The fluorescence scanning of microgels stained for glycoproteins with fluorescein isothiocyanate-labelled concanavalin A.

A technique is presented which allows one to label and quantitate glycoproteins. Small amounts of protein from biological samples (0.5-2.5 microgram for mixtures and less for individual proteins) are separated by sodium dodecyl sulfate gel electrophoresis on 1-30% polyacrylamide gradient microgels. The gels are stained with Co-omassie Brillant Blue R250 to evaluate relative migration or fixed in 2-propanol/acetic acid and stained with fluorescein isothiocyanate-labelled concanavalin A. The microgels are then scanned using a fluorescence microscope controlled by a computer, although simpler configurations are possible. Standards of known carbohydrate composition (e.g., glucose oxidase) are used for comparative purposes. Glycoproteins in the order of 5-30 ng protein (or 1-5 ng carbohydrate) can be detected without difficulty. This technique may prove valuable in evaluating glycoproteins when the available material is limited.     

High sensitivity quantification of RNA from gels and autoradiograms with affordable optical scanning.

To increase sensitivity and to improve normalization of RNA levels in Northern blot analysis, a comparatively inexpensive optical scanner was utilized for digitizing photonegatives of ethidium bromide stained gels and autoradiograms. The optical scanner captures the image with a maximum resolution of 300 dots per inch by assigning one of 256 gray levels (8-bit) to each dot in the image. With the use of the public domain NIH Image program (requires a Macintosh II and an 8-bit video card), gel or autoradiogram bands in the digitized image are selected and their average gray scale density measured. We found that the digitized image of a photonegative of a TAE (Tris-acetate/EDTA) agarose gel, loaded incrementally with 50-1500 ng total RNA, produced a linear response over a 4-fold range down to 100 ng (R2 greater than 0.950). In utilizing "quantification" gels like this, RNA samples that are too dilute or too small for traditional spectrophotometric techniques can be normalized and loaded uniformly onto subsequent Northern gels. Results from autoradiogram scans demonstrate highly linear gray scale responses over a 4-fold range of total RNA (R2 greater than 0.950) that are reproducible with different blots and probe types (e.g., riboprobe, cDNA and oligonucleotide). In addition, we describe a normalization technique using a 30-mer oligonucleotide probe for rat 28S ribosomal RNA as a measure of total RNA loaded per gel lane. Altogether, this scanning, ribosomal RNA normalization system allows the measurement of relative changes between 20% and 400% using standard autoradiographic methods.     

An improved staining procedure for the detection of the peroxidase activity of cytochrome P-450 on sodium dodecyl sulfate polyacrylamide gels

The use of 3,3′,5,5′-tetramethylbenzidine-H₂O₂ as a stain for the peroxidase activity of cytochrome P-450 (or cytochrome P-450 in sodium dodecyl sulfate polyacrylamide gels is described in this report. This reagent can be used to detect very low levels of heme-associated peroxidase activity. The blue-stained bands on polyacrylamide gels are distinet, and the color is stable. The stained gels can be photographed or scanned at 690 nm because the gel background remains clear. The stain is easily removed from the gels to permit subsequent protein staining. Staining first for peroxidase activity has no effect on the subsequent protein staining profile. The peroxidase activity of cytochrome P-450 (or cytochrome P-420) in immunoprecipitates in Ouchterlony double diffusion plates can also be detected using this reagent.     

Spatial normalization of one-dimensional electrophoretic gel images

A strategy for using processed, digitized images of one-dimensional electrophoretic gels to facilitate the analysis of large sets of overlapping clones is described. The images are acquired from fluorescently stained gels or from transilluminated gel photographs using a cooled, solid-state charge-coupled device camera. By employing sets of bands in the size-standard lanes as reference points, all the gel images are spatially normalized to a common reference template. After normalization, lane images from different gels can be compared as though the gels had been electrophoresed under identical, uniform-field conditions. Applications of this procedure to the analysis of a large set of overlapping lambda clones from chromosome VII of Saccharomyces cerevisiae and to the estimation of fragment sizes are illustrated.     

Ultraviolet imaging densitometry of unstained gels for two-dimensional electrophoresis

A system suitable for ultraviolet imaging densitometry of two-dimensional electrophoretic gels that are unstained is described, together with its applications. A flying-spot densitometer linked with a personal computer was used for data acquisition, generation of mapping data, and image processing. Randomly distributed zones of proteins on two-dimensional gels were detected at 280 nm without being stained by two-dimensional scanning, and the densitometric value of each pixel (0.2 x 0.2 mm) was memorized by the computer, which generated a mapping pattern with density contours. The amount and densitometric value of cytochrome c had a linear relationship in the range of 2-200 micrograms. Zone locations of bovine liver proteins separated on two-dimensional gels were indicated on a map expressed in X-Y coordinates, and the pIs and molecular weights could be calculated from the map by use of pI and molecular weight markers on the same gel.     

Quantitation of specific proteins in polyacrylamide gels by the elution of fast green FCF

The quantitation of proteins in polyacrylamide gels stained with Fast Green FCF has been investigated using a modification of the elution technique originally described by Fenner et al. (Fenner, C., Traut, R.R., Mason, D.T. and Wikman-Coffelt, J. (1975) Anal. Biochem. 63, 595–602) for Coomassie Blue and adapted by Medugorac (Medugorac, I. (1979) Basic Res. Cardiol. 74, 406–416) for use with proteins stained with Fast Green FCF. The elution of dye from stained protein was accomplished using 1.0 M NaOH instead of aquoeus pyridine as required by the original method. The primary advantages of our modification are that the time required for protein quantitation has been considerably reduced and the use of toxic organic solvents has been eliminated. We have investigated the applicability of the method to several different proteins and our results indicate: (a) The quantity of Fast Green eluted from specific proteins is proportional to the quantity of protein applied to the gel, but varies for each individual protein. (b) The method allows quantitation over a very wide range of protein (1–800 μg). (c) Quantitation of protein is independent of the width of the stained bands as well as acrylamide concentration. (d) The method is applicable to gels of many types including disc, slab and continuous gradient gel, (e) Protein can be estimated from the patterns obtained by two-dimensional polyacrylamide gel electrophoresis. (f) The presence of Triton X-100 in gel and protein sample does not affect quantitation; the method is applicable to gels containing SDS provided that SDS is removed prior to staining. (g) Precipitation of protein with 12.5% TCA following electrophoresis does not interfere with quantitation. (h) The reproducibility of the technique is excellent, with standard deviations being less than 10% of the mean in all cases. This method appears highly versatile but requires appropriate standards for the quantitation of individual proteins.     

Extraction of proteins and peptides from Coomassie Blue-stained sodium dodecyl sulfate--polyacrylamide gels.

A method is described for extracting proteins and peptides from stained sodecyl sulfate-polyacrylamide gels. Coomassie blue and sodium dodecyl sulfate present in stained gel sections are removed to allow subsequent analysis of the peptides (e.g., amino acid analysis or tryptic digestion and fingerprinting). The method is simple, requires no radioisotopes or special equipment, and can be carried out with a minimum of handling of the sample. The process can be used for samples at the nanomole level with recoveries of 90%.     

Quantitation of submicrogram amounts of protein using coomassie brilliant blue R on sodium dodecyl sulfate-polyacrylamide slab-gels.

A sodium dodecyl sulfate (SDS)-polyacrylamide slab-gel system was used to study the use of Coomassie brilliant blue (CB) as a quantitative stain. Quantitation curves are shown for tubulin, cytochrome c, histone, and actin from gels stained with CB. A comparison was made of three identical gels using an actin sample and stained with CB, fast green and buffalo black. CB staining was found to be quantitative in the 0.05–2.75-μg range as well as possessing an order of magnitude increase in sensitivity over other stains tested.     

Mapping Diffusion in a Living Cell via the Phasor Approach

Diffusion of a fluorescent protein within a cell has been measured using either fluctuation-based techniques (fluorescence correlation spectroscopy (FCS) or raster-scan image correlation spectroscopy) or particle tracking. However, none of these methods enables us to measure the diffusion of the fluorescent particle at each pixel of the image. Measurement using conventional single-point FCS at every individual pixel results in continuous long exposure of the cell to the laser and eventual bleaching of the sample. To overcome this limitation, we have developed what we believe to be a new method of scanning with simultaneous construction of a fluorescent image of the cell. In this believed new method of modified raster scanning, as it acquires the image, the laser scans each individual line multiple times before moving to the next line. This continues until the entire area is scanned. This is different from the original raster-scan image correlation spectroscopy approach, where data are acquired by scanning each frame once and then scanning the image multiple times. The total time of data acquisition needed for this method is much shorter than the time required for traditional FCS analysis at each pixel. However, at a single pixel, the acquired intensity time sequence is short; requiring nonconventional analysis of the correlation function to extract information about the diffusion. These correlation data have been analyzed using the phasor approach, a fit-free method that was originally developed for analysis of FLIM images. Analysis using this method results in an estimation of the average diffusion coefficient of the fluorescent species at each pixel of an image, and thus, a detailed diffusion map of the cell can be created.     

A method for in-gel fluorescent visualization of proteins after native and sodium dodecyl sulfate polyacrylamide gel electrophoresis

We have developed a simple one-step 30-min method for fluorescent visualization of proteins in native and sodium dodecyl sulfate polyacrylamide gel electrophoresis (PAGE) gels. The method is based on formation of strong fluorophores via potassium ferricyanide-provoked oxidation of tryptophan (Trp). Following PAGE, gels are soaked in water solution of potassium ferricyanide (100 mM) and NaOH (1 M) and are kept in the dark for 30 min. Gels are then transferred to water and scanned. The sensitivity of the method was slightly lower compared with standard Coomassie Brilliant Blue (CBB) staining. The method can be useful when rapid acquisition of data is of the essence. After preview, gels can be post-stained using the CBB protocol for further analysis. The intensity of fluorescence is dependent on Trp number, so the protocol might find application in the quantification of Trp residues as illustrated here. Importantly, there is room for improvement of the method. Namely, according to excitation–emission matrix analysis of stained protein bands, maximal fluorescence intensity (at 345/460 nm) was 3.5-fold higher compared with the settings that were available on a commercial imager (395/525 nm). As a supplement, we present an upgrade of the previously described method for in-gel detection of non-heme iron-binding proteins that also employs potassium ferricyanide.     

"Liquidless" cell staining by dye diffusion from gels and analysis by laser scanning cytometry: potential application at microgravity conditions in space

BACKGROUND: Conventional staining of cells or tissue sections on microscope slides involves immersing the slides into solutions of dyes then rinsing to remove the unbound dye. There are instances, however, when use of stain solutions is undesirable-e.g., at microgravity conditions in space, where the possibility of accidental spill (many dyes are known carcinogens) introduces health hazard. Likewise, transporting bulk of liquid stains and rinses may be burdensome in certain situations such as field expeditions or combat. METHODS: The "liquidless" staining procedure is proposed in which the dyes are contained in thin strips of hydrated polyacrylamide or gelatin gels that have been presoaked in the stain solutions. Fluorochromes that have affinity to DNA (propidium iodide, PI; 4,6-diamidino-2-phenylindole, DAPI, Hoechst 33342) or to protein (sulforhodamine 101) were used to saturate the gels. The gel strips were placed over the prefixed cells or tissue sections deposited on microscope slides and relatively low (20 g/cm2) pressure was applied to ensure the contact. The cells were also stained by using commercially available mounting media into which DAPI or PI were admixed. Intensity of fluorescence of the PI stained cells was measured by laser scanning cytometry (LSC). RESULTS: Satisfactory cell and tissue staining, with minimal background, was achieved after 10-20 min contact between the cells and gels. Optimal concentrations of the dyes in the solutions used to presoak the gels was found to be 2-4-fold higher than the concentrations used routinely in cytometry. The measurements of intensity of cellular fluorescence by LSC revealed that the staining of DNA was stoichiometric as reflected by the characteristic cellular DNA content frequency histograms with distinct G1, S, and G2/M cell populations and 2:1 ratio of G2/M to G1 peak fluorescence. Individual gels can be saturated with more than a single dye-e.g., to obtain differential DNA and protein staining. Cell staining with DAPI or PI in the gelatin-based mounting media led to high fluorescence background while staining with DAPI in "aqueous" medium was satisfactory. CONCLUSIONS: Relatively fast staining of cells or tissue sections on microscope slides can be achieved by nonconvective dye diffusion using hydrated gels permeated with the dyes, applied to cells at low pressure. The quality of the staining provided by this methodology is comparable to conventional cell staining in dye solutions.     

Hydrazinoacridine staining of proteins and glycoproteins in polyacrylamide gels

The histochemical method for staining polyaldehydes in tissue sections with p-hydrazinoacridine has been adapted for use in polyacrylamide gels. While staining of histological preparations was reported to be specific for polyaldehydes and independent of bisulfite, both glycoproteins (β chain of haptoglobin) and nonglycoproteins (lysozyme and α chain of haptoglobin) were stained following periodate oxidation, and satisfactory results were highly dependent on the presence of bisulfite. Hydrazinoacridine staining of periodate-treated gels produced an extremely sensitive fluorescent labeling of the haptoglobin β chain and also stained haptoglobin α chain and lysozyme. The proteins could be visualized under visible light as yellow bands which were scanned spectrophotometrically at 440 nm. The β chain of haptoglobin could be subjectively distinguished from the nonglycoproteins both by differential intensity of staining with hydrazinoacridine and Coomassie brilliant blue and by the yellow nature of the fluorescence. The sensitivity of hydrazinoacridine staining of the β chain of haptoglobin compared favorably to that of the commonly used periodic acid-Schiff staining procedures and provided the advantage that nonglycoproteins in complex mixtures could be localized in the gels.     

Computer video acquisition and analysis system for biological data

The BIAS (Biological Image Analysis System) was developed to:(i) permit accurate entry and image processing of biologicaldata; (ii) minimize the need for specialized hardware; and (iii)aid in the human genome mapping and other projects. The firstmouse/cursor key-driven module was designed to be user interactiveand readily accessible to many laboratories. It contains theDRSNDS programs which automate the entering of data in a systematicformat. The types of data that can be entered utilizing thismodule are DNA — RNA gels from either a positive or negativePolaroid^TM image, autoradiograms or biotinylated images fromSouthern, Northern and dot or slot blot hybridization analyses.The image is acquired using a video camera and then digitizedfor subsequent analysis. During the analysis graphical representationsof the intermediate results are provided to assure user confidence.At any point within the program the user may obtain on-linehelp with the current task. The output displays the mol. wtof each individual component in the appropriate context. Thepresent version of the program produces results comparable witha human interpreter for some data. Band shifting and opticaldensity calculations are in a prototype form to permit evaluationof various techniques. Future work is directed at expandingthe system's capabilities to interpret data from other biologicalanalyses including DNA sequencing gels. Received on December 1, 1987; accepted on December 12, 1987     

Copy number determination of different derivatives of the streptomycete mini-plasmid pSLG33

Copy numbers of the streptomycete plasmid vector pRS410 and five other recombinant plasmid derivatives of the original cryptic streptomycete plasmid pSLG33 were determined using calibrated laser densitometry. DNA preparations, electrophoretically separated on agarose gels, were stained with ethidium bromide, photographed and the negatives were subsequently scanned in a laser densitometer. The pSLG33 replicon is very stable, as no effect of the selective pressure was observed. It is a multicopy plasmid with up to 220 detected copies per chromosome. The use of deletion and/or insertion mutants allowed us to define two regions of the pSLG33 molecule involved in the control of plasmid replication.     

Evaluation of densitometry data using interactive computer graphics: Application to DNA agarose gels

A method of analyzing DNA agarose gels using interactive computer graphics is described. After electrophoresis in an alkaline agarose gel, DNA is neutralized, stained with ethidium bromide and excited with ultraviolet radiation. The resulting fluorescent distribution on the gel is photographed, and the negative scanned by a digitizing densitometer. The data is subsequently analyzed using a computer program developed to facilitate manipulation and selection of data from the densitometer trace. The method has been applied to determine pyrimidine dimer yields in DNA from human lymphocytes exposed to UV radiation. The technique significantly reduces the time required to analyze such data, while also providing greater accuracy. The method could be easily adapted to assist in similar analyses of other macromolecules such as RNA or proteins.     

Vacuolar Localization of Endoproteinases EP(1) and EP(2) in Barley Mesophyll Cells

The localization of two previously characterized endoproteinases (EP₁ and EP₂) that comprise more than 95% of the protease activity in primary Hordeum vulgare L. var Numar leaves was determined. Intact vacuoles released from washed mesophyll protoplasts by gentle osmotic shock and increase in pH, were purified by flotation through a four-step Ficoll gradient. These vacuoles contained endoproteinases that rapidly degraded purified barley ribulose-1,5-bisphosphate carboxylase (RuBPCase) substrate. Breakdown products and extent of digestion of RuBPCase were determined using 12% polyacrylamide-sodium dodecyl sulfate gels. Coomassie brilliant blue- or silver-stained gels were scanned, and the peaks were integrated to provide quantitative information. The characteristics of the vacuolar endoproteinases (e.g. sensitivity to various inhibitors and activators, and the molecular weights of the breakdown products, i.e. peptide maps) closely resembled those of purified EP₁ and partially purified EP₂. It is therefore concluded that EP₁ and EP₂ are localized in the vacuoles of mesophyll cells.     

Digital microscopy for multiparameter FISH imaging

Fluorescence in situ hybridization (FISH) allows the direct localization of DANN and RNA sequences on chromosomes, in cells and in tissue. The technique is based on hybridization between target sequences of single-strand DNA of chromosomes or cell nuclei with marked complementary specimens. The signal is amplified using fluorochrome-marked specific antibodies and made visible under a microscope. Signals from painted chromosomes, stained subchromosomal regions or localized single probes are generally visible when an epifluorescence microsope is used. In order to view and display different fluorochromes, single filter sets, as well as double and triple bandpass filters, are in use. For multiple fluoroscence imaging, lenses with high numerical aperture, mostly oil immersion systems, are recommended. In conventional photomicrography, triple exposure on high-speed film (e.g., 400-1,000 ASA) is more or less the limitation. Opto=electronic methods using a CCD and laser summing techniques have considerably extended the application range of multiple fluorescence techniques. By means of digitized images, simultaneous detection of multiple-labelled objects and ratio imaging up to 24 colors are possible today. Current FISH approaches are based on chromosome-painting probes to distinguish all 24 chromosomes by their unique spectral signatures.     

Electrophoretic gel image analysis software for the molecular biology laboratory

We present GelReader 1.0, a microcomputer program designed to make precision, digital analysis of one-dimensional electrophoretic gels accessible to the molecular biology laboratory of modest means. Images of electrophoretic gels are digitized via a desktop flatbed scanner from instant photographs, autoradiograms or chromogenically stained blotting media. GelReader is then invoked to locate lanes and bands and generate a report of molecular weights of unknowns, based on specified sets of standards. Frequently used standards can be stored in the program. Lanes and bands can be added or removed, based upon users' subjective preferences. A unique lane histogram feature facilitates precise manual addition of bands missed by the software. Image enhancement features include palette manipulation, histogram equalization, shadowing and magnification. The user interface strikes a balance between program autonomy and user intervention, in recognition of the variability in electrophoretic gel quality and users' analytical needs.     

Automated tracking of facial features in patients with facial neuromuscular dysfunction

Facial neuromuscular dysfunction severely impacts adaptive and expressive behavior and emotional health. Appropriate treatment is aided by quantitative and efficient assessment of facial motion impairment. We validated a newly developed method of quantifying facial motion, automated face analysis (AFA), by comparing it with an established manual marking method, the Maximal Static Response Assay (MSRA). In the AFA, motion of facial features is tracked automatically by computer vision without the need for placement of physical markers or restrictions of rigid head motion. Nine patients (seven women and two men) with a mean age of 39.3 years and various facial nerve disorders (five with Bell's palsy, three with trauma, and one with tumor resection) participated. The patients were videotaped while performing voluntary facial action tasks (brow raise, eye closure, and smile). For comparison with MSRA, physical markers were placed on facial landmarks. Image sequences were digitized into 640 x 480 x 24-bit pixel arrays at 30 frames per second (1 pixel congruent with0.3 mm). As defined for the MSRA, the coordinates of the center of each marker were manually recorded in the initial and final digitized frames, which correspond to repose and maximal response. For the AFA, these points were tracked automatically in the image sequence. Pearson correlation coefficients were used to evaluate consistency of measurement between manual (the MSRA) and automated (the AFA) tracking methods, and paired t tests were used to assess the mean difference between methods for feature tracking. Feature measures were highly consistent between methods, Pearson's r = 0.96 or higher, p < 0.001 for each of the action tasks. The mean differences between the methods were small; the mean error between methods was comparable to the error within the manual method (less than 1 pixel). The AFA demonstrated strong concurrent validity with the MSRA for pixel-wise displacement. Tracking was fully automated and provided motion vectors, which may be useful in guiding surgical and rehabilitative approaches to restoring facial function in patients with facial neuromuscular disorders.     

Western blots using stained protein gels.

A general method is described for the electrophoretic transfer of proteins from stained gels to membranes and subsequent Western detection of specific proteins on the stained membranes. Proteins are separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis, and the gels are stained using either of two different methods followed by electrophoretic transfer to nitrocellulose or Immobilon-P membranes. The transferred proteins remain stained during immunodetection, providing a set of background markers for protein location and size determination.