Expression of an immunoglobulin heavy chain gene transfected into lymphocytes

Correlation of Heavy and Light Chain mRNA Copy Numbers to Antibody Productivity in Mouse Myeloma Production Cell Lines

Manufacturing cell line development at Centocor involves transfection of antibody genes into host cell lines and isolating primary transfectomas that upon subcloning yield high expressing cell lines for the desired antibody. In an attempt to increase productivity of these cell lines, we set out to identify the rate-limiting step in the process of antibody expression and secretion. For this purpose, 30 antibody expressing cell lines with variable antibody expression levels were analyzed for heavy-chain and light-chain mRNA expression levels. Results suggested that the increase in antibody titer of the subclones (compared to their primary clones) was partly due to an increase in heavy-chain and light-chain mRNA levels; higher expressers were associated with approximately 1.0 x 10(7) and 1.5 x 10(7) copies of heavy-chain and light-chain per 10 nanogram of cDNA, respectively. Generally, the level of light-chain mRNA was higher compared to the level of heavy-chain mRNA in a majority of the cell lines, and the difference in their levels was not due to their differential stability. The data generated from all the cell lines tested in this study suggested that there was a correlation of light-chain and heavy-chain transcript levels to antibody productivity, with the coefficient of correlation being 0.59 for light chain and 0.81 for heavy chain. We conclude that transcription of heavy chain and to a lesser extent light chain could be one of the rate-limiting steps in the antibody expression pathway. Hence, methods that would increase these mRNA levels could be beneficial in the attempt to improve the antibody expression level of production cell lines.

Myeloma expression systems

Myeloma expression systems have been utilized successfully for the production of various recombinant proteins. In particular, myeloma cell lines have been exploited to express a variety of different antibodies for diagnostic applications as well as in the treatment of various human diseases. The use of myeloma cells for antibody production is advantageous because they are professional immunoglobulin-secreting cells and are able to make proper post-translational modifications. Proper glycosylation has been shown to be important for antibody function. Advances in genetic engineering and molecular biology techniques have made it possible to isolate murine and human variable regions of almost any desired specificity. Antibodies and antibody variants produced in myeloma cells have been extremely helpful in elucidating the amino acid residues and structural motifs that contribute to antibody function. Because of their domain nature, immunoglobulin genes can be easily manipulated to produce chimeric or humanized antibodies. These antibodies are less immunogenic in humans and also retain their specificity for antigen and biologic properties. In addition, novel proteins in which antibodies are fused to non-immunoglobulin sequences as well as secretory IgA have been produced in myeloma cells.

Short-term assays for detection of conditional cancerogens. I. Construction of DR-CAT Raji cells and some of their characteristics as tester cells

A number of agents including the tumor promoter 12-0-tetradecanoyl-phorbol-13-acetate (TPA) (TPA) can induce an abortive virus cycle in the EBV-non-producer Burkitt's-lymphoma line Raji. Two distant regions, DL and DR, of the EBV genome with almost complete homology carry strong promoters which are induced in an abortive or lytic cycle and additionally function as lytic origins of viral DNA replication. To set up a system in which the activity of EBV-inducing agents can be measured in a quantitative and reproducible fashion, we generated a cell line which carries multiple copies of a DR-promoter chloramphenicol-acetyltransferase (CAT) construct on an episomal vector. CAT activity is low in untreated cells, but high upon treatment of the cells with various EBV-inducing agents. Combinations of different agents can produce an over-additive effect. The Raji-DR-CAT cell line may provide a simple quantitative and reproducible test system for EBV-inducing agents, especially for tumor promoters which activate protein kinases C.

Vitamin D receptor interaction with specific DNA requires a nuclear protein and 1,25-dihydroxyvitamin D3

The regulation of osteocalcin gene expression by 1,25-dihydroxyvitamin D3 is mediated by the vitamin D receptor and a cis-acting DNA response element that has been identified within the 5' region of the osteocalcin promoter. In this report, we show that vitamin D receptors derived from nuclear extracts of mammalian cells bind directly to this cis-acting element in vitro and do so in a manner requiring hormone. Vitamin D receptors derived from reticulocyte lysate translations in vitro or from extracts of a Saccharomyces cerevisiae strain that expresses the recombinant protein also bind the osteocalcin responsive element, but only when nuclear extracts of mammalian cells are provided. The vitamin-D-receptor-DNA-binding accessory factor is isolated by salt extraction, labile to temperature, and sensitive to tryptic digestion. These studies suggest that the high-affinity interaction of the vitamin D receptor with the osteocalcin vitamin D response element in vitro requires both 1,25-dihydroxyvitamin D3 and an accessory protein derived from the mammalian cell nucleus.

Structural requirements for pairing of alpha and beta chains in HLA-DR and HLA-DP molecules

To test for the assembly of human MHC class II molecules having an alpha chain from one isotype (HLA-DR, -DQ, or -DP) and the beta chain of another (mixed isotypic pairs), murine fibroblasts were transfected with expressible cDNAs encoding the different class II alpha and beta chains. A rapid and efficient transient transfection system was developed using a polyoma virus-based vector. Typically, 30-50% of cells transfected using this system expressed high levels of class II molecules on their surface, but only with matched isotypic pairs. Biochemical analysis of cells transfected with matched or mixed isotypic pairs of the DR and DP molecules revealed that only matched chains could pair efficiently inside the cell. Thus, the lack of expression of the two mixed isotypic pairs is due to inefficient primary assembly of the class II molecule and not to a processing or transport defect. To define what region of the beta chains controlled their assembly with alpha chains, a series of chimeric cDNA molecules containing both DR and DP beta chain sequences were constructed. Expression of these chimeric beta chains with DR and DP alpha chains was determined by cytofluorimetry and biochemical analysis. Both alpha chains paired with beta chains in which only the beta 1 domain was isotypically matched. In contrast, the pattern of expression of chimeras made at other points within the beta 1 domain was different for DR and DP. These data show that different areas of primary sequence are important for the assembly of different human class II isotypes, and suggest that HLA-DR and -DP molecules have different secondary or tertiary structures in their NH2-terminal domains.

Development of new cell lines for animal cell biotechnology

Mammalian cell culture has been an important technique in laboratory-scale experimentation for many decades. Developments in large-scale culture have been due to the need to grow large numbers of cells to support the growth of viruses for vaccine production, and more recently, for growing hybridoma cells as a source of monoclonal antibody. Increasingly, however, pharmaceutical products such as hormones, enzymes, growth factors, and clotting factors are being produced from cell lines which have been manipulated by recombinant DNA techniques. It is clear, therefore, that the high cost of growing mammalian cells on a large scale does not necessarily prohibit their use for biotechnology, and indeed there is considerable evidence to suggest that animal cell biotechnology will continue to be a major growth area in the future.

Characterization and expression of the complementary DNA encoding rat histidine decarboxylase

Histamine is a neurotransmitter in the central nervous system and an important modulator of gastric acid secretion, vasomotor control, inflammation, and allergic reactions. In biological systems the formation of histamine from its precursor histidine is catalyzed by the enzyme L-histidine decarboxylase (HDC; L-histidine carboxy-lyase, EC 4.1.1.22). We have cloned HDC-encoding cDNA from a fetal rat liver cDNA library (phage lambda gt11) have deduced the amino acid sequence from the nucleotide sequence. The clone was proven to be HDC cDNA by expression of active recombinant enzyme in COS cells and by chromosomal mapping. The cDNA encodes a protein of Mr 73,450 (655 amino acid residues). The discrepancy between this molecular weight and the size of the purified fetal liver protein subunits [Taguchi, Y., Watanabe, T., Kubota, H., Hayashi, H. & Wada, H. (1984) J. Biol. Chem. 259, 5214-5221] (Mr = 54,000) suggests that HDC may be posttranslationally processed. The 469 amino acid residues from the amino-terminal portion of the protein share 50% identity with rat and Drosophila L-dopa decarboxylases and much less homology with other characterized amino acid decarboxylases.

An ochre mutation in the vitamin D receptor gene causes hereditary 1,25-dihydroxyvitamin D3-resistant rickets in three families

Hereditary 1,25-dihydroxyvitamin D3-resistant rickets is a rare autosomal-recessive disease resulting from target-organ resistance to the action of the active hormonal form of vitamin D. Four affected children from three related families with the classical syndrome of hereditary 1,25-dihydroxyvitamin D3-resistant rickets and the absence of detectable binding to the vitamin D receptor (VDR) in cultured fibroblasts or lymphoblasts were examined for genetic abnormalities in the VDR gene. Genomic DNA from Epstein-Barr virus-transformed lymphoblasts of eight family members was isolated and amplified by polymerase chain reaction techniques. Amplified fragments containing the eight structural exons encoding the VDR protein were sequenced. The DNA from all affected children exhibited a single C----A base substitution within exon 7 at nucleotide 970 that resulted in the conversion of the normal codon for tyrosine (TAC) into a premature termination codon (TAA) at amino acid 292. This mutation causes a truncation of the VDR protein thereby deleting a large portion of the steroid hormone binding domain (amino acids 292-424). Although the affected children were all homozygotic for the mutation, the four parents tested all exhibited both wild-type and mutant alleles, indicating a heterozygous state. The functional consequences of this mutation were confirmed after expression of the recreated mutant VDR cDNA in mammalian cells. Recreated mutant receptor exhibited no specific 1,25-[3H]dihydroxyvitamin D3 binding and failed to activate a cotransfected VDR promoter-reporter gene construct. Thus these findings identify an ochre mutation in a human steroid hormone receptor in patients with hereditary 1,25-dihydroxyvitamin D3-resistant rickets.

Expression of T-cell receptor alpha-chain genes in transgenic mice

To examine the influences responsible for shaping the T-cell repertoire in vivo, we have introduced T-cell receptors of defined specificity into mice. In this report, we analyze transgenic mice carrying a T-cell receptor alpha-chain gene from a pigeon cytochrome c-reactive T-cell line. A variant of this construct, which has the immunoglobulin heavy-chain enhancer inserted into the JC intron, was also introduced into mice. Addition of the enhancer increased the steady-state level of transgene-encoded mRNA three- to fivefold in cultured T cells, leading to a two- to threefold increase in surface expression. In vivo, the difference between these two constructs was even more significant, increasing the number of transgene-positive cells from approximately 5 to 70% and the T-cell receptor surface density two- to threefold. Surprisingly, while surface expression of either type of transgene was limited to T cells, we found little tissue specificity with respect to transcription. In T cells expressing the alpha chain from the enhancer-containing construct, immunoprecipitation with a 2B4 alpha-specific monoclonal antibody revealed the expected disulfide-linked dimer. Costaining of these T cells with the 2B4 alpha-specific monoclonal antibody versus anti-CD3 indicated that expression of the transgene-encoded alpha chain precludes expression of endogenous alpha chains on the majority of cells; in contrast, 2B4 alpha-chain expression from the construct lacking the enhancer is inefficient at suppressing endogenous alpha-chain expression. In mice of the enhancer lineage, Southern blot analysis indicated suppression of endogenous alpha-chain rearrangements in T-cell populations, consistent with the observed allelic exclusion at the cellular level. Interestingly, newborn, but not adult, mice of this lineage also showed an increase in retention of unrearranged delta-chain loci in thymocyte DNA, presumably resulting from the suppression of alpha-chain rearrangements. This observation indicates that at least a fraction of alpha:beta-positive T cells have never attempted to produce functional delta rearrangements, thus suggesting that alpha:beta and gamma:delta T cells may be derived from different T-cell compartments (at least during the early phases of T-cell differentiation).

Selective removal of alpha heavy-chain glycosylation sites causes immunoglobulin A degradation and reduced secretion

The importance of carbohydrate in the secretion of immunoglobulin A (IgA) has previously been suggested by results of studies with tunicamycin, which prevents N-linked glycosylation of all cell glycoproteins. To directly evaluate the role of individual oligosaccharides in the secretion of IgA, we have used site-directed mutagenesis to selectively eliminate the two N-linked attachment sites reported to be glycosylated in alpha heavy chains. Transfected wild-type and mutant alpha genes were expressed in kappa light-chain-producing MPC-11 variant myeloma cells, and secretion kinetics of the IgAs were compared. Removal of either or both glycosylation sites led to intracellular alpha heavy-chain degradation and a 90 to 95% inhibition of IgA secretion. These results reveal that both N-linked oligosaccharides of the alpha heavy chain are essential for intracellular stability and normal secretion of IgA. This suggests that the key function of carbohydrate here is to maintain proper conformation of the glycoprotein. We also found that when expressed in the MPC-11 variant cells, alpha heavy chains were glycosylated at a third, normally unused site.

Expression of T-cell receptor alpha-chain genes in transgenic mice

To examine the influences responsible for shaping the T-cell repertoire in vivo, we have introduced T-cell receptors of defined specificity into mice. In this report, we analyze transgenic mice carrying a T-cell receptor alpha-chain gene from a pigeon cytochrome c-reactive T-cell line. A variant of this construct, which has the immunoglobulin heavy-chain enhancer inserted into the JC intron, was also introduced into mice. Addition of the enhancer increased the steady-state level of transgene-encoded mRNA three- to fivefold in cultured T cells, leading to a two- to threefold increase in surface expression. In vivo, the difference between these two constructs was even more significant, increasing the number of transgene-positive cells from approximately 5 to 70% and the T-cell receptor surface density two- to threefold. Surprisingly, while surface expression of either type of transgene was limited to T cells, we found little tissue specificity with respect to transcription. In T cells expressing the alpha chain from the enhancer-containing construct, immunoprecipitation with a 2B4 alpha-specific monoclonal antibody revealed the expected disulfide-linked dimer. Costaining of these T cells with the 2B4 alpha-specific monoclonal antibody versus anti-CD3 indicated that expression of the transgene-encoded alpha chain precludes expression of endogenous alpha chains on the majority of cells; in contrast, 2B4 alpha-chain expression from the construct lacking the enhancer is inefficient at suppressing endogenous alpha-chain expression. In mice of the enhancer lineage, Southern blot analysis indicated suppression of endogenous alpha-chain rearrangements in T-cell populations, consistent with the observed allelic exclusion at the cellular level. Interestingly, newborn, but not adult, mice of this lineage also showed an increase in retention of unrearranged delta-chain loci in thymocyte DNA, presumably resulting from the suppression of alpha-chain rearrangements. This observation indicates that at least a fraction of alpha:beta-positive T cells have never attempted to produce functional delta rearrangements, thus suggesting that alpha:beta and gamma:delta T cells may be derived from different T-cell compartments (at least during the early phases of T-cell differentiation).

Selective removal of alpha heavy-chain glycosylation sites causes immunoglobulin A degradation and reduced secretion

The importance of carbohydrate in the secretion of immunoglobulin A (IgA) has previously been suggested by results of studies with tunicamycin, which prevents N-linked glycosylation of all cell glycoproteins. To directly evaluate the role of individual oligosaccharides in the secretion of IgA, we have used site-directed mutagenesis to selectively eliminate the two N-linked attachment sites reported to be glycosylated in alpha heavy chains. Transfected wild-type and mutant alpha genes were expressed in kappa light-chain-producing MPC-11 variant myeloma cells, and secretion kinetics of the IgAs were compared. Removal of either or both glycosylation sites led to intracellular alpha heavy-chain degradation and a 90 to 95% inhibition of IgA secretion. These results reveal that both N-linked oligosaccharides of the alpha heavy chain are essential for intracellular stability and normal secretion of IgA. This suggests that the key function of carbohydrate here is to maintain proper conformation of the glycoprotein. We also found that when expressed in the MPC-11 variant cells, alpha heavy chains were glycosylated at a third, normally unused site.

Cloning and expression of full-length cDNA encoding human vitamin D receptor

Complementary DNA clones encoding the human vitamin D receptor have been isolated from human intestine and T47D cell cDNA libraries. The nucleotide sequence of the 4605-base pair (bp) cDNA includes a noncoding leader sequence of 115 bp, a 1281-bp open reading frame, and 3209 bp of 3' noncoding sequence. Two polyadenylylation signals, AATAAA, are present 25 and 70 bp upstream of the poly(A) tail, respectively. RNA blot hybridization indicates a single mRNA species of approximately equal to 4600 bp. Transfection of the cloned sequences into COS-1 cells results in the production of a single receptor species indistinguishable from the native receptor. Sequence comparisons demonstrate that the vitamin D receptor belongs to the steroid-receptor gene family and is closest in size and sequence to another member of this family, the thyroid hormone receptor.

Cloning of human androgen receptor complementary DNA and localization to the X chromosome

The androgen receptor (AR) mediates the actions of male sex steroids. Human AR genomic DNA was cloned from a flow-sorted human X chromosome library by using a consensus nucleotide sequence from the DNA-binding domain of the family of nuclear receptors. The AR gene was localized on the human X chromosome between the centromere and q13. Cloned complementary DNA, selected with an AR-specific oligonucleotide probe, was expressed in monkey kidney (COS) cells and yielded a high-affinity androgen-binding protein with steroid-binding specificity corresponding to that of native AR. A predominant messenger RNA species of 9.6 kilobases was identified in human, rat, and mouse tissues known to contain AR and was undetectable in tissues lacking AR androgen-binding activity, including kidney and liver from androgen-insensitive mice. The deduced amino acid sequence of AR within the DNA-binding domain has highest sequence identity with the progesterone receptor.

Transfection of an immunoglobulin kappa gene into mature human B lymphocytes

We show in this report that the transcription induced by interleukin-2 or pokeweed mitogens of the kappa MOPC 41 immunoglobulin light-chain gene transfected into primary human or murine B lymphocytes initiates from a previously unobserved start site about 26 base pairs upstream of the start site used in myeloma cell lines.

Transfection of an immunoglobulin kappa gene into mature human B lymphocytes

We show in this report that the transcription induced by interleukin-2 or pokeweed mitogens of the kappa MOPC 41 immunoglobulin light-chain gene transfected into primary human or murine B lymphocytes initiates from a previously unobserved start site about 26 base pairs upstream of the start site used in myeloma cell lines.

Cell-type-specific synthesis of murine immunoglobulin mu RNA from an adenovirus vector

The mouse immunoglobulin heavy-chain mu constant region gene was cloned into the early region 1B of an adenovirus type 5 vector to allow reproducible kinetics of expression of the mu gene in the presence of continuous host protein synthesis after infection by the recombinant. The immunoglobulin-adenovirus recombinant is helper independent in infecting human fibroblastic and B- and T-cell lines and expresses mu in a cell-type-specific manner. By Northern blot analysis, correctly polyadenylated and spliced E1B-mu S and E1B-mu m mRNAs are found to be equally abundant at steady state in fibroblasts. In contrast, and appropriately, only E1B-mu S mRNAs accumulate in a lambda light-chain-secreting myeloma cell line. Analysis of nascent transcripts pulse labeled in isolated nuclei demonstrates equimolar polymerase loading throughout the mu region in all cell types infected by mu-Ad. Thus, correct polyadenylation and splicing of E1B-mu S and E1B-mu m in fibroblasts does not require transcription termination in the region separating the mu S and mu m polyadenylation sites. Furthermore, differential expression of mu transcripts in the background of myeloma cells is regulated at the level of RNA processing and does not require the presence of the immunoglobulin heavy-chain enhancer or promoter element.

Synergism between immunoglobulin enhancers and promoters

Enhancers are DNA sequences that stimulate transcription from eukaryotic promoters. This stimulatory effect can be exerted over large distances and from a position either 5' or 3' of a promoter. Enhancers have been found in the genomes of many viruses, and in some cellular genes such as those encoding immunoglobulin heavy chain and kappa light chain. An important feature of both viral and cellular enhancers is the ability of each enhancer to stimulate transcription from many promoters other than the one with which it is found associated. However, the question of whether cellular enhancers stimulate their 'own' promoter more efficiently than other promoters has apparently not been investigated. We show here that the kappa light-chain enhancer stimulates a kappa promoter about 20-fold more than it stimulates either the simian virus 40 (SV40) early promoter or a metallothionein (MT) promoter, two promoters that are very sensitive to other enhancers. Similarly, the heavy-chain enhancer stimulates a heavy-chain promoter much more than it stimulates the SV40 and MT promoters. This synergism between immunoglobulin enhancers and promoters might be due to the action of a protein that binds specifically to each of the regulatory elements.

A labile inhibitor blocks immunoglobulin kappa-light-chain-gene transcription in a pre-B leukemic cell line

The murine pre-B leukemic cell line 70Z/3 contains both an unrearranged immunoglobulin kappa-light-chain gene and a functionally rearranged but silent kappa-light-chain gene. Mitogenic stimulation of growing 70Z/3 cells with bacterial lipopolysaccharide (LPS) activates kappa-light-gene transcription and results in a 10- to 20-fold increase in cytoplasmic kappa-light-chain mRNA. The induction of kappa gene expression by LPS was probed by using an inhibitor of protein synthesis. Concomitant treatment of 70Z/3 cells with LPS and cycloheximide failed to block kappa-light-chain mRNA accumulation, indicating that new protein synthesis is not required for the activation of kappa-gene expression. Treatment of 70Z/3 cells with cycloheximide alone resulted in kappa-mRNA induction equivalent to those produced by LPS alone. The kappa mRNA synthesized in the presence of cycloheximide was intact and able to direct the synthesis of kappa light chains. Nuclear transcription assays revealed that cycloheximide, like LPS, activated kappa-gene transcription. These findings indicate that the trans-acting factors necessary for kappa-light-chain-gene transcription are present in pre-B cells, but their activity is blocked by short-lived inhibitory proteins.

Cell-type-specific synthesis of murine immunoglobulin mu RNA from an adenovirus vector

The mouse immunoglobulin heavy-chain mu constant region gene was cloned into the early region 1B of an adenovirus type 5 vector to allow reproducible kinetics of expression of the mu gene in the presence of continuous host protein synthesis after infection by the recombinant. The immunoglobulin-adenovirus recombinant is helper independent in infecting human fibroblastic and B- and T-cell lines and expresses mu in a cell-type-specific manner. By Northern blot analysis, correctly polyadenylated and spliced E1B-mu S and E1B-mu m mRNAs are found to be equally abundant at steady state in fibroblasts. In contrast, and appropriately, only E1B-mu S mRNAs accumulate in a lambda light-chain-secreting myeloma cell line. Analysis of nascent transcripts pulse labeled in isolated nuclei demonstrates equimolar polymerase loading throughout the mu region in all cell types infected by mu-Ad. Thus, correct polyadenylation and splicing of E1B-mu S and E1B-mu m in fibroblasts does not require transcription termination in the region separating the mu S and mu m polyadenylation sites. Furthermore, differential expression of mu transcripts in the background of myeloma cells is regulated at the level of RNA processing and does not require the presence of the immunoglobulin heavy-chain enhancer or promoter element.

Role of an RNA cleavage/poly(A) addition site in the production of membrane-bound and secreted IgM mRNA

The switch from membrane-bound to secreted IgM is accomplished by producing alternative forms of mRNA from a single mu heavy-chain gene. This process might be controlled at any of three steps--transcription termination, RNA splicing, or RNA cleavage/poly(A) addition. To distinguish between these possibilities, we have constructed a model human mu gene and observed its expression in early- and late-stage murine B cells. In each case, expression of the model gene reflects the state of development of the host cell; i.e., more of the mRNA for membrane-bound IgM is made in early B cells and more of the secreted form is made in late B cells. Using systematic deletions and analyses of RNA products of the model gene, we implicate RNA cleavage/poly(A) addition as the governing reaction. Removal of the cleavage/poly(A) signal for secreted mu mRNA by a series of BAL-31 deletions produces not only a decrease in secreted mu mRNA but also a compensatory increase in the membrane-bound form. Further, transcripts that do not terminate to the 5' side of the membrane anchor exons are found in cells producing only secreted IgM. As defined by these deletions, we establish that the RNA cleavage signal spans at least 35 bases and speculate that it forms an RNA stemloop that may be important in 3' end formation.

Structure of the murine Thy-1 gene

We have cloned the murine Thy-1.1 (AKR) and Thy-1.2 (Balb/c) genes. The complete exon/intron structure and the nucleotide sequence of the Thy-1.2 gene was determined. The gene contains four exons and three intervening sequences. The complete transcriptional unit gives rise to a tissue and developmental stage-specific mRNA of 1850 bp. The 5' end of the gene has multiple initiation sites and a non-TATA box promoter. The 3' end shows a single polyadenylation site after a very long untranslated region.

An immunoglobulin promoter displays cell-type specificity independently of the enhancer

Recent studies in which cloned immunoglobulin genes were introduced into cultured cells have produced two significant findings. First, the genes are expressed after transfection into lymphoid cells but not non-lymphoid cells. Second, transcription of an immunoglobulin gene requires, in addition to the promoter region, an enhancer element located downstream of the transcription start site. These findings raise the question of whether it is the promoter or the enhancer region that is responsible for the observed cell-type specificity. It has, in fact, been shown that immunoglobulin enhancers function only in lymphoid cells. We show here that the promoter for an immunoglobulin kappa light-chain gene also is strongly specific for lymphoid cells. Our result reemphasizes the importance of promoters relative to enhancers in determining which cells express which genes.

Gene transfer in lymphoid cells: expression of the Thy-1.2 antigen by Thy-1.1 BW5147 lymphoma cells transfected with unfractionated cellular DNA

We have transferred the gene coding for the Thy-1.2 alloantigen into a Thy-1.1-bearing T-cell lymphoma. BALB/c thymocyte DNA, precipitated with calcium phosphate, was used to effect the transfer. We report the stable transformation of lymphoid cells by total cellular DNA. To our knowledge, this has not been previously reported. Transient expression of the transfected gene could be detected by flow cytofluorometry, and 5% (range, 1.5%-11%) of the recipient cells had Thy-1.2 antigen detectable on their surface 48 hr after transfer. "Stable" transformants were isolated by repeatedly selecting for cells expressing the Thy-1.2 antigen, by use of fluorescence-activated cell sorting or "panning." No metabolic selection was required. The transferred gene, detected by Southern blotting, encoded a product that is indistinguishable from the normal antigen by immunoprecipitation and NaDod-SO4/PAGE.