In vivo tracking of Th1 cells by PET reveals quantitative and temporal distribution and specific homing in lymphatic tissue

CM Griessinger, R Kehlbach, D Bukala… - Journal of Nuclear …, 2014 - Soc Nuclear Med
CM Griessinger, R Kehlbach, D Bukala, S Wiehr, R Bantleon, F Cay, A Schmid…
Journal of Nuclear Medicine, 2014Soc Nuclear Med
Although T cells can be labeled for noninvasive in vivo imaging, little is known about the
impact of such labeling on T-cell function, and most imaging methods do not provide holistic
information about trafficking kinetics, homing sites, or quantification. Methods: We developed
protocols that minimize the inhibitory effects of 64Cu-pyruvaldehyde-bis (N 4-
methylthiosemicarbazone)(64Cu-PTSM) labeling on T-cell function and permit the homing
patterns of T cells to be followed by PET. Thus, we labeled ovalbumin (OVA) T-cell receptor …
Although T cells can be labeled for noninvasive in vivo imaging, little is known about the impact of such labeling on T-cell function, and most imaging methods do not provide holistic information about trafficking kinetics, homing sites, or quantification.
Methods
We developed protocols that minimize the inhibitory effects of 64Cu-pyruvaldehyde-bis(N4-methylthiosemicarbazone) (64Cu-PTSM) labeling on T-cell function and permit the homing patterns of T cells to be followed by PET. Thus, we labeled ovalbumin (OVA) T-cell receptor transgenic interferon (IFN)-γ–producing CD4+ T (Th1) cells with 0.7–2.2 MBq of 64Cu-PTSM and analyzed cell viability, IFN-γ production, proliferation, apoptosis, and DNA double-strand breaks and identified intracellular 64Cu accumulation sites by energy dispersive x-ray analysis. To elucidate the fate of Th1 cell homing by PET, 107 64Cu-OVA-Th1 cells were injected intraperitoneally or intravenously into healthy mice. To test the functional capacities of 64Cu-OVA-Th1 cells during experimental OVA-induced airway hyperreactivity, we injected 107 64Cu-OVA-Th1 cells intraperitoneally into OVA-immunized or nonimmunized healthy mice, which were challenged with OVA peptide or phosphate-buffered saline or remained untreated. In vivo PET investigations were followed by biodistribution, autoradiography, and fluorescence-activated cell sorting analysis.
Results
PET revealed unexpected homing patterns depending on the mode of T-cell administration. Within 20 min after intraperitoneal administration, 64Cu-OVA-Th1 cells homed to the perithymic lymph nodes (LNs) of naive mice. Interestingly, intravenously administered 64Cu-OVA-Th1 cells homed predominantly into the lung and spleen but not into the perithymic LNs. The accumulation of 64Cu-OVA-Th1 cells in the pulmonary LNs (6.8 ± 1.1 percentage injected dose per cubic centimeter [%ID/cm3]) 24 h after injection was highest in the OVA-immunized and OVA-challenged OVA airway hyperreactivity–diseased littermates 24 h after intraperitoneal administration and lowest in the untreated littermates (3.7 ± 0.4 %ID/cm3). As expected, 64Cu-OVA-Th1 cells also accumulated significantly in the pulmonary LNs of nonimmunized OVA-challenged animals (6.1 ± 0.5 %ID/cm3) when compared with phosphate-buffered saline–challenged animals (4.6 ± 0.5 %ID/cm3).
Conclusion
Our protocol permits the detection of Th1 cells in single LNs and enables temporal in vivo monitoring of T-cell homing over 48 h. This work enables future applications for 64Cu-PTSM–labeled T cells in clinical trials and novel therapy concepts focusing on T-cell–based immunotherapies of autoimmune diseases or cancer.
Society of Nuclear Medicine and Molecular Imaging