Diminished Anxiety- and Depression-Related Behaviors in Mice with Selective Deletion of the Tac1 Gene

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The Journal of Neuroscience, November 15, 2002, 22(22):10046-10052

Diminished Anxiety- and Depression-Related Behaviors in Mice with Selective Deletion of the Tac1 Gene
Andras Bilkei-Gorzo, Ildiko Racz, Kerstin Michel, and Andreas Zimmer
Laboratory of Molecular Neurobiology, Department of Psychiatry, University of Bonn, 53105 Bonn, Germany

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The tachykinin neuropeptide substance P and its receptor neurokinin 1 have been implicated in the regulation of many physiologicaland pathological processes, including the control of emotionalbehaviors. The present study examines mice with a targeted deletionof the Tac1 gene, which encodes the neuropeptides substance Pand neurokinin A, in animal models relevant to depressive illnessand anxiety. In depression-related paradigms, Tac1-deficient micewere more active in the Porsolt's forced-swimming test and thetail-suspension test, and they did not become hyperactive afterbulbectomy. Tac1 mutant mice were also less fearful in severalanimal models of anxiety. They were more active and less affectedby the light conditions in the central area of the open-fieldarena; they showed more social interactions in an aversive environment,they were more active in the open areas of an elevated zero-maze,and they had a reduced latency to feed in the Thatcher-Brittonconflict paradigm. These results demonstrate that tachykininsare powerful mediators of depression-like or anxiety-related behaviorsin mice. The tachykinin system therefore may play an importantrole in the regulation of emotional states and the developmentof anxiety disorders anddepression.

Key words: anxiety; depression; tachykinin; mice; knock-out; stress

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Tachykinins are a family of structurally related neuropeptides sharing the C-terminal sequence Phe-X-Gly-Leu-Met-NH₂. In mice,they are encoded by two genes, Tac1 and Tac2. Differential splicingof the Tac1 gene gives rise to three distinct precursor proteins,which are further processed into several related peptides. Ofthese, substance P (SP) and neurokinin A (NKA) are the best characterizedand perhaps the most important peptides. Only one neuropeptide,neurokinin B (NKB), is encoded by the Tac2gene.

Tachykinins selectively bind and activate the G-protein-coupled receptors NK1R, NK2R, and NK3R. SP is the most potent ligandfor NK1R, whereas NKA has the highest affinity for NK2R. However,the receptor-selectivity of these peptides is relatively low.Because NK1R is abundantly expressed in the CNS and NK2R is virtuallyabsent, many of the effects of SP and NKA on the brain thereforemay be mediated by NK1R. NKB is a more potent agonist for theNK3R than SP or NKA, and may be its naturalligand.

Because SP is synthesized by nociceptive neurons and released after nociceptive stimulation, SP has been implicated in themodulation of nociceptive signaling. Indeed a vast body of literaturefrom studies using diverse approaches has generally supporteda role of SP in spinal nociception (Cao et al., 1998; Zimmer etal., 1998). Nevertheless, attempts to develop NK1R antagonistsas antinociceptive drugs have beensuccessful.

More recently, SP has also been implicated in the modulation of emotional behaviors. Limbic structures contain a high densityof SP terminals and NK1 receptor sites (Honkaniemi et al., 1992;Hurd et al., 1999; Ribeiro-da-Silva and Hokfelt, 2000), and experimentalstressors of various types can trigger changes in the contentor release of SP and internalization of the NK1R in discrete brainregions. These changes may be involved in behavioral stress responses,because several studies have demonstrated anxiety-like behaviorsand conditioned place aversion after the central administrationof neurokinin receptor agonists. Antagonists can produce anxiolytic(Teixeira et al., 1996) or anxiogenic (Zernig et al., 1993) effects,depending on the animal species and the location of the injectionsite. Mice with selective deletion of the gene coding NK1R alsoshowed reduced aggressive behaviors (Rupniak et al., 2001), impairedstress-induced analgesia, and behavioral alterations in severalanimal models of anxiety anddepression.

Support for an involvement of the tachykinin system in the pathophysiology of mood disorders was obtained recently by thedemonstration that the NK1R antagonist MK869 had antidepressanteffects in a placebo-controlled clinical trial (Kramer et al.,1998). Preclinical studies have shown that the concentration ofSP was elevated in the cerebrospinal fluid of depressed patients(Rimon et al., 1984) and in the brain of a rat model of depression(Husum et al., 2001). In the latter model, SP levels were normalizedby treatment with lithium, which is used in clinical practiceas a mood stabilizer for the treatment of bipolardepression.

We have previously described the generation of a mouse strain with a targeted mutation in the Tac1 gene (Zimmer et al., 1998).Tac1-mutant animals cannot produce SP or NKA. They develop normally,are fertile, and care for their offspring. Behavioral studieswith these mice have demonstrated that they are less sensitiveto nociceptive stimulation in acute and tonic pain models. Thisphenotype is consistent with a proposed role of SP in nociceptivesignaling. In this study, we have used mice with a targeted deletionof the gene Tac1 to further investigate the role of the tachykininsystem in stress-related behaviors. We demonstrate that Tac1^/ animals display characteristic alterations in animal models ofanxiety and depression, which is consistent with a function ontachykinin peptides as modulators of emotionalbehaviors.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals. The generation of mice with a targeted mutation of the Tac1 gene on a mixed genetic background has been describedpreviously (Zimmer et al., 1998). To obtain Tac1 mutant mice onan inbred congenic genetic background, we mated heterozygous (Tac1^+/) mice with wild-type C57BL/6J (The Jackson Laboratory, Bar Harbor,ME) animals for 10 generations. Heterozygous mice from the F10generation were then intercrossed to generate animals in whichboth copies of the Tac1 gene were deleted (homozygous Tac1^/ mice). Tac1^/ mice for behavioral studies were derived from these homozygousanimals. To avoid a genetic drift, we routinely cross out mutantsback to wild-type C57BL/6J animals after three generations ofhomozygous breeding. Animals used in this study were bred in ouranimal facility. In addition, some wild-type C57BL/6J controlanimals were purchased from The Jackson Laboratory. These micewere acclimated for at least 2 weeks before testing. We testedmale mice (3-4 months old) housed in groups of three to five.Animals were kept in a room with a reversed light/dark cycle (lightson: 9 P.M., off 9 A.M.) for at least 2 weeks before testing. Everyexperimental group contained 10 mice, unless stated otherwise.The animals were naive to the test situation, they were used onlyonce, and all tests were conducted between 1 and 5 P.M. Food andwater was available ad libitum, except for the group of mice testedin the Thatcher-Britton paradigm. These animals were food deprivedfor 24 hr. Care of the animals and conduct of all experimentsfollowed the guidelines of the German Animal Protection Law (issuedin1998).

Drugs. Amitryptiline HCl, imipramine HCl, fluoxetine HCl, diazepam, and buspirone HCl were purchased from Sigma-Aldrich andsolved in saline. Diazepam (Sigma-Aldrich) was dispersed withone drop of Tween 60 in saline. Ethanol (Merck) was diluted withsaline.

Forced-swimming test. Animals were treated (10 in each group) intraperitoneally in a volume of 10 ml/kg with vehicle (saline)or antidepressant. Amitryptiline (10 mg/kg), imipramine (5 mg/kg),and fluoxetine (20 mg/kg) were used as positive control. Thirtyminutes later, mice were placed in a Plexiglas cylinder (10 cminternal diameter, 50 cm high) filled with 25-26°C water (10 cmheight). Duration of the experiment was 6 min; the behavior ofthe animals was evaluated between the first and sixth minute for5 min. The immobility time was measured by an observer, who wasunaware of the genetic background or drug treatment, using a stopwatch.A mouse was judged to be immobile when it remained floating inthe water, making only those movements necessary to keep its headabove the water (Porsolt et al., 1977a). Groups were comparedusing one-way ANOVA; the Dunnett's test was used for post hoccomparisons.

Tail-suspension test. Mice were suspended individually by their tail from a metal rod. The rod was fixed 50 cm above the surfaceof a table covered with soft cloth in a sound-isolated room. Thetip of the tail was fixed using adhesive Scotch tape; the durationof the test was 6 min. The immobility time was determined by anobserver, using a stopwatch, who was unaware of the strain (Steruet al., 1985). Mean values and SEs were calculated for each groupand compared using the Student's ttest.

Bulbectomy-induced hyperactivity. The experiment was performed with slight modifications as described previously (Otmakhovaet al., 1992). Mice were anesthetized with Avertine (2.5%, 20ml/kg). An incision was made in the skin overlying the skull,and a 2 mm hole was drilled in the skull through the frontal suture.Olfactory bulbs were removed by gentle aspiration. The same procedurewas performed on sham-operated animals, except that the olfactorybulbs were not removed. Each animal was housed singly after surgery.Locomotor activity of animals was studied 14 d after the operationin a dimly lit, sound-attenuated room. The animals were placedin an open-field arena (45 × 45 × 22 cm). The distance traveledand the number of rearings were recorded for 4 min (Actimeter,TSE). After completion of the behavioral experiments, mice weredecapitated, brains were removed, and the success of the bulbectomywas evaluated. Groups were compared using two-way ANOVA (surgery× genotype) followed by Student's-Newman-Keuls (SNK)test.

Open-field test. Mice were placed in the center of a brightly lit (650-700 lux) or dimly lit (20-30 lux) chamber of the open-fieldapparatus (44 × 44 × 30 cm). Movements of the animals were trackedby an automatic monitoring system (MED Associates) for 20 min.Horizontal motor (distance traveled) and central activity (distancetraveled in central area/total distance traveled) were evaluated.Mean value and SE was calculated in each group, which contained10 animals. Groups were compared using two-way ANOVA (genotype× illumination) followed by SNKtest.

Elevated zero-maze. Mice were kept for at least 1 hr in the normally illuminated room where the treatment and experiment wereperformed. Animals were treated with saline (Tac1^/ mice and the control Tac1^+/+ mice) or reference compound (buspirone 1 mg/kg, diazepam 1 mg/kg,or ethanol 2 gm/kg) intraperitoneally in a volume of 10 ml/kg;9-10 animals were tested in each group. Thirty minutes later theiractivity on the zero-maze was measured for 5 min. The maze consistedof an annular white platform (inner diameter 46 cm, 5.6 cm width)elevated 40 cm above ground level and divided equally into fourquadrants. The two opposite quadrants were enclosed by white walls(24 cm high) on both edges of the platform. The behavior of micewas videotaped using a camera fixed above the maze and analyzedwith a video-tracking system (Videomot; TSE GMbH). The numberof stretching postures was determined by an experienced observerwho was unaware of strain or treatment. Time spent in the openarea, distance traveled in the open and closed parts, and numberof stretching postures were evaluated (Shepherd et al., 1994;Konig et al., 1996). Mean value and SE were calculated in eachgroup, and groups were compared using one-way ANOVA followed byDunnett'stest.

Thatcher-Britton paradigm. Ten wild-type and 10 knock-out mice were food deprived for 24 hr before testing. During testing,animals were placed individually along one wall of the open-fieldapparatus lit by normal house lighting (light intensity 300-400lux in the center of the box). Six pellets (2.8-3.3 gm) of standardmouse chow were placed in the center of the open field. The latencyto eat (not sniffing or manipulating the pellets) was recordedby an observer who was unaware of the genotype (Rochford et al.,1997). One week later the experiment was repeated, but in thissession the food pellet was presented in the home cage. Mean valueand SE were calculated in each group, and groups were comparedusing Student's ttest.

Social interaction test. Social activity of male mice that were naive to each other was tested in a brightly lit, unfamiliarenvironment. The animals were placed in the opposite areas ofa transparent box (44 × 44 × 30 cm) and separated by a removablewall. After 5 min of habituation, the wall was removed, and theactivity of the animals was recorded on videotapes for 10 min.Time spent with social interactions was registered and evaluatedby an observer who was unaware of the genotype (de Angelis andFile, 1979). Mean values and SEs were calculated and comparedusing Student's ttest.

Smelling test. Male wild-type and knock-out animals were placed individually into an open field with one female urine-stainedand one water-stained filter paper (3 × 3 cm each) in oppositecorners. The number of contacts with each paper was evaluatedfor 5 min. The data were analyzed by two-way ANOVA (genotype ×odorant).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In the first set of experiments, we tested the behavior of knock-out and wild-type mice in animal models commonly used indepression research. We first used the forced-swimming test (Porsolt,1997; Persolt et al., 1977b) and the tail-suspension test (Steruet al., 1985). Both models are based on the observation that rodents,when forced to an aversive situation from which they cannot escape,will rapidly cease attempts to escape and become immobile. Manyantidepressants reduce the immobility time in these tests (Steruet al., 1987; Porsolt, 2000).

In the forced-swimming test, active escape periods alternated with periods in which the animals were completely inactive ormade only the movements necessary to keep their head above water.As shown in Figure 1A, Tac1^/ mice spend less time immobile in this test than Tac1^+/+ animals. Treatment of wild-type animals with antidepressant drugs,including the tricyclic uptake inhibitors imipramine and amitryptiline,as well as the selective serotonin reuptake inhibitor fluoxetine,significantly reduced immobility time (F_(4,45) = 6.99; p < 0.001;one-way ANOVA) (Fig. 1A). There was no difference in immobilitytime between Tac1^/ mice and Tac1^+/+ animals treated with antidepressants. In the tail-suspensiontest, the immobility time in Tac1^/ mice was also reduced significantly ( $-$ 18.2%; t_(1,18) = 3.737;p < 0.01; Student's t test) (Fig. 1B).

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Figure 1. Behavior of Tac1^+/+ and Tac1^/ male mice in behavioral despair models of depression. A, Forced-swimming test. **p < 0.01; ***p < 0.001 (one-way ANOVA followed by Dunnett's test). B, Tail-suspension test. **p < 0.01 (Student's unpaired t test). Each error bar represents the mean time spent in immobility (±SEM) of 10 animals.

We further investigated Tac1^/ mice in another animal model related to depression that is fundamentally different from the behavioraldespair models. For this purpose, we chose the bulbectomy test(Leonard and Tuite, 1981; Otmakhova et al., 1992). Bulbectomyinduces behavioral and neuroendocrinal changes, similar to thoseobserved in depressive patients, that can be reversed with antidepressanttreatment (Jesberger and Richardson, 1988). There was a significantinteraction between strain and surgery in horizontal motor activity(F_(1,38) = 4.246; p < 0.05; ANOVA) and in vertical activity (F_(1,38)= 5.929; p < 0.05; ANOVA) (Fig. 2. Post hoc analysis revealedthat horizontal and vertical activity were significantly increasedafter bulbectomy in Tac1^+/+ animals (horizontal activity: +53.8%, p < 0.001; vertical activity:+130.3%, p < 0.05; SNK test). In contrast, neither horizontalnor vertical movements were significantly increased in bulbectomizedversus sham-operated Tac1^/ animals. Because differences in the ability to smell might affectthe animals' behavior in this and other tests, we analyzed theresponses of Tac1^/ mice to olfactory cues. When male Tac1^/ and Tac1^+/+ mice were presented with a (female) urine-stained or a water-stainedfilter paper in an open field, both genotypes investigated theurine-stained paper more frequently (F_(1,17) = 21.6; p < 0.001).There was no difference between the two genotypes (F_(1,17) = 1.37;p = 0.25), and also no interaction was detected (F_(1,17) = 0.85;p = 0.36), indicating that ability to smell was not impaired inTac1^/ mice.

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Figure 2. Horizontal (distance traveled) and vertical (number of rearings) motor activity of sham-operated and bulbectomized Tac1^+/+ and Tac1^/ mice in the open-field apparatus. Each value represents the distance traveled or number of rearings (mean ± SEM; n = 10-11). **p < 0.01; ***p < 0.001 according to two-way ANOVA (surgery × genotype) followed by SNK test.

We next studied the behaviors of Tac1^/ and Tac1^+/+ mice in the open field under aversive (450 lux, white light) and less aversive(2 lux, red light) conditions (Fig. 3). Analysis of the totalhorizontal activity showed that Tac1^/ mice were slightly (15.6%) but significantly less active thanTac1^+/+ animals (genotype effect: F_(1,36) = 6,687; p < 0.05). However,there was no significant effect of the lighting condition (F_(1,36)= 2.479; p = 0.124) and no significant interaction with the genotypeeffect (F_(1,36) = 1.121; p = 0.297)).

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Figure 3. Locomotor activity of Tac1^+/+ and Tac1^/ mice in the open-field apparatus. A, Total horizontal activity. B, Activity in the central part. Each value represents the mean distance traveled (±SEM) of 10 animals. **p < 0.01; ***p < 0.001 according to two-way ANOVA (genotype × illumination) followed by SNK test.

It is thought that the activity of mice in the central area of an open field is inversely correlated to their level of anxiety.We therefore analyzed the activity of our animals in the centralfield. We found a significant interaction between genotype andillumination (F_(1,36) = 5.077; p < 0.05). Post hoc analysis revealedthat the activity of Tac1^/ mice was higher in the central area under high-light conditions(p < 0.0001), despite the fact that their overall activity waslower. Under low-light conditions, there was no difference betweenthe two genotypes, because Tac1^/ mice were not affected by the lightning conditions (p = 0.97),whereas the activity of wild-type mice was increased (p < 0.05).

Because the results of the open-field experiment suggested that anxiety-related behaviors may be affected by the Tac1 mutations,we tested Tac1^/ and Tac1^+/+ mice in additional animal models ofanxiety.

We first used the zero-maze, which consists of an elevated annular platform divided into two open and two enclosed compartments.High levels of anxiety are thought to be associated with a reducedactivity of mice in the open compartments and an increased numberof stretch-attend postures (Shepherd et al., 1994). Indeed, one-wayANOVA showed a significant difference between groups in the numberof stretching postures (F_(4,44) = 9.46; p < 0.001) and in theopen-part activity (F_(4,44) = 18.99; p < 0.001). Treatment ofwild-type animals with the anxiolytic agents ethanol, buspirone,and diazepam significantly reduced the number of stretch-attendpostures (all drugs) and increased the activity in the open areas(ethanol and diazepam only) (Fig. 4). Activity in the enclosedcompartment did not differ significantly between Tac1^+/+ and Tac1^/ or drug-treated mice. Tac1^/ mice were also more active in the open areas than Tac1^+/+ animals (p < 0.01) and also showed fewer stretch-attend postures(p < 0.001). Testing of an independent group of animals for timespent in the open areas also revealed a significant genotype effect(F_(1,18) = 13.88; p < 0.01) for this parameter.

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Figure 4. Activity of Tac1^+/+ control, reference compound-treated, and Tac1^/ knock-out mice in zero-maze test. Error bars represent mean distance traveled in the open part (A) and number of stretching postures (B) (± SEM) of 10 animals. **p < 0.01; ***p < 0.001 (one-way ANOVA followed by Dunnett's test).

Next, the Thatcher-Britton novelty conflict paradigm (Rochford et al., 1997) was used to evaluate the effect of an aversiveenvironment on feeding behavior. In this paradigm, food-deprivedmice are placed at the periphery of a well lit and unfamiliaropen-field apparatus in contact with the enclosing walls, withfood pellets in the center. The latency until the animals beginto eat is thought to be an indicator of anxiety. It was significantlylower ( $-$ 33.1%; t_(1,18) = 3.31; p < 0.01; Student's t test) inTac1^/ mice (Fig. 5A). In contrast, when the same animals were testedafter 24 hr of starvation in their home cage, there was no differencebetween the two genotypes (t_(1,18) = 0.895; p = 0.38; data notshown). Thus, the decreased latency in the first experiment isalso likely to reflect a reduced state of anxiety in Tac1^/ mice and not an increased drive to eat.

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Figure 5. A, Thatcher-Britton novelty conflict paradigm. Error bars represent mean latency time until eating in the center of the lit open arena (±SEM) of 10 animals. B, Social interaction test. Each column represents time spent with social activity in unfamiliar and aversive (high light) environment (±SEM) of 10 animals. *p $<=$ 0.05; **p $<=$ 0.01 (Student's unpaired t test).

Finally, a social activity paradigm (File, 1985) was used to study the interactions of male mice that were naive to each otherin an aversive environment. Time spent with social interactionswas significantly higher (+81%; t_(1,18) = 2.802; p < 0.05; Student'st test) in Tac1^/ mice (Fig. 5B), again indicating reduced levels of anxiety inthese animals. The social behavior of the animals was friendlyand exploratory; antagonistic behaviors were not observed. Altogetherthese results strongly suggest that Tac1^/ mice were less anxious in these animal models than Tac1^+/+animals.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The murine Tac1 gene encodes the tachykinin peptides SP, NKA, neuropeptide K, and neuropeptide $gamma$ . SP binds preferentiallyto the NK1R, which is abundantly expressed in many regions ofthe CNS. The primary target of the other Tac1-derived peptidesis the NK2 receptor, which can only be found at low levels insome restricted brain areas (Saffroy et al., 2001).

In this article, we have analyzed Tac1^/ mice in animal models related to anxiety and depression. On the basis of the clinicalassociation of depressive episodes and stressful life events,many of the animal models for the evaluation of antidepressantdrug activity assess stress-precipitated behaviors. The two mostwidely used animal models for antidepressant drug screening arethe forced-swimming and tail-suspension tests. Although the relationshipbetween immobility, a posture thought to reflect a state of "behavioraldespair" in which animals have given up the hope of escape, anddepression remains controversial (Gardier and Bourin, 2001), drugswith antidepressant activity reduce the time during which theanimals remain immobile (Porsolt et al., 1977a; Borsini and Meli,1988). A significantly decreased immobility time in the forced-swimmingtest was also observed in genetically modified mouse strains,for example with a deletion of monoamine oxidase (MAO) A (Caseset al., 1995), MAO B (Grimsby et al., 1997), or the NK1 receptorgene (Rupniak et al., 2001). Several studies using inbred mousestrains have also shown that genetic factors contribute to thebehavior of rodents in these tests (Lucki et al., 2001; Cryanet al., 2002) and to the efficacy of antidepressant drug treatment(Vaugeois et al., 1997; Liu and Gershenfeld, 2001).

In our present study we found a significantly reduced immobility time for Tac1^/ mice in both tests. These behavioral effects of the Tac1^/ mutation are similar to those that we and other investigatorshave observed after treatment with antidepressant drugs, includingMAO inhibitors, tricyclic antidepressants such as imipramine andamitryptiline, or selective serotonin reuptake inhibitors likefluoxetine (Porsolt et al., 1977a; Borsini and Meli, 1988). Tac1^/ and Tac1^+/+ mice showed characteristically uniform responses with only asmall overlap between the two genotypes. Thus, the Tac1 gene isan important determining factor in these behavioral despair models.A recent quantitative trait loci (QTL) study has identified severalgenetic links to the propensity of behavioral despair using thesame assays (Yoshikawa et al., 2002). Unexpectedly, only a smallnumber of QTLs were shared, and one common QTL on chromosome 8displayed opposite effects in the two tests. Thus, although thetest paradigms appear to be similar, distinct genetic pathwaysmay underlie the despair-like behaviors in these tests. This ideais supported by the common observation that most antidepressantdrugs have different pharmacological profiles in the forced-swimmingand tail-suspension tests. Nevertheless, the Tac1 mutation significantlyreduced the immobility time in both tests, although to a smallerextend in the tail-suspension test ( $-$ 42.29 vs $-$ 18.2%).

Further evidence for a role of the Tac1 gene in depression-related behaviors comes from the lack of bulbectomy-induced hyperactivityin Tac1^/ mice. The bulbectomy test is fundamentally different from theforced-swimming or tail-suspension tests. It does not involvethe concept of behavioral despair, but rather relies on the observationthat bulbectomy will induce behavioral changes in rodents thatcan be reversed by chronic antidepressant treatment (Otmakhovaet al., 1992).

Our results strongly support the idea that the tachykinin system is involved in the pathophysiology of depression. Such arole was suggested by a clinical study that demonstrated the efficacyof the NK1 receptor antagonist MK869 in patients with a majordepressive disorder (Kramer et al., 1998). In this clinical study,MK869 showed an efficacy similar to that ofparoxetine.

There is evidence to suggest that some antidepressant drugs lead to a downregulation of SP biosynthesis (Shirayama et al.,1996), although it has been difficult to establish a direct relationshipbetween the level of SP expression and depression. In FlindersSensitive Line rats, an animal model of depression, Husum andcoworkers (2001) found that brain levels of SP were reduced inthe striatum and elevated in the frontal cortex. These levelswere normalized after treatment with lithium (Husum et al., 2001).In humans, one study indicated that SP levels are elevated inthe CSF of depressed patients (Rimon et al., 1984).

The behavior of Tac1^/ mice was also analyzed in several animal models of anxiety. In the open-field test (lit environment),Tac1^+/+ mice spent only 6.5% of their total activity in the central part,which represents 11% of the total area. In contrast, Tac1 ^/ mice spent 13.6% of their activity in the central area. Theseresults indicate that the testing conditions were anxiogenic forTac1^+/+ animals but not for Tac1^/ mice. Tac1^/ mice were more active in the open part of the zero-maze and showedfewer stretching postures. Knock-out mice spent more time withsocial interactions in an aversive environment, and the latencytime until eating was reduced in the Thatcher-Britton paradigm.In summary, all of our results from the four different animalmodels indicate that Tac1-deficient mice were generally less emotionalthan controlanimals.

These findings are in general agreement with the recent demonstration that pharmacological blockade of the SP receptor NK1influenced emotional responses in animals (File, 1997, 2000; Cheetaet al., 2001; Rupniak et al., 2001). However, the pharmacologicalanalysis of NK1 receptor functions has been complicated by thefact that small differences in the amino acid sequence betweenhuman and mouse or rat receptors dramatically alter antagonistbinding affinity (Fong et al., 1992). Thus, antagonists with ahigh affinity for human receptor cannot be evaluated in rats ormice. Although a few antagonists with nanomolar affinities forthe rat and mouse receptor, such as RP67580, GR205171, and SR140333,have been developed (Fong et al., 1992; Emonds-Alt et al., 1993;Gardner et al., 1996), the usefulness of these compounds in vivosuffers from their short half-life and poor brain penetration.At bioactive doses these compounds can exhibit unspecific pharmacologicaleffects, including the blockade of ion channels. Therefore itwas often difficult to ascertain whether behavioral effects ofthese drugs were caused by NK1 receptor blockade or some unspecificeffect. For example, high doses of GR205171 (30 mg/kg), whichis probably the best available antagonist for the murine NK1 receptor(Bergstrom et al., 2000), increased the attack latency in theresident-intruder test, reduced stress-induced neonatal vocalization,and increased the duration of struggle in the forced-swimmingtest (Rupniak et al., 2000, 2001). These effects were similarto those observed after treatment with antidepressant drugs suchas fluoxetine or desipramine (Lucki et al., 2001; Rupniak et al.,2001; Schramm et al., 2001). However, it is not clear whetherthese behavioral effects of GR205171 were mediated by the NK1receptor, because animals responded similarly after treatmentwith the low-affinity enantiomer GR22620600 (Rupniak et al., 2000).Also, in the rat forced-swimming test, GR205171 (40 mg/kg) remainedineffective (Rupniak et al., 2001).

Separate laboratories produced mice with targeted NK1 receptor gene deletions with different genetic background (De Felipeet al., 1998; Santarelli et al., 2001). A role for the NK1 receptorin the modulation of emotional states was also suggested by theanalysis of these knock-out animals. NK1^/ animals from both strains emitted fewer ultrasonic calls aftermaternal separation (Rupniak et al., 2000; Santarelli et al.,2001), and they were more active in the forced-swimming test (Rupniaket al., 2001). De Felipe et al. (1998) also found that NK1^/ animals were less aggressive than wild-type littermates. In theelevated plus maze, however, the results were contradictory. Murtraet al. (2000) and Rupniak et al. (2001) saw no difference betweenNK1^/ and NK1^+/+ animals, whereas Santarelli et al. (2001) found that NK1^/ mice have a decreased level of anxiety according to this model.The reason for this discrepancy can be that the genetic backgroundof the knock-out mice was different in these studies [pure 129/svin the studies of Santarelli et al. (2001), whereas 129/sv andC57BL/6J were used in the studies of Murtra et al. (2000) andRupniak et al. (2001)]. Pharmacological studies also producedconflicting results with this test, with RP67580 being effectivebut not GR205171. Although it is unclear whether these differencesare attributable to different experimental procedures or strainbackground, we show here that the Tac1 gene deletion had a clearbehavioral effect in a similar animal model of anxiety, the zero-maze.

Considering (1) the similarity of the Tac1 mutant phenotype with the behavioral effects of the genetic deletion or pharmacologicalblockade of the NK1R and (2) the fact that NK1R is widely expressedin the CNS whereas NK2R expression is weak and restricted, manyof the functions of Tac1-derived neuropeptides on the brain maybe mediated by NK1R. However, SR48968, a selective antagonistof NK2 receptor, had an enantioselective effect in specific modelsrelated to anxiety (Griebel et al., 2001) or depression (Steinberget al., 2001). Thus, both receptors may serve as targets for Tac1-derivedneuropeptides in thebrain.

The serotonergic system has been suggested as a potential target for effects of tachykinins on depression-related behaviors.Indeed, NK1R antagonism resulted in an increased firing of serotonergicneurons and attenuated presynaptic 5-HT1A receptors, similar towhat has been observed after long-term antidepressant treatment(De Felipe et al., 1998; Santarelli et al., 2001). A recent analysisof inducible 5-HT1A receptor knock-out mice demonstrated thatthe absence of this receptor during early postnatal developmenthad similar effects on anxiety-related behaviors as the unconditionalmutation (Gross et al., 2002). This result suggests a criticaldevelopmental period in the manifestation of anxiety-related phenotypes.Further studies are necessary to determine whether developmentalor compensatory mechanisms also contribute to the phenotypic changesobserved in Tac1 mutantanimals.

Together these experiments support the idea that SP and other Tac1-derived neuropeptides play a major role in anxiety anddepression. Therefore, modulation of the SP-NK1 system may havetherapeutic value in the treatment of stress-related neuropsychiatricdisorders.

  FOOTNOTES

Received Feb. 26, 2002; revised Sept. 5, 2002; accepted Sept. 11, 2002.

This work was supported by grants from the Land Nordrhein-Westphalen (Innovationsprogramm Forschung), the Deutsche Forschungsgemeinschaft(SFB400), and the BONFOR Program. We thank Charlotte Schick andAnne Zimmer for breeding theanimals.

Correspondence should be addressed to Andreas Zimmer, Laboratory of Molecular Neurobiology, Department of Psychiatry, Universityof Bonn, Sigmund-Freud-Strasse 25, 53105 Bonn, Germany. E-mail:neuro{at}uni-bonn.de.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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