The proto-oncogene bcl-3 encodes an I kappa B protein

The bcl-3 gene product, overexpressed in chronic lymphocytic leukemia (CLL) patients with the translocation t(14;19), is a member of the I kappa B family. The bcl-3 protein is able to inhibit the DNA binding and trans-activation of authentic NF-kappa B heterodimers p50-p65 and p49-p65, as well as p50 and p49 homodimers. The bcl-3 protein does not inhibit either the DNA-binding activity of the Rel protein or its ability to trans-activate genes linked to the kappa B site. A human 37-kD protein (I kappa B alpha), identified previously as a member of the I kappa B family, is also unable to inhibit DNA-binding activity of the Rel protein. However, unlike bcl-3, the 37-kD (I kappa B alpha) protein has no effect on the DNA-binding activity of p50 or p49 homodimers. Two dimensional phosphotryptic peptide maps of the human bcl-3 and the human 37-kD (I kappa B alpha) proteins reveal that the phosphopeptides from the 37-kD (I kappa B alpha) protein are nested within the bcl-3 protein. Furthermore, bcl-3 antisera immunoprecipitates an in vitro-radiolabeled 37-kD (I kappa B alpha) protein. Proteins of 56 and 38 kD can be identified in HeLa cells stimulated with PMA and immunoprecipitated with bcl-3 antisera. Comparison of tryptic peptide maps of the bcl-3 protein synthesized in vitro, and p56 and p38 from HeLa cells, shows that they are all structurally related. Removal of the amino-terminal sequences of the bcl-3 protein generates a protein that inhibits the DNA binding of the p50-p65 heterodimer but, like the 37-kD (I kappa B alpha) protein, is no longer able to inhibit the binding of the p50 and p49 homodimers with kappa B DNA. We propose that the bcl-3 and 37-kD (I kappa B alpha) proteins are related and are members of the I kappa B family.

An inducible transcription factor activates expression of human immunodeficiency virus in T cells

Human immunodeficiency virus (HIV) production from latently infected T lymphocytes can be induced with compounds that activate the cells to secrete lymphokines. The elements in the HIV genome which control activation are not known but expression might be regulated through a variety of DNA elements. The cis-acting control elements of the viral genome are enhancer and promoter regions. The virus also encodes trans-acting factors specified by the tat-III and art genes. We have examined whether products specific to activated T cells might stimulate viral transcription by binding to regions on viral DNA. Activation of T cells, which increases HIV expression up to 50-fold, correlated with induction of a DNA binding protein indistinguishable from a recognized transcription factor, called NF-kappa B, with binding sites in the viral enhancer. Mutation of these binding sites abolished inducibility. That NF-kappa B acts in synergy with the viral tat-III gene product to enhance HIV expression in T cells may have implications for the pathogenesis of AIDS (acquired immune deficiency syndrome).

Abelson virus abrogation of interleukin-3 dependence in a lymphoid cell line

Among several tyrosine-protein kinases, only v-abl could abrogate interleukin 3 dependence of a lymphoblastoid cell line; v-src and v-fps proteins gave partial or no interleukin 3 independence, respectively. Lymphokine independence was achieved via a nonautocrine mechanism. Direct involvement of c-myc in this process was not evident.

Biochemical and phenotypic characterization of human basophilic cells derived from dispersed fetal liver with murine T cell factors

Metachromatically granulated cells were generated from human fetal liver stem cells cultured in heterologous mouse conditioned medium rich in interleukin 3. After 2 to 3 wk of culture with biweekly changes of medium and selection of nonadherent cells, all cells present in five cultures had cytoplasmic granules, and 60 to 95% of the cells stained metachromatically with toluidine blue or with alcian blue but not with the safranin counterstain. Ultrastructurally, many granules contained fibrillar material or electron-dense cores with fibrils and vesicular fragments. In addition, the granules of many cells were filled with electron-dense material, which in some cases had a fine structure consisting of concentric whorls or a reticular pattern. Analysis of high-affinity IgE receptors on the cultured cells by flow cytometry demonstrated a unimodal fluorescence pattern, suggesting that most cells were in the basophil or mast cell lineage. The cultured cells lacked the lymphoid cell surface determinants B1, B4, T3, and T11, the myeloid determinants Mo2 and MY9, the natural killer cell determinant 901, and Ia histocompatibility antigens, but expressed the myeloid determinant MY7. The cells contained 52 ng/10(6) cells of histamine and incorporated [35S]sulfate at an average rate of 31,300 cpm/10(6) cells/4 hr into 175,000 m.w. chondroitin sulfate A proteoglycans. Upon activation with 1 microM calcium ionophore A23187, the cultured cells released 53% of their cell-associated histamine and metabolized arachidonic acid to 15.0 ng/10(6) cells of immunoreactive leukotriene C4 equivalents, 0.5 ng/10(6) cells of leukotriene B4, and 3.1 ng/10(6) cells of prostaglandin D2 (means, n = 3). Thus, stem cells present in human fetal liver give rise, as do stem cells in mouse fetal liver, to metachromatically granulated cells when cultured in the presence of mouse interleukin 3. In both species, the cultured cells bear IgE receptors, lack characteristic lymphoid and most myeloid cell surface determinants, and contain histamine and chondroitin sulfate proteoglycans. The human fetal liver-derived cells are similar in morphology and T cell factor dependence to basophil-like cells derived from umbilical cord blood, but are novel in their capacity to generate leukotrienes and prostaglandin D2.

Biochemical and phenotypic characterization of human basophilic cells derived from dispersed fetal liver with murine T cell factors

Metachromatically granulated cells were generated from human fetal liver stem cells cultured in heterologous mouse conditioned medium rich in interleukin 3. After 2 to 3 wk of culture with biweekly changes of medium and selection of nonadherent cells, all cells present in five cultures had cytoplasmic granules, and 60 to 95% of the cells stained metachromatically with toluidine blue or with alcian blue but not with the safranin counterstain. Ultrastructurally, many granules contained fibrillar material or electron-dense cores with fibrils and vesicular fragments. In addition, the granules of many cells were filled with electron-dense material, which in some cases had a fine structure consisting of concentric whorls or a reticular pattern. Analysis of high-affinity IgE receptors on the cultured cells by flow cytometry demonstrated a unimodal fluorescence pattern, suggesting that most cells were in the basophil or mast cell lineage. The cultured cells lacked the lymphoid cell surface determinants B1, B4, T3, and T11, the myeloid determinants Mo2 and MY9, the natural killer cell determinant 901, and Ia histocompatibility antigens, but expressed the myeloid determinant MY7. The cells contained 52 ng/10(6) cells of histamine and incorporated [35S]sulfate at an average rate of 31,300 cpm/10(6) cells/4 hr into 175,000 m.w. chondroitin sulfate A proteoglycans. Upon activation with 1 microM calcium ionophore A23187, the cultured cells released 53% of their cell-associated histamine and metabolized arachidonic acid to 15.0 ng/10(6) cells of immunoreactive leukotriene C4 equivalents, 0.5 ng/10(6) cells of leukotriene B4, and 3.1 ng/10(6) cells of prostaglandin D2 (means, n = 3). Thus, stem cells present in human fetal liver give rise, as do stem cells in mouse fetal liver, to metachromatically granulated cells when cultured in the presence of mouse interleukin 3. In both species, the cultured cells bear IgE receptors, lack characteristic lymphoid and most myeloid cell surface determinants, and contain histamine and chondroitin sulfate proteoglycans. The human fetal liver-derived cells are similar in morphology and T cell factor dependence to basophil-like cells derived from umbilical cord blood, but are novel in their capacity to generate leukotrienes and prostaglandin D2.

Cloned mouse mast cells derived from immunized lymph node cells and from foetal liver cells exhibit characteristics of bone marrow-derived mast cells containing chondroitin sulphate E proteoglycan

Cloned mouse mast cells which were T cell growth-dependent were derived both from immunized lymph node and from foetal liver, and were found to be morphologically and biochemically similar to mast cells previously differentiated in vitro from mouse bone marrow (BMMC). These two T cell growth-dependent mouse mast cell clones were identical to the BMMC in their preferential synthesis of chondroitin sulphate E proteoglycan rather than heparin proteoglycan. The hydrodynamic size of the cell-associated proteoglycan from each of the three mast cell sources was 150,000-250,000 mol. wt.; and that of the covalently bound glycosaminoglycans was 13,000-25,000 mol. wt. Chondroitinase ABC digestion of the [35S]proteoglycans from both cloned mast cells, as well as the BMMC, yielded only two disaccharides which comigrated on ascending thin layer chromatography with delta Di-4S and delta Di-diSE standards, respectively. Quantification of the radioactivity in the enzyme digests revealed that one-sixth to one-half of the resulting disaccharides were disulphated, similar to that found in BMMC containing chondroitin sulphate E. When sensitized with monoclonal IgE, washed, and subsequently challenged with specific antigen, each of the two cloned mast cells generated more than 100 ng of leukotriene C4 (LTC4)/10(6) cells, but only 3-12 ng leukotriene B4 (LTB4)/10(6) cells, characteristics also observed for the BMMC. Based upon these observations, it is concluded that the cloned mast cells from lymph node and liver and the bone marrow-derived mast cell belong to a distinct subclass of mast cells. These mast cells have been designated E-mast cells (E-MC) in order to distinguish them from heparin-containing mast cells (H-MC).

Isolation and characterization of a mouse cDNA clone that expresses mast-cell growth-factor activity in monkey cells

A cDNA sequence coding for mouse mast-cell growth-factor (MCGF) has been cloned from a cDNA library prepared from mRNA derived from a concanavalin A-activated mouse T-cell clone. Cloning was achieved using the pcD vector that permits expression of cDNA inserts in mammalian cells. The DNA sequence codes for a polypeptide of 166 amino acid residues including a putative signal peptide. The supernatant fluid obtained after transfection of COS-7 monkey cells with the pcD-MCGF plasmid had mouse MCGF activity. The MCGF amino acid sequence between amino acids 33 and 41, deduced from the nucleotide sequence of its cDNA, is identical to the NH2-terminal sequence of the mouse lymphokine, interleukin 3, suggesting that MCGF is related to interleukin 3.

Interleukin 3-dependent hematopoietic progenitor cell lines

Several biological phenotypes of growth factor-dependent cell lines have been described in recent years, including those with T lymphocyte, neutrophil granulocyte, basophil/mast cell, B lymphocyte, and multipotential stem cell properties. The growth factors for each cell lineage are a subject of intense study. Continuous mouse bone marrow cultures infected with RNA type C viruses (retroviruses) produce nonadherent hematopoietic cells over a longer duration than control cultures. Marrow cultures derived from strains with spontaneously induced ecotropic endogenous retrovirus demonstrate a greater longevity than those from strains with no replicating virus. Cultures infected with murine leukemia virus also generate a greater number, compared with controls, of cloned permanent suspension cell lines dependent for growth on a 41,000-dalton glycoprotein (interleukin 3 [IL 3]). Some are multipotential with capacity for differentiation to erythroid, neutrophil, eosinophil, and basophil/mast cell types. Other cloned IL 3-dependent cell lines are committed to a single pathway. Studies with Friend spleen focus-forming virus indicate that the first effect in the marrow culture is mediated through a subset of adherent hematopoietic stem cells. Bone marrow culture-derived IL 3-dependent cell lines provide a model with which to study the role of viral genes in the control of differentiation and self-renewal capacity of hematopoietic stem cells.

Cloned mouse cells with natural killer function and cloned suppressor T cells express ultrastructural and biochemical features not shared by cloned inducer T cells

We have examined the morphology, cytochemistry, and biochemistry of mouse leukocyte subsets by analyzing cloned leukocyte populations specialized to perform different immunologic functions. Cloned cells expressing high-affinity plasma membrane receptors for IgE and mediating natural killer (NK) lysis and cloned antigen-specific suppressor T cells contained prominent osmiophilic cytoplasmic granules similar by ultrastructure to those of mouse basophils. Both clones also incorporated 35SO4 into granule-associated sulfated glycosaminoglycans, expressed a characteristic ultrastructural pattern of nonspecific esterase activity, incorporated exogenous [3H]5-hydroxytryptamine, and contained cytoplasmic deposits of particulate glycogen. By contrast, cloned inducer T cells lacked cytoplasmic granules and glycogen, incorporated neither 35SO4 nor [3H]5-hydroxytryptamine, and differed from the other clones in pattern of nonspecific esterase activity. These findings establish that certain cloned cells with NK activity and cloned suppressor T cells express morphologic and biochemical characteristics heretofore associated with basophilic granulocytes. However, these clones differ in surface glycoprotein expression and immunologic function, and the full extent of the similarities and differences among these populations and basophils remains to be determined.

Mast cell clones: a model for the analysis of cellular maturation

Cloned mouse mast cells resemble, by ultrastructure, immature mast cells observed in vivo. These mast cell clones can be grown in the absence of any other cells, facilitating direct investigations of their biochemistry and function. We find that cloned mast cells express plasma membrane receptors (Fc epsilon R) that bind mouse IgE with an equilibrium constant (KA) similar to that of normal mouse peritoneal mast cells. In addition, cloned mast cells do not display detectable la antigens and cannot enhance lg secretion when added to lymphocyte cultures or mediate natural killer lysis. In the presence of 1 mM sodium butyrate, cloned mast cells stop dividing and acquire abundant electron-dense cytoplasmic granules similar to those of mature mast cells. Their histamine content increases concomitant with cytoplasmic granule maturation and may exceed that of untreated mast cells by 50-fold. Unlike peritoneal mast cells, cloned mast cells incorporate 35SO4 into chondroitin sulfates rather than heparin. These findings demonstrate that, unlike fully differentiated mouse peritoneal mast cells, cloned immature mouse mast cells contain no heparin and low levels of histamine. In addition, they establish that high-affinity Fc epsilon R are expressed early in mast cell maturation, well before completion of cytoplasmic granule synthesis and mediator storage.

Proteins synthesized by inducer T cells: evidence for a mitogenic peptide shared by inducer molecules that stimulate different cell types

Inducer T lymphocytes synthesize and secrete peptides that stimulate growth and differentiation of many cell types, including lymphocytes and monocytes that kill foreign organisms, B lymphocytes, mast cells and hematopoietic precursor cells. To define these inducer molecules more precisely, we have generated clones of these T cells as a source of homogeneous material for biochemical analysis. These clones synthesize peptides that stimulate T and B cells to divide and that also induce the latter cells to secrete immunoglobulin. Inducer cells synthesize a 14 kilodalton growth polypeptide that stimulates T and B lymphocytes, as well as other cell types, to divide. This 14 kilodalton peptide is normally associated with different, larger peptides that appear to focus its mitogenic activity to one or another target cell.

A cloned cell line mediating natural killer cell function inhibits immunoglobulin secretion

We previously described a cloned cell line that combines information for a unique display of cell surface antigens and specialized function similar to activated natural killer (NK) cells. In addition to conventional cellular targets such as the YAC-1 and MBL-2 lymphomas, this cloned line also lysed lipopolysaccharide-activated B lymphocytes. To determine whether some NK cells can inhibit B cell function, we tested the ability of NK-like clones to suppress Ig secretion in vitro and in vivo. These cloned cells suppressed Ig secretion when they constituted as few as 0.2% of the total cell population and inhibition did not require identity at the H-2 locus. We suggest that some NK cells might recognize non-major histocompatibility complex gene products on activated B lymphocytes and lyse these cells, and this might represent a fundamental cell-cell interaction that regulates antibody secretion by activated B cells.

A cloned cell with NK function resembles basophils by ultrastructure and expresses IgE receptors

Natural killer (NK) cells are defined by their ability to lyse certain tumour cells in vitro without previous exposure to them, and have been postulated as effectors of immune surveillance against spontaneous neoplasms. Because they kill some non-neoplastic lymphoid cells, they may also have a role in immunoregulation. NK cell activity resides in a small proportion of normal mouse spleen cells (less than 5%) that have been difficult to characterize completely. They may represent a heterogeneous group of effector cells whose precise relationship to other myelopoietic or immunological cells has remained obscure. We have previously described a cloned mouse cell line (Cl. Ly 1-2-NK-1+/11) with the functional characteristics of natural killer cells activated by interferon or other factors. We now find that this cloned line, like basophils and mast cells, expresses high-affinity plasma membrane receptors (Fc epsilon R) specific for IgE antibody. In addition, the clone contains cytoplasmic granules similar by ultrastructure to those of basophils of the mouse and other species. Our findings indicate that cells sharing morphological and biochemical features of basophilic granulocytes can mediate NK lysis.

Multiple activities of a cloned cell line mediating natural killer cell function

A special class of immunologic cells can lyse or damage a variety of target cells, notably malignant cells in vitro. These cells have been called natural killer (NK) cells because lysis does not require deliberate immunization by tumor cells. Although these cells can be distinguished from conventional T cells, B cells, and phagocytic cells, they have been difficult to define. We describe a representative cloned cell line that was obtained by cloning Ig -Ly-5+ cells from spleen. This clone, Cl.Ly-1-2-NK-1+/11, displays Thy-1, Ly-5, Qat-4, Qat-5 and NK-1 cell surface antigens and lyses the NK-sensitive YAC-1 lymphoma cells, but does not lyse RL-12 cells, an NK-resistant lymphoma. In addition, this clone lysed the P815 mastocytoma, EL4 lymphoma, and lipopolysaccharide-activated B lymphocyte targets. This cloned population therefore combined information for a unique display of cell surface antigens and specialized function similar to "activated" NK cells. Because this cloned population forms conjugates with susceptible but not resistant target cells, it may prove useful to identify the structure of cell surface molecules that recognize foreign cells. Finally, cells of this clone also specificity lysed target cells coated by antibodies to determinants on the target cell surface, demonstrating that a single cloned cell population can mediate two specialized immunologic functions: antibody-dependent cellular cytotoxicity and NK cell lysis.

Antigen-specific T lymphocyte clones. II. Purification and biological characterization of an antigen-specific suppressive protein synthesized by cloned T cells

We have generated an antigen-specific T suppressor clone that synthesizes 70,000-mol wt peptides that have antigen-specific-binding activity. Although these data also indicated that antigen-binding peptides completely inhibited the in vitro primary response to a complex antigen, suppression might reflect the combined biologic activities of many different 70-mol wt polypeptides or polypeptides associated with the 70,000-mol wt material by noncovalent interactions. The protein responsible for antigen-specific suppression was therefore purified to virtual homogeneity after sequential separation of internally labeled supernate peptides on Sephacryl S-200 and DEAE-cellulose columns followed by isoeleetrofocusing. The resulting protein is greater than 95 percent homogeneous according to sodium dodeeyl sulfate-polyacrylamide electrophoresis and represents two peptides having two very close but distinguishable isoelectric point values of approximately 5.0. The purified molecules are retained by columns coated with lentil lectin or antigen but not by columns coated with antisera specific for immunoglobulins, the I region of the major histocompatibility complex or Ly-1 or Ly-2 antigens. Less than 50 pg of the purified glycoprotein specifically and completely suppresses production of anti-sheep erythrocyte plaque-forming cell by mixtures of 10(6) Ly-1 cells and B cells and this is a result of inactivation of Ly-l-mediated helper function. Specific inactivation of T (Th) cells by the 70,000-mol wt molecule is rapid, specific, and requires the presence of antigen. The mechanism of specific suppression of Th function may depend upon two functionally distinct regions of the 70,000-mol wt molecule: one that binds antigen and a second that mediates suppression.

Antigen-specific T lymphocyte clones. I. Characterization of a T lymphocyte clone expressing antigen-specific suppressive activity

We have generated continuously propagatable T lymphocyte clones to study antigen-specific T cell functions. All Ly-2+ clones mediate suppressive activity and secrete a characteristic pattern of polypeptides that differs from Ly-2- T cell clones. Cells of one clone, Cl.Ly23/4, specifically bind glycophorin from sheep erythrocytes (SRBC). After incubation with [35S]methionine, supernate material from this clone also contains biosynthetically labeled 70,000-mol wt proteins that specifically bind to SRBC and this binding is inhibited by glycophorin from sheep but not other erythrocytes. These antigen-binding 70,000-mol wt peptides specifically and completely suppress primary anti-SRBC responses generated by mixtures of primed Ly-1+2- cells and B cells. Suppression by these antigen-binding peptides reflects direct inhibition of T-helper activity.

Multiple biologic activities of a cloned inducer T-cell population

The mouse T-cell clone Ly1+2(-)/9, belonging to the Ly1 set, displays the following functions in vitro: (i) augmentation of immunoglobulin output by B cells; (ii) stimulation of bone marrow cells to produce colonies composed of granulocytes, macrophages, or both; and (iii) proliferative stimulation of T-cell clones belonging to other Ly sets. These functions are induced by Ly1+2(-)/9 cells themselves and by supernatants of Ly1+2(-)/9 cultures and are not evinced by tested clones belonging to other Ly sets. The agent or agents responsible for colony formation and for B-cell stimulation had an apparent molecular weight of 45,000-50,000 and could not be physically separated. The T-cell stimulating agent(s) had an apparent molecular weight of 30,000 and could be separated from the agent(s) that acts upon colony formation and B cells. Thus, clone LY1+2(-)/9 produces at least two soluble products that induce or augment activities of at least three other differently programmed cell sets.

Use of cloned populations of mouse lymphocytes to analyze cellular differentiation

We describe a method for generation of homogeneous cell populations that each arise from clonal expansion of cells at a discrete stage of differentiation within a single lineage. We have used this to produce continuously propagatable lymphocyte clones. Each clone represents a cell at a progressive stage of thymus-dependent cellular differentiation. These cloned cells bear stable surface membrane glycoproteins characteristic of precursor cells and mature progeny; conditions allowing maximal cloning efficiencies for each cell type (10-85%) have been established. Mature lymphocyte clones continue to express specialized function and provide material for biochemical analysis of T lymphocyte functions; one fully differentiated clone from the "inducer" lymphocyte set synthesizes a molecule that activates other lymphocytes to secrete immunoglobulin. This activity is associated with a highly purified molecule having a molecular weight of 45,000 daltons and an isoelectric point of approximately 6.0. This molecule, together with clones of precursor and mature T lymphocytes, may provide a system to further study the mechanisms of gene activation during cellular differentiation.