AGENCY:
National Institutes of Health, Public Health Service, DHHS.
ACTION:
Notice.
SUMMARY:
The inventions listed below are owned by agencies of the U.S. Government and are available for licensing in the U.S. in accordance with 35 U.S.C. 207 to achieve expeditious commercialization of results of federally-funded research and development. Foreign patent applications are filed on selected inventions to extend market coverage for companies and may also be available for licensing.
ADDRESSES:
Licensing information and copies of the U.S. patent applications listed below may be obtained by writing to the indicated licensing contact at the Office of Technology Transfer, National Institutes of Health, 6011 Executive Boulevard, Suite 325, Rockville, Maryland 20852-3804; telephone: 301/496-7057; fax: 301/402-0220. A signed Confidential Disclosure Agreement will be required to receive copies of the patent applications.
Use of Cumulative Distribution Functions To Determine Protein Purity and Homogeneity
Alfred L. Yergey, Paul S. Blank, Christin M. Sjomeling (NICHD)
DHHS Reference No. E-163-00/0 filed 28 Apr 2000
Licensing Contact: Vasant Gandhi; 301/496-7056 ext. 224; e-mail:gandhiv@od.nih.gov
Successful solutions to numerous problems in the biochemical sciences depend on the ability to produce “pure” proteins and recognize the degree to which proteins might be modified. Current methods used for assessing purity are relatively nonspecific and insensitive to small differences in molecular weight. The inventors have developed a computer-implemented method and system for nonparametric statistical analysis of matrix-assisted laser desorption ionization (MALDI) protein spectra but is equally applicable to deconvoluted electrospray ionization (ESI) spectra. The invention facilitates assessing protein heterogeneity and detection of otherwise indistinguishable differences in the distribution of molecular weight. A principal advantage is that no additional instrumentation is required beyond that typically included in a mass spectrometry analysis system.
Hsp70-Like ATPase Peptide Binds Chap1/Dsk2
Frederic J. Kaye (NCI)
DHHS Reference No. E-282-99/0 filed 15 Sep 1999
Licensing Contact: Elaine White; 301/496-7056 ext. 282; e-mail: gesee@od.nih.gov
The current invention embodies the identification of a novel gene and protein, Chap1/Dsk2, a ubiquitin-linked protein which appears to play a vital role in regulating mitosis. Identified also is the conserved 20 amino acid region within the ATPase domain of the protein chaperone STCH, an Hsp70-like protein, which is the binding site for Chap1/Dsk2 and other ubiquitin-linked proteins.
Protein chaperones are essential for cell viability, regulating various cell cycle events including the biosynthesis, folding and unfolding, transport, multiunit assembly, and degradation of cell proteins. Overexpression of protein chaperones, such as STCH, can serve to suppress tumorigenesis and apoptosis. It therefore is believed that the peptide identified as the binding domain of STCH may have potential for use as a therapeutic agent against cancer or various infectious diseases, via modulation of tumorigenesis, apoptosis, or the multiunit assembly of viral particles such as HIV.
Polypeptides Comprising IL-6 Ligand Binding Receptor Domains and Related Nucleic Acids, Antibodies, Compositions and Methods
W. Carl Saxinger (NCI)
DHHS Reference No. E-061-99/0 filed 27 Aug 1999
Licensing Contact: Richard Rodriguez; 301/496-7056 ext. 287; e-mail: rodrigur@od.nih.gov
The biological activities of IL-6 include the stimulation of B and T cell growth and differentiation, production of acute-phase proteins by hepatocytes, multilineage hematopoiesis, osteoblast formation, maturation of megakaryocytes and platelet production. An abnormal expression of IL-6 may be involved in the pathogenesis of a variety of diseases, among which are multiple myeloma, rheumatoid arthritis, postmenopausal osteoporosis, chronic autoimmune diseases, Castleman's disease and AIDS. Methods of abrogating the effects of abnormal expression of IL-6 can be made at its site of production or at its target. The inventors of this technology have focused on the latter technique. Using a unique, newly patented, automated peptide array system, the inventors have studied specific sequences potentially involved in protein-protein interactions at the molecular level. This system was used to identify and isolate potential target peptide sequences within the IL-6 receptor molecule. Candidate peptide sequences were identified by direct binding to the IL-6 ligand by optimally displayed IL-6 receptor peptide segments in solid phase form. The specific binding properties of the peptide sequences were verified by using IL-6 heteroantisera, and the peptides have been shown to mitigate or reverse the effects of the above referenced properties of IL-6 in tissue culture.
Receptor-Mediated Uptake of an Extracellular Bcl-XL Fusion Protein Inhibits Apoptosis
Richard J. Youle, Xiuhuai Liu, JoAnn Castelli (NINDS)
DHHS Reference No. E-073-99/0 filed 16 Aug 1999
Licensing Contact: Richard Rodriguez; 301/496-7056 ext. 287; e-mail: rodrigur@od.nih.gov
The present invention relates to the field of apoptosis, in particular, it relates to apoptosis-modifying fusion proteins with at least two domains, one of which targets the fusion proteins to a target cell, and another of which modifies an apoptotic response of the target cell. For example, fusing various cell-binding domains to Bcl-XL and Bad allows targeting to specific subsets of cells in vivo, permitting treatment and/or prevention of cell-death related consequences of various diseases and injuries. This technology could be used to minimize or prevent apoptotic damage that can be caused by neurodegenerative disorders, e.g., Alzheimer's disease, Huntington's disease or spinal-muscular atrophy, stroke episodes or transient ischemic neuronal injury, e.g., spinal cord injuries. Additionally, apoptotic-enhancing fusion proteins of the current invention could be used to inhibit cell growth, e.g., uncontrolled cellular proliferation.
DNA Binding Protein and Sequence as Insulators Having Specific Enhancer Blocking Activity for Regulation of Gene Expression
Adam C. Bell, Adam G. West, Gary Felsenfeld (NIDDK)
DHHS Reference Nos. E-220-98/0 filed 30 Jun 1999 and E-220-98/1 filed 19 Apr 2000
Licensing Contact: Girish Barua; 301/496-7735 ext. 263; e-mail: gb18t@nih.gov
This patent application has two components. The first is the identification of a functional 50bp fragment of a previously known chicken chromatin insulator protein. The second component is the identification of the REBL (Required for Enhancer Blocking) CTCF protein (CCCTC-binding factor) which binds to the 50bp fragment. [The relationship between these two can be analogized as a receptor (50 bp fragment) and its ligand (the REBL CTCF protein).] These two elements can be used separately or together to regulate gene expression.
An insulator is a DNA sequence which is capable of acting as a barrier to neighboring cis-acting elements, preventing gene activation when juxtaposed between an enhancer and a promoter (i.e., when the insulator is placed between the enhancer and the promoter gene activation is blocked). An insulator will also act to protect a stably integrated reporter gene from position effects. This 50 bp fragment represents a functionally active domain of the chicken insulator protein which is both necessary and sufficient for enhancer blocking activity in human cells. The previously described chicken chromatin insulator is a 1.2 kb fragment which, where overall size of the vector to be delivered is a concern, for example, in gene therapy, may be too large for some applications. The identification of this active 50 bp fragment may therefore be a preferred alternative.
The identification of the REBL CTCF protein as an agent which binds to the 50 bp insulator fragment and whose binding activity is necessary for blocking of enhancer activity provides an additional element which may be used to more specifically control gene regulation. As most gene expression is dependent on the activity of multiple components the identification of a specific binding factor which functions as a blocking enhancer activity may permit more precise control of gene expression. The human REBL protein has regions which share homology with previously disclosed partial human cDNAs. It has a molecular weight of 135 kDa. A chicken homolog has also been identified. CTCF was originally identified as a repressor of the chicken c-myc gene.
Dated: August 29, 2000.
Jack Spiegel,
Director, Division of Technology Development and Transfer, Office of Technology Transfer, National Institutes of Health.
[FR Doc. 00-22880 Filed 9-6-00; 8:45 am]
BILLING CODE 4140-01-U