Precision-cut lung slices as an ex vivo model to study Pneumocystis murina survival and antimicrobial susceptibility.

IMPORTANCE: Our study reveals the potential of precision-cut lung slices as an ex vivo platform to study the growth/survival of Pneumocystis spp. that can facilitate the development of new anti-fungal drugs.

Novel Pneumocystis Antigens for Seroprevalence Studies.

Pneumocystis jirovecii is the most common cause of fungal pneumonia in children under the age of 2 years. However, the inability to culture and propagate this organism has hampered the acquisition of a fungal genome as well as the development of recombinant antigens to conduct seroprevalence studies. In this study, we performed proteomics on Pneumocystis-infected mice and used the recent P. murina and P. jirovecii genomes to prioritize antigens for recombinant protein expression. We focused on a fungal glucanase due to its conservation among fungal species. We found evidence of maternal IgG to this antigen, followed by a nadir in pediatric samples between 1 and 3 months of age, followed by an increase in prevalence over time consistent with the known epidemiology of Pneumocystis exposure. Moreover, there was a strong concordance of anti-glucanase responses and IgG against another Pneumocystis antigen, PNEG_01454. Taken together, these antigens may be useful tools for Pneumocystis seroprevalence and seroconversion studies.

Germline IgM predicts T cell immunity to Pneumocystis.

Pneumocystis is the most common fungal pulmonary infection in children under the age of 5 years. In children with primary immunodeficiency, Pneumocystis often presents at 3-6 months of age, a time period that coincides with the nadir of maternal IgG and when IgM is the dominant Ig isotype. Because B cells are the dominant antigen-presenting cells for Pneumocystis, we hypothesized the presence of fungal-specific IgMs in humans and mice and that these IgM specificities would predict T cell antigens. We detected fungal-specific IgMs in human and mouse sera and utilized immunoprecipitation to determine whether any antigens were similar across donors. We then assessed T cell responses to these antigens and found anti-Pneumocystis IgM in WT mice, Aicda-/- mice, and in human cord blood. Immunoprecipitation of Pneumocystis murina with human cord blood identified shared antigens among these donors. Using class II MHC binding prediction, we designed peptides with these antigens and identified robust peptide-specific lung T cell responses after P. murina infection. After mice were immunized with 2 of the antigens, adoptive transfer of vaccine-elicited CD4+ T cells showed effector activity, suggesting that these antigens contain protective Pneumocystis epitopes. These data support the notion that germline-encoded IgM B cell receptors are critical in antigen presentation and T cell priming in early Pneumocystis infection.

Targeted NGS-Based Analysis of Pneumocystis jirovecii Reveals Novel Genotypes.

Pneumocystis jirovecii is an important etiological agent of pneumonia that is underdiagnosed due to the inability to culture the organism. The 2019 PERCH study identified Pneumocystis as the top fungal cause of pneumonia in HIV-negative children using a PCR cutoff of 104 copies of Pneumocystis per mL of sample in nasopharyngeal/oropharyngeal (NP/OP) specimens. Given that Pneumocystis consists of an environmental ascus form and a trophic from (the latter is the form that attaches to the lung epithelium), it is possible that life-form-specific molecular assays may be useful for diagnosis. However, to accomplish this goal, these assays require genotypic information, as the current fungal genomic data are largely from the US and Europe. To genotype Pneumocystis across the globe, we developed an NGS-based genotyping assay focused on genes expressed in asci as well as trophs using PERCH throat swabs from Africa, Bangladesh, and Thailand, as well as North American samples. The NGS panel reliably detected 21 fungal targets in these samples and revealed unique genotypes in genes expressed in trophs, including Meu10, an ascospore assembly gene; two in mitochondrial gene ATP8, and the intergenic region between COX1 and ATP8. This assay can be used for enhanced Pneumocystis epidemiology to study outbreaks but also permits more accurate RT-CPR- or CRISPR-based assays to be performed to improve the non-bronchoscopic diagnosis of this under-reported fungal pathogen.