Bright far-red fluorescent protein for whole-body imaging

Shcherbo, Dmitry; Merzlyak, Ekaterina M.; Chepurnykh, T. V.; Fradkov, Arkady F.; Ermakova, Galina V.; Solovieva, Elena A.; Lukyanov, Konstantin A.; Богданова, Е. А.; Zaraisky, Andrey G.; Lukyanov, Sergey; Chudakov, Dmitriy M.

doi:10.1038/nmeth1083

Cited by 585 publications

(541 citation statements)

References 28 publications

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“…Notably, after expression of mRuby and mCherry in HeLa cells for 4 days, we observed punctate fluorescent labelling that resembled lysosomal localization, as previously described by Miyawaki et al 12 This observation confirms our previous data for mCherry, although it should be mentioned here that in our previous work the punctate labelling was defined as 'aggregates' 6 . In contrast, we did not observe lysosomal localization of mKate2 and FusionRed after 4 days of expression under the same conditions ( Supplementary Fig.…”

Section: Performance Of Fusionred In Fusionssupporting

confidence: 92%

“…3 and Supplementary movies [1][2][3][4][5][6][7][8]. Owing to the lack of a statistical methodology to make direct comparisons of fluorescent protein performance in fusions, the practice is utilized only to provide one or several representative images that demonstrate the ability of the reporter to properly perform in each of the constructs.…”

Section: Performance Of Fusionred In Fusionsmentioning

confidence: 99%

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A monomeric red fluorescent protein with low cytotoxicity

et al. 2012

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Multicolour labelling with fluorescent proteins is frequently used to differentially highlight specific structures in living systems. Labelling with fusion proteins is particularly demanding and is still problematic with the currently available palette of fluorescent proteins that emit in the red range due to unsuitable subcellular localization, protein-induced toxicity and low levels of labelling efficiency. Here we report a new monomeric red fluorescent protein, called FusionRed, which demonstrates both high efficiency in fusions and low toxicity in living cells and tissues.

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Section: Performance Of Fusionred In Fusionssupporting

confidence: 92%

Section: Performance Of Fusionred In Fusionsmentioning

confidence: 99%

A monomeric red fluorescent protein with low cytotoxicity

et al. 2012

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“…FCM and immunohistochemistry) to continue to understand this phenomenon. These experiments also include the assessment of bright, far-red fluorescent proteins, such as the far-red mutant TurboFP635 (14), and DsRed mouse strains that are currently commercially available, such as B6.Cg-Tg(ACTB-Bgeo,-DsRed*MST)1Nagy/J. These new and highly innovative vectors may allow for improved sensitivity and specificity due to better tissue penetration, increased signal to noise ratios through the reduction of autofluorescence.…”

Section: Discussionmentioning

confidence: 99%

Quantification of green fluorescent protein by in vivo imaging, PCR, and flow cytometry: Comparison of transgenic strains and relevance for fetal cell microchimerism

et al. 2008

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Animal models are increasingly being used for the assessment of fetal cell microchimerism in maternal tissue. We wished to determine the optimal transgenic mouse strain and analytic technique to facilitate the detection of rare transgenic microchimeric fetal cells amongst a large number of maternal wild-type cells. We evaluated two strains of mice transgenic for the enhanced green fluorescent protein (EGFP): a commercially available, commonly used strain (C57BL/6-Tg(ACTB-EGFP)10sb/J) (CAG) and a newly created strain (ROSA26-EGFP) using three different techniques: in vivo and ex vivo fluorescent imaging (for whole body and dissected organs, respectively), PCR amplification of gfp, and flow cytometry (FCM). By fluorescent imaging, organs from CAG mice were 10-fold brighter than organs from ROSA26-EGFP mice (P < 0.0001). By PCR, more transgene from CAG mice was detected compared to ROSA26-EGFP mice (P 5 0.04). By FCM, ROSA26-EGFP cell fluorescence was more uniform than CAG cells. A greater proportion of cells from ROSA26-EGFP organs were positive for EGFP than cells from CAG organs, but CAG mice had a greater proportion of cells with the brightest fluorescent intensity. Each transgenic strain possesses characteristics that make it useful under specific experimental circumstances. The CAG mouse model is preferable when experiments require brighter cells, whereas ROSA26-EGFP is more appropriate when uniform or ubiquitous expression is more important than brightness. Investigators must carefully select the transgenic strain most suited to the experimental design to obtain the most consistent and reproducible data. In vivo imaging allows for phenotypic evaluation of whole animals and intact organs; however, we did not evaluate its utility for the detection of rare, fetal microchimeric cells in the maternal organs. Finally, while PCR amplification of a paternally inherited transgene does allow for the quantitative determination of rare microchimeric cells, FCM allows for both quantitative and qualitative evaluations of fetal cells at very high sensitivity in a plethora of maternal organs. '

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“…useful for exciting the shorter wavelength FPs, proteins with longer excitation wavelengths such as mCherry (k EX 5 587 nm, k EM 5 610 nm), mPlum (k EX 5 592 nm, k EM 5 645 nm), and the new bright red FP mKate (k EX 5 588 nm, k EM 5 635 nm) optimally require longer wavelength laser sources (12,15). This is shown in Figure 5 for HcRed (k EX 5 590 nm, k EM 5 649 nm) and the newly reported dimerized version of mKate, Katushka (k EX 5 588 nm, k EM 5 635 nm) (15), where 559, 580, 592, and 633 nm power-matched sources were used to excite bacteria expressing the relatively dim protein HcRed (left column), and the far brighter Katushka (right column).…”

Section: Resultsmentioning

confidence: 99%

Solid state yellow and orange lasers for flow cytometry

et al. 2008

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Diode and DPSS lasers emitting a variety of wavelengths are now commonly incorporated into flow cytometers, greatly increasing our capacity to excite a wide variety of fluorochromes. Until recently, however, virtually no practical technology existed for generating yellow or orange laser light for flow cytometry that was compatible with smaller instrumentation. In this study, we evaluate several new solid state laser systems that emit from the 570 to 600 nm as excitation sources for flow cytometry. DPSS 580, 589, and 592 nm sources were integrated into a cuvette-based flow cytometer (BD LSR II) and a stream-in-air cell sorter (FACSVantage DiVa), and used to excite a variety of yellow, orange, and red excited fluorochromes, including Texas Red, APC, and its tandem conjugates, and the genetically encoded red fluorescent protein HcRed and the more recently developed Katushka. All laser sources were successfully incorporated into the indicated flow cytometry platforms. The yellow and orange sources (particularly 592 nm) were ideal for exciting Texas Red, and provided excitation of APC and its tandems that was comparable to a traditional red laser source, albeit at higher power levels than red sources. Yellow and orange laser light was optimal for exciting HcRed and Katushka. Practical yellow and orange laser sources are now available for flow cytometry. This technology fills an important gap in the laser wavelengths available for flow, now almost any fluorochrome requiring visible light excitation can be accommodated. recently produced a variety of novel laser sources that have proven useful for flow and image cytometry (1). These lasers are small and durable enough for integration into small benchtop cuvette-based instrumentation, and often possess sufficient power levels to accommodate stream-in-air cell sorting (2). Ultraviolet (370-380 nm), violet (395-415 nm), and blue (435-445 nm) laser diodes have all been incorporated into flow cytometers and are being used for exciting a wide range of useful fluorescent probes (3-6). DPSS lasers are now available in the blue-green range (473-515 nm), with the DPSS 488 nm variant replacing traditional ion lasers for many instrument applications. Green (532 nm) and green-yellow (561 nm) DPSS lasers have proven useful for efficient excitation of phycoerythrin and its tandems, as well as rhodamine-based fluorochromes and GFP-like long-wavelength fluorescent proteins (2,7,8). These lasers are also starting to appear on commercial flow cytometry instrumentation, vastly improving our ability to utilize the full spectrum of fluorescent probes available for biomedical analysis.However, until very recently, a significant gap existed in the range of laser wavelengths available for flow cytometry. The yellow to orange bandwidth ($570-620 nm) was very difficult to achieve using existing technology. Yellow and orange

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Bright far-red fluorescent protein for whole-body imaging

Cited by 585 publications

References 28 publications

A monomeric red fluorescent protein with low cytotoxicity

A monomeric red fluorescent protein with low cytotoxicity

Quantification of green fluorescent protein by in vivo imaging, PCR, and flow cytometry: Comparison of transgenic strains and relevance for fetal cell microchimerism

Solid state yellow and orange lasers for flow cytometry

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