Kurt Brorson

Transactivation by AP-1 Is a Molecular Target of T Cell Clonal Anergy

Anergy is a mechanism of T lymphocyte tolerance induced by antigen receptor stimulation in the absence of co-stimulation. Anergic T cells were shown to have a defect in antigen-induced transcription of the interleukin-2 gene. Analysis of the promoter indicated that the transcription factor AP-1 and its corresponding cis element were specifically down-regulated. Exposure of anergic T cells to interleukin-2 restored both antigen responsiveness and activity of the AP-1 element.

Molecular regulation of the IL-2 gene: rheostatic control of the immune system.

The delivery of costimulation and the effects of the anergic state impinge on IL-2 production via different molecular mechanisms. The strongest experimental support at this stage suggests that CD28 signaling effects mRNA stability of several lymphokine genes including IL-2. While there may also be transcriptional effects of CD28 signals in human cells, controversy surrounding relevant TCR mimics must be addressed. In the case of clonal anergy, however, transcriptional non-responsiveness is evident when anergic cells are restimulated with TCR and costimulatory signals. This repression affects predominantly AP-1 activity. So far, the nature of the repression has not been identified.

Analysis of a new class I gene mapping to the Hmt region of the mouse

The major histocompatibility complex (MHC) of the BALB/c mouse contains three genes encoding classical class I molecules, as well as at least 32 nonclassical class I genes. Although much is known about the genes encoding the classical class I molecules, the majority of the nonclassical genes have not been characterized. This report describes a newly identified nonclassical class I gene,Thy19.4, which contains an open reading frame and resembles in several regards the genes encoding classical class I molecules. The similarities include shared amino acid sequence motifs which suggest that the putative Thy19.4 molecule may assume a tertiary structure similar to that of the classical class I molecules, as well as widespread transcription in a variety of tissues. However, unlike the classical class I genes, theThy19.4 gene maps approximately 1 cm distal to theTla region of the MHC, in the same region as the gene encoding theHmt element of the maternally transmitted antigen.

Expression of mouse Tla region class I genes in tissues enriched for γδ cells

The Tla region of the BALB/c mouse major histocompatibility complex contains at least 20 class I genes. The function of the products of these genes is unknown, but recent evidence demonstrates that some Tla region gene products could be involved in presentation of antigens to γδ T cells. We have generated a set of polymerase chain reaction (PCR) oligonucleotide primers and hybridization probes that permit us to specifically amplify and detect expression of 11 of the 20 BALB/c Tla region genes. cDNA prepared from 12 adult and fetal tissues and from seven cell lines was analyzed. In some cases, northern blot analysis or staining with monoclonal antibodies specific for the Tla-encoded thymus leukemia (TL) antigen were used to confirm the expression pattern of several of the genes as determined by PCR. Some Tla region genes, such as T24d and the members of the T10d/T22d gene pair, are expressed in a wide variety of tissues in a manner similar to the class I transplantation antigens. The members of the TL antigen encoding gene pair, T3d/T18d, are expressed in only a limited number of organs, including several sites enriched for γδ T cells. Other Tla region genes, including T1d, T2d, T16d, and T17d, are transcriptionally silent from the T8d/T20d gene pair do not undergo proper splicing. In general, sites that contain γδ T lymphocytes have Tla region transcripts. The newly identified pattern of expression of the genes analyzed in sites containing γδ T cells further extends the list of potential candidates for antigen presentation to γδ T cells.

Analysis of D2d: a D-region class I gene.

The mouse major histocompatibility complex is composed of several genes arranged into the K, D, Qa, and Tla regions. The D region of the BALB/c mouse includes genes D2d, D3d, and D4d, in addition to H-2Ddand H-2Ld. We have determined the DNA sequence of the D2dgene and compared it with the known sequences of several class I genes. The exon/intron structure of the D2dgene is similar to other class I genes. It also contains similar 5′ regulatory elements. A frameshift occurs in exon seven, resulting in a gene product with a truncated cytoplasmic tail. To examine the surface expression of the D2d molecule, we generated an exon-shuffled construct containing the promoter and exons 1–3, encoding the signal peptide, α1, and α2 external domains of the D2dgene linked to exons 4–8, encoding the α3, transmembrane and cytoplasmic domains, of the H-2Ddgene. The construct was transfected into mouse L cells, and a protein was detected at the cell surface by a monoclonal antibody (mAb) specific for the α3 domain of H-2Dd, as well as by other class I-specific mAbs. Although D2d is expressed at low levels, it may be a functional class I gene that most probably evolved from a Qa region gene.

Analysis of D2 d : a D-region class I gene

The mouse major histocompatibility complex is composed of several genes arranged into the K, D, Qa, and Tla regions. The D region of the BALB/c mouse includes genes D2d, D3d, and D4d, in addition to H-2Ddand H-2Ld. We have determined the DNA sequence of the D2dgene and compared it with the known sequences of several class I genes. The exon/intron structure of the D2dgene is similar to other class I genes. It also contains similar 5′ regulatory elements. A frameshift occurs in exon seven, resulting in a gene product with a truncated cytoplasmic tail. To examine the surface expression of the D2d molecule, we generated an exon-shuffled construct containing the promoter and exons 1–3, encoding the signal peptide, α1, and α2 external domains of the D2dgene linked to exons 4–8, encoding the α3, transmembrane and cytoplasmic domains, of the H-2Ddgene. The construct was transfected into mouse L cells, and a protein was detected at the cell surface by a monoclonal antibody (mAb) specific for the α3 domain of H-2Dd, as well as by other class I-specific mAbs. Although D2d is expressed at low levels, it may be a functional class I gene that most probably evolved from a Qa region gene.