Apomorphine-Susceptible and Apomorphine-Unsusceptible Wistar Rats Differ in Their Susceptibility to Inflammatory and Infectious Diseases: A Study on Rats with Group-Specific Differences in Structure and Reactivity of Hypothalamic-Pituitary-Adrenal Axis

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Volume 17, Number 7, Issue of April 1, 1997 pp. 2580-2584
Copyright ©1997 Society for Neuroscience

Apomorphine-Susceptible and Apomorphine-Unsusceptible Wistar Rats Differ in Their Susceptibility to Inflammatory and Infectious Diseases: A Study on Rats with Group-Specific Differences in Structure and Reactivity of Hypothalamic-Pituitary-Adrenal Axis

Annemieke Kavelaars¹, Cobi J. Heijnen¹, Bart Ellenbroek², Henk van Loveren³, and Alexander Cools²
¹ Department of Immunology, University Hospital for Children and Youth "Het Wilhelmina Kinderziekenhuis," 3501 CA Utrecht, The Netherlands, ² Department of Psychoneuropharmacology, University of Nijmegen, 6500 HB Nijmegen, The Netherlands, and ³ Department of Immunobiology and Haematology, Laboratory for Pathology and Immunobiology, RIVM, 3720 BA Bilthoven, The Netherlands

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Variability in susceptibility to diseases is a well known phenomenon that has been attributed to genetic and environmentalfactors. At the level of the immune system, the reactivity oftwo types of T helper cells (Th1 and Th2 cells) plays an importantrole in determining disease susceptibility. Inflammatory (autoimmune)diseases are stimulated by cytokines produced by Th1 cells. Th2cytokines stimulate antibody production (e.g., IgE) and eosinophiliaas observed in allergic reactions or during parasitic infections.We describe here that the reactivity in a Th1 or a Th2 diseasemodel significantly differs between individual rats that showgroup-specific differences in reactivity of the hypothalamic-pituitary-adrenal(HPA) axis, as well as in their behavioral responses to stress.
We used two outbred lines of Wistar rats, apomorphine-susceptible rats that have a relatively hyperreactive HPA axis (APO-SUS)and apomorphine-unsusceptible rats that have a relatively hyporeactiveHPA axis (APO-UNSUS). APO-SUS, but not APO-UNSUS, rats generateda vigorous, Th2-dependent IgE response after infection with thenematode Trichinella spiralis. In contrast, APO-UNSUS, but notAPO-SUS, rats were susceptible for Th1-mediated experimental autoimmuneencephalomyelitis. Investigation of cytokine responses of splenocytesrevealed that the ratio of mRNA expression for Th1-derived interferon(IFN)- $gamma$ and mRNA expression of Th2-derived interleukin-4 (IL-4)was significantly smaller in APO-SUS than in APO-UNSUS rats.
In conclusion, individual differences in structure and reactivity of the neuroendocrine system co-occur with group-specificdifferences in susceptibility to inflammatory and infectious diseases.
Key words: experimental autoimmune encephalomyelitis; T cells; hypothalamus-pituitary-adrenal axis; rats; Trichinella spiralis; interferon- $gamma$ ; interleukin-4

INTRODUCTION

Individual differences in susceptibility to inflammatory and infectious diseases are thought to be determined by the interplaybetween genetic and environmental factors. The immune system playsa major role in the pathogenesis of inflammatory and infectiousdiseases. The neuroendocrine system and the immune system interact(Heijnen et al., 1990; Munck and Guyre, 1990; Madden et al., 1995).Thus, it is conceivable that the reactivity of the neuroendocrinesystem contributes to disease susceptibility.

We focused on two types of rats that are present in each unselected, outbred population of Wistar rats, namely "high respondersto novelty" and "low responders to novelty" (Piazza et al., 1989,1990a,b; Cools et al., 1990, 1993). Since 1985, Cools et al. havebeen able to breed these two types of individuals. They have shownthat the bimodal variation in apomorphine susceptibility, theoriginal selection criterion for the breeding, is consistentlycoupled to a bimodal variation in a great variety of neuroanatomical,neurochemical, endocrinological, and behavioral features. Ratsmarked by a high apomorphine susceptibility (APO-SUS) are highresponders to novelty in terms of behavioral response (high exploratoryactivity) and endocrinological responses (high and long-lastingplasma release of ACTH and corticosteroids). Rats marked by lowapomorphine susceptibility (APO-UNSUS) are low responders to noveltyin terms of behavioral response (low exploratory activity) andendocrinological responses (low and short-lasting release of ACTHand corticosteroids; Cools et al., 1990; Rots et al., 1995, 1996a,b).

At the level of the immune system, it is thought that two types of T helper cells play an important role in determining susceptibilityto disease. Th1 cells predominantly produce $gamma$ -interferon (IFN- $gamma$ )and interleukin-2 (IL-2), which promote cellular immunity (Mosmannand Sad, 1996). In experimental models of autoimmune diseasessuch as experimental autoimmune encephalomyelitis (EAE), the Th1type effector cell response is dominant (Mosmann and Sad, 1996).Th2 cells secrete IL-4, IL-5, and IL-10, which provides help forB cell differentiation and humoral immune responses (Mosmann andSad, 1996). The immune response to infection with parasitic helminthssuch as T. spiralis involve elevated IgE antibody production,eosinophilia, and mastocytosis (Finkelman et al., 1991). Theseresponses are all stimulated by Th2-derived cytokines (Finkelmanet al., 1991; Mosmann and Sad, 1996). Alterations of the cytokinepattern in vivo can reverse host resistance or susceptibilityto disease (Liblau et al., 1995). The production of Th1 and Th2cytokines can, at least in vitro, be modulated by neuroendocrinemediators (Daynes and Araneo, 1989; Daynes et al., 1990; Rooket al., 1994). It is not known, however, whether the neuroendocrinesystem in vivo contributes to the Th1/Th2 balance and to diseasesusceptibility. However, studies in inbred rats have presentedevidence that the neuroendocrine system can contribute to susceptibilityto inflammatory autoimmune disease (Macphee et al., 1989; Sternberget al., 1989a,b). Rats with a blunted reactivity of the HPA axislike Lewis rats are susceptible to EAE and arthritis, whereasFischer F344 rats are resistant in models of autoimmunity (Macpheeet al., 1989; Sternberg et al., 1989a). Moreover, we have evidencethat APO-SUS and APO-UNSUS animals differ in EAE susceptibility(Cools et al., 1993).

The aim of the present study was to establish whether the reactivity of the neuroendocrine system of APO-SUS and APO-UNSUSrats is coupled to a group-specific reactivity in two fundamentallydifferent disease models, namely the EAE model for Th1-dependent,autoimmune diseases and the IgE response to infection with thenematode T. spiralis for Th2-dependent, infectious diseases.

MATERIALS AND METHODS
Animals. Male Wistar rats of the APO-SUS and APO-UNSUS lines bred and reared in the Central Animal Laboratory of the Universityof Nijmegen were used. The selection procedure has been describedin detail by Cools et al. (1990). In short, a group of 60 maleand 60 female rats of an outbred Wistar population was given s.c.injections of 1.5 mg/kg apomorphine, which induces a stereoptypicgnawing behavior. The gnawing score was determined in a modified"Ungerstedt-box," allowing a quantitative analysis of the computerizedand automated recordings of gnawing per 45 min (Cools et al.,1990). Breeding of the APO-UNSUS line was started with nine pairsof rats with a gnawing score of <10 per 45 min (27% of the originalpopulation). Breeding of the APO-SUS rats was started with ninepairs of rats with a gnawing score of >500 per 45 min (23% ofthe original population). Throughout the breeding procedure, retentionof the genetic feature was tested continuously in rats of thefirst litter of each generation. After weaning at the age of 30d, males and females were separated and grouped together (2-4rats per cage per sex per selection line). At the age of 60 d,rats were given injections of the dopaminergic agonist apomorphine(1.5 mg/kg, s.c.) and the gnawing was tested. Male rats of thesecond and third litter of APO-SUS rats (gnawing scores in firstlitter > 500 per 45 min) and of APO-UNSUS rats (gnawing scoresin first litter < 10 per 45 min) were used for the experiments.The experimental animals belonged to the 13th to 18th generations,were housed and grouped together (2-6) in macrolon cages (40 ×25 cm), and were maintained on a 12 hr light/dark cycle. Standardlab chow and water were available ad libitum. Animals tested forEAE and T. spiralis belonged to the same generation, and experimentswere performed in parallel. All experiments were performed inaccordance with international and institutional guidelines foranimal care.

EAE. Seven APO-SUS and seven APO-UNSUS rats of 250-350 gm were inoculated subcutaneously in the hind paw with 100 µl of inoculateunder brief halothane anesthesia. The inoculate consisted of 1500µg of myelin basic protein (MBP) in 1 ml saline mixed with 1 mlcomplete Freund's adjuvant (CFA) (Difco, Detroit, MI), to which10 mg Mycobacterium tuberculosis H37Ra was added. Rats were examineddaily to score the development of clinical signs of EAE. Clinicalsigns were scored on a scale from 0-5: 0, no clinical signs; 1,partial paralysis of the tail; 2, paralyzed tail; 3, paresis ofthe hindlimbs; 4, complete paralysis of the hindlimbs or completelower part of the body; 5, death as a result of EAE.

Trichinella spiralis infection. T. spiralis L1 larvae were prepared from source rats as described (Schlumpf et al., 1994).Nine APO-SUS and seven APO-UNSUS rats were infected per os with1000 L1 larvae. Six weeks after infection, rats were sacrificedand serum was collected. Serum levels of IgG, IgA, and IgE antibodiesspecific for T. spiralis were determined as described previously(Schlumpf et al., 1994).

In vitro cytokine production. To test the capacity of splenocytes to produce the Th1 cytokine IFN- $gamma$ after mitogenic stimulation,splenocytes (10⁶/ml) of APO-SUS and APO-UNSUS rats were cultured in RPMI-1640(Life Technologies, Grand Island, NY) supplemented with antibioticsand 5% heat-inactivated FCS (Gibco) with the polyclonal activatorPMA (10 ng/ml) plus ionomycine (400 ng/ml) for 20 hr. Supernatantswere harvested, and the concentration of IFN- $gamma$ was determinedby ELISA (Van der Meide et al., 1990).

Because quantitative tests for measurement of serum level of IL-4 are not yet available, the expression of IL-4 mRNA as wellas of IFN- $gamma$ mRNA was determined by quantitative RT-PCR to gaininsight into the relative contribution of Th1 or Th2 type responsesin APO-SUS and APO-UNSUS rats. At the time point when the above-mentionedsupernatants were collected, cells were harvested and RNA wasextracted by the use of RNAzol B (Campro Scientific, Veenendaal,The Netherlands). Two micrograms of RNA were reverse transcribedinto cDNA using AMV reverse transcriptase and oligo-dT 12-18 oligonucleotideas primer according to the manufacturer's protocol. Quantitativecompetition PCR was performed as described by Siegling et al.(1994), who kindly provided us with a competitor plasmid containingprimers for $beta$ -actin, IFN- $gamma$ , and IL-4. Serial dilutions of competitorfragment were coamplified with fixed amounts of cDNA. The PCRproduct for the sample cDNA and the competitor differ in sizeso that the relative intensities of the two products can be compared.For calculations, 1 unit of cDNA signal was defined as the amountthat resulted in equal density of competitor and target cDNA at1 µl of 1:50 dilution of the competitor. The following primerpairs were used: $beta$ -actin sense, 5 $'$ -CTATCGGCAATGAGCGGTTC; antisense,5 $'$ -CTTAGGAGTTGGGGGTGGCT; IFN- $gamma$ sense, 5 $'$ -CCTCTCTGGCTGTTACTGC;antisense, 5 $'$ -CTCCTTTTCCGCTTCCTTAG; IL-4 sense, 5 $'$ -ATGCACCGAGATGTTTGTACC,antisense, 5 $'$ -TTTCAGTGTTCT GAGCGTGGA. These primer pairs gaverise to PCR products for $beta$ -actin of 762 bp for sample cDNA and601 bp for competitor fragment. IFN- $gamma$ sample cDNA yields a fragmentof 419 bp, whereas the competitor results in a fragment of 319bp. For IL-4, sample cDNA results in 275 bp and competitor cDNAin 178 bp. cDNA was amplified in a 20 µl reaction volume containing2 µl of 10× PCR buffer, 0.25 mM each dNTP, 50 ng/ml of the appropriateprimer pair, 2 mM MgCl₂, and serial dilutions of competitor fragment.After 5 min denaturation at 94°C, cDNA samples were subjectedto cycles of denaturation (15 sec at 94°C), annealing (15 secat 60°C), and extension (15 sec at 72°C) using the thermal cycler9600 (Perkin-Elmer). To correct for variations across differentpreparations, cDNA samples were adjusted to equal input cDNA concentrationsbased on their $beta$ -actin content before determination of cytokinecDNA content. Control PCRs without cDNA were performed in allexperiments to exclude contamination.

Data analysis. Data were analyzed by Mann-Whitney U test or Fisher's exact test, and p < 0.05 was considered statisticallysignificant.

RESULTS

Susceptibility to experimental autoimmune encephalomyelitis
APO-SUS and APO-UNSUS rats showed a clear difference in susceptibility to EAE (Fig. 1 and Table 1). APO-SUS rats were lesssusceptible for EAE. The incidence of disease and the mean cumulativeclinical score were lower in APO-SUS animals than in APO-UNSUSanimals. In addition, there was a significant difference in thekinetics of disease development. APO-SUS animals showed a significantdelay with respect to onset of the disease when compared withAPO-UNSUS rats. The first symptoms of disease were observed onlyat day 12 after inoculation in APO-SUS rats. In contrast, APO-UNSUSrats showed the first symptoms of the disease at day 8 after inoculation,the degree of paralysis increased reaching maximal levels at day11 after inoculation in these animals; subsequently, disease activitygradually decreased, and complete remission was observed after18 d. There was no group-specific difference in duration of thedisease.
Fig. 1. Expression of EAE in APO-SUS and APO-UNSUS rats. Male APO-SUS (n = 7) and APO-UNSUS (n = 7) rats were inoculated with MBPin CFA on day 0. Clinical signs of the disease were scored dailyon a scale from 1 to 5 as described in Materials and Methods.For statistical analysis of the data, see Table 1.
[View Larger Version of this Image (18K GIF file)]

Table 1. Susceptibility to EAE of APO-SUS and APO-UNSUS rats

APO-SUS APO-UNSUS p

Incidence^a 3/7 7/7 0.04^b

Mean day of onset^c 14.7 (1.5) 9.9 (0.5) 0.017^d

range 12-17 8-11

median 15 10

Duration^e 4.3 (2.5) 6 (2.6) ns^d

range 2-7 3-9

median 4 7

Mean cumulative score^f 1.9 (1) 9.2 (2.9) 0.018^d

range 0-7 3-22

median 0 7

Animals were inoculated with MBP in CFA, and the clinical expression of the disease was determined as described in the legendto Figure 1. ^a Number of animals with disease/number tested; disease was defined as clinical score $>=$ 1. ^b Fisher's exact test. ^c Average day of disease onset of those animals that developed disease (SEM). ^d Mann-Whitney two sample test. ^e Average duration of the disease in days in those animals that developed disease (SEM). ^f Value represents the mean of the maximum EAE score for each group.

Response to inoculation with Trichinella spiralis
APO-SUS rats developed a higher level of anti-T. spiralis IgE than APO-UNSUS rats (Fig. 2). In eight of nine APO-SUS animals,T. spiralis-specific antibodies of the IgE subclass could be detected,whereas only two of seven APO-UNSUS rats developed detectablelevels of parasite-specific IgE.
Fig. 2. Specific anti-T. spiralis IgE titers in APO-SUS and APO-UNSUS rats. Seven APO-SUS rats and nine APO-UNSUS rats were infectedwith T. spiralis and killed 6 weeks after infection. Serum wascollected and levels of specific anti-T. spiralis antibodies weredetermined by ELISA. Specific IgE antibodies could be detectedin 6 of 7 APO-SUS rats and in 2 of 9 APO-UNSUS rats (Fisher'sexact test, p = 0.04).
[View Larger Version of this Image (12K GIF file)]

There were no group-specific differences in the levels of IgG or IgA specific for T. spiralis (Table 2).

Table 2. Anti-T. spiralis antibody titers in serum

APO-SUS
APO-UNSUS

Detectable^a Titer^b Detectable Titer

IgA 4 /7 80.8 ± 10.7 4 /9 54 ± 25

IgG 7 /7 10.7 ± 3.5 9 /9 7.7 ± 2.7

IgE 6 /7 18.2 ± 7.4 2 /9^* 7.3 ± 5.7

Rats were infected with T. spiralis and killed 6 weeks after infection. Serum was collected, and levels of specific anti-T.spiralis antibodies were determined by ELISA. ^a Number of animals with detectable level of antibodies/number of animals tested. ^b Mean concentration of antibody ± SEM in those animals with detectable antibodies expressed as percentage of a reference serum. ^* Fisher's exact test: p = 0.04.

Production and/or mRNA expression of Th1 and Th2 type cytokines
The splenocytes of APO-SUS and APO-UNSUS rats did not show group-specific differences in the capacity to produce IFN- $gamma$ aftermitogenic stimulation (Table 3). Moreover, neither the expressionof IFN- $gamma$ mRNA nor that of IL-4 mRNA differed between both lines,although the expression of IL-4 was slightly, but not significantly,greater in APO-SUS rats than in APO-UNSUS rats (p = 0.06; Table4). However, the relative contribution of Th1 cells versus Th2cells, as expressed in terms of the ratio IFN mRNA/IL-4, was significantlygreater in APO-UNSUS rats than in APO-SUS rats (p = 0.03; Table4).

Table 3. Production of IFN- $gamma$ (ng/ml) by splenocytes from APO-SUS and APO-UNSUS rats

APO-SUS (n = 6) APO-UNSUS (n = 6)

Mean (SEM) 10.2 (2.2) 6.6 (0.6)

Range 4.5-19.7 5.1-9.3

Median 9.6 6.2

Splenocytes from naive APO-SUS and APO-UNSUS rats were cultured for 20 hr in the presence of PMA and ionomycine. The levelof IFN- $gamma$ in the culture supernatant was determined by ELISA. Mann-Whitney two sample test: p = 0.31.

Table 4. Expression of mRNA for IL-4 and IFN- $gamma$ after polyclonal activation of splenocytes from APO-SUS and APO-UNSUS rats

APO-SUS (n = 6) APO-UNSUS (n = 6) p^a

IL-4^b 0.5 (0.14)^c 0.14 (0.04) 0.06

IFN- $gamma$ 1.7 (0.2) 1.17 (0.17) NS^d

Ratio IFN- $gamma$ :IL-4 3.5 (0.5) 6.4 (0.75) 0.03

Splenocytes from naive APO-SUS and APO-UNSUS rats were cultured for 20 hr in the presence of PMA and ionomycine. Cells wereharvested and RNA was extracted. The level of expression of mRNAfor IL-4 and IFN- $gamma$ was determined by quantitative competitionRT-PCR. ^a Mann-Whitney two sample test. ^b The level of IL-4 and IFN- $gamma$ cDNA is expressed in units as defined in Materials and Methods. ^c Data represent mean and (SEM). ^d NS, not significant.

DISCUSSION
The present study confirms and expands our previous findings that the susceptibility to EAE was significantly smaller in APO-SUSrats than in APO-UNSUS rats; when compared with APO-UNSUS rats,the severity of clinical symptoms of EAE was significantly lessand the onset was significantly delayed (see Fig. 1 and Table1 in Cools et al., 1993). In contrast, APO-SUS rats have a significantlylarger response to infection with the nematode T. spiralis thanAPO-UNSUS rats: the level of parasite-specific IgE was significantlyhigher in APO-SUS rats than in APO-UNSUS rats, although the levelsof parasite-specific levels of IgA and IgG did not differ betweenboth lines in this model for Th2-dependent infectious diseases(Table 2, Fig. 2). In line with these data, the present studyshows that the relative contribution of Th1 and Th2 type responsessignificantly differed between both lines; as shown in Table 4,the ratio of the mRNA expression for the Th1 cytokine IFN- $gamma$ andfor the Th2 cytokine IL-4 in splenocytes was much smaller in APO-SUSrats than in APO-UNSUS rats. These data together show that APO-SUSand APO-UNSUS rats show group-specific differences in their susceptibilityto inflammatory and infectious diseases, respectively.

Given the features of APO-SUS and APO-UNSUS rats mentioned in the introductory remarks, it can be concluded that the structureand reactivity of the neuroendocrine system of APO-SUS and APO-UNSUSrats is consistently coupled to a group-specific reactivity ofthe immune system in two fundamentally different disease models,namely the EAE model for a Th1-dependent autoimmune disease andthe immune response to infection with the nematode T. spiralisfor a Th2-dependent infectious disease.

The question arises whether the group-specific differences in the structure and reactivity of the HPA axis actually directthe group-specific differences in the balance between the responsesof Th1 and Th2 cells. As mentioned in the introductory remarks,APO-SUS rats have higher plasma levels of ACTH at rest and inresponse to a stressor (Rots et al., 1996b). Moreover, stress-inducedincreases in corticosteroids are higher and last longer in APO-SUSanimals (Rots et al., 1996b). Glucocorticoids are known to becapable of favouring a Th2 type of response. In vitro administrationof glucocorticoids to cultures of murine T cells selectively inhibitsthe response of Th1 cells (Daynes and Araneo, 1989; Daynes etal., 1990). In addition, in the presence of glucocorticoids, thedifferentiation and/or activation of Th2 cells is favored (Daynesand Araneo, 1989; Daynes et al., 1990). Furthermore, stress-inducedincreases in glucocorticoids can stimulate production of the Th2cytokine IL-4 (Moynihan et al., 1994). Glucocorticoids not onlyfavor the production of Th2 cytokines over Th1 cytokines but arealso capable of enhancing the secretion of IgE by B cells in thepresence of IL-4 (Nusslein et al., 1994). These data, togetherwith the group-specific differences in susceptibility to Th1-and Th2-dependent immune diseases, give rise to the hypothesisthat the group-specific differences in the structure and, especially,reactivity of the HPA axis direct the balance between the responsesof Th1 and Th2 cells in APO-SUS and APO-UNSUS rats.

The role of HPA axis reactivity in the inflammatory process in the disease EAE has been suggested in other animal models aswell. In the inbred strain of Lewis rats, which are highly susceptibleto EAE, it has been shown that the responsiveness of the HPA axisis impaired (Sternberg et al., 1989a,b). The impaired functioningof the HPA axis in Lewis rats has been ascribed to a defect inthe hypothalamic secretion of CRH (Sternberg et al., 1989b). Inthis respect it is of interest that APO-UNSUS animals expresslower levels of CRH mRNA in the paraventricular nucleus of thehypothalamus than APO-SUS animals (Rots et al., 1995). Administrationof glucocorticoids to inflammatory autoimmune disease-sensitiveLewis rats renders them into resistant animals (Sternberg et al.,1989a,b). On the other hand, resistant Fischer F344 rats can berendered into highly susceptible animals by administration ofthe glucocorticoid receptor antagonist RU 486 (Sternberg et al.,1989a,b). In the mouse model, two inbred strains have been describedthat differ in the dominance of responses of Th1 or Th2 cellsas well as in the reactivity of the neuroendocrine system. BALB/cmice respond predominantly with a Th2 type response, whereas C57/bl6mice respond with a Th1 type response (Scott et al., 1989; Heinzelet al., 1991). It is of interest that these two strains displaydifferences in the reactivity of the HPA axis that are similarto the differences between APO-SUS and APO-UNSUS rats: stress-inducedincreases in BALB/c mice are larger than in C57/bl6 mice (Shankset al., 1994). Together, these data support the hypothesis thatthe structure and, especially, the reactivity of the HPA axisdirect the Th1/Th2 balance.

In comparison with the above-mentioned animal models, the model of APO-SUS and APO-UNSUS rats has several advantages, of whichonly two are mentioned below. First, the procedure used to breedAPO-SUS and APO-UNSUS rats guarantees the maintenance of the originallypresent genotypic heterogeneity, apart from the alleles at theloci involved in the determination of the selected traits; thismatches the human situation far better than animal models withdifferent inbred strains of rodents because such inbred strains,unlike humans, are each marked by a genotypic uniformity. Second,the available knowledge about group-specific differences in structureof the brain and body, as well as in behavior of APO-SUS and APO-UNSUSrats, is far greater than that of the mentioned inbred strains.Such knowledge is a prerequisite for analyzing additional mechanismsand factors that modulate, control, or direct individual-specificdifferences in susceptibility to inflammatory and infectious diseases.In this respect, it is relevant to mention that the group-specificdifferences in the structure and reactivity of the brain of APO-SUSand APO-UNSUS rats are consistently and causally coupled to group-specificdifferences in behavioral responses to internal and external challenges(coping styles). This makes these rats very useful models forstudying the complex relation between individual-specific vulnerabilityfor immune diseases and different coping styles.

Recently, we have found that APO-SUS and APO-UNSUS rats differ also in the adrenergic reactivity of the peripheral and CNS.Apart from the finding that the basal plasma level of adrenalineis lower in APO-SUS rats than in APO-UNSUS rats that may resultin relatively hypersensitive $beta$ ₂-adrenergic receptors, the stress-inducedincrease in adrenaline is much higher in APO-SUS rats than inAPO-UNSUS rats (Rots, 1995). Therefore, the adrenergic systemmay be more effective in modulating responses in APO-SUS ratsthan in APO-UNSUS rats. Cells of the immune system express $beta$ ₂-adrenergicreceptors and from in vitro experiments it is known that adrenalinecan selectively influence the reactivity of Th1 or Th2 cells (Johnsonand Gordon, 1981). The increase in intracellular cAMP after activationof $beta$ ₂-adrenergic receptors results in increased IL-4 production(Paul-Eugene et al., 1993; Lacour et al., 1994; Katamura et al.,1995). Moreover, $beta$ ₂-adrenergic agonists can stimulate IL-4-dependentIgE synthesis (Paul-Eugene et al., 1993, 1995). We have data showingthat $beta$ ₂-adrenergic agonist inhibit IFN- $gamma$ production, resultingin a shift toward Th2 type responses (A. Kavelaars, unpublisheddata). Thus, the relatively increased responsiveness of $beta$ ₂-adrenergicreceptors in APO-SUS rats may also contribute to the relativelyincreased ratio of IL-4 over IFN- $gamma$ production. Therefore, thedifference in Th1/Th2 balance between APO-SUS and APO-UNSUS animalscould also be partly a result of the difference in the reactivityof the adrenergic system.

In conclusion, our data from the in vivo experiments are consistent with the hypothesis that the high reactivity of the HPAaxis in APO-SUS animals can facilitate differentiation to Th2type effector cell response and enhance IgE secretion, resultingin high IgE titers after infection with T. spiralis. Conversely,the low reactivity of the HPA axis in APO-UNSUS rats results insusceptibility to inflammatory autoimmune disease that is mediatedvia Th1 type T cells.

FOOTNOTES

Received Nov. 12, 1996; revised Jan. 9, 1997; accepted Jan. 13, 1997.

We are greatly indebted to Dr. H.-D. Volk, Institut fur Medizinische Immunologie, Humboldt University, Berlin, Germany, forproviding the plasmid for the competitive PCR. We thank ConnyVerbaas, Jitske Zijlstra, Anita Meijer, and Gerard Geelen forskillful technical assistance.

Correspondence should be addressed to Dr. Annemieke Kavelaars, Department of Immunology, University Hospital for Childrenand Youth "Het Wilhelmina Kinderziekenhuis," P.O. Box 18009, 3501CA Utrecht, The Netherlands.

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