PET imaging of TSPO expression in immune cells can assess organ-level pathophysiology in high-consequence viral infections.
Swati ShahSanhita SinharayReema PatelJeffrey SolomonJi Hyun LeeWilliam Schreiber-StainthorpFalguni BasuliXiang ZhangKatie R HagenRebecca ReederPaul G WakimLouis M HuzellaDragan MaricReed F JohnsonDima A HammoudPublished in: Proceedings of the National Academy of Sciences of the United States of America (2022)
Ebola virus (EBOV) disease is characterized by lymphopenia, breach in vascular integrity, cytokine storm, and multiorgan failure. The pathophysiology of organ involvement, however, is incompletely understood. Using [18F]-DPA-714 positron emission tomography (PET) imaging targeting the translocator protein (TSPO), an immune cell marker, we sought to characterize the progression of EBOV-associated organ-level pathophysiology in the EBOV Rhesus macaque model. Dynamic [18F]-DPA-714 PET/computed tomography imaging was performed longitudinally at baseline and at multiple time points after EBOV inoculation, and distribution volumes (Vt) were calculated as a measure of peripheral TSPO binding. Using a mixed-effect linear regression model, spleen and lung Vt decreased, while the bone marrow Vt increased over time after infection. No clear trend was found for liver Vt. Multiple plasma cytokines correlated negatively with lung/spleen Vt and positively with bone marrow Vt. Multiplex immunofluorescence staining in spleen and lung sections confirmed organ-level lymphoid and monocytic loss/apoptosis, thus validating the imaging results. Our findings are consistent with EBOV-induced progressive monocytic and lymphocytic depletion in the spleen, rather than immune activation, as well as depletion of alveolar macrophages in the lungs, with inefficient reactive neutrophilic activation. Increased bone marrow Vt, on the other hand, suggests hematopoietic activation in response to systemic immune cell depletion and leukocytosis and could have prognostic relevance. In vivo PET imaging provided better understanding of organ-level pathophysiology during EBOV infection. A similar approach can be used to delineate the pathophysiology of other systemic infections and to evaluate the effectiveness of newly developed treatment and vaccine strategies.
Keyphrases
- pet imaging
- positron emission tomography
- bone marrow
- computed tomography
- mesenchymal stem cells
- pet ct
- high resolution
- multiple sclerosis
- binding protein
- oxidative stress
- cell death
- magnetic resonance imaging
- endoplasmic reticulum stress
- diabetic rats
- amino acid
- photodynamic therapy
- combination therapy
- single cell
- dual energy
- signaling pathway
- transcription factor
- cell cycle arrest