Complement‐dependent loss of inhibitory synapses on pyramidal neurons following <i>Toxoplasma gondii</i> infection

Carrillo, Gabriela L.; Su, Jianmin; Cawley, Mikel Leann; Wei, Derek; Gill, Simran K.; Blader, Ira J.; Fox, Michael A.

doi:10.1111/jnc.15770

Cited by 6 publications

(3 citation statements)

References 110 publications

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“…The viral marker, CMV IgG, was correlated with plasma C4 only in controls, suggesting that in schizophrenia, this linear relationship is disrupted, as similar to our observations of C4A copy number correlations with plasma C4 only in controls. More in-depth mechanistic studies are certainly required, but one explanation may be that these pathogens evade host immune systems in different ways, such as through complement regulation and inactivation [87][88][89].…”

Section: Discussionmentioning

confidence: 99%

Prospects and Pitfalls of Plasma Complement C4 in Schizophrenia: Building a Better Biomarker

Severance,

Prandovszky,

Yang

et al. 2023

Dev Neurosci

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Complex brain disorders like schizophrenia may have multifactorial origins related to mis-timed heritable and environmental factors interacting during neurodevelopment. Infections, inflammation, and autoimmune diseases are over-represented in schizophrenia leading to immune system-centered hypotheses. Complement component C4 is genetically and neurobiologically associated with schizophrenia, and its dual activity peripherally and in the brain makes it an exceptional target for biomarker development. Studies to evaluate the biomarker potential of plasma or serum C4 in schizophrenia do so to understand how peripheral C4 might reflect central nervous system (CNS)-derived neuroinflammation, synapse pruning and other mechanisms. This effort, however, has produced mostly conflicting results, with peripheral C4 sometimes elevated, reduced or unchanged between comparison groups. We undertook a pilot biomarker development study to systematically identify sociodemographic, genetic, and immune-related variables (autoimmune, infection-related, gastrointestinal (GI), inflammatory), which may be associated with plasma C4 levels in schizophrenia (SCH; n=335) and/or in non-psychiatric comparison subjects (NCs; n=233). As with previously inconclusive studies, we detected no differences in plasma C4 levels between SCH and NCs. In contrast, levels of general inflammation, C-Reactive Protein (CRP), were significantly elevated in SCH compared to NCs (ANOVA, F=20.74, p<0.0001), suggestive that plasma C4 and CRP may reflect different sources or causes of inflammation. In multivariate regressions of C4 gene copy number variants (CNVs), plasma C4 levels were correlated only for C4A (not C4B, C4L, C4S) and only in NCs (R Coeff=0.39, CI=0.01-0.77, R2=0.18, p<0.01; not SCH). Other variables associated with plasma C4 levels only in NCs included sex, double-stranded DNA (dsDNA) IgG, tissue-transglutaminase (TTG) IgG, and cytomegalovirus (CMV) IgG. Toxoplasma gondii IgG was the only variable significantly correlated with plasma C4 in SCH but not in NCs. Many variables were associated with plasma C4 in both groups (body mass index (BMI), race, CRP, N-methyl-D-aspartate receptor (NMDAR) NR2 subunit IgG, TTG IgA, lipopolysaccharide (LPS)-binding protein (LBP), and soluble CD14 (sCD14). While the direction of most C4 associations was positive, autoimmune markers tended to be inverse, and associated with reduced plasma C4 levels. When NMDAR NR2 autoantibody-positive individuals were removed, plasma C4 was elevated in SCH versus NCs (ANOVA, F=5.16, p<0.02). Our study was exploratory and confirmation of the many variables associated with peripheral C4 require replication. Our preliminary results point toward autoimmune factors and exposure to the pathogen, T. gondii, as possibly significant contributors to variability of total C4 protein levels in plasma of individuals with schizophrenia.

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Section: Discussionmentioning

confidence: 99%

Prospects and Pitfalls of Plasma Complement C4 in Schizophrenia: Building a Better Biomarker

Severance,

Prandovszky,

Yang

et al. 2023

Dev Neurosci

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“…A link between neurotropic toxoplasmosis and neuroinflammatory and neurodegenerative conditions, such as Alzheimer’s disease (AD) has been proposed (Nimgaonkar et al, 2016; Nayeri Chegeni et al, 2019; Tyebji et al, 2019; Yang et al, 2021). More recently, more mechanistic studies have been able to link CNS Toxoplasma infection with several correlates of AD pathology - disruption of the BBB, glial activation and synapse loss, inter alia (Li et al, 2019; Ortiz-Guerrero et al, 2020; Castaño Barrios et al, 2021; Carrillo et al, 2023; Anaya-Martínez et al, 2023). The picture however remains far from conclusive.…”

Section: Discussionmentioning

confidence: 99%

A Parasite Odyssey: An RNA virus concealed inToxoplasma gondii

Gupta,

Hiller,

Chowdhury

et al. 2023

Preprint

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We are in the midst of the "Platinum Age of Virus Discovery", an era characterized by the exponential growth in the discovery of virus biodiversity. In humans (or any animal) there are more viruses than simply those directly infecting the animal cells. Viruses infect all species constituting the microbiome: including bacteria, fungi, and unicellular parasites. Thus the complexity of possible interactions between host, microbe, and viruses is unfathomable. To understand this network we must employ computationally assisted virology as a means of analyzing and interpreting the millions of available samples to decipher the myriad of ways in which viruses may intersect human health. From a global screen for human neuron-associated viruses, we identify a novel narnavirus Achaeavirus odysseus (Ao) which likely infects the neurotropic parasite Toxoplasma gondii. Previously, several parasitic protozoan viruses (PPVs) have been mechanistically established as triggers of host innate responses, and here we present in silico evidence that Ao is a plausible pro-inflammatory factor in mouse and human cells infected by T. gondii. T. gondii infects billions of people worldwide, yet the prognosis of toxoplasmosis disease is highly variable, and PPVs like Ao could function as a hitherto undescribed hypervirulence factor. More broadly, we explore phylogenetically proximal viruses to Ao and discover 18 new species of Achaeavirus, all found in vertebrate transcriptome and metatranscriptomes. While the Narnavirus samples making up this genus-like clade are derived from sheep, goat, bat, rabbit, chicken, and pigeon, the presence of virus is strongly predictive of parasitic (Apicomplexa) nucleic acid co-occurrence, supporting that these are a clade of parasite-infecting viruses. This is a computational proof-of-concept study in which we rapidly analyze millions of datasets from which we distill a mechanistically, ecologically, and phylogenetically refined hypothesis. We predict this highly diverged Ao RNA virus is biologically a T. gondii infection, and that Ao, and other viruses like it, will modulate this disease which afflicts billions worldwide.

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“…Riboprobes against Col19a1 , Gad1 , Syt1 , Syt2 , Vglut1 and Sst mRNAs were generated as described previously ( Su et al, 2010 , 2016 , 2020 ; Carrillo et al, 2023 ), where digoxigenin-labeled NTP (Roche, Basel, Switzerland) and the MAXIscript In Vitro Transcription Kit (Ambion) were used to synthesize riboprobes, which were hydrolyzed to 500 nt. Prior to addition of the riboprobes, tissue sections were prepared for ISH by fixation with 4% paraformaldehyde (PFA) for 10 min, incubation with proteinase K (1 ug/mL proteinase K, 50 mM 7.5 pH Tris, 5 mM EDTA) for 10 min, additional fixation with 4% PFA for 5 min, acetylation (1.33% triethanolamine, 20 mM HCl, 0.25% acetic anhydride) for 10 min, and permeabilization (1% Triton X-100) for 30 min, where each step listed was followed by DEPC-PBS washes.…”

Section: Methodsmentioning

confidence: 99%

Collagen XIX is required for pheromone recognition and glutamatergic synapse formation in mouse accessory olfactory bulb

Amos

Fox

2023

Front. Cell. Neurosci.

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In mammals, the accessory olfactory bulb (AOB) receives input from vomeronasal sensory neurons (VSN) which detect pheromones, chemical cues released by animals to regulate the physiology or behaviors of other animals of the same species. Cytoarchitecturally, cells within the AOB are segregated into a glomerular layer (GL), mitral cell layer (MCL), and granule cell layer (GCL). While the cells and circuitry of these layers has been well studied, the molecular mechanism underlying the assembly of such circuitry in the mouse AOB remains unclear. With the goal of identifying synaptogenic mechanisms in AOB, our attention was drawn to Collagen XIX, a non-fibrillar collagen generated by neurons in the mammalian telencephalon that has previously been shown to regulate the assembly of synapses. Here, we used both a targeted mouse mutant that lacks Collagen XIX globally and a conditional allele allowing for cell-specific deletion of this collagen to test if the loss of Collagen XIX causes impaired synaptogenesis in the mouse AOB. These analyses not only revealed defects in excitatory synapse distribution in these Collagen XIX-deficient mutants, but also showed that these mutant mice exhibit altered behavioral responses to pheromones. Although this collagen has been demonstrated to play synaptogenic roles in the telencephalon, those roles are at perisomatic inhibitory synapses, results here are the first to demonstrate the function of this unconventional collagen in glutamatergic synapse formation.

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Complement‐dependent loss of inhibitory synapses on pyramidal neurons following Toxoplasma gondii infection

Cited by 6 publications

References 110 publications

Prospects and Pitfalls of Plasma Complement C4 in Schizophrenia: Building a Better Biomarker

Prospects and Pitfalls of Plasma Complement C4 in Schizophrenia: Building a Better Biomarker

A Parasite Odyssey: An RNA virus concealed inToxoplasma gondii

Collagen XIX is required for pheromone recognition and glutamatergic synapse formation in mouse accessory olfactory bulb

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