Abstract: Means and methods for treating tumors in a mammal, in particular, malignant solid tumors, using adenovirus derived material and interleukin-3 (“IL-3 ”). Tthe adenovirus derived material preferably encodes IL-3 activity. Such an adenovirus is preferably administered systemically to the mammal, optionally in an isolated perfusion setting. In preferred embodiments, IL-3 activity is combined with other cytotoxic activity.

Abstract: The problem of replication competent adenovirus in virus production is solved in that we have developed packaging cells that have no overlapping sequences with a new basic vector and thus are suited for safe large scale production of recombinant adenoviruses one of the additional problems associated with the use of recombinant adenovirus vectors is the host-defense reaction against treatment with adenovirus. Another aspect of the invention involves screening recombinant adenovirus vector lots, especially those intended for clinical use, for the presence of adenovirus E1 sequences, as this will reveal replication competent adenovirus, as well as revertant E1 adenoviruses. It is also an aspect of the present invention to molecularly characterize the revertants that are generated in the newer helper/vector combinations.

Abstract: Presented are ways to address the problem of replication competent adenovirus in adenoviral production for use with, for example, gene therapy. Packaging cells having no overlapping sequences with a selected vector are suited for large scale production of recombinant adenoviruses. A system for use with the invention produces replication defective adenovirus. The system includes a primary cell containing a nucleic acid based on or derived from adenovirus and an isolated recombinant nucleic acid molecule for transfer into the primary cell. The isolated recombinant nucleic acid molecule is based on or derived from an adenovirus, has at least one functional encapsidation signal and at least one functional Inverted Terminal Repeat, and lacks overlapping sequences with the nucleic acid of the cell. Otherwise, the overlapping sequences would enable homologous recombination leading to replication competent adenovirus in the primary cell into which the isolated recombinant nucleic acid molecule is to be transferred.

Abstract: Cells capable of at least, in part, complementing adenovirus E2A function of an adenovirus defective in E2A function. Such cells include a nucleic acid encoding adenovirus E2A or a functional part, derivative and/or analogue thereof, integrated into the cell's genome. The cell may have E2A nucleic acid derived from a temperature sensitive adenovirus. Methods for producing an adenovirus particle containing an adenovirus vector with a functional deletion of E2A are also disclosed. Such methods involve providing a cell with the functionally deleted adenovirus vector, culturing the cell, and harvesting viral particle. The functional deletion can comprise a deletion of nucleic acid encoding E2A. In such a method, the nucleic acid encoding adenovirus E2A in the cell's genome has no sequence overlap with the vector leading to replication competent adenovirus and/or to the formation of an adenovirus vector comprising E2A function.

Abstract: Presented are ways to address the problem of replication competent adenovirus in adenoviral production for use with, for example, gene therapy. Packaging cells having no overlapping sequences with a selected vector and are suited for large scale production of recombinant adenoviruses. A system for use with the invention produces adenovirus incapable of replicating. The system includes a primary cell containing a nucleic acid based on or derived from adenovirus and an isolated recombinant nucleic acid molecule for transfer into the primary cell. The isolated recombinant nucleic acid molecule is based on or derived from an adenovirus, and further has at least one functional encapsidating signal, and at least one functional Inverted Terminal Repeat. The isolated recombinant nucleic acid molecule lacks overlapping sequences with the nucleic acid of the cell.

Abstract: Improved methods and products based on adenoviral materials which can advantageously be used in, for instance, gene therapy. In one aspect, an adenoviral vector is provided which has no overlap with a suitable packaging cell line, the packaging cell line comprising another aspect of the invention. This combination excludes the possibility of homologous recombination, thereby excluding the possibility of the formation of replication competent adenovirus. In another aspect, an adenovirus based helper construct which by its size is incapable of being encapsulated is disclosed. This helper virus can be transferred into any suitable host cell making it a packaging cell. Additionally, a number of useful mutations to adenoviral based materials and combinations of such mutations are disclosed. Furthermore, a method of intracellular amplification is provided.

Abstract: The present invention relates to a gene delivery vehicle comprising a recombinant adenovirus having a tropism for a primary human chondrocyte. By efficiently transducing a nucleic acid of interest into a primary chondrocytes, the gene delivery vehicle is able to at least in part improve the counteraction of cartilage disease. In one embodiment the recombinant adenovirus comprises a deletion in the gene encoding for fiber protein, which is replaced by a nucleic acid sequence encoding at least part of a fiber protein of a B-type adenovirus.

Abstract: Presented are ways to address the problem of replication competent adenovirus in adenoviral production for use with, for example, gene therapy. Packaging cells having no overlapping sequences with a selected vector and are suited for large scale production of recombinant adenoviruses. A system for use with the invention produces adenovirus incapable of replicating. The system includes a primary cell containing a nucleic acid based on or derived from adenovirus and an isolated recombinant nucleic acid molecule for transfer into the primary cell. The isolated recombinant nucleic acid molecule is based on or derived from an adenovirus, and further has at least one functional encapsidating signal, and at least one functional Inverted Terminal Repeat. The isolated recombinant nucleic acid molecule lacks overlapping sequences with the nucleic acid of the cell.

Abstract: Novel adenovirus vectors and methods for their use are provided to determine the function of the product(s) of one or more sample nucleic acids. The sample nucleic acids are synthetic oligonucleotides, DNA, or cDNA and encode polypeptides, antisense nucleic acids or GSEs. The sample nucleic acids are expressed in a host by recombinant adenovirus vectors to alter at least one phenotype of the host. The altered phenotype(s) is identified as a means to assign a biological function to the product(s) encoded by the sample nucleic acid(s).

Abstract: Cells capable of at least, in part, complementing adenovirus E2A function of an adenovirus defective in E2A function. Such cells include a nucleic acid encoding adenovirus E2A or a functional part, derivative and/or analogue thereof, integrated into the genome of the cell. Preferably, the cell has E2A nucleic acid derived from a temperature sensitive adenovirus such as adenovirus ts125. Methods for producing an adenovirus particle containing an adenovirus vector with a finctional deletion of E2A are also disclosed. Such a method involves providing a cell as previously described with the functionally deleted adenovirus vector, culturing the cell, and harvesting the virus particle. The functional deletion can comprise a deletion of at least part of the nucleic acid encoding E2A.

Abstract: Novel means and methods for their use are provided to determine the function of the product(s) of one or more sample nucleic acids. The sample nucleic acids are synthetic oligonucleotides, DNA, or cDNA and encode polypeptides, antisense nucleic acids, or GSEs. The sample nucleic acids are expressed in a host by a vehicle to alter at least one phenotype of the host. The altered phenotype(s) is/are identified as a means to assign a biological function to the product(s) encoded by the sample nucleic acid(s).

Abstract: Presented are ways to address the problem of replication competent adenovirus in adenoviral production for use with, for example, gene therapy. Packaging cells having no overlapping sequences with a selected vector and are suited for large scale production of recombinant adenoviruses. A method of the invention produces adenovirus incapable of replicating. The method includes a primary cell containing a nucleic acid based on or derived from adenovirus and an isolated recombinant nucleic acid molecule for transfer into the primary cell. The isolated recombinant nucleic acid molecule is based on or derived from an adenovirus, and further has at least one functional encapsidating signal, and at least one functional Inverted Terminal Repeat. The isolated recombinant nucleic acid molecule lacks overlapping sequences with the nucleic acid of the cell.

Abstract: Water soluble polymers or polymeric hydrogels are used to encapsulate antigen to form vaccines. The antigen is mixed with a polymer solution, microparticles are formed of the polymer and antigen, and, optionally, the polymer is crosslinked to form a stable microparticle. Preferred polymers are alginate and polyphospazenes, and mixtures thereof. Microparticles can be administered parenterally or mucosally. For oral delivery, the microparticles are preferably fifteen microns or less in diameter, and adhere to the mucosal lining of the gastointestinal tract, increasing uptake by the reticuloendothelium.

Abstract: The problem of replication competent adenovirus in virus production is solved in that we have developed packaging cells that have no overlapping sequences with a new basic vector and, thus, are suited for safe large scale production of recombinant adenoviruses. One of the additional problems associated with the use of recombinant adenovirus vectors is the host-defense reaction against treatment with adenovirus. Another aspect of the invention involves screening recombinant adenovirus vector lots, especially those intended for clinical use, for the presence of adenovirus E1 sequences, as this will reveal replication competent adenovirus, as well as revertant E1 adenoviruses. It is also an aspect of the present invention to molecularly characterize the revertants that are generated in the newer helper/vector combinations.

Abstract: A method for intracellular amplification of DNA is disclosed. The method includes providing a mammalian cell with a first nucleic acid sequence encoding functional adenoviral E2A and E2B gene products and with a second nucleic acid sequence encoding a linear DNA fragment to be amplified. The second nucleic acid sequence further has at least one functional adenoviral Inverted Terminal Repeat on a terminus and, in one embodiment where there is only a single ITR, a hairpin-like structure on the other terminus. This allows the linear DNA fragment to be acted upon by the adenoviral E2A and E2B gene products, thus intracellularly amplifying the linear DNA fragment, which can be extracted.

Abstract: Adenoviral vectors with a deletion of the E3 region such that the remaining E3 region reduces the TNF response of a host mammalian cell infected with the virus. The portion of the E3 region remaining in these vectors encodes the 14.7 kD protein, and may also contain a deletion of at least the E1a promoter. These partially deleted E3 vectors will inhibit the host cell's immune response so that the infected cell will live longer. Any non-adenoviral gene expressed from these vectors in the infected cell will be produced for a longer length of time and achieve a higher concentration than when adenoviral vectors not expressing function 14.7 kD protein are used. These 14.7 kD expressing adenoviral vectors will be useful for gene therapy and especially in cancer gene therapy where the non-adenoviral DNA sequence being expressed are preferably cytokine genes, such as IL-1, and suicide genes, such as HSV-tk. The vectors also are useful for antisense therapy.

Abstract: The invention provides improved methods and products based on adenoviral materials which can advantageously be used in for instance gene therapy. In one aspect an adenoviral vector is provided which has no overlap with a suitable packaging cell line which is another aspect of invention. This combination excludes the possibility of homologous recombination, thereby excluding the possibility of the formation of replication competent adenovirus. In another aspect an adenovirus based helper construct which by its size is incapable of being encapsidated. This helper virus can be transferred into any suitable host cell making it a packaging cell. Further a number of useful mutations to adenoviral based materials and combinations of such mutations are disclosed, which all have in common the safety of the methods and the products, in particular avoiding the production of replication competent adenovirus and/or interference with the immune system. Further a method of intracellular amplification is provided.

Abstract: Presented are ways to address the problem of replication competent adenovirus in adenoviral production for use with, for example, gene therapy. Packaging cells having no overlapping sequences with a selected vector and are suited for large scale production of recombinant adenoviruses. A system for use with the invention produces adenovirus incapable of replicating. The system includes a primary cell containing a nucleic acid based on or derived from adenovirus and an isolated recombinant nucleic acid molecule for transfer into the primary cell. The isolated recombinant nucleic acid molecule is based on or derived from an adenovirus, and further has at least one functional encapsidating signal, and at least one functional Inverted Terminal Repeat. The isolated recombinant nucleic acid molecule lacks overlapping sequences with the nucleic acid of the cell.

Abstract: The present invention to a synthetic transfection system comprising as a carrier a cationic, water dispersible polyphosphazene. In addition, it relates to a method for introducing DNA fragments in target cells, comprising contacting these DNA fragments with a polyphosphazene which is at least partially substituted with cationic substituents and subsequently contacting the obtained transfection system with target cells. Finally, the invention involves the use of a polyphosphazene which is at least partially substituted with cationic substituents as a transfection vehicle.