Phycoerythrin-allophycocyanin: a resonance energy transfer fluorochrome for immunofluorescence

BACKGROUND: As immunofluorescence experiments become more complex, the demand for new dyes with different properties increases. Fluorescent dyes with large Stoke's shifts that are very bright and have low background binding to cells are especially desirable. We report on the properties of the resonance energy tandems of phycoerythrin and allophycocyanin (PE-APC). PE-APC is the original fluorescence resonance energy tandem dye described in the literature, but it has not been utilized because of the difficulty of synthesizing and preparing a consistent product. METHODS: PE-APC complexes comprising different ratios of the two phycobiliproteins conjugated to streptavidin were synthesized using standard protein-protein conjugation chemistry. The PE-APC streptavidins were evaluated for flow cytometric analysis. They were compared directly to Cy5PE conjugates because Cy5PE is the fluorophore that is spectrally most like the PE-APC. RESULTS: PE-APC complexes showed the expected fluorescence spectral properties of a tandem: excitation was excellent at 488 nm (and best at the PE excitation maximum) and emission was greatest at the APC emission maximum at about 660 nm. The efficiency of transfer of energy from PE to APC was about 90%. CONCLUSION: PE-APC can be considered an excellent substitute for Cy5PE. Compared with Cy5PE, PE-APC has similar brightness (in staining experiments), slightly greater compensation requirements with PE but much lower compensation with Cy5.5PE or Cy5.5PerCP, and lower nonspecific background binding. PE-APC is a useful alternative to Cy5PE, especially in applications in which the use of Cy5 is impractical. Cytometry 44:24-29, 2001. Published 2001 Wiley-Liss, Inc.     

Single laser three color immunofluorescence staining procedures based on energy transfer between phycoerythrin and cyanine 5.

Monoclonal antibodies specific for phycoerythrin (PE) were covalently labeled with the fluorescent dye cyanine 5 (Cy5). Excitation at 488 nm of immune complexes obtained by mixing Cy5-anti-PE with PE resulted in a 4-fold reduction of PE fluorescence measured at 565 nm and an increase of fluorescence measured at 655 nm. The observed energy transfer between PE and Cy5-anti-PE was used to develop three color immunofluorescence staining procedures for flow cytometers equipped with an Argon laser tuned at 488 nm. Mouse IgG1 monoclonal antibodies specific for cell surface antigens were cross-linked with either unlabeled or Cy5 labeled mouse IgG1 anti-PE using F(ab')2 fragments of monoclonal rat anti-mouse IgG1. PE was added to these immune complexes in sufficient amounts to saturate all PE binding sites. Cells were incubated with PE-labeled and PE/Cy5-labeled tetrameric antibody complexes together with FITC labeled antibodies and analyzed by flow cytometry. The emission from FITC, PE and PE/Cy5 could be readily separated and bright three color immunofluorescence staining of mononuclear cells from human peripheral blood and bone marrow was observed. The results of these experiments demonstrate that useful probes for single laser three color staining of cell surface antigens can be readily obtained by mixing of selected reagents. Compared to standard procedures for the covalent labeling of PE (tandem) molecules to antibodies, the non-covalent procedures described in this report provide significant advantages in terms of the amount of reagents, time and equipment required to obtain suitable reagents for three color immunofluorescence staining.     

Alexa dyes, a series of new fluorescent dyes that yield exceptionally bright, photostable conjugates.

Alexa 350, Alexa 430, Alexa 488, Alexa 532, Alexa 546, Alexa 568, and Alexa 594 dyes are a new series of fluorescent dyes with emission/excitation spectra similar to those of AMCA, Lucifer Yellow, fluorescein, rhodamine 6G, tetramethylrhodamine or Cy3, lissamine rhodamine B, and Texas Red, respectively (the numbers in the Alexa names indicate the approximate excitation wavelength maximum in nm). All Alexa dyes and their conjugates are more fluorescent and more photostable than their commonly used spectral analogues listed above. In addition, Alexa dyes are insensitive to pH in the 4-10 range. We evaluated Alexa dyes compared with conventional dyes in applications using various conjugates, including those of goat anti-mouse IgG (GAM), streptavidin, wheat germ agglutinin (WGA), and concanavalin A (ConA). Conjugates of Alexa 546 are at least twofold more fluorescent than Cy3 conjugates. Proteins labeled with the Alexa 568 or Alexa 594 dyes are several-fold brighter than the same proteins labeled with lissamine rhodamine B or Texas Red dyes, respectively. Alexa dye derivatives of phalloidin stain F-actin with high specificity. Hydrazide forms of the Alexa dyes are very bright, formaldehyde-fixable polar tracers. Conjugates of the Alexa 430 (ex 430 nm/em 520 nm) and Alexa 532 (ex 530 nm/em 548 nm) fluorochromes are spectrally unique fluorescent probes, with relatively high quantum yields in their excitation and emission wavelength ranges.     

Two- and three-color immunofluorescence using aminocoumarin, fluorescein, and phycoerythrin-labelled antibodies and single laser flow cytometry.

Antibodies coupled to 7-aminocoumarin (AMCA) emit a bright blue fluorescence under ultraviolet (UV) excitation and are therefore ideal for three-color immunofluorescence (IF) with fluorescein (FITC) and phycoerythrin (PE) labeled reagents; however, due to the different absorption spectra, the use of these fluorophores for multicolor flow-cytometric analysis requires a double light excitation source (e.g., two-laser system). We report a strategy which uses a single argon-ion laser to simultaneously excite AMCA, FITC, and PE, thus allowing the flow cytometric analysis of three immunological parameters. When the UV-visible argon-ion laser is fitted with an appropriate set of mirrors, the 35.1-363.8 nm (UV) and 488 nm wavelengths (accounting for 80 mW and 520 mW, respectively) are simultaneously generated; these lines can then be exactly focused on the same observation point by an achromatic cylindrical lens. A number of comparative analysis were performed with this instrumental set up to verify the sensitivity of AMCA IF and its possible application for multicolor immunophenotypic evaluation of blood cell subsets. When AMCA- and FITC-labeled antimouse Ig antibodies were assessed for their ability to detect limiting amounts of mouse monoclonal antibody bound to cells, the former was less sensitive than the latter. A number of factors, including differences in excitation energy (80 mW for AMCA and 520 mw for FITC) and extinction coefficients (1.9 x 10(4) for AMCA and 6 x 10(4) for FITC) could explain this result.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sequential photobleaching of fluorochromes for polychromatic slide-based cytometry.

BACKGROUND: Slide-based cytometry is a key technology for polychromatic cytomic investigations. Here we exploit the relocalization and merge feature of Laser Scanning Cytometry for distinguishing fluorochromes of comparable emission spectra but different photostabilities. METHODS: Blood specimens were stained with the fluorochrome pairs: FITC/ALEXA488, PE/ALEXA532, or APC/ALEXA633. Bleaching was performed by repeated laser excitation. RESULTS: Since ALEXA dyes are photostable as compared to the conventional fluorochromes FITC, PE, and APC, a differentiation within one fluorochrome pair is possible. CONCLUSION: The sequential photobleaching method results in an increased information density on a single cell level and represents an important component to perform polychromatic cytometry.     

Use of a new violet-excitable AmCyan variant as a label in cell analysis

Here we report a new variant of AmCyan fluorescent protein that has been specifically designed for multicolor cell analysis. AmCyan is one of the existing violet fluorochromes for use in flow cytometers equipped with a violet (405 nm) laser. It is also widely used as a label in fluorescent spectroscopy. Limitations on its use are due to the significant AmCyan fluorescence spillover into the FITC detector, due to excitation of AmCyan by the blue (488 nm) laser. In order to resolve this problem, we modified the excitation profile of AmCyan. The new fluorescent protein that we developed, AmCyan100, has an emission profile similar to AmCyan with an emission maximum at 500 nm, but its excitation maximum is shifted to 395 nm, which coincides more closely with the violet laser line and decreases the excitation with the blue laser, thus reducing the spillover observed with the original AmCyan. Moreover, this new protein has a Stokes shift of more than 100 nm compared to the Stokes shift of 31 nm in its precursor. Our data also suggests that AmCyan100-mAb conjugates have brightness similar to AmCyan-mAb conjugates. In summary, AmCyan100 conjugates have minimum spillover into the FITC detector, and can potentially replace existing AmCyan conjugates in multicolor flow cytometry without any changes in instrumental setup and existing reagent panel design.     

Improved double immunofluorescence for confocal laser scanning microscopy.

Reliable double immunofluorescence labeling for confocal laser scanning microscopy requires good separation of the signals generated by the fluorochromes. We have successfully overcome the limitation of a single argon ion laser in achieving effective excitation of dyes with well-separated emission spectra by employing the novel sulfonated rhodamine fluorochromes designated Alexa 488 and Alexa 568. The more abundant antigen was visualized using the red-emitting Alexa 568, with amplification of the signal by a biotinylated bridging antibody and labeled streptavidin. This was combined with the green-emitting Alexa 488, which yielded brighter images than fluorescein but exhibited comparable photodegradation. With appropriate controls to ensure the absence of crosstalk between fluorescence channels, these dyes permitted unequivocal demonstration of co-localization. This combination of fluorochromes may also offer advantages for users of instruments equipped with alternative laser systems.     

Nine color eleven parameter immunophenotyping using three laser flow cytometry.

BACKGROUND: This study describes a three laser flow cytometer, reagents, and software used to simultaneously evaluate nine distinct fluorescent parameters on one cell sample. We compare the quality of data obtained with (1) full software compensation and (2) the use of partial spectral compensation of selected pairs of parameters in analog hardware, in combination with final software compensation. An application characterizing low frequency murine B cell subpopulations is given. METHODS: The fluorochromes used are: fluorescein (FITC), phycoerythrin (PE), Cy5PE and Cy7PE, excited at 488 nm by an argon laser; Texas Red (TR), allophycocyanin (APC), and Cy7APC excited at 595 nm by a pumped dye laser; and cascade blue (CB) and cascade yellow (CY) excited at 407 nm by a violet-enhanced krypton laser. Custom additions to commercial electronics and an extended optical bench allow the measurement of these nine parameters plus forward and side scatter light signals. RESULTS: We find the use of partial analog compensation reduces the variation in the background staining levels introduced by the compensation process. Novel B cell populations with frequencies below 1% are characterized. CONCLUSIONS: Nine color flow cytometry is capable of providing measurements with high information content. The choice of reagent-dye combinations and the ability to compensate in multi-parameter measurement space are crucial to obtaining satisfactory results.     

Polychromatic (eight-color) slide-based cytometry for the phenotyping of leukocyte, NK, and NKT subsets.

BACKGROUND: Natural killer (NK) and NK T (NKT) cells are important in innate immune defense. Their unequivocal identification requires at least four antigens. Based on the expression of additional antigens, they can be further divided into functional subsets. For more accurate immunophenotyping and to describe multiple expression patterns of leukocyte subsets, an increased number of measurable colors is necessary. To take advantage of the technologic features offered by slide-based cytometry, repeated analysis was combined with sequential optical-filter changing. METHODS: Human peripheral blood leukocytes from healthy adult volunteers were labeled with antibodies by direct or indirect staining. Tandem dyes of Cy7 (phycoerythrin [PE]-/allophycocyanin [APC]-Cy7), Cy5.5 (PE-/APC-Cy5.5), and PE-Cy5 and the fluorochromes fluorescein isothiocyanate (FITC), PE, and APC were tested alone and in combinations. Optical filters of the laser scanning cytometer were 555 DRLP/BP 530/30 nm for photomultiplier tube (PMT) 1/FITC, 605 DRLP/BP 580/30 nm for PMT 2/PE, 740 DCXR/BP 670/20 nm for PMT 3/Cy5/APC, and BP 810/90 nm for PMT 4/Cy7. Filter PMT 3 was replaced for detection of PE/Cy5.5 and APC/Cy5.5 by 740 LP/BP 710/20 nm and the sample was remeasured. Both data files were merged into one to combine the different information on a single-cell basis. The combination of eight antibodies against CD3, CD4, CD8, CD14, CD16, CD19, CD45, and CD56 was used to characterize NK and NKT cells and their subsets. RESULTS: In this way Cy5.5 is measurable at 488-nm and 633-nm excitation. Further, with the two different filters it is possible to distinguish Cy5 from Cy5.5 in the same detection channel (PMT 3). With this method we identified NK and NKT cells, subsets of NK (CD3-16+56+, CD3-16+56-, CD3-16-56+) and NKT (CD3+16+56+, CD3+16-56+) and their CD4+8-, CD4-8+, CD4-8- and CD4+8+ subsets. CONCLUSION: With our adaptations it is possible to discriminate tandem conjugates of Cy5, Cy5.5, and Cy7 for eight-color immunophenotyping. Using this method, novel rare subsets of NK and NKT cells that are CD4/CD8 double positive are reported for the first time.     

Near-infrared dyes for six-color immunophenotyping by laser scanning cytometry

BACKGROUND: To adequately analyze the complexity of the immune system and reduce the required sample volume for immunophenotyping in general, more measurable colors for the discrimination of leukocyte subsets are necessary. Immunophenotyping by the laser scanning cytometer (LSC), a slide-based cytometric technology, combines cell detection based on multiple colors with their subsequent visualization without the need for physical cell sorting. In the present study, the filter setting of the LSC was adapted for the measurement of the far-red emitting dye cyanine 7 (Cy7), thereby increasing the number of measurable commercially available fluorochromes. METHODS: The optical filters of the LSC were replaced-photomultiplier (PMT) 3/allophycocyanin (APC): 740-nm dichroic long pass, and 670-/55-nm bandpass; PMT 4/Cy7: 810-/90-nm bandpass. Peripheral blood leukocytes were stained directly by fluorochrome-labeled antibodies or by indirect staining. The tandem dyes of Cy7 (phycoerythrin [PE]-Cy7, APC-Cy7) and the fluorochromes fluorescein isothiocyanate (FITC), PE, PE-Cy5, and APC were tested alone and in different combinations. RESULTS: With the new filter combination and tandem fluorochromes, Cy7 was measurable at 488-nm (argon laser) or 633-nm (helium-neon laser) excitation. Resolution was in the range of FITC for PE-Cy7 but approximately 30% lower for APC-Cy7; spillover into the respective donor fluorochrome channel for both tandem dyes was prominent. A six-color panel for leukocyte subtyping was designed. CONCLUSIONS: With this adaptation, it is possible to measure the tandem conjugates PE-Cy7 and APC-Cy7. This new setup opens the way for six-color immunophenotyping by LSC.     

Immunofluorescence measurement in a flow cytometer using low-power helium-neon laser excitation

Helium-neon lasers are economical and efficient light sources; their utility in flow cytometry to date has been limited by the lack of fluorescent probes that can be excited at 633 nm. Allophycocyanin (APC), a highly fluorescent phycobiliprotein, can be used as an antibody label and has spectral characteristics suitable for use with He-Ne lasers; we undertook to resolve whether a low-power (7 mW) He-Ne laser could provide sufficient excitation to permit flow cytometric detection of APC-labeled antibodies on cell surfaces. We made an APC conjugate of monoclonal antibody 4F2, which reacts with an antigen abundant on the surfaces of activated human T-lymphocytes; APC-4F2 was used to stain blood mononuclear cells that had been cultured with and without phytohemagglutinin (PHA). Cells so stained were examined in a flow cytometer with orthogonal illumination at 633 nm from a 7 mW He-Ne laser; antibody-bearing cells were detectable by fluorescence emission above 665 nm. Cells from the same cultures were stained with fluorescein-labeled 4F2 antibody and examined in a flow cytometer with argon ion laser excitation at 488 nm. Percentages of antibody-bearing cells determined from APC fluorescence and from fluorescein fluorescence were in good agreement. It thus appears that He-Ne lasers and APC-antibodies are usable for immunofluorescence measurements; the sensitivity attainable with this technique remains to be determined.     

Multicolor immunofluorescence and flow cytometry utilizing cascade blue to purify murine hematopoietic stem cells from fetal liver and bone marrow.

BACKGROUND: Here we demonstrate the utility of cascade blue (CB), to purify hematopoietic stem cells by flow cytometry. Multicolor immunofluorescence and the sensitivity (signal-to-noise) of the fluorochromes are essential for the identification and isolation of rare stem cell populations. METHODS: We isolated hematopoietic stem cells utilizing a 407 nm laser line to excite CB and propidium iodide (PI) in combination with FITC, PE, and Red670 which were excited at 488 nm. RESULTS: CB is maximally excited using a 407 nm laser line, when compared to UV or 413 nm excitation. The increase in sensitivity of CB at 407 nm can be contributed to higher absorption of CB and a reduction of autofluorescence at this excitation wavelength (Ropp et al.: Cytometry 21: 309-317, 1995). CONCLUSIONS: Despite the fact that the CB antibody conjugate has a tendency to adhere specifically to a B cell subpopulation in bone marrow, we nevertheless could purify stem cells by using CB for the detection and elimination of lineage positive cells. Isolated stem cells from mouse fetal liver (Lin-CD34(+)Sca-1(+)c-Kit(high)) and adult bone marrow (Lin-CD34(-/low)Sca-1(+)c-Kit(+)) were transplanted into lethally irradiated mice, and the sorted stem cells had the ability to efficiently repopulate all mature hematopoietic lineages in recipient mice.     

Triple immunofluorescence confocal laser scanning microscopy: spatial correlation of novel cellular differentiation markers in human muscle biopsies.

Two different methods for triple immunofluorescence imaging with a confocal laser scanning microscope (CLSM) are described. The methods enable spatial "mapping" of 3 different epitope distribution patterns simultaneously in one tissue section. The key to triple imaging includes: (a) specific immunolabeling with 3 different mouse monoclonal antibodies (mAbs), (b) localization of the antibody binding sites by 3 different dyes, (c) spectral isolation of each dye by using selective band pass or long pass emission filters, (d) computerized imaging of the fluorescences as colored overlays or as selective signals in each optical section through the tissue in the z-direction. Method 1 consists of the combination of fluorescein isothiocyanate (FITC), phycoerythrin R (PE), and Texas Red (TR) as fluorescent markers. These dyes can be imaged by using 488 nm and 543 nm excitation laser lines. In method 2 aminomethyl coumarin acetic acid (AMCA) was combined with FITC and PE. For this application the CLSM was adapted to ultraviolet microscopy that enabled the use of 3 laser lines (364 nm, 488 nm, 543 nm) for excitations. Cryostat sections of diagnostic human muscle biopsies (n = 9) were studied which were normal by ordinary light microscopic examination. Sections were incubated with mAbs specific for: (1) the fast myosin heavy chain (My32); (2) the major histocompatibility class II antigen HLA-DR; (3) the lymph node homing receptor Leu8, and (4) the cell adhesion receptor OKM5 (CD36). By combining these mAbs in triple staining procedures, 3 capillary types and 4 different phenotypes expressed by muscle fibers were identified simultaneously. The mAbs Leu8 and OKM5, widely used as leukocyte typing antibodies in the blood, exhibit hitherto unrecognized specificities for antigens displayed by muscle fibers. At the level of these markers, specific spatial correlations between OKM5 reactive capillaries and both OKM5 reactive and nonreactive muscle fiber types become visible. The presented results provide direct evidence for cellular complexity and novel insight into the immunoanatomical architecture of skeletal muscle. The methods may be of general significance for the construction and quantification of three-dimensional multiparameter "maps" of cells and tissues.     

Cryptomonad algal phycobiliproteins as fluorochromes for extracellular and intracellular antigen detection by flow cytometry

BACKGROUND: Phycobiliproteins play an important role in fluorescent labeling, particularly for flow cytometry. The spectral properties of R-phycoerythrin (R-PE) and allophycocyanin (APC) have made them the dominant reagents in this class of fluorochromes. In this study, we evaluate a lesser-known but potentially important series of low-molecular weight cryptomonad-derived phycobiliproteins (commercially termed the CryptoFluortrade mark dyes) for their applicability to flow cytometry, both in extracellular and intracellular labeling applications. METHODS: Several cell lines were labeled with biotin-conjugated antibodies against expressed extracellular surface proteins, followed by streptavidin conjugates of three cryptomonad phycobiliproteins (CryptoFluor-2, CryptoFluor-4, and CryptoFluor-5). Cells were then analyzed by flow cytometry using a variety of laser lines and emission filters to establish the optimal excitation/emission characteristics for each fluorochrome. Some cells were permeabilized and labeled for intracellular antigens, also using the cryptomonad fluorochromes. Where appropriate, parallel samples were labeled with other fluorochromes (including R-PE, APC, the cyanin dyes Cy3 and Cy5, and others) to gauge the performance of the cryptomonad fluorochromes against fluorescent labels previously evaluated for flow cytometry. RESULTS: CryptoFluor-2 possessed excitation/emission maxima similar to those of APC and Cy5, with good excitation in the red (HeNe laser 632 nm) and strong emission in the far red (660 nm). CryptoFluor-4 possessed excitation/emission maxima similar to those of Cy3, with optimal excitation in the green (Kr 530 nm) and strong emission in the yellow/orange (585 nm). CryptoFluor-5 possessed excitation/emission maxima similar to those of lissamine rhodamine, with optimal excitation in the yellow (Kr 568 nm) and emission in the orange (610 nm). All cryptomonad fluorochromes gave satisfactory results for both intracellular and extracellular labeling, with detection sensitivities that were comparable or better than traditional phycobiliproteins and low- molecular weight synthetic fluorochromes such as the cyanin dyes. CONCLUSIONS: The CryptoFluor fluorochromes were applicable to flow cytometric immunodetection, with excitation and emission conditions commonly found on multilaser instruments. Performance of several of these dyes was at least comparable to existing fluorescent labels. The low molecular weights (30-60 kd) of phycobiliproteins may make them particularly useful in intracellular antigen detection. Cytometry 44:16-23, 2001. Published 2001 Wiley-Liss, Inc.     

Biotinylated photocleavable polyethylenimine: capture and triggered release of nucleic acids from solid supports

A biotinylated photocleavable polyethylenimine (B-PC-PEI) was designed and synthesized for the capture and controlled release of nucleic acids from solid supports. B-PC-PEI was synthesized via a three-step reaction process and verified by 1H NMR and mass spectrometry. In aqueous solution, the o-nitrobenzyl group within B-PC-PEI was efficiently cleaved by 5 min of 365 nm light exposure from a distance of 20 cm (9 mW/cm2). When coupled to streptavidin-coated beads, the PEI domain of Cy5-labeled B-PC-PEI was released by 365 nm light exposure. In contrast, a Cy5-labeled biotinylated PEI (B-PEI) was used as a control and negligible fluorescence loss was observed. Cy5-labeled siRNA was electrostatically captured to streptavidin-coated beads preabsorbed with B-PC-PEI or B-PEI, and flow cytometry demonstrated significant loss of fluorescence from the bead surface after 5 min of light exposure only for B-PC-PEI, demonstrating controlled release of siRNA from the bead surface. Finally, the release of the Cy5-labeled siRNA into the supernatant was quantified. The release of Cy5-siRNA into the supernatant was significantly greater after 5 min of light exposure for B-PC-PEI/streptavidin beads compared to 0 min exposure and remained unchanged for B-PEI/streptavidin beads. B-PC-PEI facilitates capture and triggered release of surface-tethered nucleic acids with light exposure and is fully compatible with streptavidin-based applications.     

Heterodimeric DNA-binding dyes designed for energy transfer: synthesis and spectroscopic properties.

Heterodimeric dyes are described which bind tightly to double-stranded (dsDNA) with large fluorescence enhancements. These dyes are designed to exploit energy transfer between donor and acceptor chromophores to tune the separation between excitation and emission wavelengths. The dyes described here absorb strongly at the 488 nm argon ion line, but emit at different wavelengths, and can be applied to multiplex detection of various targets. The chromophores in these dyes, a thiazole orange-thiazole blue heterodimer (TOTAB), two different thiazole orange-ethidium heterodimers (TOED1 and TOED2), and a fluorescein-ethidium heterodimer (FED), are in each case linked through polymethyleneamine linkers. The emission maxima of the DNA-bound dyes lie at 662 (TOTAB), 614 (TOED 2), and 610 nm (FED). The dyes showed a > 100 fold enhancement of the acceptor chromophore fluorescence on binding to dsDNA and no sequence selectivity. In comparison with direct 488 nm excitation of the constituent monomeric dyes, in the heterodimers the fluorescence of the acceptor chromophores was greatly enhanced and the emission of the donor chromophores quenched by over 90%. The acceptor emission per DNA-bound dye molecule was constant from 100 DNA bp:dye to 20 bp:dye and decreased sharply at higher dye:DNA ratios.     

A luminescent ruthenium complex for ultrasensitive detection of proteins immobilized on membrane supports

SYPRO Ruby protein blot stain provides a sensitive, gentle, fluorescence-based method for detecting proteins on nitrocellulose or polyvinylidene difluoride (PVDF) membranes. SYPRO Ruby dye is a permanent stain composed of ruthenium as part of an organic complex that interacts noncovalently with proteins. Stained proteins can be excited by ultraviolet light of about 302 nm or with visible light of about 470 nm. Fluorescence emission of the dye is approximately 618 nm. The stain can be visualized using a wide range of excitation sources utilized in image analysis systems including a UV-B transilluminator, 488-nm argon-ion laser, 532-nm yttrium-aluminum-garnet (YAG) laser, blue fluorescent light bulb, or blue light-emitting diode (LED). The detection sensitivity of SYPRO Ruby protein blot stain (0.25-1 ng protein/mm(2)) is superior to that of amido black, Coomassie blue, and india ink staining and nearly matches colloidal gold staining. SYPRO Ruby protein blot stain visualizes proteins more rapidly than colloidal gold stain and the linear dynamic range is more extensive. Unlike colloidal gold stain, SYPRO Ruby protein blot stain is fully compatible with subsequent biochemical applications including colorimetric and chemiluminescent immunoblotting, Edman-based sequencing and mass spectrometry.     

Seven-color fluorescence imaging of tissue samples based on Fourier spectroscopy and singular value decomposition.

Seven-color analyses of immunofluorescence-stained tissue samples were accomplished using Fourier spectroscopy-based hyperspectral imaging and singular value decomposition. This system consists of a combination of seven fluorescent dyes, three filtersets, an epifluorescence microscope, a spectral imaging system, a computer for data acquisition, and data analysis software. The spectra of all pixels in a multicolor image were taken simultaneously using a Sagnac type interferometer. The spectra were deconvolved to estimate the contribution of each component dye, and individual dye images were constructed based on the intensities of assigned signals. To obtain mixed spectra, three filter sets, i.e., Bl, Gr, and Rd for Alexa488 and Alexa532, for Alexa546, Alexa568, and Alexa594, and for Cy5 and Cy5.5, respectively, were used for simultaneous excitation of two or three dyes. These fluorophores have considerable spectral overlap which precludes their separation by conventional analysis. We resolved their relative contributions to the fluorescent signal by a method involving linear unmixing based on singular value decomposition of the matrices consisting of dye spectra. Analyses of mouse thymic tissues stained with seven different fluorescent dyes provided clear independent images, and any combination of two or three individual dye images could be used for constructing multicolor images.     

低强度532nm与633nm激光血管内照射生物效应比较

目的：研究同等照射条件的低强度532nm与633nm激光血管内照射对家兔白细胞计数与淋巴细胞凋亡的影响,比较两种激光生物效应的特点。方法：用532nm和633nm激光对健康日本大耳白家兔血管内照射,平均照射功率均设在5mW左右,照射总能量约12J。两组家兔均于照前及照后1d、4d、7d、11d进行外周血白细胞计数,于照前及照后1d、5d进行淋巴细胞凋亡分析。结果：532nm激光照射后,家兔外周血白细胞计数表现为先显著升高后趋向恢复,633nm激光照射后白细胞计数变化类似,但与照前相比升高不明显;与照前相比,两组家免外周血淋巴细胞凋亡比例于照后1d均明显降低,照后5d均显著升高;两组家兔相比,照射后白细胞计数差别明显,但淋巴细胞凋亡比例差异不显著。结论：同等照射条件下,低强度532nm与633nm激光照射血液的生物效应相似,都可以促进白细胞的代谢更新,只是532nm激光的效应略强一些。     

Highlighted generation of fluorescence signals using simultaneous two-color irradiation on Dronpa mutants

Dronpa absorbs blue light and emits bright green fluorescence. It can also be converted by strong irradiation at 490 nm to a nonfluorescent state, which can then be switched back to the original emissive state with irradiation at 400 nm. Through semirandom mutagenesis studies, we have developed two mutants of Dronpa that show efficient photoswitching kinetics. Compared to Dronpa, the mutants can be turned off by blue light more efficiently. Thus, excitation with an argon laser line (488 nm) makes the mutants quickly become dark such that no substantial fluorescence signals can be observed. Excitation with a violet laser diode (405 nm) also produces no fluorescence signals. Simultaneous 488- and 405-nm irradiation, however, results in a rapid oscillation between the two states, thereby keeping the emissive state population large enough to produce sufficiently bright fluorescence signals.