Abstract: Embodiments of the present invention are directed to non-naturally occurring cells and methods for screening compositions and genes which interact with interleukin 1 beta and interleukin-1 beta converting enzyme (ICE) processing, methods and non-naturally occurring cells for making ICE, and agonists and inhibitors of ICE.
Abstract: Sustained delivery formulations comprising a water-insoluble complex of a peptidic compound (e.g., a peptide, polypeptide, protein, peptidomimetic or the like) and a carrier macromolecule are disclosed. The formulations of the invention allow for loading of high concentrations of peptidic compound in a small volume and for delivery of a pharmaceutically active peptidic compound for prolonged periods, e.g., one month, after administration of the complex. The complexes of the invention can be milled or crushed to a fine powder. In powdered form, the complexes form stable aqueous suspensions and dispersions, suitable for injection. In a preferred embodiment, the peptidic compound of the complex is an LHRH analogue, preferably an LHRH antagonist, and the carrier macromolecule is an anionic polymer, preferably carboxymethylcellulose. Methods of making the complexes of the invention, and methods of using LHRH-analogue-containing complexes to treat conditions treatable with an LHRH analogue, are also disclosed.
Type:
Grant
Filed:
December 11, 1997
Date of Patent:
January 30, 2001
Assignee:
Praecis Pharmaceuticals, Inc.
Inventors:
Malcolm L. Gefter, Nicholas Barker, Gary Musso, Christopher J. Molineaux
Abstract: Methods for treating prostate cancer are disclosed. The methods of the invention generally feature administration to a subject of an LHRH-R antagonist, in combination with a second therapy. In one embodiment, this second therapy is performance of a procedure that removes or destroys prostatic tumor tissue, such as a radical prostatectomy, cryosurgery or X-ray therapy (external or interstitial). In another embodiment, the second therapy is treatment with an LHRH-R agonist, either simultaneous with or subsequent to LHRH-R antagonist therapy. The methods of the invention can further involve administering an antiandrogen and/or an inhibitor of sex steroid biosynthesis to the subject in combination with the LHRH-R antagonist.
Type:
Grant
Filed:
November 11, 1999
Date of Patent:
January 30, 2001
Assignee:
Praecis Pharmaceuticals, Inc.
Inventors:
Marc B. Garnick, Christopher J. Molineaux, Malcolm L. Gefter
Abstract: Disclosed is a transformed yeast cell containing a first heterologous DNA sequence which codes for a mammalian G protein coupled receptor and a second heterologous DNA sequence which codes for a mammalian G protein &agr; subunit (mammalian G&agr;). The first and second heterologous DNA sequences are capable of expression in the cell, but the cell is incapable of expressing an endogenous G protein &agr;-subunit (yeast G&agr;) The cells are useful for screening compounds which affect the rate of dissociation of G&agr; from G&bgr;&ggr; in a cell. Also disclosed is a novel DNA expression vector useful for making cells as described above. The vector contains a first segment comprising at least a fragment of the extreme amino-terminal coding sequence of a yeast G protein coupled receptor. A second segment is positioned downstream from the first segment (and in correct reading frame therewith), with the second segment comprising a DNA sequence encoding a heterologous G protein coupled receptor.
Type:
Grant
Filed:
April 8, 1998
Date of Patent:
January 2, 2001
Assignee:
Duke University
Inventors:
Klim King, Henrik G. Dohlman, Marc G. Caron, Robert J. Lefkowitz
Abstract: Methods of regulating gene expression in subjects using tetracycline-responsive fusion proteins are disclosed. In one embodiment, the method involves introducing into a cell the subject a nucleic acid molecule encoding a fusion protein which inhibits transcription, the fusion protein comprising a first polypeptide which binds to a tet operator sequence, operatively linked to a heterologous second polypeptide which inhibits transcription in eukaryotic cells; and modulating the concentration of a tetracycline, or analogue thereof, in the subject. The first polypeptide can binds to a tet operator sequence in the absence, but not the presence, of tetracycline. Alternatively, the first polypeptide can binds to a tet operator sequence in the presence, but not the absence, of tetracycline.
Abstract: A novel protein associated with multidrug resistance in living cells and capable of conferring multidrug resistance on a cell is disclosed. Nucleic acids encoding the novel multidrug resistance protein are also disclosed. Transformant cell lines which express the nucleic acid encoding the novel protein are also disclosed. Antibodies which bind the novel multidrug resistance protein are also disclosed. Diagnostic and treatment methods using the novel proteins, nucleic acids, antibodies and cell lines of the invention are also encompassed by the invention.
Abstract: A Plasmodium falciparum gene encoding immunogenic SERA protein has been isolated by a) systematically screening a lambda gt11 recombinant DNA expression library with a murine monoclonal antibody directed against protein antigens of this pathogen, and b) systematically screening a lambda gt11 genomic cDNA and oligonucleotide probes directed against this pathogen. A 111 kDa protein has been shown to have immunogenic activity against parasite inhibitory antibodies. The gene encoding this protein, including the signal sequence and regulatory sequence in the adjacent 5' flanking sequence has been isolated and sequenced.Isolation and characterization of genes encoding major protein antigens of P. falciparum make it possible to develop reagents useful in the diagnosis, prevention and treatment of malaria. In addition, the signal sequences or regulatory sequences of this gene can be used to stimulate the production of other useful genetic products.
Abstract: A novel protein associated with multidrug resistance in living cells and capable of conferring multidrug resistance on a cell is disclosed. Nucleic acids encoding the novel multidrug resistance protein are also disclosed. Transformant cell lines which express the nucleic acid encoding the novel protein are also disclosed. Antibodies which bind the novel multidrug resistance protein are also disclosed. Diagnostic and treatment methods using the novel proteins, nucleic acids, antibodies and cell lines of the invention are also encompassed by the invention.
Abstract: A novel protein associated with multidrug resistance in living cells and capable of conferring multidrug resistance on a cell is disclosed. Nucleic acids encoding the novel multidrug resistance protein are also disclosed. Transformant cell lines which express the nucleic acid encoding the novel protein are also disclosed. Antibodies which bind the novel multidrug resistance protein are also disclosed. Diagnostic and treatment methods using the novel proteins, nucleic acids, antibodies and cell lines of the invention are also encompassed by the invention.
Abstract: The present invention pertains to a line of human blood cells which have high levels of oxidative activity (such as oxygenase, oxidase, peroxidase, and hydroxylase activity). Such cells grow in suspension culture, and are useful to determine the mutagenicity of xenobiotic substances that are metabolized into toxic or mutagenic substances. The invention also includes mutation assays using these cells, and other cells with similar characteristics.
Abstract: A novel protein associated with multidrug resistance in living cells and capable of conferring multidrug resistance on a cell is disclosed. Nucleic acids encoding the novel multidrug resistance protein are also disclosed. Transformant cell lines which express the nucleic acid encoding the novel protein are also disclosed. Antibodies which bind the novel multidrug resistance protein are also disclosed. Diagnostic and treatment methods using the novel proteins, nucleic acids, antibodies and cell lines of the invention are also encompassed by the invention.
Abstract: A novel protein associated with multidrug resistance in living cells and capable of conferring multidrug resistance on a cell is disclosed. Nucleic acids encoding the novel multidrug resistance protein are also disclosed. Transformant cell lines which express the nucleic acid encoding the novel protein are also disclosed. Antibodies which bind the novel multidrug resistance protein are also disclosed. Diagnostic and treatment methods using the novel proteins, nucleic acids, antibodies and cell lines of the invention are also encompassed by the invention.
Abstract: In vivo and in vitro methods of increasing amyloid deposition using amyloid-enhancing compounds are described. Methods of forming amyloid fibrils and screening for agents useful in treating amyloidosis are also described. Animals having non-naturally occurring amyloid deposits produced using the amyloid-enhancing compounds even further are described.
Type:
Grant
Filed:
June 6, 1995
Date of Patent:
January 12, 1999
Assignees:
Neurochem, Inc., Queen's University at Kingston
Inventors:
Robert Kisilevsky, Walter Szarek, Donald Weaver, Paul Fraser, Xianqi Kong
Abstract: Sulfonated multiblock copolymers, and uses thereof, are disclosed. The sulfonated copolymers are useful for providing non-thrombogenic coatings, e.g., for medical devices, and for promoting cell growth, differentiation, or production of normal cell products. The sulfonated copolymers are also useful for administration of therapeutic agents.
Type:
Grant
Filed:
June 10, 1996
Date of Patent:
November 24, 1998
Assignee:
Aegis Biosciences L.L.C.
Inventors:
Laurence Berlowitz-Tarrant, Timothy N. Tangredi, Gary E. Wnek, Robert J. Nicolosi
Abstract: A gene encoding a leukocyte-derived growth factor (LDGF) has been isolated, cloned and sequenced. LDGF is believed to correspond to a PDGF-like monocyte-derived growth factor with chemotactic activity which is found in human wound fluid. Protease-resistant and other analogues of LDGF, as well as recombinant LDGF of native amino acid sequence, may now be produced by gene expression in transformed hosts.
Abstract: A novel protein associated with multidrug resistance in living cells and capable of conferring multidrug resistance on a cell is disclosed. Nucleic acids encoding the novel multidrug resistance protein are also disclosed. Transformant cell lines which express the nucleic acid encoding the novel protein are also disclosed. Antibodies which bind the novel multidrug resistance protein are also disclosed. Diagnostic and treatment methods using the novel proteins, nucleic acids, antibodies and cell lines of the invention are also encompassed by the invention.
Abstract: Antibodies that bind soluble IgE but not IgE on the surface of B lymphocytes or basophils are described. The antibodies do not induce histamine release by basophils or mast cells.
Abstract: Chimeric antibodies which bind to unique antigenic epitopes of IgE (designated ige.b1) which are present on IgE-bearing B lymphocytes but not basophils are described.
Abstract: Anti-idiotypic monoclonal antibodies that recognize the paratope of monoclonal antibodies specific for unique antigenic epitopes of IgE (designated ige.bl) which are present on membrane-bound IgE-expressed by bearing B cells but not on IgE bound to Fc.epsilon.R on basophils are described.
Type:
Grant
Filed:
May 26, 1989
Date of Patent:
May 30, 1995
Assignee:
Tanox Biosystems, Inc.
Inventors:
Tse-wen Chang, Bill N. Sun, Cecily R. Sun