Chapter 9. Brain–Immune System Interactions: Relevance to the Pathophysiology and Treatment of Neuropsychiatric Disorders

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Charles L. Raison, Monica Kelly Cowles, Andrew H. Miller: Chapter 9. Brain–Immune System Interactions: Relevance to

the Pathophysiology and Treatment of Neuropsychiatric Disorders, in The American Psychiatric Publishing Textbook of

Psychopharmacology, 4th Edition. Edited by Alan F. Schatzberg, Charles B. Nemeroff. Copyright ©2009 American

Psychiatric Publishing, Inc. DOI: 10.1176/appi.books.9781585623860.417357. Printed 5/10/2009 from

www.psychiatryonline.com

Textbook of Psychopharmacology >

Chapter 9. Brain–Immune System Interactions: Relevance to the

Pathophysiology and Treatment of Neuropsychiatric Disorders

BRAIN–IMMUNE SYSTEM INTERACTIONS: RELEVANCE TO THE

PATHOPHYSIOLOGY AND TREATMENT OF NEUROPSYCHIATRIC

DISORDERS: INTRODUCTION

Although once considered heresy, the notion that meaningful interactions occur between the brain

and the immune system has become scientific dogma. This change in scientific orthodoxy results

from more than 30 years of research demonstrating that brain-mediated events, such as

psychological stress and depression, can alter peripheral immune system functioning and,

conversely, that changes in peripheral immune functioning, such as those that occur during illness,

can profoundly affect the brain, leading to clinically meaningful changes in mood, anxiety, and

cognition. In this chapter, we provide an overview of brain–immune system interactions that are of

potential relevance to the field of psychiatry.

This effort needs to be understood within the far wider context of psychoneuroimmunology, which

is the interdisciplinary field that focuses on brain–mind–immune system interactions. When Robert

Ader first coined the term psychoneuroimmunology as a title for his textbook on brain–immune

system interactions in 1981, the resulting text filled a single slim volume (Ader 1981). In contrast,

the most recent edition fills two volumes, each running more than 1,000 pages, and covers topics

as diverse as gene–ribonucleic acid interactions within the cellular nucleus and the effects of

spirituality on the immune system (Ader 2007).

THE IMMUNE SYSTEM: AN OVERVIEW

When considered in the broadest sense as the process whereby organisms maintain functional and

organizational integrity against foreign encroachment, immunity is clearly a prerequisite to life

itself. Given this, it is not surprising that even the simplest of organisms demonstrate immune

functioning, which is consistent with the notion that immunity arose early in the evolution of life on

earth (Maier and Watkins 1998). In vertebrates, the immune system has evolved a wide array of

separate, but cooperative, mechanisms that serve to attack invading pathogens, destroy tumor

cells, and remove and repair damaged tissue. From an evolutionary perspective, the high rate of

autoimmune disorders, such as multiple sclerosis and rheumatoid arthritis, suggests that the

adaptive advantages of robust immune system functioning outweigh the frequently disastrous

consequences engendered when the immune system overreacts and begins attacking the self

(Nesse and Williams 1994). The immune system review that follows is necessarily simplified. More

extensive discussions of the immune system can be found elsewhere (Abbas and Lichtman 2004;

Rabin 1999; Roitt et al. 1998).

Innate Versus Acquired Immunity

A primary distinction within the immune system is between innate immunity (also known as natural

or nonspecific immunity) and acquired (or specific) immunity. Innate immunity provides a first line

of defense by attacking foreign substances rapidly in a nonspecific manner, without requiring that a

specific antigen (or antibody-generating molecule) be recognized (Table 9–1). Although this lack of

antigenic specificity precludes the development of an immunological memory to speed the response

should a pathogen be encountered again in the future, the nonselectivity of the innate immune

system allows for a rapid response to a wide variety of environmental assaults. The immediatePrint: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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response sets in motion a complicated series of processes that contribute to activation of the

acquired immune system, which responds more slowly, but far more selectively, to the particular

invading entity. An acquired immune response requires specific recognition of a foreign substance

and allows for the establishment of memory cells that react far more quickly when the same

substance is again encountered. Finally, both innate and acquired immune systems contain

mechanisms to control and extinguish activation; therefore, immune activity, with its attendant

metabolic costs and danger of self attack, does not become self-perpetuating.

TABLE 9–1. Major divisions of the immune response

Acquired immune response

Innate immune response Cellular response Humoral response

Effector cells Phagocytes (macrophages,

neutrophils), NK cells

Th1 lymphocytes, cytolytic T

lymphocytes

Th2 lymphocytes, B

lymphocytes

Soluble mediators Complement, acute-phase

reactants

Antibodies

Representative

cytokines

TNF- , IL-1 and , IL-6 IL-2, IL-12, IFN-

IL-4, IL-10

Note. IFN = interferon; IL = interleukin; NK = natural killer; Th1 = T-helper 1; Th2 = T-helper 2; TNF =

tumor necrosis factor.

Innate immunity begins with the skin and other mucosal surfaces lining the gastrointestinal and

respiratory tracts, which provide a physiochemical barrier to invasion by foreign pathogens. When

these surfaces are breached, phagocytic cells, such as macrophages, microglia (in the brain), and

certain dendritic cells, recognize invading pathogens through relatively crude pattern-recognition

molecules referred to as toll-like receptors and, depending on the cell type, ultimately engulf and

destroy these foreign agents. Upon activation, these cells and other participants in the early innate

immune response (e.g., natural killer [NK] cells) release soluble, proteinaceous, immune mediators

known as cytokines. Cytokines that mediate innate immunity include the type I interferons, which

have direct antiviral effects, and proinflammatory cytokines. Of these, interleukin-1 (IL-1),

interleukin-6 (IL-6), and tumor necrosis factor– (TNF- ) are important in inducing inflammation at

the site of pathogen invasion or tissue damage. IL-6 also plays a central role in stimulating the liver

to produce a host of acute-phase reactants, such as C-reactive protein; 1-acid glycoprotein;

complement C3; haptoglobin; 2-macroglobulin; 1-antitrypsin; ceruloplasmin; and -, -, and

-fibrinogen (Baumann and Gauldie 1994). These proteins, which make up the acute-phase

response, serve to both facilitate destruction of foreign substances and limit tissue damage from

immune activation. In addition to the release of cytokines and acute-phase proteins, other

molecules are induced, including chemokines and adhesion molecules, which assist in the

recruitment of multiple cell types to the site of infection and/or tissue damage and destruction.

Depending on the magnitude of the innate immune response, relevant cytokines can enter the

peripheral blood or activate local afferent nerve fibers and have potent effects on the

neuroendocrine system, especially the hypothalamic-pituitary-adrenal (HPA) axis and the central

nervous system (CNS), where they mediate many symptoms of illness, including fever, loss of

appetite, social withdrawal, and sleep changes (Maier et al. 1998). These behavioral changes are

believed to subserve the metabolic demands inherent in the task of fighting infection and

maintaining an elevated body temperature.

Acquired immunity relies on hematopoietically derived lymphocytes, which have the ability to

specifically recognize an astoundingly wide array of foreign substances. These lymphocytes fall into

two general categories. T lymphocytes mature in the thymus and mediate cellular immunity, which

is essential for protection against intracellular pathogens, such as viruses and mycobacteria. B

lymphocytes mature in the bone marrow and produce antibodies that are especially effective in

neutralizing bloodborne and extracellular pathogens, such as parasites, viruses in replication

phase, and many species of bacteria. A further key function of the acquired immune system is toPrint: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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screen out lymphocytes that might react against self molecules. When this essential function fails,

autoimmune conditions can result.

Like innate immunity, acquired immunity utilizes soluble cytokine mediators. It is generally

recognized that an acquired immune response develops along one of two lines, Th1 or Th2, on the

basis of the cytokine profiles induced by T-helper CD4 cells (Elenkov and Chrousos 1999). A Th1

response is characterized by cytokines that promote cell-mediated inflammatory reactions, such as

delayed-type hypersensitivity (DTH). These cytokines include interleukin-2 (IL-2), interleukin-12

(IL-12), tumor necrosis factor– (TNF- ), and interferon- (IFN- ). Cytokines generated by

T-helper cells during a Th2 immune response include interleukin-4 (IL-4), interleukin-9 (IL-9), and

interleukin-10 (IL-10). IL-6 is also produced by CD4 cells during a Th2-type acquired immune

response. The development of a Th2 response favors antibody production, may provide protection

against parasites, and is associated with allergic and hypersensitivity reactions.

An acquired immune system response consists of three phases: an induction phase, in which the

system detects the presence of antigen; an activation phase, in which the presence of antigen

triggers the expansion of antigen-specific T and B cells; and an effector phase, in which the foreign

substance is cleared from the body (Miller et al. 2000). In this process, the acquired immune

system utilizes and empowers many innate immune elements. For example, the coating of bacteria

by B cell–produced antibodies enhances the ability of innate immune system phagocytes to destroy

pathogens. Like other complicated physiological response systems, the immune response has

built-in negative feedback elements that have evolved to limit immune reactivity once the

pathogenic challenge has been met. Other bodily systems, including the HPA axis, perform

important extrinsic immunomodulatory roles, and when functioning optimally, these systems limit

inflammation and immune system proliferation. A final feature of the acquired immune system,

which is central to its functioning, is the formation of long-lived B and T lymphocytes that serve as

memory cells for recognizing an antigen should it be encountered in the future. This mechanism

accounts for the ability of acquired immunity to mount far more rapid and effective responses to

previously seen antigens. It also provides the physiological basis for the effectiveness of vaccines,

which activate acquired immunity toward a specific pathogen without inducing illness.

BRAIN TO BODY: CENTRAL NERVOUS SYSTEM EFFECTS ON THE IMMUNE

SYSTEM

Despite the fact that a general belief in the ability of psychological states to affect health has been

apparent since antiquity, scientific formulations, until recently, have tended to view the CNS and

the immune system as separate and noninteracting entities. Indeed, the immune system has

historically been conceptualized as autonomous and self-contained, with a purpose that begins and

ends with the tasks of protection against infection and malignancy and the repair of damaged

tissue. Such a view tends to preclude any physiological mechanism by which mental events might

directly affect immune functioning. However, in the 1970s, researchers made the startling

discovery that the immune system was amenable to classical Pavlovian conditioning (Ader and

Cohen 1975). Numerous studies have confirmed and extended this initial insight and established

beyond argument the ability of brain states to significantly modulate immune system functioning.

The majority of these studies have focused on the effects of stress on the immune response.

Virtually every type of stressor, ranging from laboratory stressors (e.g., public speaking, mental

arithmetic) to more naturalistic stressors (e.g., bereavement, loneliness, and academic

examinations), has demonstrated a measurable effect on the immune response, including effects on

various aspects of both innate and acquired immunity (Raison et al. 2002). Although the

relationship between stress and immunity is quite complex, more acute and/or mild stressors, in

general, tend to be associated with activation of immune responses, whereas more chronic and

intense stressors tend to be associated with activated innate immune system elements and

impaired acquired immune system responses. The health relevance of these stress-related immune

changes has been demonstrated in studies that have shown an association between chronic stress

and increased susceptibility to the common cold, reduced antibody responses to vaccination, and

delayed wound healing (Cohen et al. 1991; Glaser et al. 1992; Kiecolt-Glaser et al. 1995). In Print: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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addition, stress, as well as depression, has been linked to increased morbidity and mortality in

infectious diseases (e.g., HIV infection), neoplastic diseases (including breast cancer and malignant

melanoma), diabetes, and cardiovascular disease (Evans et al. 2005; Fenton and Stover 2006;

Leserman et al. 1999; Raison and Miller 2003a).

Effects of Depression and Stress on Acquired Immune (Lymphocyte)

Responses

In psychiatry, the practical import of connections between brain outflow pathways and the immune

system has been best documented in the effects of stress-related disorders, especially major

depression, on immune functioning. Despite a significant degree of heterogeneity across individual

studies, significant evidence suggests that patients with major depression demonstrate a number of

immune changes similar to those seen in individuals undergoing chronic and/or severe stress

(Herbert and Cohen 1993; Zorrilla et al. 2001). This is hardly surprising, given the many indices of

stress system hyperactivity that are apparent in patients with major depression, including

increased corticotropin-releasing hormone (CRH) and cortisol production (Pariante et al. 1995) and

augmented sympathetic nervous system (SNS) activity as manifested in part by increased

peripheral blood catecholamines (Veith et al. 1994; Wong et al. 2000). Enumerative immune

changes shared by major depression and chronic/severe stress include a decrease in lymphocytes,

B cells, and T cells and an increase in the ratio of CD4 to CD8 T cell subsets (Herbert and Cohen

1993). Shared functional changes include a decrease in NK cell activity and lymphocyte

proliferation in response to nonspecific mitogens (Herbert and Cohen 1993; Zorrilla et al. 2001).

In a meta-analysis examining the issue, major depression was found to have a larger effect than

stress on these immune variables (Zorrilla et al. 2001) (Table 9–2). It is important to note,

however, that major depression is a heterogeneous condition and that immune changes are not

uniform across all patients. Indeed, inhibited lymphocyte responses tend to be most striking in

patients who are older, are hospitalized, or have more severe and/or melancholic types of

depression (Miller 1998; Schleifer et al. 1989). In addition, the sleep changes common in

depression are known to alter lymphocyte responses, especially NK cell activity (NKCA), even in the

absence of other depressive symptoms (Irwin et al. 1996). Nonetheless, it does not appear that

these factors completely account for the association between major depression and alterations in

measures of the number and function of lymphocyte subsets (Herbert and Cohen 1993).

TABLE 9–2. Immune alterations in major depression

Increased white blood cells

Increased neutrophil percentage

Decreased lymphocyte percentage

Increased CD4-to-CD8 ratio

Decreased natural killer cell activity

Decreased mitogen-induced lymphocyte proliferation

Increased interleukin-6

Increased haptoglobin

Increased prostaglandin E2

Compared with chronic/severe stress, major depression has been less well characterized in terms

of effects on in vivo functional immunity; however, the little evidence that is available suggests that

depression, like chronic/severe stress, may impair T-cell function in ways that are relevant to

disease vulnerability. For example, although it is not known whether major depression is associated

with an increase in antibody titers to latent viruses, one study reports that patients with major

depression have a marked decrease in the ability to generate lymphocytes that respond to the

herpes zoster virus (Irwin et al. 1998). Also consistent with impaired T-cell function in depression

is the observation that depressed patients, especially those with melancholia, demonstratePrint: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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impaired DTH (Hickie et al. 1993).

Effects of Depression and Stress on Innate Immune Inflammatory

Responses

Although stress and depression have been most often seen as suppressing lymphocyte function,

emerging data suggest that such a conclusion oversimplifies the complexities of the mammalian

immune response to environmental perturbation and that stress indeed may also activate certain

aspects of the immune system (Raison and Miller 2001; Raison et al. 2006). For example, stress

exposure in animals and humans has been shown to increase the expression of innate immune

cytokines (Goebel et al. 2000; Maier and Watkins 1998; Paik et al. 2000), activate microglia (Frank

et al. 2007), and sensitize subsequent immune responses to inflammatory immune challenge

(Johnson et al. 2004). Peripheral production of either IL 1 or its soluble receptor antagonist

(sIL-1ra), as well as IL-6, has been reported to be increased in the context of several acutely

stressful situations, including exercise, academic examinations, and laboratory stressors

(Ackerman et al.1998; Goebel et al. 2000; Maes et al. 1998; Pace et al. 2006; Paik et al. 2000;

Steptoe et al. 2001). While the mechanism by which stress induces cytokine production has yet to

be fully elucidated, it has been shown that catecholamines may play an important role. In

particular, – but not -adrenoreceptors are critical for central production of inflammatory

cytokines, whereas both – and -adrenoreceptors contribute to the induction of plasma cytokines

following stress (Johnson et al. 2005). These effects of stress appear to be mediated in part by

activation of inflammatory signaling pathways including nuclear factor kappa B (NF- B), which is a

linchpin in the initiation of the inflammatory response following the stimulation of toll-like

receptors as well as relevant cytokine receptors (Bierhaus et al. 2003).

A growing database suggests that depression (in addition to stress) in both medically healthy and

medically ill patients is associated with innate immune system activation (Andrei et al. 2007; Kim

et al. 2007; Lesperance et al. 2004; Maes 1999; Musselman et al. 2001b; Raison et al. 2006).

Findings consistent with inflammatory activation in depression include increased plasma and

cerebrospinal fluid (CSF) concentrations of inflammatory cytokines, increased in vitro production of

proinflammatory cytokines from stimulated peripheral blood mononuclear cells, increased

acute-phase proteins (and decreased negative acute-phase proteins), increased chemokines and

adhesion molecules, and increased production of prostaglandins (Kim et al. 2007; Maes 1999;

Raison et al. 2006). Based on meta-analyses, increases in peripheral blood IL-6 and C-reactive

protein are two of the most reliable inflammatory biomarkers associated with depression (Zorrilla

et al. 2001). Indeed, careful studies examining IL-6 across the circadian cycle have shown a

reverse circadian pattern of IL-6 in depressed patients, with markedly elevated levels of this

cytokine compared with control subjects during the morning hours (Alesci et al. 2005).

Interestingly, given the role of IL-6 and C-reactive protein in predicting disease outcome in both

cardiovascular disorders and diabetes (Ridker et al. 2000a, 2000b), as well as data indicating that

inflammation may play a role in cancer (Aggarwal et al. 2006), the relationship between depression

and activation of the innate immune inflammatory response may provide a mechanism that explains

the negative impact of depression on a number of illnesses (Evans et al. 2005). Moreover, immune

activation in major depression may be involved in several of the pathophysiological changes that

are common in the context of depression, including bone loss, insulin resistance, cachexia,

increased body temperature, and hippocampal volume loss (Raison et al. 2006). Interestingly,

activation of innate immune responses following stress and depression may also contribute to

stress- and depression-induced decreases in acquired immune (lymphocyte) responses. For

example, administration of IL-1ra prior to stressor exposure has been found to reduce the

inhibitory impact of stress on antibody production (Moraska et al. 2002).

There are a number of potential factors that may contribute to increased innate immune responses

in depressed patients. One factor that has received special attention is body mass index (BMI). BMI

has been reliably correlated with peripheral markers of inflammation including IL-6, in part related

to the capacity of adipocytes to produce inflammatory cytokines (Schaffler et al. 2007). Relevant in

this regard, an analysis of data from the Third National Health and Nutrition Examination SurveyPrint: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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revealed that after adjustment for a multitude of variables, including BMI, there was a strong

association between major depression and elevated levels of C-reactive protein in men but not

women (Ford and Erlinger 2004). Early life stress is another factor that may be involved. For

example, males with current major depression and increased early life stress exhibited significantly

greater increases in IL-6 and NF- B DNA binding following a psychosocial stressor compared with

control subjects (Pace et al. 2006).

Given the anti-inflammatory properties of glucocorticoids (Rhen and Cidlowski 2005) (see below for

further discussion of the immunological effects of glucocorticoids), it might be expected that

patients with depression who have decreased glucocorticoid sensitivity, as manifested by

nonsuppression of cortisol on the dexamethasone suppression test (DST), would be especially

prone to showing evidence of immune activation. Some evidence suggests that this is indeed the

case. Compared with patients with depression who have normal in vivo glucocorticoid sensitivity,

patients who are DST nonsuppressors demonstrate increased plasma concentrations of the

acute-phase reactant 1-glycoprotein, as well as increased in vitro mitogen-stimulated IL-6

production (Sluzewska 1999). Glucocorticoid resistance, as assessed by the DST, has been

associated with a poor response to antidepressant treatment (Holsboer 2000). Of interest, in light

of the relationship between DST nonsuppression and increased inflammatory activity, findings

suggest that patients with depression who are treatment resistant are more likely than patients

who are treatment responders to show evidence of increased inflammatory activity, including

increased plasma concentrations of acute-phase proteins, IL-6, and the soluble receptor for IL-6

(sIL-6r), which synergistically enhances IL-6 activity (Raison et al. 2006; Sluzewska 1999).

Moreover, depressed patients who exhibit a decrease in unstimulated TNF- during antidepressant

treatment are more likely to respond than those whose TNF- remains elevated (Lanquillon et al.

2000).

Other Psychiatric Disorders and the Immune Response

Some evidence suggests that other stress-related neuropsychiatric conditions may be associated

with immune activation, although these conditions are less well characterized than major

depression. These disorders include posttraumatic stress disorder (PTSD), chronic fatigue

syndrome (CFS), seasonal affective disorder (SAD), and fibromyalgia. Patients with combat-related

PTSD have been reported to demonstrate increased plasma concentrations of IL-1 and increased

CSF concentrations of IL-6 (Baker et al. 2001; Spivak et al. 1997). PTSD following civilian disasters

appears to be associated with elevated plasma concentrations of IL-6 and its soluble receptor

(Maes et al. 1999c). Although not found consistently (Maes et al. 1999c), both severity of

symptoms and duration of illness have been reported to correlate positively with indices of immune

activation in PTSD (Miller et al. 2001; Spivak et al. 1997).

A growing body of literature suggests that patients exposed to early life trauma may be especially

vulnerable to the development of psychophysical disorders (e.g., CFS, fibromyalgia) that are

characterized by complaints of chronic pain, fatigue, and cognitive difficulties of unknown etiology

(Heim et al. 1997). Consistent with this, these disorders have also been associated with evidence of

increased inflammatory activity. For example, it has been reported that both CFS and fibromyalgia

are accompanied by an increase in acute-phase reactants and increased plasma concentrations

and/or peripheral blood mononuclear cell production of proinflammatory cytokines, including IL-1,

IL-6, and TNF- (Borish et al. 1998; Cannon et al. 1999; Gupta et al. 1997; Maes et al. 1999b). Of

note, one report indicates that SAD, a condition with significant symptom overlap with CFS and

fibromyalgia, may be characterized by increased plasma concentrations of IL-6 (Leu et al. 2001).

Finally, although the picture is far less clear, there has been speculation that immune system

activation may contribute to the pathophysiology of psychotic disorders, including schizophrenia,

possibly related to an autoimmune diathesis (Pearce 2001; Rothermundt et al. 2001). Elevated

levels of cytokines and their receptors, including IL-2, sIL-2, and IL-6, have been reported in the

blood and CSF of patients with schizophrenia, and a high level of CSF IL-2 has been found to predict

subsequent schizophrenic relapse (Rothermundt et al. 2001). In a related fashion, considerationPrint: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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has been given to the role of viral infection early in development (Pearce 2001), based on seasonal

birth patterns that have been reliably replicated in large epidemiological studies of patients with

schizophrenia. These findings are consistent with in utero infections of relevant brain structures,

including the hippocampus, during critical periods of development (especially during the second

trimester) (Pearce 2001). Moreover, cross-reactivity between brain antigens and antigens of

infectious agents may contribute not only to schizophrenia but also to the neurological and

psychiatric complications associated with streptococcal infection (i.e., pediatric autoimmune

neuropsychiatric disorders associated with streptococcal infections [PANDAS]) (Snider and Swedo

2000).

MEDIATING PATHWAYS

Underlying the ability of the CNS to affect the immune system is a host of connections between

autonomic and neuroendocrine pathways and immune system elements. Immune cells are able to

directly respond to brain outflow pathways via receptors for small-molecule neurotransmitters,

adrenal and gonadal steroids, hypothalamic-releasing factors, and other neuropeptides (Raison et

1. 2002). Specific receptor densities vary among immune cell types, and these variations correlate

with cell sensitivity to a given ligand.

Autonomic Nervous System

It is well known that sympathetic and parasympathetic pathways within the autonomic nervous

system (ANS) interact to maintain homeostasis in a variety of physiological states, including

regulation of the immune response. In addition to expressing receptors for autonomic and

neuroendocrine signaling molecules, immune cells and tissues are innervated by fibers derived

from the ANS, together comprising a neural pathway which can reflexively regulate the immune

response (Czura et al. 2007; Downing and Miyan 2000; Miller 1998; Raison et al. 2002; Sanders and

Kavelaars 2007; Tracey 2002). For example, the sympathetic branch of the ANS sends fibers into

immune tissues in association with the vascular supply. Within tissue parenchyma, these fibers are

associated with vascular smooth muscle cells, where they regulate vascular tone. In addition,

sympathetic nerve terminals have been observed by electron microscopy to exist in close

approximation with lymphocytes and macrophages. Thus, the sympathetic branch of the ANS

appears able to influence the immune system either by changing the vascular tone and blood flow

into lymphoid organs or by directly influencing immune cell function via locally released

neurotransmitters, especially norepinephrine and neuropeptides such as neuropeptide Y, substance

P, vasoactive intestinal peptide, calcitonin gene–related peptide, and CRH, which, in turn, interact

with specific receptors on nearby immune cells (Bellinger et al. 1997; Czura et al. 2007).

Initial conceptualizations of the effect of the SNS on immune functioning tended to view the system

as being primarily immunosuppressive. Catecholamines are well known to diminish NKCA and

nonspecific mitogen-stimulated lymphocyte proliferation and appear to be the primary mediators of

rapid immune changes in humans in response to acute stress paradigms (Raison and Miller 2001).

Many of the immunosuppressive effects of catecholamines result from -adrenergic receptor

activation: blocking the receptor obviates many of the stress-related immune alterations,

especially those that occur in solid immune tissues, such as the spleen (Benschop et al. 1994;

Cunnick et al. 1990; Rabin 1999; Sanders et al. 2007).

However, in recent years, it has become evident that the immune system effects of both

norepinephrine and epinephrine cannot be adequately subsumed under a single rubric of

immunosuppression. Indeed, as noted above, it has become apparent that catecholamines also

have immune-activating effects, given data that catecholamines can stimulate the production of

proinflammatory cytokines, especially IL-6, both in the periphery and in the CNS and activate

inflammatory signaling cascades (Bierhaus et al. 2003; Johnson et al. 2005; Norris and Benveniste

1993; Papanicolaou et al. 1998). The ability of catecholamines to induce inflammation may be

related in part to a “switch” that occurs whereby protein kinase A activation leads to -adrenergic

receptor phosphorylation, which in turn switches -receptor signaling from Gs to Gi. Gi has been

associated with activation of the ras inflammatory signaling cascade (Daaka et al. 1997). Of note,Print: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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catecholamines also appear to favor the development of Th1 cellular immune responses and

promote the production of the Th1 cytokine IFN- (Kohm and Sanders 2000). Consistent with this,

-adrenergic receptors are found on Th1 CD4 T cells, but not on Th2 cells (Kohm and Sanders 2000).

In addition to immune regulation by the sympathetic branch, the parasympathetic branch of the

ANS has been shown to contribute to the regulation of innate immune responses via an efferent

neural signaling pathway referred to as the cholinergic anti-inflammatory pathway (Tracey 2002).

The existence of this pathway was initially identified in studies showing that stimulation of the

vagus nerve attenuates immune system activation and the physiological signs of septic shock in

response to lipopolysaccharide, a key component of gram-negative bacterial cell walls (Borovikova

et al. 2000). Follow-up studies have determined that vagal release of acetylcholine, which in turn

interacts with the 7 subunit of the nicotinic AChR ( 7 nAChR) on relevant immune cells, is capable

of suppressing production of cytokines, including TNF- , via inhibitory effects on nuclear

translocation of NF- B (Altavilla et al. 2006; Guarini et al. 2003) and activation of Janus kinase

(JAK) 2 signal transducers and activators of transcriptions (STAT) 3 (de Jonge et al. 2005; Pavlov

and Tracey 2005). Subsequent studies have established that cytokine production is inhibited by

efferent vagal pathways in the context of a variety of inflammatory processes, including myocardial

ischemia, hemorrhagic shock, ischemia/reperfusion, and pancreatitis (Altavilla et al. 2006; Guarini

et al. 2003; Mioni et al. 2005; van Westerloo et al. 2006; H. Wang et al. 2004). It also has been

shown that both vagus nerve stimulation and 7nAChR agonists inhibit production of a number of

proinflammatory cytokines, including TNF, IL-1, IL-6, IL-8, and high-mobility group box 1 (HMGB1)

(H. Wang et al. 2004). Of note, a specific nAChR-dependent vagus nerve pathway to the spleen

has been identified that inhibits proinflammatory cytokine production during endotoxemia and

polymicrobial sepsis. Furthermore, both splenectomy and vagotomy interrupt the cholinergic

anti-inflammatory response (Huston et al. 2006). Taken together, these findings suggest that in

addition to effects on cellular signaling, there are anatomical and hard-wired components of the

cholinergic anti-inflammatory pathway.

Hypothalamic-Pituitary-Adrenal Axis

In concert with the ANS, the HPA axis serves as a central component of the mammalian stress

response system. Although glucocorticoids, which represent the final product of HPA axis

activation, have long been viewed as immunosuppressive because of their well-documented ability

to suppress inflammation (largely through protein–protein interactions between the glucocorticoid

receptor and NF B) (Rhen et al. 2005), it is increasingly recognized that HPA axis effects on

immunity are complex (Dhabhar et al. 1995). This complexity arises from the fact that HPA axis

effects on the immune system depend on numerous factors, including the immune compartment

that is assessed, the element of the HPA axis being evaluated (i.e., CRH vs. cortisol), and the

duration and timing relative to the immune response and stressor application. Thus, for example,

glucocorticoids are known to acutely diminish CD4 cell counts in the blood; however, at the same

time, glucocorticoids enhance CD4-mediated DTH reactions in the skin, through their effects on

lymphocyte trafficking (Dhabhar 1998). Moreover, different HPA axis elements demonstrate

divergent immune system effects. For example, the end result of CRH-induced HPA axis activation

is proinflammatory cytokine suppression, and yet studies demonstrate that the direct effect of CRH

on proinflammatory cytokine production may be stimulatory (Labeur et al. 1995; Paez Pereda et al.

1995).

Finally, the effect of glucocorticoids on naturalistic measures of immunity, such as DTH, depends on

both the concentration and the duration of glucocorticoids within the immune compartment under

consideration. Thus, low doses of glucocorticoids applied for brief periods have been shown in

rodents to stimulate DTH, whereas higher (or more protracted) glucocorticoid exposure suppresses

DTH (Dhabhar and McEwen 1999).

CRH applied within the CNS suppresses several measures of immunity, including splenic NKCA,

mitogen-stimulated lymphocyte proliferation, and in vivo and in vitro antibody formation, as well as

T-cell responses to T-cell receptor antibody (Caroleo et al. 1993; Irwin et al. 1988; Labeur et al. Print: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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1995; Rassnick et al. 1994). CRH-overproducing mice demonstrate a profound decrease in the

number of B cells and severely diminished primary and memory antibody responses (Stenzel-Poore

et al. 1994). These immunosuppressive effects appear to be mediated by stress response outflow

pathways activated by CRH, given that blockade of the SNS abolishes CRH effects on NKCA and

adrenalectomy obviates CRH effects on lymphocyte proliferation (Irwin et al. 1988; Labeur et al.

1995). In addition, the B-cell decreases in CRH-overproducing mice are consistent with the marked

reduction in rodent B cells observed after chronic glucocorticoid exposure (Miller et al. 1994).

In contradistinction to its immunosuppressive properties, CRH has also been shown to enhance

proinflammatory cytokine production in animals and humans when administered peripherally or

within the CNS. Chronic intracerebroventricular administration of CRH to rats leads to induction of

IL-1 messenger RNA (mRNA) in splenocytes, and acute intravenous administration in humans has

been reported to cause a fourfold increase in the induction of IL-1 (Labeur et al. 1995; Schulte et

1. 1994). Similarly, the addition of CRH to in vitro mononuclear cell preparations induces the

release of IL-1 and IL-6 (Leu and Singh 1992; Paez Pereda et al. 1995). Both chronic and acute CRH

infusion have also been reported to increase production of the immunoregulatory cytokine IL-2 in

humans and animals (Labeur et al. 1995; Schulte et al. 1994). In addition to potential

proinflammatory activities of CRH within the CNS, peripheral production of CRH has been

demonstrated in inflammatory diseases, such as ulcerative colitis and arthritis, in which it appears

to act as a local proinflammatory agent (Karalis et al. 1997; Nishioka et al. 1996).

Of all neurotransmitters or hormones known to modulate immune functioning, the actions of

glucocorticoids, although complicated, are probably best understood (Raison et al. 2002). Identified

effects of glucocorticoids on the immune (and inflammatory) system include

Modulation of immune cell trafficking throughout the body (Dhabhar et al. 1995)

Modulation of cell death pathways (i.e., apoptosis) (McEwen et al. 1997)

Inhibition of arachidonic acid pathway products (e.g., prostaglandins) that mediate inflammation and

sickness symptoms (e.g., fever) (Goldstein et al. 1992)

Modulation of Th1/Th2 cellular immune response patterns in a manner that inhibits Th1 (cell-mediated)

responses and promotes Th2 (antibody) responses (Elenkov and Chrousos 1999)

Inhibition of T-cell– and NK-cell–mediated cytotoxicity (Raison et al. 2002)

Inhibition of cytokine production and function through interaction of glucocorticoid receptors with

transcription factors (NF- B, in particular), which, in turn, regulate cytokine gene expression and/or the

expression of cytokine-inducible genes (McKay and Cidlowski 1999)

Although, as discussed below, glucocorticoids may actually enhance certain aspects of naturalistic

immune functioning when produced for brief periods at low to moderate doses in the context of

acute and/or mild stress, glucocorticoids, in general, play a primary role in restraining excessive or

prolonged inflammatory activation (Munck 1989). This property has long been exploited by modern

medicine for the treatment of autoimmune and other chronic inflammatory conditions, with the

result that glucocorticoids remain a cornerstone of our anti-inflammatory armamentarium.

Consistent with their pharmacological uses, glucocorticoids have been shown to be essential for

inflammatory regulation in response to immune system activation. For example, neutralization of

endogenous glucocorticoid function results in enhanced pathology and mortality in animals exposed

to lipopolysaccharide, as well as other inflammatory stimulators, such as streptococcal cell wall

antigen or myelin basic protein (Bertini et al. 1988; Sternberg et al. 1989). Similarly, rodents that

have been rendered glucocorticoid deficient by adrenalectomy have markedly increased death rates

following infection with murine cytomegalovirus, an effect that arises from unrestrained activity of

the proinflammatory cytokine TNF- (Ruzek et al. 1999).

BODY TO BRAIN: IMMUNE SYSTEM EFFECTS ON CENTRAL NERVOUS

SYSTEM FUNCTIONING

Immune System to Brain Signaling Pathways

The field of psychoneuroimmunology is based on the existence of bidirectional communication

pathways between the brain and the immune system. This implies that just as the CNS is capable ofPrint: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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modulating immunity, the immune system can alter functioning within the CNS. Although

researchers historically were first interested in pathways by which the brain affects immunity, the

past 10–15 years have seen a groundswell of interest in the ways in which the immune system

contributes to the development of psychopathology.

Underpinning this growing interest is an increasing appreciation for the multiple ways in which

proinflammatory cytokines are able to signal the brain and change CNS function (Table 9–3).

Although the brain was historically considered an “immune privileged” organ, protected from

immune system activity by the blood–brain barrier, it is now clear that cytokines released in the

periphery rapidly affect CNS functioning via at least four pathways that are not mutually exclusive

(Raison et al. 2002). Proinflammatory cytokines injected into the abdominal cavity

(intraperitoneal) have been shown to activate the vagus nerve, resulting in the independent

production of proinflammatory cytokines within the CNS, especially in the hypothalamus and

hippocampus, which are regions of central importance for the regulation of the ANS and emotion

(Maier et al. 1998). Recent studies suggest that in addition to activating the vagus nerve,

proinflammatory cytokines in the blood are able to signal the CNS by entering through “leaky”

regions lacking a fully formed blood–brain barrier, such as the circumventricular organs, and, from

there, to circulate in CSF to other brain regions (Rivest et al. 2000). Bloodborne proinflammatory

cytokines can also communicate with the brain through intermediaries, without themselves

entering the CNS parenchyma, for example, by acting on cells of the brain endothelium or choroid

plexus and inducing the release of secondary messengers, such as prostaglandins and nitric oxide

(Rivest et al. 2000). Finally, active transport across the blood–brain barrier provides another

mechanism by which small quantities of proinflammatory cytokines may gain access to the CNS

(Banks 2006; Banks et al. 1995; Plotkin et al. 1996).

TABLE 9–3. Evidence that cytokines can alter central nervous system function

Cytokines released peripherally have access to the brain.

Passage through leaky regions in the blood–brain barrier (e.g., circumventricular organs)

Active transport

Activation of intermediary cell types (e.g., endothelial cells) that produce relevant second messengers (e.g.,

prostaglandins, nitric oxide)

Transmission of cytokine signals through afferent nerve fibers (e.g., vagus)

A cytokine network exists within the brain.

Glia (especially microglia) and neurons express/produce cytokines and express cytokine receptors

Cytokines have effects on neurotransmitter turnover, neuroendocrine function, synaptic plasticity, and

behavior (sickness behavior).

Once proinflammatory cytokines have gained access to the CNS through any of the routes outlined

above, the inflammatory signal appears to be amplified by a cytokine network within the brain itself

(Quan et al. 1999). It has already been noted that cytokines produced in the periphery stimulate

the production of proinflammatory cytokines, such as IL-1, IL-6, and TNF- , in a number of brain

regions (Dantzer and Kelley 2007; Gatti and Bartfai 1993; Laye et al. 1994; Quan et al. 1999).

Receptors for proinflammatory cytokines are found in the brain, especially in areas that are of

central importance to homeostatic and emotional regulation, such as the hypothalamus and

hippocampus (Benveniste 1998). Among neural cells, activated microglia are capable of producing

significant amounts of proinflammatory cytokines, which, in turn, are potent activators of glial cells

(Schobitz et al. 1994). Of interest, growing evidence suggests that nonimmunological stressors can

induce cytokine expression in the brain, likely due in part to stress-induced activation of microglia

(Frank et al. 2007). These data suggest that CNS cytokine pathways may participate in the

response of an organism to a wide variety of environmental perturbations. Consistent with this

finding, proinflammatory cytokines have been implicated in the modulation of circadian functioning,

especially the sleep–wake cycle (Hohagen et al. 1993; Opp 2005).Print: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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Sickness Behavior and the Development of Depression in the Medically Ill

It has long been known that rates of major depression, as well as milder forms of mood

disturbance, are many times more common in people with medical illnesses than in the general

population (Evans et al. 1999). Although this has been typically ascribed to the overwhelming

psychological stress frequently engendered by being seriously ill, more recent attention has been

paid to the idea that immune system activation, which typically accompanies medical illness, may

itself biologically predispose patients to depression (Raison and Nemeroff 2000). Evidence for this

comes from the observation that rates of depression are significantly elevated in a wide variety of

medical conditions including inflammatory and autoimmune disorders such as multiple sclerosis and

rheumatoid arthritis, as well as illnesses such as cardiovascular disease, diabetes, and cancer,

which are increasingly being recognized as having an important inflammatory component

(Aggarwal et al. 2006; Blake and Ridker 2002; Evans et al. 2005). Moreover, prospective studies of

conditions that are characterized by episodic immune dysregulation, such as multiple sclerosis or

herpes infection, typically find that depression immediately precedes, rather than follows, episodes

of disease exacerbation, suggesting that depressive symptoms associated with these conditions

may result from underlying immune system activity rather than arising from a psychological

reaction to exacerbation of the illness (Foley et al. 1992; Hickie and Lloyd 1995). Finally, as noted

above, numerous groups have shown that when compared with similar patients without a current

mood disorder, plasma concentrations of proinflammatory cytokines are significantly higher in

medically ill patients with major depression versus those without (Raison et al. 2006). For example,

IL-6 is elevated in depressed patients with cancer (Musselman et al. 2001b), and C-reactive protein

is elevated in depressed patients with both acute coronary syndromes and chronic heart failure

(Andrei et al. 2007; Lesperance et al. 2004).

More direct evidence that inflammatory processes may contribute to psychopathology, especially in

the context of medical illness, comes from many studies in humans and animals demonstrating that

the administration of proinflammatory cytokines reliably induces changes in mood, cognition, and

behavior similar to those commonly observed in patients with mood and anxiety disorders, as well

as in psychophysical conditions such as CFS and fibromyalgia (Dantzer and Kelley 2007; Raison et

1. 2006). This constellation of immune-induced changes, alternately referred to as “sickness

syndrome” or “sickness behavior,” consists of dysphoria, anhedonia, fatigue, social withdrawal,

hyperalgesia, and cognitive and sleep disturbances, as well as decreases in appetite and libido

(Kent et al. 1992). Although seen in response to infection, the full syndrome can be reproduced in

animals and humans by administration of innate immune cytokines, such as IFN- , IL-1, TNF- , and

IL-6, as well as IL-2, even in the absence of infection (Raison et al. 2002).

Results from studies utilizing positron emission tomography (PET) and functional magnetic

resonance imaging (fMRI) provide further evidence that peripheral cytokine activity can induce

centrally mediated behavioral changes. These and other imaging modalities provide a means by

which various behavioral alterations can be associated with specific brain regions. For example,

during an fMRI task of visuospatial attention, in comparison with control subjects, patients

administered IFN- exhibited significantly greater activation of the dorsal anterior cingulate cortex

(dACC) that highly correlated with the number of task-related errors (Capuron et al. 2005).

Interestingly, increased dACC activity during cognitive tasks has also been demonstrated in

patients vulnerable to mood disorders, such as those with high trait anxiety, neuroticism, or

obsessive-compulsive disorder (Capuron et al. 2005). IFN- has also been shown to lead to changes

in basal ganglia metabolic activity as measured by PET that resemble those seen in Parkinson’s

disease. These changes also correlate with IFN- –induced fatigue-related symptoms and may be a

function of IFN- effects on dopamine metabolism (Capuron et al. 2007).

Blocking cytokine activity with an IL-1 receptor antagonist, -melanocyte-stimulating hormone, or

IL-10 diminishes or prevents the development of sickness behavior in laboratory animals, even

when such behavior develops as a result of psychological stress (Milligan et al. 1998). Similarly,

etanercept, a novel agent that blocks TNF- activity, has been reported to improve energy and

overall emotional functioning in patients with rheumatoid arthritis, a condition characterized byPrint: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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increased proinflammatory cytokine activity (Mathias et al. 2000). Recently TNF antagonists have

been shown to reduce depressive symptoms in patients with several autoimmune conditions

(Persoons et al. 2005; Tyring et al. 2006). Further evidence that cytokine-induced behavioral

toxicity is related to major depression comes from studies showing that in humans and animals,

antidepressants are able to abolish or attenuate the development of sickness behavior in response

to cytokine administration (Musselman et al. 2001a; Yirmiya et al. 2001).

Pathways by Which Inflammatory Cytokines Produce Neuropsychiatric

Disturbance

In keeping with the observation that antidepressants mitigate emotional and behavioral symptoms

resulting from immune system activation, significant evidence demonstrates that inflammatory

cytokines affect neurotransmitters and neuroendocrine pathways that are regulated by currently

available antidepressants and that have been implicated in the pathophysiology of depression and

other stress-related neuropsychiatric disorders. It is increasingly recognized that these effects on

the CNS and its outflow pathways may provide a physiological basis for the observation that

immune activation frequently produces neuropsychiatric disturbance (Table 9–4).

TABLE 9–4. Potential mechanisms by which cytokines may influence behavior

Activation of corticotropin-releasing hormone pathways

Alteration of monoamine metabolism

Induction of the euthyroid sick syndrome

Disruption of glucocorticoid receptor signaling

Alteration of regional brain activity

Inhibition of relevant growth factors

Effects on Monoamine Neurotransmitters

In laboratory animals, the acute intracerebral administration of IL-1 produces a rapid and

significant increase in norepinephrine and serotonin (5-HT) turnover in several brain regions

(Linthorst et al. 1995a, 1995b). Far less is known about the effect of chronic proinflammatory

cytokine exposure on functioning of monoamine systems in either animals or humans; however,

cytokines, including IFN- , have been shown to diminish 5-HT availability as a result of a

cytokine-mediated enhancement in the activity of indoleamine 2,3-dioxygenase (IDO), an enzyme

that shunts tryptophan metabolism away from 5-HT toward kynurenine and quinolinic acid, which is

known to have neurotoxic properties (Dantzer et al. 2007; Raison et al. 2006). Tryptophan is the

primary precursor of 5-HT, and depletion of tryptophan has been associated with the precipitation

of mood disturbances in vulnerable patients (Moore et al. 2000). Moreover, significant evidence

suggests that serotonergic neurotransmission is decreased in many patients with depression

(Owens and Nemeroff 1998). It has also been shown that proinflammatory cytokines, via p38

mitogen-activated protein kinase (MAPK)–linked pathways, can increase the expression and

function of synaptic reuptake pumps for serotonin (and norepinephrine), potentially further

contributing to reduced synaptic availability of mood-relevant monoamines (Zhu et al. 2005, 2006).

Of interest, the development of major depression in the context of chronic IFN- treatment has

been shown to correlate closely with decreased plasma concentrations of tryptophan, possibly as a

result of increased IDO activity, consistent with the idea that cytokine-induced decrements in 5-HT

availability may contribute to the development of depression (Capuron et al. 2002b). Furthermore,

treatment with paroxetine attenuates the behavioral consequences of IFN- –mediated tryptophan

depletion (Capuron et al. 2003a). In addition to the effects of chronic cytokine exposure on

serotonergic transmission, both IL-2 and IFN- , when they are administered chronically, have been

reported to alter dopamine metabolism, and as noted above, IFN- has been shown to lead to

altered metabolic activity in brain regions high in dopaminergic neurocircuits including the basal

ganglia (Capuron et al. 2007; Lacosta et al. 2000; Shuto et al. 1997).Print: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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Effects on the Thyroid Axis

Medical illness is often associated with a state of functional thyroid deficiency known as euthyroid

sick syndrome (ESS) (Papanicolaou 2000). In its early stages, ESS is characterized by normal

thyroid-stimulating hormone (TSH) and thyroxine (T4) levels, but by reduced levels of

triiodothyronine (T3), which is the more biologically active form of thyroid hormone. In later stages

of ESS, T4 levels are also decreased. Evidence suggests that proinflammatory cytokines promote

this condition via direct effects on the thyroid gland, as well as by inhibition of enzymes responsible

for peripheral conversion of T4 to T3, especially in the liver (Papanicolaou 2000). It is well known

that decreased thyroid functioning is associated with the development of symptoms of depression,

and functional abnormalities of the thyroid axis are observed in many patients with major

depression who do not have clinically obvious thyroid disease (Musselman and Nemeroff 1996).

Effects on the Hypothalamic-Pituitary-Adrenal Axis

Inflammatory cytokines have well-described effects on the HPA axis that are consistent with

changes frequently seen in patients with major depression, including increased production of CRH

and cortisol and decreased tissue sensitivity to glucocorticoid hormones (Capuron et al. 2003a;

Hasler et al. 2004; Pace et al. 2007; Silverman et al. 2005). Although cytokines have been shown to

be capable of activating the HPA axis at multiple levels, with a resultant increase in glucocorticoid

release, significant evidence suggests that a major final common pathway for cytokine activation

involves stimulation of CRH production in the paraventricular nucleus (PVN) of the hypothalamus

(Besedovsky and del Rey 1996). Several lines of evidence suggest that this increase in CRH activity

may contribute to cytokine-induced depression/sickness behavior. CRH has behavioral effects in

animals that are similar to those seen in patients with depression and/or sickness syndrome,

including alterations in appetite, activity, and sleep (Owens and Nemeroff 1991). Patients with

major depression frequently demonstrate increased CRH production, as assessed by increased CRH

in CSF, increased messenger RNA in the PVN, downregulated frontal CRH receptors, and a blunted

adrenocorticotropic hormone (ACTH) response to CRH challenge (likely reflecting downregulation of

pituitary CRH receptors) (Owens and Nemeroff 1993). Agents that block the CRH type I receptor

have been shown to have antidepressant and anxiolytic effects in humans (Zobel et al. 2000). In

animals, blocking CRH reverses some of the behavioral sequelae of proinflammatory cytokine

administration (Dantzer 2001). Indirect evidence for a role of CRH in cytokine-induced depression

in humans comes from a study in which individuals who developed depression during IFN

administration exhibited significantly higher ACTH and cortisol responses to the first injection of

IFN- compared with control subjects (Capuron et al. 2003b). These findings suggest that

sensitized CRH pathways may serve as a vulnerability factor for cytokine-induced behavioral

changes.

In addition to direct stimulatory effects on CRH within the CNS, in vivo and in vitro studies suggest

that inflammation may induce resistance to circulating glucocorticoids in nervous, endocrine, and

immune system tissues (Pariante and Miller 2001; Raison and Miller 2003b). This is of great

potential relevance, given the high rates of relative glucocorticoid resistance in HPA axis tissues (as

assessed in vivo by the DST or the dexamethasone–CRH stimulation test) and the immune system

(as measured in vitro) seen in patients with major depression and in animals and humans exposed

to chronic and/or severe stressors (Holsboer 2000). Supporting a role for cytokines in the induction

of glucocorticoid resistance is the observation that many chronic inflammatory conditions, including

steroid-resistant asthma, rheumatoid arthritis, multiple sclerosis, and HIV infection, are

characterized by a decrease in sensitivity to glucocorticoids (Raison et al. 2002). In HIV infection,

glucocorticoid resistance has been shown to correlate with increased IFN- plasma levels (Norbiato

et al. 1998).

There are several mechanisms by which proinflammatory cytokines can disrupt glucocorticoid

receptor (GR) function and contribute to glucocorticoid resistance. In addition to downregulating

the expression of GR protein, proinflammatory cytokines have been found to increase the

expression of the inert isoform of the GR (Oakley et al. 1996). Exposure of cells thatPrint: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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constitutively express both GR- (the active isoform) and GR- to either TNF- or IL-1 in vitro

results in a marked increase in GR- production, which is associated with the development of

glucocorticoid resistance, as evidenced by a significant reduction in dexamethasone-stimulated

activity of a GR-sensitive reporter gene in cytokine-treated cells (Webster et al. 2001). That

overproduction of the negative GR- isoform has a clinically relevant effect on glucocorticoid

sensitivity is suggested by several recent studies documenting that patients with a variety of

inflammatory and immune system disorders, including asthma, ulcerative colitis, and chronic

lymphocytic leukemia, whose conditions are resistant to steroid treatment demonstrate a

significantly increased GR- to GR- ratio (Honda et al. 2000; Leung 1997; Shahidi et al. 1999;

Sousa et al. 2000).

Another mechanism by which inflammatory cytokines may attenuate GR signal transduction and,

hence, cause glucocorticoid resistance is through induction of inflammatory signaling pathways that

directly influence GR function (Pace et al. 2007). For example, adding IL 1 to an in vitro

preparation of mouse fibroblast cells has been shown to suppress the ability of dexamethasone to

induce translocation of the GR from the cytoplasm to its site of action in the nucleus (Pariante et al.

1999). This IL-1 –mediated blockade of GR translocation from the cytoplasm to the cellular nucleus

inhibits GR activity, as indicated by a decrease in the ability of dexamethasone to activate a

glucocorticoid-sensitive reporter gene construct. The signaling pathways involved in this effect

include p38 MAPK, which has been shown to phosphorylate the GR (X. Wang et al. 2004). Other

inflammatory signaling pathways have also been shown to alter GR function, including NF- B, Jun

N-terminal kinase (JNK), and STAT5 (Pace et al. 2007).

PSYCHOPHARMACOLOGICAL IMPLICATIONS OF BRAIN–IMMUNE SYSTEM

INTERACTIONS

Antidepressants and Immune System Activation

The term antidepressant has been depicted, more than once, as a misnomer, given the wide

spectrum of activity evinced by these pharmacological agents. Adding to this activity spectrum are

findings that antidepressants have clear immunomodulatory effects in animals and humans. In

general, antidepressants have been found to decrease immune responsiveness (Kenis and Maes

2002). Because of this, these agents may be of benefit for a wide range of symptoms that arise in

the context of immune activation. Of special interest, given the ability of inflammatory cytokines to

induce sickness behavior and/or major depression, a number of antidepressants have been

reported to attenuate proinflammatory cytokine production, not just from peripheral immune cells

(Maes 1999) but also from within the CNS, where desipramine has been reported to diminish TNF

release within the locus coeruleus (Ignatowski and Spengler 1994). Interestingly in this regard, the

antidepressant efficacy of desipramine during the forced-swim test has been shown to be

dependent on reductions in neuronal production of TNF- and can be reversed by exogenous TNF

coadministered with the antidepressant (Reynolds et al. 2004). Desipramine has also been shown

to lower peripheral TNF- production in response to lipopolysaccharide (LPS) administration—an

effect that was associated with abrogation of the depressive-like behavioral effects of LPS (Shen et

1. 1999). The heterocyclic antidepressant bupropion has been similarly noted to markedly diminish

TNF- production following LPS administration in animals (Brustolim et al. 2006). Of note,

concomitant with attenuating proinflammatory cytokine production, antidepressants enhance

production of the anti-inflammatory cytokine IL-10 (Maes et al. 1999d).

In addition to potential direct effects on cytokine production, antidepressants impact

neuroendocrine and neurotransmitter systems in ways known to diminish inflammatory activity. For

example, all antidepressants appear to downregulate the overproduction of CRH and cortisol that

frequently occurs in the context of major depression. Much evidence suggests that this

downregulation results from the ability of antidepressants to enhance glucocorticoid signaling via

increased glucocorticoid receptor functioning, which, in turn, leads to a restoration of

glucocorticoid-mediated inhibitory control on the HPA axis (Pariante and Miller 2001). Because CRH

has been shown to directly stimulate proinflammatory cytokine production, antidepressants may

modulate inflammatory activity in part by diminishing CRH production. Glucocorticoid receptors, inPrint: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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addition to inhibiting CRH release in the hypothalamus, also mediate the well-characterized

anti-inflammatory properties of glucocorticoids. It is likely that antidepressants decrease

inflammatory activity in part via their ability to potentiate glucocorticoid receptor functioning

(Pariante and Miller 2001). Antidepressants also normalize the hyperactivity of the locus coeruleus

and SNS frequently seen in major depression (Ressler and Nemeroff 1999). Because

catecholamines have been shown to enhance proinflammatory activity, the ability of

antidepressants to normalize catecholaminergic functioning would be expected to diminish

inflammatory activity. Finally, antidepressants are known to enhance functioning in intracellular

second-messenger systems (such as the cyclic adenosine monophosphate [cAMP] cascade) known

to suppress the activation of genes that encode for the production of proinflammatory cytokines

(Duman et al. 2001).

Whatever the mechanism, it is clear from studies in animals and humans that antidepressants

effectively diminish many physical, emotional, cognitive, and behavioral symptoms that arise in the

context of immune system activation (Capuron et al. 2002a). In animals, pretreatment with a

number of antidepressants has been shown to prevent or diminish the development of sickness

syndrome in response to either pathogen or cytokine exposure (Yirmiya et al. 2001). In humans,

pretreatment with an antidepressant has been shown in a double-blind, placebo-controlled trial to

significantly reduce the development of major depression in patients receiving high doses of the

proinflammatory cytokine IFN- for the treatment of malignant melanoma (Musselman et al.

2001a). In this study, 45% of patients receiving placebo had developed major depression within 3

months of starting IFN- , compared with only 11% receiving the selective serotonin reuptake

inhibitor paroxetine. Of interest, however, paroxetine was not equally efficacious for all the

symptoms associated with sickness syndrome. Specifically, the antidepressant significantly reduced

the symptoms of depressed mood, anxiety, and poor cognitive functioning but was no more

effective than placebo in the treatment of somatic or neurovegetative symptoms, such as fatigue

and anorexia, suggesting that these symptom domains may have nonoverlapping etiologies

(Capuron et al. 2002a). Consistent with this finding, neurovegetative symptoms tended to develop

early (and to persist) in the course of IFN- treatment in a majority of patients, whereas symptoms

of depressed mood, anxiety, and cognitive disturbance tended to develop insidiously over weeks or

months of treatment in a smaller percentage of patients (Trask et al. 2000). The success of

pretreatment strategies in preventing the development of neuropsychiatric disorders in medically ill

patients at high risk for mood disorders is intriguing and suggests that prophylactic antidepressants

may be considered in other medical contexts, such as for patients about to undergo treatment with

radiation and/or chemotherapy, as well as for patients about to undergo major surgery.

There are also data to suggest that antipsychotics, although not as well studied as antidepressants,

may have immunological effects relevant to their mechanism of action. Intriguing in this regard is a

study demonstrating increased antipsychotic efficacy in patients with schizophrenia treated with

the combination of the cyclo-oxygenase-2 inhibitor celecoxib, an anti-inflammatory drug, and

risperidone versus risperidone plus placebo (Müller et al. 2002).

Immune System Interventions for Behavioral Symptoms

Given that proinflammatory cytokines induce depressive syndromes, and given that many medically

healthy patients with depression appear to demonstrate increased inflammatory activity, it is

logical to inquire as to whether agents that directly target inflammatory mediators, such as

anti-inflammatory agents and drugs that disrupt cytokines and their cytokine signaling pathways

(e.g., NF- B, p38 MAPK), might be of benefit in the treatment of both stress- and immune-related

neurobehavioral disorders. Indeed, in a recent double-blind, randomized, placebo-controlled study,

patients with major depressive disorder who took celecoxib as an adjunct to reboxetine

experienced a significantly greater therapeutic benefit than those taking reboxetine alone (Müller

et al. 2006). In animal models, endogenous inhibitors of proinflammatory cytokines, such as the

soluble receptor antagonist for IL-1 (sIL-1ra), have been reported to attenuate or abolish sickness

symptoms following endotoxin or cytokine administration (Maier and Watkins 1998). Of interest, in

addition to direct anti-inflammatory activities, sIL-1ra also blocks many of the sequelae ofPrint: Chapter 9. Brain-Immune System Interactions: Relevance to the … http://www.psychiatryonline.com/popup.aspx?aID=417362&print=yes…

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psychological stress in rodents. For example, direct injection of sIL-1ra blunts HPA axis responses

to psychological stressors, such as restraint, and prevents stress from causing learned helplessness

(a frequent animal model for depression) (Maier and Watkins 1998). Administration of IL-ra has

also been shown to reverse the inhibitory effects of stress on the expression of brain-derived

neurotrophic factor in the dentate gyrus of the rat hippocampus (Barrientos et al. 2003). Of note,

mice whose TNF- receptor genes have been knocked out exhibit an antidepressant phenotype and

are resistant to anxiety-conditioning paradigms and virus-induced anxiety behaviors (Silverman et

1. 2004, 2007; Simen et al. 2006). Of further relevance to the behavioral effects of targeting

cytokines such as TNF- are data demonstrating improvements in behavioral symptoms in patients

with inflammatory and autoimmune disorders who are receiving therapies that block TNF- activity

(e.g., etanercept, infliximab). For example, significant improvement in emotional well-being has

been observed in patients treated with these agents for psoriasis, rheumatoid arthritis, and

ankylosing spondylitis (Braun et al. 2007; Katugampola et al. 2007; Mathias et al. 2000). Most

relevant, however, was a recent double-blind, placebo-controlled trial of etanercept for the

treatment of psoriasis, in which patients who received active drug exhibited significantly greater

improvement in depressive symptoms compared with placebo-treated patients, independent of the

effect of the drug on disease activity (Tyring et al. 2006). Although the risk of side effects with

cytokine antagonists is relatively low, when adverse events do occur, they can be serious, including

life-threatening infections, reactivation of tuberculosis, congestive heart failure, lymphoma,

induction of autoantibodies, and a lupus-like reaction.

Treatment of chronic pain, with or without the presence of mood symptoms, is another burgeoning

area of translational drug discovery. Data from animal models suggest that proinflammatory

cytokines, specifically IL-1 and TNF, play a pivotal role in the creation and maintenance of

neuropathic pain (Marchand et al. 2005; Moalem and Tracey 2006). These findings led to the

hypothesis that IL-10, an anti-inflammatory cytokine, may prove to be a promising therapeutic

option via attenuation of IL-1 and TNF activity. Indeed, it has been shown in animal studies that

IL-10, via intrathecal IL-10 gene therapy, is effective in the control of both acute and chronic pain

(Ledeboer et al. 2007; Milligan et al. 2006).

It has been suggested that the increased prevalence of major depression observed in the Western

world over the past half-century may be caused, at least in part, by a decrease in the consumption

of omega-3 fatty acids (Maes et al. 1999a), which are well known to have anti-inflammatory effects

via the inhibition of prostaglandins and proinflammatory cytokines. Consistent with this,

populations that consume diets high in omega-3 fatty acids (found especially in fish) appear to

have diminished rates of major depression (Tanskanen et al. 2001). Conversely, patients with

major depression have been reported to have decreased serum concentrations of omega-3 fatty

acids (Maes et al. 1999a; Tiemeier et al. 2003). These observations suggest that the administration

of omega-3 fatty acids might be beneficial to patients with mood disorders. Preliminary studies

have indeed shown that adjunctive administration of omega-3 fatty acids under double-blind,

placebo-controlled conditions significantly improves persistent mood symptoms in patients with

depression (Peet and Horrobin 2002) and decreases disease relapse in patients with bipolar

disorder (Stoll et al. 1999). Low omega-3 fatty acid levels may also contribute to the increased

rates of depression in the medically ill, in particular in patients with cardiovascular disease. In a

study evaluating patients 2 months after an acute coronary event (myocardial infarction or unstable

angina), patients with comorbid major depression had significantly lower levels of omega-3 fatty

acids (Frasure-Smith et al. 2004) than their nondepressed counterparts. Given that low omega-3

fatty acid levels are associated with mood disorders (Parker et al. 2006), in addition to increased

levels of inflammation (Simopoulos 2002), an increased risk for coronary artery disease

(Kris-Etherton et al. 2003), and fatal arrhythmias (Leaf et al. 2003), further studies evaluating the

effects of omega-3 supplements in at-risk populations are warranted.

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