Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P06126 (CD1a)
 2,221 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Dermal dendritic cells from eleven cases of mycosis fungoides (MF) (six patch and five plaque stage), two cases of pre-MF, and five specimens of normal human skin, were characterized immunohistochemically using a panel of antibodies including anti-human Thy-1, intercellular adhesion molecule-1 (ICAM-1; CD54), endothelial leukocyte adhesion molecule-1 (ELAM-1), vascular cell adhesion molecule-1 (VCAM-1), CD1a, CD2, CD14, CD18, CD34, MAC387, KP-1, EBM-11, factor XIIIa, factor XIIIs, and S100. Thy-1 expression in normal skin was limited to the microvascular endothelium and perivascular dendritic cells. An extensive interstitial network of Thy-1+ dendritic cells was seen in the papillary dermis of all cases of MF, whereas no epidermal cells were Thy-1+. The mean +/- standard deviation of interstitial Thy-1+ cells per high power field in the dermis was: normal skin, 2.86 +/- 0.34; pre-MF, 15; patch stage MF, 13.4 +/- 7.08; plaque stage MF, 49.96 +/- 21.29. Thy-1+ dendritic cells morphologically resembled the factor XIIIa+ "dermal dendrocyte" (DD) and shared their VCAM-1+, ICAM-1+, CD1a, CD2-, CD14+, CD18+, EMB11+, factor XIIIa+, factor XI-IIs-, S100-, MAC387- and KP-1-immunophenotype in MF. Double labeling studies revealed up to 50% of Thy-1+DD were also factor XIIIa+ in MF. Immediately beneath these cells was a similar network of CD34+, Thy-1-, factor XIIIa- dendritic cells limited to the reticular dermis. Strong microvascular endothelial cell expression of Thy-1 and VCAM-1, and focal vascular ELAM-1 expression were also seen in MF. Distinct cellular compartmentalization (papillary dermis versus reticular dermis versus epidermis) of dendritic cells is demonstrated by the differential expression of Thy-1, factor XIIIa, and CD34 antigens. The extensive number and prominent dermal dendritic network in the papillary dermis juxtaposed between epidermal keratinocytes (KC) and dermal/epidermal T cells, suggests an important pathophysiologic role for this newly recognized and immunophenotypically distinctive cell population in MF.
Am J Pathol 1992 Dec
PMID:Cutaneous expression of Thy-1 in mycosis fungoides. 128 18

In this study we show the expression of the newly identified carbohydrate ligand, sialosyl-Le(X) on Langerhans cells. The receptor for sialosyl-Le(X) is the endothelial leukocyte adhesion molecule-1 (ELAM-1) present on activated endothelial cells. Using flow cytometry, Langerhans cells were selected due to positivity for an antibody against CD1a and low orthogonal light scatter. The CD1a antigen stained by the OKT6 antibody is considered a maturational marker of Langerhans cells in agreement with the specific labeling of dendritic cells in the epithelium only. Double immunostaining (OKT6/anti-sialosyl-Le(X)) using flow cytometry and immunohistochemistry demonstrated that almost all OKT6-positive cells in normal stratified epithelium expressed sialosyl-Le(X). Conversely, by immunohistochemistry of oral epithelium with acute inflammation, additional dendritic cells negative for OKT6 were found to express sialosyl-Le(X). In addition, sialosyl-Le(X)-positive but not OKT6-positive dendritic cells were found in the submucosa. These findings indicate that the carbohydrate antigen sialosyl-Le(X) is expressed earlier than the CD1a antigen in the maturation of the Langerhans cell lineage. Future studies should aim at investigating the importance of adhesion between sialosyl Le(X) and ELAM-1 in epithelial recruitment of Langerhans cells.
Exp Dermatol 1992 Dec
PMID:The ELAM-1 ligand sialosyl-Le(X) is present on Langerhans cells isolated from stratified epithelium. 128 12

The purpose of this study was to determine whether human tissue macrophages (M phi s) in various inflammatory/reactive conditions express different immunophenotypes. Using a large panel of monoclonal antibodies to monocyte/M phi-related antigens and a frozen-section immunoperoxidase technique, the following conditions were studied: granulomatous inflammation of unknown etiology, sarcoidosis, cat-scratch fever, toxoplasmosis, Gaucher's disease, and juvenile xanthogranulomas. The results show that there is immunophenotypic variation of the M phi s among the various inflammatory/reactive conditions. For example, the M phi s in cat-scratch fever are nearly unique in the expression of the "early inflammation" antigen identified by antibody 27E10, and the M phi s in juvenile xanthogranulomas, unlike those in most of the other conditions, lacked the antigen detected by antibody 25F9. The M phi s in Gaucher's disease differed from those in the other disorders by the combined absence of CD11b, CD14, G16/1, CD1a, CD25, and CD30. The inflammatory/reactive M phi s also exhibited differences from those in "normal" tissues, namely, a tendency toward acquisition of the antigens identified by antibodies Mac 387 and G16/1 and the more uniform expression of the "activation" antigens CD25, CD30, and CD71. The antigenic variations described here probably reflect differences in antigenic stimuli and M phi function. In addition to the possible biologic implications, this M phi immunophenotypic diversity may have practical diagnostic applications.
Hum Pathol 1992 Dec
PMID:Macrophages (histiocytes) in various reactive and inflammatory conditions express different antigenic phenotypes. 133 45

We studied whether abnormalities in epidermal APC could be responsible for intracutaneous T cell activation in atopic dermatitis (AD). In the absence of added Ag, patients' peripheral blood T cells demonstrated significantly increased proliferation to their autologous lesional epidermal cells (mean +/- SEM = 19,726 +/- 9,754 cpm [3H]TdR uptake) relative to epidermal cells from uninvolved AD skin (2179 +/- 697 cpm) (n = 10) (p = 0.0001, log transformed data). AD T cell proliferative responses to autologous epidermal cells were dependent upon cells expressing HLA-DR, CD1a, and CD36, and not upon keratinocytes or their cytokines. Ultrastructurally, these cells ranged from typical Langerhans cells to indeterminate cells with irregular nuclear contours. Enriched populations of lesional AD Langerhans cells were highly stimulatory for autologous T cells, whereas equal numbers of Langerhans cells from non atopic epidermis were poor stimulators, even at high concentrations. The dermal perivascular dendritic cell markers CD36 and CD1b, not usually present on normal epidermal APC, were expressed by 40 and 60% of lesional AD CD1a+ epidermal Langerhans cells, respectively. Addition of anti-CD1b to cocultures of AD epidermal cells and autologous T lymphocytes augmented T cell activation, suggesting that the expression of CD1b by AD Langerhans cells may represent over expression of a molecule functionally linked to the enhanced T cell stimulatory capacity of these cells. Thus, stimulatory signals for T cells contained within AD epidermis are carried by cells in an abnormal differentiation state as indicated by expression of phenotypic characteristics of both epidermal and dermal antigen presenting cells (HLA-DR+, CD1a+, CD1b+, CD36+). We propose that activation of autologous T cells by an altered cutaneous APC population may represent a mechanism for the hyperactive and disordered cell-mediated immune response that characterizes the dermatitic lesions of AD.
J Immunol 1991 Dec 01
PMID:Hyperstimulatory CD1a+CD1b+CD36+ Langerhans cells are responsible for increased autologous T lymphocyte reactivity to lesional epidermal cells of patients with atopic dermatitis. 171 88

Three different strategies for isolating RNA from epidermal cells were compared. Starting with dermatome sections frozen or disaggregated epidermal cells purified by fluorescence activated cell sorting (FACS), RNA was isolated with a guanidinium thiocyanate technique. Specific mRNA were detected by Northern blot analysis (involucrin, keratin 5, actin), or by reverse transcription and amplification with the polymerase chain reaction (PCR), using primers specific for keratinocyte products (keratins 1 and 14) and Langerhans cells (CD1a). Messenger RNA's characteristic of Langerhans cells and of keratinocytes at different stages of differentiation were detected in dermatome and epidermal sheet preparations as well as in FACS-separated cells. The use of snap-frozen dermatome sections allows the isolation of RNA from epidermis that has undergone minimal trauma and is very close to its in vivo state, but that includes RNA from some dermal cells. Extraction of RNA from Dispase-separated sheets involves slightly more manipulation of the epidermis but provides a sample free from dermal contaminants. PCR analysis of sorted epidermal cells is both sensitive and specific, but involves still greater manipulation. This final technique, however, allows the investigation of mRNA produced by small groups of epidermal cells that are still much closer to their in vivo state than if they had been cultured. By combining these techniques it is possible to determine the baseline production of specific mRNA in the skin in vivo and to assign their production to specific groups of cells with a sensitivity and specificity greater than any approach previously described.
J Invest Dermatol 1991 Dec
PMID:Isolation, detection, and amplification of intact mRNA from dermatome strips, epidermal sheets, and sorted epidermal cells. 174 22

The CD1 human antigens are a family of at least three components, CD1a, CD1b, and CD1c, that are characteristic of the cortical stage of thymocyte maturation. CD1a was originally named HTA1 or T6 and thought to be the human equivalent of mouse Tla. The genes coding for all three have now been identified by transfection into mouse cells. The transfectants express the surface antigens that can then be recognized by the corresponding cluster of monoclonal antibodies used to define the three members of CD1. The full sequence of the genomic DNA is described for all three. The intron-exon structure of CD1a is deduced by comparison with a near-full-length cDNA clone. Similar structures are proposed for the other two, largely based on sequence homology. An unusually long 5'-untranslated exon (280 bases long) is highly conserved between the three genes, suggesting an important but unknown function. CD1c has a duplicated form of this exon that is thought to be spliced out. The major homology between the three antigens is in the beta 2-microglobulin-binding domain. The general relatedness to major histocompatibility complex class I and class II molecules is significant but low, with no section of higher homology to mouse Tla.
Proc Natl Acad Sci U S A 1987 Dec
PMID:Structure and expression of the human thymocyte antigens CD1a, CD1b, and CD1c. 244 86

Beta 2-microglobulin (beta 2m) forms the invariant light chain of the MHC-encoded HLA-ABC and the non-MHC-encoded CD1 molecules. While HLA-ABC (MHC Class I) molecules are virtually ubiquitous in tissue distribution, CD1 determinants by contrast are more restricted. We have assessed, by indirect immunoenzymeassay, the relative membrane densities of these molecules on malignant thymic and post-thymic T cells. It was found that the T cells of mature post-thymic proliferations expressed significantly more beta 2m-associated protein, predominantly HLA-ABC in nature, than thymic-ALL blasts. This parallels the situation found in normal peripheral T cells and thymocytes. In contrast to post-thymic T cells, thymic-ALL blasts showed considerable case to case variation with respect to non-HLA-associated beta 2m and, of particular interest, not all of this excess beta 2m could be accounted for by CD1a. We therefore conclude that other beta 2m-containing molecules may be expressed on thymic-ALL blasts and possibly also on post-thymic leukaemic T cells. In addition, it was found that T cells from CD4+ cases of post-thymic proliferations expressed more beta 2m-associated determinants than other T cells, whether of either normal or malignant origin, and that certain post-thymic malignancies express significantly increased levels of beta 2m-associated protein relative to normal peripheral T-cells. This is in direct contrast to the situation seen in many solid malignancies.
Clin Exp Immunol 1988 Dec
PMID:MHC class I and class I-like gene product expression by malignant T cells: relationships between CD1a, HLA-ABC and beta 2-microglobulin. 246 92

Human CD1 is a family of thymocyte differentiation antigens which consist of heavy chains with mol. wts between 43 and 49 kd binding to beta 2 microglobulin. They are distant relatives of the major histocompatibility complex (MHC) class I and II products. Five human CD1 genes have been described. Three (CD1A, -B and -C) code for the serologically defined CD1a, -b and -c antigens. The protein products of the other two genes, CD1D and CD1E, remain unknown. All CD1 genes are located on chromosome 1 and hence are independent of the MHC locus. In this paper, the tight linkage of the CD1 genes has been established by pulse field gel electrophoresis, cosmid cloning and walking techniques. The 190 kb of DNA linking all five CD1 genes has been spanned by 14 overlapping cosmids. The order of the genes in the CD1 complex is CD1D-CD1A-CD1C-CD1B-CD1E, and, with the exception of CD1B, they are arranged in the same transcriptional orientation. The genes are evenly spaced in the complex except for the distance between CD1D and CD1A, which is two to three times greater than the average.
EMBO J 1989 Dec 01
PMID:A physical map linking the five CD1 human thymocyte differentiation antigen genes. 258 17

The immunophenotypes of the HLA-DR-positive leucocyte populations in normal human skin were studied using an extensive panel of monoclonal antibodies, which included antibodies from the Third International Leucocyte Differentiation Antigen Workshop (3rd LDAW). Langerhans' cells (LC) in the epidermis stained with antibodies from CD15c, Groups 10, 12a, 12b and 15, of the myeloid panel and from CD39 of the B-cell panel. However, LC did not react with CD14 antibodies or 63D3, which are frequently used to stain tissue macrophages. In addition to epidermal LC (26 cells/linear mm) a significant population of CD1a-positive cells was identified in the papillary dermis (7 cells/linear mm of overlying epidermis). The dermal HLA-DR-positive leucocytes consisted of three cell populations. The most numerous cell type stained with antibodies to monocytes/macrophages. There were fewer, though substantial, numbers of T lymphocytes (mainly CD7-negative) and the least numerous was the population of CD1a-positive cells. The CD1a-positive cells and the population of dermal cells that stain with monocyte/macrophage markers are both potential antigen-presenting cells for the skin-associated immune system.
Immunology 1988 Dec
PMID:HLA-DR-positive leucocyte subpopulations in human skin include dendritic cells, macrophages, and CD7-negative T cells. 306 20

Using a Saccharomyces cerevisiae strain containing an integrated copy of an H2A-lacZ fusion gene, we screened for mutants which overexpressed beta-galactosidase as a way to identify genes which regulate transcription of the histone genes. Five recessive mutants with this phenotype were shown to contain altered regulatory genes because they had lost repression of HTA1 transcription which occurs upon inhibition of chromosome replication (D. E. Lycan, M. A. Osley, and L. Hereford, Mol. Cell. Biol. 7:614-621, 1987). Periodic transcription was affected in the mutants as well, since the HTA1 gene was transcribed during the G1 and G2 phases of the cell cycle, periods in the cell cycle when this gene is normally not expressed. A similar loss of cell cycle-dependent transcription was noted for two of the three remaining histone loci, while the HO and CDC9 genes continued to be expressed periodically. Using isolated promoter elements inserted into a heterologous cycl-lacZ fusion gene, we demonstrated that the mutations fell in genes which acted through a negative site in the TRT1 H2A-H2B promoter.
Mol Cell Biol 1987 Dec
PMID:Trans-acting regulatory mutations that alter transcription of Saccharomyces cerevisiae histone genes. 312 20


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