Your search keyword '"Clare-Salzler M"' showing total 6 results

1. Modulating autoimmune responses to GAD inhibits disease progression and prolongs islet graft survival in diabetes-prone mice.

Author

Tian J, Clare-Salzler M, Herschenfeld A, Middleton B, Newman D, Mueller R, Arita S, Evans C, Atkinson MA, Mullen Y, Sarvetnick N, Tobin AJ, Lehmann PV, and Kaufman DL

Subjects

Adoptive Transfer, Animals, Autoantibodies blood, Diabetes Mellitus, Type 1 immunology, Diabetes Mellitus, Type 1 surgery, Disease Progression, Female, Interferon-gamma metabolism, Interleukin-4 metabolism, Interleukin-5 metabolism, Lymphocyte Activation, Mice, Mice, Inbred NOD, Pancreatin immunology, Self Tolerance, Spleen immunology, Th1 Cells immunology, Autoantigens therapeutic use, Diabetes Mellitus, Type 1 prevention & control, Glutamate Decarboxylase therapeutic use, Graft Survival drug effects, Islets of Langerhans Transplantation, Th2 Cells immunology

Abstract

In nonobese diabetic (NOD) mice, beta-cell reactive T-helper type 1 (Th1) responses develop spontaneously and gradually spread, creating a cascade of responses that ultimately destroys the beta-cells. The diversity of the autoreactive T-cell repertoire creates a major obstacle to the development of therapeutics. We show that even in the presence of established Th1 responses, it is possible to induce autoantigen-specific anti-inflammatory Th2 responses. Immune deviation of T-cell responses to the beta-cell autoantigen glutamate decarboxylase (GAD65), induced an active form of self-tolerance that was associated with an inhibition of disease progression in prediabetic mice and prolonged survival of syngeneic islet grafts in diabetic NOD mice. Thus, modulation of autoantigen-specific Th1/Th2 balances may provide a minimally invasive means of downregulating established pathogenic autoimmune responses.

Published

1996

2. Nasal administration of glutamate decarboxylase (GAD65) peptides induces Th2 responses and prevents murine insulin-dependent diabetes.

Author

Tian J, Atkinson MA, Clare-Salzler M, Herschenfeld A, Forsthuber T, Lehmann PV, and Kaufman DL

Subjects

Administration, Intranasal, Animals, Autoantibodies biosynthesis, Diabetes Mellitus, Type 1 immunology, Female, Glutamate Decarboxylase immunology, Immune Tolerance, Immunoglobulin G biosynthesis, Immunoglobulin Isotypes biosynthesis, Immunotherapy, Adoptive, Incidence, Interferon-gamma biosynthesis, Interleukin-5 biosynthesis, Islets of Langerhans pathology, Mice, Mice, Inbred NOD, Mice, SCID, Peptide Fragments immunology, Th1 Cells immunology, Diabetes Mellitus, Type 1 prevention & control, Glutamate Decarboxylase therapeutic use, Peptide Fragments therapeutic use, Th2 Cells immunology

Abstract

We previously demonstrated that a spontaneous Th1 response against glutamate decarboxylase (GAD65) arises in NOD mice at four weeks in age and subsequently T cell autoimmunity spreads both intramolecularly and intermolecularly. Induction of passive tolerance to GAD65, through inactivation of reactive T cells before the onset of autoimmunity, prevented determinant spreading and the development of insulin-dependent diabetes mellitus (IDDM). Here, we examined whether an alternative strategy, designed to induce active tolerance via the engagement of Th2 immune responses to GAD65, before the spontaneous onset of autoimmunity, could inhibit the cascade of Th1 responses that lead to IDDM. We observed that a single intranasal administration of GAD65 peptides to 2-3-wk-old NOD mice induced high levels of IgG1 antibodies to GAD65. GAD65 peptide treated mice displayed greatly reduced IFN gamma responses and increased IL-5 responses to GAD65, confirming the diversion of the spontaneous GAD65 Th1 response toward a Th2 phenotype. Consistent with the induction of an active tolerance mechanism, splenic CD4+ (but not CD8+) T cells from GAD65 peptide-treated mice, inhibited the adoptive transfer of IDDM to NOD-scid/scid mice. This active mechanism not only inhibited the development of proliferative T cell responses to GAD65, it also limited the expansion of autoreactive T cell responses to other beta cell antigens (i.e., determinant spreading). Finally, GAD65 peptide treatment reduced insulitis and long-term IDDM incidence. Collectively, these data suggest that the nasal administration of GAD65 peptides induces a Th2 cell response that inhibits the spontaneous development of autoreactive Th1 responses and the progression of beta cell autoimmunity in NOD mice.

Published

1996

3. Spontaneous loss of T-cell tolerance to glutamic acid decarboxylase in murine insulin-dependent diabetes.

Author

Kaufman DL, Clare-Salzler M, Tian J, Forsthuber T, Ting GS, Robinson P, Atkinson MA, Sercarz EE, Tobin AJ, and Lehmann PV

Subjects

Aging immunology, Amino Acid Sequence, Animals, Diabetes Mellitus, Type 1 pathology, Epitopes immunology, Female, Immunosuppression Therapy, Islets of Langerhans immunology, Islets of Langerhans pathology, Mice, Mice, Inbred NOD, Molecular Sequence Data, Autoantigens immunology, Diabetes Mellitus, Type 1 immunology, Glutamate Decarboxylase immunology, T-Lymphocytes, Helper-Inducer immunology

Abstract

Insulin-dependent diabetes mellitus (IDDM) in non-obese diabetic (NOD) mice results from the T-lymphocyte-mediated destruction of the insulin-producing pancreatic beta-cells and serves as a model for human IDDM. Whereas a number of autoantibodies are associated with IDDM, it is unclear when and to what beta-cell antigens pathogenic T cells become activated during the disease process. We report here that a T-helper-1 (Th1) response to glutamate decarboxylase develops in NOD mice at the same time as the onset of insulitis. This response is initially limited to a confined region of glutamate decarboxylase, but later spreads intramolecularly to additional determinants. Subsequently, T-cell reactivity arises to other beta-cell antigens, consistent with intermolecular diversification of the response. Prevention of the spontaneous anti-glutamate decarboxylase response, by tolerization of glutamate decarboxylase-reactive T cells, blocks the development of T-cell autoimmunity to other beta-cell antigens, as well as insulitis and diabetes. Our data suggest that (1) glutamate decarboxylase is a key target antigen in the induction of murine IDDM; (2) autoimmunity to glutamate decarboxylase triggers T-cell responses to other beta-cell antigens, and (3) spontaneous autoimmune disease can be prevented by tolerization to the initiating target antigen.

Published

1993

4. Autoimmunity to two forms of glutamate decarboxylase in insulin-dependent diabetes mellitus.

Author

Kaufman DL, Erlander MG, Clare-Salzler M, Atkinson MA, Maclaren NK, and Tobin AJ

Subjects

Amino Acid Sequence, Autoantibodies blood, Autoantibodies immunology, Autoantigens immunology, Autonomic Nervous System immunology, Autonomic Nervous System pathology, Diabetes Mellitus, Type 2 complications, Diabetes Mellitus, Type 2 immunology, Diabetic Neuropathies etiology, Diabetic Neuropathies immunology, Enterovirus genetics, Enterovirus immunology, Epitopes immunology, Glutamate Decarboxylase genetics, Humans, Islets of Langerhans enzymology, Islets of Langerhans immunology, Molecular Sequence Data, Peptides genetics, Peptides immunology, Sequence Homology, Nucleic Acid, Viral Proteins genetics, Viral Proteins immunology, Autoimmunity immunology, Diabetes Mellitus, Type 2 etiology, Glutamate Decarboxylase immunology, Isoenzymes immunology

Abstract

Insulin-dependent diabetes mellitus (IDDM) is thought to result from the autoimmune destruction of the insulin-producing beta cells of the pancreas. Years before IDDM symptoms appear, we can detect autoantibodies to one or both forms of glutamate decarboxylase (GAD65 and GAD67), synthesized from their respective cDNAs in a bacterial expression system. Individual IDDM sera show distinctive profiles of epitope recognition, suggesting different humoral immune responses. Although the level of GAD autoantibodies generally decline after IDDM onset, patients with IDDM-associated neuropathies have high levels of antibodies to GAD, years after the appearance of clinical IDDM. We note a striking sequence similarity between the two GADs and Coxsackievirus, a virus that has been associated with IDDM both in humans and in experimental animals. This similarity suggests that molecular mimicry may play a role in the pathogenesis of IDDM.

Published

1992

5. Glutamate decarboxylase: an autoantigen in IDDM.

Author

Clare-Salzler MJ, Tobin AJ, and Kaufman DL

Subjects

Diabetes Mellitus, Type 1 blood, Diabetes Mellitus, Type 1 enzymology, Glutamate Decarboxylase analysis, Glutamate Decarboxylase blood, Humans, Islets of Langerhans immunology, Recombinant Proteins analysis, Recombinant Proteins immunology, Autoantibodies analysis, Autoantigens analysis, Diabetes Mellitus, Type 1 immunology, Diabetic Neuropathies immunology, Glutamate Decarboxylase immunology

Published

1992

6. Identical and Nonidentical Twins: Risk and Factors Involved in Development of Islet Autoimmunity and Type 1 Diabetes

Author

Triolo, T.M., Fouts, A., Pyle, L., Yu, L., Gottlieb, P.A., Steck, A.K., Greenbaum, C.J., Atkinson, M., Baidal, D., Battaglia, M., Becker, D., Bingley, P., Bosi, E., Buckner, J., Clements, M., Colman, P., DiMeglio, L., Gitelman, S., Goland, R., Gottlieb, P., Herold, K., Knip, M., Krischer, J., Lernmark, A., Moore, W., Moran, A., Muir, A., Palmer, J., Peakman, M., Philipson, L., Raskin, P., Redondo, M., Rodriguez, H., Russell, W., Spain, L., Schatz, D.A., Sosenko, J., Wentworth, J., Wherrett, D., Wilson, D., Winter, W., Ziegler, A., Anderson, M., Antinozzi, P., Benoist, C., Blum, J., Bourcier, K., Chase, P., Clare-Salzler, M., Clynes, R., Eisenbarth, G., Fathman, C.G., Grave, G., Hering, B., Insel, R., Kaufman, F., Kay, T., Leschek, E., Mahon, J., Marks, J.B., Nanto-Salonen, K., Nepom, G., Orban, T., Parkman, R., Pescovitz, M., Peyman, J., Pugliese, A., Roep, B., Roncarolo, M., Savage, P., Simell, O., Sherwin, R., Siegelman, M., Skyler, J.S., Steck, A., Thomas, J., Trucco, M., Wagner, J., Krischer, J.P., Rafkin, L., Cowie, C., Foulkes, M., Krause-Steinrauf, H., Lachin, J.M., Malozowski, S., Ridge, J., Zafonte, S.J., Sosenko, J.M., Kenyon, N.S., Santiago, I., Bundy, B., Abbondondolo, M., Adams, T., Amado, D., Asif, I., Boonstra, M., Burroughs, C., Cuthbertson, D., Deemer, M., Eberhard, C., Fiske, S., Ford, J., Garmeson, J., Guillette, H., Geyer, S., Hays, B., Henderson, C., Henry, M., Heyman, K., Hsiao, B., Karges, C., Keaton, N., Kinderman, A., Law, P., Leinbach, A., Liu, S., Lloyd, J., Malloy, J., Maddox, K., Martin, J., Miller, J., Milliot, E., Moore, M., Muller, S., Nguyen, T., O'Donnell, R., Roberts, A., Sadler, K., Stavros, T., Tamura, R., Wood, K., Xu, P., Young, K., Alies, P., Badias, F., Baker, A., Bassi, M., Beam, C., Boulware, D., Bounmananh, L., Bream, S., Freeman, D., Gough, J., Ginem, J., Granger, M., Kieffer, M.H.M., Lane, P., Linton, C., Nallamshetty, L., Oduah, V., Parrimon, Y., Paulus, K., Pilger, J., Ramiro, J., Ritzie, A.L., Sharma, A., Shor, A., Song, X., Terry, A., Weinberger, J., Wootten, M., Harding, P., McDonough, S., Mcgee, P.F., Hess, K.O., Phoebus, D., Quinlan, S., Raiden, E., Batts, E., Buddy, C., Kirpatrick, K., Ramey, M., Shultz, A., Webb, C., Romesco, M., Fradkin, J., Aas, S., Blumberg, E., Beck, G., Brillon, D., Gubitosi-Klug, R., Laffel, L., Vigersky, R., Wallace, D., Braun, J., B. lo, Mitchell, H., Naji, A., Nerup, J., Orchard, T., Steffes, M., Tsiatis, A., Veatch, R., Zinman, B., Loechelt, B., Baden, L., Green, M., Weinberg, A., Marcovina, S., Palmer, J.P., Babu, S., Eisenbarth, G.S., Marks, J., Matheson, D., Gomez, D., McDonald, A., Pena, S., Pietropaolo, M., Shippy, K., Brown, T., Dove, A., Hammond, M., Hefty, D., Klein, J., Kuhns, K., Letlau, M., Lord, S., McCulloch-Olson, M., Miller, L., Odegard, J., Sachter, E., St Marie, M., Stickney, K., VanBuecken, D., Vellek, B., Webber, C., Allen, L., Bollyk, J., Hilderman, N., Ismail, H., Lamola, S., Sanda, S., Vendettuoli, H., Tridgell, D., Monzavi, R., Bock, M., Fisher, L., Halvorson, M., Jeandron, D., Kim, M., Wood, J., Geffner, M., Salazar, C., Cook, S., Freeby, M., Gallagher, M.P., Gandica, R., Greenberg, E., Kurland, A., Pollak, S., Wolk, A., Chan, M., Koplimae, L., Levine, E., Smith, K., Trast, J., Evans-Molina, C., Hufferd, R., Jagielo, B., Kruse, C., Patrick, V., Rigby, M., Spall, M., Swinney, K., Terrell, J., Christner, L., Ford, L., Lynch, S., Menendez, M., Merrill, P., and Pesc

Subjects

Adult, Male, medicine.medical_specialty, Adolescent, Endocrinology, Diabetes and Metabolism, Concordance, Twins, Autoimmunity, 030209 endocrinology & metabolism, Type 2 diabetes, Environment, medicine.disease_cause, Islets of Langerhans, Young Adult, 03 medical and health sciences, 0302 clinical medicine, Risk Factors, Seroepidemiologic Studies, Diabetes mellitus, Internal medicine, Diseases in Twins, Twins, Dizygotic, Internal Medicine, medicine, Genetic predisposition, Humans, Insulin, Mass Screening, Genetic Predisposition to Disease, 030212 general & internal medicine, Child, Mass screening, Autoantibodies, Advanced and Specialized Nursing, Type 1 diabetes, Glutamate Decarboxylase, business.industry, Siblings, Autoantibody, Twins, Monozygotic, Predicting Diabetes Using Genetic Risk Scores, medicine.disease, Diabetes Mellitus, Type 1, Endocrinology, Child, Preschool, Disease Progression, Female, business

Abstract

OBJECTIVE There are variable reports of risk of concordance for progression to islet autoantibodies and type 1 diabetes in identical twins after one twin is diagnosed. We examined development of positive autoantibodies and type 1 diabetes and the effects of genetic factors and common environment on autoantibody positivity in identical twins, nonidentical twins, and full siblings. RESEARCH DESIGN AND METHODS Subjects from the TrialNet Pathway to Prevention Study (N = 48,026) were screened from 2004 to 2015 for islet autoantibodies (GAD antibody [GADA], insulinoma-associated antigen 2 [IA-2A], and autoantibodies against insulin [IAA]). Of these subjects, 17,226 (157 identical twins, 283 nonidentical twins, and 16,786 full siblings) were followed for autoantibody positivity or type 1 diabetes for a median of 2.1 years. RESULTS At screening, identical twins were more likely to have positive GADA, IA-2A, and IAA than nonidentical twins or full siblings (all P < 0.0001). Younger age, male sex, and genetic factors were significant factors for expression of IA-2A, IAA, one or more positive autoantibodies, and two or more positive autoantibodies (all P ≤ 0.03). Initially autoantibody-positive identical twins had a 69% risk of diabetes by 3 years compared with 1.5% for initially autoantibody-negative identical twins. In nonidentical twins, type 1 diabetes risk by 3 years was 72% for initially multiple autoantibody–positive, 13% for single autoantibody–positive, and 0% for initially autoantibody-negative nonidentical twins. Full siblings had a 3-year type 1 diabetes risk of 47% for multiple autoantibody–positive, 12% for single autoantibody–positive, and 0.5% for initially autoantibody-negative subjects. CONCLUSIONS Risk of type 1 diabetes at 3 years is high for initially multiple and single autoantibody–positive identical twins and multiple autoantibody–positive nonidentical twins. Genetic predisposition, age, and male sex are significant risk factors for development of positive autoantibodies in twins.

Published

2019