A simple method for estimation of cell cycle parameters

A simple and convenient method of estimating cell cycle parameters was proposed. The means and the standard deviations of G1, S and G2 phase durations in the cell cycle of an ascites tumor, LY-1, a sub-line of Yoshida sarcoma, were estimated by plotting the fraction of the labelled mitoses on probit paper. The frequency distribution of the duration of each phase was assumed to follow a normal distribution. When this method was compared with the Monte Carlo program where each phase duration was assumed to follow a log-normal distribution, results by the two methods were in good agreement.     

Automated live cell imaging of green fluorescent protein degradation in individual fibroblasts.

To accurately interpret the data from fluorescent proteins as reporters of gene activation within living cells, it is important to understand the kinetics of the degradation of the reporter proteins. We examined the degradation kinetics over a large number (>1,000) of single, living cells from a clonal population of NIH3T3 fibroblasts that were stably transfected with a destabilized, enhanced green fluorescent protein (eGFP) reporter driven by the tenascin-C promoter. Data collection and quantification of the fluorescence protein within a statistically significant number of individual cells over long times (14 h) by automated microscopy was facilitated by culturing cells on micropatterned arrays that confined their migration and allowed them to be segmented using phase contrast images. To measure GFP degradation rates unambiguously, protein synthesis was inhibited with cycloheximide. Results from automated live cell microscopy and image analysis indicated a wide range of cell-to-cell variability in the GFP fluorescence within individual cells. Degradation for this reporter was analyzed as a first order rate process with a degradation half-life of 2.8 h. We found that GFP degradation rates were independent of the initial intensity of GFP fluorescence within cells. This result indicates that higher GFP abundance in some cells is likely due to higher rates of gene expression, because it is not due to systematically lower rates of protein degradation. The approach described in this study will assist the quantification and understanding of gene activity within live cells using fluorescent protein reporters.     

Quantitative analysis of gene expression with an improved green fluorescent protein. p6.

The fast and easy in vivo detection predestines the green fluorescent protein (GFP) for its use as a reporter to quantify promoter activities. We have increased the sensitivity of GFP detection 320-fold compared to the wild-type by constructing gfp+, which contains mutations improving the folding efficiency and the fluorescence yield of GFP+. Twelve expression levels were measured using fusions of the gfp+ and lacZ genes with the tetA promoter in Escherichia coli. The agreement of GFP+ fluorescence with beta-galactosidase activities was excellent, demonstrating that the gfp+ gene can be used to accurately quantify gene expression in vivo. However, expression of the gfp+ gene from the stronger hsp60 promoter revealed that high cellular concentrations of GFP+ caused an inner filter effect reducing the fluorescence by 50%, thus underestimating promoter activity. This effect is probably due to the higher absorbance of cells containing GFP+. Thus promoters with activities differing by about two orders of magnitude can be correctly quantified using the gfp+ gene. Possibilities of using GFP variants beyond this range are discussed.     

Correlating cell cycle with apoptosis in a cell line expressing a tandem green fluorescent protein substrate specific for group II caspases.

BACKGROUND: We describe a rapid flow cytometric assay that correlates cell cycle with apoptotic cell death in a cell line expressing a tandem green fluorescent protein (GFP). METHODS: A Jurkat cell line was transfected with a gene construct coding for constitutive expression of a tandem GFP molecule carrying a consensus cleavage site (DEVD) for group II caspases (C-2-Y). Cells were treated with CD95 antibody (Ab), then incubated with annexin V-phycoerythrin (PE), propidium iodide (PI), and Hoechst 33342. RESULTS: After CD95 treatment, the C-2-Y cell line had twice the number of nonapoptotic cells compared with both control cell lines. This proportion of viable, nonapoptotic cells after treatment was unaffected by the level of GFP (DEVD) expression in the cells, as confirmed by sorted populations. The early apoptotic cells in the C-2-Y cell line had an increased G0-G1 phase population compared with the control cell lines. CONCLUSIONS: Apoptosis is delayed in the C-2-Y cell line and the early apoptotic cells have a higher G0-G1 cell cycle frequency. The artificial substrate competes with the natural substrate(s), thereby slowing the apoptotic process. The expression level of DEVD-GFP does not alter the delayed induction of apoptosis. Caspase activation occurs prior to phosphatidylserine translocation.     

Folding of green fluorescent protein and the cycle3 mutant

Although the correct folding of green fluorescent protein (GFP) is required for formation of the chromophore, it is known that wild-type GFP cannot mature efficiently in vivo in Escherichia coli at 37 degrees C or higher temperatures that the jellyfish in the Pacific Northwest have never experienced. Recently, by random mutagenesis by the polymerase chain reaction (PCR) method, a mutant called Cycle3 was constructed. This mutant had three mutations, F99S, M153T, and V163A, on or near the surface of the GFP molecule and was able to mature correctly even at 37 degrees C [Crameri et al. (1996) Nat. Biotechnol. 143, 315-319]. In the present study, we investigated the differences in their folding behavior in vitro. We observed the folding and unfolding reactions of both wild-type GFP and the Cycle3 mutant by using green fluorescence as an indicator of the formation of the native structure and examining hydrogen-exchange reactions by Fourier transform infrared spectroscopy. Both proteins showed unusually slow refolding and unfolding rates, and their refolding rates were almost identical under the native state at 25 and at 35 degrees C. On the other hand, aggregation studies in vitro showed that wild-type GFP had a strong tendency to aggregate, while the Cycle3 mutant did not. These results indicated that the ability to mature efficiently in vivo at 37 degrees C was not due to the improved folding and that reduced hydrophobicity on the surface of the Cycle3 mutant was a more critical factor for efficient maturation in vivo.     

A transposon for green fluorescent protein transcriptional fusions: application for bacterial transport experiments

The movement of bacteria through groundwater is a poorly understood process. Factors such as soil porosity and mineralogy, heterogeneity of soil particle size, and response of the bacteria to their environment contribute to the pattern of bacterial flow. The identification of transported bacteria is often a limiting factor in both laboratory and field transport experiments. Two bacterial strains were modified for use in bacterial transport experiments: a strain of Escherichia coli harboring the pGFP plasmid and a strain of Pseudomonas putida modified with a Tn5 derivative, Tn5GFP1. The Tn5GFP1 transposon incorporates the gene (gfp) encoding green fluorescent protein (GFP) and can be used to mutagenize Gram^- bacteria. Fluorescent colonies were suspended in phosphate-buffered saline (PBS) at a concentration of approx. 10⁹ bacteria/ml. A 10-cm glass column packed with quartz sand (diameter range 177–250 μm) was equilibrated with PBS prior to the forced flow introduction of the bacteria. Collected fractions were analyzed and the bacteria quantitated using a fluorescence spectrometer. Results demonstrate that the bacteria can be accurately tracked using their fluorescence, and that the intensity of the signal can be used to determine a C/Co ratio for the transported bacteria. The data show a rapid breakthrough of the bacteria followed by a characteristic curve pattern. A lower limit of detection of 10⁵ cells was estimated based on these experiments. The Tn5GFP1 transposon should become a valuable tool for labeling bacteria.     

Targeting of green fluorescent protein expression to the cell surface.

We have previously reported on GPI-anchored fusion proteins that bind radioactive isotopes. We targeted their expression to the cell surface to obtain a marker protein detectable by nuclear and optical imaging (1, 2). Here we suggest a novel approach for targeting a model protein (GFP) to the exoplasmic surface of the plasma membrane. An expression vector (pcPEP-GFP) was constructed containing GFP cDNA fused with the fragment encoding the N-terminal cytoplasmic domain and signal peptide/membrane anchoring domain of the rabbit neutral endopeptidase (PEP-GFP). Flow cytometry showed green fluorescence in 45% of cells transfected with GFP and in 34% of cells transfected with PEP-GFP (24 h after transfection). Fluorescence microscopy of fixed cells stained with rhodaminated anti-GFP antibodies showed positive reaction only in the case of PEP-GFP-transfected cells indicating cell-surface expression. The PEP-GFP fusion protein was identified as a component of the light microsomal and Golgi fractions by immunoblotting.     

A rapid and simple estimation of cell cycle parameters by continuous labeling with bromodeoxyuridine

The DNA synthesis time (Ts) and other related cell cycle parameters were roughly estimated in HeLa cells labeled with bromodeoxyuridine (BrdUrd) for various durations by using the flow cytometrical technique. The labeling indices increased in proportion to time after addition of BrdUrd. The Ts can be calculated from the slope of the regression line obtained by plotting the serial labeling indices against the labeling time and was equivalent to the value determined by fraction labeled cells in mid S-phase (FLSm) method. These parameters would be determined by only two samples labeled for different times. This simple method using BrdUrd provides rough but rapid estimation of Ts and other cell cycle parameters without complicated mathematical procedures, in addition to cell cycle partition of cell populations.     

A method for the analysis of protein turnover characteristics. Indirect estimation of rates of protein degradation.

A method for the calculation of rate constants of degradation of a specific protein during a period of change in protein amount is described. The calculation uses measurements of rates of synthesis and amount of the protein, together with one estimate of the protein half-life. The method is demonstrated by using data from measurements made on the accumulation of fatty acid synthetase in hormonally treated explants of mammary gland from mid-pregnant rabbits, and data from other authors. These calculations demonstrate a regulated programme of co-ordinated changes in rates of synthesis and degradation during a period of change in protein mass. The role of such changes in protein degradation during protein accumulation is discussed.     

Scanning fluorescent microscopy is an alternative for quantitative fluorescent cell analysis.

BACKGROUND: Fluorescent measurements on cells are performed today with FCM and laser scanning cytometry. The scientific community dealing with quantitative cell analysis would benefit from the development of a new digital multichannel and virtual microscopy based scanning fluorescent microscopy technology and from its evaluation on routine standardized fluorescent beads and clinical specimens. METHODS: We applied a commercial motorized fluorescent microscope system. The scanning was done at 20 x (0.5 NA) magnification, on three channels (Rhodamine, FITC, Hoechst). The SFM (scanning fluorescent microscopy) software included the following features: scanning area, exposure time, and channel definition, autofocused scanning, densitometric and morphometric cellular feature determination, gating on scatterplots and frequency histograms, and preparation of galleries of the gated cells. For the calibration and standardization Immuno-Brite beads were used. RESULTS: With application of shading compensation, the CV of fluorescence of the beads decreased from 24.3% to 3.9%. Standard JPEG image compression until 1:150 resulted in no significant change. The change of focus influenced the CV significantly only after +/-5 microm error. CONCLUSIONS: SFM is a valuable method for the evaluation of fluorescently labeled cells.     

Incomplete proteasomal degradation of green fluorescent proteins in the context of tandem fluorescent protein timers

Tandem fluorescent protein timers (tFTs) report on protein age through time-dependent change in color, which can be exploited to study protein turnover and trafficking. Each tFT, composed of two fluorescent proteins (FPs) that differ in maturation kinetics, is suited to follow protein dynamics within a specific time range determined by the maturation rates of both FPs. So far, tFTs have been constructed by combining slower-maturing red fluorescent proteins (redFPs) with the faster-maturing superfolder green fluorescent protein (sfGFP). Toward a comprehensive characterization of tFTs, we compare here tFTs composed of different faster-maturing green fluorescent proteins (greenFPs) while keeping the slower-maturing redFP constant (mCherry). Our results indicate that the greenFP maturation kinetics influences the time range of a tFT. Moreover, we observe that commonly used greenFPs can partially withstand proteasomal degradation due to the stability of the FP fold, which results in accumulation of tFT fragments in the cell. Depending on the order of FPs in the timer, incomplete proteasomal degradation either shifts the time range of the tFT toward slower time scales or precludes its use for measurements of protein turnover. We identify greenFPs that are efficiently degraded by the proteasome and provide simple guidelines for the design of new tFTs.     

A simple fluorescent method for quantitative determination of aortic protein uptake.

A quantitative system for direct protein tracing and measurement of net protein uptake in the aorta using fluorescein isothiocyanate conjugated bovine serum albumin (FITCBSA) is described. Using Wistar rats, a mean aortic FITCBSA net uptake of 29.7 times 10(-17) g FITCBSA per mum2 aortic endothelial surface area per 24 h was obtained. Intra-aortic localization of the FITCBSA was observed along the endothelium and the collagen-elastin bands. The values obtained using this FITCBSA system are comparable with those of a previously established isotopic technique measuring aortic albumin flux and reconfirm the previous findings of the existence of an albumin permeability gradient in the thoracic aorta.     

A T-extended vector using a green fluorescent protein as an indicator

T-extended vector (T-vector) is a useful tool for cloning PCR products directly. We exploited a novel T-vector using a green fluorescent protein (GFP) as an indicator based on insertional inactivation. The brightest GFP mutant was used for easy detection even under daylight. The 100bp and 0.9kb of PCR products were cloned, and the transformant colonies with inserts were adjudged by the fluorescent green-white screening. The GFP system was more sensitive to insertional inactivation than the beta-galactosidase system at the conventional insertion sites.     

Reliable use of green fluorescent protein in fluorescent pseudomonads.

When fluorescent pseudomonads are cultured on standard solid media under iron limiting conditions, they produce fluorescent, pigmented iron collating agents (siderophores). Siderophores can be readily identified by strong fluorescence seen under UV/blue light. The application of the eukaryotic green fluorescent protein (GFP) as a bacterial marker in microbial ecology is increasingly being used, particularly as it is a powerful method for non-destructive monitoring in situ. As gfp expressing bacteria have to be detected under UV/blue light, the fluorescence of siderophore-producing Pseudomonas spp. masks normal levels of GFP fluorescence when colonies are viewed on standard bacterial agar. Here, we describe a simple but effective way of identifying gfp-expressing Pseudomonas fluorescens using media supplemented with 0.45 mM FeSO(4).7H(2)O. This is of relevance for the screening of insertion libraries and in the application of GFP transposons as promoter probes.     

Characterization of a novel component of the peroxisomal protein import apparatus using fluorescent peroxisomal proteins.

Fluorescent peroxisomal probes were developed by fusing green fluorescent protein (GFP) to the matrix peroxisomal targeting signals PTS1 and PTS2, as well as to an integral peroxisomal membrane protein (IPMP). These proteins were used to identify and characterize novel peroxisome assembly (pas) mutants in the yeast Pichia pastoris. Mutant cells lacking the PAS10 gene mislocalized both PTS1-GFP and PTS2-GFP to the cytoplasm but did incorporate IPMP-GFP into peroxisome membranes. Similar distributions were observed for endogenous peroxisomal matrix and membrane proteins. While peroxisomes from translocation-competent pas mutants sediment in sucrose gradients at the density of normal peroxisomes, >98% of peroxisomes from pas10 cells migrated to a much lower density and had an extremely low ratio of matrix:membrane protein. These data indicate that Pas10p plays an important role in protein translocation across the peroxisome membrane. Consistent with this hypothesis, we find that Pas10p is an integral protein of the peroxisome membrane. In addition, Pas10p contains a cytoplasmically-oriented C3HC4 zinc binding domain that is essential for its biological activity.     

Human cytomegalovirus labeled with green fluorescent protein for live analysis of intracellular particle movements

Human cytomegalovirus (HCMV) replicates in the nuclei of infected cells. Successful replication therefore depends on particle movements between the cell cortex and nucleus during entry and egress. To visualize HCMV particles in living cells, we have generated a recombinant HCMV expressing enhanced green fluorescent protein (EGFP) fused to the C terminus of the capsid-associated tegument protein pUL32 (pp150). The resulting UL32-EGFP-HCMV was analyzed by immunofluorescence, electron microscopy, immunoblotting, confocal microscopy, and time-lapse microscopy to evaluate the growth properties of this virus and the dynamics of particle movements. UL32-EGFP-HCMV replicated similarly to wild-type virus in fibroblast cultures. Green fluorescent virus particles were released from infected cells. The fluorescence stayed associated with particles during viral entry, and fluorescent progeny particles appeared in the nucleus at 44 h after infection. Surprisingly, strict colocalization of pUL32 and the major capsid protein pUL86 within nuclear inclusions indicated that incorporation of pUL32 into nascent HCMV particles occurred simultaneously with or immediately after assembly of the capsid. A slow transport of nuclear particles towards the nuclear margin was demonstrated. Within the cytoplasm, most particles performed irregular short-distance movements, while a smaller fraction of particles performed centripetal and centrifugal long-distance movements. Although numerous particles accumulated in the cytoplasm, release of particles from infected cells was a rare event, consistent with a release rate of about 1 infectious unit per h per cell in HCMV-infected fibroblasts as calculated from single-step growth curves. UL32-EGFP-HCMV will be useful for further investigations into the entry, maturation, and release of this virus.     

Vibrational analysis of a solvated green fluorescent protein chromophore

Resonance Raman (RR) spectra of green fluorescent protein (GFP) model chromophores in solution have been simulated with the CASSCF/MM methodology. Although several reports on vibrational analysis of GFP model chromophores have been recently published, the RR spectra were simulated for the first time in explicit solution with the inclusion of the counterion, as these effects are crucial for unambiguously reproducing the vibrational band assignment in the anionic form of the GFP chromophore. This strategy allows for a one-to-one correspondence of the calculated vibrational modes to the observed RR bands, concerning both the location and intensity pattern. In addition, these simulations were complemented with total energy distribution calculations to aid in the unambiguous assignment of the measured spectra. The current study helps to clarify some of the previous RR bands assignments as well as producing some new assignment for the anionic form of GFP chromophore. The explicit solvent simulations and PCM-based calculations are compared to the measured spectra, and these results demonstrate that explicit solvent simulations provide better agreement with experiment, both in terms of vibrational frequencies and intensity distribution. Figure a Correlation of explicit hydration calculations (CASSCF/6-31G*/MM) for the HBI model chromophore and experimental RR data [21]; slope = 0.982, intercept = 27.210 and regression coefficient = 0.997. b Correlation of implicit PCM calculations (CASSCF/6-31G*) for the HBI model chromophore and experimental RR data [21], slope = 1.017, intercept = −48.838 and regression coefficient = 0.984     

A new method for the estimation of cell cycle phases.

A method is described, which is applicable to cell renewal systems with an anatomical structure in which all cell locations may be uniquely mapped. Its use is demonstrated on the rat incisor inner enamel epithelium, which forms a one cell thick column in the sagittally sectioned tooth. Cells born in the apical part of the column migrate toward the distal end of the tooth, where they mature. As the cells migrate along the column, they traverse the various cell cycle phases. The present study has been designed to estimate the probability of a cell being in a given phase; all cells touching the basement membrane were numbered, and the number of cells separating any two cells was taken as a measure of distance. Since generally all cells move in one direction (lateral cell migration may occur), it is possible to solve the problem with the aid of functions describing the renewal counting stochastic process in which cell distance serves as an independent variable. The method predicts labelled cell and mitotic rates which agree with those estimated in the usual way. It was then utilized to estimate the fraction of cells in G2.     

Expression of green fluorescent protein in insect larvae and its application for heterologous protein production

Many eukaryotic proteins have been successfully expressed in insect cells infected with a recombinant baculovirus derived from the Autographa californica nuclear polyhedrosis virus (AcNPV). There are, however, disadvantages with this cell-based system when carried out in suspension cultures at high bioreactor volume (e.g., limited oxygen transfer, susceptibility to contamination, high cost). These problems can be avoided by using whole larvae as the "reactors." There are, however, other problems encountered with larvae, one being their inaccessibility for product sampling. To combat this problem, we have investigated the expression of green fluorescent protein (GFP) as a reporter molecule in Trichoplusia ni insect larvae. A high production level of GFPuv (1.58 mg per larva, 26% of total protein) was obtained, enabling the rapid and non-invasive monitoring of GFP. Bright green light was emitted directly from the large opaque carcasses ( approximately 30mm) after illumination with UV light. Based on the green light intensity and a correlation between intensity and GFP mass, we determined the optimal harvest time (c.a. approximately 3 days post-infection). In parallel experiments, we expressed human interleukin-2 (IL-2) from another recombinant baculovirus with an almost identical expression profile. Since both GFP and IL-2 were rapidly degraded by protease activity during the fourth day post-infection (another disadvantage with larvae), we found an accurate determination of harvest time was critical. Correspondingly, our results demonstrated that GFP was an effective on-line marker for expression of heterologous protein in insect larvae. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 56: 239-247, 1997.