Psychic disorders
nowadays are increasing parallelly with increasing of beef consumption. Autism
and schizophrenia, Alzheimer, Parkinson, dementia are autoimmune deceases,
connected with the sensitive bowel syndrome, that means that through
gastrointestinal tract is imported a protein which is common to a human
receptor in brain. The immune system recognizes it falsely as foreign and
reacts to it, genes which are responsible for autoimmune inflammation of brain
are proliferated, and that causes psychic disorder.
Jacobs-Kreuzfeld disease
is a parallel disease in humans and bovines. This proves that the prion
receptor in humans and cows is common. That means the reaction to the bovine
prion receptor causes production of antibodies which react falsely with the
human prion receptor. Thus psychic disorders are caused not only by the prion
(by Jacobs-Kreuzfeld disease) but also through the immune reaction of the human
organism against the nerve prion receptor in beef and the false recognition of
the human nerve receptor by the antibodies produced to react to the bovine
prion receptor. In human brain this autoimmune reaction causes destruction of
neurons and the above mentioned diseases.
Which of the above
mentioned diseases would develop the person depends on against which receptor
in brain is the autoimmune reaction and where is it found. For example the
Parkinson syndrome is caused by destruction of substantia nigra in brain stem,
Alzheimer by destruction of neurons in the frontal part of the hemispheres,
etc.
This article shows
the non-questionable connection between neuroinflammation and psychic
disorders.
Neuroinflammation and
psychiatric illness
Souhel Najjar, corresponding author1,5 Daniel M
Pearlman,2,5 Kenneth Alper,4 Amanda Najjar,3 and Orrin Devinsky1,4,5
Abstract
Multiple lines of evidence support the
pathogenic role of neuroinflammation in psychiatric illness. While systemic
autoimmune diseases are well-documented causes of neuropsychiatric disorders,
synaptic autoimmune encephalitides with psychotic symptoms often go
under-recognized. Parallel to the link between psychiatric symptoms and
autoimmunity in autoimmune diseases, neuroimmunological abnormalities occur in
classical psychiatric disorders (for example, major depressive, bipolar,
schizophrenia, and obsessive-compulsive disorders). Investigations into the
pathophysiology of these conditions traditionally stressed dysregulation of the
glutamatergic and monoaminergic systems, but the mechanisms causing these
neurotransmitter abnormalities remained elusive. We review the link between
autoimmunity and neuropsychiatric disorders, and the human and experimental
evidence supporting the pathogenic role of neuroinflammation in selected
classical psychiatric disorders. Understanding how psychosocial, genetic,
immunological and neurotransmitter systems interact can reveal pathogenic clues
and help target new preventive and symptomatic therapies.
Introduction
As biological abnormalities are increasingly identified
among patients with psychiatric disorders, the distinction between neurological
and psychiatric illness fades. In addition to systemic autoimmune diseases
associated with psychiatric manifestations (for example, lupus), more recently,
patients with acute isolated psychosis were identified with synaptic autoimmune
encephalitides. These patients are often erroneously diagnosed with refractory
primary psychotic disorders, delaying initiation of effective immune therapy).
Additionally, growing evidence supports the pathogenic role of anti-neuronal
antibodies in neuropsychiatric disorders.
Clinical features of
anti-synaptic and anti-glutamic acid decarboxylase autoimmune encephalitides
Separation of neurological and psychiatric disorders,
supported by Descartes’s conception of the ‘mind’ as an ontologically distinct
entity and by the reproducibility of neuropathological abnormalities, dominated
medicine in the 19th and early 20th centuries. Since then, an expanding
collection of reproducible biological causes, from neurosyphilis, head trauma,
stroke, tumor, demyelination and many others caused symptom complexes that
overlapped with classic psychiatric disorders. More recently, neuro-inflammatory
and immunological abnormalities have been documented in patients with classical
psychiatric disorders.
Peripheral immune modulators can induce psychiatric
symptoms in animal models and humans. Healthy animals injected with
pro-inflammatory IL-1β and tumor necrosis
factor alpha (TNF-α) cytokines
demonstrate ‘sickness behavior’ associated with social withdrawal. In humans,
injections of low-dose endotoxin deactivate the ventral striatum, a region
critical for reward processing, producing anhedonia a debilitating depressive
symptom. Approximately 45% of non-depressed hepatitis C and cancer patients
treated with IFN-α develop depressive
symptoms associated with increased serum IL-6 levels.
Medical conditions associated with chronic
inflammatory and immunological abnormalities, including obesity, diabetes,
malignancies, rheumatoid arthritis, and multiple sclerosis, are risk factors
for depression and bipolar disorder. The positive correlation between these
medical conditions and psychiatric illness suggests the presence of a
widespread underlying inflammatory process affecting the brain among other
organs. A 30-year population-based study showed that having an autoimmune
disease or a prior hospitalization for serious infection increased the risk of
developing schizophrenia by 29% and 60%, respectively. Further, herpes simplex
virus, Toxoplasma gondii, cytomegalovirus, and influenza during
pregnancy increase the risk of developing schizophrenia.
Peripheral cellular and humoral immunological
abnormalities are more prevalent in psychiatric patients relative to healthy
controls. In both pilot (n = 34 patients with major depressive disorder (MDD),
n = 43 healthy controls) and replication studies (n = 36 MDD, n = 43 healthy
controls), a serum assay comprising nine serum biomarkers distinguished MDD
subjects from healthy controls with 91.7% sensitivity and 81.3% specificity;
significantly elevated biomarkers for neuropsychiatric symptoms were the
immunological molecules alpha 1 antitrypsin, myeloperoxidase, and soluble TNF-α receptor II.
Summary of neuro-inflammatory and immunological
abnormalities observed in pure psychiatric disorders
We first review the association between autoimmunity
and neuropsychiatric disorders, including: 1) systemic lupus erythematosus (SLE)
as a prototype of systemic autoimmune disease; 2) autoimmune encephalitides
associated with serum anti-synaptic and glutamic acid decarboxylase (GAD)
autoantibodies; and 3) pediatric neuropsychiatric autoimmune disorders
associated with streptococcal infections (PANDAS) and pure obsessive-compulsive
disorder (OCD) associated with anti-basal ganglia/thalamic autoantibodies. We
then discuss the role of innate inflammation/autoimmunity in classical
psychiatric disorders, including MDD, bipolar disorder (BPD), schizophrenia,
and OCD.
Neuropsychiatric disorders associated with
autoimmunity
Systemic lupus erythematosus
Between 25% to 75% of SLE patients have central
nervous system (CNS) involvement, with psychiatric symptoms typically occurring
within the first two years of disease onset. Psychiatric symptoms may include
anxiety, mood and psychotic disturbances. Brain magnetic resonance imaging
(MRI) is normal in approximately 42% of neuropsychiatric SLE cases.
Microangiopathy and blood–brain barrier (BBB) breakdown may permit entry of
autoantibodies into the brain. These antibodies include anti-ribosomal P
(positive in 90% of psychotic SLE patients), anti-endothelial cell,
anti-ganglioside, anti-dsDNA, anti-2A/2B subunits of N-methyl-D-aspartate
receptors (NMDAR) and anti-phospholipid antibodies. Pro-inflammatory
cytokines—principally IL-6, S100B, intra-cellular adhesion molecule 1 and
matrix-metalloproteinase-9 are also elevated in SLE. Psychiatric manifestations
of SLE, Sjögren’s disease, Susac’s syndrome, CNS vasculitis, CNS Whipple’s
disease, and Behçet’s disease were recently reviewed.
Neuropsychiatric autoimmune encephalitides
associated with serum anti-synaptic and glutamic acid decarboxylase
autoantibodies
Autoimmune encephalitides are characterized by an
acute onset of temporal lobe seizures, psychiatric features, and cognitive
deficits. The pathophysiology is typically mediated by autoantibodies targeting
synaptic or intracellular autoantigens in association with a paraneoplastic or
nonparaneoplastic origin. Anti-synaptic autoantibodies target NR1 subunits of
the NMDAR , voltage-gated potassium channel (VGKC) complexes (Kv1 subunit,
leucine-rich glioma inactivated (LGI1) and contact in associated protein 2
(CASPR2), GluR1 and GluR2 subunits of the
amino-3-hydroxy-5-methyl-l-4-isoxazolepropionic acid receptor (AMPAR) and B1
subunits of the γ-aminobutyric acid B
receptors (GABABR). Anti-intracellular autoantibodies target
onco-neuronal and GAD-65 autoantigens.
The inflammation associated with anti-synaptic
autoantibodies, particularly NMDAR-autoantibodies, is typically much milder
than that associated with GAD-autoantibodies or anti-neuronal autoantibodies
related to systemic autoimmune disorders or paraneoplastic syndromes .
Although neurological symptoms eventually emerge,
psychiatric manifestations, ranging from anxiety to psychosis mimicking
schizophrenia, can initially dominate or precede neurological features. Up to
two-thirds of patients with anti-NMDAR autoimmune encephalitis, initially
present to psychiatric services. Anti-synaptic antibodies-mediated autoimmune
encephalitides must be considered in the differential of acute psychosis.
Psychiatric presentations can include normal brain MRI and cerebrospinal fluid
(CSF) analysis, without encephalopathy or seizures. We reported a case of
seropositive GAD autoantibodies associated with biopsy-proven
neuro-inflammation, despite normal brain MRI and CSF analyses, where the
patient presented with isolated psychosis diagnosed as schizophrenia by
Diagnostic and Statistical Manual of Mental Disorders, 4th Edition (DSM-IV)
criteria. Further, seronegative autoimmune encephalitides can also present with
prominent neuropsychiatric disturbances, making diagnosis more elusive.
Serum anti-synaptic and GAD autoantibodies may occur
in patients with pure psychiatric disorders. In a prospective cohort of 29
subjects who met the DSM-IV criteria for schizophrenia, serum anti-NMDAR
autoantibodies were found in three subjects, and anti-VGKC-complex
autoantibodies were found in one subject. Using more sensitive techniques to
detect immunoglobulin G (IgG) NR1 autoantibodies in 100 patients with definite
schizophrenia, no autoantibodies were identified. However, this study did not
assess autoantibodies targeting the NR2 subunit of NMDAR. Other studies
reported significantly increased odds of elevated (≥90th percentile
non-psychiatric control levels) NR2 antibody levels (odds ratio (OR) 2.78, 95%
confidence interval (CI) 1.26 to 6.14, P = 0.012) among individuals
with acute mania (n = 43), but not in chronic mania or schizophrenia.
PANDAS and pure obsessive-compulsive disorder
associated with anti-basal ganglia/thalamic autoantibodies
OCD often complicates neurological disorders involving
the basal ganglia including Sydenham’s chorea, Huntington’s disease and
Parkinson’s disease. Anti-basal ganglia antibodies are implicated in Sydenham’s
chorea. PANDAS is characterized by acute exacerbations of OCD symptoms and/or
motor/phonic tics following a prodromal group A β-hemolytic streptococcal infection. The
pathophysiology is thought to involve cross-reactivity between
anti-streptococcal antibodies and basal ganglia proteins. The clinical overlap
between the PANDAS and pure OCD suggests a common etiological mechanism.
Among a random cohort of 21 pure OCD patients, 91.3%
had CSF anti-basal ganglia (P <0.05) and anti-thalamic
autoantibodies (P <0.005) at 43 kDa, paralleling
functional abnormalities in the cortico-striatal-thalamo-cortico circuitry of
OCD subjects. Another study documented that 42% (n = 21) of OCD pediatric and
adolescent subjects had serum anti-basal ganglia autoantibodies at 40, 45, and
60 kDa compared to 2% to 10% of controls (P = 0.001). Anti–basal
ganglia autoantibodies were detected in the sera of 64% of PANDAS subjects
(n = 14), compared to only 9% (n = 2) of streptococcal-positive/OCD-negative
controls (P <0.001). One study found no difference between the
prevalence of anti-basal ganglia autoantibodies in OCD (5.4%, n = 4) versus MDD
controls (0%); however, a limitation was the random use of rat cortex and
bovine basal ganglia and cortex that might have limited the identification of
seropositive cases.
The basal ganglia autoantigens are aldolase C
(40 kDa), neuronal-specific/non-neuronal enolase (45 kDa doublet) and
pyruvate kinase M1 (60 kDa)—neuronal glycolytic enzymes—involved in
neurotransmission, neuronal metabolism and cell signaling. These enzymes
exhibit substantial structural homology to streptococcal proteins. The latest study
(96 OCD, 33 MDD, 17 schizophrenia subjects) tested patient serum against
pyruvate kinase, aldolase C and enolase, specifically; a greater proportion of
OCD subjects were sero-positive relative to controls (19.8% (n = 19) versus 4%
[n = 2], P = 0.012).
Yet, in the same study only one of 19 sero-positive
OCD subjects also had positive anti-streptolysin O antibody titers, suggesting
that in pure OCD the anti-streptolysin O antibody seronegativity does not
exclude the presence of anti-basal ganglia autoantibodies.
In pure OCD, sero-positivity for anti-basal
ganglia/thalamic antibodies is associated with increased levels of CSF glycine
(P = 0.03), suggesting that these antibodies contribute to
hyperglutamatergia observed in OCD. The improvement of infection-provoked OCD
with immune therapies supports the pathogenicity of these autoantibodies. A
large NIH trial assessing the efficacy of intravenous immunoglobulin (IVIG) for
children with acute onset OCD and anti-streptococcal antibodies is ongoing
(ClinicalTrials.gov: NCT01281969). However, the finding of slightly higher CSF
glutamate levels in OCD patients with negative CSF anti-basal ganglia/thalamic
antibodies as compared to those with positive CSF antibodies suggests that
non-immunological mechanisms may play role in OCD. Other mechanisms, including
cytokine-mediated inflammation, are also hypothesized.
Psychiatric disorders associated with innate
inflammation
Disorders of innate inflammation/autoimmunity occur in
some patients with classical psychiatric disorders. We discuss innate
inflammation-related CNS abnormalities—including glial pathology, elevated
cytokines levels, cyclooxygenase activation, glutamate dysregulation, increased
S100B levels, increased oxidative stress, and BBB dysfunction—in MDD, BPD,
schizophrenia, and OCD. We also describe how innate inflammation may be
mechanistically linked to the traditional monoaminergic and glutamatergic
abnormalities reported in these disorders. The therapeutic role of
anti-inflammatory agents in psychiatric disorders is also reviewed.
Astroglial and oligodendroglial histopathology
Astroglia and oligodendroglia are essential to neural
metabolic homeostasis, behavior and higher cognitive functions. Normal
quiescent astroglia provide energy and trophic support to neurons, regulate
synaptic neurotransmission, synaptogenesis, cerebral blood flow, and maintain
BBB integrity. Mature oligodendroglia provide energy and trophic support to
neurons and maintain BBB integrity, and regulate axonal repair and myelination
of white matter tracts providing inter- and intra-hemispheric connectivity.
Both astroglia and oligodendroglia produce anti-inflammatory cytokines that can
down-regulate harmful inflammation.
In MDD, astroglial loss is a consistent post-mortem
finding in functionally relevant areas, including the anterior cingulate
cortex, prefrontal cortex, amygdala, and white matter, with few exceptions.
Post-mortem studies revealed reduced glial fibrillary acidic protein
(GFAP)-positive astroglial density primarily in the prefrontal cortex and
amygdala. A large proteomic analysis of frontal cortices from depressed
patients showed significant reductions in three GFAP isoforms. Although in one
study that reported no significant glial loss, subgroup analysis revealed a
significant decrease (75%) in GFAP-positive astroglial density among study
subjects younger than 45 years of age. A morphometric study similarly
showed no changes in glial density in late-life MDD brains. We hypothesize that
the apparent absence of astroglial loss among older MDD patients may reflect
secondary astrogliosis that is associated with older age rather than a true
negative.
Animal studies are consistent with human studies
showing astroglial loss in MDD. Wistar-Kyoto rats—known to exhibit
depressive-like behaviors—revealed reduced astroglial density in the same areas
as observed in humans. Administration of the astroglial-toxic agent,
L-alpha-aminoadipic acid, induces depressive-like symptoms in rats, suggesting
that astroglial loss is pathogenic in MDD.
Post-mortem studies of MDD subjects documented reduced
oligodendroglial density in the prefrontal cortex and amygdala, which may
correlate with brain MRI focal white matter changes occasionally noted in some
MDD patients. However, microvascular abnormalities may also contribute to these
changes.
In BPD, some studies demonstrate significant glial
loss, while others do not. These inconsistent findings may result from lack of
control for: 1) treatment with mood stabilizers, because post-hoc analysis
reported by some studies showed significant reduction in glial loss only after
controlling for treatment with lithium and valproic acid; 2) familial forms of
BPD, as glial loss is particularly prominent among BPD patients with a strong
family history; and/or, 3) the predominant state of depression versus mania, as
glial loss is frequent in MDD. Whether astroglia or oligodendroglia account for
the majority of glial loss is unclear; while proteomic analysis revealed a
significant decrease in one astroglial GFAP isoform, several other post-mortem
studies found either unchanged or reduced GFAP-positive astroglial expression
in the orbitrofrontal cortex, or reduced oligodendroglial density.
In schizophrenia, astroglial loss is an inconsistent
finding. While some studies showed no significant astroglial loss, several
others found reduced astroglial density and significant reductions in two GFAP
isoforms. Inconsistent findings may result from: 1) MDD comorbidity, which is
often associated with glial loss; 2) age variation, as older patients have
increased GFAP-positive astroglia; 3) regional and cortical layer variability;
4) treatment with antipsychotic drugs, as experimental studies show both
reduced and increased astroglial-density related to chronic antipsychotic
treatment; and 5) disease state (for example, suicidal versus non-suicidal
behavior). Post-mortem studies documented oligodendroglial loss, particularly
in the prefrontal cortex, anterior cingulate cortex, and hippocampus.
Ultrastructural examination of the prefrontal region showed abnormally
myelinated fibers in both gray and white matter; both age and duration of
illness were positively correlated with the white matter abnormalities.
In contrast to neurodegenerative disorders that are
commonly associated with astroglial proliferation, psychiatric disorders are
instead associated with either reduced or unchanged astroglial density. The
lack of increased glial density in early-onset psychiatric disorders may
reflect the slower rate of degenerative progression in psychiatric illnesses.
We postulate that degenerative changes associated with
psychiatric disorders are subtler and not severe enough to provoke astroglial
intracellular transcription factors that positively regulate astrogliosis,
including signal transducer activator of transcription 3 and nuclear factor
kappa B (NF-κB).
While the majority of post-mortem studies focused on
the alteration of glial density in MDD, BPD, and schizophrenia, others
described alteration of glial cell morphology, with mixed findings. In MDD and
BPD, glial size is either increased or unchanged. One study found reduced glial
size in BPD and schizophrenia but not in MDD. A post-mortem study of depressed
patients who committed suicide found increased astroglial size in the anterior
cingulate white matter but not in the cortex. One study in schizophrenic
subjects found markedly decreased astroglial size in layer V of the
dorsolateral prefrontal cortex, notwithstanding that astroglial density is
double that of controls in the same layer. The mixed results may partially
reflect earlier studies of glial alterations in psychiatric illnesses that did
not specify astroglia versus oligodendroglia.
Glial loss in psychiatric illnesses may contribute to
neuroinflammation through several mechanisms, including abnormal cytokine
levels (see Cytokine section), dysregulated glutamate
metabolism (see Glutamate section), elevated S100B protein
(see S100B section), and altered BBB function (see Blood
brain barrier section), resulting in impaired cognition and behavior
.
Microglial histopathology
Microglia are the resident immune cells of the CNS.
They provide ongoing immune surveillance and regulate developmental synaptic
pruning. CNS injury transforms ramified resting microglia into activated
elongated rod-shaped and macrophage-like phagocytic amoeboid cells that
proliferate and migrate towards the site of injury along chemotactic gradients
(that is, microglial activation and proliferation (MAP)). Human microglial
cells express NMDARs that may mediate MAP leading to neuronal injury.
In MDD, BPD and schizophrenia, the results of
post-mortem studies investigating the presence of MAP are mixed. Post-mortem
studies revealed elevated MAP in only one out of five MDD subjects. In some BPD
disorder patients, increased human leukocyte antigen-DR-positive microglia
displaying thickened processes were documented in the frontal cortex. In
schizophrenia, while some studies reported elevated MAP relative to controls,
others showed no difference between groups. In a post-mortem study assessing
MAP in MDD and BPD; quinolinic acid-positive microglial cell density was
increased in the subgenual anterior cingulate cortex and anterior midcingulate
cortex of MDD and BPD patients who committed suicide relative to controls.
Post-hoc analysis revealed this increased MAP was solely attributable to MDD
and not BPD, since the positive microglial immunostaining in MDD subjects was
significantly greater than that in the BPD subgroup in both the subgenual
anterior cingulate and midcingulate cortices, and since the microglia density
was similar in both BPD and control groups. A study comparing all three
disorders (nine MDD, five BPD, fourteen schizophrenia, ten healthy controls)
demonstrated no significant difference in microglial density across the four groups.
These mixed results may be attributed to variable
microglial immunological markers used among different studies and/or the
failure to control for disease severity. Notably, three post-mortem studies of
MDD and schizophrenic subjects documented a strong positive correlation between
MAP and suicidality in the anterior cingulate cortex and mediodorsal thalamus,
independent of psychiatric diagnosis. Thus, MAP may be a state rather than a
trait marker for MDD and schizophrenia.
In OCD, animal models suggest that dysfunction and
reduction of certain microglial phenotypes, such as those expressing the Hoxb8
gene, which encodes homeobox transcription factor, can cause OCD-like behavior.
Hoxb8 knockout mice exhibit excessive grooming behavior and anxiety in association
with reduced microglial density. This excessive grooming behavior resembles the
behavioral characteristics of human OCD. Hoxb8 injection in adult Hoxb8
knockout mice reverses microglial loss and restores normal behavior. The role
of these specific microglial phenotypes in human OCD is unclear.
Experimental data suggest that MAP comprises
distinctive harmful and neuroprotective phenotypes. Harmful microglia do not
express major histocompatibility complex II (MHC-II) and, therefore, cannot act
as antigen presenting cells (APC); they promote deleterious effects through
proinflammatory cytokine production, nitric oxide synthase signaling, promoting
glial and BBB-pericyte/endothelial cyclooxygenase-2 (COX-2) expression,
inducing astroglial S100B secretion (see S100B section), and
microglial glutamate release. Harmful microglia also secrete prostaglandin E-2
(PGE-2) that promotes proinflammatory cytokines production, which in turn
increases PGE-2 levels in a feed-forward cycle. Further, PGE-2 stimulates COX-2
expression, which mediates the conversion of arachidonic acid to PGE-2, setting
up another feed-forward cycle.
Neuroprotective microglia by contrast can: 1) express
MHC-II in vivo and in vitro and act as cognate
APC; 2) facilitate healing and limit neuronal injury by promoting secretion of
anti-inflammatory cytokines, brain-derived neurotrophic factor, and
insulin-like growth factor-1; and 3) express excitatory amino acid
transporter-2 (EAAT2) that eliminates excess extracellular glutamate, and
promotes neuroprotective T lymphocytic autoimmunity. However, more studies are
needed to confirm the contributory role of neuroprotective microglia to
neuropsychiatric disorders in humans.
In vitro animal studies
suggest that the ratio of harmful versus neuroprotective microglia can be
influenced by the net effect of inflammatory counter-regulatory mechanisms.
These mechanisms include the number of neuroprotective CD4+CD25+FOXP3+ T
regulatory cells ((T regs) and brain cytokine levels; low IFN-γ levels may promote
neuroprotective microglia, whereas high levels can promote the harmful
phenotype.
The role of cytokines
Proinflammatory cytokines include IL-1β, IL-2, IL-6, TNF-α and IFN-γ. They are secreted primarily by microglia, Th1
lymphocytes and M1 phenotype monocytes/macrophages. They promote harmful
inflammation. Antiinflammatory cytokines include IL-4, IL-5 and IL-10. They are
primarily secreted by astroglia, Th2 lymphocytes, T regs and M2 phenotype
monocytes/macrophages. They can limit harmful inflammation by converting the
proinflammatory M1-phenotype into the beneficial antiinflammatory M2-phenotype,
and potentially by promoting the neuroprotective microglial phenotype. The role
of proinflammatory/antiinflammatory cytokines in psychiatric disorders is
supported by several lines of evidence.
In MDD, the most recent meta-analysis (29 studies, 822
MDD, 726 healthy controls) of serum proinflammatory cytokines confirmed that
soluble IL-2 receptor, IL-6 and TNF-α levels are increased in MDD (trait markers), while,
IL-1β, IL-2, IL-4, IL-8
and IL-10, are not statistically different from controls. In a primary cytokine
study comparing MDD subgroups (47 suicidal-MDD, 17 non-suicidal MDD, 16 health
controls), both sera IL-6 and TNF-α were significantly
higher, while IL-2 levels were significantly lower in MDD subjects who committed
suicide relative to both other groups. This finding suggests that IL-6 and TNF-α are also state markers of MDD.
The decrease of serum IL-2 levels associated with acute suicidal behavior may
reflect increased binding to its upregulated receptor in the brain; parallel to
the aforementioned meta-analysis showing increased soluble IL-2 receptor in
MDD. Studies investigating the clinical significance of cytokines in MDD showed
that serum cytokine levels are elevated during acute depressive episodes and
normalized following successful, but not failed, treatment with antidepressants
and electroconvulsive therapy; these findings suggest a possible pathogenic
role for cytokines.
In BPD, serum cytokine alterations were summarized in
a recent review; TNF-α, IL-6 and IL-8 are
elevated during manic and depressive phases, whereas IL-2, IL-4 and IL-6 are
elevated during mania . Other studies showed that sera IL-1β and IL-1 receptor levels are not
statistically different from healthy controls, although tissue studies
documented increased levels of IL-1β and IL-1 receptor in the BPD frontal cortex.
In schizophrenia, results from studies investigating
cytokine abnormalities are conflicting. While some studies found both decreased
serum proinflammatory (IL-2, IFN-γ) and increased serum
and CSF antiinflammatory cytokines (IL-10), others found elevated serum pro-
and antiinflammatory cytokines, with a proinflammatory type dominance. One
cytokine meta-analysis (62 studies, 2,298 schizophrenia, 858 healthy controls)
showed increased levels of IL-1R antagonist, sIL-2R and IL-6. However, this
study did not account for the use of antipsychotics, which is thought to
enhance proinflammatory cytokine production. A more recent cytokine
meta-analysis (40 studies, 2,572 schizophrenics, 4,401 controls) that accounted
for antipsychotics, found that TNF-α, IFN-γ, IL-12 and sIL-2R
are consistently elevated in chronic schizophrenia independent of disease
activity (trait markers), while IL-1β, IL-6 and transforming growth factor beta positively
correlate with disease activity (state markers). Cell cultures of peripheral
blood mononuclear cells (PBMC) obtained from schizophrenic patients produced
higher levels of IL-8 and IL-1β spontaneously as
well as after stimulation by LPS, suggesting a role for activated
monocytes/macrophages in schizophrenia pathology.
In OCD, results from a random survey of sera and CSF
cytokines, and LPS-stimulated PBMC studies, are inconsistent. There is a
correlation between OCD and a functional polymorphism in the promoter region of
the TNF-α gene, although
low-powered studies did not confirm this association. Therefore, the mixed
results from studies documenting either increased or decreased TNF-α cytokine levels may reflect
their variable inclusion of the subset of OCD subjects with this particular
polymorphism in their cohorts.
Cytokine response polarization in major
depression and schizophrenia
Cytokine response phenotypes are classified as either
proinflammatory Th1 (IL-2, IFN-γ) or antiinflammatory
Th2 (IL-4, IL-5, IL-10) according to the immune functions they regulate. While
Th1 cytokines regulate cell-mediated immunity directed against intra-cellular
antigens, Th2 cytokines regulate humoral immunity directed against
extra-cellular antigens. Th1 cytokines are produced by Th1 lymphocytes and M1
monocytes whereas Th2 cytokines are produced by Th2 lymphocytes and M2
monocytes. In the brain, microglia predominantly secrete Th1 cytokines, whereas
astroglia predominately secrete Th2 cytokines. The reciprocal ratio of Th1:Th2
cytokines, henceforth ‘Th1-Th2 seesaw’, is influenced by the proportion of
activated microglia (excess Th1) to astroglia (excess Th2) and the interplay
between activated T cells and excessive CNS glutamate levels that we
hypothesized to favor Th1 response.
The Th1-Th2 seesaw imbalance can influence tryptophan
metabolism by altering its enzymes thereby shifting tryptophan catabolism
towards kynurenine (KYN) and KYN catabolism towards either of its two
down-stream metabolites; microglia quinolinic acid that is Th1
response-mediated or astroglial kynurenic acid (KYNA) that is Th2
response-mediated.
Tryptophan metabolism enzymes affected by Th1-Th2
seesaw include: indoleamine 2,3-dioxygenase (IDO) expressed by microglia and
astroglia, the rate-limiting enzymes that mediate the conversion of tryptophan
to KYN and serotonin to 5-hydroxyindoleacetic acid. Kynurenine 3-monooxygenase
(KMO), solely expressed by microglia, is the rate-limiting enzyme that converts
KYN to 3-hydroxykynurenine (3-OH-KYN), which is further metabolized to
quinolinic acid. Tryptophan-2,3-dioxygenase (TDO), expressed solely by
astroglia, is the rate-limiting enzyme that converts tryptophan to KYN.
Kynurenine aminotransferase (KAT), expressed primarily in astroglial processes,
is the rate-limiting enzyme that mediates the conversion of KYN to KYNA.
Th1 cytokines activate microglial IDO and KMO,
shifting microglial KYN catabolism towards quinolinic acid (NMDAR agonist)
synthesis, while Th2 cytokines inactivate microglial IDO and KMO, shifting
astroglial KYN catabolism towards TDO- and KAT-mediated KYNA (NMDAR antagonist)
synthesis.
Th1 and Th2 predominant immunophenotypes have been
proposed for MDD and schizophrenia, respectively, based on peripheral, rather
than CNS, cytokines patterns. We believe that peripheral cytokines patterns are
unreliable surrogate markers of those in the CNS. Indeed, peripheral cytokine
levels can be influenced by many extra-CNS variables, which are not
consistently controlled for in several of the peripheral cytokines studies,
including: 1) age, body mass index, psychotropic medications, smoking, stress
and circadian fluctuations; 2) the influence of disease activity/state on the
production of selected cytokines synthesis; and 3) the effects of psychotropic agents
on cytokines production. The short half-lives and the rapid turnover of serum
cytokines (for example, 18 minutes for TNF-α versus 60 minutes for IL-10), may further limit
the reliability of interpreting their levels measured from random sera
sampling.
In MDD, there is a consensus that a proinflammatory
Th1 immunophenotype response predominates. High levels of quinolinic acid in
post-mortem MDD brains, suggest the presence of an upregulated Th1 response.
Elevated CNS quinolinic acid can promote calcium influx mediated apoptosis of
human astroglia, which hypothetically may blunt the astroglia-derived Th2
response, tipping Th1 versus Th2 seesaw balance in favor of the microglial Th1
response. CNS hyposerotonergia adds further support to an excess Th1 response,
which is shown to reduce CNS serotonin synthesis and to increase its
degradation.
CNS hyperglutamatergia may also contribute to an
excess Th1 response in the brain in in vitro study suggests that
the peripheral resting T lymphocytes constitutively express metabotropic
glutamate receptor 5 (mGluR5), whose binding to glutamate inhibits lymphocytic
IL-6 release, thereby downregulating auto-reactive T-effector cell
proliferation. Activated T lymphocytes, but not resting T lymphocytes, can
cross the BBB.
Experimental data suggest that the interaction between
T cell receptors of activated T lymphocytes and their cognate antigen
presenting cells can downregulate mGluR5 and induce mGluR1 expressions. In
animal models, binding of excess glutamate to lymphocytic mGluR1 receptors
promotes production of Th1 cytokines, including IFN-γ.
We hypothesize that in some MDD patients, parallel to
experimental data, the binding of excess CNS glutamate to induced lymphocytic
mGluR1 receptors may contribute to an excess Th1 response, including IFN-γ. We speculate that IFN-γ in a small quantity, similar to
its in vitro effects on microglia, may induce microglial
expression of MHC-II and EAAT2, allowing microglia to serve as cognate antigen
presenting cells and to provide glutamate reuptake function, thereby
transforming harmful microglia into neuroprotective phenotype that participate
in eliminating excess extracellular glutamate. Therefore, we also hypothesize
that excess Th1 response in subgroups of MDD patients is a double-edged sword,
promoting harmful inflammation and serving as a beneficial counter-regulatory
mechanism that may limit excess glutamate-related neuroexcitotoxicity.
In schizophrenia, while some peripheral cytokine
studies suggest the predominance of an antiinflammatory Th2
immunophenotype/response, others refute this. However, we agree with the
authors who hypothesized that the Th2 response is the dominant phenotype in
schizophrenia. Elevated brain, CSF, and serum levels of KYNA suggest
downregulation of microglial IDO and KMO, which is a function of Th2 response
that shifts astroglial KYN catabolism towards KYNA synthesis. Reduced KMO
activity and KMO mRNA expression in post-mortem schizophrenic brains is
consistent with excess Th2 response. Increased prevalence of Th2-mediated
humoral immunity abnormalities in subgroups of schizophrenia patients—as
evidenced by increased B cell counts, increased production of autoantibodies
including antiviral antibodies and increased immunoglobulin E adds further
support to the Th2 response dominance hypothesis.
Neuroinflammation and CNS glutamate
dysregulation
Glutamate mediates cognition and behavior. Synaptic
glutamate levels are regulated by high-affinity sodium-dependent glial and
neuronal EAATs, namely, the XAG- system responsible for glutamate
reuptake/aspartate release and the sodium-independent astroglial
glutamate/cystine antiporter system (Xc-) responsible for glutamate
release/cystine reuptake. Astroglial EAAT1 and EAAT2 provide more than 90% of
glutamate re-uptake.
Neuroinflammation can alter glutamate metabolism and
the function of its transporters, producing cognitive, behavioral, and
psychiatric impairments.
In MDD, there is evidence for cortical
hyperglutamatergia. Cortical glutamate levels correlated positively with the
severity of depressive symptoms, and a five-week course of antidepressants
decreased serum glutamate concentrations. A single dose of ketamine, a potent
NMDAR antagonist, can reverse refractory MDD for a week. Excess CNS glutamate
levels can induce neurotoxicity-mediated inflammation, including a
proinflammatory Th1 response.
Limited in vitro evidence suggests
that inflammation/proinflammatory cytokines can increase CNS glutamate levels
in a feed-forward cycle through several potential mechanisms: 1)
proinflammatory cytokines can inhibit and reverse astroglial EAAT-mediated
glutamate reuptake function; 2) proinflammatory cytokines can enhance
microglial quinolinic acid synthesis, which has been experimentally shown to
promote synaptosomal glutamate release; 3) increased COX-2/PGE-2 and TNF-α levels can induce calcium
influx, which, based on in vitro data, may increase
astroglial glutamate and D-serine release; and 4) activated microglia can
express excess Xc- antiporter systems that mediate glutamate
release.
In schizophrenia, prefrontal cortical
hypoglutamatergia and reduced NMDAR functionality are found. Recent H1 magnetic
resonance spectroscopy (MRS) meta-analysis (28 studies, 647 schizophrenia, 608
control) confirmed decreased glutamate and increased glutamine levels in the
medial frontal cortex. The contributory role of inflammation to
hypoglutamatergia is not proven. Elevated KYNA synthesis in schizophrenia
brains, typically a function of Th2 response, can inhibit NR1 subunit of NMDAR
and alpha 7 nicotinic acetylcholine receptor (α7nAchR), leading to decreased NMDAR function and
reduced α7nAchR-mediated
glutamate release.
In BPD and OCD, data suggest CNS cortical
hyper-glutamatergia in both disorders. The contribution of inflammation (BPD
and OCD) and autoantibodies (OCD) to increased CNS glutamate levels requires
further investigation.
The role of S100B
S100B is a 10 kDa calcium-binding protein
produced by astroglia, oligodendroglia, and choroid plexus ependymal cells. It
mediates its effects on the surrounding neurons and glia via the receptor for
advanced glycation end-product. Nanomolar extracellular S100B levels provide
beneficial neurotrophic effects, limit stress-related neuronal injury, inhibit
microglial TNF-α release, and
increase astroglial glutamate reuptake. Micromolar S100B concentrations,
predominantly produced by activated astroglia and lymphocytes, have harmful
effects transduced by receptor for advanced glycation end product that include
neuronal apoptosis, production of COX-2/PGE-2, IL-1β and inducible nitric oxide species, and upregulation
of monocytic/microglial TNF-α secretion.
Serum and, particularly, CSF and brain tissue S100B
levels are indicators of glial (predominantly astroglial) activation. In MDD
and psychosis, serum S100B levels positively correlate with the severity of
suicidality, independent of psychiatric diagnosis. Post-mortem analysis of
S100B showed decreased levels in the dorsolateral prefrontal cortex of MDD and
BPD, and increased levels in the parietal cortex of BPD.
Meta-analysis (193 mood disorder, 132 healthy
controls) confirmed elevated serum and CSF S100B levels in mood disorders,
particularly during acute depressive episodes and mania.
In schizophrenia, brain, CSF and serum S100B levels
are elevated. Meta-analysis (12 studies, 380 schizophrenia, 358 healthy
controls) confirmed elevated serum S100B levels in schizophrenia. In
post-mortem brains of schizophrenia subjects, S100B-immunoreactive astroglia
are found in areas implicated in schizophrenia, including anterior cingulate
cortex, dorsolateral prefrontal cortex, orbitofrontal cortex and hippocampi.
Elevated S100B levels correlate with paranoid and negativistic psychosis,
impaired cognition, poor therapeutic response and duration of illness. Genetic
polymorphisms in S100B and receptor for advanced glycation end-product genes in
schizophrenia cohorts suggest these abnormalities are likely primary/pathogenic
rather than secondary/biomarkers. Indeed, the decrease in serum S100B levels
following treatment with antidepressants and antipsychotics suggests some
clinical relevance of S100B to the pathophysiology of psychiatric disorders.
Neuroinflammation and increased oxidative stress
Oxidative stress is a condition in which an excess of
oxidants damages or modifies biological macromolecules such as lipids, proteins
and DNA. This excess results from increased oxidant production, decreased
oxidant elimination, defective antioxidant defenses, or some combination
thereof. The brain is particularly vulnerable to oxidative stress due to: 1)
elevated amounts of peroxidizable polyunsaturated fatty acids; 2) relatively
high content of trace minerals that induce lipid peroxidation and oxygen
radicals (for example, iron, copper); 3) high oxygen utilization; and 3)
limited anti-oxidation mechanisms.
Excess oxidative stress can occur in MDD, BPD,
schizophrenia, and OCD. Peripheral markers of oxidative disturbances include
increased lipid peroxidation products (for example, malondialdehyde and
4-hydroxy-2-nonenal), increased nitric oxide (NO) metabolites, decreased
antioxidants (for example, glutathione) and altered antioxidant enzyme levels.
In MDD, increased superoxide radical anion production
correlates with increased oxidation-mediated neutrophil apoptosis. Serum levels
of antioxidant enzymes (for example, superoxide dismutase-1) are elevated
during acute depressive episodes and normalize after selective serotonin
reuptake inhibitors (SSRIs) treatment. This suggests that in MDD, serum
antioxidant enzyme levels are a state marker, which may reflect a compensatory
mechanism that counteracts acute increases in oxidative stress. In schizophrenia
by contrast, CSF soluble superoxide dismutase-1 levels are substantially
decreased in early-onset schizophrenic patients relative to chronic
schizophrenic patients and healthy controls. This suggests that reduced brain
antioxidant enzyme levels may contribute to oxidative damage in acute
schizophrenia, though larger studies are needed to confirm this finding.
Several additional experimental and human studies
examined in more detail the mechanisms underlying the pathophysiology of
increased oxidative stress in psychiatric disorders. In animal models of
depression, brain levels of glutathione are reduced while lipid peroxidation
and NO levels are increased.
Postmortem studies show reduced brain levels of total
glutathione in MDD, BPD and schizophrenic subjects. Fibroblasts cultured from
MDD patients show increased oxidative stress independent of glutathione levels,
arguing against a primary role of glutathione depletion as the major mechanism
of oxidative stress in depression.
Microglial activation may increase oxidative stress
through its production of proinflammatory cytokines and NO. Proinflammatory
cytokines and high NO levels may promote reactive oxygen species (ROS)
formation, which in turn accelerates lipid peroxidation, damaging membrane
phospholipids and their membrane-bound monoamine neurotransmitter receptors and
depleting endogenous antioxidants. Increased ROS products can enhance
microglial activation and increase proinflammatory production via stimulating
NF-κB, which in turn
perpetuates oxidative injury, creating the potential for a pathological
positive feedback loop in some psychiatric disorders. Although
neuroinflammation can increase brain glutamate levels, the role of
glutamatergic hyperactivity as a cause of oxidative stress remains unsubstantiated.
Mitochondrial dysfunction may contribute to increased
oxidative stress in MDD, BPD and schizophrenia. Postmortem studies in these
disorders reveal abnormalities in mitochondrial DNA, consistent with the high
prevalence of psychiatric disturbances in primary mitochondrial
disorders. In vitro animal studies show that proinflammatory
cytokines, such as TNF-α, can reduce
mitochondrial density and impair mitochondrial oxidative metabolism, leading to
increased ROS production. These experimental findings may imply mechanistic
links among neuroinflammation, mitochondrial dysfunction and oxidative stress,
meriting further investigation of these intersecting pathogenic pathways in
human psychiatric disorders.
The vulnerability of neural tissue to oxidative damage
varies among different psychiatric disorders based on the neuroanatomical,
neurochemical and molecular pathways involved in the specific disorder.
Treatment effects may also be critical, as preliminary evidence suggests that
antipsychotics, SSRIs and mood stabilizers possess antioxidant properties. The
therapeutic role of adjuvant antioxidants (for example, vitamins C and E) in
psychiatric disorder remains to be substantiated by high-powered randomized
clinical trials. N-acetylcysteine shows the most promising results to-date,
with several randomized placebo-controlled trials demonstrating its efficacy in
MDD, BPD and schizophrenia.
Blood–brain barrier dysfunction
The BBB secures the brain’s immune-privileged status
by restricting the entry of peripheral inflammatory mediators, including
cytokines and antibodies that can impair neurotransmission. The hypothesis of
BBB breakdown and its role in some psychiatric patients is consistent with the
increased prevalence of psychiatric comorbidity in diseases associated with its
dysfunction, including SLE, stroke, epilepsy and autoimmune encephalitides. An
elevated ‘CSF:serum albumin ratio’ in patients with MDD and schizophrenia
suggests increased BBB permeability.
In one study (63 psychiatric subjects, 4,100 controls),
CSF abnormalities indicative of BBB-damage were de-tected in 41% of psychiatric
subjects (14 MDD and BPD, 14 schizophrenia), including intrathecal synthesis of
IgG, IgM, and/or IgA, mild CSF pleocytosis (5 to 8 cells per mm3)
and the presence of up to four IgG oligoclonal bands. One post-mortem
ultrastructural study in schizophrenia revealed BBB ultrasructural
abnormalities in the prefrontal and visual cortices, which included vacuolar
degeneration of endothelial cells, astroglial-end-foot-processes, and
thickening and irregularity of the basal lamina. However, in this study, the
authors did not comment on the potential contribution of postmortem changes to
their findings. Another study investigating transcriptomics of BBB endothelial
cells in schizophrenic brains identified significant differences among genes
influencing immunological function, which were not detected in controls.
Oxidation-mediated endothelial dysfunction may
contribute to the pathophysiology of BBB dysfunction in psychiatric disorders.
Indirect evidence from clinical and experimental studies in depression and, to
a lesser extent, in schizophrenia suggests that increased oxidation may
contribute to endothelial dysfunction. Endothelial dysfunction may represent a
shared mechanism accounting for the known association between depression and
cardiovascular disease, which may be related to decreased levels of vasodilator
NO. Experimental studies suggest that reduced endothelial NO levels are
mechanistically linked to the uncoupling of endothelial nitric oxide synthase
(eNOS) from its essential co-factor tetrahydrobiopterin (BH4), shifting its
substrate from L-arginine to oxygen. Uncoupled eNOS promotes synthesis of ROS
(for example, superoxide) and reactive nitrogen species (RNS) (for example,
peroxynitrite; a product of the interaction of superoxide with NO) rather than
NO, leading to oxidation-mediated endothelial dysfunction.
Animal data showed that SSRIs could restore deficient
endothelial NO levels, suggesting that anti-oxidative mechanisms may contribute
to their antidepressant effects. In humans, L-methylfolate may potentiate
antidepressant effects of SSRIs, putatively by increasing levels of BH4, which
is an essential cofactor for eNOS re-coupling-mediated anti-oxidation, as well
as for the rate-limiting enzymes of monoamine (that is, serotonin,
norepinephrine, dopamine) synthesis.
Taken together, both the recent work emphasizing the
role of uncoupled eNOS-induced oxidative stress in the pathogenesis of vascular
diseases and the epidemiological studies
establishing depression as an independent risk factor for vascular pathologies,
such as stroke and heart disease, add further support to the clinical relevance
of uncoupled eNOS-mediated endothelial oxidative damage in depression. Despite
abundant evidence for cytokine abnormalities in human psychiatric illnesses and
the experimental data showing that proinflammatory cytokines can reduce eNOS
expression and increase BBB permeability, human evidence that directly links
excess proinflammatory cytokines to eNOS dysfunction and/or BBB impairment is
lacking.
Imaging and treating inflammation in psychiatric
illness
Imaging neuroinflammation in situ
Clinically, neuroinflammation imaging may prove to be
crucial for identifying the subgroup of psychiatric patients with
neuroinflammation who would be most likely to respond favorably to
immunomodulatory therapies. Additionally, such imaging may allow clinicians to
monitor neuroinflammation-related disease activity and its response to immune
therapy in psychiatric patients. Imaging inflammation in the human brain has
traditionally depended upon MRI or CT visualization of extravagated intravenous
contrast agents, indicating localized breakdown of the BBB. Gadolinium-enhanced
MRI occasionally demonstrates such breakdown in the limbic regions associated
with emotional processing in patients with psychiatric disorders attributable
to paraneoplastic or other encephalitides. To our knowledge, however, abnormal
enhancement has never been demonstrated in any classical psychiatric disorder,
despite functional and ultrastructural BBB abnormalities.
Whether or not subtler neuroinflammation can be
visualized in vivo in classical psychiatric disorders
remains unknown. One promising technique is positron emission tomography (PET)
using radiotracers, such as C11-PK11195, which bind to the translocator
protein, previously known as the peripheral benzodiazepine receptor, expressed
by activated microglia.
Using this method, patients with schizophrenia were
shown to have greater microglial activation throughout the cortex and in the
hippocampus during acute psychosis. One study (14 schizophrenia, 14 controls)
found no significant difference between [11C] DAA1106 binding in schizophrenia
versus controls, but a direct correlation between [11C] DAA1106 binding and the
severity of positive symptoms and illness duration in schizophrenia.
Investigators from our institution utilized
C11-PK11195 PET to demonstrate bi-hippocampal inflammation in a patient with
neuropsychiatric dysfunction, including psychotic MDD, epilepsy, and
anterograde amnesia, associated with anti-GAD antibodies. However, PK11195 PET
has low signal-to-noise properties and requires an on-site cyclotron.
Accordingly, research is being devoted to developing
improved translocator protein ligands for PET and SPECT. Future high-powered
post-mortem brain tissues studies utilizing protein quantification aimed at
elucidating metabolic and inflammatory pathways, CNS cytokines and their
binding receptors, in psychiatric disorders are needed to advance our
understanding of the autoimmune pathophysiology.
Role of antiinflammatory drugs in psychiatric
disorders
Several human and animal studies suggest that certain
antiinflammatory drugs may play an important adjunctive role in the treatment
of psychiatric disorders. Common drugs are cyclooxygenase inhibitors,
minocycline, omega-3 fatty acids, and neurosteroids.
Several human studies showed that COX-2 inhibitors
could ameliorate psychiatric symptoms of MDD, BPD, schizophrenia and OCD. By
contrast, adjunctive treatment with non-selective COX-inhibitors (that is,
non-steroidal antiinflammatory drugs (NSAIDs)) may reduce the efficacy of
SSRIs; two large trials reported that exposure to NSAIDs (but not to either
selective COX-2 inhibitors or salicylates) was associated with a significant
worsening of depression among a subset of study participants.
In the first trial, involving 1,258 depressed patients
treated with citalopram for 12 weeks, the rate of remission was
significantly lower among those who had taken NSAIDs at least once relative to
those who had not (45% versus 55%, OR 0.64, P = 0.0002). The
other trial, involving 1,545 MDD subjects, showed the rate of
treatment-resistant depression was significantly higher among those taking
NSAIDs (OR 1.55, 95% CI 1.21 to 2.00). The worsening of depression in the NSAID
groups may not be mechanistically linked to NSAID therapy but instead related
to co-existing chronic medical conditions that necessitate long-term NSAIDs and
which are known to be independently associated with increased risk of
treatment-resistant depression. Future studies investigating the impact of
NSAIDs on depression and response to antidepressants in humans are needed.
In other experimental studies utilizing acute-stress
paradigms to induce a depression-like state in mice, citalopram increased TNF-α, IFN-γ, and p11 (molecular factor linked to depressive
behavior in animals) in the frontal cortex, while the NSAID ibuprofen decreased
these molecules; NSAIDs also attenuated the antidepressant effects of SSRIs but
not other antidepressants. These findings suggest that proinflammatory
cytokines may paradoxically exert antidepressant effects despite overwhelming
evidence from human studies to the contrary (as reviewed above), which can be
attenuated by NSAIDs. At least two considerations may account for this apparent
paradox: 1) under some experimental conditions, proinflammatory cytokines have
been associated with a neuroprotective role, [251; (for example, IFN-γ in low levels can induce
neuroprotective microglia; and 2) whether these responses observed in the
context of an acute stress paradigm in an animal model are applicable to
endogenous MDD in humans remains unclear.
The therapeutic effects of COX-2 inhibitors in psychiatric
disorders may involve modulation of biosynthesis of COX-2-derived
prostaglandins, including proinflammatory PGE2 and antiinflammatory 15-deoxy-Δ12,14-PGJ2 (15d-PGJ2). COX-2
inhibitors can reduce PGE2-mediated inflammation, which may contribute to the
pathophysiology of psychiatric disorders. They may also alter the levels
15d-PGJ2, and the activity of its nuclear receptor peroxisome
proliferator-activated nuclear receptor gamma (PPAR-γ).
Several studies suggest that 15d-PGJ2 and
its nuclear receptor PPAR-γ can serve as
biological markers for schizophrenia. In schizophrenic patients, serum PGE2
levels are increased, whereas serum levels of 15d-PGJ2 are
decreased, as is the expression of its nuclear receptor PPAR-γ in PBMC. While COX-2 inhibitors
may limit the potentially beneficial antiinflammatory effects of the
COX-2–dependent ‘15d-PGJ2/PPAR-γ pathway’, they may advantageously reduce its harmful
effects, including 1) the increased risk for myocardial infarction and certain
infections (for example, cytomegalovirus and Toxoplasma gondii)
in schizophrenic patients and 2) its pro-apoptotic effects observed in human
and animal cancer tissue. Other potential mechanisms of COX-2 inhibitors
therapeutic effects may involve their ability to reduce proinflammatory
cytokine levels, limit quinolinic acid excitotoxicity (as in MDD) and decrease
KYNA levels (as in schizophrenia).
Minocycline can be effective in psychiatric
disorders. In vitro data suggest that minocycline inhibits
MAP, cytokine secretion, ‘COX-2/PGE-2 expression,’ and inducible nitric oxide
synthase. Minocycline may also counteract dysregulated glutamatergic and
dopaminergic neurotransmission.
Omega-3 fatty acid effectiveness in psychiatric
disorders is unclear. In a 2011 meta-analysis of 15 randomized-controlled
trials (916 MDD), omega-3 supplements containing eicosapentaenoic acid ≥60%
(dose range 200 to 2,200 mg/d in excess of the docosahexaenoic acid dose)
significantly decreased depressive symptoms as an adjunctive therapy to SRIs (P <0.001).
A subsequent meta-analysis, however, concluded that there is no significant
benefit of omega-3 fatty acids in depression and that the purported efficacy is
merely a result of publication bias. A 2012 meta-analysis of 5
randomized-controlled trials including 291 BPD participants found that
depressive, but not manic, symptoms were significantly improved among those
randomized to omega-3 fatty acids relative to those taking placebo (Hedges g
0.34, P = 0.025). In a randomized controlled trial of
schizophrenic subjects followed up to 12 months, both positive and
negative symptom scores were significantly decreased among the 66 participants
randomized to long-chain omega-3 (1.2 g/day for 12 weeks; P = 0.02
and 0.01, respectively); the authors concluded that omega-3 augmentation during
the early course of schizophrenia can also prevent relapses and disease
progression.
A 2012 meta-analysis of seven randomized-controlled
trials assessing omega-3 augmentation in 168 schizophrenic patients found no
benefit of treatment. The authors of this meta-analysis specifically stated
that no conclusion could be drawn regarding the relapse prevention or disease
progression endpoints. Experimental data suggest that eicosapentaenoic acid and
docosahexaenoic acid mediate their antiinflammatory effects by promoting
synthesis of resolvins and protectins, which can inhibit leukocyte infiltration
and reduce cytokine production.
Neurosteroids, including pregnenolone and its
downstream metabolite allopregnanolone, may have a beneficial role in some
psychiatric disorders. In MDD, several studies found decreased plasma/CSF
allopregnanolone levels correlating with symptom severity, which normalized
after successful treatment with certain antidepressants (for example, SSRIs),
and electroconvulsive therapy. In schizophrenia, brain pregnenolone levels can
be altered and serum allopregnanolone levels may increase after some
antipsychotic drugs (for example, clozapine and olanzapine). In three
randomized-controlled trials (100 schizophrenia (pooled); treatment duration,
approximately nine weeks) positive, negative, and cognitive symptoms, as well
as extrapyramidal side effects of antipsychotics were significantly improved in
one or more trials among those randomized to pregnenolone relative to those
receiving placebo. In one trial, the improvement was sustained with long-term
pregnenolone treatment. Pregnenolone can regulate cognition and behavior by
potentiating the function of NMDA and GABAA receptors.
Furthermore, allopregnanolone may exert neuroprotective and antiinflammatory
effects. More RCT studies are needed to confirm the beneficial role of
neuroactive steroids in early-onset psychiatric disorders in humans.
We are awaiting the results of several ongoing
clinical trials investigating the therapeutic effects of other
anti-inflammatory agents, including salicylate, an inhibitor of NF-κB (NCT01182727); acetylsalicylic
acid (NCT01320982); pravastatin (NCT1082588); and dextromethorphan, a
non-competitive NMDAR antagonist that can limit inflammation-induced
dopaminergic neuronal injury (NCT01189006).
Future treatment strategies
Although current immune therapies (for example, IVIG,
plasmapheresis, corticosteroids and immunosuppressive agents) are often
effective for treating autoimmune encephalitides wherein inflammation is acute,
intense and predominately of adaptive origin, their efficacy in classical
psychiatric disorders wherein inflammation is chronic, much milder, and
predominately of innate origin, is limited. Development of novel therapeutics
should aim at reversing glial loss, down-regulating harmful MAP, while
optimizing endogenous neuroprotective T regs and beneficial MAP, rather than
indiscriminately suppressing inflammation as occurs with current
immunosuppressive agents. Additionally, development of potent co-adjuvant
antioxidants that would reverse oxidative injury in psychiatric disorders is
needed.
Conclusions
Autoimmunity can cause a host of neuropsychiatric
disorders that may initially present with isolated psychiatric symptoms. Innate
inflammation/autoimmunity may be relevant to the pathogenesis of psychiatric
symptoms in a subset of patients with classical psychiatric disorders. Innate
inflammation may be mechanistically linked to the traditional monoaminergic and
glutamatergic abnormalities and increased oxidative injury reported in
psychiatric illnesses.
Abbreviations
3-OH-KYN: 3-hydroxy-kynurenine; α7nAchR: Alpha 7 nicotinic acetylcholine receptors;
AMPAR: Amino-3-hydroxy-5-methyl-l-4-isoxazolepropionic acid receptors; APC:
Antigen presenting cell; BBB: Blood–brain barrier; BH4: Tetrahydrobiopterin;
BPD: Bipolar disorder; CI: Confidence interval; CNS: Central nervous system;
COX-2: Cyclooxegenase-2; CSF: Cerebrospinal fluid; DSM-IV: Diagnostic and
Statistical Manual of Mental Disorders 4th Edition; EAATs: Excitatory amino
acid transporters; eNOS: Endothelial nitric oxide synthase; GABAB: Gamma
aminobutyric acid-beta; GAD: Glutamic acid decarboxylase; GFAP: Glial
fibrillary acidic protein; GLX: 1H MRS detectable glutamate,
glutamine, gamma aminobutyric acid composite; IDO: Indoleamine 2,3-dioxygenase;
Ig: Immunoglobulin; IL: Interleukin; IL-1RA: Interleukin 1 receptor antagonist;
IFN-γ: Interferon gamma;
KAT: Kynurenine aminotransferase; KMO: Kynurenine 3-monooxygenase; KYN:
Kynurenine; KYNA: Kynurenic acid; LE: Limbic encephalitis; LPS:
Lipopolysaccharide; MAP: Microglial activation and proliferation; MDD: Major
depressive disorder; mGluR: Metabotropic glutamate receptor; MHC: II Major
histocompatibility complex class two; MRI: Magnetic resonance imaging; MRS:
Magnetic resonance spectroscopy; NF-κB: Nuclear factor kappa B; NMDAR: N-methyl-D-aspartate
receptor; NR1: Glycine site; OCD: Obsessive-compulsive disorder; OR: Odds
ratio; PANDAS: Pediatric neuropsychiatric autoimmune disorders associated with
streptococcal infections; PBMC: Peripheral blood mononuclear cells; PET:
Positron emission tomography; PFC: Prefrontal cortex; PGE-2: Prostaglandin E2;
PPAR-γ: Peroxisome
proliferator-activated nuclear receptor gamma; QA: Quinolinic acid; RNS:
Reactive nitrogen species; ROS: Reactive oxygen species; sIL: Soluble
interleukin; SLE: Systemic lupus erythematosus; SRI: Serotonin reuptake
inhibitor; TNF-α: Tumor necrosis
factor alpha; T-regs: CD4+CD25+FOXP3+ T
regulatory cells; TDO: Tryptophan-2,3-dioxygenase; Th: T-helper; VGKC:
Voltage-gated potassium channel; XAG-: Glutamate aspartate transporter; Xc-:
Sodium-independent astroglial glutamate/cystine antiporter system
Competing
interests
The authors declare that they have no competing
interests.
Authors’
contributions
SN and DMP performed an extensive literature review,
interpreted data, prepared the manuscript, figures, and tables. KA prepared the
section pertaining to oxidative mechanisms and contributed to the manuscript
revisions. AN and OD critically-revised and improved the design and quality of
the manuscript. All authors read and approved the final manuscript.
Acknowledgments
We gratefully acknowledge Drs. Josep Dalmau, MD, PhD,
Tracy Butler, MD, and David Zazag, MD, PhD, for providing their expertise in
autoimmune encephalitides, neuroinflammation imaging, and neuropathology,
respectively.
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