Rearrangement of immunoglobulin gamma 1-chain gene and mechanism for heavy-chain class switch

Cloning and nucleotide sequence determination suggest that the rearranged gamma 1-chain gene in a gamma 1-chain-producing myeloma a-pears to be formed by the recombination between the 5' flanking regions of the gamma 1- and mu-chain genes of undifferentiated cells. The recombination site is distinct from the putative J region and is a novel region that we call the S region. We have extended our previous model that explains the heavy-chain class switching by two or more successive recombination events.

Cloning immunoglobulin gamma 2b chain gene of mouse: characterization and partial sequence determination

DNA from newborn mice was digested with restriction endonuclease EcoRI, and a 6.6-kilobase fragment encoding immunoglobulin gamma 2b chain mRNA derived from MPC 11 myeloma was enriched about 100-fold by RPC-5 column chromatography and agarose gell electrophoresis. The 6.6-kilobase fragment was cloned with lambda gt WES.lambda B as EK2 vector. The cloned phage (lambda WES.IgH22) contained the constant region gene of the gamma 2b chain but not the variable region gene of MPC 11 mRNA. The constant region genes of the other gamma chains (i.e., gamma 1, gamma 2a, and gamma 3) were not present in lambda gt WES.IgH22 DNA. R-loop mapping indicates that the gamma 2b chain structural gene is divided into two parts (330 +/- 60 SD base pairs and 930 +/- 110 SD base pairs) by an intervening sequence (360 +/- 100 SD base pairs). The nucleotide sequence around the junction of the hinge region and CH2 domain was determined and shown to match the amino acid sequence of the initial part of the CH2 domain of the gamma 2b chain. The base sequence upstream from the junction, however, is unrelated to the amino acid sequence of the CH1 domain and the hinge region of all the gamma chains whose sequences have been determined. These results indicate that the gamma 2b chain gene is interrupted at the junction of the hinge region and CH2 domain by an intervening sequence. The existence of two more intervening sequences, one between the CH1 domain and the hinge region and the other between the CH2 and CH3 domains, is discussed.

Mutual homology of mouse immunoglobulin gamma-chain gene sequences

We have assessed the relative homology of mouse immunoglobulin heavy-chain gene sequence using complementary DNAs (cDNAs) synthesized against gamma-chain mRNAs (gamma 1, gamma 2a, gamma 2b, and gamma 3) purified from mouse myelomas. cDNAs complementary to the gamma-chain mRNAs did not cross-hybridize with the mu- and alpha-chain mRNAs, whereas they cross-hybridized to significant extents (22--66%) with the gamma-chain mRNAs of other subclasses. The heterologous hybrids formed, however, melt at 5--13 degrees C lower temperatures as compared to the homologous hybrids, indicating that significant portions of the heterologous hybrids are mismatched. The rates of the cross-hybridization reactions are 2- to 17-fold slower than those of the homologous hybridization reactions. Therefore, the gamma-chain gene sequences of four subclasses share a part of homology with each other, but they are different enough to be measured separately. Cross-hybridization analysis indicate that the gamma 2a and gamma 2b genes are the most closely related, while the gamma 1 and gamma 3 genes are the least related among the gamma subclass genes.

Induced synthesis of immunoglobulin messenger RNA accompanies induction of immunoglobulin production in cultured mouse spleen cells

Immunoglobulin kappa type light chain mRNA (Lkappa mRNA) accumulated in parallel with secretion of immunoglobulin M in cultured mouse spleen cells activated by lipopolysaccharide. Actinomycin D suppressed the accumulation of kappa chain mRNA completely without affecting the degradation rate of kappa chain mRNA. The half life of kappa chain mRNA was about 9 h. Available evidence indicates that lipopolysaccharide stimulates de novo synthesis of kappa chain mRNA. The accumulation of kappa chain mRNA was markedly suppressed by inhibitors of DNA or protein synthesis such as hydroxyurea, cytosine arabinoside and cycloheximide.

Organization of immunoglobulin heavy chain genes and allelic deletion model

We have assessed the number of times the gene sequence encoding constant regions of mouse immunoglobulin heavy chains gamma1, gamma2a, and gamma3 are represented in the mouse genome by hybridization kinetic analysis. All three genes are present at one copy each per haploid genome in normal tissues and myelomas producing IgM or IgG3. IgG1-producing myelomas, however, contain 1 copy each of the gamma1 and gamma2a genes and 0.5 copy of the gamma3 gene per haploid genome. IgG2b-producing myelomas contain 1 copy of the gamma2a gene and 0.5 copy each of the gamma1 and gamma3 genes per haploid genome. IgG2a-producing myelomas contain 1 copy of the gamma2a gene and 0.5 copy each of the gamma1 and gamma3 genes per haploid genome. In myelomas producing IgA, all three gamma genes are represented 0.5 times per haploid genome. In order to account for the results we propose an allelic deletion model: (i) The specific deletion of heavy chain constant region genes accompanies the recombination of a variable region gene to a constant region gene. (ii) The portion of the chromosome that resides between two joining sequences is excised out of the chromosome. (iii) The recombination occurs on one of the alleles. Based on this model we also propose that heavy chain genes are arranged on one chromosome in the following order; variable region genes, unknown spacer sequence, mu, gamma3, gamma1, gamma2b, gamma2a, and alpha.

Accumulation of immunoglobulin messenger ribonucleic acid in immunized mouse spleen

We have measured the concentration of mRNAs coding for immunoglobulins, k and lambda type light chains and gamma 1 type heavy chain, in mouse spleen cells activated by bacterial lipopolysaccharide or sheep red blood cells. These mRNAs were quantitated by hybridization to radioactive DNA complementary to highly purified immunoglobulin mRNAs from mouse myelomas. In the lipopolysaccharide-stimulated spleen cells, only light chain mRNA accumulated, whereas gamma 1 type heavy chain mRNA remained unvaried. The light chain mRNA concentration also increased in purified bone-marrow-derived lymphocytes. The lipopolysaccharide-induced light chain mRNA was similar to light chain mRNAs purified from myelomas. The accumulation and disappearance of light chain mRNA in bone-marrow-derived lymphocytes coincide with the kinetics of synthesis of immunoglobulin M which is the major species induced by lipopolysaccharide. In sheep red blood cell stimulated spleen, the specific accumulation of k type light chain and gamma 1 type heavy chain mRNAs parallels immunoglobulin G synthesis. These results seem to indicate that the increment of immunoglobulin mRNA concentration in bone-marrow-derived lymphocytes is important for induction of immunoglobulin synthesis.

Purification of immunoglobulin heavy chain messenger RNA by immunoprecipitation from the mouse myeloma tumor, MOPC-31C

Immunoglobulin heavy chain mRNA was purified from immunoprecipitated polysomes derived from the mouse myeloma tumor, MOPC-31C. The purified mRNA migrated predominantly as a single band upon polyacrylamide gel electrophoresis in 98% formamide and the molecular weight of this mRNA was calculated to be 700,000. This mRNA was as active as the purified light chain mRNA when it was employed as a template in a cell-free protein synthesizing system from wheat germ. The translation product had a molecular weight of 55,000 daltons, and migrated slightly faster than mature heavy chain upon polyacrylamide gel electrophoresis in sodium dodecylsulfate. The protein synthesized by the direction of this mRNA was shown to yield tryptic peptides corresponding to those derived from the mature heavy chain protein except that one missing peptide was replaced by another additional peptide. DNA complementary to the mRNA was synthesized by RNA-dependent DNA polymerase from avian myeloblastosis virus. Hybridization kinetic analysis between the heavy chain mRNA and its complementary DNA indicated that the RNA was essentially homogenous with rabbit globin mRNA as a standard.

Purification and translation of an immunoglobulin lambda chain messenger RNA from mouse myeloma

Here we describe the 500-fold purification of an mRNA encoding an immunoglobulin lambda light chain derived from the mouse myeloma tumor, RPC-20. Purification involves the isolation of membrane-bound polysomes, oligo(dT)-cellulose chromatography, and sucrose gradient centrifugation under conditions favoring denaturation of polynucleotide complexes. The mRNA purified in this way directs the cell-free synthesis of a polypeptide which is five or six amino acids longer than the mature form of RPC-20 light chain. In addition to directing the synthesis of a precursor-like polypeptide, the mRNA migrates on electrophoresis as a band containing approximately 1150 nucleotides, about 500 more than required to encode the mature form of the light chain.

Quantitation of constant and variable region genes for mouse immunoglobulin lambda chains

We have synthesized and characterized cDNA complementary to purified mRNA derived from the lambda chain producing myeloma tumor, RPC-20. This cDNA is of sufficinet length to encode the constant region and a major portion of the variable region sequence of the lambda gene. In addition, the expected range of cross-hybridization of this lambda probe has been shown to extend to several different members of the closely related lambda subgroup, as well as to a member of the lambda subgroup represented by MOPC-315. Since there are a minimum of seven known members of the common lambda subgroup in addition to MOPC-315, these sequences, in accordance with the germ line hypothesis, must be represented by a minimum of eight variable region genes. Using the RPC-20 cDNA probe and hybridization kinetic analysis, this sequence was found to be represented as approximately two copies per haploid genome in DNA derived from a variety of k-and lambda-producing tumors and normal tissue. Inasmuch as the cross-hybridization range of the probe has been assessed and a minimum size of the lambda subgroup determined, this observation tends to rule out separate germ line genes corresponding to each individual lambda light chain variant. Certain reservations about these conclusions are discussed.

The organization and diversity of immunoglobulin genes

We have used purified mouse immunoglobulin light chain mRNA and synthetic DNA which is complementary to it to assess the reiteration frequency of gene sequences corresponding to the kappa constant region of the mouse immunoglobulin light chain. These studies indicate that the constant region sequence is represented only two to three times per haploid mouse genome, a finding that rules out a simple stringent germ line mechanism which would require the constant region sequence to be represented hundreds if not thousands of times. Hybridization studies involving (125)I-labeled myeloma light chain mRNA yield interesting results which may eventually permit us to distinguish between the remaining somatic mutation and recombinational germ line hypotheses. These results reveal a major component of relatively unique frequency and a minor component with a reiteration frequency of approximately 30 to 50 copies per haploid genome. As discussed, these results do not permit us to distinguish unambiguously between a germ line model and a type of somatic mutation model that permits germ line genes corresponding to each kappa subgroup. The results do, however, clearly rule out the existence of thousands of variable region sequences so closely related to the MOPC-41 V-region as to permit extensive stable cross-hybridization.

Organization of immunoglobulin genes: reiteration frequency of the mouse kappa chain constant region gene

Hybridization kinetic analyses with synthetic DNA indicate that there are only two to three copies of the kappa constant region gene per haploid genome. This result lends weight to the argument that the immunoglobulin light chain is encoded by more than one continuous gene sequence.