Genetic and biochemical characterization of a human surface determinant on somatic cell hybrids: the 4F2 antigen

Enrichment during transdominant genetic experiments using a flow sorter

BACKGROUND

Flow cytometry, in combination with retroviral expression libraries, is a powerful tool for genetic experimentation in mammalian cells. Expression libraries are transduced into cells engineered with a fluorescent reporter. Sorting for either bright or dim cells allows enrichment for specific inhibitors that alter reporter activity. This strategy has been used to isolate peptides and RNAs that either activate or suppress defined biochemical pathways.

METHODS

Several variables contribute to the enrichment process: (1) the background of the fluorescence bioassay; (2) the mean fluorescence ratio between the induced and noninduced reporter cell populations; (3) the genetic penetrance, or strength, of the inhibitor; and (4) the multiplicity of infection (MOI). An experimental and theoretical analysis, including computer modeling, of these issues in the context of a mammalian cell bioassay was undertaken.

RESULTS

MOI measurements were shown to be problematic. High MOI had little effect on enrichment early in the cycling process but a significant effect at later stages. Penetrance and background were critical throughout the process. Enrichments within about twofold of the theoretical maximum were observed.

CONCLUSIONS

Caution should be exercised in MOI determination because of the danger of significant underestimation. High MOI is potentially advantageous early in the selection process but hinders enrichment in the later rounds. Modeling shows that MOI, assay background and clone penetrance are the principal variables that determine the success of transdominant selections by FACS.

Transporters for cationic amino acids in animal cells: discovery, structure, and function

The structure and function of the four cationic amino acid transporters identified in animal cells are discussed. The systems differ in specificity, cation dependence, and physiological role. One of them, system y+, is selective for cationic amino acids, whereas the others (B[0,+], b[0,+], and y+ L) also accept neutral amino acids. In recent years, cDNA clones related to these activities have been isolated. Thus two families of proteins have been identified: 1) CAT or cationic amino acid transporters and 2) BAT or broad-scope transport proteins. In the CAT family, three genes encode for four different isoforms [CAT-1, CAT-2A, CAT-2(B) and CAT-3]; these are approximately 70-kDa proteins with multiple transmembrane segments (12-14), and despite their structural similarity, they differ in tissue distribution, kinetics, and regulatory properties. System y+ is the expression of the activity of CAT transporters. The BAT family includes two isoforms (rBAT and 4F2hc); these are 59- to 78-kDa proteins with one to four membrane-spanning segments, and it has been proposed that these proteins act as transport regulators. The expression of rBAT and 4F2hc induces system b[0,+] and system y+ L activity in Xenopus laevis oocytes, respectively. The roles of these transporters in nutrition, endocrinology, nitric oxide biology, and immunology, as well as in the genetic diseases cystinuria and lysinuric protein intolerance, are reviewed. Experimental strategies, which can be used in the kinetic characterization of coexpressed transporters, are also discussed.

Monoclonal antibodies specific for human chromosome 5 obtained with a monochromosomal hybrid can be used to sort out cells containing the chromosome with a FACS

Using a human-mouse monochromosomal hybrid, BG15-6, that contains an intact human chromosome 5, we isolated four monoclonal antibodies, 2A10, 3H9, 5G9, and 6G12, as chromosome marker antibodies recognizing cell surface antigens specific for human chromosome 5. The binding patterns of these antibodies to BG15 subclones containing fragments of human chromosome 5 indicated that 2A10, 3H9, and 6G12 recognized the antigens produced by genes located on 5pter-q22, and that 5G9 recognized the antigen produced by a gene located on 5q23. Cells containing human chromosome 5 were very effectively sorted in a fluorescence-activated cell sorter (FACS) using monoclonal antibody 6G12. This method for sorting cells containing human chromosome 5 or an appropriate fragment of this chromosome from among human-rodent hybrid cells should be very useful in studies on gene expression, gene cloning and gene mapping.

Definition of selectable cell surface markers for human chromosomes and chromosome segments in rodent-human hybrids

A panel of 22 monoclonal antibodies (MAbs) recognizing 21 distinct human cell surface antigens was tested by mixed hemadsorption assays for reactivity with a large number of rodent-human somatic cell hybrids containing different subsets of the human chromosome complement. The serological typing results permit the assignment of six gene loci determining cell surface antigens to human chromosomes 3, 6, 11, 19, 20, and 22. In addition, analysis of hybrids retaining deleted copies (but no normal homologs) of specific human chromosomes provides regional assignments for 18 gene loci, located on seven different chromosomes. These findings extend and refine the genetic map for human cell surface antigens and identify new selectable markers for defined chromosome segments.

Cloning, sequence analysis, and expression of the large subunit of the human lymphocyte activation antigen 4F2

Among the earliest expressed antigens on the surface of activated human lymphocytes is the surface antigen 4F2. We have used DNA-mediated gene transfer and fluorescence-activated cell sorting to obtain cell lines that contain the gene encoding the large subunit of the human 4F2 antigen in a mouse L-cell background. Human DNAs cloned from these cell lines were subsequently used as hybridization probes to isolate a full-length cDNA clone expressing 4F2. Sequence analysis of the coding region has revealed an amino acid sequence of 529 residues. Hydrophobicity plotting has predicted a probable structure for the protein that includes an external carboxyl terminus, an internal leader sequence, a single hydrophobic transmembrane domain, and two possible membrane-associated domains. The 4F2 cDNA detects a single 1.8-kilobase mRNA in T-cell and B-cell lines. RNA gel blot analysis of RNA derived from quiescent and serum-stimulated Swiss 3T3 fibroblasts reveals a cell-cycle modulation of 4F2 gene expression: the mRNA is present in quiescent fibroblasts but increases 8-fold 24-36 hr after stimulation, at the time of maximal DNA synthesis.

Fluorescence-activated cell sorting of hybrid and transfected cells

Mouse cells containing human surface antigen genes introduced by cell hybridization or DNA transfection can be labeled by indirect immunofluorescence and isolated using the FACS. As illustrated in this chapter, this methodology facilitates genetic studies of the human cell surface ranging from the initial chromosome mapping of a surface antigen gene to its isolation and cloning.

Evolution in the structure and distribution of 4F2-antigen from the oncofetal to the adult phenotype of human fibroblasts

The monoclonal antibody (MAb) 4F2 defines an oncofetal antigen in human fibroblastic cells. Two-dimensional electrophoretic analysis reveals that tumor cell lines from mesenchymal tissues co-express two or more heavy-chain molecular variants of the antigen whereas the light subunit (41 kDa) is not affected. Among normal cells, only embryonic and newborn fibroblasts (from donors up to 20 days after birth) clearly co-express two distinct molecular forms of the heavy chain with MW of 85 and 75 kDa, respectively. Cells derived from 3-month-old donors express detectable amounts of the 85 kDA but only faint traces of the 75 kDa subunit, while fibroblastic cells derived from donors older than 3 months seem to express only the 85 kDa subunit. Immunofluorescence analysis performed on adherent living cells shows that, in the first months after birth, there is a gradual evolution from the oncofetal to the adult phenotype also in the cell distribution of the 4F2. This evolution is reflected by a progressive disappearance of the 4F2 antigen from the cell membrane becoming, in adult normal cells, inaccessible to anti-4F2 MAb. The existence of different molecular forms and different membrane positions of the 4F2 antigen could facilitate surveillance of morphological and structural changes in the evolution of human fibroblastic cells during the developmental process and neoplastic transformation.

Expression of human chromosome 11-encoded cell-surface antigens by DNA-mediated transfectants

DNA-mediated transfectants were isolated that expressed two of the cell-surface antigens encoded by human chromosome 11. These tranfectants were used to analyze monoclonal antibodies selected to recognize human cell-surface antigens expressed by a somatic cell hybrid containing 11 as its only human chromosome. Analysis of the transfectants, deletion hybrids, and mutants showed that the monoclonal antibodies recognized at least five different antigens, one of which we had not identified previously. A majority of the monoclonal antibodies recognized the a1 antigen. The use of cells from higher primates demonstrated that the a1-specific monoclonal antibodies recognize at least two epitopes.

Role of human chromosome 11 in determining surface antigenic phenotype of normal and malignant cells. Somatic cell genetic analysis of eight antigens, including putative human Thy-1

The expression of eight serologically and biochemically distinct human cell surface antigens defined by monoclonal antibodies was examined on a panel of rodent-human somatic cell hybrids. Cosegregation was observed for human chromosome 11, and surface expression of all eight antigens was studied. Serological analysis of hybrids containing defined segments of human chromosome 11 permitted the regional assignment of genes controlling antigens JF23 (90 kD glycoprotein), G344 (25 kD), T43 (85 kD), A124, and NP13 to chromosome 11pter-q13, and of genes controlling Q14 (130 kD), MC139 (35 kD), and K117 (25 kD) to chromosome 11q13-qter. K117, the putative human Thy-1 antigen, was expressed at high levels in chromosome 11-containing hybrids constructed with mouse neuroblastoma cells, but showed little or no expression in hybrids constructed with mouse L cells. A similar pattern of expression in hybrids was found for MC139, an antigen shared by neuroectoderm-derived cells and normal and malignant T lymphocytes. T43 is a marker of malignant tumors (but not benign tumors) derived from a number of T43- epithelia, and the regional assignment of the T43 locus on chromosome 11 raises questions about its possible involvement in the specific rearrangements of this chromosome seen in human malignancies.

Analysis of the expression of the 4F2 surface antigen in normal and neoplastic fibroblastic human cells of embryonic and adult origin

4F2 monoclonal antibody recognizes a 120-kD glycoprotein on the surface of human spread fibroblastic cells of embryonic and neoplastic origin, but it does not bind to normal spread adult fibroblasts. Flow cytometric analysis reveals that human adult fibroblasts become 4F2-positive when they are analyzed as round-shaped cells; this means that, in normal adult cells, 4F2 antigen behaves as a cryptic molecule. Thus, the basic difference between embryonic, neoplastic and normal adult cells consists in a different organization in the architecture of the cell membrane, since in embryonic and neoplastic cells there is a continuous expression of the 4F2 antigen independently of the cell shape and cell cycle phase. Quantitative flow cytometry shows that the mean surface density (MSD) of the 4F2 antigen 1, does not vary as a function of the cell cycle; 2, is inversely related to cell size and "metabolic time". This suggests that at the plateau phase the surface organization of G1 resting cells changes as a function of the number of days spent in culture; and 3, sarcoma and SV40-transformed cells show significantly increased MSD levels of the 4F2 antigen in comparison with normal cells of similar size. Electrophoretic analysis under reducing conditions confirms the quantitative differences in the expression of the 4F2 antigen described with the cell sorter. It also reveals, in a way different from that previously found with lymphoid cells, the coexistence of two molecules (85 and 73 kD) in the heavy chain regions. The 73 kD is, however, much more strongly expressed in the fibrosarcoma than in the embryonic cells. Finally, it shows that 4F2 antigen is a very useful tool for studying the organization and the structure of the cell membrane of human fibroblasts and can provide new insights to understand better the developmental and transformation processes.

Assignment of gene for human cell-surface membrane antigen Trop-4 to chromosome 11

The gene (named MF16) for a surface membrane antigen, Trop-4, is assigned to human chromosome 11 on the basis of studies using a mouse monoclonal antibody, immunofluorescence, fluorescence-activated cell sorting (FACS), immunoprecipitation, and mouse-human lymphocyte hybrids. The Trop-4 antigen is present on all human cell lines tested, on peripheral blood monocytes and granulocytes, and on a small fraction of peripheral blood lymphocytes, but is absent from erythrocytes. The Trop-4 monoclonal antibody precipitates an 85,000-dalton glycopolypeptide from hybrid cells containing human chromosome 11. However, in a human cell line expressing this antigen, a larger-molecular-weight species, 100-105,000 daltons was coprecipitated with the 85,000-dalton glycopeptide, and under nonreducing conditions a larger compound of 110-125,000 daltons was obtained. Although the Trop-4 antigen is of similar molecular weight to the Mab-4 and F10.44.2 antigens previously assigned to chromosome 11, it is shown to be different from them.

A human cell-surface antigen defined by a monoclonal antibody and controlled by a gene on human chromosome 1

An antigen expressed by most human cells, but not erythrocytes, has been defined by a murine monoclonal antibody, TRA-2-10. This antigen is expressed on the surface of human-mouse somatic cell hybrids, and segregation analysis indicates that it is controlled by a gene located on human chromosome 1. From lysates of most human cells, surface-labelled with 125I, TRA-2-10 immunoprecipitates two polypeptides with molecular weights in the range of about 55 000 to 73 000 depending upon the cell line. Since the TRA-2-10 polypeptides from a fibroblast cell strain and a hepatoma cell line from one individual differ, we conclude that the observed difference in molecular weight has an epigenetic origin.

Chromosome mapping of cell membrane antigens expressed on activated B cells

Hybrids formed by fusion of either human acute lymphoblastic or chronic lymphocytic leukemia cells and the mouse myeloma P3.X63.Ag8/653 have been used to show that the expression of two cell surface antigens, Bp37 and p76, associated with B cell activation and detected by the monoclonal antibodies BB1 and BB2, respectively, segregate with human chromosomes 12 and 19, respectively. Another antigen expressed on activated B cells (p24) also maps to chromosome 12 (Katz et al., Eur. J. Immunol. 1984. 13: 1008) which is of interest in the light of the frequent involvement of this chromosome in certain B cell leukemias and lymphomas.

Use of somatic cell hybrids for quantitation of mutagenesis: reduction in background mutants by fluorescence-activated cell sorting (FACS)

Environmentally induced mutations, especially those involving large scale genetic damage such as deletions and chromosome loss, are of central importance in the production of human genetic disease and cancer. We have developed a methodology, the AL assay, that permits detection of such extensive genetic changes which often escape detection in other systems in which they are lethal. The AL assay employs a human-Chinese hamster ovary cell hybrid that retains a single human chromosome, number 11. A set of specific cell surface antigens result from genes located on opposite arms of this chromosome. Exposure to mutagens produces mutants which form colonies in the presence of complement and specific antiserum that kill nonmutant cells. The frequency and pattern of marker loss provides a measure of single gene mutation, large and small deletion, and loss of the entire chromosome 11. We have employed the indirect fluorescein conjugated isothiocyanate (FITC) technique and fluorescence-activated cell sorting (FACS) to remove spontaneous mutants from the initial population. The 100-fold reduction in background thus far achieved should allow accurate analysis of mutation by ionizing radiation at doses of less than 10 rad.

Human muscle cell surface antigen 16.3A5 is encoded by a gene on chromosome 11

A monoclonal antibody (McAb), 16.3A5, has been characterized that reacts with a cell surface antigen of human muscle cells and a variety of nonmuscle cells. The gene controlling synthesis of 16.3A5 antigen has been assigned to human chromosome 11 by assessing McAb reactivity on a panel of mouse-human cell hybrids. The 16.3A5 has a novel specificity distinct from other chromosome 11-encoded antigens such as W6/34, F10.44.2, TRA1.10, and 4D12 antigens.

Relationships between genes on human chromosome 11 encoding cell-surface antigens

Genes encoding seven monoclonal antibody-defined cell-surface antigens have been regionally mapped on human chromosome 11, and compared to those of the AL complex defined by polyclonal antibodies using mutational analysis. MIC1, encoding W6/34 antigen, is probably identical to S1, previously mapped to 11pter-p13. MDU1 and MIC8, encoding 4F2 and TRA-1.10 antigens, respectively, are probably identical to S2(a4) and map to 11q13-q22. MIC9, which governs expression of 4D12 and 2E2 antigens, and maps to 11q22-qter, is not related to any of the five AL genes. MIC4 and MIC11, both mapping to 11pter-p13, may have some relationship to S3 and S1, respectively, but identity has not been proven.

Assignment of low-molecular-weight human (2', 5')A synthetase to chromosome 11

Human low-molecular-weight (2', 5')A synthetase is induced in certain human X mouse somatic hybrid cell lines when these cells are treated with mouse interferon. We have assigned the gene coding for this interferon-inducible antiviral enzyme to human chromosome 11 by somatic cell genetic techniques (1). Fluorescence-activated cell sorting for cells expressing or lacking 4F2 antigen in two independently derived, chromosome 11-containing hybrid cell lines separated the cells into subpopulations of cells that had retained or segregated chromosome 11, respectively (2). We used these subpopulations to confirm our gene assignment by demonstrating that retention of chromosome 11 was required for expression of human (2', 5')A synthetase.

The use of cell surface antigens to characterize and select for fragments of human chromosomes retained by interspecies hybrids

We have used a mouse cell transformant generated by human chromosome-mediated gene transfer (CMGT) to explore the use of cell surface antigens in the identification of fragments of human chromosomes retained by somatic cell hybrids. The transformed line, 21-30b, contained an intact rear-ranged human chromosome, and could be shown by isozyme analysis to contain genetic material from chromosomes 9 and X. By using the transformant as an immunogen in mice, it was also possible to produce antiserum to human-specific surface antigens. Using genetically characterized human X rodent hybrid lines, the genes controlling expression of these antigens could be localized to 11per----11p13, segregating concordantly with surface antigen S3. These conclusions were possible despite the fact that the presence of chromosome 11 in the transformant was not detectable by the presence of chromosome specific isozyme LDH-A or surface antigens W6/34 and 4F2. Finally, the fluorescence-activated cell sorter (FACS) was used to fractionate the transformant cells into antigen positive and negative subpopulations. This resulted in the isolation and characterization of four additional chromosome rearrangements involving interspecies chromosome translocations. This work demonstrates the value of chromosome-specific surface antigens and the FACS in the evaluation of human chromosome fragments retained by interspecies hybrids.

Genetic and biochemical characterization of human lymphocyte cell surface antigens. The A-1A5 and A-3A4 determinants

The genes that code for the human lymphocyte cell surface determinants defined by monoclonal antibodies A- 1A5 and A- 3A4 have been genetically mapped. All human chromosomes, except Y, were included in a series of human less than mouse lymphocyte hybrid populations that retained expression of lymphocyte-specific surface markers. Expression of the A- 1A5 and A- 3A4 antigens was quantitated by indirect immunofluorescence and fluorescence-activated cell sorter (FACS) analysis. Hybrid populations heterogeneous for antigen expression were sorted to yield antigenically homogeneous subpopulations. Isozyme analysis indicated concordant segregation of the A- 1A5 determinant with chromosome 10, and the A- 3A4 determinant with chromosome 4. In contrast to the unhybridized human parent cell line (MOLT-4), from which A- 1A5 immunoprecipitated two proteins (160,000 and 125,000 Mr), A- 1A5 only immunoprecipitated a single band (125,000 Mr) from an A- 1A5 -expressing human less than mouse hybrid. The genetic disassociation of these two proteins from the A- 1A5 -reactive complex suggests that the appearance of the 160,000 Mr protein requires a gene locus that is unlinked to the locus for the 125,000 Mr protein on chromosome 10. A third component of the A- 1A5 -reactive protein complex (210,000 Mr), which is recognized by the monoclonal antibody TS2/7, was not expressed on the parent MOLT-4 cells, but was weakly expressed on MOLT-4 less than mouse BW5147 hybrids. This allowed preliminary mapping of that determinant to either chromosome 10 or 15. The A- 3A4 antigen (approximately 45,000 Mr) is a novel cell surface structure expressed on all hematopoietic cell lines tested, and represents the first cell surface marker mapped to chromosome 4.

Somatic cell hybrid mapping panels

The recent advances in human gene mapping have been largely due to the development of interspecies cell hybrids containing human chromosomes and their fragments. The importance of characterized panels of these hybrid lines has grown exponentially with the application of recombinant DNA technologies to human genetics. In this article, we discuss current strategies employed in the construction of somatic cell hybrid mapping panels.

SV40 immortalization of adult human mesenchymal cells from neuroretina. Biological, functional and molecular characterization

Human adult mesenchymal cells from neuroretina (human choroid cells, HC) have acquired an infinite lifespan, following phenotypic transformation with a wild-type SV40. Immortalized cells (HC/SV40) contain high numbers of free circular viral DNA, and integrated molecules in a head-to-tail array in the cellular DNA. HC/SV40 cells express both the virus-coded "T" antigens and the cell-coded p53 transformation-associated protein. The transformed phenotype was further characterized by loss of contact inhibition of cell division, inability to induce the retraction of a fibrin clot and to spread within fibrin, and the existence of an altered distribution of actin cables. For the first time we also describe a coupling of the immunofluorescence and the quantitative cytofluorometric analyses, a new transformation parameter, since we show that SV40 transformation causes reorganization of the cell membrane by inducing the unmasking of the antigen recognized by the 4F2 monoclonal antibody, which is present in a "cryptic" form in the untransformed cells. Though the HC/SV40 cells have been continuously passaged over a 3-year period, they have not yet achieved a fully malignant phenotype, since they retain serum-dependency and the presence of a well developed fibronectin pericellular network, and they are not tumorigenic in nude mice. Thus this human immortal cell line constitutes a very useful tool for studying the progression toward full malignancy and the relationships between evolution of transformation parameters and changes in the viral and cellular genome interplay.

4F2 monoclonal antibody recognizes a surface antigen on spread human fibroblasts of embryonic but not of adult origin

The 4F2 monoclonal antibody (mAb) has been shown to recognize a 120-kilodalton glycoprotein expressed on the cell surface of human peripheral blood monocytes, activated (but not resting) T or B cells, and T and B lymphoblastoid cell lines. In this report we show that 4F2 mAb specifically binds to the surface of adherent human embryonic fibroblasts but fails to bind to normal adult fibroblasts. Moreover, 4F2 antigen was expressed on sarcoma-derived or SV40-transformed adult fibroblastic cells. Finally, addition of 4F2 mAb inhibited the growth of cultured HT-1080 fibrosarcoma cell line, but had no inhibitory effect on various embryonic and adult normal or transformed fibroblasts.

The gene coding the human S11 surface antigens maps between the loci for HPRT and G6PD on the X-chromosome

The human S11 surface antigens are expressed on fibroblasts and are coded by a gene on the X-chromosome. We have regionally mapped this gene by examining S11 expression on a panel of hybrid lines which had fragmented the X-chromosome either during chromosome-mediated gene transfer, or by interspecies translocation during hybrid cell expansion. using indirect immunofluorescence and the fluorescence-activated cell sorter (FACS), it was possible to isolate antigen-positive and -negative hybrid subpopulations for subsequent genetic analysis. The gene coding S11 could be localized to Xq27-28, between the loci for HPRT and G6PD where genes for the S10 and S12 antigens have been previously mapped. This work demonstrates the value of cell surface antigens and the FACS in somatic cell genetic analysis, and provides evidence for regional clustering of surface antigen loci on the human X-chromosome.

Assignment of gene(s) coding for antigen defined by monoclonal antibody 2B2

A mouse monoclonal antibody (2B2) recognizes an antigen which is present on most human peripheral blood leukocytes but is absent from most proliferating cells. The antibody precipitated two surface-labeled membrane glycopolypeptides with molecular weights of 86,000 and 145,000, and it was strongly mitogenic to normal human lymphocytes. Somatic cell hybrids have been used for assigning the genes coding for these membrane glycoproteins to human chromosome 21. The assignment was based on correlation of antigen expression on mouse-human T-lymphocyte hybrids with the presence of human chromosomes in the same hybrid clones.

Somatic cell genetics and flow cytometry

Human genes coding cell surface molecules can be introduced into mouse host cells using a variety of somatic cell genetic techniques. Because these human gene products can be detected using indirect immunofluorescence on viable cells, the genes themselves can be monitored and manipulated using flow cytometry and sorting. In this paper, we review ways that we have used cell sorting to develop a somatic cell genetic analysis of the human cell surface.

Human chromosome 11 carries at least four genes controlling expression of cell-surface antigens

We have mapped two new genes to chromosome 11 which control the cell-surface expression of two distinct antigens defined by monoclonal antibodies. One of the antigens has a general tissue distribution and is associated with a molecular complex of two polypeptides of 80,000 dalton and 40,000 dalton molecular weight. The second antigen has a restricted tissue distribution and is carried on a polypeptide of 100,000 daltons. We have used a combination of genetic and biochemical techniques to demonstrate that these new markers are distinct from the antigens defined by the monoclonal antibodies F10.44.2 and W6/34 which are also encoded by genes on chromosome 11. It is concluded that human chromosome 11 carries at least four distinct genes controlling cell-surface antigen expression.

Production of interspecies T cell hybrids which retain differentiation specific surface antigens

Genetic mapping of differentiation specific surface antigens has been hampered by difficulty in preparation of interspecies hybrid cells which continue to express differentiated functions. A method has been developed for production of interspecies T cell hybrids which continue to express T cell specific cell surface molecules. Hybrids were constructed from either the human leukemic cell line MOLT-4 or freshly isolated human peripheral blood T cells and the mouse T lymphoma line BW5147. Optimal fusion efficiency resulted with pre-treatment of the human parental line with phytohemagglutinin followed by hybridization with 40% polyethylene glycol and plating without thymocyte feeder layers. Immortalization of hybrid lines was accomplished through addition of rat T cell growth factor to cultures.

Further studies on a hybrid cell-surface antigen associated with human chromosome 11 using a monoclonal antibody

A monoclonal antibody has been obtained that recognizes an antigen encoded by human chromosome 11. We present evidence that this monoclonal antibody recognizes the same or a similar antigenic activity as that previously called a1. Genetic information necessary for a1 expression and recognition by the monoclonal antibody both map to 11p13 leads to 11pter. Mutants that have lost a1 are no longer recognized by the monoclonal antibody. The macroglycolipid fraction of human erythrocyte membranes which contains the a1 antigenic activity is able to convert antigen-negative Chinese hamster ovary cells into cells which are killed by the monoclonal antibody plus complement.

Chromosomal assignment of a family of human oncogenes

A family of human transforming genes, previously shown to share homology with the ras family of viral oncogenes, maps to three different human chromosomes. A well-characterized mouse-human hybrid cell panel, combined with Southern blotting, was used in this study. The transforming gene of the T24 bladder carcinoma cell line maps to human chromosome 11. An oncogene isolated from the lung carcinoma cell line SK-Calu-1 maps to human chromosome 12. The third ras-related gene, cloned from SK-N-SH, a neuroblastoma cell line, maps to human chromosome 1.

Fluorescence-activated cell sorting of mouse-human hybrid cells aids in locating the gene for the Leu 7 (HNK-1) antigen to human chromosome 11

Leu 7 (HNK-1) is a membrane antigen expressed on human natural killer cells and some other lymphoid cells. Starting with two clones of mouse-human hybrid lymphoid cells that had 1.6% and 35% Leu 7-positive cells, respectively, we viably sorted Leu 7-positive and -negative cells using a fluorescence-activated cell sorter (FACS). Short-term progeny of the sorted cells were then karyotyped. Chromosome 11 was the only human chromosome that was absent from the Leu 7-negative population and present in nearly all of the progeny of the Leu 7-positive selected cells. Thus, we assigned the Leu 7 gene to chromosome 11.

Chromosome mapping of human cell surface molecules: monoclonal anti-human lymphocyte antibodies 4F2, A3D8, and A1G3 define antigens controlled by different regions of chromosome 11

Monoclonal antibodies 4F2, A3D8, and A1G3, directed against cell surface antigens present on subsets of human cells, were used to identify the human chromosome regions that code for the antigenic determinants. Human fibroblasts expressed all three antigens, and no cross-reactivity with Chinese hamster or mouse cells was found. Fourteen rodent X human somatic cell hybrids, derived from six different human donors and from two different Chinese hamster and one mouse cell line, were studied simultaneously for human chromosome content and for antibody binding as detected by indirect immunofluorescence. Concordancy with binding of all three antibodies was observed only for human chromosome 11. All other chromosomes were excluded by three or more discordant hybrid clones. Data from six hybrids containing three different regions of chromosome 11 indicate that it is the long arm of chromosome 11 which is both necessary and sufficient for expression of the human antigen defined by 4F2 while the antigen(s) defined by A3D8 and A1G3 map to short arm.