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Molecular Probes acidotropic reagents can be used to stain lysosomes and yeast vacuoles, as well as several other types of acidic compartments such as trans-Golgi vesicles, endosomes and subpopulations of coated vesicles in fibroblasts, secretory vesicles in insulin-secreting pancreatic β-cells, acrosomes of spermatozoa and plant vacuoles.ref Lysosomes contain glycosidases, acid phosphatases, elastase, cathepsins, carboxypeptidases and a variety of other proteases. Enzyme Substrates and Assays—Chapter 10 describes a number of substrates for detecting the activity of these hydrolytic enzymes. An excellent compendium of human diseases that affect intracellular transport processes through lysosomes, Golgi and endoplasmic reticulum (ER) has been published.ref

Like lysosomes, peroxisomes are single membrane–bound vesicles that contain digestive enzymes. The chief function of these basic organelles is to enzymatically oxidize fatty acids and to subsequently catalyze the breakdown of H2O2, a by-product of fatty acid degradation. Recently, interest in peroxisomes has increased, especially studies related to peroxisomal origin and maintenance.ref Morphological abnormalities in peroxisomes related to disease states and diet have also been the subject of current research.ref The SelectFX Alexa Fluor 488 Peroxisome Labeling Kit (S34201), described below, provides an antibody-based method for labeling peroxisomes in fixed cells.

CellLight Fluorescent Protein–Based Markers for Lysosomes, Peroxisomes and Endosomes

CellLight reagents combine the utility and selectivity of targeted fluorescent proteins with the efficiency of the BacMam gene delivery and expression technology. These reagents incorporate all the customary advantages of BacMam technology, including high efficiency transduction of mammalian cells and long-lasting, titratable expression ( BacMam Gene Delivery and Expression Technology—Note 11.1). CellLight reagents are provided in a ready-to-use format—simply add, incubate and image—with highly efficient expression in cell lines, primary cells, stem cells and neurons. A complete list of CellLight reagents and their targeting sequences can be found in CellLight reagents and their targeting sequences—Table 11.1.

CellLight Lysosomes-GFP (C10507, C10596) and CellLight Lysosomes-RFP (C10504, C10597; Figure 12.3.1) are BacMam expression vectors encoding fusions of Green Fluorescent Protein (GFP) or Red Fluorescent Protein ref (RFP) with the targeting sequence from Lamp1 (lysosomal-associated membrane protein 1). These CellLight reagents generate lysosomally localized fluorescent labeling in live cells that is retained after fixation and permeabilization procedures—procedures that will dissipate LysoTracker Red DND-99 staining.ref The titratable expression capacity of BacMam vectors is a particularly useful feature in the context of the Lamp1–GFP fusion, as high levels of overexpression have sometimes been found to induce aberrant aggregation of late-endocytic organelles.ref

CellLight Early Endosomes–GFP (C10586, Figure 12.3.2) and CellLight Early Endosomes–RFP (C10587) reagents provide BacMam expression vectors encoding fusions of GFP or RFP with the small GTPase Rab5a. Rab5a fusions with autofluorescent proteins are sensitive and precise early endosome markers for real-time imaging of endosomal transport along microtubules (Figure 12.3.3) and of clathrin-mediated endocytosis in live cells.ref We also offer CellLight Late Endosomes–GFP (C10588) and CellLight Late Endosomes–RFP (C10589) reagents, which are BacMam expression vectors encoding fusions of GFP or RFP with the late-endosomal protein Rab7a.

CellLight Peroxisome-GFP (C10604, Figure 12.3.4) is a BacMam expression vector encoding GFP linked on the C-terminal to a peroxisomal targeting sequence ref (PTS1). Live-cell imaging with the GFP–PTS1 fusion has provided many insights into normal and pathologically abnormal biogenesis and degradation of peroxisomes and the controlling influence of peroxisome proliferator–activated receptors (PPARs).

probes-lysosomes.par.76553.image.275.208.1.s006950-lysosomes-gif


Figure 12.3.1
Human aortic smooth muscle cell (HASMC) labeled with CellLight Lysosomes-RFP (C10504, C10597) and CellLight MAP4-GFP reagents and with Hoechst 33342 nucleic acid stain.

probes-lysosomes.par.52464.image.275.208.1.s006951-lysosomes-gif


Figure 12.3.2
Human aortic smooth muscle cell (HASMC) labeled with CellLight Early Endosomes-GFP (C10586) and Organelle Lights Golgi-OFP reagents and with Hoechst 33342 nucleic acid stain.

probes-lysosomes.par.93381.image.275.208.1.s004481-lysosomes-gif


Figure 12.3.4
HEK 293 cell labeled with CellLight Peroxisomes-GFP (C10604) and CellLight Plasma Membrane-CFP (C10606) reagents

LysoTracker Probes: Acidic Organelle–Selective Cell-Permeant Probes

LysoTracker Probes

Weakly basic amines selectively accumulate in cellular compartments with low internal pH and can be used to investigate the biosynthesis and pathogenesis of lysosomes.ref DAMP is a weakly basic amine frequently used as a probe for acidic organelles; however, DAMP is not fluorescent and therefore must be used in conjunction with anti-DNP antibodies (Anti-Dye and Anti-Hapten Antibodies—Section 7.4) directly or indirectly conjugated to a fluorophore or enzyme in order to visualize the staining pattern.ref The fluorescent probes neutral red (N3246) and acridine orange (A1301, A3568) are also commonly used for staining acidic organelles, though they lack specificity.ref

These limitations have motivated us to search for alternative acidic organelle–selective probes, both for short-term and long-term tracking studies. The LysoTracker probes are fluorescent acidotropic probes for labeling and tracing acidic organelles in live cells. These probes have several important features, including high selectivity for acidic organelles and effective labeling of live cells at nanomolar concentrations. Furthermore, the LysoTracker probes are available in several fluorescent colors ( Summary of the LysoTracker and LysoSensor probes—Table 12.3, Figure 12.3.5), making them especially suitable for multicolor applications.

The LysoTracker probes, which comprise a fluorophore linked to a weak base that is only partially protonated at neutral pH, are freely permeant to cell membranes and typically concentrate in spherical organelles (photo). We have found that the fluorescent LysoTracker probes must be used at very low concentrations—usually about 50 nM—to achieve optimal selectivity. Their mechanism of retention has not been firmly established but is likely to involve protonation and retention in the organelles' membranes, although staining is generally not reversed by subsequent treatment of the cells with weakly basic cell-permeant compounds. Kinetic studies on the internalization of LysoTracker probes indicate that the rates of uptake of these dyes into living cells can occur within seconds. Unfortunately, these lysosomal probes can exhibit an alkalinizing effect on the lysosomes, such that longer incubation with these probes can induce an increase in lysosomal pH. Therefore, we recommend incubating cells with these probes for only one to five minutes at 37°C before imaging.

The larger acidic compartments of cells stained with LysoTracker Red DND-99 (L7528; photo, photo) usually retain their staining pattern following fixation with aldehydes. Simultaneous staining of lysosomes by two LysoTracker dyes—LysoTracker Yellow HCK-123 (L12491) and LysoTracker Red DND-99 (L7528)—yields identical staining patterns when viewed through either the bandpass filter set appropriate for fluorescein or a longpass filter set appropriate for rhodamine (photo). The LysoTracker probes were principally developed for fluorescence microscopy applications. The lysosomal fluorescence in LysoTracker dye–stained cells may constitute only a portion of total cellular fluorescence due to cellular autofluorescence or nonspecific staining. Consequently, successful application of these probes for quantitating the number of lysosomes by flow cytometry or fluorometry will likely depend on the particular cell lines and staining protocols used.

LysoTracker Deep Red dye (L12492) exhibits excitation and emission properties that exactly match the Cy5 fluorescence channel, thereby facilitating multiplex imaging with GFP and RFP markers; LysoTracker Deep Red dye is the ideal marker for four-color imaging with GFP, RFP and a blue-fluorescent counterstain (Figure 12.3.6). Colocalization of lysosome-targeted GFP expression (using CellLight Lysosomes-GFP) with LysoTracker Deep Red fluorescence confirms the lysosome selectivity of LysoTracker Deep Red dye (Figure 12.3.6). LysoTracker Green DND-26 (L7526) was used to identify acidic compartments in a study of a membrane protein that facilitates vesicular sequestration of zinc,ref to visualize acidic organelles labeled with rhodamine B in denervated skeletal muscle ref and to assess acrosomal integrity in cryopreserved bovine spermatozoa.ref This LysoTracker probe also proved useful in a continuous assay for the secretion of pulmonary surfactant by exocytosis of lamellar bodies.ref LysoTracker Red DND-99 provided researchers with a probe for examining lysosome damage in Trypanosoma brucei after specific uptake of cytokine tumor necrosis factor-α,ref for studying apoptosis in organogenesis-stage mouse embryos ref and for determining the subcellular localization of receptor and channel proteins.ref

probes-lysosomes.par.26764.image.275.254.1.s000227-fluorescence-emission-spectra-gif


Figure 12.3.5
Normalized fluorescence emission spectra of 1) LysoTracker Blue DND-22 (L7525), 2) LysoTracker Green DND-26 (L7526) and 3) LysoTracker Red DND-99 (L7528) in aqueous solutions, pH 6.0.

bioprobes-69.par.42158.image.640.216.1.s008205-bioprobes-69-autophagy-5-jpg
Figure 12.3.6 Lysosome-selective staining with LysoTracker Deep Red dye. A) U2OS cells were transduced with CellLight Lysosome-GFP (green, C10596) and labeled with 50 nM LysoTracker Deep Red dye (red, L12492). B) Enlargement of an area of the cell in (A) shows that LysoTracker Deep Red dye (B1, B3) is located in the lumen of the lysosome, as depicted by the membrane labeling of CellLight Lysosome-GFP (green; B2, B3). C) HeLa cells expressing both CellLight Tubulin-GFP (green, C10613) and CellLight Late Endosomes-RFP (red, C10589) were labeled with 50 nM LysoTracker Deep Red dye (pink) and stained with Hoechst 33342 dye (purple, H3570). Images were acquired using a DAPI/FITC/TRITC/Cy5 optical filter set.

Image-iT LIVE Lysosomal and Nuclear Labeling Kit

The Image-iT LIVE Lysosomal and Nuclear Labeling Kit (I34202) provides two stains—red-fluorescent LysoTracker Red DND-99 dye (excitation/emission maxima ~577/590 nm) and blue-fluorescent Hoechst 33342 dye (excitation/emission maxima when bound to DNA ~350/461 nm)—for highly selective staining of lysosomes and the nucleus, respectively, in live, Green Fluorescent Protein (GFP)–transfected cells (photo). When used according to the sample protocol, cell-permeant LysoTracker Red DND-99 dye provides highly selective lysosomal staining with minimal background. A significant amount of specific staining is retained after formaldehyde fixation, although some cytoplasmic background staining may be seen. Hoechst 33342 dye, a cell-permeant nucleic acid stain that is selective for DNA and spectrally similar to DAPI, is UV excitable and emits blue fluorescence when bound to DNA. This dye does not interfere with GFP fluorescence and is retained after fixation and permeabilization. It is not recommended that the dyes be combined into one staining solution; they should instead be used in separate labeling steps, with Hoechst 33342 staining first.

The Image-iT LIVE Lysosomal and Nuclear Labeling Kit contains:

Each kit provides enough staining solution for 500 assays using the protocol provided for labeling live, cultured cells that are adhering to coverslips.

LysoSensor Probes: Acidic Organelle–Selective pH Indicators

LysoSensor Probes

For researchers studying the dynamic aspects of lysosome biogenesis and function in live cells, we have developed the LysoSensor probes—fluorescent pH indicators that partition into acidic organelles. The LysoSensor dyes are acidotropic probes that appear to accumulate in acidic organelles as the result of protonation. This protonation also relieves the fluorescence quenching of the dye by its weakly basic side chain, resulting in an increase in fluorescence intensity. Thus, the LysoSensor reagents exhibit a pH-dependent increase in fluorescence intensity upon acidification, in contrast to the LysoTracker probes, which exhibit fluorescence that is not substantially enhanced at acidic pH.

We offer three LysoSensor reagents that differ in color and pKa ( Summary of the LysoTracker and LysoSensor probes—Table 12.3). Because these probes may localize in the membranes of organelles, it is probable that the pKa values listed in  Summary of the LysoTracker and LysoSensor probes—Table 12.3 will not be equivalent to those measured in cellular environments and that only qualitative and semiquantitative comparisons of organelle pH will be possible. The green-fluorescent LysoSensor probes are available with optimal pH sensitivity in either the acidic or neutral range (pKa ~5.2 or ~7.5 in aqueous buffers). With their low pKa values, LysoSensor Blue DND-167 (L7533) and LysoSensor Green DND-189 (L7535) are almost nonfluorescent except when inside acidic compartments. LysoSensor Yellow/Blue DND-160 (PDMPO, L7545) is unique in that it exhibits both dual-excitation and dual-emission spectral peaks that are pH dependent (Figure 12.3.7, photo) .

LysoSensor Yellow/Blue DND-160 exhibits predominantly yellow fluorescence in acidic organelles, and in less acidic organelles it exhibits blue fluorescence. Dual-emission measurements facilitate ratio imaging of the pH in acidic organelles such as lysosomes,ref myeloid leukemic cells ref and acidic vacuoles of plant cells.ref LysoSensor Yellow/Blue DND-160, frequently referred to by the acronym PDMPO, has been widely utilized as a tracer of silica deposition and transport in marine diatoms.ref Kinetic studies on the internalization of LysoSensor Yellow/Blue DND-160 indicate that the probe is taken up by live cells within seconds. Unfortunately, this lysosomal probe can exhibit an alkalinizing effect on the lysosomes, such that longer incubation with this probe can induce an increase in lysosomal pH. Therefore, it is a useful pH indicator only when incubation times are kept short; we recommend incubating cells for only one to five minutes before imaging.

The cell-permeant LysoSensor probes can be used singly or in combination to investigate the acidification of lysosomes and alterations of lysosomal function or trafficking that occur in cells. For example, lysosomes in some tumor cells have a lower pH than normal lysosomes,ref whereas other tumor cells contain lysosomes with higher pH.ref In addition, cystic fibrosis and other diseases result in defects in the acidification of some intracellular organelles, and the LysoSensor probes are useful in studying these aberrations.ref LysoSensor Green DND-189 has been used to selectively label acidic compartments within granule cell neurites ref and, along with LysoSensor Green DND-153, to examine the acidification of endosomes and lysosomes in a mutant CHO cell line.ref LysoSensor Yellow/Blue DND-160 was employed in a study that demonstrated the involvement of lysosomes in the acquired drug-resistance phenotype of a doxorubicin-selected variant of human U-937 myeloid leukemia cells.ref

As with the LysoTracker probes, the cell-permeant LysoSensor probes were originally developed for fluorescence microscopy applications. The lysosomal fluorescence in LysoSensor dye–stained cells may constitute only a portion of total cellular fluorescence due to cellular autofluorescence or nonspecific staining. Therefore, the successful application of these probes for quantitating the number of lysosomes or their pH by flow cytometry or fluorometry will likely depend on the particular cell lines and staining protocols used.

probes-lysosomes.par.44793.image.559.266.1.s000228-lysosensor-yellow-blue-gif
Figure 12.3.7 The pH-dependent spectral response of LysoSensor Yellow/Blue DND-160 (L7545): A) fluorescence excitation spectra and B) fluorescence emission spectra.

LysoSensor Yellow/Blue Dextran

We have prepared a 10,000 MW dextran conjugate of the LysoSensor Yellow/Blue dye (L22460). As this labeled dextran is taken up by the cells and moves through the endocytic pathway, the fluorescence of the LysoSensor dye changes from blue fluorescent in the near-neutral endosomes to longer-wavelength yellow fluorescent in the acidic lysosomes.ref The greatest change in fluorescence emission occurs near the pKa of the dye at pH ~3.9. Unlike the cell-permeant LysoSensor dyes, LysoSensor Yellow/Blue dextran allows measurement of pH in lysosomes using either fluorescence microscopy (photo) or flow cytometry.

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DAMP and Other Lysosomotropic Probes

DAMP and its alternatives

The reagent DAMP (N-(3-((2,4-dinitrophenyl)amino)propyl)-N-(3-aminopropyl)methylamine, dihydrochloride) is a weakly basic amine that is taken up in acidic organelles of live cells. This cell-permeant acidotropic reagent can be detected with anti-DNP antibodies (Anti-Dye and Anti-Hapten Antibodies—Section 7.4), including those labeled with Alexa Fluor 488 dye, biotin, Qdot 655 nanocrystal or enzymes,ref making DAMP broadly applicable for detecting acidic organelles by electron and light microscopy. For example, DAMP has been used to investigate:

  • Endocytic and secretory pathways ref
  • Defective acidification of intracellular organelles in cells from cystic fibrosis patients ref
  • Dependence on pH of the conversion of proinsulin to insulin in beta cells ref
  • Development of autophagic vacuoles ref
  • Location of intracellular acidic compartments during viral infectionref

As alternatives to DAMP, our cell-permeant fluorescent LysoTracker and LysoSensor probes described above have significant potential in many of these applications. Because they can be visualized directly without any secondary detection reagents, the LysoTracker and LysoSensor reagents enable researchers to study acidic organelles and follow their dynamic processes in live cells.

RedoxSensor Red CC-1 Stain

RedoxSensor Red CC-1 stain (2,3,4,5,6-pentafluorotetramethyldihydrorosamine) passively enters live cells and is subsequently oxidized in the cytosol to a red-fluorescent product (excitation/emission maxima ~540/600 nm), which then accumulates in the mitochondria. Alternatively, this nonfluorescent probe may be transported to the lysosomes where it is oxidized. The differential distribution of the oxidized product between mitochondria and lysosomes appears to depend on the redox potential of the cytosol.ref In proliferating cells, mitochondrial staining predominates; whereas in contact-inhibited cells, the staining is primarily lysosomal (photo). The best method we have found to quantitate the distribution of the oxidized product is to use the mitochondrion-selective MitoTracker Green FM stain (M7514) in conjunction with the RedoxSensor Red CC-1 stain.ref

Other Lysosomotropic Probes

BODIPY FL histamine combines the pH-insensitive, bright green-fluorescent BODIPY FL dye with the weakly basic imidazole moiety of histamine. When used at low concentrations, this probe selectively stains lysosomes (photo).

Our high-purity neutral red (N3246) is a common lysosomal probe that stains lysosomes a fluorescent red.ref It has also been used to determine the number of adherent and nonadherent cells in a microplate assay ref and to stain cells in brain tissue.ref

The DNA intercalator acridine orange (A1301, A3568) has also been reported to be a useful lysosomotropic reagent.ref

Cell-Permeant Probes for Yeast Vacuoles

Biogenesis of the yeast vacuole has been extensively studied as a model system for eukaryotic organelle assembly.ref Using a combination of genetic and biochemical approaches, researchers have isolated a large collection of yeast vacuolar protein sorting (vps) mutants ref and characterized the vacuolar H+-ATPase (V-ATPase) responsible for compartment acidification.ref To facilitate the investigation of yeast vacuole structure and function, we offer membrane-permeant reagents and a Yeast Vacuole Marker Sampler Kit (Y7531).

FUN 1 Vital Cell Stain for Yeast

The FUN 1 vital cell stain (F7030) exploits endogenous biochemical processing mechanisms that appear to be well conserved among different species of yeast and other fungi.ref When used at micromolar concentrations, the FUN 1 cell stain is freely taken up by several species of yeast and fungi and converted from a diffusely distributed pool of yellow-green–fluorescent intracellular stain into compact red-orange–fluorescent intravacuolar structures (photo). This conversion requires both plasma membrane integrity and metabolic capability. Only metabolically active cells are marked clearly with fluorescent intravacuolar structures, while dead cells exhibit extremely bright, diffuse, yellow-green fluorescence ref (Figure 12.3.8, photo). FUN 1 staining has been used to detect antifungal activity against Candida species ref and to measure susceptibility of fungi to fungicides by flow cytometry.ref The FUN 1 cell stain is also available as a component in the LIVE/DEAD Yeast Viability Kit (L7009, Viability and Cytotoxicity Assay Kits for Diverse Cell Types—Section 15.3).

 

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Figure 12.3.8
Fluorescence emission spectra of a Saccharomyces cerevisiae suspension that has been stained with the FUN 1 cell stain, which is available separately (F7030) or in the LIVE/DEAD Yeast Viability Kit (L7009). After the FUN 1 reagent was added to the medium, the fluorescence emission spectrum (excited at 480 nm) was recorded in a spectrofluorometer at the indicated times during a 30-minute incubation period. The shift from green (G) to red (R) fluorescence reflects the processing of FUN 1 by metabolically active yeast cells.

FM 4-64 and FM 5-95

One of our FM styryl dyes, FM 4-64, has been reported to selectively stain yeast vacuolar membranes with red fluorescence ref (excitation/emission maxima ~515/640 nm). This styryl dye is proving to be an important tool for visualizing vacuolar organelle morphology and dynamics, for studying the endocytic pathway and for screening and characterizing yeast endocytosis mutants.ref We offer FM 4-64 in 1 mg vials (T3166) or specially packaged in 10 vials of 100 µg each (T13320). The increasing number of successful applications for our FM dyes has prompted us to synthesize FM 5-95 (T23360), a slightly less lipophilic analog of FM 4-64 with essentially identical spectroscopic properties.

Yeast Vacuole Marker Sampler Kit

The Yeast Vacuole Marker Sampler Kit (Y7531) contains sample quantities of a series of both novel and well-established vacuole marker probes that show promise for the study of yeast cell biology:

  • 5-(and 6-)Carboxy-2',7'-dichlorofluorescein diacetate (carboxy-DCFDA) ref
  • CellTracker Blue CMAC ref
  • Aminopeptidase substrate Arg-CMAC (photo)
  • Dipeptidyl peptidase substrate Ala-Pro-CMAC
  • Yeast vacuole membrane marker MDY-64 ref (photo)

Our experiments have demonstrated that several cell-permeant derivatives of 7-amino-4-chloromethylcoumarin (CMAC) are largely sequestered within yeast vacuoles. The corresponding 7-amino-4-methylcoumarin derivatives are known to be substrates for yeast vacuolar enzymes.ref This sampler kit's three coumarin-based vacuole markers selectively stain the lumen of the yeast vacuole. To complement the blue-fluorescent staining of the lumen, we provide a novel green-fluorescent membrane marker MDY-64 for staining the yeast vacuole membrane. Membrane staining can also be accomplished using the red-fluorescent probe FM 4-64, as described above. The commonly used vacuole marker 5-(and 6-)carboxy-2',7'-dichlorofluorescein diacetate (carboxy-DCFDA) is supplied for use as a standard.ref Three of the components in the Yeast Vacuole Marker Sampler Kit—CellTracker Blue CMAC (C2110Membrane-Permeant Reactive Tracers—Section 14.2), the proprietary yeast vacuole membrane marker MDY-64 ref (Y7536) and carboxy-DCFDA (C369Viability and Cytotoxicity Assay Reagents—Section 15.2)—are also available separately for those researchers who find that one of these dyes is well suited for their application.

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SelectFX Alexa Fluor 488 Peroxisome Labeling Kit

Peroxisomes, single membrane–bound vesicles found in most eukaryotic cells, function to enzymatically oxidize fatty acids and to subsequently catalyze the breakdown of H2O2, a by-product of fatty acid degradation. Peroxisomes are similar in size to lysosomes (0.5–1.5 µm). The SelectFX Alexa Fluor 488 Peroxisome Labeling Kit (S34201) provides all the reagents required for labeling peroxisomes in fixed cells, including cell fixation and permeabilization reagents. To specifically detect peroxisomes, this kit uses an antibody directed against peroxisomal membrane protein 70 (PMP 70), which is a high-abundance integral membrane protein in peroxisomes,ref and an Alexa Fluor 488 dye–labeled secondary antibody (photo). The Alexa Fluor 488 dye exhibits bright green fluorescence that is compatible with filters and instrument settings appropriate for fluorescein. PMP 70 is significantly induced by administration of hypolipidemic agents, in parallel with peroxisome proliferation and the induction of peroxisomal fatty acid β-oxidation enzymes.ref

Each SelectFX Alexa Fluor 488 Peroxisome Labeling Kit contains:

  • Rabbit IgG anti–peroxisomal membrane protein 70 (PMP 70) antibody
  • Highly cross-adsorbed Alexa Fluor 488 goat anti–rabbit IgG antibody
  • Concentrated fixative solution
  • Concentrated phosphate-buffered saline (PBS)
  • Concentrated permeabilization solution
  • Concentrated blocking solution
  • Detailed protocols for mammalian cell preparation and staining (SelectFX Alexa Fluor 488 Peroxisome Labeling Kit)

Spectral and Chemical Data Table

For a detailed explanation of column headings, see Definitions of Data Table Contents

Cat #MWStorageSolubleAbsECEmSolventNotes
A1301
acridine orange
301.82LH2O, EtOH48965,000520MeOH 
A3568
acridine orange
301.82RR,LH2O48965,000520MeOH1
BODIPY FL histamine385.22F,D,LDMSO50382,000511MeOH 
DAMP384.26F,D,LpH <7, DMF34916,000noneMeOH 
F7030
FUN 1 cell stain
528.84F,D,LDMSO50871,000nonepH 71, 2
L7525
LysoTracker Blue DND-22
524.40F,D,LDMSO3739600422pH 71, 3
L7526
LysoTracker Green DND-26
398.69F,D,LDMSO50480,000511MeOH1
L7528
LysoTracker Red DND-99
399.25F,D,LDMSO57778,000590MeOH1, 4
L7533
LysoTracker Blue DND-167
376.50F,D,LDMSO37311,000425pH 51, 5
L7535
LysoTracker Green DND-189
398.46F,D,LDMSO44316,000505pH 51, 5
L7545
LysoTracker Yellow/Blue DND-160
366.42F,D,LDMSO38421,000540pH 31, 6
L12491
LysoTracker Yellow HCK-123
364.40F,D,LDMSO46622,000536MeOH1
L22460
LysoTracker Yellow/Blue dextran, 10,000 MW
see NotesF,D,LH2O384ND540pH 36, 7, 8
N3246
neutral red
288.78D,LH2O, EtOH54139,000640see Notes9
RedoxSensor Red CC-1434.41F,D,L,AADMSO23952,000noneMeOH 
T3166
FM 4-64
607.51D,LH2O, DMSO50547,000725see Notes10, 11
T13320
FM 4-64
607.51D,LH2O, DMSO50547,000725see Notes10, 11
T23360
FM 5-95
565.43D,LH2O, DMSO56043,000734CHCl310
Y7536
MDY-64
384.48F,LDMSO, DMF45627,000505MeOH 
  1. This product is supplied as a ready-made solution in the solvent indicated under "Soluble."
  2. F7030 is fluorescent when bound to DNA (Em = 538 nm). Uptake and processing of the dye by live yeast results in red-shifted fluorescence (Em ~590 nm).
  3. L7525 has structured absorption and fluorescence spectra with additional peaks at Abs = 394 nm and Em = 401 nm.
  4. The pKa of the dimethylamino substituent of LysoTracker Red DND-99 is 7.5.ref The absorption and fluorescence spectra of the dye are insensitive to protonation of this substituent.
  5. This LysoSensor dye exhibits increasing fluorescence as pH decreases with no spectral shift. L7533 has additional absorption and fluorescence emission peaks at Abs = 394 nm and Em = 401 nm.
  6. LysoSensor Yellow/Blue spectra are pH dependent. Abs and Em shift to shorter wavelengths at pH >5.
  7. The molecular weight is nominally as specified in the product name but may have a broad distribution.
  8. ND = not determined.
  9. Spectra of N3246 are pH dependent (pKa ~6.7). Data reported are for 1:1 (v/v) EtOH/1% acetic acid.
  10. FM 4-64 and FM 5-95 are nonfluorescent in water. For two-color imaging in GFP-expressing cells, these dyes can be excited at 568 nm with emission detection at 690–730 nm.ref
  11. Abs, EC and Em determined for dye bound to detergent micelles (20 mg/mL CHAPS in H2O). These dyes are essentially nonfluorescent in pure water.

仅供科研使用,不可用于诊断目的。