Mutational activity in cell line WEHI-231

The cell line WEHI-231 expresses activation-induced cytidine deaminase (AID), the enzyme that mediates hypermutation and immunoglobulin class switch recombination in activated B cells. Although both the cDNA sequence and protein expression of AID appear normal, the frequency of mutation at the endogenous immunoglobulin locus is low. In this report, we have tested the mutational activity of the cell line with three different indicator constructs. The first construct measures a composite rate of transversions of C to G and C to A, respectively. The second construct measures only transversion from C to G. The third measures the canonical AID activity, from C to U, which after cell replication can result in a C to T transition. We found that in WEHI-231, the C to G activity is 32- to 37-times lower than in the hypermutating cell line 18–81. The C to T activity is also much reduced, but only 12-fold. We suggest that the WEHI-231 lacks an activity that subverts the faithful repair of incipient C to U mutations.     

Rapid methods for the analysis of immunoglobulin gene hypermutation: application to transgenic and gene targeted mice.

Hypermutation of immunoglobulin genes is a key process in antibody diversification. Little is known about the mechanism, but the availability of rapid facile assays for monitoring immunoglobulin hypermutation would greatly aid the development of culture systems for hypermutating B cells as well as the screening for individuals deficient in the process. Here we describe two such assays. The first exploits the non-randomness of hypermutation. The existence of a mutational hotspot in the Ser31 codon of a transgenic immunoglobulin V gene allowed us to use PCR to detect transgene hypermutation and identify cell populations in which this mutation had occurred. For animals that do not carry immunoglobulin transgenes, we exploited the fact that hypermutation extends into the region flanking the 3'-side of the rearranged J segments. We show that PCR amplification of the 3'-flank of VDJH rearrangements that involve members of the abundantly-used VHJ558 family provides a large database of mutations where the germline counterpart is unequivocally known. This assay was particularly useful for analysing endogenous immunoglobulin gene hypermutation in several mouse strains. As a rapid assay for monitoring mutation in the JH flanking region, we show that one can exploit the fact that, following denaturation/renaturation, the PCR amplified JH flanking region DNA from germinal centre B cells yields mismatched heteroduplexes which can be quantified in a filter binding assay using the bacterial mismatch repair protein MutS -Wagner et al. (1995) Nucleic Acids Res. 23, 3944-3948-. Such assays enabled us, by example, to show that antibody hypermutation proceeds in the absence of the p53 tumour suppressor gene product.     

Scope of action of the immunoglobulin mutator system

The authors have developed a method to measure the rate of spontaneous mutations taking place in IgH, the gene encoding the immunoglobulin heavy chain. When an amber chain-termination codon mutates to a sense codon, translation of the polypeptide chain will be completed, and mutant cells producing the heavy chain can be detected with a fluorescent labelled antibody. The protocol used is the compartmentalization test which minimizes any effect of selection. In subclones of the pre-B lymphocyte line 18-81, the spontaneous mutation rate in the part of IgH encoding the variable region is somewhat greater than 10(-5) mutations per base pair per generation. This supports the hypothesis that hypermutation is not dependent on cell stimulation by an antigen. In a hybrid between a cell of this line and a myeloma (which represents the terminal stage of the B-cell lineage), the mutation rate was too low to be determined by this test, less than 10(-9). When the same loss to gain procedure system was used with an opal chain-terminating codon in the part of IgH encoding the constant region (C mu), a high rate of reversion by deletion was found. Long (more than one exon) and short (less than one exon) deletions occurred at rates of 1.7 x 10(-5) and 1.4 x 10(-7) per generation, respectively. It is thought that the high rate of deletion is not related to somatic hypermutation but rather to DNA rearrangement during the heavy-chain class switch, which is occurring in these pre-B cell lines. The point mutation rate was too low to be detected above the background of deletion mutants, less than 5 x 10(-8). The immunoglobulin mutator system works weakly, if at all, on two other, nonimmunoglobulin, genes tested: B2m (beta 2 microglobulin) and the gene for ouabain resistance.     

Identification of a single base-pair mutation of TAA (Stop codon) → GAA (Glu) that causes light chain extension in a CHO cell derived IgG1

We describe here the identification of a stop codon TAA (Stop) → GAA (Glu) = Stop221E mutation on the light chain of a recombinant IgG1 antibody expressed in a Chinese hamster ovary (CHO) cell line. The extended light chain variants, which were caused by translation beyond the mutated stop codon to the next alternative in-frame stop codon, were observed by mass spectra analysis. The abnormal peptide peaks present in tryptic and chymotryptic LC–MS peptide mapping were confirmed by N-terminal sequencing as C-terminal light chain extension peptides. Furthermore, LC-MS/MS of Glu-C peptide mapping confirmed the stop221E mutation, which is consistent with a single base-pair mutation in TAA (stop codon) to GAA (Glu). The light chain variants were approximately 13.6% of wild type light chain as estimated by RP-HPLC analysis. DNA sequencing techniques determined a single base pair stop codon mutation, instead of a stop codon read-through, as the cause of this light chain extension. To our knowledge, the stop codon mutation has not been reported for IgGs expressed in CHO cells. These results demonstrate orthogonal techniques should be implemented to characterize recombinant proteins and select appropriate cell lines for production of therapeutic proteins because modifications could occur at unexpected locations.     

Identification of a single base-pair mutation of TAA (Stop codon) → GAA (Glu) that causes light chain extension in a CHO cell derived IgG1

We describe here the identification of a stop codon TAA (Stop) → GAA (Glu) = Stop221E mutation on the light chain of a recombinant IgG1 antibody expressed in a Chinese hamster ovary (CHO) cell line. The extended light chain variants, which were caused by translation beyond the mutated stop codon to the next alternative in-frame stop codon, were observed by mass spectra analysis. The abnormal peptide peaks present in tryptic and chymotryptic LC–MS peptide mapping were confirmed by N-terminal sequencing as C-terminal light chain extension peptides. Furthermore, LC-MS/MS of Glu-C peptide mapping confirmed the stop221E mutation, which is consistent with a single base-pair mutation in TAA (stop codon) to GAA (Glu). The light chain variants were approximately 13.6% of wild type light chain as estimated by RP-HPLC analysis. DNA sequencing techniques determined a single base pair stop codon mutation, instead of a stop codon read-through, as the cause of this light chain extension. To our knowledge, the stop codon mutation has not been reported for IgGs expressed in CHO cells. These results demonstrate orthogonal techniques should be implemented to characterize recombinant proteins and select appropriate cell lines for production of therapeutic proteins because modifications could occur at unexpected locations.     

Development of Transgenic Mice Containing an Introduced Stop Codon on the Human Methylmalonyl-CoA Mutase Locus

The mutation R403stop was found in an individual with mut⁰ methylmalonic aciduria (MMA) which resulted from a single base change of C→T in exon 6 of the methylmalonyl-CoA mutase gene (producing a TGA stop codon). In order to accurately model the human MMA disorder we introduced this mutation onto the human methylmalonyl-CoA mutase locus of a bacterial artificial chromosome. A mouse model was developed using this construct.The transgene was found to be intact in the mouse model, with 7 copies integrated at a single site in chromosome 3. The phenotype of the hemizygous mouse was unchanged until crossed against a methylmalonyl-CoA mutase knockout mouse. Pups with no endogenous mouse methylmalonyl-CoA mutase and one copy of the transgene became ill and died within 24 hours. This severe phenotype could be partially rescued by the addition of a transgene carrying two copies of the normal human methylmalonyl-CoA mutase locus. The “humanized” mice were smaller than control litter mates and had high levels of methylmalonic acid in their blood and tissues.This new transgenic MMA stop codon model mimics (at both the phenotypic and genotypic levels) the key features of the human MMA disorder. It will allow the trialing of pharmacological and, cell and gene therapies for the treatment of MMA and other human metabolic disorders caused by stop codon mutations.     

Somatic hypermutation of immunoglobulin kappa may depend on sequences 3'' of C kappa and occurs on passenger transgenes.

We have compared the pattern of somatic mutation in different immunoglobulin kappa transgenes and suggest that an element(s) located between 1 kb and 9 kb 3' of C kappa is necessary for somatic hypermutation of the antibody V gene. The sequences of transgenic and endogenous Ig V regions were determined in antigen-specific B cell hybridomas specific for 2-phenyloxazolone from independent lines of hyperimmunized transgenic mice. We analysed somatic mutation of the transgene both in hybridomas in which the transgenic kappa chain contributes to the antigen combining site as well as in hybridomas in which the transgene is a passenger with the expressed antibody being composed of endogenously-encoded heavy and light chains. In both cases, nucleotide changes in the transgene are correctly targeted to the V region and are absent from the C region. They accumulate at a similar rate to that in the endogenous Ig genes within the same cell and we find that, irrespective of whether or not the transgene kappa is directly selected by antigen, somatic mutation occurs at a similar rate and involves only single base substitutions. Furthermore, the pattern of mutations in passenger transgenes gives information about the intrinsic sequence specificities of the somatic hypermutation mechanism.     

Overexpression of the RADICAL-INDUCED CELL DEATH1 (RCD1) gene of Arabidopsis causes weak rcd1 phenotype with compromised oxidative-stress responses

rcd1 is a mutant of Arabidopsis thaliana that is more resistant to methyl viologen, but more sensitive to ozone than the wild type. rcd1-2 is caused by a single nucleotide substitution that results in a premature stop codon at Trp-332. The rcd1-2 mRNA level does not change significantly with the mutation. Since overexpression of rcd1-1 cDNA has been shown to bring about an rcd1-like phenotype, we created and examined the overexpression lines of RCD1 by the use of the cauliflower mosaic virus 35S promoter. The transgenic lines exhibited a weak rcd1-like phenotype, although no resistance to methyl viologen was observed. Further, they fully complemented the aberrant rcd1-2 phenotype. Subcellular localization of RCD1 was examined by transiently expressing green fluorescent protein (GFP) fused with RCD1 in onion epidermal cells. GFP signals are observed as aggregated foci in the inner nuclear matrix-like region.     

alpha-L-iduronidase premature stop codons and potential read-through in mucopolysaccharidosis type I patients

alpha-L-Iduronidase is a glycosyl hydrolase involved in the sequential degradation of the glycosaminoglycans heparan sulphate and dermatan sulphate. A deficiency in alpha-L-iduronidase results in the lysosomal accumulation and urinary secretion of partially degraded glycosaminoglycans and is the cause of the lysosomal storage disorder mucopolysaccharidosis type I (MPS I; Hurler and Scheie syndromes; McKusick 25280). The premature stop codons Q70X and W402X are two of the most common alpha-l-iduronidase gene (IDUA) mutations accounting for up to 70% of MPS I disease alleles in some populations. Here, we have reported a new mutation, making a total of 15 different mutations that can cause premature IDUA stop codons and have investigated the biochemistry of these mutations. Natural stop codon read-through was dependent on the fidelity of the codon when evaluated at Q70X and W402X in CHO-K1 cells, but the three possible stop codons TAA, TAG and TGA, had different effects on mRNA stability and this effect was context dependent. In CHO-K1 cells expressing the Q70X and W402X mutations, the level of gentamicin-enhanced stop codon read-through was slightly less than the increment in activity caused by a lower fidelity stop codon. In this system, gentamicin had more effect on read-through for the TAA and TGA stop codons when compared to the TAG stop codon. In an MPS I patient study, premature TGA stop codons were associated with a slightly attenuated clinical phenotype, when compared to classical Hurler syndrome (e.g. W402X/W402X and Q70X/Q70X genotypes with TAG stop codons). Natural read-through of premature stop codons is a potential explanation for variable clinical phenotype in MPS I patients. Enhanced stop codon read-through is a potential treatment strategy for a large sub-group of MPS I patients.     

Histone H2A and H2B Are Monoubiquitinated at AID-Targeted Loci

Background

Somatic hypermutation introduces base substitutions into the rearranged and expressed immunoglobulin (Ig) variable regions to promote immunity. This pathway requires and is initiated by the Activation Induced Deaminase (AID) protein, which deaminates cytidine to produce uracils and UG mismatches at the Ig genes. Subsequent processing of uracil by mismatch repair and base excision repair factors contributes to mutagenesis. While selective for certain genomic targets, the chromatin modifications which distinguish hypermutating from non-hypermutating loci are not defined.

Methodology/Principal Findings

Here, we show that AID-targeted loci in mammalian B cells contain ubiquitinated chromatin. Chromatin immunoprecipitation (ChIP) analysis of a constitutively hypermutating Burkitt''s B cell line, Ramos, revealed the presence of monoubiquitinated forms of both histone H2A and H2B at two AID-associated loci, but not at control loci which are expressed but not hypermutated. Similar analysis using LPS activated primary murine splenocytes showed enrichment of the expressed V_H and Sγ3 switch regions upon ChIP with antibody specific to AID and to monoubiquitinated H2A and H2B. In the mechanism of mammalian hypermutation, AID may interact with ubiquitinated chromatin because confocal immunofluorescence microscopy visualized AID colocalized with monoubiquitinated H2B within discrete nuclear foci.

Conclusions/Significance

Our results indicate that monoubiquitinated histones accompany active somatic hypermutation, revealing part of the histone code marking AID-targeted loci. This expands the current view of the chromatin state during hypermutation by identifying a specific nucleosome architecture associated with somatic hypermutation.     

Mutation pattern of immunoglobulin transgenes is compatible with a model of somatic hypermutation in which targeting of the mutator is linked to the direction of DNA replication.

We have previously demonstrated that B lymphocyte specific somatic mutations are introduced into the variable regions of immunoglobulin kappa transgenes in two independent transgenic mouse lines. The frequency, distribution and nature of these mutations strongly suggest that they arose as a result of the process of somatic hypermutation, which is responsible, in part, for affinity maturation during an immune response. Unexpectedly, in these multiple copy transgenic lines, many of the transgene copies showed no evidence of somatic mutation. This paradox was addressed by determining the sequence of each transgene copy in several B cell hybridomas derived from a mouse line carrying three copies of the kappa transgene. It was found that the somatic hypermutation process in different B cells from the same mouse preferentially targets one, but not the same, transgene copy. We present a model, based on the pattern of this targeting, which links somatic hypermutation to the orientation of the Ig gene relative to the direction of DNA replication.     

Identification of a novel splicing mutation and 1-bp deletion in the 17α-hydroxylase gene of Japanese patients with 17α-hydroxylase deficiency

We report studies of two unrelated Japanese patients with 17α-hydroxylase deficiency caused by mutations of the 17α-hydroxylase (CYP17) gene. We amplified all eight exons of the CYP17 gene, including the exon-intron boundaries, by the polymerase chain reaction and determined their nucleotide sequences. Patient 1 had novel, compound heterozygous mutations of the CYP17 gene. One mutant allele had a guanine to thymine transversion at position +5 in the splice donor site of intron 2. This splice-site mutation caused exon 2 skipping, as shown by in vitro minigene expression analysis of an allelic construct, resulting in a frameshift and introducing a premature stop codon (TAG) 60 bp downstream from the exon 1-3 boundary. The other allele had a missense mutation of His (CAC) to Leu (CTC) at codon 373 in exon 6. These two mutations abolished the 17α-hydroxylase and 17,20-lyase activities. Restriction fragment length polymorphism (RFLP) analysis with a mismatch oligonucleotide showed that the patient’s mother and brother carried the splice-site mutation, but not the missense mutation. Patient 2 was homozygous for a novel 1-bp deletion (cytosine) at codon 131 in exon 2. This 1-bp deletion produces a frameshift in translation and introduces a premature stop codon (TAG) proximal to the highly conserved heme iron-binding cysteine at codon 442 in microsomal cytochrome P450 steroid 17α-hydroxylase (P450c17). RFLP analysis showed that the mother was heterozygous for the mutation. Received: 15 November 1997 / Accepted: 15 March 1998