Spectral phasor analysis of Pyronin Y labeled RNA microenvironments in living cells.

We show that the spectral phasor approach of the fluorescent dye Pyronin Y (PY) can be used to identify specific RNA subspecies of ribonuclear proteins complexes in live cells. We applied spectral phasors to isolate intracellular RNA species with similar spectral properties. We identified at least 4 different PY labeled species in live cells and further spatially mapped their presence at the pixel level. Most notable were transcripts in the nucleoli which were spectrally similar to RNA clusters in the cytoplasm. We propose that these species represent ribosomal RNA and clustered ribonucleoprotein complexes. Further, we observed within this cluster Cajal bodies in the proximity of the nucleolus. In addition, transcripts in the cytoplasm undertook a filamentous morphology composed of multiple puncti structures which individually localized along and close to mitochondria but were distinct from mitochondria.

Detecting Pyronin Y labeled RNA transcripts in live cell microenvironments by phasor-FLIM analysis.

Pyronin Y is an environment-sensitive probe which labels all double-stranded RNA in live cells. Methods to determine which RNA species Pyronin Y may be labeling are limited due to the lack of studies aimed at determining whether this probe has different spectroscopic properties when bound to specific transcripts. A major issue is that transcripts are difficult to isolate and study individually. We detected transcripts directly in their biological environment allowing us to identify RNA species on the basis of their location in the cell. We show that the phasor approach to lifetime analysis has the sensitivity to determine at least six different RNA species in live fibroblast cells. The detected lifetime differences were consistent among cells. To our knowledge this is the first application of a spectroscopic technique aimed at identifying Pyronin Y labeled RNA subtypes in living cells.

Phasor-FLIM analysis of NADH distribution and localization in the nucleus of live progenitor myoblast cells.

Analysis of the cellular distributions of coenzymes including NADH may aid in understanding a cells metabolic status. We altered serum concentration (0, 2, and 10%) to induce living myoblast cells to undergo the early stages of differentiation. Through microscopy and phasor-FLIM, we spatially mapped and identified variations in the distribution of free and bound NADH. Undifferentiated cells displayed abundant free NADH within the nucleus along with specific regions of more bound NADH. Complete serum starvation dramatically increased the fraction of bound NADH in the nucleus, indicating heightened requirement for transcriptional processes. In comparison, cells exposed to 2% serum exhibited intermediate free nuclear NADH fraction. Overall our results suggest an order of events in which a cell metabolic status alters significantly during the early stages of serum induced differentiation.

NADH distribution in live progenitor stem cells by phasor-fluorescence lifetime image microscopy.

NADH is a naturally fluorescent metabolite associated with cellular respiration. Exploiting the different fluorescence lifetime of free and bound NADH has the potential to quantify the relative amount of bound and free NADH, enhancing understanding of cellular processes including apoptosis, cancer pathology, and enzyme kinetics. We use the phasor-fluorescence lifetime image microscopy approach to spatially map NADH in both the free and bound forms of live undifferentiated and differentiated myoblast cells. The phasor approach graphically depicts the change in lifetime at a pixel level without the requirement for fitting the decay. Comparison of the spatial distribution of NADH in the nucleus of cells induced to differentiate through serum starvation and undifferentiated cells show differing distributions of bound and free NADH. Undifferentiated cells displayed a short lifetime indicative of free NADH in the nucleus and a longer lifetime attributed to the presence of bound NADH outside of the nucleus. Differentiating cells displayed redistribution of free NADH with decreased relative concentration of free NADH within the nucleus whereas the majority of NADH was found in the cytoplasm.