Untranslated immunoglobulin kappa light chain mRNA in a lambda light chain-producing mouse myeloma, MOPC104E

Fourteen clones were isolated in culture from a mouse myeloma, MOPC104E. All clones had kappa and lambda types of light chain mRNAs in approximately equimolar quantity as assayed by hybridization with specific complementary DNA (cDNA). However, the myeloma produces and secretes only lambda-type light chain protein. Both kappa- and lambda-type mRNAs in these clones were indistinguishable from kappa- and lambda-type mRNAs of other myelomas with respect to (a) adsorption to oligo-(dT) cellulose, (b) molecular size (12.6 S), and (c) thermal stability of the hybrids formed with corresponding cDNA. The kappa chain mRNA of MOPC104E cells, however, was translated very inefficiently both in vivo and in vitro, whereas the lambda chain mRNA was translated efficiently. These results indicate that each cell of MOPC104E myeloma synthesizes a crippled kappa chain mRNA in addition to a normal lambda chain mRNA.     

Cloning of immunoglobulin kappa light chain genes from mouse liver and myeloma MOPC 173

The organization of the kappa chain constant region gene was compared in DNA from an immunoglobulin-producing mouse myeloma (MOPC 173) and from liver. In situ hybridization using the Southern blotting technique revealed constant region gene-containing EcoRI-DNA fragments of 14 and 20 kb in the myeloma tissue whereas one EcoRI-DNA fragment with a length of 15 kb was found in liver DNA. After enrichment by RPC-5 chromatography and preparative electrophoresis the 14 kb fragment from MOPC 173 DNA and the 15 kb fragment from liver DNA were cloned in the bacteriophage lambda vector Charon 4A using in vitro packaging. Extensive characterization of the two fragments by restriction endonuclease mapping, in situ hybridization, and electron microscopy (R-loop and heteroduplex) showed that both fragments contain the constant region but no MOPC 173 variable region gene. Both fragments are homologous over a length of 12.5 kb including the constant region but differ from one another starting about 2.7 kb from the 5' end of the constant region gene. This indicates that the 14 kb EcoRI-DNA fragment from the myeloma tissue clearly resulted from somatic DNA rearrangement although it does not seem to carry the MOPC 173 variable region gene. These observations suggest that somatic DNA rearrangement of immunoglobulin light chain genes can involve both homologous chromosomes.Images     

Evidence for noncontiguous variable and constant region genes in both germ line and myeloma DNA.

A study has been made of the hybridization of mouse light chain cDNA to restriction enzyme digests of DNA. DNA was digested with B. st (specificity GGATCC) and fractionated on preparative agarose gels for hybridization analysis. Experiments with liver or kidney DNA yielded two peaks of hybridization with V+C cDNA corresponding to the C_κ gene and to the germ line V gene homologous to the MOPC21 V gene. Since there is no site for digestion by B. st within the MOPC21 V or C genes, this result shows that the germ line DNA carries separately the V²¹ and C_κ genes.The hybridization profiles of two different myeloma DNAs (MOPC21 and AdjPC5) differed from those of the germ line DNA. In both myelomas, only one hybridization peak was observed and no peaks corresponding to the germ line pattern were seen. The new pattern of hybridization implies that the events involved in maturation of antibody-producing cells includes rearrangement of the V and C genes.To study whether this proposed rearrangement of DNA results in contiguous V and C genes in producing cells, discrete V+C cDNA size classes (prepared with MOPC21 mRNA) were hybridized to both unfractionated restriction digested MOPC21 DNA and to the partially purified L chain gene of MOPC21 DNA. The length of the cDNA rendered resistant to single-strand-specific S₁ nuclease was determined. In no case was the full length of V+C cDNA protected from nuclease; instead, a fragment of about 290 bases (C region length) plus smaller fragments were generated. These results indicate that the rearrangement of L chain genes, which seems to occur in myeloma cells, may well not produce contiguous V and C genes in the DNA.     

Complete sequence of an immunoglobulin mRNA using specific priming and the dideoxynucleotide method of RNA sequencing.

The complete sequence of the mouse immunoglobulin kappa light chain MOPC 21 messenger RNA has been determined using a chain termination method and chemically synthesised deoxyoligonucleotides to initiate the synthesis of a DNA molecule complementary to the mRNA template. Five such oligonucleotide primers have been used for the sequence analysis of this messenger RNA. The approach is excellent for comparative studies of mouse k-chain mRNAs because they can be made on impure mRNA preparations. The MOPC 21 light chain mRNA is 943 nucleotides in length excluding the poly(A) region. An unexpected finding was that there are only three bases in the 5' non-coding region and its significance in terms of ribosome binding is discussed; 87 code for the precursor or leader sequence of the protein, 642 for the mature protein and 211 for the 3' non-coding region. The codons for the precursor region allows the previously undetermined amino acid sequence to be predicted. In common with other precursor regions a high proportion of the predicted amino acids are hydrophobic.     

Arrangement of lambda light chain genes in mutant clones of the MOPC 315 mouse myeloma cells

The synthesis of lambda light chains and the arrangement of the lambda-chain genes was examined in cells of the mouse myeloma MOPC 315, which is an alpha lambda 2 producer, and in several mutants derived from it. The mutants produce lambda 2 chains only (MOPC 315.26, MOPC 315.34, and MOPC 315.37) or fail to produce alpha and lambda 2 chains (MOPC 315.25 and MOPC 315.36). Messenger RNA from the lambda 2 chain-producing cells directed the synthesis of a lambda 2 chain precursor and a fragment of the lambda 1 chain (lambda 1 F) in a wheat embryo cellfree system, whereas mRNA from the cells that do not produce lambda 2 chains directed the synthesis of lambda 1 F only. DNA from the parental MOPC 315 cells and from the lambda 2 chain-producing cells contained discrete EcoRI restriction fragments coding for rearranged lambda 1 and lambda 23 chain genes and their respective germ-line V and J-C regions. DNA from the no-Ig-producing cells contained fragments coding for the rearranged lambda 1 chain gene and the germ-line V lambda 2 region, but it lacked the sequences coding for the rearranged lambda 2 chain gene and the germ-line V lambda 1 and J-C lambda 1 regions. These results suggest that rearrangements of the lambda 1 and lambda 2 chain genes occur on different chromosomes in MOPC 315 cells and imply that rearrangements of the lambda 1 and lambda 2 chain genes on the same chromosome may be mutually exclusive.     

Two rearranged immunoglobulin kappa light chain genes in one mouse myeloma.

The organization of immunoglobulin gene segments coding for kappa light chains has been studied in uncloned and cloned DNA from mouse liver and a mouse myeloma. It is known that the C (constant, ref. 2) gene segment is present in the tumor DNA on two EcoRI fragments of 14 and 20 kb and in liver DNA on a 15 kb fragment. The 14 kb myeloma and the 15 kb liver fragment have been cloned previously. Here we report on the cloning of the 20 kb myeloma fragment and present detailed restriction maps covering about 22 kb of DNA surrounding the C gene segment in liver and tumor DNA. The region on the 20 kb fragment has been localized where a DNA rearrangement had occurred. The presence of two rearranged kappa light chain genes in one tumor is discussed in regard to the molecular basis of allelic exclusion.     

Cloning and characterization of five overlapping cDNAs specific for the human pro alpha 1(I) collagen chain.

We report the cloning of five overlapping cDNAs bearing sequences specific for the human pro alpha 1(I) collagen chain. Poly-A RNA enriched for collagen sequences was purified from normal human fibroblasts and used as template to synthesize double stranded cDNA. The cDNA was inserted into the Eco RI site of pBR 322 by blunt-ending and dG:dC tailing. The clones were screened by colony hybridization using the original RNA population and the resulting five positive clones subjected to restriction endonuclease mapping analysis and DNA sequencing. These overlapping clones cover from residue 247 in the alpha chain to part of the 3' end untranslated region of the pro alpha 1(I) mRNA for a total of 3400 nucleotides.     

Molecular cloning of rabbit gamma heavy chain mRNA.

A cDNA library of rabbit spleen mRNA was screened for immunoglobulin heavy chain sequences. In this paper we report the nucleotide sequence of two cDNA clones containing part of the constant region of the rabbit gamma heavy chain mRNA. The sequence encodes part of the CH2 domain (amino acids 268 to 340), the entire CH3 domain (amino acids 341 to 447) and the 3' untranslated region. This nucleotide sequence has been compared to the corresponding sequences of mouse gamma 1, gamma 2a and gamma 2b genes. The homologies between rabbit gamma chain gene sequence and each of the mouse gamma chain gene sequences are of the same magnitude order. This comparison shows that the CH2 domains are more homologous to each other than CH3 domains or 3' untranslated sequences. The presence of species specific nucleotide positions suggests that mouse gamma chain genes could have evolved from a common ancestor shortly after the mouse-rabbit species separation. Genomic blot analysis of rabbit liver DNA with the rabbit C gamma probes shows a limited number of related sequences, with little restriction site polymorphism between individual rabbits.     

Nucleotide sequence of a mouse kappa light chain cDNA cloned in a bacterial plasmid.

A mouse MOPC21 cDNA previously cloned in plasmid pMB9(Higuchi $\text{et}\text{al.}$, Proc. Natl. Acad. Sci. 73 (1976) 2136–2140; Wall $\text{et}\text{al.}$, Nucleic Acid Res. 5 (1978) 3113–3128) and is designated pL21-3 has been extensively characterized. Cleavage of pL21-3 with Hpall has shown the insert to be 910 basepairs long, consistent with the length of the entire variable and constant regions and the untranslated regions. Digestion of pL21-3 with various restriction endonucleases has established that the insert sequence starts from parts of the 5′ leader region and extends downstream to include the untranslated 3′ terminus. 131 nucleotides in the variable region corresponding to amino acids 49–91 have been determined.     

Complete nucleotide sequence of mouse immunoglobulin mu gene and comparison with other immunoglobulin heavy chain genes

We have determined the complete nucleotides sequence (2168 bases) of the immunoglobulin mu gene cloned from newborn mouse DNA. The cloned 13kb fragment contained the entire constant region gene sequence that is interrupted by three intervening sequences at the junction of domains as previously shown in the gamma 1, gamma 2 b and alpha genes. The amino acid sequence predicted by the nucleotide sequence agrees with that of the mu chain secreted by a myeloma MOPC104E except for 8 residues out of 448 residues. The homologous domains of the mu, gamma 1 and gamma 2b genes are more similar to each other than the different domains of the mu genes are. The result implicates that the class of the immunoglobulin heavy chain genes diverged after the heavy chain genes established the multi-domain structure. The short intervening sequences of the mu and gamma genes are more conserved than the coding sequences except for the COOH-terminal domains. The results implicate that the nucleotide sequence of the intervening sequence is under selective pressure, possibly to maintain a secondary structure of the nuclear RNA to be spliced.     

Cloning and sequence of the cDNA corresponding to the variable region of immunoglobulin heavy chain MPC11.

Poly(A)-containing mRNA from mouse myeloma MPC11 was transcribed into cDNA which was cloned in the PstI site of the plasmid pBR322. The transformants were screened by hybridization with a cDNA fragment, derived from plasmid p gamma(11)7, corresponding to the 5' portion of the constant region of MPC11 heavy chain. Several positive transformants were found to contain various lengths of the variable region of the heavy chain. We describe the structure and sequence of one of these clones, pV(11)2, which contains cDNA corresponding to the entire variable region of MPC11 heavy chain and extends to codon 248 in the constant region. The protein sequence deduced from the DNA sequence indicates that the variable region of MPC11 heavy chain contains 121 amino acids and belongs to subgroup II of mouse heavy chains. Comparison of this sequence with other heavy chain sequences suggests a J (joining) segment of 16 residues which overlaps five residues of the third hypervariable region. The cDNA sequence shows that there is no discontinuity between the end of the variable region and the beginning of the constant region.     

Somatic DNA rearrangement generates functional rat immunoglobulin kappa chain genes: the J kappa gene cluster is longer in rat than in mouse

The kappa immunoglobulin (Ig) genes from rat kidney and from rat myeloma cells were cloned and analyzed. In kidney DNA one C kappa species is observed by Southern blotting and cloning in phage vectors; this gene most likely represents the embryonic configuration. In the IR52 myeloma DNA two C kappa species are observed: one in the same configuration seen in kidney and one which has undergone a rearrangement. This somatic rearrangement has brought the expressed V region to within 2.7 kb 5' of the C kappa coding region; the rearrangement site is within the J kappa cluster which we have mapped. The rat somatic Ig rearrangement, therefore, closely resembles that seen in mouse Ig genes. In the rat embryonic fragment two J kappa segments were mapped at 2 and 4.3 kb 5' from the C kappa coding region. Therefore, the rat J kappa cluster extends over about 2.3 kb, a region much longer than the 1.4 kb of the mouse and human J kappa clusters. In the region between C kappa and the expressed J kappa of IR52 myeloma DNA, and XbaI site present in the embryonic kappa gene has been lost. A somatic mutation has therefore occurred in the intervening sequence DNA approx. 0.7 kb 3' from the V/J recombination site. Southern blots of rat kidney DNA hybridized with different rat V kappa probes showed non-overlapping sets of bands which correspond to different subgroups, each composed of 8-10 closely related V kappa genes.     

Molecular cloning and nucleotide sequencing of human immunoglobulin epsilon chain cDNA.

DNA complementary to mRNA of human immunoglobulin E heavy chain (epsilon chain) isolated and purified from U266 cells has been synthesized and inserted into the PstI site of pBR322 by G-C tailing. This recombinant plasmid was used to transform E. coli chi 1776 to screen 1445 tetracycline resistant colonies. Nine clones (pGETI - 9) containing cDNA coding for the human epsilon chain were recognized by colony hybridization and Southern blotting analysis with a nick-translated human IgE genome fragment. The nucleotide sequence of the longest cDNA contained in pGET2 was determined. The results indicate that the sequence of 1657 nucleotides codes for 494 amino acids covering a part of the variable region and all of the constant region of the human epsilon chain. Most of the amino acid sequence deduced from the nucleotide sequence is in substantial agreement with that reported. Furthermore a termination codon after the -COOH terminal amino acid marks the beginning of a 3' untranslated region of 125 nucleotides with a poly A tail. Taking this into account, the structure of the human epsilon chain mRNA, except a part of the 5' end, is conserved fairly well in the cDNA insert in pGET2.     

Characterization of new mouse V kappa groups

A lambda gt10 BXSB spleen cDNA library was screened with a DNA probe for the C kappa region. Forty individual C kappa+ phages were tested for hybridization with DNA probes representing 11 V kappa region groups. Of the phage inserts large enough to contain V kappa region sequences, 3 were negative for hybridization with all 11 V kappa region probes. The inserts from those three were subcloned, sequenced, and compared with V kappa region sequences in the gene bank. One was identical to 87.92.6 for the region sequenced (a member of V kappa RF). The second showed 93.8% sequence similarity with AN04 and called V kappa 32. The third called V kappa 33 showed 76% sequence similarity with the human sequence V52 and 73.2% sequence similarity with the mouse sequence L6. An insert from V kappa 32 containing the 5' untranslated regions through the codon for Cys 88 of the V kappa region was used as a probe in Southern blot analysis of genomic DNA from inbred and congenic strains of mice. V kappa 32 is a four to eight member group and some of the members are retained in the B6.PL-Ly2a congenic and missing from the B6.PL (85NS) congenic consistent with a map location near V kappa 28. The same filters were hybridized with the insert from V kappa 33 containing 5' untranslated region through the codon for Ser 93 of the V kappa region. V kappa 33 is a one to three member group and using the B6.PL congenics maps with the polymorphic fragments of V kappa 32 and V kappa 28.     

Identification of a novel substitution in the constant region of a gene coding for an amyloidogenic kappa1 light chain.

Current concepts regarding the association between immunoglobulin (Ig) light chain structure and AL amyloidosis (AL) emphasize Ig variable region amino acid substitutions because the majority of light chain amyloid fibrils that have been sequenced contain amino termini of the variable region with only small amounts of the constant region. In this report, we describe a patient with rapidly progressive AL whose amyloid deposits contained primarily monoclonal kappa light chain constant region fragments. We sequenced and analyzed this AL protein, determining that it was an O18-O8 kappa1 variant and that the constant region possessed an unusual Ser-->Asn substitution at position 177. Using pre-mortem bone marrow cells, we cloned and sequenced the cDNA for this AL protein (HCAK1) and, using DNA from post-mortem somatic tissue, we cloned and sequenced the patient's kappa germline O18-O8 donor and kappa constant region (Ckappa) gene segments. The cDNA that coded for HCAK1 contained a variable region that was derived from O18-O8, showing 96.1% homology to germline, and a Ckappa that had a nucleotide substitution (AGC to AAC), resulting in the 177Ser-->Asn replacement. Two Ckappa genes were cloned from somatic tissue DNA, one identical to a known Ckappa sequence and another containing this substitution which likely is a new Ckappa allotype. Our findings indicate that further investigation is warranted into the contributions genetic polymorphisms and light chain constant regions may make to amyloidogenesis.     

Two different forms of beta myosin heavy chain are expressed in human striated muscle

Summary We have found evidence for two beta-like myosin heavy chains in humans, one cardiac and one skeletal. The cDNA sequences of the cardiac beta myosin heavy chain cDNA clone pHMC3 and the skeletal beta-like myosin heavy chain cDNA clone pSMHCZ, were compared to each other. It was found that the 3 untranslated regions as well as 482 nucleotides specifying the carboxyl coding region, were 100% homologous. Further examination revealed that the skeletal clone pSMHCZ diverges from the human cardiac beta myosin heavy chain cDNA clone pHMC3 at the 5 end. We present evidence in this report which indicates that the cardiac beta myosin heavy chain mRNA is expressed in skeletal muscle tissues. The human cardiac beta myosin heavy chain cDNA clone, pHMC3, which codes for a portion of the light meromyosin section of the myosin heavy chain, was used as a probe for S1 nuclease mapping studies with RNA derived from cardiac tissue, smooth muscle and skeletal muscle tissues consisting of fast-twitch, slow-twitch and mixed fast- and slow-twitch muscle fibres. Two probes were used to examine the expression of the mRNA. One probe (406 nucleotides) constitutes the 3 untranslated region and a portion of the coding region of the beta cardiac myosin heavy chain cDNA clone, which is 100% homologous to pSMHCZ, the skeletal cDNA clone. The other constitutes the majority of the coding region (1017 nucleotides) of the cardiac clone pHMC3 in which the first 216 nucleotides from the labelled end are 100% homologous to the skeletal clone pSMHCZ. In the soleus muscle, which is rich in slow-twitch type I muscle fibres, the expression of the cardiac beta myosin heavy chain mRNA was very prominent. In gastrocnemius muscle, a mixed fibre muscle, the expression of this mRNA was detected to a lesser degree than that for the soleus muscle. In vastus lateralis and vastus medialis, which consist of predominantly type II, fast-twitch fibres, there were trace amounts of the cardiac beta myosin heavy chain mRNA. When expression of this mRNA was tested in smooth muscle tissue none could be detected.     

Purification of immunuglobulin light chain messenger RNA by immunoprecipitation from mouse myeloma tumor, MOPC-31C.

Polysomes producing IgGl(kappa) myeloma protein were specifically selected by an immunoprecipitation method, and immunoglobulin light chain mRNA was purified from the precipitated polysomes. The purified mRNA migrated predominantly as a single band and the molecular weight of this mRNA was calculated to be 410.000 by polyacrylamide gel electrophoresis in 98% formamide. A protein possessing a molecular weight of 25,000, which is the size of the light chain precursor, was synthesized as a major product of translation in a wheat germ cell-free system. DNA complementary to the mRNA (cDNA) was prepared with avian myeloblastosis virus RNA-dependent DNA polymerase. This cDNA had an average size of 8.3S as determined by sedimentation through an alkaline sucrose gradient. Using this cDNA, Crt 1/2 values of template RNA and RNA from various preparations were calculated from the results of molecular hybridization. The relative content of the mRNA increased 4,4-fold during the immunoprecipitation of polysomes.     

Rearranged and germline immunoglobulin kappa genes: different states of DNase I sensitivity of constant kappa genes in immunocompetent and nonimmune cells

The rearrangement of a variable (V) and a constant (C) gene appears to be a necessary prerequisite for immunoglobulin gene expression. Multiple different rearranged kappa genes were found in several mouse myelomas, although these cells produce only one type of kappa chain [Wilson, R., Miller, J., & Storb, U. (1979) Biochemistry 18, 5013--5021]. It is therefore of interest to understand how only one allele within a lymphoid cell becomes expressed, while the other allele remains nonfunctional ("allelic exclusion"). We have studied the chromatin conformation of kappa genes by making use of the preferential digestion of potentially active genes by DNase I described, for example, for globin genes [Weintraub, H., & Groudine, M. (1976) Science (Washington, D.C.) 193, 848--856]. The DNase I sensitivity of kappa genes in myeloma tumors, in a B cell lymphoma, and in liver was determined by hybridization with DNA on Southern blots. It was found that rearranged C kappa genes are DNase I sensitive in myelomas in which several kappa genes are rearranged, regardless of whether the rearranged genes code for the kappa chains synthesized by the cell. Furthermore, the C kappa gene in germline configuration is also DNase I sensitive in a B cell lymphoma; i.e., it is in the same chromatin state as the rearranged C kappa gene which probably codes for the kappa chains produced by the cell. The altered chromatin state appears to be localized: V kappa genes in germline context are not DNase I sensitive in myeloma or B lymphoma cells while C kappa genes present in a kappa gene cluster on the same chromosomes are sensitive. When rearranged, however, the V kappa genes are as sensitive to DNase I as are rearranged C kappa genes. V lambda and C lambda genes are not DNase I sensitive in kappa myelomas. Thus, commitment to kappa gene expression is apparently correlated with a chromatin conformation which confers increased DNase I sensitivity to the DNA in the vicinity of all C kappa genes in the cell. "Allelic exclusion" does not operate on the level of chromatin conformation which can be detected by altered DNase I sensitivity.