Abstract

Using restriction fragment length polymorphism analysis (RFLP), three allelic DQ-alpha and three allelic DQ-beta patterns associated DQw1 have been recognized. One of these alpha/beta pairs was found to associate with DR1, two with DR2, and a fourth with DRw6. """"""""Complementary"""""""" alloreactive T-cell clones were generated that were able to specifically recognize one or the other of the two DR2 associated, DQw1-positive molecules of the stimulator cells. These molecules carry the same alpha chain but a different (allelic) form of beta chain. In the last few months, evidence has also been obtained by nucleotide sequencing that there are as many allelic forms of DQ-alpha and DQ-beta genes as there are different molecular DQ-alpha and DQ-beta (RFLP) patterns, and each alpha/beta gene combination is associated with the same DR allele as its corresponding molecular alpha/beta pattern pair. It would now be certainly interesting to definitively prove that: a) antibodies may recognize determinants present only on the alpha or on the beta chain of the DQ molecule, while T-cells recognize simultaneously alpha and beta determinants. An allelic modification on only one chain is sufficient to completely abrogate the T-cell alloreaction, but may not interfere with the ability of the antibodies to recognize other epitopes or epitopes of the other chain; b) specificities, against which reagents in general cannot be found because of the strong association of certain alpha with certain beta genes, can be artificially generated by co-transfecting alpha and beta genes in anusual associations; c) specific reagents (monoclonal antibodies as well as T-cell clones) can be generated against these """"""""new"""""""" specificities. The spontaneous generation of these """"""""new"""""""" specificities may rarely take place by transcomplementation in the presence of particular haplotype combinations. This may be the cause of the immunological failure or the immunological auto-aggression which has generally been found present in the majority of HLA associated diseases. The reagents generated against the artificially obtained """"""""new"""""""" specificities would be useful for the early recognition of their presence at the surface of the patient cells.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
1R01AI023963-01A2
Application #
3136580
Study Section
Allergy and Immunology Study Section (ALY)
Project Start
1988-07-01
Project End
1993-06-30
Budget Start
1988-07-01
Budget End
1989-06-30
Support Year
1
Fiscal Year
1988
Total Cost
Indirect Cost

  Institution

Name
University of Pittsburgh
Department
Type
Overall Medical
DUNS #
053785812
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213

  Publications

Lampasona, V; Ferrari, M; Bonifacio, E et al. (1995) HLA-DQ screening for risk assessment of insulin dependent diabetes in northern Italy. Acta Diabetol 32:137-42
Chicz, R M; Lane, W S; Robinson, R A et al. (1994) Self-peptides bound to the type I diabetes associated class II MHC molecules HLA-DQ1 and HLA-DQ8. Int Immunol 6:1639-49
Farber, D L; Giorda, R; Nettleton, M Y et al. (1993) Rat class III Fc gamma receptor isoforms differ in IgG subclass-binding specificity and fail to associate productively with rat CD3 zeta. J Immunol 150:4364-75
Giorda, R; Lampasona, V; Kocova, M et al. (1993) Non-radioisotopic typing of human leukocyte antigen class II genes on microplates. Biotechniques 15:918-25
Nimgaonkar, V L; Ganguli, R; Rudert, W A et al. (1993) A negative association of schizophrenia with an allele of the HLA DQB1 gene among African-Americans. Schizophr Res 8:199-209
Gutierrez-Lopez, M D; Bertera, S; Chantres, M T et al. (1992) Susceptibility to type 1 (insulin-dependent) diabetes mellitus in Spanish patients correlates quantitatively with expression of HLA-DQ alpha Arg 52 and HLA-DQ beta non-Asp 57 alleles. Diabetologia 35:583-8
Carcassi, C; Giorda, R; Trucco, M et al. (1992) A novel HLA-DR4 haplotype generated by a rare recombinational event between DRB1 and DQA1 loci. Immunogenetics 36:338-40
Giorda, R; Weisberg, E P; Ip, T K et al. (1992) Genomic structure and strain-specific expression of the natural killer cell receptor NKR-P1. J Immunol 149:1957-63
Trucco, M (1992) To be or not to be Asp 57, that is the question. Diabetes Care 15:705-15
Boehm, B O; Manfras, B; Seissler, J et al. (1991) Epidemiology and immunogenetic background of islet cell antibody--positive nondiabetic schoolchildren. Ulm-Frankfurt population study. Diabetes 40:1435-9

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