Influence of 5' flanking sequences on TL and H-2 expression in transfected L cells

Expression of nonclassical MHC class Ib genes: comparison of regulatory elements

Peptide binding proteins of the major histocompatibility complex consist of the "classical" class Ia and "nonclassical" class Ib genes. The gene organization and structure/function relationship of the various exons comprising class I proteins are very similar among the class Ia and class Ib genes. Although the tissue-specific patterns of expression of these two gene families are overlapping, many class Ib genes are distinguished by relative low abundance and/or limited tissue distribution. Further, many of the class Ib genes serve specialized roles in immune responses. Given that the coding sequences of the class Ia and class Ib genes are highly homologous we sought to examine the promoter regions of the various class Ib genes by comparison to the well characterized promoter elements regulating expression of the class Ia genes. This analysis revealed a surprising complexity of promoter structures among all class I genes and few instances of conservation of class Ia promoter regulatory elements among the class Ib genes.

Comparison of anti-tumor responses against TL positive lymphoma induced by skin grafting and dendritic cell immunization

When the skin of Tg.Con.3-1 transgenic mice expressing the TL (thymus leukemia) antigen in most tissues is grafted on syngeneic C3H mice, it is rejected, and a cytotoxic T cell (CTL) response against the TL antigen is induced. In this study, we first demonstrated that growth of TL positive lymphoma is suppressed in mice immunized by skin grafting. Immunization with bone marrow derived dendritic cells (DCs) from Tg.Con.3-1, was also found to be associated with an anti-tumor response, but less potent than skin grafting. Relative CTL precursor frequency with DC immunization was also approximately only one third that of skin grafting. The numbers of IFN-gamma producing cells in responder CD8 and CD4 T cell populations were higher with DC immunization than with skin grafting. However, DC immunization seems to induce non-specific immune responses, as re-stimulation with TL negative C3H spleen cells resulted in induction of almost half the number observed with TL positive cells. Thus, the actual number of IFN-gamma producing cells in specific responses to TL is not necessarily larger than with skin grafting immunization. The present results altogether suggest that DC immunization is capable of inducing an anti-tumor reaction, but also possibly unwanted immune responses. In vitro monitoring of specific and non-specific responses in the immune system, thus, is of particular importance for future development of cancer immunotherapy.

The T3(b) gene promoter directs intestinal epithelial cell-specific expression in transgenic mice

Although a few promoters that direct intestinal epithelial cell-specific expression in transgenic animals have been reported, they are not necessarily appropriate for transgenic studies in terms of activity and tissue specificity. Here, we examined the tissue specificity of transgene expression directed by the 2.8-kb promoter region of the T3(b) gene, which encodes one of the non-classical major histocompatibility complex class I molecules. The transgene was expressed exclusively in the epithelial cells of the small and large intestines at high levels. The results indicate that the T3(b) promoter is useful for directing transgene expression specifically in intestinal epithelial cells.

Two Types of Anti-TL (Thymus Leukemia) CTL Clones with Distinct Target Specificities: Differences in Cytotoxic Mechanisms and Accessory Molecule Requirements

TCRαβ CTL clones recognizing mouse thymus leukemia (TL) Ags were established and categorized into two groups: those killing any TL+ target cells (type I) and those killing only TL+ Con A blasts (type II). Cold target inhibition assays showed that the antigenic determinant(s) recognized by type II clones are expressed not only on TL+ Con A blasts but also on other TL+ target cells. The relation of the target specificity to the killing machinery and the accessory molecules involved in cytotoxicity were therefore analyzed using four representative clones selected from each type. Of the target cells tested, Fas was only expressed on Con A blasts, indicating that Fas ligand (FasL)-dependent cytotoxicity is limited to such cells. All four type II and one of four type I clones expressed FasL on the surface, while both types contained perforin in the cytoplasm. Blocking studies using neutralizing anti-FasL mAbs and concanamycin A (CMA), a selective inhibitor of the perforin pathway, suggested that type I clones kill target cells by way of perforin, while type II clones kill TL+ Con A blasts through FasL together with perforin. For their cytotoxicity, type I CTLs require a signal through CD8, while type II require LFA-1/ICAM-1 interactions. Type II clones also need a costimulatory signal through an unknown molecule for perforin-dependent cytotoxicity. These results taken together suggest that the difference in the target specificity of anti-TL CTL clones is due to variation in the killing machineries and the dependence on accessory molecules.

Down-regulation of major histocompatibility complex Q1b gene expression by 2,3,7,8-tetrachlorodibenzo-p-dioxin

We analyzed mouse hepatoma cells using differential display to discover new genes that respond to the environmental contaminant 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD). We identified a class I major histocompatibility complex (MHC) gene, which we designated as MHC Q1b, whose expression decreases in the presence of TCDD. TCDD-induced down-regulation of MHC Q1b requires both the aromatic hydrocarbon receptor and the aromatic hydrocarbon receptor nuclear translocator, transcription factors that up-regulate other genes in response to TCDD. Down-regulation of MHC Q1b by TCDD appears to involve both transcriptional and post-transcriptional regulatory events; the post-transcriptional destabilization of MHC Q1b mRNA is probably a secondary response to TCDD. Our findings reveal new mechanistic aspects of gene regulation by TCDD. In addition, our observations suggest a mechanism that might account for some of TCDD's immunotoxic effects.

Characterization of mature and immature RadLV-induced thymic T-cell lines for tumorigenesis and MHC-class-I gene expression

Class-I-MHC molecules are divided into class-Ia molecules, which play major roles in recognition of virus-infected cells, graft rejection and immune responses against tumors, and class-Ib molecules, which are less polymorphic and may be responsible for presenting unique classes of peptides. Our report characterizes RadLV-induced thymic T-cell lines that differ both in their tumorigenic potential and in the level of protein for class-Ia and TL genes. The PD1.1 cell line is CD4-CD8+ and expresses relatively high levels of class-I as compared with the CD4+CD8+ PD1.2 cell line. These class-I-expression levels correlate with thymocytes and splenic T cells of the same phenotype, except that normal cells fail to express TL3b. Interferon-treated PD1.2 cells demonstrate significantly lower levels of class-I expression than do interferon-treated PD1.1 cells, and were shown to contain large amounts of degraded class-I mRNA, at least some of which was TL in origin. These RNA products were not detected in PD1.1 cells, suggesting the existence of a mechanism controlling cell-specific and gene-specific mRNA stability. Such RadLV-induced cell lines provide a means for obtaining stage-specific T cells, which can be used for studying the regulation of class-I gene expression during T-cell differentiation, as well as factors that differentially regulate class-Ia and class-Ib expression and are potentially useful for studying T-cell differentiation in general.

Structure, function, and evolution of mouse TL genes, nonclassical class I genes of the major histocompatibility complex

In contrast to well-studied "classical" class I genes of the major histocompatibility complex (MHC), the biology of nonclassical class I genes remains largely unexamined. The mouse TL genes constitute one of the best defined systems among nonclassical class I genes in the T region of the MHC. To elucidate the function and the evolution of TL genes and their relationship to classical class I genes, seven TL DNA sequences, including one from a Japanese wild mouse, were examined and compared with those of several mouse and human classical class I genes. The TL genes differ from either classical class I genes or pseudogenes in the extent and pattern of nucleotide substitutions. Natural selection appears to have operated so as to preserve the function of TL, which might have been acquired in an early stage of its evolution. In a putative peptide-binding region encoded by TL genes, the rate of nonsynonymous (amino acid replacing) substitution is considerably lower than that of synonymous substitution. This conservation is completely opposite that in classical class I genes, in which the peptide-binding region has evolved to diversify amino acid sequences so as to recognize a variety of antigens. Thus, it is suggested that the function of TL antigens is distinct from that of classical class I antigens and is related to the recognition of a relatively restricted repertoire of antigens and their presentation to T-cell receptors.

TL antigen as a transplantation antigen recognized by TL-restricted cytotoxic T cells

In contrast to broadly expressed classical class I antigens of the major histocompatibility complex, structurally closely related TL antigens are expressed in a highly restricted fashion. Unlike classical class I antigens, TL antigens are not known to be targets of cytotoxic T cells or to mediate graft rejection. Whereas classical class I antigens function as antigen-presenting molecules to T cell receptors (TCR), the role of TL is yet to be defined. To elucidate the function of TL, we have derived transgenic mice expressing TL in most tissues including skin by introducing a TL gene, T3b of C57BL/6 mouse origin, driven by the H-2Kb promoter. By grafting the skin of transgenic mice, we demonstrate that TL can serve as a transplantation antigen and mediate a TCR-alpha/beta+ CD8+ cytotoxic T cell response. This T cell recognition of TL does not require antigen presentation by H-2 molecules. Furthermore, we show that C57BL/6 F1 mice develop CD8+ T cells that are cytotoxic for C57BL/6 TL+ leukemia cells, providing further support for the concept that aberrantly expressed nonmutated proteins such as TL can be recognized as tumor antigens.

DNA-binding proteins for transcription enhancing region of HLA class I gene

Class I regulatory complex (CRC) located in the 5'-upstream region of MHC class I gene contains transcriptional enhancing sequences, called Enh A. This Enh A region contains tandem-arranged kappa B-like sites, one of which has a well-conserved perfect palindromic sequence. The second kappa B-like site, juxtaposed to the perfect palindrome, contains an imperfect palindromic sequence. In B-cell nuclear extracts, we have identified at least four sequence-specific protein complexes; three shared the repeated kappa B enhancer as their binding motifs. The perfect palindromic sequence facilities the binding of a complex termed BI, while the imperfect palindrome provides the binding sites for two other complexes, BII and BIII. The BII and BIII complexes exhibited binding crossreactivity with other kappa B-related motifs and recognized both the perfect and imperfect palindromic sequences, whereas the BI complex was specific for the perfect palindromic sequence which is unique to the class I promoters. A DNA segment outside the repeated kappa B enhancers probably binds the fourth complex, BIV. These complexes, except for the perfect palindrome-binding complex, differ from those described for the murine class I promoter. The binding characteristics of these factors suggest that the mechanism controlling the class I transcription may be quite complex.

Biochemical characterization of a pedigree with mitochondrially inherited deafness

A large kindred with a predicted 2-locus inheritance of sensorineural deafness, caused by the combination of a mitochondrial and an autosomal recessive mutation, was examined at the biochemical level. Because of the mitochondrial inheritance of this disease, we looked for defects in the oxidative phosphorylation Complexes I, III, IV, and V, the 4 enzymes that include all of the 13 mitochondrially encoded polypeptides. Biosynthetic labelling of lymphoblastoid cells from deaf patients, unaffected siblings, and an unrelated control showed no difference in size, abundance, rate of synthesis, or chloramphenicol-sensitivity of the mitochondrially encoded subunits. Since overall mitochondrial protein synthesis appears normal, these results suggest that the mitochondrial mutation is unlikely to be in a tRNA or rRNA gene. No change in enzymatic levels was seen in lymphoblastoid mitochondria of the deaf patients, compared to unaffected sibs and controls, for Complexes I and IV. Both affected and unaffected family members showed an increase in Complex III activity compared to controls, which may reflect the mitochondrial DNA shared by maternal relatives, or be due to other genetic differences. Complex V activity was increased in deaf individuals compared to their unaffected sibs. Since the family members share the presumptive mitochondrial mutation, differences between deaf and unaffected individuals likely reflect the nuclear background and suggest that the autosomal recessive mutation may be related to the increase in Complex V activity. These biochemical studies provide a guide for sequence analysis of the patients' mitochondrial DNA and for linkage studies in this kindred.

Expression of mouse Tla region class I genes in tissues enriched for gamma delta 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 gamma delta 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 gamma delta T cells. Other Tla region genes, including T1d, T2d, T16d, and T17d, are transcriptionally silent and transcripts from the T8d/T20d gene pair do not undergo proper splicing. In general, sites that contain gamma delta T lymphocytes have Tla region transcripts. The newly identified pattern of expression of the genes analyzed in sites containing gamma delta T cells further extends the list of potential candidates for antigen presentation to gamma delta T cells.

Genomic DNA sequence and organization of a TL-like gene in the grc-G/C region of the rat

Genes in the grc-G/C region, which is linked to the rat major histocompatibility complex, influence the control of growth, development, and susceptibility to chemical carcinogens. As an initial approach to analyzing the structure and organization of these genes, a class I hybridizing fragment designated RT(5.8) was isolated from an R21 genomic DNA library and sequenced from overlapping restriction enzyme fragments. The RT(5.8) clone has 5788 base pairs and contains the eight exons characteristic of a class I gene. There are CAAT and TATA boxes upstream of the signal peptide, and the recognition sequence that precedes the site of polyadenylation is located downstream from the third cytoplasmic domain. Comparison of the RT(5.8) gene with representative class I genes from the rat and other species shows that the nucleotide sequences of RT(5.8) have a high level of similarity to those of TL region genes of several strains of mice. The peptide sequence deduced from the RT(5.8) clone is distinct from all previously published class I gene sequences, and at many positions there are amino acid residues that are unique to the RT(5.8) sequence. Probes have been isolated from the third exon and from the 5' and 3' flanking regions of the RT(5.8) clone, and Southern blot analysis with genomic DNA of various rat strains shows that these probes are specific for the RT(5.8) fragment. Northern blot analysis shows that the gene is transcribed in the thymus but not in the liver or spleen. The RT(5.8) sequence is more similar to some mouse TL genes (especially in the alpha 2 and cytoplasmic domains and in the 5' and 3' untranslated regions) than it is to other rat class I genes. Hence, TL-like genes are not restricted to the mouse.

A role for the interferon response DNA sequence in directing transcription of the T18d Tla gene

T18d of BALB/c mice is a member of the Tla category of class I genes of the major histocompatibility complex of the mouse and is highly restricted in expression. Deletion analysis implies that an element essential to T18d expression resides within the region -4 to +54. The homologous region of T3d, a Tla gene which normally is not expressed in BALB/c mice, also has promoter activity. Thus the expressibility of T18d vs T3d is unlikely to be due to sequence differences in this region. A DNA-binding protein, factor VI, was found to bind to the region -33 to +54. DNase I footprinting analysis indicated that the DNA fragment 5'-ACTATAGTTTCACTTTTT-3' (+3 to +20) was protected by factor VI. This region includes the interferon response sequence (IRS). Homologous DNA segments of other class I genes, Ld and Dd, competed for factor VI in DNA-protein binding assay with lower affinity as compared with T18d. In mutation analysis, the 3' portion of the IRS is more important than the 5' portion with respect to binding affinity of factor VI and to transcriptional activity in transfected cells. This result signifies a role of IRS in T18d transcription and suggests that the mechanism of T18d transcription might be unusual.

Abnormal thymic development, impaired immune function and gamma delta T cell lymphomas in a TL transgenic mouse strain

During derivation of transgenic mouse strains with various TL and TL/H-2 chimeric genes, one strain, Tg.Tlaa-3-1, introduced with a TL gene (Tlaa-3), was found to have an abnormal thymic T cell population and to develop a high incidence of T cell lymphomas. To investigate the etiology of the thymic abnormalities and of the lymphomas, the development of lymphoid organs in transgenic mice was studied. The thymus of these mice goes through three unusual successive events: perturbation of thymic development during embryogenesis, disappearance of thymocytes between day 14 and day 21 after birth, and subsequent proliferation of large blast-like cells. These events are associated with the abolishment of T cell receptor (TCR) alpha beta lineage of the T cell differentiation, leading to preponderance of cells belonging to the TCR gamma delta L3T4-Lyt-2- double negative (DN) lineage. Bone marrow transplantation and thymic graft experiments demonstrate that the abnormality resides in the bone marrow stem cells rather than in the thymic environment. The expression of TL antigen in the transgenic mice is greatly increased and TL is expressed in a wide range of T cells, including normally TL- DN cells and L3T4+ Lyt-2- and L3T4-Lyt-2+ single positive cells. These quantitative and qualitative abnormalities in TL expression most likely cause the abnormal T cell differentiation. The gamma delta DN cells migrate into peripheral lymphoid organs and constitute nearly 50% of peripheral T cells. Immune function of the transgenic mice is severely impaired, as T cell function is defective in antibody production to sheep red blood cells, in mixed lymphocyte culture reaction to allogenic spleen cells and also in stimulation with concanavalin A. These results indicate that the gamma delta cells are incapable of participating in these reactions. Molecular and serological analysis of T cell lymphomas reveal that they belong to the gamma delta lineage, suggesting that the gamma delta DN cells in this strain are susceptible to leukemic transformation. Based on cell surface phenotype and TCR expression of the DN thymocytes and T cell lymphomas, a map of the sequential steps involved in the differentiation of gamma delta DN cells is proposed.(ABSTRACT TRUNCATED AT 400 WORDS)

Highly restricted expression of the thymus leukemia antigens on intestinal epithelial cells

The TL region of the major histocompatibility complex of the mouse contains dozens of tandemly arranged class I genes, including those encoding the thymus leukemia (TL) antigens. TL antigens have been thought to be expressed only on the surface of some T lineage cells, namely immature thymocytes of some mouse strains (TL+ strains), some leukemia cells, and activated T cells. While the function of TL antigens is unknown, recent studies have implicated the products of at least some TL region class I genes as molecules that present antigens to gamma/delta T cells. Since some gamma/delta T cells are known to be specifically associated with certain epithelial tissues, we have investigated the expression of some TL region class I genes in a variety of epithelium-containing tissues. Our results show that the TL antigen gene of C57BL/6 mice, T3b, and the TL antigen genes of BALB/c mice, T3d (previously T3c) and T18d (previously T13c), are highly expressed in the epithelium of the small intestine. In the case of T3b, we further show, using a T3 product-specific antibody, that its product is expressed on the surface of the columnar epithelial cells. In addition, we demonstrated that two other TL region class I genes of C57BL/6 origin, T9b and T21b, are also expressed nearly exclusively in intestinal epithelial cells. These results are consistent with the hypothesis that the products of these TL region class I genes are recognized by gamma/delta T cell receptors of intestinal intraepithelial lymphocytes, a subset of gamma/delta T cells that is localized in the intestinal epithelium and has a restricted V gamma repertoire. Finally, our study indicates that the relative levels of expression of the two homologous TL antigen genes, T3d and T18d, differ widely between the thymus and the intestine.

Properties of the promoter region of the T18d (T13c) Tla gene

The T18d (formerly T13c) gene of BALB/c mice belongs to the category of Tla genes which is expressed by both thymocytes and TL+ T-cell leukemias. To elucidate the regulation of T18d, different restriction fragments of the 5' flanking region between -457 and +146 were linked to the chloramphenicol acetyltransferase (CAT) gene and transfected into TL+ and TL- cells. By comparison of transiently expressed CAT activity among cells transfected with different CAT constructs, the results suggest that determination of TL+ vs TL- phenotypes is located within the region -105 to -33, and that an element essential to T18d expression resides within the region -33 to +54. Putative DNA-binding factors characterizing particular cell types and displaying selective affinity for particular T18d restriction fragments were identified by electrophoretic mobility shift assays with nuclear extracts (NEs). Two factors (or complexes) which bound specifically to the T18d fragment -105 to -33 were expressed preferentially in TL+ cells and thus may be involved in determining the tissue-selective expression of T18d. The close proximity of negative and positive cis-acting elements within the promoter region is consistent with regulation of T18d gene expression by a variety of trans-acting factors whose production is attuned to development and differentiation. The data provided may serve as a guide to study the regulation of other categories of Tla genes that are normally silent in thymocytes but may become expressed by leukemia cells.

Regulation of expression of TL genes of the mouse Mhc

The expression of thymus leukemia (TL) antigens and genes in thymocytes and activated T cells was examined by immunoprecipitation, flow cytometric, northern, and nuclear run-off transcription analyses. Cell surface forms of TL were detectable by immunoprecipitation on activated peripheral T cells from Tla haplotypes except Tla(b), in agreement with expression observed on thymocytes. Approximately 40%-50% of concanavalin A (Con A) or anti-CD3-activated T cells were TL+, with expression detected on both the CD4 and CD8 subsets by dual-color analysis. Activated T cells expressed detectable levels of TL mRNA 48 h after stimulation, but no TL transcripts were detectable in unstimulated splenocytes. However, TL mRNA expression in mature activated T cells did not precisely mimic thymocyte expression: the level of expression was considerably lower in activated T cells, and in most haplotypes the transcripts produced in activated T cells appeared to represent a subset of the transcripts produced in thymocytes. By run-off transcription assays in isolated nuclei, TL gene expression was detected in activated but not resting T cells indicating that lack of expression of TL in resting T cells is not due to message instability. These data demonstrate that TL genes are inducible and transcriptionally regulated.

Expression of the thymus leukemia antigen in mouse intestinal epithelium

The Qa and Tla regions of the mouse major histocompatibility complex contain a series of genes encoding proteins with structural similarity to the class I transplantation antigens of the same complex. In contrast to the genes encoding the transplantation antigens, the Qa and Tla genes show very little polymorphism. Function(s) of the proteins encoded by the Qa and Tla loci remain an enigma. Recently, the protein products of the Qa and Tla loci, often referred to as class Ib major histocompatibility complex molecules, have been proposed to present antigen to gamma delta T cells. In mice, gamma delta T cells have been found concentrated in several epithelial barriers and in the skin; yet, expression of serologically detectable Tla antigens is believed restricted to thymocytes, activated T lymphocytes, and some T-cell leukemias. Here we report that luminal epithelial cells of the mouse small intestine express the thymus leukemia antigen (TLA). We also find that, unlike T cells in Peyer's patches, a significant fraction of intestinal epithelial lymphocytes also express TLA. RNA prepared from intestinal cells contains transcripts of the T18d gene, which encodes TLA. These data extend the known expression profile of TLA molecules to mature lymphocytes and to nonhematopoietic cells. These data also demonstrate the specific expression of TLA on antigen-presenting cells in a site enriched for T cells that express gamma delta T-cell antigen receptor.

Differential regulation of HLA class I genes by interferon

Allele-specific differences in the regulation of HLA class I genes by type I interferon (IFN) were observed after transfection of eight HLA-B, -A, or -C genes into mouse L cells. HLA-B7 and -Bw64 gene expression was significantly more inducible by type I IFN than the genes coding for HLA-B27, HLA-B51, HLA-B38, HLA-B39, HLA-Cw3, and HLA-A2 antigens. Modification of the 5' end of HLA-B7 and HLA-B27 genes revealed the presence of enhancer sequences responding to IFN treatment in the 5' untranslated region of HLA-B7, but not of HLA-B27 and suggested further, independently acting enhancer elements downstream of the transcription initiation site. Comparison of 5' enhancer region sequences in correlation with type I IFN inducibility of the different HLA class I alleles indicated that the exchange of only two nucleotides in the interferon response sequence (IRS) or enhancer A region of HLA-B7 or -Bw64 could account for nonregulated promoters in all other HLA-A, -B, or -C alleles analyzed. Thus, type I IFN stimulation of HLA class I genes in mouse L cells appears to predominantly operate in most alleles by a mechanism targeted to enhancer sequences downstream of the gene's transcription initiation site.

Expression of TL, H-2, and chimeric H-2/TL genes in transgenic mice: abnormal thymic differentiation and T-cell lymphomas in a TL transgenic strain

To investigate the genetic regulation of TL expression, 12 transgenic mouse strains on a C3H (TL-nonexpressing) background have been derived: two Tg.Tlaa-3 strains with Tlaa-3 isolated from A-strain TL+ thymocytes, four Tg.T3b strains with T3b from a TL+ leukemia arising in a C57BL/6 (TL-) mouse, three Tg.Con.3 strains with an H-2Kb/T3b chimeric gene (construct 3,5'flanking region and exon 1 of H-2Kb and exons 2-6 of T3b), one Tg.Con.4 strain with a T3b/H-2Kb chimeric gene (construct 4, 5' flanking region and exon 1 of T3b and exons 2-8 of H-2Kb), and two Tg.H-2Kb strains with H-2Kb. Expression of the transgenes was determined by the presence of TL or H-2Kb products or transcripts. Both Tg.Tlaa-3 strains expressed high levels of TL antigen in thymus, indicating that (i) the 9.6-kilobase Tlaa-3 DNA fragment contains sufficient information for correct tissue-specific expression in thymocytes and (ii) TL- thymocytes of C3H provide conditions for the transcriptional activation of Tlaa-3. In contrast, neither the four Tg.T3b strains nor the Tg.Con.4 strain expressed transgenes, indicating that (i) T3b lacks elements necessary for TL expression in normal thymocytes and (ii) the corresponding endogenous TL genes of C3H mice also lack these elements. The pattern of TL expression in two of the three Tg.Con.3 strains was similar to that of H-2Kb expression, indicating that transcription of this H-2Kb/T3b chimeric gene was driven by the regulatory sequences of H-2Kb. The thymuses of mice derived from the Tg.Tlaa-3-1 strain were smaller than C3H thymuses, and the surface phenotype of Tg.Tlaa-3-1 thymocytes resembled thymocyte precursors (TL+L3T4-Lyt-2-Thy-1+H-2+). These mice developed a high incidence of lymphomas with the same thymocyte precursor phenotype. The study of TL transgenic strains should prove useful in defining the role of TL in normal and abnormal T-cell differentiation.