HomeCancer ResearchTokeOni: Properties and Applications

TokeOni: Properties and Applications

Takahiro Kuchimaru, Shinae Kizaka-Kondoh

Graduate School of Bioengineering & Biotechnology, Tokyo Institute of Technology, Yokohama, Japan.


Bioluminescence imaging (BLI) systems allow for high-sensitive and noninvasive monitoring of cell proliferation, activity of signaling pathways and protein-protein interactions in living tissues.1-3 In this decade, BLI has extended its applications to a broad range of biomedical research. However, one bottleneck of the current BLI system is that the standard combination of firefly luciferase (Fluc) and its natural substrate D-luciferin emits a relatively short wavelength of bioluminescence (λmax = 560 nm) which is highly absorbed and scattered by biological tissues.4,5 To overcome this, a BLI system that utilizes near-infrared (NIR) bioluminescence has been desired.

TokeOni (Product No. 808350) is a first-time practical substrate that achieves 1) good chemical stability, 2) high water solubility and 3) robust emission of NIR-bioluminescence (λmax = 677 nm) with native Fluc. TokeOni is immediately compatible with current BLI systems using native Fluc and provides superior detection sensitivity of targets particularly in deep living tissues6.

High-sensitive imaging of deep tissues using TokeOni

TokeOni is dissolved in sterile water (not buffer solution) up to 40 mM of concentration and stored in -80 oC (< 3 months). TokeOni emits NIR-bioluminescence in reaction with native Fluc in the presence of ATP-Mg (Figure 1).

Chemical structure and bioluminescence spectrum of TokeOni

Figure 1.Chemical structure and bioluminescence spectrum of TokeOni (Product No. 808350) and D-luciferin with native Fluc proteins.

To exemplify the performance of TokeOni in vivo, detection sensitivity of bone metastasis was compared for D-luciferin with TokeOni. SCID mice were intra-arterially injected with human prostate cancer PC-3 stably expressing firefly luciferase (PC-3/luc) to form bone metastasis. 100 uL of the 33 mM substrate (〜50 mg/body) was intraperitoneally injected into the same mice with a 4-hour interval and bioluminescence images were acquired using IVIS-Spectrum (PerkinElmer). TokeOni greatly enhanced the signals emanating from metastatic lesions in the hindlimb and iliac bones, demonstrated by a 5.2-fold increase in the photon flux observed with TokeOni over D-luciferin (Figure 2).

High-sensitive in vivo imaging of bone metastasis using TokeOni

Figure 2.High-sensitive in vivo imaging of bone metastasis using TokeOni. Representative bioluminescence images obtained at 10 min after injecting the substrates (left panel) and quantitative analysis of bioluminescence intensity from hind limbs (right panel). TokeOni was injected into the same mice 4 hours after injecting D-luciferin. Error bars are standard error of the mean. n=6, *p<0.05.

TokeOni typically displays a peak bioluminescence production at a relatively early time point after the intraperitoneal injection compared to D-luciferin. Therefore, a peak-time bioluminescence production after i.p. injection of TokeOni will be found in the mouse model before performing in vivo imaging. In addition, the NIR-bioluminescence sensitivity to the luminometer has been enhanced when performing in vitro tube assays with TokeOni since typical luminometers for in vitro assays are less sensitive to the NIR light compared to the visible one.


TokeOni is one of the best options to observe fewer cells which could not be detected in deep tissue using D-luciferin. Improved detection sensitivity of TokeOni would allow for more accurate quantitative-detection of targets in vivo.



Rehemtulla A, Stegman LD, Cardozo SJ, Gupta S, Hall DE, Contag CH, Ross BD. 2000. Rapid and Quantitative Assessment of Cancer Treatment Response Using In Vivo Bioluminescence Imaging. Neoplasia. 2(6):491-495.
Luker KE, Smith MCP, Luker GD, Gammon ST, Piwnica-Worms H, Piwnica-Worms D. 2004. Kinetics of regulated protein-protein interactions revealed with firefly luciferase complementation imaging in cells and living animals. Proceedings of the National Academy of Sciences. 101(33):12288-12293.
Kuchimaru T, Hoshino T, Aikawa T, Yasuda H, Kobayashi T, Kadonosono T, Kizaka-Kondoh S. 2014. Bone resorption facilitates osteoblastic bone metastatic colonization by cooperation of insulin-like growth factor and hypoxia. Cancer Sci. 105(5):553-559.
Dawson JB, Barker DJ, Ellis DJ, Cotterill JA, Grassam E, Fisher GW, Feather JW. 1980. A theoretical and experimental study of light absorption and scattering by in vivo skin. Phys. Med. Biol.. 25(4):695-709.
Weissleder R, Ntziachristos V. 2003. Shedding light onto live molecular targets. Nat Med. 9(1):123-128.
Kuchimaru T, Iwano S, Kiyama M, Mitsumata S, Kadonosono T, Niwa H, Maki S, Kizaka-Kondoh S. 2016. A luciferin analogue generating near-infrared bioluminescence achieves highly sensitive deep-tissue imaging. Nat Commun. 7(1):
Single-cell bioluminescence imaging of deep tissue in freely moving animals. [Internet]. Available from:
Martin RM, Fowler JL, Cromer MK, Lesch BJ, Ponce E, Uchida N, Nishimura T, Porteus MH, Loh KM. 2020. Improving the safety of human pluripotent stem cell therapies using genome-edited orthogonal safeguards. Nat Commun. 11(1):
Fukuchi M, Saito R, Maki S, Hagiwara N, Nakajima Y, Mitazaki S, Izumi H, Mori H. 2020. Visualization of activity-regulated BDNF expression in the living mouse brain using non-invasive near-infrared bioluminescence imaging. Mol Brain. 13(1):
Saito-Moriya R, Nakayama J, Kamiya G, Kitada N, Obata R, Maki SA, Aoyama H. How to Select Firefly Luciferin Analogues for In Vivo Imaging. IJMS. 22(4):1848.
Ogawa H, Ono R, Noguchi Y, Kitada N, Saito?Moriya R, Maki SA, Akiyama H, Itabashi H, Hiyama M. 2021. Absorption Spectra for Firefly Bioluminescence Substrate Analog: TokeOni in Various pH Solutions. Photochem Photobiol. 97(5):1016-1022.