I am a pulmonary immunologist with over 20 years of experience in studies of inflammatory/infectious diseases in the lungs and at the systemic level. Sixteen of those years, I have worked at the Ann Arbor VAHS. My overall career goal is to expand the understanding of host pathogen interactions, specifically the effect of microbe- and host-derived signals on the fate of the immune response. I deeply believe that an understanding of these interactions will create a foundation for the development of safe and effective immunomodulatory therapies that will greatly enhance the effectiveness of antimicrobial therapeutics in persistent infections. Our lab has specialized in animal modeling and translational studies applying these principles, which are highly relevant to broader range of diseases as shown by more recent clinical data. Over the last 15 years, my studies have mostly focused on host pathogen interactions between invasive fungus C. neoformans and the mammalian immune system. The studies of invasive fungal infections are of specific interest to the VA, because of the higher than average rate of immunocompromised patients among veterans and increased risk of exposure to various endemic and environmental fungi due to locations and conditions of military service that favor fungal exposures. Unfortunately, the invasive fungal infections have unacceptably high mortality rates, due to limited effectiveness of antifungal drugs, toxicity, and the high potential of fungal organisms to develop resistance to these drugs. Thus, it is crucial to understand the effects of immunomodulation on fungal disease from the perspective of the natural mechanisms of host defenses, mechanisms of immune evasion exhibited by fungi, and to explore pre-clinical approaches of immuno-modulatory therapies. The long-standing support of VA BLR&D was one of the crucial factors that allowed our group to establish itself among leaders in cryptococcal and fungal immunology. While this support has led to many important findings, there is still a lot more that we need to learn before we can safely and efficiently apply immunomodulatory therapies in persistent infections. The VA RCS Award will allow our group to continue this great work and create stability supportive of exploration of very novel but more risky directions of research. This award will also allow to further broaden PI?s collaborative interactions with physician scientists, enhance training efforts, and to continue PI?s service to the scientific community at the VA and beyond.

Public Health Relevance

Fungal and bacterial infections are a major source of morbidity and mortality in veterans with compromised immune systems as a result of AIDS, substance abuse, or stemming from treatment of malignancy, auto-immune disease, or organ transplantation. Persistent microbial lung infections in immunocompetent or mildly immunocompromised veterans results in chronic lung disease. Antibiotic therapies are often inadequate; thus enhanced knowledge of pulmonary host defense is essential for the development of new therapies or vaccine strategies to treat these patient populations. Strategies designed to diminish or enhance immunomodulatory pathways hold the greatest promise for enhancing therapies of persistent infections, malignancy, allergies, autoimmune disease, or organ transplants. Dr. Olszewski?s studies identify and test the role of immunological pathways during infections. His studies also dissect interactions of microbial factors with host defenses to identify mechanisms of their evasion and potential therapeutic targets within microbes. These studies are an essential step in design of new therapies strategies against infections.

Agency
National Institute of Health (NIH)
Institute
Veterans Affairs (VA)
Project #
5IK6BX003615-05
Application #
10046729
Study Section
Research Career Scientist (RCSR)
Project Start
2016-10-01
Project End
2021-09-30
Budget Start
2020-10-01
Budget End
2021-09-30
Support Year
5
Fiscal Year
2021
Total Cost
Indirect Cost
Name
Veterans Health Administration
Department
Type
DUNS #
096318480
City
Ann Arbor
State
MI
Country
United States
Zip Code
48105
So, Yee-Seul; Jang, Juyeong; Park, Goun et al. (2018) Sho1 and Msb2 Play Complementary but Distinct Roles in Stress Responses, Sexual Differentiation, and Pathogenicity of Cryptococcus neoformans. Front Microbiol 9:2958
Wang, Shiwen; Yang, Feng; Li, Dong et al. (2018) Clinical application of a multiplex genetic pathogen detection system remaps the aetiology of diarrhoeal infections in Shanghai. Gut Pathog 10:37
Neal, Lori M; Xing, Enze; Xu, Jintao et al. (2017) CD4+ T Cells Orchestrate Lethal Immune Pathology despite Fungal Clearance during Cryptococcus neoformans Meningoencephalitis. MBio 8:
Xu, Jintao; Flaczyk, Adam; Neal, Lori M et al. (2017) Scavenger Receptor MARCO Orchestrates Early Defenses and Contributes to Fungal Containment during Cryptococcal Infection. J Immunol 198:3548-3557
Roussey, Jonathan A; Viglianti, Steven P; Teitz-Tennenbaum, Seagal et al. (2017) Anti-PD-1 Antibody Treatment Promotes Clearance of Persistent Cryptococcal Lung Infection in Mice. J Immunol 199:3535-3546
Fa, Zhenzong; Xie, Qun; Fang, Wei et al. (2017) RIPK3/Fas-Associated Death Domain Axis Regulates Pulmonary Immunopathology to Cryptococcal Infection Independent of Necroptosis. Front Immunol 8:1055
Xu, Jintao; Flaczyk, Adam; Neal, Lori M et al. (2017) Exploitation of Scavenger Receptor, Macrophage Receptor with Collagenous Structure, by Cryptococcus neoformans Promotes Alternative Activation of Pulmonary Lymph Node CD11b+ Conventional Dendritic Cells and Non-Protective Th2 Bias. Front Immunol 8:1231
Neal, Lori M; Qiu, Yafeng; Chung, Jooho et al. (2017) T Cell-Restricted Notch Signaling Contributes to Pulmonary Th1 and Th2 Immunity during Cryptococcus neoformans Infection. J Immunol 199:643-655
Malachowski, Antoni N; Yosri, Mohamed; Park, Goun et al. (2016) Systemic Approach to Virulence Gene Network Analysis for Gaining New Insight into Cryptococcal Virulence. Front Microbiol 7:1652
Hu, Binjie; Zhao, Fuju; Wang, Shiwen et al. (2016) A high-throughput multiplex genetic detection system for Helicobacter pylori identification, virulence and resistance analysis. Future Microbiol 11:1261-1278

Showing the most recent 10 out of 11 publications