Cat odors induce rapid, innate and stereotyped defensive behaviors in rats at first exposure, a presumed response to the evolutionary pressures of predation. Bizarrely, rats infected with the brain parasite Toxoplasma gondii approach the cat odors they typically avoid. Since the protozoan Toxoplasma requires the cat to sexually reproduce, this change in host behavior is thought to be a remarkable example of a parasite manipulating a mammalian host for its own benefit. Toxoplasma does not influence host response to non-feline predator odor nor does it alter behavior on olfactory, social, fear or anxiety tests, arguing for specific manipulation in the processing of cat odor. We report that Toxoplasma infection alters neural activity in limbic brain areas necessary for innate defensive behavior in response to cat odor. Moreover, Toxoplasma increases activity in nearby limbic regions of sexual attraction when the rat is exposed to cat urine, compelling evidence that Toxoplasma overwhelms the innate fear response by causing, in its stead, a type of sexual attraction to the normally aversive cat odor.
Citation: House PK, Vyas A, Sapolsky R (2011) Predator Cat Odors Activate Sexual Arousal Pathways in Brains of Toxoplasma gondii Infected Rats. PLoS ONE 6(8): e23277. doi:10.1371/journal.pone.0023277
Editor: Georges Chapouthier, Université Pierre et Marie Curie, France
Received: May 23, 2011; Accepted: July 11, 2011; Published: August 17, 2011
Copyright: © 2011 House et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by the National Institutes of Health (5R01 MH079296) and The Stanley Medical Research Institute (06R-1463). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
A fascinating phenomenon in behavioral biology is the ability of parasites to manipulate host behavior for their own benefit. A handful of examples are noted for insect ,  and crustacean  hosts, but rarely so in mammals. The extraordinary effectiveness of the mammalian blood brain barrier denies most pathogens access to the privileged central nervous system, the seat of will.
Toxoplasma gondii is an obligate, single-celled protozoan parasite capable of crossing into the central nervous system of any warm-blooded vertebrate. Toxoplasma requires the cat intestine to reproduce sexually, is shed in cat feces, and must make its way from the ground to another cat host .
Toxoplasma manages this in part by infecting ground-dwelling rats who, remarkably, begin selectively preferring areas with cat urine , , . Infected rats retain normal defensive behavior to non-feline predator odor and normal performance on memory, anxiety, fear and social tasks , . This specific preference for cat odor is likely an adaptive manipulation by Toxoplasma, increasing infected rat predation rates and facilitating Toxoplasma transmission to the cat.
Little is known about how Toxoplasma inspires this manipulation. By two weeks post infection, Toxoplasma has settled throughout the host rat brain in spherical cysts approximately 50–70 µm in diameter . Intriguingly, cysts show a slight preference for limbic system regions responsive to both predator stimuli and sexual stimuli, regions responsible for gating innate approach and avoidance behaviors . We investigated the effect of Toxoplasma on the neural activity in limbic system regions involved in both ‘defensive’ and ‘reproductive’ innate behavior. Neural activity was quantified using the immediate early gene c-Fos, a proxy for neural activity (see Materials and Methods).
We first confirmed limbic activity during exposure to either cat urine or an inaccessible estrous female. As expected , ,  in uninfected rats, cat urine increased neural activity in the ‘defensive’ ventromedial hypothalamus, dorsomedial part (VMHdm) (Figure 1B and Table S1). Exposure to an estrous female rat increased activity in the ‘reproductive’ posterodorsal medial amygdala (MEApd) (Figure 1B and Table S1) .
(A) Toxoplasma infected rats spent more time exploring cat urine than uninfected rats. (B) In uninfected animals, female odor induces relatively greater ‘reproductive’ MEApd activity and relatively diminished ‘defensive’ VMHdm activity, as expected. (C) In infected animals, activity levels in the MEApd are the same, regardless of whether exposed to a ‘reproductive’ or ‘defensive’ odor. (D) Neural activity in infected male rats, normalized to uninfected controls, after exposure to cat urine. Infection increased neural activity in the BLA, MEApd and VMHdm. (E) Neural activity in infected male rats, normalized to uninfected controls, after exposure to an estrous female. Infection again increased neural activity in the BLA and VMHdm, but did not change MEApd levels. (F) Toxoplasma infection increased ‘reproductive’ MEApd neural activity during exposure to cat odor, mimicking neural activity in uninfected animals exposed to a female rat. MEApd, posterodorsal medial amygdala; VMHdm, ventromedial hypothalamus, dorsomedial part; BLA, basolateral amygdala. P values listed where appropriate.
Toxoplasma infection made rats spend more time exploring cat urine (Figure 1A) and increased neural activity in the MEApd, VMHdm and basolateral amygdala (BLA) (Figure 1C and 1D) during this exploration. During exposure to an estrous female, Toxoplasma increased activity in the VMHdm and BLA, but did not significantly alter MEApd activity (Figure 1E) relative to uninfected controls. Toxoplasma infected rats had reduced volumes of both the MEApd and the posteroventral medial amygdala (MEApv) (Figure S1 and see Discussion S1).
Rats have separate ‘defensive’ and ‘reproductive’ pathways gating innate behavioral response to, respectively, predator or sexual stimuli . Given the precipitous evolutionary pressures of both reproduction and predation, these pathways run as direct projections from the olfactory bulb to the limbic system and generate rapid and stereotyped behavioral output (see Figure 2B and Figure 2C). Although functionally distinct, the limbic ‘defensive’ and ‘reproductive’ pathways run in parallel through the medial amygdala and hypothalamus in close anatomical proximity. Previous findings of increased Toxoplasma cyst density in these areas compel the possibility that Toxoplasma is somehow perturbing its surrounding neural environment and thereby manipulating the host response to cat urine. We find, indeed, that Toxoplasma infection perturbs the ‘defensive’ pathway in the infected rat during exposure to cat urine, shifting neural activity to the nearby ‘reproductive’ pathway, specifically the MEApd (see Figure 2D).
(A) General schematic model of limbic brain activity in a male rat after exposure to an emotionally salient odor. (B) Exposure to an inaccessible estrous female activates the ‘reproductive’ pathway, producing robust MEApd activity and evoking approach behavior. (C) Exposure to cat urine activates the ‘defensive’ pathway, producing robust activation of excitatory (+) VMHdm neurons and evoking defensive, aversion behavior. Excitatory (pointed arrow) projections from the MEApv activate inhibitory (−) VMHvl neurons, countering inhibitory (blunted arrow) projections from the MEApd and suppressing any approach behavior. (D) Proposed model for Toxoplasma rats during exposure to cat urine. Robust MEApd activity biases toward approach behavior. Aversion behavior remains, but is lessened. Raw density of c-Fos (large print) ±SEM (small print) activity is given for each region during relevant odor exposure. Model adapted from Choi 2005. AOB, accessory olfactory bulb; MEA, medial amygdala; VMH, ventromedial hypothalamus.
The MEApd projects robustly to hypothalamic nuclei involved in sexual arousal and the generation of approach behavior. The MEApd is responsive to a variety of social odorants , but responds strongest to opposite-sex mating stimuli. Lesioning the MEApd reduces, specifically, attraction to opposite-sex odors . Interestingly, Toxoplasma increased MEApd activity during cat urine exposure to levels mimicking uninfected rats during female exposure (Figure 1F). This suggests that the specifically increased magnitude of MEApd activity in male Toxoplasma infected rats is biasing the processing of the cat urine toward the sexual, ‘reproductive’ pathway (Figure 2D). Plausibly, this shift is altering the salience of the cat urine stimuli and mitigating the defensive response by creating, in its stead, a competing attraction to the cat urine.
Little is known about how, if at all, Toxoplasma cysts exert themselves in the host brain. Much work remains to be done, based on striking findings that Toxoplasma raises whole brain dopamine levels in mice by up to 15%  and that dopamine receptor antagonists block rodent host attraction to cat urine . These data suggest a link between dopamine, a primary neurotransmitter in decision-making and reward, and the altered behavior. Intriguingly, the Toxoplasma genome contains a homolog of tyrosine hydroxylase , the rate-limiting enzyme in the vertebrate synthesis of dopamine, raising the possibility that Toxoplasma is altering dopamine levels by synthesizing its own tyrosine hydroxylase.
From the ground, Toxoplasma finds its way into other hosts besides rats, including cows, sheep, pigs and many grazing livestock. Ingestion of undercooked meat from infected livestock and the profligacy of private cat ownership are responsible for a strikingly high number of human chronic Toxoplasma infections. Approximately one-third of humans are seropositive for Toxoplasma across the world , and several recent studies find infection increases risk for schizophrenia , ,  and obsessive compulsive disorder , diseases noted for elevated dopamine levels and disturbed amygdala function . Our results are therefore of wide interest, as the ability of Toxoplasma to dramatically alter host behavior and proper amygdala functioning may extend beyond the rat into ancillary Toxoplasma hosts, including humans.
Materials and Methods
The use and care of animals complied with the guidelines of the Animal Advisory Committee at Stanford University. The protocol was approved by the Institutional Animal Care and Use Committee (Protocol #: APLAC-11603).
Animals were split into four groups: cat-urine uninfected (n = 9), female-odor uninfected (n = 9), cat-urine infected (n = 9) or female-odor infected (n = 9). On the day of sacrifice, animals were exposed to either cat odor or an inaccessible estrous female. Brains were collected and regions of interest were analyzed for c-Fos activation. For stereological analysis, twelve animals were split into two groups: stereology-control (n = 6) and stereology-infected (n = 6).
All studies involved male Long Evans rats. The animals were housed in groups of three, kept on a 12 hr light/dark cycle and given food and water ad libitum. Behavioral testing occurred during the light cycle.
The Toxoplasma infected groups (n = 18 for cat-urine infected groups, n = 6 for stereolgy-infected group) were injected i.p. with approximately 10∧7 Toxoplasma tachyzoites. We employed a Prugnaud strain of Toxoplasma, maintained as tachyzoites by passage in human foreskin fibroblast monolayers. Infected fibroblasts were syringe lysed using a 27-gauge needle and injected into animals. Animals were either infected i.p. with Toxoplasma tachyzoites or mock-infected with sterile PBS. Behavior experiments and c-Fos quantification was performed six weeks post-infection.
Odor Exposure and Behavior
For cat-urine groups, a towel with 1 ml bobcat urine was clipped to a rack above the home cage for 20 min. For female-odor groups, an inaccessible estrous female was placed in the home cage for 20 min, separated from the male rats by a plastic divider with holes in it. Male rats could not touch the female. Video recordings were scored by A.V. Briefly, in the videos post hoc ‘incentive zones’ were created around the feline urine or the towel and the number of nose pokes into this area were scored across the twenty minute period.
Animals were sacrificed 90 min after the end of the 20 minute exposure to either cat odor or a female rat. Animals were deeply anaesthetized and transcardially perfused with 4% paraformaldehyde (PFA) made in 0.1 M phosphate buffer (PB). The brains were removed from the skull and postfixed in 4% PFA overnight. Blocks containing the amygdala and hypothalamus were cut on a cryostat and subsequently sectioned into 40 µm thick sections.
Sections were incubated in 1% H202 for 15 min and then incubated for 90 hrs at 4°C with a c-Fos primary antibody (1:2000, sc52 Rabbit Polyclonal, Santa Cruz Biotechnology) diluted in PBS+ (0.1 M PBS with 0.2% Triton-X and 0.1% BSA). Sections were then incubated for 1 hr in a secondary antibody solution (1:400, biotinylated anti-rabbit IgG, Vector Laboratories), followed by incubation for 1 hr in Vectastain Elite ABC Reagent (1:25, Vectastain Elite ABC Kit, PK6101 Rabbit, Vector Laboratories). Next, sections were incubated for 6 min in a DAB solution (DAB Substrate Kit SK-4100, Vector Laboratories). Sections were mounted and coverslipped. Sections were washed in 0.1 M PBS for 30 min between each of these steps and all steps were done under agitation.
For technical reasons, not all brains could be counted. Two animals were lost in the cat-urine uninfected group (leaving n = 7), one in the female-odor uninfected group (leaving n = 8) and one in the cat-urine Toxoplasma group (leaving n = 8). Regions of interest were traced in Stereo Investigator software and scored. Only darkly-labeled oval shaped nuclei were counted as c-Fos positive. The area of the region of interest was scored using the Cavalieri Estimator tool in Stereo Investigator software. The number of positive nuclei was divided by the area of the region to arrive at c-Fos density per region of interest.
A systematic and randomly sampled series of sections through regions of interest was used to estimate volumes. Specifically, 40 µm coronal sections throughout the entire region of interest were cut and cresyl-violet stained. The area of the ROI in every fourth section was estimated using the Cavalieri Estimator tool in Stereo Investigator software. The first section in the series was randomly selected from among the first four sections. The distance between the upper surfaces of the sections was 160 µm (4×40 µm). Areas were recorded for each ROI as described above and total volumes were calculated using the Stereo Investigator software.
Behavior was analyzed using one-way analysis of variance (ANOVA) to compare between uninfected and Toxoplasma infected groups exposed to cat urine. Values are reported as mean ± SEM throughout. For c-Fos counts and volume data, an independent-samples T test was conducted. A P value of <0.05 indicates statistical significance throughout.
Toxoplasma Alters Volumes and c-Fos Expression of Limbic Regions Involved in Processing Cat Odor. (A) Schematic diagram (adapted from Paxinos and Watson 2007) of coronal slices of rat brain showing areas of c-Fos and volume quantification. (B) Volumes of amygdalar and hypothalamic regions of interest in uninfected and Toxoplasma-infected animals. Coronal 40 um sections were taken throughout the whole region and 3-dimensional volumes were calculated via stereological analysis. (C) Digital camera lucida drawings of c-Fos signal in the lateral amygdala in uninfected (left) or infected (right) rats. (D) Digital camera lucida drawings of c-Fos signal in the medial amygdala in uninfected (left) or infected (right) rats. (E) c-Fos photomicrograph from which (C) is based. (F) c-Fos photomicrograph from which (D) is based.
Density of c-Fos positive cells (mean ± SEM).
The authors would like to thank Dr. John Boothroyd and Dr. Anita Koshy for valuable advice and technical help.
Conceived and designed the experiments: PKH AV RS. Performed the experiments: PKH. Analyzed the data: PKH AV. Wrote the paper: PKH.
- 1. Biron DG, Marché L, Ponton F, Loxdale HD, Galéotti N, et al. (2005) Behavioural manipulation in a grasshopper harbouring hairworm: a proteomics approach. Proc Biol Sci 272: 2117–2126.
- 2. Libersat F, Delago A, Gal R (2009) Manipulation of host behavior by parasitic insects and insect parasites. Annu Rev Entomol 54: 189–207.
- 3. Kuris AM, Goddard JHR, Torchin ME, Murphy N, Gurney R, et al. (2007) An experimental evaluation of host specificity: the role of encounter and compatibility filters for a rhizocephalan parasite of crabs. Int J Parasitol 37: 539–545.
- 4. Dubey JP, Lindsay DS, Speer CA (1998) Structures of Toxoplasma gondii tachyzoites, bradyzoites, and sporozoites and biology and development of tissue cysts. Clin Microbiol Rev 11: 267–299.
- 5. Berdoy M, Webster JP, Macdonald DW (2000) Fatal attraction in rats infected with Toxoplasma gondii. Proc Biol Sci 267: 1591–1594.
- 6. Vyas A, Kim S-K, Giacomini N, Boothroyd JC, Sapolsky RM (2007) Behavioral changes induced by Toxoplasma infection of rodents are highly specific to aversion of cat odors. Proc Natl Acad Sci USA 104: 6442–6447.
- 7. Webster JP, Lamberton PHL, Donnelly CA, Torrey EF (2006) Parasites as causative agents of human affective disorders? The impact of anti-psychotic, mood-stabilizer and anti-parasite medication on Toxoplasma gondii's ability to alter host behaviour. Proc Biol Sci 273: 1023–1030.
- 8. Lamberton PHL, Donnelly CA, Webster JP (2008) Specificity of the Toxoplasma gondii-altered behaviour to definitive versus non-definitive host predation risk. Parasitology 135: 1143–1150.
- 9. Dielenberg RA, Hunt GE, McGregor IS (2001) “When a rat smells a cat”: the distribution of Fos immunoreactivity in rat brain following exposure to a predatory odor. Neuroscience 104: 1085–1097.
- 10. Canteras NS (2002) The medial hypothalamic defensive system: hodological organization and functional implications. Pharmacol Biochem Behav 71: 481–491.
- 11. Choi GB, Dong H-W, Murphy AJ, Valenzuela DM, Yancopoulos GD, et al. (2005) Lhx6 delineates a pathway mediating innate reproductive behaviors from the amygdala to the hypothalamus. Neuron 46: 647–660.
- 12. Goodson JL, Kabelik D (2009) Dynamic limbic networks and social diversity in vertebrates: from neural context to neuromodulatory patterning. Frontiers in Neuroendocrinology 30: 429–441.
- 13. Maras PM, Petrulis A (2006) Chemosensory and steroid-responsive regions of the medial amygdala regulate distinct aspects of opposite-sex odor preference in male Syrian hamsters. Eur J Neurosci 24: 3541–3552.
- 14. Stibbs HH (1985) Changes in Brain Concentrations of Catecholamines. Ann Trop Med Parasitol 79: 153–157.
- 15. Gaskell EA, Smith JE, Pinney JW, Westhead DR, McConkey GA (2009) A unique dual activity amino acid hydroxylase in Toxoplasma gondii. PLoS ONE 4: e4801.
- 16. Lafferty KD (2006) Can the common brain parasite, Toxoplasma gondii, influence human culture? Proc Biol Sci 273: 2749–2755.
- 17. Torrey EF, Yolken RH (2007) Schizophrenia and toxoplasmosis. Schizophr Bull 33: 727–728.
- 18. Leweke FM, Gerth CW, Koethe D, Klosterkötter J, Ruslanova I, et al. (2004) Antibodies to infectious agents in individuals with recent onset schizophrenia. Eur Arch Psychiatry Clin Neurosci 254: 4–8.
- 19. Cetinkaya Z, Yazar S, Gecici O, Namli MN (2007) Anti-Toxoplasma gondii antibodies in patients with schizophrenia–preliminary findings in a Turkish sample. Schizophr Bull 33: 789–791.
- 20. Miman O, Mutlu EA, Ozcan O, Atambay M, Karlidag R, et al. (2010) Is there any role of Toxoplasma gondii in the etiology of obsessive-compulsive disorder? Psychiatry Research 177: 263–265.
- 21. Benes FM (2010) Amygdalocortical circuitry in schizophrenia: from circuits to molecules. Neuropsychopharmacology 35: 239–257.