A near‐infrared fluorescent probe based on boric acid hydrolysis for hydrogen peroxide detection and imaging in HeLa cells

Using the characteristics of hydrogen peroxide that are able to cleave phenyl‐boric acid selectively and efficiently, we here report a dicyanoisophorone‐boric acid ( DCP‐BA )‐based near‐infrared (NIR) fluorescent probe for detection of hydrogen peroxide. This probe shows a rapid, highly selective, and sensitive detection process for hydrogen peroxide with a significant NIR fluorescent turn‐on response that has been successfully applied to detect exogenous hydrogen peroxide in HeLa cells.     

Multispecificity of a recombinant anti‐ras monoclonal antibody

Recombinant monoclonal antibodies (Ab's) have widespread application as research tools, diagnostic reagents and as biotherapeutics. Whilst studying the cellular molecular switch protein m‐ras, a recombinant monoclonal antibody to m‐ras was generated for use as a research tool. Antibody genes from a single rabbit B cell secreting IgG to an m‐ras specific peptide sequence were expressed in mammalian cells, and monoclonal rabbit IgG binding was characterized by ELISA and peptide array blotting. Although the monoclonal Ab was selected for specificity to m‐ras peptide, it also bound to both recombinant full‐length m‐ras and h‐ras proteins. The cross‐reactive binding of the monoclonal Ab to h‐ras was defined by peptide array blot revealing that the Ab showed preference for peptide sequences containing multiple positively charged amino acid residues. These data reinforce the concept of antibody multispecificity through multiple interactions of the Ab paratope with diverse polypeptides. They also emphasize the importance of immunogen and Ab selection processes when generating recombinant monoclonal Ab's.     

Computed tomography for in vivo deep over‐1000 nm near‐infrared fluorescence imaging

This study aims to develop a novel cross‐sectional imaging of fluorescence in over‐1000 nm near‐infrared (OTN‐NIR), which allows in vivo deep imaging, using computed tomography (CT) system. Cylindrical specimens of composite of OTN‐NIR fluorophore, NaGdF₄ co‐doped with Yb³⁺ and Ho³⁺ (ex: 980 nm, em: 1150 nm), were embedded in cubic agar (10.5–12 mm) or in the peritoneal cavity of mice and placed on a rotatable stage. When the fluorescence from inside of the samples was serially captured from multiple angles, the images were disrupted by the reflection and refraction of emitted light on the sample‐air interface. Immersing the sample into water filled in a rectangular bath suppressed the disruption at the interface and successfully reconstructed the position and concentration of OTN‐NIR fluorophores on the cross‐sectional images using a CT technique. This is promising as a novel three‐dimensional imaging technique for OTN‐NIR fluorescent image projections of small animals captured from multiple angles.     

Melanin quantification by in vitro and in vivo analysis of near‐infrared fluorescence

Objective measurements of melanin can provide important information for differentiating melanoma from benign pigmented lesions and in assessing pigmentary diseases. Herein, we evaluate near‐infrared (NIR) fluorescence as a possible tool to quantify melanin. Various concentrations of in vitro Sepia melanin in tissue phantoms were measured with NIR fluorescence and diffuse reflectance spectroscopy. Similar optic measurements were conducted in vivo on 161 normal human skin sites. Diffuse reflectance spectroscopy was used to quantify the melanin content via Stamatas–Kollias algorithm. At physiologic concentrations, increasing in vitro melanin concentrations demonstrated higher fluorescence that was linearly correlated (R² = 0.99, p < .001). At higher concentrations, the fluorescence signal plateaued. A linear relationship was also observed with melanin content in human skin (R² = 0.59, p < .001). Comparing the fluorescence and reflectance signals with in vitro and in vivo samples, the estimated melanin concentration in human skin ranged between 0 and 1.25 mg/ml, consistent with previous quantitative studies involving invasive methods.     

Successful selection of an infection‐protective anti‐Staphylococcus aureus monoclonal antibody and its protective activity in murine infection models

Recent clinical trials to develop anti‐methicillin‐resistant Staphylococcus aureus (MRSA) therapeutic antibodies have met unsuccessful sequels. To develop more effective antibodies against MRSA infection, a panel of mAbs against S. aureus cell wall was generated and then screened for the most protective mAb in mouse infection models. Twenty‐two anti‐S. aureus IgG mAbs were obtained from mice that had been immunized with alkali‐processed, deacetylated cell walls of S. aureus. One of these mAbs, ZBIA5H, exhibited life‐saving effects in mouse models of sepsis caused by community‐acquired MRSA strain MW2 and vancomycin‐resistant S. aureus strain VRS1. It also had a curative effect in a MW2‐caused pneumonia model. Curiously, the target of ZBIA5H was considered to be a conformational epitope of either the 1,4‐β‐linkage between N‐acetylmuramic acid and N‐acetyl‐D‐glucosamine or the peptidoglycan per se. Reactivity of ZBIA5H to S. aureus whole cells or purified peptidoglycan was weaker than that of most of the other mAbs generated in this study. However, the latter mAbs did not have the protective activities against S. aureus that ZBIA5H did. These data indicate that the epitopes that trigger production of high‐yield and/or high‐affinity antibodies may not be the most suitable epitopes for developing anti‐infective antibodies. ZBIA5H or its humanized form may find a future clinical application, and its target epitope may be used for the production of vaccines against S. aureus infection.     

A water‐soluble fluorescent pH probe based on perylene dyes and its application to cell imaging

A fluorescent pH probe, N,N′‐bi( l ‐phenylalanine amine)‐perylene‐3,4;9,10‐dicarboxylic diimide (PDCDA) was synthesized and used for pH sensing in living cells. A significant fluorescence intensity change was observed over a pH range from 7.0 to 4.0. Electrostatic potential maps (MEP) suggested that the electronic repulsion between PDCDAs was increased by the high negative electrostatic potential which resulted in a high water solubility of PDCDA. PDCDA was successfully applied as a high‐performance fluorochrome for living HeLa cell imaging. The results demonstrate that the probe PDCDA is a good candidate for monitoring pH fluctuations in living cells with good water solubility, low cytotoxicity, high fluorescence quantum yield and photostability. Copyright © 2015 John Wiley & Sons, Ltd.     

A new xanthene‐based two‐photon fluorescent probe for the imaging of 1,4‐dithiothreitol (DTT) in living cells

1,4‐Dithiothreitol (DTT) has wide applications in cell biology and biochemistry. Development of effective methods for monitoring DTT in biological systems is important for the safe handling and study of toxicity to humans. Herein, we describe a two‐photon fluorescence probe (Rh‐DTT) to detect DTT in living systems for the first time. Rh‐DTT showed high selectivity and sensitivity to DTT. Rh‐DTT can be successfully used for the two‐photon imaging of DTT in living cells, and also can detect DTT in living tissues and mice.     

Novel application of anti‐human Fc nanobody for screening high‐producing CHO cells for monoclonal antibody

Animal‐derived anti‐IgG secondary antibodies are currently employed to stain and screen of human monoclonal antibody(mAb)‐producing cells, but using animal‐derived antibodies may raise the concerns of high cost, complicated operations and biological safety issues in biopharmaceutical manufacturing. Nanobodies(VHHs) are attractive forms of antibodies for their straightforward engineering and expression in both eukaryotic and prokaryotic systems. Using phage‐displayed immune llama VHH library, we identified new anti‐Fc VHHs that could bind to human Fc with high affinity. In GFP fusion format, the anti‐Fc VHH‐GFP generated dramatically stronger FACS signals than AF488 conjugated anti‐IgG antibodies when used for staining mAb‐producing CHO cells. Furthermore, preparative sorting of CHO cells based on anti‐Fc VHH‐GFP staining resulted in the enrichment of cell lines capable of synthesizing mAb at high productivity. This safe and cost‐efficient anti‐Fc VHH‐GFP may optimize the process of generating highly productive cell lines for therapeutic mAb production compared to conventional animal‐derived fluorescent antibodies.     

In vitro and in vivo efficacy of anti‐chikungunya virus monoclonal antibodies produced in wild‐type and glycoengineered Nicotiana benthamiana plants

Chikungunya virus (CHIKV) is a mosquito‐transmitted alphavirus, and its infection can cause long‐term debilitating arthritis in humans. Currently, there are no licensed vaccines or therapeutics for human use to combat CHIKV infections. In this study, we explored the feasibility of using an anti‐CHIKV monoclonal antibody (mAb) produced in wild‐type (WT) and glycoengineered (?XFT) Nicotiana benthamiana plants in treating CHIKV infection in a mouse model. CHIKV mAb was efficiently expressed and assembled in plant leaves and enriched to homogeneity by a simple purification scheme. While mAb produced in ?XFT carried a single N‐glycan species at the Fc domain, namely GnGn structures, WT produced mAb exhibited a mixture of N‐glycans including the typical plant GnGnXF₃ glycans, accompanied by incompletely processed and oligomannosidic structures. Both WT and ?XFT plant‐produced mAbs demonstrated potent in vitro neutralization activity against CHIKV. Notably, both mAb glycoforms showed in vivo efficacy in a mouse model, with a slight increased efficacy by the ?XFT‐produced mAbs. This is the first report of the efficacy of plant‐produced mAbs against CHIKV, which demonstrates the ability of using plants as an effective platform for production of functionally active CHIKV mAbs and implies optimization of in vivo activity by controlling Fc glycosylation.     

A coumarin‐based fluorescent probe for Hg2+ and its application in living cells and zebrafish

Mercury (Hg) is a heavy metal with high toxicity and easy migration; it can be enriched through the food chain, and cause serious threats to the natural environment and human health. So, the development of a method that can be used to detect mercury ions (Hg²⁺) in the environment, in cells, and in organisms is very important. Here, a new 7‐hydroxycoumarin‐derived carbonothioate‐based probe ( CC‐Hg ) was designed and synthesized for detection of Hg²⁺. After addition of Hg²⁺, a large fluorescence enhancement was observed due to the formation of 7‐hydroxyl, which reinforced the intramolecular charge transfer process. The CC‐Hg probe had good water solubility and selectivity. Moreover, the probe was able to detect Hg²⁺ quantitatively over the concentration range 0–2 μM and with a detection limit of 7.9 nM. Importantly, we successfully applied the probe to detect Hg²⁺ in water samples, in living cells, and in zebrafish. The experimental results demonstrated its potential value in practical applications.     

The whither of bacteriophytochrome‐based near‐infrared fluorescent proteins: Insights from two‐photon absorption spectroscopy

We present one‐ and two‐photon‐absorption fluorescence spectroscopic analysis of biliverdin (BV) chromophore–based single‐domain near‐infrared fluorescent proteins (iRFPs). The results of these studies are used to estimate the internal electric fields acting on BV inside iRFPs and quantify the electric dipole properties of this chromophore, defining the red shift of excitation and emission spectra of BV‐based iRFPs. The iRFP studied in this work is shown to fit well the global diagram of the red‐shift tunability of currently available BV‐based iRFPs as dictated by the quadratic Stark effect, suggesting the existence of the lower bound for the strongest red shifts attainable within this family of fluorescent proteins. The absolute value of the two‐photon absorption (TPA) cross section of a fluorescent calcium sensor based on the studied iRFP is found to be significantly larger than the TPA cross sections of other widely used genetically encodable fluorescent calcium sensors.      

A novel anti‐prion protein monoclonal antibody and its single‐chain fragment variable derivative with ability to inhibit abnormal prion protein accumulation in cultured cells

mAbs T1 and T2 were established by immunizing PrP gene ablated mice with recombinant MoPrP of residues 121–231. Both mAbs were cross‐reactive with PrP from hamster, sheep, cattle and deer. A linear epitope of mAb T1 was identified at residues 137–143 of MoPrP and buried in PrP^C expressed on the cell surface. mAb T1 showed no inhibitory effect on accumulation of PrP^Sc in cultured scrapie‐infected neuroblastoma (ScN2a) cells. In contrast, mAb T2 recognized a discontinuous epitope ranged on, or structured by, residues 132–217 and this epitope was exposed on the cell surface PrP^C. mAb T2 showed an excellent inhibitory effect on PrP^Sc accumulation in vitro at a 50% inhibitory concentration of 0.02 μg/ml (0.14 nM). The scFv form of mAb T2 (scFv T2) was secreted in neuroblastoma (N2a58) cell cultures by transfection through eukaryotic secretion vector. Coculturing of ScN2a cells with scFv T2‐producing N2a58 cells induced a clear inhibitory effect on PrP^Sc accumulation, suggesting that scFv T2 could potentially be an immunotherapeutic tool for prion diseases by inhibition of PrP^Sc accumulation.     

Expression of recombinant anti‐colorectal cancer large single‐chain monoclonal antibody in insect cells

Colorectal cancer is the third most commonly diagnosed cancer in the world. Monoclonal antibody (mAb) CO17‐1A recognizes the tumor‐associated antigen GA733‐2, a cell surface glycoprotein highly expressed in colorectal carcinoma cells which is applicable for preventing and curing colorectal cancer. In this study, we tried to produce a new recombinant anti‐colorectal cancer large single chain (lsc) mAb based on mAb CO17‐1A in the baculovirus‐insect cell protein expression system. Two kinds of recombinant lsc mAbs were generated where variable light chain (VL) and heavy chain (HC) of mAb CO17‐1A were fused together by an interchain linker. The only difference between the two mAbs is based on fusion of an ER retention signal (KDEL) at its C‐terminus of HC. Polymerase chain reaction analysis verified the presence of both recombinant genes in the bacmid for generating viral expression vectors in insect cells. Western blot confirmed the expression of lsc mAbs in baculovirus‐infected insect cells. Cell enzyme linked immunosorbent assay (ELISA) showed that the mAbs from cell lysates bound to SW480 and SW620 human colorectal cancer cells. These results indicate that the baculovirus insect expression system can produce anti‐colorectal lsc mAb recognizing human colorectal cancer cells.     

Widefield fluorescence lifetime imaging of protoporphyrin IX for fluorescence‐guided neurosurgery: An ex vivo feasibility study

Achieving a maximal safe extent of resection during brain tumor surgery is the goal for improved patient prognosis. Fluorescence‐guided neurosurgery using 5‐aminolevulinic acid (5‐ALA) induced protoporphyrin IX has thereby become a valuable tool enabling a high frequency of complete resections and a prolonged progression‐free survival in glioblastoma patients. We present a widefield fluorescence lifetime imaging device with 250 mm working distance, working under similar conditions such as surgical microscopes based on a time‐of‐flight dual tap CMOS camera. In contrast to intensity‐based fluorescence imaging, our method is invariant to light scattering and absorption while being sensitive to the molecular composition of the tissue. We evaluate the feasibility of lifetime imaging of protoporphyrin IX using our system to analyze brain tumor phantoms and fresh 5‐ALA‐labeled human tissue samples. The results demonstrate the potential of our lifetime sensing device to go beyond the limitation of current intensity‐based fluorescence‐guided neurosurgery.      

Rational design of a monomeric and photostable far‐red fluorescent protein for fluorescence imaging in vivo

Fluorescent proteins (FPs) are powerful tools for cell and molecular biology. Here based on structural analysis, a blue‐shifted mutant of a recently engineered monomeric infrared fluorescent protein (mIFP) has been rationally designed. This variant, named iBlueberry, bears a single mutation that shifts both excitation and emission spectra by approximately 40 nm. Furthermore, iBlueberry is four times more photostable than mIFP, rendering it more advantageous for imaging protein dynamics. By tagging iBlueberry to centrin, it has been demonstrated that the fusion protein labels the centrosome in the developing zebrafish embryo. Together with GFP‐labeled nucleus and tdTomato‐labeled plasma membrane, time‐lapse imaging to visualize the dynamics of centrosomes in radial glia neural progenitors in the intact zebrafish brain has been demonstrated. It is further shown that iBlueberry can be used together with mIFP in two‐color protein labeling in living cells and in two‐color tumor labeling in mice.     

Optimal imaging windows of indocyanine green‐assisted near‐infrared dental imaging with rat model and its comparison to X‐ray imaging

In this study, we used rat animal model to compare the efficiency of indocyanine green (ICG)‐assisted dental near‐infrared fluorescence imaging with X‐ray imaging, and we optimized the imaging window for both unerupted and erupted molars. The results show that the morphology of the dental structures was observed clearly from ICG‐assisted dental images (especially through the endoscope). A better image contrast was easily acquired at the short imaging windows (<10 minutes) for unerupted and erupted molars. For unerupted molars, there is another optimized imaging window (48‐96 hours) with a prominent glow‐in‐the‐dark effect: only the molars remain bright. This study also revealed that the laser ablation of dental follicles can disrupt the molar development, and our method is able to efficiently detect laser‐treated molars and acquire the precise morphology. Thus, ICG‐assisted dental imaging has the potential to be a safer and more efficient imaging modality for the real‐time diagnosis of dental diseases.     

Expression of recombinant anti‐breast cancer immunotherapeutic monoclonal antibody in baculovirus–insect cell system

The anti‐breast cancer monoclonal antibody (mAb) BR55 was expressed in the baculovirus–insect cell expression system, which is advantageous because of its high production capacity, cell culture flexibility and glycosylation capability. The baculovirus–insect cell expression system was successfully established for production of mAb BR55 and mAb BR55 fused with the KDEL (Lys–Asp–Glu–Leu) endoplasmic reticulum (ER) retention signal (mAb BR55K). The heavy chain (HC) and light chain (LC) genes of mAb BR55 were cloned under the control of the polyhedrin (P_PH) and P₁₀ promoters, respectively, in the pFastBacDual vector. The antibody gene‐expression cassettes carrying both the HC and LC genes were transferred into a bacmid in Escherichia coli (DH10Bac). The bacmid carrying the expression cassettes was transfected into Sf9 insect cells to generate baculovirus expressing mAb BR55 and BR55K. Western blot analysis confirmed the expression of mAb BR55 and BR55K in baculovirus‐infected insect cells. Cell direct enzyme linked immunosorbent assay (ELISA) showed that both mAbs from insect cell lysates or cell culture medium bound to MCF‐7 human breast cancer cells. Both mAb BR55 and BR55K were successfully purified using a Protein A affinity column. Collectively, these results suggest that the anti‐breast cancer mAb BR55 can be expressed, properly assembled and purified from the baculovirus expression system, which can serve as an alternative system for antibody production.     

Correlation of interleukin‐6 and monocyte chemotactic protein‐1 concentrations with crescent formation and myeloperoxidase‐specific anti‐neutrophil cytoplasmic antibody titer in SCG/Kj mice by treatment with anti‐interleukin‐6 receptor antibody or mizoribine

Myeloperoxidase‐specific anti‐neutrophil cytoplasmic antibody (MPO–ANCA) is associated with rapidly progressive glomerulonephritis (RPGN) and glomerular crescent formation. Pathogenic factors in RPGN were analyzed by using SCG/Kj mice, which spontaneously develop MPO–ANCA‐associated RPGN. The serum concentration of soluble IL‐6R was determined by using ELISA and those of another 23 cytokines and chemokines by Bio‐Plex analysis. Sections of frozen kidney tissue were examined by fluorescence microscopy and the CD3⁺B220⁺ T cell subset in the spleen determined by a flow cytometry. Concentrations of IL‐6 and monocyte chemotactic protein‐1 were significantly correlated with the percentages of crescent formation. Anti‐IL‐6R antibody, which has been effective in patients with rheumatoid arthritis, was administered to SCG/Kj mice to elucidate the role of IL‐6 in the development of RPGN. MPO–ANCA titers decreased after administration of anti‐IL‐6R antibody, but not titers of mizoribine, which is effective in Kawasaki disease model mice. These results suggest that IL‐6‐mediated signaling is involved in the production of MPO–ANCA.     

Subchronic intravenous toxicity study of biofunctional ZnO and its application as a fluorescence probe for cell‐specific targeting

Successful development of safe and highly effective nanoprobes for targeted imaging of in vivo early cancer is a great challenge. Herein, we choose the visible‐light emitting zinc oxide non–core/shell type nanoparticle (NP) fluorophores (ZHIE) as prototypical materials. We have reported on these materials previously. The results showed that the ZHIE NPs exhibited good water solubility and good biocompatibility. This study was conducted to investigate the toxicity of ZHIE NPs when intravenously administered to mice repeatedly at the dose required for successful tumor imaging in vivo. Anti‐macrophage‐1 antigen (Mac1), a macrophage differentiation antigen, antibody‐conjugated ZHIE NPs successfully realized targeted imaging of murine macrophage cell line Raw264.7 cells. In conclusion, ZHIE NPs are not toxic in vivo and antibody‐conjugated ZHIE NPs have great potential in applications, such as single cell labeling.     

Epitope specificity of two anti‐morphine monoclonal antibodies: In vitro and in silico studies

Monoclonal antibodies (mAbs) against morphine are important in the development of immunotherapeutic and diagnostic methods for the treatment and prevention of drug addiction. By the surface plasmon resonance (SPR) and enzyme immunoassay techniques, we characterized two previously obtained mAbs 3K11 and 6G1 and showed their ability to recognize free morphine and morphine‐containing antigens in different ways because of the epitope specificity thereof. Using the defined amino acid sequences, we obtained three‐dimensional models of the variable regions of Fab fragments of these antibodies and compared them with the known sequence and spatial structure of the anti‐morphine antibody 9B1. Docking simulations are performed to obtain models of the antibodies complexes with morphine. Differences in the models of 3K11 and 6G1 complexes with morphine correlate with their experimentally detected epitope specificity. The results, in particular, can be used for the structure‐based design of the corresponding humanized antibodies. According to our modeling and docking results, the very different modes of morphine binding to mAbs 3K11 and 6G1 are qualitatively similar to those previously reported for cocaine and two anti‐cocaine antibodies. Thus, the obtained structural information brings more insight into the hapten recognition diversity.