`Vol. 79, pp. 7862-7865, December 1982
`Immunology
`
`Regulated expression of an immunoglobulin K gene introduced into
`a mouse lymphoid cell line
`(Abelson murine leukemia virus/DNA transfection/ gpt selection/lipopolysaccharide induction)
`
`DOUGLAS RICE AND DAVID BALTIMORE
`
`The Whitehead Institute for Biomedical Research, the Center for Cancer Research, and the Department of Biology, Massachusetts Institute of Technology,
`Cambridge, Massachusetts 02139
`
`Contributed by David Baltimore, September 16, 1982
`
`ABSTRACT We have introduced a functionally rearranged
`murine K light chain immunoglobulin (Ig) gene into an Abelson
`murine leukemia virus-transformed lymphoid cell line. Plasmid
`pSV2gpt-K41, containing the K light chain gene from the myeloma
`MOPC41 and the selectable marker gene gpt, was introduced into
`81A-2 cells by the calcium phosphate coprecipitation technique.
`Cells expressing the gpt gene were selected by growth in medium
`containing mycophenolic acid. One transfected cell line, K-2, was
`shown to make K mRNA and polypeptide chains and to assemble
`the K chain product with y2b heavy chains to form an apparently
`complete IgG2b. When bacterial lipopolysaccharide was added to
`the growth medium, levels of K mRNA and polypeptide increased,
`showing regulated expression of the introduced K gene.
`
`B cell differentiation proceeds from the "pre-B" lymphocyte,
`which synthesizes JJ- immunoglobulin (Ig) heavy chains but no
`light chains, to the mature B lymphocyte, which synthesizes
`both heavy and light chains and expresses surface lg, and finally
`to the Ig-secreting plasma cell (1-5). The availability of trans(cid:173)
`formed cell analogs has allowed biochemical characterization of
`these stages of cellular differentiation (6-11). Recently, such
`studies have contributed greatly to our understanding of the
`structure of lg gene segments and the joining of these segments
`to produce a functionally rearranged lg gene (12-17).
`Although much is now known about Ig gene structure, rel(cid:173)
`atively little is known about the molecular mechanisms that
`control lg gene expression. One approach to study such controls
`is to introduce Ig genes into various cell lines, including both
`lymphoid cells at various stages of differentiation and nonlym(cid:173)
`phoid cells. One might then be able to identify control mech(cid:173)
`anisms unique to lymphoid cells that allow the cells to express,
`assemble, and secrete lgs. To begin such studies, we have at(cid:173)
`tempted to introduce a functionally rearranged murine K light
`chain gene into an Abelson murine leukemia virus (A-MuLV)(cid:173)
`transformed lymphoid cell line.
`Previous studies have shown that A-MuLV infection of bone
`marrow or fetal liver cells transforms cells of the B-lymphoid
`lineage, usually "pre-B" cells (18, 19). Derivatives of one A(cid:173)
`MuLV transformant, 18-8, have been shown to switch from JJ(cid:173)
`to ")12b heavy chain synthesis while in culture (20-22). One such
`derivative, 81A-2, synthesizes ")12b protein, but has lost its K
`constant region light chain gene segments (unpublished data).
`Here we report that, after the introduction of a functionally
`rearranged K gene into 81A-2 cells, the K gene is expressed in
`a regulated manner.
`
`MATERIALS AND METHODS
`Cells. The A-MuLV -transformed cell line 81A-2, a derivative
`of the line 18-8, synthesizes ")12b heavy chain protein, but no
`
`light chain, and has lost its K constant region genes (refs. 18 and
`22; unpublished data). Cells were grown and analyzed for lg
`protein synthesis by metabolic labeling and immunoprecipita(cid:173)
`tion as described (18). Nonreduced samples were prepared for
`electrophoresis as described by Margulies et al. (23).
`DNA Procedures. The phage ACh4A-4IKC21, containing
`the rearranged genomic K light chain gene from the myeloma
`MOPC41, was obtained from P. Leder (12). The 7-kilobase-pair
`(kbp) EcoRI/BamHI fragment containing the K gene was in(cid:173)
`serted into EcoRI- and BamHI-cleaved plasmid pSV2gpt, ob(cid:173)
`tained from R. Mulligan (24). The resulting plasmid, shown in
`Fig. 1, is called pSV2gpt-K41. Ten micrograms of DNA from
`this plasmid was transfected into 5 x 107 81A-2 cells by a mod(cid:173)
`ification of the calcium phosphate technique of Graham and Van
`der Eb (25). Cells were washed in phosphate-buffered saline
`(0.14 M NaCI/2.5 mM KCI/16 mM Na2HP04/1.4 mM
`KH 2P04), resuspended in 1 ml of transfection cocktail [made
`by adding DNA to 1 ml of Hepes-buffered saline, then adding
`62.5 JJ-1 of2 M CaC12 (26)] and incubated 15 min at room tem(cid:173)
`perature. Then 10 ml of medium was added and the cells were
`incubated at 37"C for 4 hr. Cells were then washed in phos(cid:173)
`phate-buffered saline, incubated at 37°C for 2 min in 2 ml of
`Hepes-buffered saline with glycerol (26), and washed again in
`phosphate-buffered saline. Cells were then resuspended in 10
`ml of nonselective medium, grown for 3 days, and then trans(cid:173)
`ferred to selective medium [RPMI 1640 medium supplemented
`with mycophenolic acid at 2 JJ-g/ml, xanthine at 250 JJ-g/ml,
`hypoxanthine at 15 JJ-g/ml, and glutamine at 150 JJ-g/ml (27)].
`Transfected and mock-transfected 81A-2 cells were passaged in
`selective medium for approximately 3 weeks, until the mock(cid:173)
`transfected cells had died. The transfected cells were then
`cloned by limiting dilution in nonselective medium.
`RNA. Total cellular poly(A)-containing RNA was isolated by
`the guanidine·HCI procedure (28), fractionated according to
`size by electrophoresis in formaldehyde gels (29), transferred
`to nitrocellulose, and hybridized with 32P-Iabeled DNA probes
`as described (30).
`
`RESULTS
`To examine expression of a K gene from transfected plasmid
`DNA, the plasmid pSV2gpt-K41 was constructed to contain the
`rearranged chromosomal K light chain gene from the myeloma
`MOPC41 (12) and the selectable marker gene gpt, the gene
`from Escherichia coli that codes for the enzyme xanthine-gua(cid:173)
`nine phosphoribosyltransferase [CPT; EC 2.4.2.22 (27)] (Fig.
`1). In mammalian cells grown in media containing inhibitors of
`purine synthesis (here, mycophenolic acid), expression of the
`gpt gene allows selective cell growth using xanthine as the pre-
`
`The publication costs of this article were defrayed in part by page charge
`payment. This article must therefore be hereby marked "advertise(cid:173)
`ment" in accordance with 18 U. S. C. §1734 solely to indicate this fact.
`
`Abbreviations: A-MuLV, Abelson murine leukemia virus; GPT, xan(cid:173)
`thine-guanine phosphoribosyltransferase; kb, kilobase(s); kbp, kilobase
`pair(s); LPS, bacterial lipopolysaccharide; SV40, simian virus 40.
`
`7862
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`Sanofi/Regeneron Ex. 1020, pg 591
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`Merck Ex. 1020, pg 617
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`
`
`Immunology: Rice and Baltimore
`
`Proc. NatL Acad. Sci. USA 79 (1982)
`
`7863
`
`EcoRI
`
`SV40 early
`promoter
`
`K gene
`
`FIG. 1. Structure of the plasmid pSV2gpt-K41 (11.4 kbp). Mouse
`DNA sequences containing the rearranged K light chain gene from the
`myeloma MOPC41 are represented by the heavy dark line. The leader
`(L), variable plus joining region (VJ), and constant region (C.) of the
`K gene are indicated. Simian virus 40 (SV40) sequences, represented
`by hatched regions, include DNA segments containing the early pro(cid:173)
`moter, the small tumor antigen intervening sequence, and sequences
`for termination and polyadenylylation of SV40 early transcripts. The
`gpt gene from Escherichia coli is shown as a stippled region. ori, Origin
`of replication; amp', ampicillin resistance. Transcription units are in(cid:173)
`dicated by wavy lines.
`
`cursor for synthesis of guanine nucleotides (27). In pSV2gpt, the
`parental plasmid used for this construction, the gpt gene is tran(cid:173)
`scribed from the SV40 early promoter and is followed by are(cid:173)
`gion of SV40 DNA containing the small tumor antigen inter(cid:173)
`vening sequence and signal sequences for transcript termination
`and polyadenylylation (24). To reduce the possibility of tran(cid:173)
`scription of the K light chain gene from promoters other than
`its own, plasmid pSV2gpt-K41 was designed so that transcrip(cid:173)
`tion from the SV 40 promoter is in opposite orientation from that
`required for K gene expression.
`The 81A-2 cell line used as recipient of the transfected DNA
`is an A-MuLV-transformed murine lymphoid cell that synthe(cid:173)
`sizes y2b heavy chain but no light chain [no C. alleles can be
`detected by hybridization (ref. 22 and unpublished data)]. Plas(cid:173)
`mid pSV2gpt-K41 DNA was introduced into 81A-2 cells by the
`calcium phosphate coprecipitation technique (25). Cells ex(cid:173)
`pressing the gpt gene were selected by growth in medium con(cid:173)
`taining mycophenolic acid and then cloned by limiting dilution.
`When DNA from three selected cell lines was prepared and
`analyzed by hybridization with a K probe, all three lines were
`found to have acquired one or a small number of the introduced
`K genes. From the pattern of the hybridizing bands, at least two
`of three lines were judged to be independent transfectants.
`Eight cell lines were assayed for CPT enzyme activity by the
`in situ gel assay of Mulligan and Berg (24); all eight were positive
`(data not shown).
`When the eight gpt+ cell lines were assayed for production
`of K protein by metabolic labeling with [35S]methionine and im(cid:173)
`munoprecipitation with anti-K antiserum, all eight were found
`to synthesize a polypeptide which (i) was precipitable with anti(cid:173)
`K antiserum (Fig. 2, lane d for clone K-2 and data not shown for
`the others); (ii) comigrated with the K chain produced by the
`myeloma MPCll (apparent Mr 23,000) (Fig. 2, lane a); and (iii)
`was not evident in the nontransfected 81A-2 parent cell line
`(Fig. 2, lane b). In the original autoradiogram, the background
`bands in theM r 23,000 region are much fainter than reproduced
`here. Because the 81A-2 cells lack C. alleles, none of the back(cid:173)
`ground bands are K light chain. Precipitation of the Mr 23,000
`
`~ ..,.
`,....; s
`G u
`0..
`;:,...
`0
`::;
`::;
`"" ""
`" "
`-;:;
`-;:;
`-f
`..a
`..a
`"'
`"'
`:g
`lf1
`"2
`"2
`0..
`" "
`"'
`>--"
`+ + + +
`""
`""
`N
`"'
`"'
`"'
`"'
`"'
`""
`u ~ 4: ~ ~ ~ ~ ~
`0.. ::; ~ oc
`
`lf1
`0..
`>--"
`
`,....;
`,....;
`
`N
`
`N
`
`N
`
`N
`
`N
`
`N
`
`N
`
`00
`
`00
`
`00
`
`00
`
`N
`
`00 .. M,
`
`1
`•
`
`i
`
`x w- 3
`
`•
`
`-120
`
`-86
`-65
`-48.5
`
`...
`
`-24
`
`-18.5
`
`a
`
`b
`
`d
`
`e
`
`g h
`
`FIG. 2. Polyacrylamide gel electrophoresis of lg polypeptides syn(cid:173)
`thesized by SlA-2 cells and the transfectant K-2. Cytoplasmic extracts
`were prepared from cells labeled with [35S]methionine, immunopre(cid:173)
`cipitated, and analyzed by NaDodS04/polyacrylamide gel electropho(cid:173)
`resis. Lane a, myeloma MPCll extract immunoprecipitated with anti(cid:173)
`K antiserum; lanes band c, extract from parent A-MuL V -transformant
`81A-2 grown in the absence (lane b) and presence (lane c) of SalTTUinella
`typhimurium lipopolysaccharide (LPS) and immunoprecipitated with
`anti-K antiserum; lanes d and e, extract from the transfectant K-2
`grown in the absence (lane d) and presence (lane e) of LPS and im(cid:173)
`munoprecipitated with anti-K antiserum; lanes f and g, extract from
`the transfectant K-2 mixed with unlabeled MPCll extract (lane f) or
`unlabeled MOPC104E extract (lane g) and immunoprecipitated with
`anti-K antiserum; lane h, extract from the transfectant K-2 immuno(cid:173)
`precipitated with anti-A1 antiserum. Sizes of molecular weight marker
`proteins are indicated.
`
`polypeptide by anti-K serum was blocked by competition with
`an unlabeled MPCll protein extract (containing authentic K
`light chains) but not by an unlabeled MOPC104E protein ex(cid:173)
`tract (containing A1 light chains) (Fig. 2, lanes f and g). Also, the
`apparent K chain was not precipitable by anti-A1 antiserum (Fig.
`2, lane h). Therefore, the Mr 23,000 polypeptide appears to be
`the protein product of the K light chain gene transfected into
`the 81A-2 cells.
`To examine the RNA produced from the transfected K gene,
`poly(A)-containing mRNA was prepared from the parent 81A-
`2 cell line and the transfectant K-2. The RNA was size-fraction(cid:173)
`ated by agarose gel electrophoresis, transferred to nitrocellu(cid:173)
`lose, and hybridized with a 32P-labeled plasmid DNA probe
`containing the K constant region (C.), the K joining (J.) seg(cid:173)
`ments, and the sequence that intervenes between them. No
`hybridization was detected to the RNA prepared from the par-
`
`Sanofi/Regeneron Ex. 1020, pg 592
`
`Merck Ex. 1020, pg 618
`
`
`
`7864
`
`Immunology: Rice and Baltimore
`
`Proc. Natl. Acad. Sci. USA 79 (1982)
`
`116
`
`66
`
`4:)
`
`•
`
`a
`
`h
`
`d
`
`Fl?. 4. Polyacrylamide gel electrophoresis of nonreduced Ig syn(cid:173)
`thesiZed by the K-2 transfectant. Cytoplasmic extracts were prepared
`a~ for Fig. 2. Lanes a a~d b, extracts from the parent 81A-2 cells grown
`Wit~out O~e a) and w1th (lane b) LPS and immunoprecipitated with
`a~ti-K antiserum; lane~ c and d, extract from K-2 transfectants grown
`Wit~out (i~e c) and w1th (lane d) LPS and immunoprecipitated with
`anti-K antiserum; lane e, myeloma MPCll extract immunoprecipi(cid:173)
`tated with anti-K antiserum.
`
`detected in the parental cells, but the K-2 cells contained in(cid:173)
`creased levels of the 1.2- and 1.9-kb species (Fig. 3, lane b).
`Interestingly, the level of the 1. 9-kb RNA species increased
`even more than that of the presumably authentic 1.2-kb RNA
`species.
`Because the transfected cells were producing both y2b heavy
`chains and K light chains, it was possible that the cells could
`assemble the heavy and light chains into IgG. To examine this
`question, samples of [35S]methionine-labeled protein extracts
`were immunoprecipitated with anti-K antiserum and the non(cid:173)
`reduced samples were subjected to NaDodS04/polyacryl(cid:173)
`amide gel electrophoresis. The parental 81A-2 cells produced
`a protein of approximately the correct size for y2b heavy chain
`dimers (Fig. 4, lanes a and b; the darker appearance of lane a
`is due to more labeled extract present). The K-2 cells produced
`a protein that migrated slightly faster than the lgG2b produced
`by the myeloma MPCll (Fig. 4, lanes d and e) but slower than
`the bulk of the rabbit lgG antiserum visualized by staining (not
`shown). In other experiments (not shown) no free K chain was
`found in the K-2 cells, although a significant amount was present
`in MPCll cells. Essentially all of the K chain produced in the
`K-2 cells appears to be assembled into IgG2b.
`
`DISCUSSION
`The major result of these studies is the demonstration that a
`functional K gene can be introduced into a lymphoid cell line
`in which it will be continuously expressed. This opens the pos(cid:173)
`sibility of examining control and rearrangement mechanisms in
`
`Sanofi/Regeneron Ex. 1020, pg 593
`
`FIG. 3. Analysis of K RNA transcripts in the transfectant K-2.
`Poly(A)-containing RNA was isolated from cells, size-fractionated by
`aga~~ gel ~lect[ophoresis, transferred to nitrocellulose paper, and
`hybndized with :!JI-labeled DNA from a plasmid containing the se(cid:173)
`quence fromJ. through C •. Lanes a and b, RNA from the transfectant
`K-2 grown in the absence (lane a) or presence (lane b) of LPS. Lane c,
`RNA from the K-producing A-MuLV-transformed cell line 18-48.
`
`ent line 81A-2 (not shown), but RNA from the K-2line contained
`hybridizing species of approximately 1.2, 1.9, and 2.6 kilobases
`(kb) (Fig. 3, lane a). The smaller RNA comigrated with authentic
`K mRNA from the A-MuLV-transformed cell line 18-48 (Fig.
`3, lane c).[The smaller 0.8-kb RNA in 18-48 is an aberrantly
`small K transcript (5) .] In other experiments, both the 1. 9-kb
`and the 2.6-kb RNAs were found to hybridize strongly to a probe
`specific for the intervening sequence between J. and C. and
`hybridize weakly to a pBR322 DNA probe. Hence, these higher
`molecular weight species are some type of aberrant RNA. The
`1.2-kb species, however, appears to be an authentic K mRNA
`transcript in that it hybridizes only to the probe containing K
`coding sequences and not to the intervening sequence probe
`or pBR322.
`Because many A-MuLV-transformed lymphoid cell lines in(cid:173)
`crease Ig production when LPS is added to the medium (18, 31),
`we investigated the effects of LPS on K chain synthesis in the
`transfected line. The parent line 81A-2 increases synthesis of
`'}'2b heavy chain protein and mRNA upon induction by LPS
`(22) (Fig. 2, lane c). When LPS was added to the K-2 cells K
`light chain synthesis increased approximately 5-fold, to a le~el
`approximately 1/15th that of the myeloma MPCll (Fig. 2, lane
`e). To determine if the LPS-induced increase in K chain syn(cid:173)
`thesis was due to an increased content of specific mRNA, the
`mRNA fraction was prepared from LPS-treated 81A-2 parent
`cells and transfected K-2 cells. Again, no K mRNA species was
`
`Merck Ex. 1020, pg 619
`
`
`
`Immunology: Rice and Baltimore
`
`Proc. Natl. Acad. Sci. USA 79 (1982)
`
`7865
`
`lymphoid cells by using inserted genetic elements.
`The K gene introduced into 81A-2 cells apparently functions
`normally in spite of being in a very unusual context. The gene
`was in an SV40/pBR322 vector that then integrated into a pre(cid:173)
`sumably random site in the cell genome, a site unlikely to be
`related to the normal location of the K gene in chromosome 6.
`In spite of its unusual context, the introduced gene was ex(cid:173)
`pressed at about the same level as the resident y2b heavy chain
`gene. The K gene was apparently using its own promoter be(cid:173)
`cause in the construction no promoter was provided that faced
`·in the correct direction. It is possible that the SV40 DNA se(cid:173)
`quences present might have provided some enhancing function
`for K expression (32).
`The introduced K gene not only was expressed at a basal level
`but also· was inducible by LPS. The mechanism and function
`of this induction system are far from clear, but the ability of the
`introduced K gene to respond indicates that sufficient K~related
`DNA sequences to provide for LPS inducibility were included
`in the construct.. The construct contained, in addition to the V.,
`J., and C K coding segments, the intervening sequence between
`the coding regions and about l-L5 kb of DNA both 5' of VKJ.
`and 3' of C •. Any of this extra DNA could be involved in pro(cid:173)
`moter and control functions, but the results make it unlikely that
`any sequences important for K expression exist more than 1.5
`kb to either side of the coding region.
`LPS control of heavy chain expression in 81A-2 cells is allele
`specific and correlates with a deletion in the intervening se(cid:173)
`quence between V HDJH and C,. (22, 33). The productively rear(cid:173)
`ranged heavy chain allele is inducible by LPS and contains this
`deletion, whereas the other allele, containing a nonproductive
`rearrangement, lacks the deletion and is not inducible by LPS.
`Therefore, LPS inducibility of heavy chain seems to be deter(cid:173)
`mined at the DNA level. Whether the introduced K gene is
`responding directly to LPS or to the product of the heavy chain
`allele is an open question. The possibility that transcription of
`the light chain gene is controlled by a product of the heavy chain
`locus is an interesting possibility and needs further investigation.
`
`We thank Drs. F. Alt, M. Boss, S. Lewis, and R. Mulligan for helpful
`discussions. We thank Dr. R. Mulligan for plasmid pSV2gpt and Dr.
`P. Leder for the cloned MOPC41 K gene. This work was supported by
`Grant MV-34N from the American Cancer Society, Grant CA14051
`(core grant to S. E. Luria) from the National Cancer Institute, and a
`contribution from the Whitehead Charitable Foundation. D.R. was
`supported by a Helen Hay Whitney Postdoctoral Fellowship. D.B. is
`an American Cancer Society Research Professor.
`
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`Sanofi/Regeneron Ex. 1020, pg 594
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`Merck Ex. 1020, pg 620