Chemistry: natural resins or derivatives; peptides or proteins; – Proteins – i.e. – more than 100 amino acid residues – Blood proteins or globulins – e.g. – proteoglycans – platelet...
Reexamination Certificate
1999-03-30
2004-05-11
Nolan, Patrick J. (Department: 1644)
Chemistry: natural resins or derivatives; peptides or proteins;
Proteins, i.e., more than 100 amino acid residues
Blood proteins or globulins, e.g., proteoglycans, platelet...
C530S387300, C530S388100
Reexamination Certificate
active
06734287
ABSTRACT:
FIELD OF THE INVENTION
This invention concerns peptides. More particularly, the invention concerns compositions for administration to dogs, which actively provide immunity to the dog's immunoglobulin E molecules.
BACKGROUND ART
It is estimated that up to 30% of all dogs suffer from allergies or allergy-related skin disorders. Specifically, allergic dermatitis has been estimated to affect between 3 and 15% of the entire canine population. Given the prevalence of allergies in dogs, there is a need to develop methods and compositions to properly diagnose and treat canine allergies.
The substances most likely to cause an allergic reaction vary from species to species. Common canine allergens include fleas, pollens, molds and dust. Allergy to fleas is believed to be the most common dog allergy. Typically, a flea's saliva is the allergen, and a single fleabite can cause substantial itching. An additional form of allergy in dogs is termed atopy. Atopy is a condition where a dog is allergic to inhalants such as pollens, molds or microscopic mites such as are found in house dust.
Antibody molecules play a role in allergic manifestations. In mammals, antibody molecules are classified into various isotypes referred to as IgA, IgD, IgE, IgG, and IgM. Antibody molecules consist of both heavy and light chain components. The heavy chains of molecules of a given isotype have extensive regions of amino acid sequence homology, and conversely have regions of difference from antibodies belonging to other isotypes. The shared regions of the heavy chains provide members of each isotype with common abilities to bind to certain cell surface receptors or to other macromolecules, such as complement. These heavy chain regions, therefore, serve to activate particular immune effector functions. Accordingly, separation of antibody molecules into isotypes serves to separate the antibodies according to a set of effector functions that they commonly activate.
In humans and dogs, immunoglobulin E (hereinafter IgE) is involved in allergy. Thus, IgE is the antibody type that is understood to be an important mediator of allergic responses, including Type I immediate hypersensitivity.
IgE molecules bind to mast cells and basophils. This binding occurs when the Fc region of the IgE molecule is bound to Fc receptors on the mast cells. When such bound IgE antibodies then bind to an allergen, the allergen cross-links multiple IgE antibodies on the cell surface. This cross-linking mediates Type I immediate hypersensitivity reactions and causes release of histamines and other molecules that produce symptoms associated with allergy.
Monoclonal antibodies having different degrees of sensitivity to canine IgE and IgG have been identified. (DeBoer, et al. Immunology and Immunopathology 37, 183-199 (1993).) DeBoer, et al. identified several monoclonal antibodies which had cross reactivity between IgG and IgE. (See, e.g., DeBoer, et al., Table 4 and accompanying text.) Three monoclonal antibodies (A5, D9, and B3) were identified by DeBoer et al., as having some affinity for canine IgE. Of the monoclonal antibodies identified in DeBoer et al., antibody D9 appeared to have the greatest degree of neutralization of Prausnitz-Kustner reactivity for atopic dog serum. In the context of canine allergy, DeBoer et al. proposed use of their monoclonal antibodies (MAbs) in the use of antigen-specific IgE ELISA, and for quantifying canine IgE. Additionally, they proposed use of their MAbs for immunostaining of Western Blot assays, to evaluate the molecular specificity of IgE antibodies, as well as for in vitro studies on degranulation of mast cells.
In humans the serum level of total IgE is diagnostic of allergic disease. To explore the possibility that the serum level of IgE might also be diagnostic of allergy in dogs, several studies were performed. (Hill and DeBoer Am. J. Yet. Res., (July 1994) 55(7), 944-48). Publications following the DeBoer article used a monoclonal antibody designated D9 in an ELISA assay having the following configuration: D9 was bound to a substrate, antibodies were captured by D9 and then D9 having a marker was used to flag the captured antibody. The Hill and DeBoer ELISA was used to establish the total amount of IgE in canine serum in an effort to diagnose canine allergy. In contrast to humans, the quantity of IgE determined to exist in canine circulation was of no use whatsoever in the diagnosis of allergy in dogs. (See, e.g., Abstract and Discussion Sections of Hill and DeBoer) This finding was in direct contrast to the situation in human immunology.
This divergent diagnostic result based on levels of IgE in humans compared to such levels in dogs, points out the difficulty of any attempt to correlate data between animals of two different genera. This difficulty is further exacerbated by the fact that dogs can be allergic to a different set of antigens than humans are. Fleas, for instance, are a severe problem for dogs, but not humans. Furthermore, in instances where dogs and humans appear to be allergic to the same allergen extract, studies by doctors Esch and Greer of Greer Laboratories, have indicated that the specific allergens in an allergen extract which produce canine disease are not necessarily the same allergens that produce disease in humans. For example, it is known that the immunodominant components of dust mite extracts are different in dogs than in humans.
The genomic sequences encoding human and murine IgE heavy chain constant region are known (For example, see Ishida et al., “The Nucleotide Sequence of the Mouse Immunoglobulin E Gene: Comparison with the Human Epsilon Gene Sequence”, EMBO Journal 1,1117-1123 (1982). A comparison of the human and murine genes shows that they possess 60% homology within exons, and 45-50% homology within introns, with various insertions and deletions.
Patel et al. published the nucleotide and predicted amino acid sequence for exons 1-4 of the heavy chain constant region of canine IgE in the article entitled “Sequence of the Dog Immunoglobulin Alpha and Epsilon Constant Region Genes,” Immunogenetics 41, 282-286 (Mar. 22, 1995). The complete sequence of the canine IgE heavy chain constant region, with membrane bound portions encoded by exons 5 and 6 are disclosed in copending applications Ser. No. 08/800,698 filed Feb. 14, 1997, Ser. No. 09/146,400 filed Sep. 3, 1998, and Ser. No. 09/146,617 filed Sep. 3, 1998.
Because IgE is believed to mediate allergic symptoms, it may be desirable to decrease IgE levels as a mechanism for alleviating allergic symptoms. However, a patient's own IgE molecules are self-proteins, and immune responses to such proteins are usually suppressed. The suppression of immune responses to self-proteins, i.e., tolerance to self-antigens, is hypothesized to occur in a number of ways.
The current hypothesis for suppression of T cells directed to self-antigens, involves an induction of “clonal deletions” of such T cells in the thymus, whereby T cell receptors which might recognize self-peptides in association with MHC molecules are eliminated, and only those which recognize foreign peptide and MHC molecules are allowed to expand. In addition, suppressor T cells may also exist which prevent the induction of immune responses to self-proteins.
In contrast to the situation with T cells, it is believed that there are many B cells which express receptors (i.e., surface immunoglobulin) for self-proteins, and that the reason these cells do not produce antibodies to self-proteins is because the T cells required for the antigen presentation to the B cell are normally missing.
A B cell which recognizes epitopes (antigen-binding sites) on a patient's own IgE antibodies is capable of generating antibodies, generally IgG, directed to this self-antigen, i.e., IgE. The existence of such B cells, therefore, presents a unique opportunity to induce the production of auto-antibody responses. There is an unmet need for such antibodies in order to treat allergic disease.
The hypothesis regarding “antigen presentation” involves: the recognition of a
Francoeur Greg
Lawton Robert
Mermer Brion
IDEXX Laboratories, Inc.
McDonnell & Boehnen Hulbert & Berghoff
Nolan Patrick J.
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