Elimination of laboratory ozone leads to a dramatic improvement in the reproducibility of microarray gene expression measurements

Background  

Environmental ozone can rapidly degrade cyanine 5 (Cy5), a fluorescent dye commonly used in microarray gene expression studies. Cyanine 3 (Cy3) is much less affected by atmospheric ozone. Degradation of the Cy5 signal relative to the Cy3 signal in 2-color microarrays will adversely reduce the Cy5/Cy3 ratio resulting in unreliable microarray data.     

A Targeted Proteomics Approach for Biomarker Discovery Using Bilateral Matched Nipple Aspiration Fluids

Introduction  

The objective of this study was to identify cancer-associated protein expression patterns in bilateral matched nipple aspiration fluids using nanoscale reciprocal Cy3/Cy5 labeling and high-content antibody microarrays. This novel platform allows the pair-wise comparisons of the relative abundance of 512 different antigens using minimal NAF sample containing 1 μg of total protein.     

Statistical methodology for the analysis of dye-switch microarray experiments

Background  

In individually dye-balanced microarray designs, each biological sample is hybridized on two different slides, once with Cy3 and once with Cy5. While this strategy ensures an automatic correction of the gene-specific labelling bias, it also induces dependencies between log-ratio measurements that must be taken into account in the statistical analysis.     

Signal stability of Cy3 and Cy5 on antibody microarrays

Background  

The antibody microarray technique is a newly emerging proteomics tool for differential protein expression analyses that uses fluorescent dyes Cy 3 and Cy 5. Environmental factors, such as light exposure, can affect the signal intensity of fluorescent dyes on microarray slides thus, it is logical to scan microarray slides immediately after the final wash and drying processes. However, no research data are available concerning time-dependent changes of fluorescent signals on antibody microarray slides to this date. In the present study, microarray slides were preserved at -20°C after regular microarray experiments and were rescanned at day 10, 20 and 30 to evaluate change in signal intensity.     

Whole Cell-SELEX Aptamers for Highly Specific Fluorescence Molecular Imaging of Carcinomas In Vivo

Background

Carcinomas make up the majority of cancers. Their accurate and specific diagnoses are of great significance for the improvement of patients'' curability.

Methodology/Principal Findings

In this paper, we report an effectual example of the in vivo fluorescence molecular imaging of carcinomas with extremely high specificity based on whole cell-SELEX aptamers. Firstly, S6, an aptamer against A549 lung carcinoma cells, was adopted and labeled with Cy5 to serve as a molecular imaging probe. Flow cytometry assays revealed that Cy5-S6 could not only specifically label in vitro cultured A549 cells in buffer, but also successfully achieve the detection of ex vivo cultured target cells in serum. When applied to in vivo imaging, Cy5-S6 was demonstrated to possess high specificity in identifying A549 carcinoma through a systematic comparison investigation. Particularly, after Cy5-S6 was intravenously injected into nude mice which were simultaneously grafted with A549 lung carcinoma and Tca8113 tongue carcinoma, a much longer retention time of Cy5-S6 in A549 tumor was observed and a clear targeted cancer imaging result was presented. On this basis, to further promote the application to imaging other carcinomas, LS2 and ZY8, which are two aptamers selected by our group against Bel-7404 and SMMC-7721 liver carcinoma cells respectively, were tested in a similar way, both in vitro and in vivo. Results showed that these aptamers were even effective in differentiating liver carcinomas of different subtypes in the same body.

Conclusions/Significance

This work might greatly advance the application of whole cell-SELEX aptamers to carcinomas-related in vivo researches.     

A new non-linear normalization method for reducing variability in DNA microarray experiments

Background  

Microarray data are subject to multiple sources of variation, of which biological sources are of interest whereas most others are only confounding. Recent work has identified systematic sources of variation that are intensity-dependent and non-linear in nature. Systematic sources of variation are not limited to the differing properties of the cyanine dyes Cy5 and Cy3 as observed in cDNA arrays, but are the general case for both oligonucleotide microarray (Affymetrix GeneChips) and cDNA microarray data. Current normalization techniques are most often linear and therefore not capable of fully correcting for these effects.     

Microarray scanner calibration curves: characteristics and implications

Background

Microarray-based measurement of mRNA abundance assumes a linear relationship between the fluorescence intensity and the dye concentration. In reality, however, the calibration curve can be nonlinear.

Results

By scanning a microarray scanner calibration slide containing known concentrations of fluorescent dyes under 18 PMT gains, we were able to evaluate the differences in calibration characteristics of Cy5 and Cy3. First, the calibration curve for the same dye under the same PMT gain is nonlinear at both the high and low intensity ends. Second, the degree of nonlinearity of the calibration curve depends on the PMT gain. Third, the two PMTs (for Cy5 and Cy3) behave differently even under the same gain. Fourth, the background intensity for the Cy3 channel is higher than that for the Cy5 channel. The impact of such characteristics on the accuracy and reproducibility of measured mRNA abundance and the calculated ratios was demonstrated. Combined with simulation results, we provided explanations to the existence of ratio underestimation, intensity-dependence of ratio bias, and anti-correlation of ratios in dye-swap replicates. We further demonstrated that although Lowess normalization effectively eliminates the intensity-dependence of ratio bias, the systematic deviation from true ratios largely remained. A method of calculating ratios based on concentrations estimated from the calibration curves was proposed for correcting ratio bias.

Conclusion

It is preferable to scan microarray slides at fixed, optimal gain settings under which the linearity between concentration and intensity is maximized. Although normalization methods improve reproducibility of microarray measurements, they appear less effective in improving accuracy.

     

F?rster Resonance Energy Transfer Measurements of Ryanodine Receptor Type 1 Structure Using a Novel Site-Specific Labeling Method

Background

While the static structure of the intracellular Ca²⁺ release channel, the ryanodine receptor type 1 (RyR1) has been determined using cryo electron microscopy, relatively little is known concerning changes in RyR1 structure that accompany channel gating. Förster resonance energy transfer (FRET) methods can resolve small changes in protein structure although FRET measurements of RyR1 are hampered by an inability to site-specifically label the protein with fluorescent probes.

Methodology/Principal Findings

A novel site-specific labeling method is presented that targets a FRET acceptor, Cy3NTA to 10-residue histidine (His) tags engineered into RyR1. Cy3NTA, comprised of the fluorescent dye Cy3, coupled to two Ni²⁺/nitrilotriacetic acid moieties, was synthesized and functionally tested for binding to His-tagged green fluorescent protein (GFP). GFP fluorescence emission and Cy3NTA absorbance spectra overlapped significantly, indicating that FRET could occur (Förster distance = 6.3 nm). Cy3NTA bound to His₁₀-tagged GFP, quenching its fluorescence by 88%. GFP was then fused to the N-terminus of RyR1 and His₁₀ tags were placed either at the N-terminus of the fused GFP or between GFP and RyR1. Cy3NTA reduced fluorescence of these fusion proteins by 75% and this quenching could be reversed by photobleaching Cy3, thus confirming GFP-RyR1 quenching via FRET. A His₁₀ tag was then placed at amino acid position 1861 and FRET was measured from GFP located at either the N-terminus or at position 618 to Cy3NTA bound to this His tag. While minimal FRET was detected between GFP at position 1 and Cy3NTA at position 1861, 53% energy transfer was detected from GFP at position 618 to Cy3NTA at position 1861, thus indicating that these sites are in close proximity to each other.

Conclusions/Significance

These findings illustrate the potential of this site-specific labeling system for use in future FRET-based experiments to elucidate novel aspects of RyR1 structure.     

Chemo-Immunotherapy of murine solid tumors: Enhanced therapeutic effects by interleukin-2 combined with interferon α and the role of specific T cells

Summary The aim of the present study has been to assess the therapeutic efficacy of various cytokines, singly or in combination, with and without chemotherapy (cyclophosphamide, Cy), in mice carrying advanced, weakly immunogenic tumors (MCA-105 sarcoma, M109 carcinoma). Treatment of animals with i.p. growths or experimental pulmonary metastases began 8–18 days after i.p. or i.v. tumor cell inoculation respectively. None of the cytokines tested [interleukin-2 (IL-2), interferon (IFN), tumor necrosis factor (TNF) and macrophage-colony-stimulating factor (M-CSF)] nor Cy had by itself a significant curative effect. A synergistic therapeutic effect was obtained with IL-2 or IFN (but not with TNF or M-CSF) in combination with Cy. The most efficacious regimen (65%–90% cure of mice carrying i.p. tumors) was the combination of Cy+IL-2+IFN. Preliminary experiments suggested that sequential administration of these cytokines might be more beneficial than concurrent administration. Following successful immunotherapy, long-term (3–6 months) survivors showed a tumor-specific resistance to a second tumor challenge and their spleen contained an increased number of specific antitumor cytotoxic T lymphocyte precursors (5- to 20-fold, compared to control mice). In vitro and in vivo cell-depletion experiments using monoclonal antibodies revealed that T cells (primarily CD8), but not NK cells, are crucial for the therapeutic effects. This study indicates that a potent specific antitumor T cell immunity can be elicited against advanced weakly immunogenic tumors by combining chemotherapy (Cy) with IL-2 and IFN.     

FeCo/graphite nanocrystals for multi-modality imaging of experimental vascular inflammation

Background

FeCo/graphitic-carbon nanocrystals (FeCo/GC) are biocompatible, high-relaxivity, multi-functional nanoparticles. Macrophages represent important cellular imaging targets for assessing vascular inflammation. We evaluated FeCo/GC for vascular macrophage uptake and imaging in vivo using fluorescence and MRI.

Methods and Results

Hyperlipidemic and diabetic mice underwent carotid ligation to produce a macrophage-rich vascular lesion. In situ and ex vivo fluorescence imaging were performed at 48 hours after intravenous injection of FeCo/GC conjugated to Cy5.5 (n = 8, 8 nmol of Cy5.5/mouse). Significant fluorescence signal from FeCo/GC-Cy5.5 was present in the ligated left carotid arteries, but not in the control (non-ligated) right carotid arteries or sham-operated carotid arteries (p = 0.03 for ligated vs. non-ligated). Serial in vivo 3T MRI was performed at 48 and 72 hours after intravenous FeCo/GC (n = 6, 270 µg Fe/mouse). Significant T2* signal loss from FeCo/GC was seen in ligated left carotid arteries, not in non-ligated controls (p = 0.03). Immunofluorescence staining showed colocalization of FeCo/GC and macrophages in ligated carotid arteries.

Conclusions

FeCo/GC accumulates in vascular macrophages in vivo, allowing fluorescence and MR imaging. This multi-functional high-relaxivity nanoparticle platform provides a promising approach for cellular imaging of vascular inflammation.     

Evaluation of five different cDNA labeling methods for microarrays using spike controls

Background

Several different cDNA labeling methods have been developed for microarray based gene expression analysis. We have examined the accuracy and reproducibility of such five commercially available methods in detection of predetermined ratio values from target spike mRNAs (A. thaliana) in a background of total RNA. The five different labeling methods were: direct labeling (CyScribe), indirect labeling (FairPlay? – aminoallyl), two protocols with dendrimer technology (3DNA^® Array 50? and 3DNA^® submicro?), and hapten-antibody enzymatic labeling (Micromax? TSA?). Ten spike controls were mixed to give expected Cy5/Cy3 ratios in the range 0.125 to 6.0. The amounts of total RNA used in the labeling reactions ranged from 5 – 50 μg.

Results

The 3DNA array 50 and CyScribe labeling methods performed best with respect to relative deviation from the expected values (16% and 17% respectively). These two methods also displayed the best overall accuracy and reproducibility. The FairPlay method had the lowest total experimental variation (22%), but the estimated values were consistently higher than the expected values (36%). TSA had both the largest experimental variation and the largest deviation from the expected values (45% and 48% respectively).

Conclusion

We demonstrate the usefulness of spike controls in validation and comparison of cDNA labeling methods for microarray experiments.

     

Double Labeling of Oligonucleotide Probes for Fluorescence In Situ Hybridization (DOPE-FISH) Improves Signal Intensity and Increases rRNA Accessibility

Fluorescence in situ hybridization (FISH) with singly labeled rRNA-targeted oligonucleotide probes is widely applied for direct identification of microbes in the environment or in clinical specimens. Here we show that a replacement of singly labeled oligonucleotide probes with 5′-, 3′-doubly labeled probes at least doubles FISH signal intensity without causing specificity problems. Furthermore, Cy3-doubly labeled probes strongly increase in situ accessibility of rRNA target sites and thus provide more flexibility for probe design.Since its introduction almost 20 years ago (2, 7), the identification of microorganisms by fluorescence in situ hybridization (FISH) with singly labeled rRNA-targeted probes has found widespread application in environmental and medical microbiology (1, 16). Despite being a methodologically robust technique, standard FISH suffers from several limitations (26) that may prevent successful detection of target microorganisms. One of the most frequently reported FISH problems is a low signal intensity of the detected microbes.Dim signals can be caused by a low cellular concentration of the target molecules (16S rRNA or 23S rRNA), a feature typically found in microorganisms thriving in oligotrophic environments (19). In order to increase the sensitivity of FISH and make it suitable for the detection of microbes with a low ribosome content, several strategies have been developed (6, 13, 18, 19, 21, 25), of which catalyzed reporter deposition (CARD)-FISH has found the most widespread application. The CARD-FISH technique (18, 21) uses horseradish peroxidase (HRP)-labeled oligonucleotide probes and tyramide signal amplification and achieves a 26- to 41-fold-higher sensitivity than standard FISH (11). However, CARD-FISH is rather expensive, requires enzymatic pretreatment to allow the large horseradish peroxidase-labeled probes to penetrate the target cells (17), and causes a dramatically altered melting behavior of the probes (11).Another frequently encountered FISH problem is the low in situ accessibility of many regions of the 16S and 23S rRNA for singly labeled probes (9, 10). Probes targeting such regions, which comprise about one-third of the Escherichia coli 16S rRNA (10), confer signals which are very dim or even below the detection limit. In order to avoid the selection of poorly accessible target sites for FISH probe design, a consensus 16S rRNA accessibility map for prokaryotes has been established based on detailed accessibility maps of two bacterial model organisms and one archaeal model organism (3). Considering this consensus map during probe design is recommended, but it excludes many probes with useful specificities from FISH applications. Furthermore, accessibility of many 16S and 23S rRNA target sites varies between different microorganisms and thus cannot yet be reliably predicted in silico. Accessibility of target sites to probes can be improved by the following: (i) use of unlabeled helper probes (8), (ii) elongation of the hybridization time up to 96 h (30), (iii) elongation of the probes, resulting in an altered ΔG°_overall (30), or (iv) use of peptide nucleic acid probes (reference 26 and references therein). However, all these strategies have specific limitations. For example, the design of helper probes is often impossible for probes with broader specificities, the extension of the hybridization time might lead to unspecific probe or dye binding in complex samples, probe elongation is often not possible without narrowing its specificity, and previously published oligonucleotide probes cannot simply be converted into the expensive peptide nucleic acid probes without a dramatically changed specificity (26).In principle, using oligonucleotide probes labeled with multiple fluorescent dyes should provide a simple means to increase the FISH signal intensity. The first experiments with multilabeled oligonucleotides were performed briefly after the introduction of the technique in microbiology but resulted in a pronounced increase in unspecific staining of nontarget organisms and/or an unexpected decrease in the signal intensity of the target organism which was attributed to quenching effects (28). Inconsistent with these data, Spear et al. (23) reported a successful increase in the signal-to-noise ratio of FISH-detected fungal cells by application of a multilabeled 18S rRNA-targeted oligonucleotide probe. In this work, we systematically evaluated the effect of 5′- and 3′-doubly labeled oligonucleotide probes (which were not included in the previously published study of multilabeled probes [28]) on the FISH signal intensity of Gram-negative and Gram-positive cells and studied the influence of double labeling on the in situ accessibility of rRNA target sites.The double-labeling-of-oligonucleotide-probes (DOPE)-FISH approach was initially tested with four bacterial pure cultures. These included the gamma- and betaproteobacterial Gram-negative species Escherichia coli (DSM 498) and Burkholderia cepacia (DSM 7288), respectively. In addition, the two Gram-positive bacteria Bacillus subtilis (DSM 10) and Listeria monocytogenes (strain LO28) were used. E. coli, B. cepacia, and B. subtilis were grown according to the DSMZ instructions until they reached their stationary growth phase and were fixed with paraformaldehyde (E. coli and B. cepacia) or ethanol (B. subtilis) as described elsewhere (5). L. monocytogenes strain LO28 was grown on brain heart infusion for 5 h and fixed with ethanol as outlined previously (27). The oligonucleotide probes EUB338 (targeting the 16S rRNA of most but not all bacteria), NonEUB338 (a nonsense probe), GAM42a (targeting the 23S rRNA of many members of the Gammaproteobacteria), and five E. coli-targeted probes with a low 16S rRNA accessibility (10) were obtained as singly and doubly labeled derivatives from Thermo Hybaid (Interactiva Division, Ulm, Germany). More information about the applied probes can be found at probeBase (14) and in the publication by Fuchs et al. (10). FISH was performed by following the standard protocol (5) under the conditions recommended for each probe (14). If not stated otherwise, all hybridizations were carried out with identical hybridization (4 h) and washing times (10 min), respectively. Probe-conferred signal intensities were quantified using a confocal laser scanning microscope (CLSM) (LSM 510 Meta; Zeiss, Oberkochen, Germany) and the software program daime (4) by analyzing at least 1,000 single cells per experiment. For these measurements, individual cells were detected by image segmentation via edge detection.Regardless of the dye used (Cy3, Cy5, or FLUOS) and the respective target organism analyzed, hybridization with the doubly labeled probe EUB338 resulted in an increase in the FISH signal compared to the use of the singly labeled probe EUB338. For three of the four reference organisms, this increase was about 2-fold, while an even stronger signal amplification was observed for B. cepacia (Fig. ​(Fig.1A).1A). Consequently, the distance between the two dye molecules in 18-nucleotide probes labeled at both ends is sufficient to avoid quenching. This is in contrast to oligonucleotides which are multiply labeled at one end or within the probe (28). Hybridization of the four reference organisms with the singly and doubly labeled derivatives of probe GAM42a confirmed these results and demonstrated that double labeling does not increase the background fluorescence of nontarget microorganisms (Fig. ​(Fig.1B).1B). Consistent with these findings, hybridization of all reference organisms with a doubly labeled nonsense probe (with FLUOS, Cy3, and Cy5) resulted in signals below the detection limit of the CLSM if standard FISH settings were applied (data not shown). We also evaluated the influence of the hybridization time on the signal intensity achievable by DOPE-FISH by varying the hybridization time between 1 and 6 h. In these experiments, no significant difference in DOPE-FISH signal intensities of the Gram-positive and Gram-negative reference organisms were observed, indicating that the additional label of the DOPE-FISH probes does not dramatically influence the hybridization kinetics (data not shown).Open in a separate windowFIG. 1.(A) Effect of double labeling of the EUB338 probe on the FISH signal intensity of four reference organisms. For each organism, the signal intensity conferred by a doubly labeled EUB338 probe was normalized to the signal intensity obtained with the same probe as a singly labeled derivative. Hatched, light-gray, and dark-gray bars depict results with the Cy3-, Cy5- and FLUOS-labeled probe EUB338, respectively. (B) Effect of double labeling of the probe Gam42a (in the presence of the unlabeled competitor probe Bet42a, specific for most members of the Betaproteobacteria [14]) on the FISH signal intensities of four reference organisms. For each organism, the signal intensity conferred by the doubly labeled probe Gam42a was normalized to the signal intensity obtained for E. coli with the same probe as a singly labeled derivative. Hatched, light-gray, and dark-gray bars depict results with the Cy3-, Cy5-, and FLUOS-labeled probe, respectively. The weak unspecific signals observed with some DOPE-FISH probes for B. subtilis are also detectable at comparable intensities with singly labeled probes (data not shown). (C) Cy3-doubly labeled but not FLUOS-doubly labeled probes improve in situ accessibility of E. coli 16S rRNA target sites. E. coli was hybridized with five probes representing brightness classes V and VI (3). FISH signals were recorded for Cy3-singly and -doubly labeled probes and normalized to the FISH signal obtained for E. coli with the singly labeled probe EUB338. Light-gray and dark-gray bars depict results with Cy3-singly and doubly labeled probes, respectively. FLUOS-singly and -doubly labeled probes showed no signal. For all panels, all experiments were performed in triplicate. Error bars indicate the standard deviation. ND, not detectable.Although DOPE-FISH worked well with all tested reference organisms, it should be noted that the Gram-positive species L. monocytogenes showed a signal amplification only if it was treated with lysozyme (according to Wagner et al. [27]) prior to the application of the doubly labeled probe. Without this enzymatic pretreatment, application of the singly labeled probe EUB338 resulted in a stronger signal than was seen with the doubly labeled probe EUB338, indicating that for some Gram-positive microorganisms with dense cell walls, double labeling impairs probe penetration. The observation that lysozyme treatment of L. monocytogenes also enhanced the probe-conferred signal of the singly labeled EUB338 probe confirmed that the cell wall of this organism after ethanol fixation is also not freely permeable to singly labeled probes (27; also data not shown). Enzymatic pretreatment of fixed microbial cells is also routinely applied for successful application of CARD-FISH, but since this method uses peroxidase-labeled probes which are much larger than DOPE-FISH probes, such treatments are also used for Gram-negative bacteria (11). Although many microorganisms are detectable by CARD-FISH with enhanced signal intensities, appropriate pretreatment protocols are not yet available for all microbes. For example, the sheathed filamentous methane oxidizer Crenothrix polyspora can easily be detected by standard FISH (24), but only very few cells within the filaments show a signal after CARD-FISH even if harsh permeabilization pretreatments are applied (see Fig. S1A in the supplemental material), a phenomenon known for sheathed microorganisms (12). In contrast, detection of all Crenothrix cells with more than 2-fold-increased signal intensity is readily possible by DOPE-FISH (see Fig. S1B).Prior research has demonstrated that probe labeling with horseradish peroxidase for CARD-FISH dramatically alters the melting behavior of oligonucleotide probes (11). Therefore, we recorded melting curves for Cy3-, Cy5-, and FLUOS-singly and -doubly labeled probes EUB338 and Gam42a by applying increasingly stringent conditions in the hybridization and wash steps (5). Interestingly, these experiments showed that the FLUOS singly labeled probes formed less-stable duplexes with their target sequences than the respective Cy3- and Cy5-labeled probes (Fig. ​(Fig.2).2). This effect, which is consistent with recent data on the stabilizing effect of various fluorophores on model probe-target duplexes (15), indicates that FLUOS-labeled FISH probes are generally applied under more-stringent conditions than Cy3- or Cy5-labeled probes. Cy3- and Cy5-doubly labeled probes displayed with their target organisms probe dissociation profiles similar to those of the respective FLUOS singly labeled probes, demonstrating that Cy3 or Cy5 double labeling does not further stabilize but rather moderately weakens the probe-target hybrid. Consistent with these findings, doubly FLUOS-labeled probes showed the lowest T_m (Fig. ​(Fig.2).2). Importantly, double labeling of probe GAM42a did not adversely affect mismatch discrimination, as shown by its dissociation profiles if in situ hybridizations were performed at various stringencies with B. cepacia containing a single mismatch in the probe target site of its 23S rRNA. (Fig. ​(Fig.2B).2B). These results indicate that the specificities of DOPE-FISH probes can be regarded as identical to those of standard singly labeled FISH probes.Open in a separate windowFIG. 2.Comparison of probe dissociation profiles of singly and doubly labeled probes. For each profile, the microscopic settings were adjusted for the lowest formamide concentration and subsequently kept constant. Dashed and solid lines represent sigmoid fittings for singly and doubly labeled probes, respectively. (A) Dissociation profiles of the singly and doubly labeled probe Gam42a with E. coli as the target organism. Empty circles, squares, and triangles represent data obtained with the Cy3-, Cy5-, and FLUOS-singly labeled probe GAM42a, respectively. Filled circles, squares, and triangles depict the data measured for the Cy3-, Cy5-, and FLUOS-doubly labeled probe GAM42a, respectively. (B) Dissociation profiles of the singly and doubly labeled probe Gam42a with B. cepacia as a nontarget organism having a single mismatch to probe GAM42a. Empty circles, squares, and triangles represent data obtained with the Cy3-, Cy5-, and FLUOS-singly labeled probe GAM42a, respectively. Filled circles, squares, and triangles depict the data measured for the Cy3-, Cy5-, and FLUOS-doubly labeled probe GAM42a, respectively. The melting curves for FLUOS-singly labeled and Cy5-doubly labeled probes are almost identical and thus overlap. In the presence of the unlabeled probe Bet42a as a competitor, no probe-conferred signal was recordable for both singly and doubly labeled GAM42a probes. (C) Dissociation profiles of the singly and doubly labeled probe EUB338 with E. coli as the target organism. Empty circles, squares, and triangles represent data obtained with the Cy3-, Cy5-, and FLUOS-singly labeled probe EUB338, respectively. Filled circles, squares, and triangles depict the data measured for the Cy3-, Cy5-, and FLUOS-doubly labeled probe EUB338, respectively. For all panels, error bars are not shown since they were always smaller than the symbols.In order to analyze whether the in situ accessibility of rRNA target sites to doubly labeled probes differs from that to those labeled with only one dye, we tested five probes targeting E. coli 16S rRNA. These probes were described as yielding only very dim signals with standard FISH as a consequence of limited target site accessibility and were thus assigned to the lowest brightness classes, V or VI (3, 10). Consistently, standard FISH with these five singly labeled probes (Cy3 and FLUOS) gave no or very weak signals (Fig. ​(Fig.1C).1C). Unexpectedly, however, Cy3-doubly labeled derivatives of these probes produced much brighter signals (Fig. ​(Fig.1C),1C), and for some of the probes (Eco468 and Eco1310), the DOPE-FISH signal intensity was higher than that measured for the Cy3-singly labeled probe EUB338 (Fig. ​(Fig.1C).1C). One could speculate that a Cy3 label at the 3′ end and not the double labeling might be responsible for the improved accessibility of rRNA target sites for Cy3 DOPE-FISH probes. However, since selected probes (Eco262, Eco468, and Eco1310) labeled with a single Cy3 molecule at the 3′ end did not result in increased fluorescence, this hypothesis can be rejected (data not shown). Interestingly, FLUOS-labeled DOPE-FISH probes did not show increased fluorescence, strongly indicating that the improved accessibility of Cy3 DOPE-FISH probes depends on the chemical structure of the fluorophore. This is consistent with the observation that Cy5 double labeling of the five E. coli probes also resulted in improved probe accessibilities (data not shown). While Cy3 and Cy5 double labeling decreases the probe-target duplex stability (Fig. ​(Fig.2),2), it apparently helps to resolve secondary or tertiary structures responsible for poor in situ accessibility of rRNA target sites. It is tempting to speculate that binding of Cy3 or Cy5 to double-stranded rRNA regions, analogous to the previously reported intercalation of certain cyanine class dyes in DNA (29) or other modes of nucleic acid binding by cyanine dyes (15), contributes to this phenomenon.The improved accessibility of rRNA target sites for Cy3 DOPE-FISH probes offers more flexibility for probe design because it enables the use of probes with excellent specificity but low standard FISH signal intensity for the successful in situ detection of microbes. This advantage of DOPE-FISH is nicely demonstrated by the probe Ntspa175 (5′-GAC CAG GAG CCG TAT GCG-3′), which targets the 16S rRNA (GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"GU229885","term_id":"281398158","term_text":"GU229885"}}GU229885) of an uncultured nitrite oxidizer of the genus Nitrospira thriving in activated sludge. At 25% formamide in the standard FISH hybridization buffer (5), this probe is highly specific as demonstrated by Clone-FISH (22) using another activated sludge-derived 16S rRNA Nitrospira-like sequence with a single mismatch to probe Ntspa175 as a nontarget control (data not shown). Standard FISH of activated sludge with the Cy3-labeled probe Ntsp175, which targets the 175-to-193 region in the 16S rRNA, resulted in the detection of Nitrospira microcolonies with very variable FISH signal intensities. A considerable number of stained microcolonies had extremely dim FISH signals, indicating that these cells had a ribosome content too low to be reliably detectable by a standard FISH probe of a low brightness class. DOPE-FISH of the same sample with the Cy3-doubly labeled probe Ntspa175 led to a pronounced increase in signal intensity of the target cells (see Fig. S2 in the supplemental material) without causing increased background fluorescence if standard confocal-microscope settings were applied. In accordance with this observation, the relative biovolume-abundance of the detectable Ntspa175-stained population compared to the biovolume of those cells labeled by the Nitrospira genus-specific probe Ntspa662 (14) in the activated sludge increased by a factor of 1.81 ± 0.1 if a doubly labeled Ntspa175 probe was used (measurements made by the software package daime using confocal-microscope images as described previously [4]).In summary, DOPE-FISH with commercially available doubly labeled oligonucleotide probes is a straightforward modification of the standard FISH procedure which increases the signal intensity of standard FISH probes by at least a factor of 2 without causing specificity problems. Importantly, the influence of DOPE-FISH on the dissociation profile of probes is not larger than that caused by a dye switch from Cy3 to FLUOS if singly labeled probes are used for FISH. Thus, previously optimized hybridization and washing conditions for published probes can be applied for DOPE-FISH. Since DOPE-FISH unlocks previously inaccessible target sites on the rRNA, this new FISH approach offers more options for the design of specific probes, a task which becomes increasingly difficult with the rapid growth of rRNA databases (20).      

Blood-brain barrier-associated pericytes internalize and clear aggregated amyloid-β42 by LRP1-dependent apolipoprotein E isoform-specific mechanism

Background

Clearance at the blood-brain barrier (BBB) plays an important role in removal of Alzheimer’s amyloid-β (Aβ) toxin from brain both in humans and animal models. Apolipoprotein E (apoE), the major genetic risk factor for AD, disrupts Aβ clearance at the BBB. The cellular and molecular mechanisms, however, still remain unclear, particularly whether the BBB-associated brain capillary pericytes can contribute to removal of aggregated Aβ from brain capillaries, and whether removal of Aβ aggregates by pericytes requires apoE, and if so, is Aβ clearance on pericytes apoE isoform-specific.

Methods

We performed immunostaining for Aβ and pericyte biomarkers on brain capillaries (<?6 μm in diameter) on tissue sections derived from AD patients and age-matched controls, and APP^Swe/0 mice and littermate controls. Human Cy3-Aβ42 uptake by pericytes was studied on freshly isolated brain slices from control mice, pericyte LRP1-deficient mice (Lrp^lox/lox;Cspg4-Cre) and littermate controls. Clearance of aggregated Aβ42 by mouse pericytes was studied on multi-spot glass slides under different experimental conditions including pharmacologic and/or genetic inhibition of the low density lipoprotein receptor related protein 1 (LRP1), an apoE receptor, and/or silencing mouse endogenous Apoe in the presence and absence of human astrocyte-derived lipidated apoE3 or apoE4. Student’s t-test and one-way ANOVA followed by Bonferroni's post-hoc test were used for statistical analysis.

Results

First, we found that 35% and 60% of brain capillary pericytes accumulate Aβ in AD patients and 8.5-month-old APP^Sw/0 mice, respectively, compared to negligible uptake in controls. Cy3-Aβ42 species were abundantly taken up by pericytes on cultured mouse brain slices via LRP1, as shown by both pharmacologic and genetic inhibition of LRP1 in pericytes. Mouse pericytes vigorously cleared aggregated Cy3-Aβ42 from multi-spot glass slides via LRP1, which was inhibited by pharmacologic and/or genetic knockdown of mouse endogenous apoE. Human astrocyte-derived lipidated apoE3, but not apoE4, normalized Aβ42 clearance by mouse pericytes with silenced mouse apoE.

Conclusions

Our data suggest that BBB-associated pericytes clear Aβ aggregates via an LRP1/apoE isoform-specific mechanism. These data support the role of LRP1/apoE interactions on pericytes as a potential therapeutic target for controlling Aβ clearance in AD.

     

Anomalous fluorescence enhancement of Cy3 and cy3.5 versus anomalous fluorescence loss of Cy5 and Cy7 upon covalent linking to IgG and noncovalent binding to avidin

This study provides a critical examination of protein labeling with Cy3, Cy5, and other Cy dyes. Two alternate situations were tested. (i) Antibodies were covalently labeled with Cy dye succinimidyl ester at various fluorophore/protein ratios and the fluorescence of the labeled antibodies was compared to that of free Cy dye. (ii) Fluorescent biotin derivatives were synthesized by derivatizing ethylenediamine with one biotin and one Cy3 (or Cy5) residue. The fluorescence properties of these biotin-Cy dye conjugates were examined at all ligand/(strept)avidin ratios (0 相似文献   

A Cy5.5-labeled phage-displayed peptide probe for near-infrared fluorescence imaging of tumor vasculature in living mice

Near-infrared (NIR) fluorescence optical imaging is an emerging imaging technique for studying diseases at the molecular level. Optical imaging with a NIR emitting fluorophore for targeting tumor vasculature offers a noninvasive method for early detection of tumor angiogenesis and efficient monitoring of response to anti-tumor vasculature therapy. The previous in vitro results demonstrated that the GX1 peptide, identified by phage-display technology, is a tumor vasculature endothelium-specific ligand. In this report, Cy5.5-conjugated GX1 peptide was evaluated in a subcutaneous U87MG glioblastoma xenograft model to investigate tumor-targeting efficacy. The in vitro flow cytometry results revealed dose-dependent binding of Cy5.5-GX1 peptide to U87MG glioma cells. In vivo optical imaging with the Cy5.5-GX1 probe exhibited rapid U87MG tumor targeting at 0.5 h p.i., and high tumor-to-background contrast at 4 h p.i. Tumor specificity of Cy5.5-GX1 was confirmed by effective blocking of tumor uptake in the presence of unlabeled GX1 peptide (20 mg/kg). Ex vivo imaging further confirmed in vivo imaging findings, and demonstrated that Cy5.5-GX1 has a tumor-to-muscle ratio (15.21 ± 0.84) at 24 h p.i. for the non-blocked group and significantly decreased ratio (6.95 ± 0.75) for the blocked group. In conclusion, our studies suggest that Cy5.5-GX1 is a promising molecular probe for optical imaging of tumor vasculature.     

ST segment depression: the possible role of global repolarization dynamics

Background  

At least some clinical data suggests that, regardless of which major coronary artery is narrowed, the early ST segment body surface pattern is characterized by a minimum near precordial lead V5 and a broad area of left precordial negative potentials. Some clinical data also suggests that late ST segment potentials can localize an ischemic heart region.