Showing papers by "Per A. Peterson published in 1986"

Only one DQ-beta restriction fragment pattern of each DR specificity is associated with insulin-dependent diabetes.

Abstract: Insulin-dependent diabetes is generally associated with the serologic HLA-DR specificities 3 and 4, in particular with DR-3,4 heterozygosity. The disease is negatively associated with DR-2. To investigate these associations further at the genomic level, DNA from 13 families with a proband having insulin-dependent diabetes, from 11 other individuals with the same disease, and from HLA-DR-matched control individuals was subjected to restriction fragment analysis. Three different enzymes (Bam HI, Eco RI, and Pvu II) and cDNA clones for three HLA-D region class II antigen alpha- and beta-chains (DR-beta, DQ-beta, and DQ-alpha) were used. In six families, a total of 11 siblings HLA-DR-identical to the proband were examined. There was no discrepancy between the hybridization patterns of the proband and those of the DR-identical siblings. Two different DQ-B fragment patterns were detected with each one of the serologic specificities DR-2 and DR-4. In both cases, only one of the patterns correlated significantly with diabetes. Thus, DQ-beta genomic hybridization may be used in conjunction with HLA-DR typing to identify individuals with higher relative risk to acquire insulin-dependent diabetes. These results may suggest that insulin-dependent diabetes is associated with the DQ rather than with the DR locus.

Adenoviruses of subgenera B, C, D, and E modulate cell-surface expression of major histocompatibility complex class I antigens.

Abstract: The immune defense against viral infections involves cytotoxic T lymphocytes that recognize viral products in the context of class I major histocompatibility complex (MHC) antigens. To evade such immune surveillance viruses may have evolved various strategies to manipulate the expression of class I antigens. Adenovirus 2 manufactures an early glycoprotein, E19, that binds to nascent class I antigens in the endoplasmic reticulum and impedes their transport to the cell surface. We now show that adenoviruses typical of all viral subgenera except the highly oncogenic subgenus A dramatically reduce the cell-surface expression of class I antigens. It has been shown that subgenus A viruses abolish class I antigen expression in transformed cells by reducing mRNA levels. Thus, all adenoviruses can modulate the cell-surface expression of class I antigens.

Structural and functional dissection of an MHC class I antigen-binding adenovirus glycoprotein.

Abstract: The early transmembrane glycoprotein E19 of adenovirus-2 binds to class I antigens of the major histocompatibility complex (MHC). The association is initiated in the endoplasmic reticulum of infected cells and abrogates the intracellular transport of the class I molecules. To examine which parts of the E19 molecule are responsible for the association with the class I antigens and which parts confine the protein to the endoplasmic reticulum we have constructed a series of mutated E19 genes, which have been expressed in an improved mammalian expression vector. By various manipulations the membrane anchoring and the cytoplasmic domains were removed from the protein. The biosynthesis of the mutant protein was examined. All mutant proteins were secreted from the cells suggesting that the transmembrane and/or cytoplasmic portions of the E19 molecule are responsible for its confinement to the endoplasmic reticulum. The ability to associate with class I antigens was retained by the lumenal domain of the E19 protein.

Increased levels of several retinoid binding proteins resulting from retinoic acid-induced differentiation of F9 cells.

Abstract: The embryonal carcinoma cell line F9 is known to differentiate when exposed to retinoic acid. We have examined the quantities of two intracellular retinoid-binding proteins in undifferentiated and differentiated F9 cells. The existence of a cell surface receptor that recognizes the plasma retinol-binding protein was also explored. It was shown that undifferentiated F9 cells contain low concentrations of the two retinoid-binding proteins. The cellular retinoic acid-binding protein was present in approximately 3-fold molar excess over the cellular retinol-binding protein. Upon culture in the presence of retinoic acid, F9 cells display elevated concentrations of both cellular retinol-binding protein and cellular retinoic acid-binding protein. Since the levels of β2-microglobulin, a marker of the differentiated state with no known involvement in the metabolism of vitamin A, increased in parallel with the retinoid-binding proteins, it seems unlikely that retinoic acid selectively increased the levels of the two retinoid-binding proteins. The differentiated, in contrast to the undifferentiated cells, can accumulate retinol from plasma retinol-binding protein and display a cell surface receptor for this protein. Despite the fact that retinoic acid-induced differentiation of F9 cells promotes increased levels of several proteins involved in the normal metabolism of vitamin A, no evidence was obtained to suggest that the cells were dependent on retinoids to maintain their differentiated state.

Differential association between two human MHC class I antigens and an adenoviral glycoprotein.

Abstract: The glycoprotein E19, encoded in early region 3 of adenovirus-2, forms complexes with major histocompatibility complex class I antigens. As a result of the complex formation, the intracellular transport of the class I antigens is abrogated, and adenovirus-infected cells display gradually diminishing quantities of cell surface-expressed class I molecules. To assess whether the E19 protein interacts equally well with different class I antigens, the associations between the viral protein and HLA-A2 and HLA-B7 antigens have been estimated. By infecting transfected HeLa cells expressing various amounts of HLA-A2 and HLA-B7 molecules, respectively, with various infectious doses of adenovirus-2, experimental conditions could be established that allowed quantitative estimates of the interactions to be determined. It was found that HLA-A2 molecules and the E19 protein interacts with a binding constant that is more than twice as high as that for HLA-B7 antigens and the viral protein. It is suggested that the pathogenicity of the virus may be dependent on the HLA-type of the infected individual.

Structure of the human Ia-associated invariant (gamma)-chain gene: identification of 5' sequences shared with major histocompatibility complex class II genes

Abstract: The human gene encoding the Ia-associated gamma (or invariant) chain was isolated by screening a genomic library in phage lambda with cDNA probes. The frequency of positive clones in the library, the overlapping restriction maps of the cloned fragments, and the patterns of genomic hybridization suggested that the gamma-chain gene exists as a single copy per haploid genome. The gene consists of 8 exons, spanning approximately 12 kilobases of DNA. All exon sequences were in an open reading frame, contained appropriate splice junction sequences, and encompassed the entire sequence of full-length gamma-chain mRNA, suggesting that the gene we isolated is most likely functional. Furthermore, "CAAT"-type and "TATA"-type promoter sequences were found at the expected positions upstream from the proposed cap site. The organization of the gamma-chain gene has none of the distinctive features of the immunoglobulin superfamily of genes, of which Ia alpha and beta chains are members. Therefore, the evolutionary origins, and perhaps the functions, of the Ia gamma chains are distinct from those of the other two Ia subunits alpha and beta. Despite the unrelatedness of these genes, consensus sequences found approximately 150 base pairs upstream from all the Ia alpha- and beta-chain genes sequenced to date were also found in analogous positions in the gamma-chain gene, suggesting a possible role in the coregulation of expression of these genes.

Cell surface expression of invariant gamma-chain of class II histocompatibility antigens in human skin.

Abstract: A rat monoclonal antibody (McAb 21:9) reactive with the human invariant gamma-chain of class II major histocompatibility complex (MHC)-encoded antigens was isolated and was shown to react with the carbohydrate-carrying, COOH-terminal part of the gamma-chain. The McAb 21:9 binds to a molecule that is identified as the gamma-chain for the following reasons: it has an apparent m.w. of 33,000, similar to that of the gamma-chain; it has a two-dimensional gel migration pattern identical to that of the gamma-chain; and it associates with immature, but not processed class II antigens. When used for immunohistochemical staining on sections of normal human skin, only dendritic, class II MHC antigen, and anti-Leu-6 reactive Langerhans cells are labeled in the epidermis. HLA-DR-expressing keratinocytes present in the tuberculin reaction, cutaneous T cell lymphoma, and lichen planus, however, did not react with the anti-gamma-chain antibody, nor with a HLA-DQ-reactive antibody. Cell surface expression of the gamma-chain was observed on 1 to 3% of normal viable epidermal cells in suspension. By using double indirect immunofluorescence, it was possible to demonstrate the simultaneous binding of anti-gamma-chain, anti-HLA-DR, anti-Leu-10, and anti-Leu-6 antibodies, respectively, on the same cells, thus confirming their identity as Langerhans cells. The presence of the gamma-chain on the surface of the immunocompetent Langerhans cells may indicate that the cell surface, not the cytoplasm as has been suggested, is the site of the primary function of the gamma-chain.