The effect of toxoplasma brain parasites can cause personality alterations.
Long-Term Effects of Toxoplasmosis Brain Infection
Below is an approximation of this video’s audio content. To see any graphs, charts, graphics, images, and quotes to which Dr. Greger may be referring, watch the above video.
Of all foodborne diseases, a brain parasite called toxoplasma is “ranked as the fourth leading cause of hospitalization and the second leading cause of death” in the United States. Nearly a quarter of us have already been infected—one in three of us by the time we hit our fifties. Although we may then be stuck with this thing in our brain for life, our immune system is so good at keeping it at bay, for most healthy people it’s never able to rear its ugly head—or at least overtly: “studies have now revealed associations between [toxoplasma infection] and the presence of various psychiatric disorders in humans”—schizophrenia, bipolar, suicide, self-harm, and memory impairment when we get older. How can a tiny parasite alter our very behavior?
I talked about how the rabies virus hangs out in the saliva, while specifically targeting the emotion center of the brain to drive animals into a fury, so they’ll effectively do the virus’s bidding to bite others to transmit the virus; or the famous zombie-ant brain fungus that takes over the animal completely. These are examples of so-called parasitic manipulation, where the parasite manipulates the host to “[enhance] its own transmission by altering host behavior.” And toxoplasma is “perhaps one of the most convincing examples of a manipulative parasite of [higher animals, like us].”
Since the parasite thrives in cats, “chronically infected rodents no longer respond to cat odour with fear and indeed the physical response is reversed to attraction.” Mice become attracted to the smell of cats, serving the parasite up on a silver platter. The parasite manipulates the rodent’s brain to turn “their innate aversion to cats into a ‘suicidal’ ‘fatal feline attraction.’” Mice become attracted to cat pee, and such fatal feline attraction appears specific towards cats. They don’t become attracted to pee in general. They remain indifferent to rabbit pee, and continue to be turned off by other predator pee. So, on one hand, the parasitic manipulation appears incredibly specific, but the parasite doesn’t just want the mouse to seek out the cat, but get eaten as well. And so, there are these general effects too: impaired motor function, slower response times, “memory, and co-ordination.” And so, when the cat pounces, the parasite tries to make sure the mouse doesn’t get away. It’s like when California sea otters get toxoplasma, they’re more likely to get eaten by a shark. It’s not that the parasite wants to get into the shark—it may just be a by-product of the kind of general cognitive deficits that is so helpful for the parasite in other contexts.
It’s like when humans get toxoplasma, we start liking the smell of cat pee more, too. Isn’t that wacky? The parasite knows just what strings to pull. But it’s the more general effects we’re concerned about. We don’t need to worry our newfound appreciation for saber-tooth tiger urine is going to get us eaten, but mucking with our reaction times, that could be a problem. That could be why multiple studies have shown more traffic and worksite accidents among those that are chronically infected. But it may not just be our slowed reaction time. The parasite appears to also affect “subtle behavioural alterations,” like personality alterations that make us more likely to take risks. Great for the parasite in the cat-and-mouse game, but not so much if we’re driving a car, or wondering whether or not to take that next drink. Maybe one reason people with this brain parasite get into so many car accidents is that it may make people engage in riskier behaviors, like excessive alcohol consumption.
We typically think of malaria as being humanity’s greatest killer parasite. “However, when we take into account the hundreds of thousands of deaths that occur due to the increased probability of traffic accidents, working accidents, suicides, and possibly also other side effects of the infection,” maybe this supposed “’asymptomatic’ latent toxoplasma infection [that has infested one in four Americans] could easily take malaria down [a notch].” Before I get into how to prevent and treat the darn thing, what might these other side effects be?
How exactly does toxoplasma manipulate behavior? Well, one clue we got decades ago is the rise in dopamine levels in the brain. You can show it right in a petri dish of infected brain tissue. Turns out that these parasites actually have an enzyme to make dopamine from scratch, which they then release into the surrounding brain tissue. Why do we care? Because elevated dopamine is a characteristic of schizophrenia. That’s how nearly all modern antipsychotic drugs work, by trying to bring dopamine levels back down—”either inhibit[ing] dopamine receptors or decreas[ing] the level of dopamine in the brain.”
Is it “possible that the increased dopamine accumulation and release observed during [toxoplasma] infection” might increase the risk of schizophrenia? Well, that should be easy to figure out. I mean, do schizophrenics have an increased prevalence of infection? “The increased prevalence of toxoplasmosis in schizophrenics [has been] demonstrated by at least 50 studies.”
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- Jones JL, Kruszon-moran D, Wilson M, Mcquillan G, Navin T, Mcauley JB. Toxoplasma gondii infection in the United States: seroprevalence and risk factors. Am J Epidemiol. 2001;154(4):357-65.
- Jones JL, Parise ME, Fiore AE. Neglected parasitic infections in the United States: toxoplasmosis. Am J Trop Med Hyg. 2014;90(5):794-9.
- Guo M, Mishra A, Buchanan RL, et al. Development of Dose-Response Models to Predict the Relationship for Human Toxoplasma gondii Infection Associated with Meat Consumption. Risk Anal. 2016;36(5):926-38.
- Tedford E, Mcconkey G. Neurophysiological Changes Induced by Chronic Toxoplasma gondii Infection. Pathogens. 2017;6(2).
- Flegr J. How and why Toxoplasma makes us crazy. Trends Parasitol. 2013;29(4):156-63.
- Jackson AC. Diabolical effects of rabies encephalitis. J Neurovirol. 2016;22(1):8-13.
- Evans HC, Elliot SL, Hughes DP. Hidden diversity behind the zombie-ant fungus Ophiocordyceps unilateralis: four new species described from carpenter ants in Minas Gerais, Brazil. PLoS ONE. 2011;6(3):e17024.
- Thomas F, Adamo S, Moore J. Parasitic manipulation: where are we and where should we go?. Behav Processes. 2005;68(3):185-99.
- Webster JP, Kaushik M, Bristow GC, Mcconkey GA. Toxoplasma gondii infection, from predation to schizophrenia: can animal behaviour help us understand human behaviour?. J Exp Biol. 2013;216(Pt 1):99-112.
- Samojłowicz D, Borowska-solonynko A, Kruczyk M. New, previously unreported correlations between latent Toxoplasma gondii infection and excessive ethanol consumption. Forensic Sci Int. 2017;280:49-54.
- Prandovszky E, Gaskell E, Martin H, Dubey JP, Webster JP, Mcconkey GA. The neurotropic parasite Toxoplasma gondii increases dopamine metabolism. PLoS ONE. 2011;6(9):e23866.
Image credit: CDC/Dr. L.L. Moore, Jr. via publicdomainfiles. Image has been modified.
Motion graphics by Avocado Video
Below is an approximation of this video’s audio content. To see any graphs, charts, graphics, images, and quotes to which Dr. Greger may be referring, watch the above video.
Of all foodborne diseases, a brain parasite called toxoplasma is “ranked as the fourth leading cause of hospitalization and the second leading cause of death” in the United States. Nearly a quarter of us have already been infected—one in three of us by the time we hit our fifties. Although we may then be stuck with this thing in our brain for life, our immune system is so good at keeping it at bay, for most healthy people it’s never able to rear its ugly head—or at least overtly: “studies have now revealed associations between [toxoplasma infection] and the presence of various psychiatric disorders in humans”—schizophrenia, bipolar, suicide, self-harm, and memory impairment when we get older. How can a tiny parasite alter our very behavior?
I talked about how the rabies virus hangs out in the saliva, while specifically targeting the emotion center of the brain to drive animals into a fury, so they’ll effectively do the virus’s bidding to bite others to transmit the virus; or the famous zombie-ant brain fungus that takes over the animal completely. These are examples of so-called parasitic manipulation, where the parasite manipulates the host to “[enhance] its own transmission by altering host behavior.” And toxoplasma is “perhaps one of the most convincing examples of a manipulative parasite of [higher animals, like us].”
Since the parasite thrives in cats, “chronically infected rodents no longer respond to cat odour with fear and indeed the physical response is reversed to attraction.” Mice become attracted to the smell of cats, serving the parasite up on a silver platter. The parasite manipulates the rodent’s brain to turn “their innate aversion to cats into a ‘suicidal’ ‘fatal feline attraction.’” Mice become attracted to cat pee, and such fatal feline attraction appears specific towards cats. They don’t become attracted to pee in general. They remain indifferent to rabbit pee, and continue to be turned off by other predator pee. So, on one hand, the parasitic manipulation appears incredibly specific, but the parasite doesn’t just want the mouse to seek out the cat, but get eaten as well. And so, there are these general effects too: impaired motor function, slower response times, “memory, and co-ordination.” And so, when the cat pounces, the parasite tries to make sure the mouse doesn’t get away. It’s like when California sea otters get toxoplasma, they’re more likely to get eaten by a shark. It’s not that the parasite wants to get into the shark—it may just be a by-product of the kind of general cognitive deficits that is so helpful for the parasite in other contexts.
It’s like when humans get toxoplasma, we start liking the smell of cat pee more, too. Isn’t that wacky? The parasite knows just what strings to pull. But it’s the more general effects we’re concerned about. We don’t need to worry our newfound appreciation for saber-tooth tiger urine is going to get us eaten, but mucking with our reaction times, that could be a problem. That could be why multiple studies have shown more traffic and worksite accidents among those that are chronically infected. But it may not just be our slowed reaction time. The parasite appears to also affect “subtle behavioural alterations,” like personality alterations that make us more likely to take risks. Great for the parasite in the cat-and-mouse game, but not so much if we’re driving a car, or wondering whether or not to take that next drink. Maybe one reason people with this brain parasite get into so many car accidents is that it may make people engage in riskier behaviors, like excessive alcohol consumption.
We typically think of malaria as being humanity’s greatest killer parasite. “However, when we take into account the hundreds of thousands of deaths that occur due to the increased probability of traffic accidents, working accidents, suicides, and possibly also other side effects of the infection,” maybe this supposed “’asymptomatic’ latent toxoplasma infection [that has infested one in four Americans] could easily take malaria down [a notch].” Before I get into how to prevent and treat the darn thing, what might these other side effects be?
How exactly does toxoplasma manipulate behavior? Well, one clue we got decades ago is the rise in dopamine levels in the brain. You can show it right in a petri dish of infected brain tissue. Turns out that these parasites actually have an enzyme to make dopamine from scratch, which they then release into the surrounding brain tissue. Why do we care? Because elevated dopamine is a characteristic of schizophrenia. That’s how nearly all modern antipsychotic drugs work, by trying to bring dopamine levels back down—”either inhibit[ing] dopamine receptors or decreas[ing] the level of dopamine in the brain.”
Is it “possible that the increased dopamine accumulation and release observed during [toxoplasma] infection” might increase the risk of schizophrenia? Well, that should be easy to figure out. I mean, do schizophrenics have an increased prevalence of infection? “The increased prevalence of toxoplasmosis in schizophrenics [has been] demonstrated by at least 50 studies.”
Please consider volunteering to help out on the site.
- Jones JL, Kruszon-moran D, Wilson M, Mcquillan G, Navin T, Mcauley JB. Toxoplasma gondii infection in the United States: seroprevalence and risk factors. Am J Epidemiol. 2001;154(4):357-65.
- Jones JL, Parise ME, Fiore AE. Neglected parasitic infections in the United States: toxoplasmosis. Am J Trop Med Hyg. 2014;90(5):794-9.
- Guo M, Mishra A, Buchanan RL, et al. Development of Dose-Response Models to Predict the Relationship for Human Toxoplasma gondii Infection Associated with Meat Consumption. Risk Anal. 2016;36(5):926-38.
- Tedford E, Mcconkey G. Neurophysiological Changes Induced by Chronic Toxoplasma gondii Infection. Pathogens. 2017;6(2).
- Flegr J. How and why Toxoplasma makes us crazy. Trends Parasitol. 2013;29(4):156-63.
- Jackson AC. Diabolical effects of rabies encephalitis. J Neurovirol. 2016;22(1):8-13.
- Evans HC, Elliot SL, Hughes DP. Hidden diversity behind the zombie-ant fungus Ophiocordyceps unilateralis: four new species described from carpenter ants in Minas Gerais, Brazil. PLoS ONE. 2011;6(3):e17024.
- Thomas F, Adamo S, Moore J. Parasitic manipulation: where are we and where should we go?. Behav Processes. 2005;68(3):185-99.
- Webster JP, Kaushik M, Bristow GC, Mcconkey GA. Toxoplasma gondii infection, from predation to schizophrenia: can animal behaviour help us understand human behaviour?. J Exp Biol. 2013;216(Pt 1):99-112.
- Samojłowicz D, Borowska-solonynko A, Kruczyk M. New, previously unreported correlations between latent Toxoplasma gondii infection and excessive ethanol consumption. Forensic Sci Int. 2017;280:49-54.
- Prandovszky E, Gaskell E, Martin H, Dubey JP, Webster JP, Mcconkey GA. The neurotropic parasite Toxoplasma gondii increases dopamine metabolism. PLoS ONE. 2011;6(9):e23866.
Image credit: CDC/Dr. L.L. Moore, Jr. via publicdomainfiles. Image has been modified.
Motion graphics by Avocado Video
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Long-Term Effects of Toxoplasmosis Brain Infection
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And remember, chronic infection is not rare—nearly one in four American adults and adolescents are already infected. If that surprises you, you may have missed the first video of this four-part series. Check out Toxoplasmosis: A Manipulative Foodborne Brain Parasite and stay tuned for Does Toxoplasmosis Cause Schizophrenia? and How to Prevent Toxoplasmosis.
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