Longitudinal adaptive optics fluorescence microscopy reveals cellular mosaicism in patients
HaeWon Jung, … , Robert Fariss, Johnny Tam
HaeWon Jung, … , Robert Fariss, Johnny Tam
Published March 21, 2019
Citation Information: JCI Insight. 2019;4(6):e124904. https://doi.org/10.1172/jci.insight.124904.
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Resource and Technical Advance Ophthalmology

Longitudinal adaptive optics fluorescence microscopy reveals cellular mosaicism in patients

Abstract

The heterogeneity of individual cells in a tissue has been well characterized, largely using ex vivo approaches that do not permit longitudinal assessments of the same tissue over long periods of time. We demonstrate a potentially novel application of adaptive optics fluorescence microscopy to visualize and track the in situ mosaicism of retinal pigment epithelial (RPE) cells directly in the human eye. After a short, dynamic period during which RPE cells take up i.v.-administered indocyanine green (ICG) dye, we observed a remarkably stable heterogeneity in the fluorescent pattern that gradually disappeared over a period of days. This pattern could be robustly reproduced with a new injection and follow-up imaging in the same eye out to at least 12 months, which enabled longitudinal tracking of RPE cells. Investigation of ICG uptake in primary human RPE cells and in a mouse model of ICG uptake alongside human imaging corroborated our findings that the observed mosaicism is an intrinsic property of the RPE tissue. We demonstrate a potentially novel application of fluorescence microscopy to detect subclinical changes to the RPE, a technical advance that has direct implications for improving our understanding of diseases such as oculocutaneous albinism, late-onset retinal degeneration, and Bietti crystalline dystrophy.

Authors

HaeWon Jung, Jianfei Liu, Tao Liu, Aman George, Margery G. Smelkinson, Sarah Cohen, Ruchi Sharma, Owen Schwartz, Arvydas Maminishkis, Kapil Bharti, Catherine Cukras, Laryssa A. Huryn, Brian P. Brooks, Robert Fariss, Johnny Tam

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Figure 3

Imaging RPE cell ICG uptake across cultured cells, mice, and humans.

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Imaging RPE cell ICG uptake across cultured cells, mice, and humans. Tra...
Translational imaging framework to evaluate the effects of melanin pigment on ICG signal as assessed by custom confocal microscopes outfitted with near-infrared excitation and emission capabilities. (A–D) AO-ICG images of unfixed, fresh RPE flatmounts from (A–C) 3 BALB/cJ mice that were systemically injected with ICG and (D) 1 BALB/c mouse that was not injected with ICG. The heterogeneous pattern was observed with ICG accumulating in the cytoplasmic space, revealing the binuclear murine RPE cells. Images in A–D are histogram adjusted between the minimum and maximum intensity values of each image. (E–H) Transmitted light (E and G) and ICG fluorescence (F and H) collected from live fetal RPE cells grown in culture. The heterogeneous melanin distribution can be seen (dark areas) in the transmitted light images. ICG-incubated RPE cells (F) exhibit substantially higher fluorescence than control RPE cells that have not been incubated with ICG (H). Images in F and H were acquired using the same imaging parameters. Comparison of areas of heavy vs. light pigmentation reveals a subtle quenching of the ICG fluorescence signal in some areas (solid boxes) but not others (dotted boxes). There is a faint infrared autofluorescence (IRAF) visible in H that can be enhanced by increasing the laser power. (I–K) Induced pluripotent stem cell–derived RPE cells from a pigmented human donor grown in culture imaged using transmitted light (I) and IRAF (J). Individual melanin granules visible in I colocalize with areas of IRAF as can be seen in K (white arrows). A z-stack through these cells is shown in Supplemental Video 2. (L and N) Adaptive optics enhanced infrared autofluorescence (AO-IRAF) image of foveal RPE cells in the living human eye prior to ICG injection. (M and O) AO-ICG image of coregistered RPE cells following ICG injection. Comparison of areas of brighter and darker IRAF reveals a subtle quenching of the AO-ICG in some areas (solid boxes) but not others (dotted boxes). (P and Q) There was no relationship between AO-IRAF and AO-ICG fluorescence in individual cells (S10L, P = 0.21, n = 324 cells; S14L, P = 0.26, n = 425 cells; one-way ANOVA). Dotted lines, univariate linear regression. Scale bars: (A–D) 50 μm, (E–K) 10 μm, (L and M) 100 μm, (N and O) 50 μm.