The promyelocytic leukemia gene product (PML) forms stable complexes with the retinoblastoma protein.

PML is a nuclear protein with growth-suppressive properties originally identified in the context of the PML-retinoic acid receptor alpha (RAR alpha) fusion protein of acute promyelocytic leukemia. PML localizes within distinct nuclear structures, called nuclear bodies, which are disrupted by the expression of PML-RAR alpha. We report that PML colocalizes with the nonphosphorylated fraction of the retinoblastoma protein (pRB) within nuclear bodies and that pRB is delocalized by PML-RAR alpha expression. Both PML and PML-RAR alpha form complexes with the nonphosphorylated form of pRB in vivo, and they interact with the pocket region of pRB. The regions of PML and PML-RAR alpha involved in pRB binding differ; in fact, the B boxes and the C-terminal region of PML, the latter of which is not present in PML-RAR alpha, are essential for the formation of stable complexes with pRB. Functionally, PML abolishes activation of glucocorticoid receptor-regulated transcription by pRB, whereas PML-RAR alpha further increases it. Our results suggest that PML may be part of transcription-regulatory complexes and that the oncogenic potential of the PML-RAR alpha protein may derive from the alteration of PML-regulated transcription.

Promyelocytic leukemia-specific PML-retinoic acid alpha receptor fusion protein interferes with erythroid differentiation of human erythroleukemia K562 cells.

Acute promyelocytic leukemia (APL) is characterized by a t(15;17) chromosomal translocation with breakpoints within the retinoic acid alpha receptor (RAR alpha) gene on 17 and the PML gene, which encodes a putative transcription factor, on 15. A PML-RAR alpha fusion protein is formed as a consequence of the translocation. We show here that expression of the PML-RAR alpha protein in K562 erythroleukemia cells results in a reduced expression of erythroid differentiation markers and a reduced sensitivity to the erythroid differentiative action of heme. Overexpression of RAR alpha, but not of PML, elicited a similar inhibition of K562 erythroid differentiation. These findings indicate that overexpression of either RAR alpha or PML/RAR alpha interferes with erythroid differentiation and support the hypothesis that RAR alpha is involved in the regulation of normal hematopoiesis and alteration of the RAR alpha signaling by PML/RAR alpha is implicated in the promyelocytic leukemogenesis.

PML/RAR alpha+ U937 mutant and NB4 cell lines: retinoic acid restores the monocytic differentiation response to vitamin D3.

We have analyzed the differentiation program of a U937 promonocytic leukemia clone transduced with the acute promyelocytic leukemia specific PML/RAR alpha fusion gene, the expression of which is under the control of the inducible metallothionine (MT) I promoter (MTPR9 clone). MTPR9 cells treated with Zn2+ hence exhibit levels of PML-RAR alpha protein as high as fresh acute promyelocytic leukemia blasts. In the absence of Zn2+, i.e., upon low level PML/RAR alpha expression, 1,25-dihydroxyvitamin D3 (D3) and particularly D3 plus transforming growth factor beta 1 (TGF-beta 1) induced terminal differentiation of MTPR9 cells (as observed in "wild-type" U937 cells), on the basis of morphology, membrane antigen pattern, and functional criteria. Conversely, in the presence of Zn2+, D3 and D3 plus TGF-beta 1 failed to induce terminal differentiation, as evaluated by the above parameters. Interestingly, retinoic acid (RA) treatment suppresses the differentiation blockade induced by high level PML-RAR alpha protein; indeed, Zn(2+)-treated MTPR9 cells incubated with RA plus D3 exhibited significant terminal monocytic maturation, comparable to that of cells treated with D3 alone or combined with RA in absence of Zn2+. Similar observations were made in NB4, a PML-RAR+ human acute leukemic line. As expected RA treatment of NB4 cells causes granulocytic differentiation. Interestingly, the cell line is only scarcely induced to mature monocytic cells by D3 or D3 plus TGF-beta 1 treatment, whereas it is effectively induced to monocytic maturation by combined treatment with D3 and RA. Accordingly, the rate of NB4 cell proliferation is only slightly affected by D3 or D3 plus TGF-beta 1 treatment, mildly inhibited by RA, and markedly decreased by D3 plus RA. These results indicate that in both U937 and NB4 cells high level PML/RAR alpha expression inhibits the monocytic terminal differentiation program triggered by D3 or D3 plus TGF-beta 1, whereas RA treatment effectively antagonizes this inhibitory PML-RAR alpha action and restores the D3 differentiative effect.

Interferon-beta induces S phase slowing via up-regulated expression of PML in squamous carcinoma cells.

Type I Interferon (IFN) and all-trans retinoic acid (RA) inhibit cell proliferation of squamous carcinoma cell lines (SCC). Examinations of growth-affected cell populations show that SCC lines ME-180 and SiHa treated with IFN-beta undergo a specific slower progression through the S phase that seems to trigger cellular death. In combination treatment RA potentiates IFN-beta effect in SCC ME-180 but not in SiHa cell line, partially resistant to RA antiproliferative action. RA added as single agent affects cell proliferation differently by inducing a slight G1 accumulation. The IFN-beta-induced S phase lengthening parallels the increased expression of PML, a nuclear phosphoprotein specifically up-regulated at transcriptional level by IFN, whose overexpression induces cell growth inhibition and tumor suppression. We report that PML up-regulation may account for the alteration of cell cycle progression induced by IFN-beta in SCC by infecting cells with PML-PINCO recombinant retrovirus carrying the PML-3 cDNA under the control of the 5' LTR. In fact PML overexpression reproduces the IFN-beta-induced S phase lengthening. These findings provide important insight into the mechanism of tumor suppressing function of PML and could allow PML to be included in the pathways responsible for IFN-induced cell growth suppression.

The acute promyelocytic leukaemia-associated PML gene is induced by interferon.

The PML protein concentrates within discrete nuclear structures known as nuclear bodies, also called NDs or PODs, which contain several proteins including the interferon (IFN)-inducible SP100 product. The function of these structures remains elusive. We and others have shown recently that they represent specific targets for adenovirus and herpes simplex virus. This prompted us to investigate whether PML, like SP100, might be induced by IFN and to explore the role of PML in viral infection. Here we report that PML mRNA levels increase rapidly in response to interferon treatment. This accumulation of PML transcripts is a primary IFN response since it does not require de novo protein synthesis. The IFN-induced activation of the PML gene is accompanied by enhanced protein expression as revealed by immunolabelling. Both the intensity of the staining and the number of labelled structures increased upon interferon exposure. To probe the role of PML in IFN action, we compared the antiviral state established by alpha-interferon in embryonic fibroblasts (EFs) derived from null mutant mice for PML and from wild-type control mice. The resistance to viral infection conferred by IFN-alpha was identical in both PML+/+ and PMLm/m fibroblasts indicating that PML is not an essential mediator of the antiviral effect of interferon. We also noted that DNA-binding factors are normally activated by IFN in PMLm/m cells.

Alternative splicing of PML transcripts predicts coexpression of several carboxy-terminally different protein isoforms.

The acute promyelocytic leukaemia (APL)-specific chromosome 15;17 translocation leads to the fusion of a newly identified putative transcription factor, PML, and the retinoic acid receptor alpha. We have characterized the structure of the PML genomic locus and preliminarily characterized its expression pattern. The PML locus spans a minimum of 35 kb and is subdivided into nine exons. The putative PML DNA binding site is encoded by exons 2 and 3. We isolated a large number of alternatively spliced PML transcripts that encode numerous PML isoforms. Two groups of isoforms were identified that differed either in their C-terminal region or in the length of their central region, but retained the putative DNA-binding and dimerization domains. RNAase protection experiments revealed that the different PML isoforms are equally expressed in established cell lines of different histological origin.

The acute promyelocytic leukaemia specific PML and PLZF proteins localize to adjacent and functionally distinct nuclear bodies.

Acute promyelocytic leukaemia is characterized by translocations that involve the retinoic acid receptor alpha (RAR alpha) locus on chromosome 17 and the PML locus on 15 or the PLZF locus on 11. The resulting abnormal translocation products encode for PML/RAR alpha or PLZF/RAR alpha fusion proteins. There is increasing experimental evidence that the APL-specific fusion proteins have similar biologic activities on differentiation and survival and that both components of the fusion proteins (PML or PLZF and RAR alpha) are indispensable for these biological activities. The physiologic function of PML or PLZF or whether PML and PLZF contribute common structural or functional features to the corresponding fusion proteins is not known. We report here immunofluorescence studies on the cellular localization of PLZF and PLZF/RAR alpha and compare it with the localization of PML and PML/RAR alpha. PLZF localizes to nuclear domains of 0.3-0.5 microns, approximately 14 per cell in the KG1 myeloid cell line. These PLZF-bodies are morphologically similar to the domains reported for PML (PML-NBs). There is tight spatial relationship between about 30% of PLZ-NBs and PML-NBs: they partially overlap. However, PML and PLZF do not form soluble complexes in vivo. PLZF- and PML-NBs are functionally distinct. Adenovirus E4-ORF3 protein expression alters the structure of the PML-NBs and interferon increases the number of PML-NBs and neither has any effect on PLZF NBs. The localization of PLZF/RAR alpha is different to that of PLZF and RAR alpha. The nuclear distribution pattern of PLZF/RAR alpha is one of hundreds of small dots (microspeckles) less than 0.1 micron. Expression of PLZF/RAR alpha did not provoke disruption of the PML-NBs. Co-expression of PML/RAR alpha and PLZF/RAR alpha in U937 cells revealed apparent colocalization. Overall the results suggest that the PML- and PLZF-NBs are distinct functional nuclear domains, but that they may share common regulatory pathways and/or targeting sequences, as revealed by the common localization of their corresponding fusion proteins.

Cooperation between the RING + B1-B2 and coiled-coil domains of PML is necessary for its effects on cell survival.

PML/RARalpha is the abnormal protein product of the Acute Promyelocytic Leukemia-specific 15;17 translocation. Both the PML and RARalpha components are required for the PML/RARalpha biological activities, namely its capacity to block differentiation and to increase survival of haematopoietic precursors. The physiological role of PML and its contribution to the function of the fusion protein are unknown. PML localizes to the cytoplasm and within specific nuclear bodies (NBs). In vitro, overexpression of PML correlates with suppression of cell transformation. The PML aminoterminal portion retained within the PML/RARalpha protein contains the RING finger, two newly defined cystein/histidine-rich motifs called B-boxes (B1 and B2) and a coiled-coil region. We report here that PML has a growth suppressive activity in all the cell lines tested, regardless of their transformed phenotype, and that the cellular basis for the PML growth suppression is induction of apoptotic cell death. Analysis of various nuclear and cytoplasmic PML isoforms showed that the PML growth suppressive activity correlates with its nuclear localization. Analysis of the localization and growth suppressive activity demonstrated that: (i) the Ring + B1-B2 and coiled-coil regions are both indispensable and sufficient to target PML to the NBs; (ii) individual deletions of the various PML domains have no effect on its growth suppressor activity; (iii) the Ring + B1-B2 region exerts a partial growth suppressor activity but its fusion with the coiled-coil region is sufficient to recapitulate the suppressive function of wild type PML. These results indicate that PML is involved in cell survival regulation and that the PML component of the fusion protein (Ring + B1-B2 and coiled-coil regions) retains intact biological activity, thereby suggesting that the effects of PML/RARalpha on survival derive from the activation of the incorporated PML sequence.

Common themes in the pathogenesis of acute myeloid leukemia.

The pathogenesis of acute myeloid leukemia is associated with the appearance of oncogenic fusion proteins generated as a consequence of specific chromosome translocations. Of the two components of each fusion protein, one is generally a transcription factor, whereas the other partner is more variable in function, but often involved in the control of cell survival and apoptosis. As a consequence, AML-associated fusion proteins function as aberrant transcriptional regulators that interfere with the process of myeloid differentiation, determine a stage-specific arrest of maturation and enhance cell survival in a cell-type specific manner. The abnormal regulation of transcriptional networks occurs through common mechanisms that include recruitment of aberrant co-repressor complexes, alterations in chromatin remodeling, and disruption of specific subnuclear compartments. The identification and analysis of common and specific target genes regulated by AML fusion proteins will be of fundamental importance for the full understanding of acute myeloid leukemogenesis and for the implementation of disease-specific drug design.

Effect of the acute promyelocytic leukemia PML/RAR alpha protein on differentiation and survival of myeloid precursors.

Acute promyelocytic leukaemia is characterized by an expansion of haematopoietic precursors arrested at the promyelocytic stage (1). The differentiation block can be reversed by retinoic acid, which induces blast differentiation both in vitro (2) and in vivo (3-4). Acute promyelocytic leukaemia is also characterized by a 15;17 chromosome translocation (5) with breakpoints within the retinoic acid alpha receptor (RAR alpha) gene on 17 and within the PML gene, that encodes a putative transcription factor of unknown function (6-7), on 15 (8-10). As a consequence of the translocation a PML/RAR alpha gene is formed. It is transcriptionally active and encodes a PML/RAR alpha fusion protein detectable in all APL cases (11-14). We expressed the PML/RAR alpha protein in U937 myeloid precursor cell line and show that they: 1) lose the capacity to differentiate under the action of different stimuli (vitamin D3, transforming growth factor beta 1); ii) acquire enhanced sensitivity to retinoic acid; iii) exhibit a higher growth rate that is due to a reduction in apoptotic cell death. These results provide the first evidence of biological activity of PML/RAR alpha and recapitulate critical features of the promyelocytic leukemia phenotype.

Nuclear factor-erythroid 2 (NF-E2) expression in normal and malignant megakaryocytopoiesis.

Although the transcription factor nuclear factor-erythroid 2 (NF-E2) is known to be functionally linked to the megakaryocytic lineage, little is known about its role in malignant megakaryocytes. We used real-time RT-PCR and Western blotting to investigate expression of NF-E2 and its partner, MafG, in CD34-derived normal (five cases) and malignant megakaryocytes from essential thrombocythemia (ET) patients (eight cases) and in megakaryoblastic cell lines. We also quantitated the mRNA of the thromboxane synthase (TXS) gene, which is directly regulated by NF-E2. Although real-time RT-PCR showed that both a and f NF-E2 isoforms were significantly reduced with respect to the normal counterpart both in ET megakaryocytes and in cell lines (P < or = 0.01), western blotting revealed decreased NF-E2 protein expression only in the latter. However, both the NF-E2a/MafG mRNA ratio (P < or = 0.01) and TXS (P< or = 0.01) mRNA expression were significantly reduced in megakaryocytes from ET patients and cell lines with respect to healthy subjects. These two findings provide strong indirect evidence of altered activity of the a isoform of NF-E2 in malignant megakaryocytes, raising the possibility that NF-E2 could play a role in megakaryocyte transformation.

The molecular genetics of acute promyelocytic leukemia.

The chromosome breakpoints of the acute promyelocytic leukemia (APL)-specific 15;17 translocation have recently been isolated. They are localized on a previously unknown gene, PML, on chromosome 15 and in the gene that encodes the alpha retinoic acid receptor (RAR alpha) on 17. The translocation, which is balanced and reciprocal, leads to the formation of two fusion genes, PML/RAR alpha and RAR alpha/PML. Both are expressed in APL. The PML/RAR alpha gene codes for two abnormal proteins: the PML/RAR alpha fusion protein and an abnormal PML protein, the RAR alpha/PML gene encodes the RAR alpha/PML fusion protein. Experiments to investigate the biological activity of the abnormal translocation products are in progress. Preliminary results suggest that the PML/RAR alpha fusion protein is responsible for two important properties of the APL phenotype: the differentiation block characteristic of the leukemic blasts and the high sensitivity of the blasts to the differentiative action of retinoic acid (RA) both in vivo and in vitro. The mechanism through which PML/RAR alpha exerts its biological function remains unknown. However, there is accumulating evidence that it acts by interfering with normal endogenous pathways of both RAR alpha and PML. The RAR alpha receptor is implicated in regulating the myeloid differentiation induced by RA. Although the physiological function of PML is not known, it is probably a transcription factor. Definition of the molecular architecture of the t(15;17) has furnished further tools for: (1) molecular diagnosis of APL and (2) highly sensitive evaluation of the neoplastic clone during antileukaemic therapy. The molecular identification of residual APL disease after anti-leukaemia therapy allows patients at risk of relapse to be identified.

Evolutionary conservation in various mammalian species of the human proliferation-associated epitope recognized by the Ki-67 monoclonal antibody.

The human proliferation-associated epitope recognized by the Ki-67 monoclonal antibody (MAb) was detected in proliferating normal and neoplastic cells of many mammalian species (lamb, calf, dog, rabbit, rat) besides human. In contrast, Ki-67 stained proliferating cells from other species weakly (mouse) or not at all (swine, cat, chicken, pigeon). The immunostaining pattern of Ki-67 in animal tissues was identical to that previously described in human: Ki-67 reacted only with cells known to proliferate (e.g., germinal center cells, cortical thymocytes) but not with resting cells (e.g., hepatocytes, brain cells, renal cells); this MAb produced a characteristic nuclear staining pattern (e.g., stronger labeling of nucleoli than of the rest of the nuclei and staining of chromosomes in mitotic figures); and Ki-67 crossreacted with the squamous epithelium in both animal and human tissues. In vitro studies showed that when quiescent (Ki-67-negative) NIH 3T3 fibroblasts or bovine peripheral blood lymphocytes were induced to proliferate, the appearance of Ki-67-positive cells paralleled the induction of cell proliferation caused by addition of fetal calf serum or PHA, respectively, to the cultures, and in both human and rat proliferating cells the Ki-67 expression closely paralleled the incorporation of [3H]-thymidine. These findings indicate that the epitope recognized by the Ki-67 MAb in human and animal species is the same. The widespread evolutionary conservation of the human proliferation-associated epitope recognized by the Ki-67 MAb suggests that it and/or its carrier molecule may play an important role in regulation of cell proliferation.

Molecular studies on LAK cells.

We have developed a culture system for long-term growth of human LAK cells exhibiting an elevated, wide-spectrum anti-tumor cytotoxicity. The phenotypic and molecular properties of the final LAK cell populations indicated that they consist of three main types: a) NK-like lymphocytes (type I): NKH-1+, Ti alpha/beta-, Ti gamma/delta-, CD3-lymphocytes carrying the germline configuration of all TCR genes and expressing variable amount of the 1.0 beta mRNA and variably sized T delta transcripts; b) gamma/delta-like T lymphocytes (type II) NKH-1+, Ti alpha/beta-, Ti gamma/delta+, CD3+ lymphocytes carrying polyclonal rearrangements of the gamma and delta genes and expressing high levels of mature gamma and delta transcripts; c) alpha/beta-like T lymphocytes (type III): NKH-1+, Ti alpha/beta+, Ti gamma/delta-, CD3+ lymphocytes carrying rearrangements of all TCR genes and expressing high levels of mature alpha and beta transcripts. We took advantage of the high number of available LAK cells to clarify: 1) the origin of the NK-LAK delta transcripts. delta gene expression in LGL, NK clones and type I LAK cultures revealed six delta transcripts (3.5, 3.1, 2.2, 2.0, 1.5 and 1.3 kb), which varied in number and relative abundance in the different samples. None of the six known V delta was expressed and the delta locus was retained in its germline configuration suggesting that the delta expression is due to a partially rearranged or germline transcripts; 2) the origin of the NK-LAK truncated T beta transcript. We isolated two different clone types from a type I LAK cell cDNA library: a) J-C clones consisting of one of three J beta regions and the corresponding C beta 1 or C beta 2 regions; b) X-J-C and C-X clones, containing as yet unidentified (X) sequences. The presence of RSSs in J-C clones suggests that they derive from mRNAs transcribed from a promoter in the 5'J. Nucleotide analysis demonstrated that only one of the isolated clones had the potential to code a short T beta protein.

Three functional subdomains of the Escherichia coli FtsQ protein are involved in its interaction with the other division proteins.

FtsQ, an essential protein for the Escherichia coli divisome assembly, is able to interact with various division proteins, namely FtsI, FtsL, FtsN, FtsB and FtsW. In this paper, the FtsQ domains involved in these interactions were identified by two-hybrid assays and co-immunoprecipitations. Progressive deletions of the ftsQ gene suggested that the FtsQ self-interaction and its interactions with the other proteins are localized in three periplasmic subdomains: (i) residues 50-135 constitute one of the sites involved in FtsQ, FtsI and FtsN interaction, and this site is also responsible for FtsW interaction; (ii) the FtsB interaction is localized between residues 136 and 202; and (iii) the FtsL interaction is localized at the very C-terminal extremity. In this third region, the interaction site for FtsK and also the second site for FtsQ, FtsI, FtsN interactions are located. As far as FtsW is concerned, this protein interacts with the fragment of the FtsQ periplasmic domain that spans residues 67-75. In addition, two protein subdomains, one constituted by residues 1-135 and the other from 136 to the end, are both able to complement an ftsQ null mutant. Finally, the unexpected finding that an E. coli ftsQ null mutant can be complemented, at least transiently, by the Streptococcus pneumoniae divIB/ftsQ gene product suggests a new strategy for investigating the biological significance of protein-protein interactions.

Use of a two-hybrid assay to study the assembly of a complex multicomponent protein machinery: bacterial septosome differentiation.

The ability of each of the nine Escherichia coli division proteins (FtsZ, FtsA, ZipA, FtsK, FtsQ, FtsL, FtsW, FtsI, FtsN) to interact with itself and with each of the remaining eight proteins was studied in 43 possible combinations of protein pairs by the two-hybrid system previously developed by the authors' group. Once the presumed interactions between the division proteins were determined, a model showing their temporal sequence of assembly was developed. This model agrees with that developed by other authors, based on the co-localization sequence in the septum of the division proteins fused with GFP. In addition, this paper shows that the authors' assay, which has already proved to be very versatile in the study of prokaryotic and eukaryotic protein interaction, is also a powerful instrument for an in vivo study of the interaction and assembly of proteins, as in the case of septum division formation.

Cell death induction by the acute promyelocytic leukemia-specific PML/RARalpha fusion protein.

PML/RARalpha is the abnormal protein product generated by the acute promyelocytic leukemia-specific t(15;17). Expression of PML/RARalpha in hematopoietic precursor cell lines induces block of differentiation and promotes survival. We report here that PML/RARalpha has a potent growth inhibitory effect on all nonhematopoietic cell lines and on the majority of the hematopoietic cell lines tested. Inducible expression of PML/RARalpha in fibroblasts demonstrated that the basis for the growth suppression is induction of cell death. Deletion of relevant promyelocytic leukemia (PML) and retinoic acid receptor (RARalpha) domains within the fusion protein revealed that its growth inhibitory effect depends on the integrity of the PML aminoterminal region (RING, B1, B2, and coiled coil regions) and the RARalpha DNA binding region. Analysis of the nuclear localization of the same PML/RARalpha deletion mutants by immunofluorescence and cell fractionation revealed that the biological activity of the fusion protein correlates with its microspeckled localization and its association to the nuclear matrix. The PML aminoterminal region, but not the RARalpha zinc fingers, is required for the proper nuclear localization of PML/RARalpha. We propose that the matrix-associated microspeckles are the active sites of PML/RARalpha and that targeting of RARalpha sequences to this specific nuclear subdomain through PML sequences is crucial to the activity of the fusion protein on survival regulation.

Expression of the intestinal T-lymphocyte associated molecule HML-1: analysis of 75 non-Hodgkin's lymphomas and description of the first HML-1 positive T-lymphoblastic tumour.

The expression of the gut intra-epithelial T-cell associated molecule HML-1, a trimeric protein of 150, 125, 105 kD, was studied in 75 T-cell lymphomas of different subtypes: 20 T-lymphoblastic lymphomas/leukaemias; 50 nodal peripheral T-cell lymphomas; and five intestinal T-cell lymphomas. Our results confirm: (i) the usefulness of the HML-1 monoclonal antibody as an immunohistochemical marker for intestinal T-cell lymphomas: and (ii) the lack of reactivity of HML-1 with nodal peripheral T-cell lymphomas. Moreover, expression of the HML-1 molecule was found for the first time in a case of T-lymphoblastic lymphoma/leukaemia. The patient presented with a mediastinal mass which consisted of HML-1 + neoplastic cells displaying a phenotypic profile consistent with early thymocytes. Genes coding for the alpha, beta, gamma and delta chains of the T-cell receptor were in a germline configuration. The neoplastic cells could have been derived from the small subset of HML-1 + thymocytes detectable in the cortex of normal human thymus.

Distribution of T cells bearing different forms of the T cell receptor gamma/delta in normal and pathological human tissues.

Frozen sections from normal and pathologic human tissues were immunostained by the APAAP technique with three mAb directed against different epitopes of the TCR gamma delta; TCR delta 1 which binds to all cells bearing the TCR gamma delta; BB3 and delta TCS1 which, by immunoprecipitation studies, appear to react respectively with the disulfide-linked and nondisulfide-linked form of the TCR gamma delta. In normal thymus, TCR delta 1+ cells accounted for approximately 2% of the CD3+ thymocytes and were about three times more numerous in the medulla than in the cortex. TCR delta 1+ cells were mostly constituted by the delta TCS1 reactive subset (average ratio delta TCS1/BB3: 3.7). In the tonsil, the TCR delta 1+ cells (about 3% of CD3+ elements) were mainly located in the interfollicular area, where they frequently tended to arrange around high endothelium venules. In most samples, TCR delta 1+ cells were distributed beneath to the tonsil epithelium. Unlike thymus, the majority of TCR delta 1+ cells were usually constituted by the BB3-reactive subset (average BB3/delta TCS1 ratio: 2.0). A similar predominance of BB3+ over delta TCS1+ cells was also observed in normal peripheral blood. The spleen was the organ with the highest concentration of TCR delta 1+ cells that, like in the thymus, were mostly represented by delta TCS1+ elements. Noteworthy, the TCR delta 1+ cells were preferentially located in the splenic sinusoids while TCR alpha beta-bearing lymphocytes mostly occupied the periarteriolar sheaths of penicilliary arteries. The majority of neoplastic T cell proliferations studied lacked to express the TCR gamma delta. Two cases of beta F1-(TCR alpha beta-) T lymphoblastic lymphoma, however, were TCR gamma delta+ (delta TCS1+/BB3-). Both of them showed a stage II cortical phenotype, e.g., CD1+/CD3+/CD4+/CD8+/TCR delta 1+. Among inflammatory conditions, an increase of BB3+ cells was observed in close association with necrotic areas in cases of Kikuchi's and tuberculous lymphadenitis. The significance of this finding is under study.