKenzie R et al. Low-dose
hydrocortisone for treatment of chronic fatigue syndrome. JAMA. 1998;
280:1061-1066.
Bronnegard M et al. Primary cortisol
resistance associated with a thermolabile glucocorticoid receptor in a patient
with fatigue as the only symptom. J Clin Invest. 1986;
78:1270-1278.
Chrousos GP et al. Syndromes of
glucocorticoid resistance. Ann Intern
Med.1993;119:1113-1124.
Torpy DJ et al. Familial
cortico-steroid-binding globulin deficiency due to a novel null mutation:
association with fatigue and relative hypotension. J Clin Endocrinol
Metab. 2001; 86:3692-3700.
Emptoz-Bonneton A et al. Novel human
corticosteroid-binding globulin variant with low cortisol-binding affinity.
J Clin Endocrinol Metab. 2000; 85:361-367.
Brunner E et al. Molecular
characterization of corticosteroid-binding globulin deficiency in a Brazilian
kindred. Endocrine Society Annual Scientific Meeting 2001, Denver CO, poster
P1-404.
Baima J et al. Hereditary corticosteroid
binding globulin deficiency
Proceedings of the 77th Annual Meeting
of the Endocrine Society, Washington DC, 1995, poster 353.
Hickie I et al. Unique genetic and
environmental determinants of prolonged fatigue: a twin study. Psychol
Med. 1999; 29:259-268.
Hickie I et al. Complex genetic and
environmental relationships between psychological distress, fatigue and immune
functioning: a twin study. Psychol Med. 1999;
29:269-277.
Dr. Torpy is a Senior Lecturer
in the University of
Queens-land Department of Medicine, Greenslopes Private Hospital, Brisbane,
Australia. He is the lead author of a study on a newly described genetic
mutation that has been associated with fatigue and relative hypotension.
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