Murine models of Pneumocystis infection recapitulate human primary immune disorders
Waleed Elsegeiny, … , Kong Chen, Jay K. Kolls
Waleed Elsegeiny, … , Kong Chen, Jay K. Kolls
Published June 21, 2018
Citation Information: JCI Insight. 2018;3(12):e91894. https://doi.org/10.1172/jci.insight.91894.
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Research Article Immunology Infectious disease

Murine models of Pneumocystis infection recapitulate human primary immune disorders

Abstract

Despite the discovery of key pattern recognition receptors and CD4+ T cell subsets in laboratory mice, there is ongoing discussion of the value of murine models to reflect human disease. Pneumocystis is an AIDS-defining illness, in which risk of infection is inversely correlated with peripheral CD4+ T cell counts. Due to medical advances in the control of HIV, the current epidemiology of Pneumocystis infection is predominantly due to primary human immunodeficiencies and immunosuppressive therapies. To this end, we found that every human genetic immunodeficiency associated with Pneumocystis infection that has been tested in mice recapitulated susceptibility. For example, humans with a loss-of-function IL21R mutation are severely immunocompromised. We found that IL-21R, in addition to CD4+ T cell intrinsic STAT3 signaling, were required for generating protective antifungal class-switched antibody responses, as well as effector T cell–mediated protection. Furthermore, CD4+ T cell intrinsic IL-21R/STAT3 signaling was required for CD4+ T cell effector responses, including IL-22 production. Recombinant IL-22 administration to Il21r–/– mice induced the expression of a fungicidal peptide, cathelicidin antimicrobial peptide, which showed in vitro fungicidal activity. In conclusion, SPF laboratory mice faithfully replicate many aspects of human primary immunodeficiency and provide useful tools to understand the generation and nature of effector CD4+ T cell immunity.

Authors

Waleed Elsegeiny, Mingquan Zheng, Taylor Eddens, Richard L. Gallo, Guixiang Dai, Giraldina Trevejo-Nunez, Patricia Castillo, Kara Kracinovsky, Hillary Cleveland, William Horne, Jonathan Franks, Derek Pociask, Mark Pilarski, John F. Alcorn, Kong Chen, Jay K. Kolls

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Figure 3

IL-22–FC treatment is protective in Il21r–/– mice.

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IL-22–FC treatment is protective in Il21r–/– mice. (A) Histology slides ...
(A) Histology slides of lung tissue from WT naive and P. murina–infected mice were stained for IL-22RA by IHC. IL-21R–deficient and CD4-depleted WT mice were infected with P. murina for 2 weeks prior to 2 weeks of biweekly treatment of IL-22–FC (n = 4). (B) Schematic timeline of IL-22–FC treatment model. Real-time PCR of whole lung RNA for (C) P. murina mitochondrial ribosomal RNA large subunit, (D) Sp, and (E) Arp was performed to assess degree of Pneumocystis burden. (F) Schematic timeline of the short-term IL-22–FC treatment model where IL-21R–deficient mice received a single dose of IL-22–FC at the 2 week mark of infection (n = 3). (G) Representative transmission electron microscopy images of pneumocyte/trophozoite interaction. (H) Quantification of percent trophozoite perimeter bound to murine pneumocytes. (I) Whole lung RNA was isolated, sequenced using an Illumina NextSeq 500, and analyzed for differential expression of genes associated with antimicrobial responses (n = 3). P. murina was cultured in vitro with 10 or 50 μg/ml concentrations of LL-37 protein. RNA from in vitro incubation with LL-37 was used to perform Real-time PCR on (J) P. murina mitochondrial ribosomal RNA small subunit, (K) Arp, and Sp and normalized to input expression. Values are represented as means ± SEM. A–E, J, and K are representative of 2 experiments. G–I were performed once. P values are annotated as follows: *P ≤0.05, **P ≤0.01, and ****P ≤0.0001 (1-way ANOVA).