Brucella abortus S19 GFP-tagged vaccine allows the serological identification of vaccinated cattle.

Bovine brucellosis induces abortion in cows, produces important economic losses, and causes a widely distributed zoonosis. Its eradication was achieved in several countries after sustained vaccination with the live attenuated Brucella abortus S19 vaccine, in combination with the slaughtering of serologically positive animals. S19 induces antibodies against the smooth lipopolysaccharide (S-LPS), making difficult the differentiation of infected from vaccinated bovines. We developed an S19 strain constitutively expressing the green fluorescent protein (S19-GFP) coded in chromosome II. The S19-GFP displays similar biological characteristics and immunogenic and protective efficacies in mice to the parental S19 strain. S19-GFP can be distinguished from S19 and B. abortus field strains by fluorescence and multiplex PCR. Twenty-five heifers were vaccinated withS19-GFP (5×109 CFU) by the subcutaneous or conjunctival routes and some boosted with GFP seven weeks thereafter. Immunized animals were followed up for over three years and tested for anti-S-LPS antibodies by both the Rose Bengal test and a competitive ELISA. Anti-GFP antibodies were detected by an indirect ELISA and Western blotting. In most cases, anti-S-LPS antibodies preceded for several weeks those against GFP. The anti-GFP antibody response was higher in the GFP boosted than in the non-boosted animals. In all cases, the anti-GFP antibodies persisted longer, or at least as long, as those against S-LPS. The drawbacks and potential advantages of using the S19-GFP vaccine for identifying vaccinated animals in infected environments are discussed.

Advances in the Genetically Engineered KillerRed for Photodynamic Therapy Applications.

Photodynamic therapy (PDT) is a clinical treatment for cancer or non-neoplastic diseases, and the photosensitizers (PSs) are crucial for PDT efficiency. The commonly used chemical PSs, generally produce ROS through the type II reaction that highly relies on the local oxygen concentration. However, the hypoxic tumor microenvironment and unavoidable dark toxicity of PSs greatly restrain the wide application of PDT. The genetically encoded PSs, unlike chemical PSs, can be modified using genetic engineering techniques and targeted to unique cellular compartments, even within a single cell. KillerRed, as a dimeric red fluorescent protein, can be activated by visible light or upconversion luminescence to execute the Type I reaction of PDT, which does not need too much oxygen and surely attract the researchers' focus. In particular, nanotechnology provides new opportunities for various modifications of KillerRed and versatile delivery strategies. This review more comprehensively outlines the applications of KillerRed, highlighting the fascinating features of KillerRed genes and proteins in the photodynamic systems. Furthermore, the advantages and defects of KillerRed are also discussed, either alone or in combination with other therapies. These overviews may facilitate understanding KillerRed progress in PDT and suggest some emerging potentials to circumvent challenges to improve the efficiency and accuracy of PDT.

Nanotheranostic Application of Fluorescent Protein-Gold Nanocluster Hybrid Materials: A Mini-review.

The gold nanoclusters (Au NCs) are a special kind of gold nanomaterial containing several gold atoms. Because of their small size and large surface area, Au NCs possess macroscopic quantum tunneling and dielectric domain effects. Furthermore, Au NCs fluorescent materials have longer luminous time and better photobleaching resistance compared with other fluorescent materials. The synthetic process of traditional Au NCs is complicated. Traditional Au NCs are prepared mainly by using polyamide amine type dendrites, and sixteen alkyl trimethylamine bromide or sulfhydryl small molecule as stabilizers. They are consequently synthesized by the reduction of strong reducing agents such as sodium borohydride. Notably, these materials are toxic and environmental-unfriendly. Therefore, there is an urgent need to develop more effective methods for synthesizing Au NCs via a green approach. On the other hand, the self-assembly of protein gold cluster-based materials, and their biomedical applications have become research hotspots in this field. We have been working on the synthesis, assembly and application of protein conjugated gold clusters for a long time. In this review, the synthesis and assembly of protein-gold nanoclusters and their usage in cell imaging and other medical research are discussed.

Triple función de la fluorescencia con verde de indocianina en cirugía colorrectal / Triple function of indocyanine green fluorescence in colorectal surgery

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Immunomodulatory Lipocomplex Functionalized with Photosensitizer-Embedded Cancer Cell Membrane Inhibits Tumor Growth and Metastasis.

Liposomes are clinically used as drug carriers for cancer therapy; however, unwanted leakage of the encapsulated anticancer drug and poor tumor-targeting efficiency of liposomes may generate toxic side effects on healthy cells and lead to failure of tumor eradication. To overcome these limitations, we functionalized liposomes with a photosensitizer (KillerRed, KR)-embedded cancer cell membrane (CCM). A lipid adjuvant was also embedded in the lipocomplex to promote the anticancer immune response. KR proteins were expressed on CCM and did not leak from the lipocomplex. Owing to the homotypic affinity of the CCM for the source cancer cells, the lipocomplex exhibited a 3.3-fold higher cancer-targeting efficiency in vivo than a control liposome. The liposome functionalized with KR-embedded CCM and lipid adjuvant generated cytotoxic reactive oxygen species in photodynamic therapy and effectively induced anticancer immune responses, inhibiting primary tumor growth and lung metastasis in homotypic tumor-bearing mice. Taken together, the lipocomplex technology may improve liposome-based cancer therapy.

MR-guided parenchymal delivery of adeno-associated viral vector serotype 5 in non-human primate brain.

The present study was designed to characterize transduction of non-human primate brain and spinal cord with AAV5 viral vector after parenchymal delivery. AAV5-CAG-GFP (1 × 1013 vector genomes per milliliter (vg ml-1)) was bilaterally infused either into putamen, thalamus or with the combination left putamen and right thalamus. Robust expression of GFP was seen throughout infusion sites and also in other distal nuclei. Interestingly, thalamic infusion of AAV5 resulted in the transduction of the entire corticospinal axis, indicating transport of AAV5 over long distances. Regardless of site of injection, AAV5 transduced both neurons and astrocytes equally. Our data demonstrate that AAV5 is a very powerful vector for the central nervous system and has potential for treatment of a wide range of neurological pathologies with cortical, subcortical and/or spinal cord affection.

Deep-penetrating photodynamic therapy with KillerRed mediated by upconversion nanoparticles.

The fluorescent protein KillerRed, a new type of biological photosensitizer, is considered as a promising substitute for current synthetic photosensitizes used in photodynamic therapy (PDT). However, broad application of this photosensitiser in treating deep-seated lesions is challenging due to the limited tissue penetration of the excitation light with the wavelength falling in the visible spectral range. To overcome this challenge, we employ upconversion nanoparticles (UCNPs) that are able to convert deep-penetrating near infrared (NIR) light to green light to excite KillerRed locally, followed by the generation of reactive oxygen species (ROS) to kill tumour cells under centimetre-thick tissue. The photosensitizing bio-nanohybrids, KillerRed-UCNPs, are fabricated through covalent conjugation of KillerRed and UCNPs. The resulting KillerRed-UCNPs exhibit excellent colloidal stability in biological buffers and low cytotoxicity in the dark. Cross-comparison between the conventional KillerRed and UCNP-mediated KillerRed PDT demonstrated superiority of KillerRed-UCNPs photosensitizing by NIR irradiation, manifested by the fact that ∼70% PDT efficacy was achieved at 1-cm tissue depth, whereas that of the conventional KillerRed dropped to ∼7%. STATEMENT OF SIGNIFICANCE: KillerRed is a protein photosensitizer that holds promise as an alternative for the existing hydrophobic photosensitizers that are widely used in clinical photodynamic therapy (PDT). However, applications of KillerRed to deep-seated tumours are limited by the insufficient penetration depth of the excitation light in highly scattering and absorbing biological tissues. Herein, we reported the deployment of upconversion nanoparticles (UCNPs) to enhance the treatment depth of KillerRed by converting the deep-penetrating near-infrared (NIR) light to upconversion photoluminescence and activating the PDT effect of KillerRed under deep tissues. This work demonstrated clear potential of UCNPs as the NIR-to-visible light converter to overcome the light penetration limit that has plagued PDT application for many years.

Effects of Self-Complementarity, Codon Optimization, Transgene, and Dose on Liver Transduction with AAV8.

Numerous methods of vector design and delivery have been employed in an attempt to increase transgene expression following AAV-based gene therapy. Here, a gene transfer study was conducted in mice to compare the effects of vector self-complementarity (double- or single-stranded DNA), codon optimization of the transgene, and vector dose on transgene expression levels in the liver. Two different reporter genes were used: human ornithine transcarbamylase (hOTC) detected by immunofluorescence, and enhanced green fluorescent protein (EGFP) detected by direct fluorescence. The AAV8 capsid was chosen for all experiments due to its strong liver tropism. While EGFP is already a codon-optimized version of the original gene, both wild-type (WT) and codon-optimized (co) versions of the hOTC transgene were compared in this study. In addition, the study evaluated which of the two hOTC modifications-codon optimization or self-complementarity-would confer the highest increase in expression levels at a given dose. Interestingly, based on morphometric image analysis, it was observed that the difference in detectable expression levels between self-complementary (sc) and single-stranded (ss) hOTCco vectors was dose dependent, with a sevenfold increase in OTC-positive area using sc vectors at a dose of 3 × 109 genome copies (GC) per mouse, but no significant difference at a dose of 1 × 1010 GC/mouse. In contrast, with EGFP as a transgene, the increases in expression levels when using the sc vector were observed at both the 3 × 109 GC/mouse and 1 × 1010 GC/mouse doses. Furthermore, codon optimization of the hOTC transgene generated a more significant improvement in expression than the use of self-complementarity did. Overall, the results demonstrate that increases in expression levels gained by using sc vectors instead of ss vectors can vary between different transgenes, and that codon optimization of the transgene can have an even more powerful effect on the resulting expression levels.

Use of αv Integrin Linked to Green Fluorescent Protein in Osteosarcoma Cells and Confocal Microscopy to Image Molecular Dynamics During Lung Metastasis in Nude Mice.

BACKGROUND: We report here imaging of the behavior of αv integrin linked to green fluorescent protein (GFP) in human osteosarcoma cells colonizing the lung of nude mice. MATERIALS AND METHODS: 143B osteosarcoma cells expressing αv integrin-GFP were generated by transfection of an αv integrin-GFP fusion-gene vector pCMV-AC- ITGAV-GFP. In order to generate experimental lung metastases, 143B osteosarcoma cells (1×10(6)), stably expressing αv integrin-GFP, were injected intravenously via the tail vein. The osteosarcoma cells were transplanted orthotopically in the tibia of nude mice in order to generate spontaneous metastases. Lungs were harvested and imaged by confocal microscopy within 1 hour. RESULTS: In the experimental lung-metastasis model, extravasating and deformed osteosarcoma cells expressing αv integrin-GFP were observed. Pseudopodia of the osteosarcoma cells contained small puncta of αv integrin-GFP. In early-stage spontaneous lung metastasis, tumor emboli were observed in pulmonary vessels. At high magnification, small αv integrin-GFP puncta were observed in the tumor embolus. In late-stage spontaneous metastasis, tumor emboli were also observed in pulmonary vessels. Invading cancer cells with strong expression of αv integrin-GFP were observed at the margin of the tumor emboli. CONCLUSION: The results of this study demonstrate that molecular dynamics of αv integrin-GFP can be imaged in lung metastasis, which will allow further understanding of the role of αv integrin in this process. The results also suggest a general concept for imaging molecular behavior in vivo.

Experimental Curative Fluorescence-guided Surgery of Highly Invasive Glioblastoma Multiforme Selectively Labeled With a Killer-reporter Adenovirus.

Fluorescence-guided surgery (FGS) of cancer is an area of intense current interest. However, although benefits have been demonstrated with FGS, curative strategies need to be developed. Glioblastoma multiforme (GBM) is one of the most invasive of cancers and is not totally resectable using standard bright-light surgery (BLS) or current FGS strategies. We report here a curative strategy for FGS of GBM. In this study, telomerase-dependent adenovirus OBP-401 infection brightly and selectively labeled GBM with green fluorescent protein (GFP) for FGS in orthotopic nude mouse models. OBP-401-based FGS enabled curative resection of GBM without recurrence for at least 150 days, compared to less than 30 days with BLS.

Transplantation of NIT-1 cells with ectopic FADDdel-GFP expression for treatment of streptozotocin-induced diabetes.

Islet transplantation is considered a therapeutic option for type 1 diabetes (T1D). However, allorejection is one major barrier for the successful islet transplantation. In the present study, we have tested the feasibility of a deletion construct for Fas-associated death domain protein (FADD; without the death effecter domain) fused with green fluorescent protein (FADDdel-GFP) for blocking the Fas-FasL signaling pathway in prevention of transplanted beta cell destruction by allo-rejection in T1D. In vitro studies have shown that NIT-1 cells with ectopic FADDdel expression were resistant to cytokine-induced apoptosis and CTL-mediated lysis. Diabetic Balb/c mice reached normoglycemia promptly and gained weight after transplantation of NIT-1 cells with ectopic FADDdel-GFP expression. These recipients showed a significant longer survival time than that of recipients transplanted with NIT cells with ectopic GFP expression only. Our results together suggest that FADDdel could be a useful target for the improvement of islet transplantation for T1D.

Direct and distant antitumor effects of a telomerase-selective oncolytic adenoviral agent, OBP-301, in a mouse prostate cancer model.

We previously constructed OBP-301 (Telomelysin, a telomerase-specific replication-competent adenovirus with human telomerase reverse transcriptase (hTERT) promoter), which showed a strong anticancer effect by inducing cell lysis of human non-small cell lung cancer and colorectal cancer cells. To investigate the utility of OBP-301 for prostate cancer treatment, we herein evaluate the cell killing and antitumor effects. First, in vitro hTERT-specific adenovirus transduction in human prostate cancer cells (LNCaP, PC3, DU145) was confirmed using OBP-401 (Telomelysin-green fluorescent protein (GFP)). There was no detectable GFP transduction in the human prostate normal cells (PrEC, PrSC). Consistently, the cell-killing effect of OBP-301 was observed only in the cancer cells. Second, using an in vivo subcutaneous LNCaP tumor model in nude mice, we demonstrated that three intratumoral OBP-301 injections (10(7) PFU per tumor x 3 days) were sufficient to eradicate the detectable LNCaP prostate tumor. We also demonstrated that the ispilateral treatment with OBP-301 significantly suppressed contralateral LNCaP tumor growth in both sides of the tumor model. Histological and immunohistochemical analyses revealed diffuse oncolytic degeneration and adenoviral E1A protein expression in both sides of the tumors. Therefore, in situ OBP-301 administration could be a promising therapeutic strategy against prostate cancer and its metastatic lesions.

The use of tissue-engineered bone with human bone morphogenetic protein-4-modified bone-marrow stromal cells in repairing mandibular defects in rabbits.

In this study, the capacity of hBMP-4 gene therapy combined with tissue-engineering techniques to improve the repair of mandibular osseous defects in rabbits was explored. A mammalian plasmid vector expressing enhanced green fluorescent protein-human bone morphogenetic protein-4 (pEGFP-hBMP-4) was initially constructed through subcloning techniques. Bone-marrow stromal cells (bMSCs) from New Zealand White rabbits were cultured and either transfected with pEGFP-hBMP-4 or pEGFP, or left untransfected in vitro. Once the transfer efficiency was determined through the expression of EGFP, cells from the three groups were combined with natural non-organic bone (NNB) at a concentration of 50 x 10(6)cells/ml and placed in 15 mm x 6 mm bilateral, full-thickness, mandibular defects surgically made in 12 rabbits. Together with NNB control, there were six samples per group. Four weeks after surgery, the implants were harvested and evaluated histomorphologically. Under optimal experimental conditions, gene transfer efficiency reached a maximum of 38.2+/-9.4%. While the percentage of new bone area in the NNB control group was 8.8+/-3.1%, in the untransfected bMSC group 22.5+/-8.2%, and in the pEGFP group 18.1+/-9.0%, a significantly higher amount of 32.5+/-6.1% was observed in the pEGFP-hBMP-4 group. These results suggest that transfection of bMSCs with hBMP-4 enhances their inherent osteogenic capacity for maxillofacial bone tissue-engineering applications.

Fibroblast growth factor-2-retargeted adenoviral vector for selective transduction of primary glioblastoma multiforme endothelial cells.

OBJECT: Adenovirus transduction in gene therapy is dependent on the expression of the coxsackie virus-adenovirus receptor (CAR) for initial binding and on the integrin receptors (avb3, avb5) for viral internalization. Low and variable expression of CAR may be responsible for the low transduction rates seen with native adenoviral vectors. The goal of this study was to demonstrate increased transduction efficiency by retargeting the adenovirus with a fibroblast growth factor (FGF) ligand, FGF-2. METHODS: The retargeted adenoviruses were used to transduce human glioblastoma multiforme (GBM)-derived ECs (tumor-associated brain endothelial cells [TuBECs]), in which there is minimal CAR expression but a high expression of FGF receptor (FGFR). The results demonstrate that the transduction efficiency of TuBECs can reach as high as 80% when one uses an FGF2-conjugated adenovirus containing green fluorescent protein (FGF2-AdGFP) yet be only 5% when one uses the native adenovirus (AdGFP). The TuBECs were transduced with either a native adenovirus (AdHSV-TK) or a retargeted adenovirus (FGF2-AdHSV-TK), both of which carry the suicide herpes simplex virus-thymidine kinase (HSV-TK) gene. Administered as a cytotoxic prodrug, ganciclovir induced a significant decline in the proliferation rate and increased apoptosis in TuBECs treated with the retargeted adenovirus, compared with its effect on TuBECs treated with the native adenovirus. Increased transduction efficiency was determined by performing GFP-based flow cytometry, and the expression of the TK protein by the retargeted adenovirus was assessed by performing an immunohistochemical analysis focused on HSV-TK. The mechanism of cytotoxicity was determined to be apoptosis by performing a terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick-end labeling assay. CONCLUSIONS: Fibroblast growth factor-2-retargeted adenoviral vectors may be used to increase the transduction of GBM-derived endothelial cells, enabling a new and efficient antiangiogenesis strategy for the treatment of malignant gliomas.

Liposome-mediated adenomatous polyposis coli gene therapy: a novel anti-adenoma strategy in multiple intestinal neoplasia mouse model.

PURPOSE: Familial adenomatous polyposis is a highly penetrant, autosomal dominant disease resulting from a germline mutation of the adenomatous polyposis coli gene. Besides colorectal polyps and cancer, more than 90 percent of familial adenomatous polyposis patients also develop duodenal polyposis with an approximately 5 percent lifetime risk of malignant transformation. Because adenomatous polyposis coli protein has a "gatekeeper role" in the adenoma-carcinoma sequence, replacing its function may reduce polyp formation. We studied the functional outcome of per-oral, liposome-mediated adenomatous polyposis coli gene replacement therapy in a multiple intestinal neoplasia mouse model. METHODS: Twenty multiple intestinal neoplasia mice, heterozygous for the human homologue adenomatous polyposis coli gene, were randomly assigned to three groups: no treatment (n = 8); control plasmid containing green fluorescence protein reporter gene (n = 6); and plasmid containing the full-length adenomatous polyposis coli gene (n = 6). For the adenomatous polyposis coli-treated and green fluorescence protein reporter gene-treated groups, each mouse received the appropriate plasmid complexed with liposome, administered twice per week by oral gavage regime. Treatment lasted four weeks and all animals were killed at the end of treatment period with harvesting of intestinal tissue for polyp number estimation. RESULTS: There was a statistically significant 25 percent reduction in the total number of polyps in the adenomatous polyposis coli-treated (73.1 +/- 1.4) group compared with untreated control (97.8 +/- 5.3, P < 0.01, Tukey test) and multiple intestinal neoplasia mice treated with control green fluorescence protein gene (103.3 +/- 1.7, P < 0.01, Tukey test). CONCLUSION: Adenomatous polyposis coli gene dysfunction underlies tumorigenesis in familial adenomatous polyposis patients and multiple intestinal neoplasia mice. This in vivo study provides evidence to support a novel anti-adenoma strategy using enteral adenomatous polyposis coli gene replacement therapy.