[Federal Register: December 9, 2003 (Volume 68, Number 236)]
[Notices]
[Page 68637-68638]
From the Federal Register Online via GPO Access [wais.access.gpo.gov]
[DOCID:fr09de03-92]
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DEPARTMENT OF HEALTH AND HUMAN SERVICES
National Institutes of Health
Government-Owned Inventions; Availability for Licensing
AGENCY: National Institutes of Health, Public Health Service, DHHS.
ACTION: Notice.
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SUMMARY: The inventions listed below are owned by an agency 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.
A Mouse Model for Systemic Inflammation in Glucocerebrosidase-Deficient
Mice With Minimal Glucosylceramide Storage
Richard L. Proia (NIDDK). DHHS Reference No. E-256-2003/0--Research
Tool. Licensing Contact: Susan Carson; (301) 435-5020; carsonsu@mail.nih.gov.
Gaucher disease, the most common lysosomal storage disease, is an
inherited metabolic disorder in which harmful quantities of the lipid
glucocerebroside accumulate in the spleen, liver, lungs, bone marrow
and in rare cases in the brain, due to a deficiency of the enzyme
glucocerebrosidase (Gba) that catalyses the first step in the
biodegradation of glucocerebrosides. Type 1 Gaucher disease is the most
common and is distinguished from the other forms of the disease, types
2 and 3, by the lack of neurologic involvement. The clinical features
of Type 1 are heterogeneous, vary broadly in clinical severity and
affect many organ systems. The major disease manifestations include
enlarged spleen and liver, bone lesions, hematologic abnormalities and
lung involvement. The disease has also been associated with a sustained
inflammatory reaction. Gaucher disease is most prevalent in the
Ashkenazi Jewish population with an incidence of approximately 1 in 450
persons while in the general public the incidence is 1 in 100,000.
There are an estimated 30,000 Gaucher disease patients world-wide with
approximately 3000 patients currently receiving enzyme replacement
therapy which has been shown to be highly effective in treatment of the
disease. The cost of therapy is approximately $100,000-$300,000
annually and is a life-long treatment, which makes the case for
affordable new therapies urgent.
The etiology of the disease has been difficult to study due to the
absence of viable mouse models for the disease, as a complete
disruption of the glucocerebrosidase (Gba) gene results in rapid
neonatal death. In an attempt to produce a viable model scientists at
the NIDDK introduced a human Gaucher disease point mutation, L444P,
into the mouse Gba gene in order to cause a partial enzyme deficiency
(J. Clin. Invest (2002) 109, 1215-1221; Proc. Natl. Acad. Sci. USA
(1998) 95, 2503-2508).
The mice exhibit a partial glucocerebrosidase deficiency (15-20% of
normal activity), without bulk accumulation of glucosylceramide or the
presence of Gaucher cells. The mice demonstrate other clinical features
of Gaucher disease, including multisystem inflammation, B cell
hyperproliferation, skin abnormalities, anemia and lymphadenopathy.
These mice provide a useful model for studying certain aspects of
Gaucher disease pathology and in evaluating new therapeutic treatments.
Tec Kinase Deficient Mice
Pamela L. Schwartzberg (NHGRI), Michael J. Lenardo (NIAID), Harold
Varmus (EM), Dan Littman (EM).
DHHS Reference No. E-178-2003/0 and DHHS Reference No. E-178-2003/1--
Research Tools.Licensing Contact: Susan Carson; (301) 435-5020; carsonsu@mail.nih.gov.
Stimulation of T lymphocytes through the T Cell Receptor (TCR)
elicits broad responses required for proper immune function, including
cell proliferation, cytokine production and apoptosis. Activation of
distinct families of tyrosine kinases (Zap-70, Src) are important in
TCR signalling, while the role of other tyrosine kinases, such as the
Tec Kinases Rlk and Itk is less clear. However, evidence suggests that
these kinases play a role in CD4+ T helper (Th) cell differentiation.
Responses to infection are regulated in part by two distinct types of T
helper cells, type 1 (Th1) and Th2 subclasses which produce different
cytokines and have discrete effector functions. Th1 cells produce
interferon-gamma (IFN-gamma), which is a key mediator of cellular
immunity. In contrast Th2 cells produce interleukin 4 (IL-4), Il-5, Il-
10, and Il-13 which assist humoral immunity and dominate immune
responses to both helminths and allergens. Regulation of these
subclasses is important not only for normal immune response, but also
for abnormal disease processes, including autoimmunity and
hypersensitivity. Generation of type 1 and type 2 Th cells is
influenced by multiple factors including cytokines, costimulation and
TCR-based signals. Understanding the mechanisms and signals important
in T cell signalling is important for identifying new therapeutics that
target Th1 and Th2-mediated pathologies (for example autoimmune
disorders and asthma, respectively).
The Tec family of tyrosine kinases have been implicated as
important mediators of polarized cytokine production and Th2 cell
differentiation. Rlk is preferentially expressed in Th1 cells and Itk
is important in Th2 response. Numerous studies have implicated
alterations in the strength of TCR-mediated signals as playing
important roles in Th cell differentiation. Researchers at the NIH have
developed transgenic mouse models in order to address these issues.
Rlk-deficient mice and Rlk/Itk double-deficient mice were generated and
have been shown to have defects in TCR responses including
proliferation, cytokine production and apoptosis in vitro and adaptive
immune response to infectious agents in vivo (Science (1999) 284, 638-
641; Nature Immunol (2001) 2: 1183-188). Molecular analyses of cells
from these mice indicate that these kinases are critical for proper
regulation of phospholipase C, calcium mobilisation and ERK activation
as well as activation of downstream transcription factors in response
to T cell receptor stimulation. Defects are minor in Rlk-deficient
animals and most severe in Rlk/Itk double-deficient mice.
[[Page 68638]]
These mice provide a useful mechanistic model for dissecting out the
complex interactions of TCR signalling. Additionally, the mice are
useful for evaluation of therapeutics directed at specific classes of
diseases (Th1 or Th2) and the utility of potential global Tec kinase
inhibitors.
A Mouse Model for Type 2 Diabetes
Derek LeRoith and Ana M. Fernandez (NIDDK).
DHHS Reference No. E-132-2003/0--Research Tool.Licensing Contact: Pradeep Ghosh; (301) 435-5282; ghoshpr@mail.nih.gov.
Diabetes affects over 120 million people worldwide (16 million in
the US) and is a major health problem with associated health costs
estimated at almost $100 billion dollars. Type 2 diabetes affects as
many as 10% of the population of the Western World (with 15 million
patients in the U.S. alone) and arises from a heterogeneous etiology,
with secondary effects from environmental influences. Risk factors for
type 2 diabetes include obesity, high blood pressure, high
triglycerides and age. Type 2 diabetes is an active area for drug
development and there continues to be a need for novel animal models
and research tools to aid in the discovery and development of new, more
efficient and cost-effective therapeutics.
Peripheral insulin resistance and impaired insulin action are the
primary characteristics of type 2 diabetes. The first observable defect
in this major disorder occurs in muscle, where glucose disposal in
response to insulin is impaired. In an effort to study the progression
of diabetes, researchers at NIDDK have developed a transgenic mouse
strain (MKR) with a dominant-negative insulin-like growth factor-I
receptor (KR-IGF-IR) specifically targeted to skeletal muscle (Genes &
Development (2001) 15, 1926-1934). Expression of KR-IGF-IR resulted in
the formation of hybrid receptors between the mutant and the endogenous
IGF-I and insulin receptors, thereby abrogating the normal function of
these receptors and leading to insulin resistance. Pancreatic [beta]-
cell dysfunction developed at a relative early age, resulting in
diabetes.
One of the great advantages of the MKR mouse over other mouse
models is the early onset of the disease phenotype as seen by insulin
resistance (as early as 4 weeks), fasting hyperglycemia (from 5 weeks)
and abnormal glucose tolerance (at 7-12 weeks). The MKR mice provide an
extremely useful model for the study of type 2 diabetes, its
pathogenesis and potential new therapies.
A Tet-Regulated Mouse Model for Cataract
Robert W. Sobol, Samuel H. Wilson (NIEHS). DHHS Reference No. E-316-
2002/0--Research Tool. Licensing Contact: Susan Carson; (301) 435-5020; carsonsu@mail.nih.gov.
Cataract is the most common cause of blindness worldwide, with an
estimated 25 million blind and 119 million visually impaired
individuals worldwide. Over 20 million adults in the U.S. alone are
currently diagnosed with cataracts making this disease a major health
concern. The incidence of cataract increases with age and a number of
etiologic factors have been proposed in the pathogenesis of age-related
cataract in humans including genetic factors, environmental factors and
metabolic and biochemical changes in the crystalline lens. Ultraviolet
radiation exposure and oxidative injury to the lens has been considered
by some to be one of the most important factors in cataractogenesis.
The present therapy of choice for cataract is laser surgery.
Experimental investigation of human age-related cataract is
hindered by a lack of available animal models of cataract. Several
laboratory mice strains with heritable cataracts have been studied
including the Nakona, Frasier and the Philly mouse strains. An animal
model with a predictable phenotype of cataract, particularly one with a
pathogenesis relating to oxidative injury to the lens (the proposed
central factor in human-related cataract) would be of great value to
ophthalmic researchers and in the development of pharmacological agents
for delaying or preventing cataract.
Researchers at the NIEHS have developed a transgenic mouse model in
which the DNA repair gene DNA polymerase [beta] ([beta]-pol) is highly
over-expressed in the lens epithelial cells of the eye (DNA Repair
(2003) 609-622). A bicistronic tetracycline-responsive transgenic
system was used to over-express [beta]-pol in mice. Over-expression of
[beta]-pol in the lens epithelium results in the early onset of severe
cortical cataract with cataractogenesis beginning within 4 days after
birth. In utero and post-natal suppression of transgenic Flag-[beta]-
pol-expression by doxycycline administration completely prevents
cataract formation through adulthood, yet cataract is subsequently
observed following removal of doxycycline and re-expression of the
transgene. This predictable and regulated onset of cataract makes this
mouse an ideal animal model both for evaluating new therapeutics for
delaying or preventing cataract as well as for understanding the
mechanisms responsible for cataract formation.
A Mouse Model for Human Osteoarthritis
Laurent G. Ameye (NIDCR), Marian F. Young (NIDCR), Ake Oldberg
(EM), Tianshun Xu (NIDCR). DHHS Reference No. E-081-2002/0--Research
Tool. Licensing Contact: Susan Carson; (301) 435-5020; carsonsu@mail.nih.gov.
Osteoarthritis (OA) is the most common form of arthritis and
affects more than 20 million Americans, costing billions of dollars in
health care annually. Osteoarthritis is caused by the breakdown of
joint cartilage, leading to a loss of the cartilage ``cushion'' between
the bones of the joints. Risk factors associated with OA include age,
obesity, traumatic injury and overuse due to sports or occupational
stresses. There is no cure for OA and current treatments are directed
at the symptomatic relief of pain, and at improving and maintaining
joint function. There remains, however, a critical need both to develop
OA treatments that focus on slowing down the degenerative process of
the disease and for validated animal models to test these new
treatments. NIH scientists at the NIDCR have generated a mouse model
for osteoarthritis (FASEB J. (2002) 16, 673-680) that fills one part of
this important gap.
The mouse model is a double knockout mouse that lacks biglycan and
fibromodulin, two members of the small leucine-rich proteoglycan
family, and that spontaneously develops OA. All the hallmarks of human
osteoarthritis are present, including: progressive degeneration of the
articular cartilage from early fibrillation to complete erosion,
subchondral sclerosis, an absence of inflammation and development of
osteophytes and cysts. Advantages over the existing models for
osteoarthritis include: high phenotypic penetrance, early onset (at 1-2
months) and a rapid disease progression (between 3-6 months) which can
be accelerated by moderate levels of exercise, such as treadmill
running. These properties, combined with a normal life span, make the
biglycan/fibromodulin-deficient mouse an ideal animal model for
evaluating new drugs and treatments for osteoarthritis.
Dated: December 1, 2003.
Steven M. Ferguson,
Director, Division of Technology Development and Transfer, Office of
Technology Transfer, National Institutes of Health.
[FR Doc. 03-30496 Filed 12-8-03; 8:45 am]
BILLING CODE 4140-01-P