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Adenovirus Vaccine

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Most cited protocols related to «Adenovirus Vaccine»

Spreading and Measuring DNA Fibers

Cited 64 times

Chromosomes and nuclei were spread onto glass slides following a standard procedure. Cell cultures (5 × 10⁵ cells/ml) were incubated in medium containing colcemid (50 ng/ml, 30 min; 37°C; Sigma Chemical Co., Ltd.), washed once in HBSS, once in PBS, swollen (0.075 M KCl, 15 min; 37°C), fixed with methanol/acetic acid (3:1), dropped (three drops; 2.5 × 10⁶ cells/ml) onto washed slides, and then air dried.
To prepare extended DNA fibers (Parra and Windle, 1993 (link)), 2 μl cells resuspended in PBS (10⁶ cells/ml) were spotted onto cleaned glass slides and lysed with 5 μl of 0.5% SDS in 200 mM Tris-HCl, pH 7.4, 50 mM EDTA (10 min, 20°C). Slides were tilted (15° to horizontal), allowing a stream of DNA to run slowly down the slide, air dried, and then fixed in methanol/acetic acid (3:1). For most purposes, cells containing halogenated DNA were diluted 30- and 100-fold with untreated HeLa cells, before spreading. This simplifies the spreads, allows isolated labeled DNA fibers to be found with relative ease, and makes possible the identification of replicons from a single labeled cell (see Fig. 4).
To estimate the extension of DNA fibers, spreads were prepared from HeLa cells infected with adenovirus serotype 2 and grown in medium supplemented with 100 μM BrdU 15–20 h after infection (Pombo et al., 1994 (link)). Abundant Br-labeled DNA molecules measured 13.9 ± 1.3 μm (mean ± SD; n = 50). As the viral genome is 36 kbp, the extension of these DNA fibers is 2.59 ± 0.24 kbp/μm.

Jackson D.A, & Pombo A. (1998). Replicon Clusters Are Stable Units of Chromosome Structure: Evidence That Nuclear Organization Contributes to the Efficient Activation and Propagation of S Phase in Human Cells. The Journal of Cell Biology, 140(6), 1285-1295.

Publication 1998

Acetic Acid Adenovirus Vaccine Bromodeoxyuridine Cell Culture Techniques Cell Nucleus Cells Chromosomes Colcemide DNA, A-Form Edetic Acid HeLa Cells Hemoglobin, Sickle Infection Methanol Replicon Tromethamine Viral Genome

Recombinant Adenovirus Generation Protocol

Cited 47 times

Recombinant adenovirus was generated as described previously [13] (link). In brief, a
DNA fragment encoding NLS-EGFP-2A-mCherry-CAAX was cloned into the NotI/SalI
sites of a pShuttle vector (Agilent Technologies, CA, USA). The resulting
construct was linearized with PmeI and then introduced via electroporation into
BJ5183 electroporation-competent cells harboring pAdEasy-1 (Agilent
Technologies). The resulting recombinant clones were selected by kanamycin and
digestion with restriction endonucleases. Subsequently, the verified clone was
amplified, linearized with PacI and then transfected into HEK293 A packaging
cells. The recombinant adenovirus was released from the cells through four
freeze-thaw-vortex cycles 14–20 day post-transfection, amplified through
infection of HEK293 A packaging cells and purified by CsCl ultracentrifugation.
The resulting high-titer (tissue-culture infected dose at 50%
[TCID₅₀]) recombinant adenovirus was injected into mice
via the tail vein.

Kim J.H., Lee S.R., Li L.H., Park H.J., Park J.H., Lee K.Y., Kim M.K., Shin B.A, & Choi S.Y. (2011). High Cleavage Efficiency of a 2A Peptide Derived from Porcine Teschovirus-1 in Human Cell Lines, Zebrafish and Mice. PLoS ONE, 6(4), e18556.

Publication 2011

Adenovirus Vaccine Cells cesium chloride Clone Cells Cloning Vectors DNA, Ancient DNA Restriction Enzymes Electroporation Kanamycin Tail Tissues Transfection Ultracentrifugation Veins

Isolation and Culture of Glioblastoma Stem Cells

Cited 44 times

Protocol full text hidden due to copyright restrictions

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Publication 2013

accutase Adenovirus Vaccine Cells Cloning Vectors Culture Media Cytokine Diagnosis Ethics Committees, Research Growth Factor Homo sapiens IL10 protein, human isolation Malignant Neoplasms Neoplasms Patients PDGFD protein, human Tissues Transforming Growth Factor beta Tumor Necrosis Factor-alpha

Conditional Cassette Insertion into ROSA26

Cited 37 times

The components of the ROSA26 targeting vectors were a gift from Philippe Soriano. The adenovirus splice acceptor (SA) and bovine growth hormone polyadenylation sequence (bpA) were from plasmid pSAβgeo [21 (link)]. The loxP flanked neo cassette, and trimer of the SV40 polyadenylation sequence (tpA), were from plasmid PGKneotpAlox2 [4 (link)]. The ROSA26 genomic sequence and the diphtheria toxin (DTA) expression cassette were from plasmid pROSA26-1 [4 (link)], and the template for the external probe used to genotype ES cells was from plasmid pROSA26-5' [4 (link)].
The plasmids pEYFP-N1 and pECFP containing cDNA for EYFP and ECFP were purchased from Clontech Laboratories Inc.

Srinivas S., Watanabe T., Lin C.S., William C.M., Tanabe Y., Jessell T.M, & Costantini F. (2001). Cre reporter strains produced by targeted insertion of EYFP and ECFP into the ROSA26 locus. BMC Developmental Biology, 1, 4.

Publication 2001

Adenovirus Vaccine Cloning Vectors Diphtheria Toxin DNA, Complementary Embryonic Stem Cells Genome Genotype growth hormone, bovine Plasmids Polyadenylation Simian virus 40

Engineering Redox-Sensitive RoGFP Sensors

Cited 27 times

The RoGFP protein contains two engineered cysteine thiols, as first described by Remington et al. (RoGFP2) 11 (link). The cDNA encoding the protein was created by introducing four mutations in the mammalian GFP expression vector (pEGFP-N1) (C48S, Q80R, S147C, and Q204C) using a QuikChange Multi Site-directed mutagenesis kit (Strategene). The RoGFP construct was ligated into the VQ Ad5CMV K-NpA adenoviral shuttle vector between the KpnI and NotI sites; after sequencing and amplification this plasmid was used to generate a recombinant adenovirus to permit widespread expression in our cells (ViraQuest Inc., North Liberty, IA). The resulting redox-sensitive protein has excitation maxima at 400 and 484 nm, with emission at 525 nm. In response to changes in redox conditions, RoGFP exhibits reciprocal changes in intensity at the two excitation maxima 12 (link), and its ratiometric characteristics render it insensitive to expression levels 13 (link)-15 (link). Although RoGFP’s fluorescence behavior is relatively independent of pH and it does not respond to authentic nitric oxide (NO), reduced NADH, or the antioxidant N-acetyl-L-cysteine (NAC), its spectrum is slightly affected by reduced glutathione (GSH) possibly due to thiol-disulfide exchange (Online Figures I and II).
RoGFP was expressed in the mitochondrial matrix (Mito-RoGFP) by appending a 48 bp region encoding the mitochondrial targeting sequence from cytochrome oxidase subunit IV, at the 5′ end of the coding sequence. This construct was then ligated into the VQ Ad5CMV K-NpA plasmid between the KpnI and NotI sites, and used to generate an adenoviral vector. RoGFP was targeted to the mitochondrial inter-membrane space (IMS-RoGFP) by appending it to glycerol phosphate dehydrogenase (GPD). A cDNA construct encoding GPD, an integral protein of the inner mitochondrial membrane whose C-terminus protrudes into the inter-membrane space 17 (link), was ligated in-frame with cDNA encoding RoGFP 17 (link). The corresponding polypeptide includes amino acids 1–626 of GPD, with RoGFP at the carboxy terminus. This method has been used previously to express YFP in the inter-membrane space 18 (link). (See Online Supplemental Material for characterization of the RoGFP sensors and experimental protocols).

Waypa G.B., Marks J.D., Guzy R., Mungai P.T., Schriewer J., Dokic D, & Schumacker P.T. (2009). HYPOXIA TRIGGERS SUBCELLULAR COMPARTMENTAL REDOX SIGNALING IN VASCULAR SMOOTH MUSCLE CELLS. Circulation research, 106(3), 526-535.

Publication 2009

Acetylcysteine Adenoviruses Adenovirus Vaccine Amino Acids Antioxidants Cells Cloning Vectors Cysteine Cytochrome-c Oxidase Subunit IV Disulfides DNA, Complementary Fluorescence glycerol-1-phosphate dehydrogenase Glycerol-3-Phosphate Dehydrogenase Integral Membrane Proteins Mammals Mitochondria Mitochondrial Membrane, Inner Mitochondrial Membranes Mitomycin Mutagenesis, Site-Directed Mutation NADH Open Reading Frames Oxidation-Reduction Oxide, Nitric Plasmids Polypeptides Proteins Reading Frames Reduced Glutathione Shuttle Vectors Sulfhydryl Compounds Tissue, Membrane

Most recents protocols related to «Adenovirus Vaccine»

Potentiation of Gluconeogenesis by LbNOX

Not available on PMC !

Example 6

As a result of its ability to elevate the intracellular ratio of NAD⁺ to NADH, LbNOX is also capable of potentiating gluconeogenesis in mammalian cells (e.g., human cells). The first step of gluconeogenesis from lactate is the conversion of lactate to pyruvate, which requires cytosolic NAD⁺. Gluconeogenesis from lactate was significantly increased when primary hepatocytes were transduced with either LbNOX or mitoLbNOX-containing adenovirus (FIG. 3D). The effect of LbNOX and mitoLbNOX on gluconeogenesis was commensurate to their effect on lactate/pyruvate ratio (FIG. 3B), suggesting that cytoplasmic and not mitochondrial NAD⁺/NADH is important for regulation of gluconeogenesis rate from lactate. These examples demonstrate the ability of water-forming NADH oxidases to control the rate of gluconeogenesis upon introducing these enzymes to mammalian cells.

US11866736B2. Protein prostheses for mitochondrial diseases or conditions (2024-01-09). The General Hospital Corporation [US]. Inventors: Vamsi Mootha [US], Denis Titov [US], Valentin Cracan [US], Zenon Grabarek [US].

Patent 2024

Adenovirus Vaccine Cells Cytoplasm Cytosol Enzymes Gluconeogenesis Hepatocyte Homo sapiens Lactates Mammals Mitochondria NADH Protoplasm Pyruvates Water-Splitting Enzyme of Photosynthesis

Comparison of AdY25 and AdCh68 Vaccine Vectors

Not available on PMC !

Example 7

Balb/c mice (6/group) were immunised with 108 infectious units of either of the following vectors, both expressing TIPeGFP:

- viii. ΔE1 ΔE3 AdCh68; or
- ix. ChAdOX1.

After 56 days post prime, mice were boosted with 106 pfu MVA-TIPeGFP. Serum was collected 50 days post-prime and 10 days post-boost to compare pre- and post-boost anti-GFP antibody responses. Responses were measured by endpoint ELISA. Statistical analyses were performed by one way ANOVA.

As shown in FIG. 7, humoral immunogenicity of the AdY25-based vector ChAdOX1 is superior to current chimpanzee adenovirus vector AdCh68, indicating an enhanced antibody response elicited by the AdY25-based vector in comparison to the AdCh68-based vector.

US11857640B2. Simian adenovirus and hybrid adenoviral vectors (2024-01-02). Oxford University Innovation Limited [GB]. Inventors: Matthew Douglas James Dicks [GB], Matthew Guy Cottingham [GB], Adrian Vivian Sinton Hill [GB], Sarah Gilbert [GB].

Patent 2024

Adenovirus Vaccine Antibodies, Anti-Idiotypic Antibody Formation Antigens Cloning Vectors Enzyme-Linked Immunosorbent Assay Infection Mice, Inbred BALB C Mus neuro-oncological ventral antigen 2, human Pan troglodytes Serum

Wound Healing Assay for HTR-8/SVneo and HUVECs

A total of 5 × 10⁵ HTR-8/SVneo cells or HUVECs administered vehicle or A2M-expressing adenovirus vectors over 48 h were seeded in 6-well plates and grown to reach confluent monolayers. Then, a 2-μl pipette tip was used to create the scratches. The images of migrated cells were recorded at 0–36 h. The percentage of wound closure was analyzed.

Wang J., Zhang P., Liu M., Huang Z., Yang X., Ding Y., Liu J., Cheng X., Xu S., He M., Zhang F., Wang G., Li R, & Yang X. (2023). Alpha-2-macroglobulin is involved in the occurrence of early-onset pre-eclampsia via its negative impact on uterine spiral artery remodeling and placental angiogenesis. BMC Medicine, 21, 90.

Publication 2023

Adenovirus Vaccine Cloning Vectors Wounds

Packaging of AAV8 Vectors for Gene Editing

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Publication 2023

Adenovirus Vaccine azo rubin S Biological Assay Cells CISH protein, human Cloning Vectors Culture Media Endotoxins Fingers Genome HEK293 Cells iodixanol Oligonucleotide Primers Plasmids Serum Transfection Ultracentrifugation Virus

Conditional Replicating Adenoviruses with Fc Fusions

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Publication 2023

Adenoviruses Adenovirus Vaccine A Fibers Anabolism Cytomegalovirus Deletion Mutation Genes Genome Peptides Service, Genetic Transgenes

Top products related to «Adenovirus Vaccine»

Lipofectamine 2000 by Thermo Fisher Scientific

Sourced in United States, China, Germany, United Kingdom, Canada, Japan, France, Italy, Switzerland, Australia, Spain, Belgium, Denmark, Singapore, India, Netherlands, Sweden, New Zealand, Portugal, Poland, Israel, Lithuania, Hong Kong, Argentina, Ireland, Austria, Czechia, Cameroon, Taiwan, Province of China, Morocco

Lipofectamine 2000 is a cationic lipid-based transfection reagent designed for efficient and reliable delivery of nucleic acids, such as plasmid DNA and small interfering RNA (siRNA), into a wide range of eukaryotic cell types. It facilitates the formation of complexes between the nucleic acid and the lipid components, which can then be introduced into cells to enable gene expression or gene silencing studies.

Fetal bovine serum (fbs) by Thermo Fisher Scientific

Sourced in United States, China, United Kingdom, Germany, Australia, Japan, Canada, Italy, France, Switzerland, New Zealand, Brazil, Belgium, India, Spain, Israel, Austria, Poland, Ireland, Sweden, Macao, Netherlands, Denmark, Cameroon, Singapore, Portugal, Argentina, Holy See (Vatican City State), Morocco, Uruguay, Mexico, Thailand, Sao Tome and Principe, Hungary, Panama, Hong Kong, Norway, United Arab Emirates, Czechia, Russian Federation, Chile, Moldova, Republic of, Gabon, Palestine, State of, Saudi Arabia, Senegal

Fetal Bovine Serum (FBS) is a cell culture supplement derived from the blood of bovine fetuses. FBS provides a source of proteins, growth factors, and other components that support the growth and maintenance of various cell types in in vitro cell culture applications.

Dulbecco modified eagle medium (dmem) by Thermo Fisher Scientific

Sourced in United States, China, United Kingdom, Germany, France, Australia, Canada, Japan, Italy, Switzerland, Belgium, Austria, Spain, Israel, New Zealand, Ireland, Denmark, India, Poland, Sweden, Argentina, Netherlands, Brazil, Macao, Singapore, Sao Tome and Principe, Cameroon, Hong Kong, Portugal, Morocco, Hungary, Finland, Puerto Rico, Holy See (Vatican City State), Gabon, Bulgaria, Norway, Jamaica

DMEM (Dulbecco's Modified Eagle's Medium) is a cell culture medium formulated to support the growth and maintenance of a variety of cell types, including mammalian cells. It provides essential nutrients, amino acids, vitamins, and other components necessary for cell proliferation and survival in an in vitro environment.

Lipofectamine 3000 by Thermo Fisher Scientific

Sourced in United States, China, Germany, Japan, United Kingdom, France, Canada, Italy, Australia, Switzerland, Denmark, Spain, Singapore, Belgium, Lithuania, Israel, Sweden, Austria, Moldova, Republic of, Greece, Azerbaijan, Finland

Lipofectamine 3000 is a transfection reagent used for the efficient delivery of nucleic acids, such as plasmid DNA, siRNA, and mRNA, into a variety of mammalian cell types. It facilitates the entry of these molecules into the cells, enabling their expression or silencing.

Adeno x rapid titer kit by Takara Bio

Sourced in United States, Japan, France

The Adeno-X Rapid Titer Kit is a laboratory tool designed to quantify the titer of adenoviral particles. It provides a rapid and simple method to determine the concentration of adenoviral stocks.

Penicillin streptomycin by Thermo Fisher Scientific

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Penicillin/streptomycin is a commonly used antibiotic solution for cell culture applications. It contains a combination of penicillin and streptomycin, which are broad-spectrum antibiotics that inhibit the growth of both Gram-positive and Gram-negative bacteria.

Virapower adenoviral expression system by Thermo Fisher Scientific

Sourced in United States

The ViraPower Adenoviral Expression System is a laboratory tool designed for the production of recombinant adenovirus. The system provides the necessary components, including plasmids and cell lines, to facilitate the generation of adenoviral particles for various research applications.

Lipofectamine rnaimax by Thermo Fisher Scientific

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Lipofectamine RNAiMAX is a transfection reagent designed for efficient delivery of small interfering RNA (siRNA) and short hairpin RNA (shRNA) into a wide range of cell types. It is a cationic lipid-based formulation that facilitates the uptake of these nucleic acids into the target cells.

Penicillin by Thermo Fisher Scientific

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Penicillin is a type of antibiotic used in laboratory settings. It is a broad-spectrum antimicrobial agent effective against a variety of bacteria. Penicillin functions by disrupting the bacterial cell wall, leading to cell death.

Streptomycin by Thermo Fisher Scientific

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Streptomycin is a broad-spectrum antibiotic used in laboratory settings. It functions as a protein synthesis inhibitor, targeting the 30S subunit of bacterial ribosomes, which plays a crucial role in the translation of genetic information into proteins. Streptomycin is commonly used in microbiological research and applications that require selective inhibition of bacterial growth.

What are the different types of Adenovirus Vaccines?

Adenovirus vaccines can be classified into several types based on the specific adenovirus strain used. These include vaccines derived from adenovirus serotypes 4, 5, 26, 35, and others. Each type may have unique characteristics, such as varying immunogenicity, safety profiles, and potential applications. Understanding the differences between these adenovirus vaccine types can help researchers select the most appropriate option for their specific research goals.

How can PubCompare.ai assist in Adenovirus Vaccine research?

PubCompare.ai allows researchers to streamline their Adenovirus vaccine research in several ways. The platform can help you screen protocol literature more efficiently by leveraging AI to pinpoint critical insights. This enables you to identify the most effective protocols related to Adenovirus Vaccine for your specific research goals. The platform's AI-driven analysis can highlight key differences in protocol effectiveness, helping you choose the best option for reproducibility and accuracy. By optimizing your research workflow, PubCompare.ai can save you time and resources while improving the overall quality of your Adenovirus vaccine development process.

What are some common usage challenges with Adenovirus Vaccines?

One of the key challenges with Adenovirus vaccines is the potential for pre-existing immunity in the target population. Many individuals may have been exposed to adenovirus serotypes used in the vaccines, which can reduce the vaccines' effectivenes. Additionally, there may be concerns about the safety profile of certain adenoviruse vaccine types, particularly in immunocompromised individuals. Researchers must carefully consider these factors when selecting and optimizing Adenovirus vaccine protocols for their studies.

How can Adenovirus Vaccines be applied in different settings?

Adenovirus vaccines have a wide range of potential applications, including: 1. Infectious disease prevention: Adenovirus vaccines have been developed for the prevention of diseases caused by adenoviruses, such as respiratory infections. 2. Oncolytic therapy: Some adenovirus-based vaccines are being investigated as potential oncolytic therapies, where the virus is used to selectively target and destroy cancer cells. 3. Gene delivery: The adenovirus vector can be used as a delivery mechanism for gene therapies, allowing for the introduction of therapeutic genes into target cells. 4. Veterinary use: Adenovirus vaccines have also been developed for use in veterinary medicine, such as for the prevention of diseases in livestock and companion animals.

More about "Adenovirus Vaccine"

Adenovirus vaccines are a crucial tool in the fight against infectious diseases, offering a promising approach to vaccine development.
These vaccines utilize adenovirus vectors as a delivery mechanism, providing a safe and effective way to introduce antigens into the body and stimulate an immune response.
Adenovirus vectors are derived from a group of DNA viruses that are commonly used in vaccine research due to their ability to efficiently transduce a wide range of cell types, including those in the respiratory and gastrointestinal tracts.
This makes them particularly well-suited for targeting infectious diseases that affect these areas, such as respiratory illnesses like COVID-19.
The development of adenovirus vaccines often involves the use of various cell culture media and reagents, such as Lipofectamine 2000, FBS, DMEM, and Lipofectamine 3000, which aid in the transfection and propagation of the adenovirus constructs.
Additionally, specialized kits like the Adeno-X Rapid Titer Kit can be used to quantify the viral titers, ensuring consistent and effective vaccine production.
Researchers and vaccine developers are leveraging the power of artificial intelligence (AI) to streamline the adenovirus vaccine development process.
Tools like PubCompare.ai allow for the efficient comparison of vaccine protocols from the literature, preprints, and patents, enabling the identification of the most effective adenovirus vaccine products and protocols through data-driven analysis.
By combining the strengths of adenovirus vectors, advanced cell culture techniques, and AI-powered data analysis, scientists are making strides in advancing adenovirus vaccine research and development.
This includes the exploration of novel adenovirus-based vaccine candidates, as well as the optimization of existing protocols to improve efficacy and safety.
With continued progress in this field, adenovirus vaccines hold great potential to contribute to the prevention and control of a wide range of infectious diseases.